Np/np+ Advanced Diagnostics

Transcript

Technical Publications 2202119 Revision 13 CT HiSpeed Series Advanced Diagnostics Copyrighte 1998, 1999, 2000, 2001 by General Electric Company Advanced Service Documentation Property of GE For GE Service Personnel Only No Rights Licensed – Do Not Use or Copy Disclosure to Third Parties Prohibited CT HISPEED SERIES ADVANCED DIAGNOSTICS PROPRIETARY TO GENERAL ELECTRIC COMPANY REV 0 2202119 D THIS SERVICE MANUAL IS AVAILABLE IN ENGLISH ONLY. WARNING D IF A CUSTOMER’S SERVICE PROVIDER REQUIRES A LANGUAGE OTHER THAN ENGLISH, IT IS THE CUSTOMER’S RESPONSIBILITY TO PROVIDE TRANSLATION SERVICES. D DO NOT ATTEMPT TO SERVICE THE EQUIPMENT UNLESS THIS SERVICE MANUAL HAS BEEN CONSULTED AND IS UNDERSTOOD. D FAILURE TO HEED THIS WARNING MAY RESULT IN INJURY TO THE SERVICE PROVIDER, OPERATOR OR PATIENT FROM ELECTRIC SHOCK, MECHANICAL OR OTHER HAZARDS. D CE MANUEL DE MAINTENANCE N’EST DISPONIBLE QU’EN ANGLAIS. AVERTISSEMENT D SI LE TECHNICIEN DU CLIENT A BESOIN DE CE MANUEL DANS UNE AUTRE LANGUE QUE L’ANGLAIS, C’EST AU CLIENT QU’IL INCOMBE DE LE FAIRE TRADUIRE. D NE PAS TENTER D’INTERVENTION SUR LES ÉQUIPEMENTS TANT QUE LE MANUEL SERVICE N’A PAS ÉTÉ CONSULTÉ ET COMPRIS. D LE NON-RESPECT DE CET AVERTISSEMENT PEUT ENTRAÎNER CHEZ LE TECHNICIEN, L’OPÉRATEUR OU LE PATIENT DES BLESSURES DUES À DES DANGERS ÉLECTRIQUES, MÉCANIQUES OU AUTRES. WARNUNG D DIESES KUNDENDIENST–HANDBUCH EXISTIERT NUR IN ENGLISCHER SPRACHE. D FALLS EIN FREMDER KUNDENDIENST EINE ANDERE SPRACHE BENÖTIGT, IST ES AUFGABE DES KUNDEN FÜR EINE ENTSPRECHENDE ÜBERSETZUNG ZU SORGEN. D VERSUCHEN SIE NICHT, DAS GERÄT ZU REPARIEREN, BEVOR DIESES KUNDENDIENST–HANDBUCH NICHT ZU RATE GEZOGEN UND VERSTANDEN WURDE. D WIRD DIESE WARNUNG NICHT BEACHTET, SO KANN ES ZU VERLETZUNGEN DES KUNDENDIENSTTECHNIKERS, DES BEDIENERS ODER DES PATIENTEN DURCH ELEKTRISCHE SCHLÄGE, MECHANISCHE ODER SONSTIGE GEFAHREN KOMMEN. D ESTE MANUAL DE SERVICIO SÓLO EXISTE EN INGLÉS. AVISO D SI ALGÚN PROVEEDOR DE SERVICIOS AJENO A GEMS SOLICITA UN IDIOMA QUE NO SEA EL INGLÉS, ES RESPONSABILIDAD DEL CLIENTE OFRECER UN SERVICIO DE TRADUCCIÓN. D NO SE DEBERÁ DAR SERVICIO TÉCNICO AL EQUIPO, SIN HABER CONSULTADO Y COMPRENDIDO ESTE MANUAL DE SERVICIO. D LA NO OBSERVANCIA DEL PRESENTE AVISO PUEDE DAR LUGAR A QUE EL PROVEEDOR DE SERVICIOS, EL OPERADOR O EL PACIENTE SUFRAN LESIONES PROVOCADAS POR CAUSAS ELÉCTRICAS, MECÁNICAS O DE OTRA NATURALEZA. a CT HISPEED SERIES ADVANCED DIAGNOSTICS PROPRIETARY TO GENERAL ELECTRIC COMPANY REV 0 2202119 ATENÇÃO D ESTE MANUAL DE ASSISTÊNCIA TÉCNICA SÓ SE ENCONTRA DISPONÍVEL EM INGLÊS. D SE QUALQUER OUTRO SERVIÇO DE ASSISTÊNCIA TÉCNICA, QUE NÃO A GEMS, SOLICITAR ESTES MANUAIS NOUTRO IDIOMA, É DA RESPONSABILIDADE DO CLIENTE FORNECER OS SERVIÇOS DE TRADUÇÃO. D NÃO TENTE REPARAR O EQUIPAMENTO SEM TER CONSULTADO E COMPREENDIDO ESTE MANUAL DE ASSISTÊNCIA TÉCNICA. D O NÃO CUMPRIMENTO DESTE AVISO PODE POR EM PERIGO A SEGURANÇA DO TÉCNICO, OPERADOR OU PACIENTE DEVIDO A‘ CHOQUES ELÉTRICOS, MECÂNICOS OU OUTROS. AVVERTENZA D IL PRESENTE MANUALE DI MANUTENZIONE È DISPONIBILE SOLTANTO IN INGLESE. D SE UN ADDETTO ALLA MANUTENZIONE ESTERNO ALLA GEMS RICHIEDE IL MANUALE IN UNA LINGUA DIVERSA, IL CLIENTE È TENUTO A PROVVEDERE DIRETTAMENTE ALLA TRADUZIONE. D SI PROCEDA ALLA MANUTENZIONE DELL’APPARECCHIATURA SOLO DOPO AVER CONSULTATO IL PRESENTE MANUALE ED AVERNE COMPRESO IL CONTENUTO. D NON TENERE CONTO DELLA PRESENTE AVVERTENZA POTREBBE FAR COMPIERE OPERAZIONI DA CUI DERIVINO LESIONI ALL’ADDETTO ALLA MANUTENZIONE, ALL’UTILIZZATORE ED AL PAZIENTE PER FOLGORAZIONE ELETTRICA, PER URTI MECCANICI OD ALTRI RISCHI. b CT HISPEED SERIES ADVANCED DIAGNOSTICS PROPRIETARY TO GENERAL ELECTRIC COMPANY REV 0 2202119 IMPORTANT! . . . X-RAY PROTECTION X-ray equipment if not properly used may cause injury. Accordingly, the instructions herein contained should be thoroughly read and understood by everyone who will use the equipment before you attempt to place this equipment in operation. The General Electric Company, Medical Systems Group, will be glad to assist and cooperate in placing this equipment in use. Although this apparatus incorporates a high degree of protection against x-radiation other than the useful beam, no practical design of equipment can provide complete protection. Nor can any practical design compel the operator to take adequate precautions to prevent the possibility of any persons carelessly exposing themselves or others to radiation. It is important that everyone having anything to do with x-radiation be properly trained and fully acquainted with the recommendations of the National Council on Radiation Protection and Measurements as published in NCRP Reports available from NCRP Publications, 7910 Woodmont Avenue, Room 1016, Bethesda, Maryland 20814, and of the International Commission on Radiation Protection, and take adequate steps to protect against injury. The equipment is sold with the understanding that the General Electric Company, Medical Systems Group, its agents, and representatives have no responsibility for injury or damage which may result from improper use of the equipment. Various protective material and devices are available. It is urged that such materials or devices be used. CERTIFIED ELECTRICAL CONTRACTOR STATEMENT All electrical installations that are preliminary to positioning of the equipment at the site prepared for the equipment shall be performed by licensed electrical contractors. In addition, electrical feeds into the Power Distribution Unit shall be performed by licensed electrical contractors. Other connections between pieces of electrical equipment, calibrations, and testing shall be performed by qualified GE Medical personnel. The products involved (and the accompanying electrical installations) are highly sophisticated, and special engineering competence is required. In performing all electrical work on these products, GE will use its own specially trained field engineers. All of GE’s electrical work on these products will comply with the requirements of the applicable electrical codes. The purchaser of GE equipment shall only utilize qualified personnel (i.e., GE’s field engineers, personnel of third-party service companies with equivalent training, or licensed electricians) to perform electrical servicing on the equipment. c CT HISPEED SERIES ADVANCED DIAGNOSTICS PROPRIETARY TO GENERAL ELECTRIC COMPANY REV 0 2202119 DAMAGE IN TRANSPORTATION All packages should be closely examined at time of delivery. If damage is apparent, have notation “damage in shipment” written on all copies of the freight or express bill before delivery is accepted or “signed for” by a General Electric representative or a hospital receiving agent. Whether noted or concealed, damage MUST be reported to the carrier immediately upon discovery, or in any event, within 14 days after receipt, and the contents and containers held for inspection by the carrier. A transportation company will not pay a claim for damage if an inspection is not requested within this 14 day period. Call Traffic and Transportation, Milwaukee, WI (414) 827–3449 / 8*285–3449 immediately after damage is found. At this time be ready to supply name of carrier, delivery date, consignee name, freight or express bill number, item damaged and extent of damage. Complete instructions regarding claim procedure are found in Section “S” of the Policy & Procedure Bulletins. OMISSIONS & ERRORS GE personnel, please use the GEMS CQA Process to report all omissions, errors, and defects in this documentation. Customers, please contact your GE Sales or Service representatives. CAUTION Do not use the following devices near this equipment. Use of these devices near this equipment could cause this equipment to malfunction. Devices not to be used near this equipment: Devices which intrinsically transmit radio waves such as; cellular phone, radio transceiver, mobile radio transmitter, radio–controlled toy, etc. Keep power to these devices turned off when near this equipment. Medical staff in charge of this equipment is required to instruct technicians, patients and other people who may be around this equipment to fully comply with the above regulation. d CT HISPEED SERIES ADVANCED DIAGNOSTICS PROPRIETARY TO GENERAL ELECTRIC COMPANY REV 13 2202119 LIST OF EFFECTIVE PAGES Off–line Test 3–1 to 3–6 12 Error Message 4–1 to 4–53 13 i 9 1–1 to 1–19 10 2–1 5 i to ii 11 LED Description 1–1 to 1–11 11 Errors, Diagnostics & Troubleshooting (NP, NP+, NP+ Twin) 2–1 to 2–39 11 Errors, Diagnostics & Troubleshooting (NP++, NP++ Twin) 3–1 to 3–45 13 4–1 to 4–47 11 5 Errors, Diagnostics & Troubleshooting (for p5.4 or later JEDI Software) 6–1 to 6–11 9 6 (Functional Diagram) i 5 7–1 to 7–2 11 Emergency 1–1 5 i 10 Safety Loop 2–1 5 LED Description 1–1 to 1–33 10 Gantry Rotation 3–1 5 Test Programs 2–1 to 2–18 11 Tilt FWD/BWD 4–1 5 Host Processor Troubleshooting 3–1 to 3–11 11 Cradle In/Out 5–1 5 NPR (Recon Engine) Troubleshooting 4–1 to 4–23 10 IMS In/Out 6–1 5 i 13 Table Up/Down 7–1 5 LED Description 1–1 to 1–9 10 Auto Voice 8–1 5 Power–on Test 2–1 to 2–5 1 Blank/Rear cover – Tab – Section Page REV – Title page 13 Title page rear blank (Warning and other important information) a to d 0 (Revision Information) A to C 13 (System Notation (NP, NP+, ...) i 11 1 (System) i to iii 13 Service Menu 1–1 to 1–92 13 Message Display 2–1 to 2–5 10 Unix Commands 3–1 to 3–11 13 Irix Guide 4–1 to 4–10 11 Software Structure 5–1 to 5–6 Troubleshooting Ring Value Measurement 2 (Operator Console) 3 (Table/Gantry) 4 (DAS/Detector) Channel – Ring Radius Table LED Description 5 (X–ray Generator) – A CT HISPEED SERIES ADVANCED DIAGNOSTICS PROPRIETARY TO GENERAL ELECTRIC COMPANY REV 13 2202119 REVISION HISTORY REV Date 13 8/22/01 Primary Reason for Change System Operator Console Updated the error message information for V/R 6 (Sec. 4). DAS/Detector – Functional Diagram 4/18/01 – Table/Gantry X–ray Generator 12 Updated: Service Tool For V/R 6 (Sec. 1) and Unix Commands (Sec. 3). System Added explanations to 30–0324H error (Sec. 3). – Updated: For V/R 5.5 (sec 1) Added: SnapState option, TubeTempMax, history log (sec3) Table/Gantry 11 12/08/00 System Added a new TGP board part No. (Sec. 3). Colored: Sec. 1, 4. Added the section ‘Ring Value Measurement’ (Sec. 7). Operator Console Colored: Sec. 2, 3. Table/Gantry Colored: Sec. 3. X–ray Generator Colored: Sec. 1. Updated the descriptions–which section is applicable to which systems (Sec. 2, 3, 4). 10 8/31/00 System Changed: The stationary scan parameter during aperture Z–axis zigzag motion (Sec. 1–tube procedure(change)). Added (within Sec. 1): View log file note on GSA, Scan Analysis – Z–Axis Tracking, A note for Raw Data Functions, Z–axis collimation diagnostics. Adopted the new revision control for Sec. 2, 3, 4. Operator Console Added: New DASM information (DASM II–VDB (2191523–3), DASM II–LCAM (2191524–2)) (Sec. 1), Other error message information to IDE tests (Sec. 3), NPR (Recon Engine) Troubleshooting (Sec. 4). Adopted the new revision control for Sec. 2. Table/Gantry Adopted the new revision control for Sec. 1, 3. DAS/Detector Added the cross reference tables for Twin systems (Sec. 1). X–ray Generator Adopted the new revision control for Sec. 2, 3, 4. 9 6/02/00 – Added Twin system related information. 8 4/20/00 – JEDI p5.4 software. 7 2/25/00 – Tube spits log description; Host Processor Troubleshooting, System menu. 6 12/17/99 – Corrected some Service Menu descriptions; Service Tool for V/R 4.1; Corrected some of the XG diagnostic procedures. B CT HISPEED SERIES ADVANCED DIAGNOSTICS PROPRIETARY TO GENERAL ELECTRIC COMPANY REV 13 2202119 REVISION HISTORY REV Date Primary Reason for Change 5 10/19/99 – Added Software Structure diagram/descriptions; Corrected pin numbers in Ring Radius Charts; Corrected/Added LED descriptions; Added Power–on Test descriptions; Added NP++ XG diagnostics. 4 4/22/99 – Added Unix command information to the System tab. 3 2/25/99 – Service Menu – Automated DAS Linearity Test, Detector Channel Information, MTF Survey, TGP off–line test, Jedi V4.0 software. 2 10/29/98 – Service Menu – XG Test – Error log retrieve (Jedi). 1 7/23/98 – MTF Survey, OC H/W diag test time, LED descriptions for TGP and OGP, TGP Power–on tests and off–line tests, OGP power–on tests and error messages, XG Diagnostics, Functional Interconnection Diagrams. 0 4/09/98 – Initial release. C CT HISPEED SERIES ADVANCED DIAGNOSTICS PROPRIETARY TO GENERAL ELECTRIC COMPANY blank 2202119 D CT HISPEED SERIES ADVANCED DIAGNOSTICS PROPRIETARY TO GENERAL ELECTRIC COMPANY REV 11 2202119 SYSTEM NOTATION (NP, NP+, ...) Hardware Constitution of NP, NP+, NP++, and Twin According to system models or customer options installed on the system, a number of system specifications or functions available may differ from system to system; such are: D Selectable scan times, MA values, FOV dimensions D ‘Remote Tilt’ function D Number of arrays of DAS/detector units, i.e., single or twin DAS/detector subsystem D ... However, the ‘HiSpeed’ series scanners are principally grouped into four, for which the following notations are given respectively: ‘NP’, ‘NP+’, ‘NP++’ and ‘Twin’ In this ‘Diagnostics’ manual, these notations NP, NP+, NP++, and Twin are used to describe differences among these four groups and to make descriptions of this manual read simpler. (However, ‘Twin’ is further grouped into two, that is, ‘NP+ Twin’ and ‘NP++ Twin’. In general outline, NP+ Twin systems are NP/NP+ systems with a twin DAS/detector, and NP++ Twin systems are NP++ systems with a twin DAS/detector. These notations also will be used when required.) The following table describes the constitution of the major hardware of NP, NP+, NP++, and Twin. Hardware Constitution Subsystem/Component OC Gantry Table NP NP+ – Mechanics – Positioning Light NP++ NP+ Twin common Halogen Lamps Laser Mechanics – others common Electrics Firmware only is different. IMS (Intermediate Support) NP++ Twin Standard or Option Others Standard Standard or Option Standard common DAS – common twin DAS Detector – common twin detector X–ray Generator – common (Jedi) NP++ Jedi Jedi NP++ Jedi X–ray Tube – common (D3142T tube) D3152T tube D3142T tube D3152T tube PDU – common i CT HISPEED SERIES ADVANCED DIAGNOSTICS PROPRIETARY TO GENERAL ELECTRIC COMPANY blank 2202119 ii CT HISPEED SERIES ADVANCED DIAGNOSTICS PROPRIETARY TO GENERAL ELECTRIC COMPANY REV 13 2202119 SYSTEM TABLE OF CONTENTS SECTION PAGE SECTION 1 – SERVICE TOOL . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 1-1 1-2 1-3 1-4 1-5 1-6 1-7 1-8 1-9 1-10 1-11 1-12 1-13 1-14 1-15 1-16 1-17 1-18 1-19 1-20 1-21 GENERAL . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 1-1-1 Service Tool Structure . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 1-1-2 Service Tool Index (Alphabetical Order) . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 1-1-3 Service Desktop User Interface (For V/R 5.5x or later ONLY) . . . . . . . . . . . 1-1-4 Home (For V/R 5.5x or later ONLY) . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 1-1-5 Security Key . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 1-1-6 Accessing the System Message Log . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . AUDIO CONTROL . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . AUTOMATED ALIGNMENT . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 1-3-1 POR (For the Single Detector System ONLY) . . . . . . . . . . . . . . . . . . . . . . . . . AUTO DAS LINEARITY TEST . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . AUTO POST RECON TEST . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . DAS DATA TRANSFER TEST . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . DASM DIAG . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . DETECTOR CHANNEL INFORMATION . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . GENERATOR TEST . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . GENERIC SYSTEM ANALYZER . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 1-10-1 View Log Files . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 1-10-2 Format Raw Data . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 1-10-3 Analysis . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . GETSTATS . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 1-11-1 General . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 1-11-2 Command . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . HEAT SOAK . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . H/W DIAGNOSTICS . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 1-13-1 Diagnostics . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 1-13-1-1 Interactive Test . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 1-13-1-2 Offline Test . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . IMAGE PROFILE . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . MTF SURVEY . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . OFFLINE SCAN . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 1-16-1 T/G Control . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . RAW DATA FUNCTIONS . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . SCAN ANALYSIS . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 1-18-1 Z–Axis Tracking . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 1-18-2 DD . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . SERVICE CALIBRATION . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . SERVICE MANUAL . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . SHUTDOWN . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . i 1–1 1–1 1–1 1–3 1–8 1–9 1–16 1–17 1–18 1–19 1–20 1–24 1–25 1–26 1–27 1–28 1–29 1–32 1–32 1–34 1–37 1–42 1–42 1–43 1–44 1–45 1–47 1–48 1–52 1–53 1–54 1–59 1–59 1–61 1–62 1–67 1–71 1–75 1–76 1–77 SYSTEM CT HISPEED SERIES ADVANCED DIAGNOSTICS PROPRIETARY TO GENERAL ELECTRIC COMPANY REV 13 2202119 TABLE OF CONTENTS (continued) SECTION PAGE 1-21-1 Application Shutdown . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 1-21-2 System Shutdown (For the system V/R 5.5 or later) – Class C . . . . . . . . . . SYSTEM BROWSER . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . TUBE PRO. (NOFILM, CHANGE) . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . TUBE PRO. (NOFILM, MFG.) . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . TUBE PROCEDURE (CHANGE) . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . TUBE PROCEDURE (MFG.) . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . UPDATE SYSTEM LOG . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . USER PREFERENCE . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . VECTOR CONVERT . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 1–77 1–77 1–78 1–83 1–84 1–85 1–89 1–90 1–91 1–92 SECTION 2 – MESSAGE DISPLAY . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 2–1 1-22 1-23 1-24 1-25 1-26 1-27 1-28 1-29 2-1 2-2 MESSAGE DESKTOP . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . ERROR LOG VIEWER MESSAGE FORMAT . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 2–1 2–3 SECTION 3 – UNIX COMMANDS . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 3–1 3-1 UNIX COMMANDS FOR TROUBLESHOOTING . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 3-1-1 Disk Usage Information . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 3-1-2 Recovery . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 3-1-3 Software Problem . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 3-1-4 How to Collect Log (SnapState) . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 3-1-5 How to Display History Log (For V/R 4.13 or later) . . . . . . . . . . . . . . . . . . . . . 3-1-6 How to Use MOD . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 3-1-7 How to Display Cooling Trend . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 3-1-8 How to Rise the Tube Temperature to 100 % . . . . . . . . . . . . . . . . . . . . . . . . . 3-1-9 How to Install SMPTE and QA Images . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 3-1-10 How to Change AutoVoice, X–ray Buzzer Sounds . . . . . . . . . . . . . . . . . . . . . 3-1-11 How to Change Image Direction . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 3-1-12 How to Change Image Annotation . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 3-1-13 How to Change Display Gamma . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 3-1-14 How to Restart Process . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 3-1-15 How to Delete All Recon Queues . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 3-1-16 How to Change Exhibition Mode, Stand Alone Mode . . . . . . . . . . . . . . . . . . . 3-1-17 How to Perform Z–axis Collimation Diagnostics . . . . . . . . . . . . . . . . . . . . . . . 3–1 3–1 3–1 3–1 3–2 3–5 3–6 3–6 3–7 3–7 3–8 3–8 3–8 3–9 3–9 3–9 3–10 3–11 SECTION 4 – IRIX GUIDE . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 4–1 4-1 4-2 4-3 4-4 4-5 INTRODUCTION . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . IRIX OPERATING COMMANDS . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . LOG FILES . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . SCRIPTS AND EXECUTABLES . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . VI EDITOR . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . ii 4–1 4–2 4–6 4–8 4–10 SYSTEM CT HISPEED SERIES ADVANCED DIAGNOSTICS PROPRIETARY TO GENERAL ELECTRIC COMPANY REV 13 2202119 TABLE OF CONTENTS (continued) SECTION PAGE SECTION 5 – SOFTWARE STRUCTURE . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 5-1 5-2 5–1 SOFTWARE STRUCTURE DIAGRAM . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . SOFTWARE MODULE DESCRIPTION . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 5-2-1 UIF: User Interface . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 5-2-2 IOS: Imaging and Operating System . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 5-2-3 ScanReconMgr: Scan Recon Manager . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 5-2-4 ScanCtrl: Scan Control . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 5-2-5 tgp_in, tgp_out . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 5-2-6 AcqCtrl: Acquisition Control . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 5-2-7 RawMgr: Raw Manager . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 5-2-8 RawLoad: Raw Load . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 5-2-9 RawStore/RawStoreSlave . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 5-2-10 ReconCtrl: Recon Control . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 5-2-11 ReconJob: Recon Job . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 5-2-12 ImageReceive, RTImageReceive, RTScoutReceive . . . . . . . . . . . . . . . . . . . . 5-2-13 ToolCtrl: Tool Control . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 5–1 5–2 5–2 5–2 5–2 5–3 5–3 5–4 5–4 5–4 5–5 5–5 5–5 5–6 5–6 SECTION 6 – TROUBLESHOOTING . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 6–1 6-1 COMMUNICATION BETWEEN OC, TGP, OGP, CIF AND JEDI . . . . . . . . . . . . . . . . . 6-1-1 Theory of Wake–up Communication . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 6-1-2 Error Messages and Troubleshooting . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . DAS DATA PATH . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 6-2-1 Pre–requisite . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 6-2-2 DAS TRIG Signal Troubleshooting . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 6-2-3 DAS Data Troubleshooting . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 6-2-4 Data Path Troubleshooting under Intermittent Failure . . . . . . . . . . . . . . . . . . 6–1 6–1 6–2 6–3 6–3 6–4 6–7 6–9 SECTION 7 – RING VALUE MEASUREMENT . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 7–1 6-2 iii SYSTEM CT HISPEED SERIES ADVANCED DIAGNOSTICS PROPRIETARY TO GENERAL ELECTRIC COMPANY blank 2202119 iv SYSTEM CT HISPEED SERIES ADVANCED DIAGNOSTICS PROPRIETARY TO GENERAL ELECTRIC COMPANY REV 13 2202119 SECTION 1 – SERVICE TOOL 1-1 GENERAL Click on the ‘Service’ icon to display the Service Tool desktop. 1-1-1 Service Tool Structure The Tools for V/R 5.5x or later ONLY: Underlined : Class C tool Depending on the system version, some tools cannot be used. (See table 1–1, Service tool index, Version compatibility.) Error Logs Diagnostics Image Quality Calibration OC SYSLOG (System Browser) Viewlog AW Logs (System Browser) Storelog System Browser (All features) Tube Usage (System Browser) Update System Log Shell Offline Scan Generic System Analyzer Scan Analysis Auto Scan Auto DAS Linearity Test DAS Data Transfer Test Generator Test (Shutdown) H/W Diagnostics (Shutdown) View H/W Diag DASM Diag Auto Post Recon Test Detector Channel Information Vector Convert SnapState FRU Report Verify Security Shell Generic System Analyzer Scan Analysis Image Profile MTF Survey Install SMTPE Image Verify Security Shell Automated Alignment Service Calibration CT Number Adjustment Quick CT Number Adjustment Gravity SAG Heat Soak Audio Controls Verify Security Shell Configuration User Preference OC Hardware Info (System Browser) Software Version Verify Options Verify Security Shell * : For the system witn Version 6 or later ONLY Replacement Offline Scan Generic System Analyzer Tube Procedure (Mfg.) Tube Procedure (Change) *Tube Pro. (NoFilm, Mfg.) *Tube Pro. (NoFilm, Change) Generator Test (Shutdown) Auto DAS Linearity Test Automated Alignment Service Calibration CT Number Adjustment Quick CT Number Adjustment Verify Security Shell 1–1 Toolboxes/Utilities PM Service Manual Raw Data Function Increment Exam# Savestate Selective Save SnapState Calculator Calendar getStats Change Display IP Shutdown –Application Shutdown – System shutdown Verify Security Shell Offline Scan Generic System Analyzer Audio Controls System Browser getStats Service Notepad Verify Security Shell Home See Section 1-1-4. SYSTEM CT HISPEED SERIES ADVANCED DIAGNOSTICS PROPRIETARY TO GENERAL ELECTRIC COMPANY REV 13 1-1-1 2202119 Service Tool Structure (Continued) The Tools for V/R 5.0x or lower ONLY: Underlined : Class C tool Depending on the system version, some tools cannot be used. (See table 1–1, Service tool index, Version compatibility.) System Func. Check Service Adjustment Diagnostics & analysis Utilities Offline Scan Auto Scan Auto Image Verification Auto DAS Linearity Test Generator Test Service Calibration Automated Alignment CT Number Adjustment Quick CT Number Adj. Audio Control Heat Soak Gravity sag Tube Procedure (Mfg.) Tube Procedure (change) H/W Diagnostics DAS Data Transfer Test Auto Post Recon Test Generic System Analyzer Scan Analysis Detector Channel Information MTF Survey Image Profile Raw Data Functions Install SMPTE image Vector Convert Increment Exam# User Preference SnapState Viewlog SaveState Verify Security Service Manual Selective Save DASM Diag FRU Report Update System Log System Tools Information Calculator Calendar Unix Shell System Browser Application Shutdown Software Version 1–2 SYSTEM PROPRIETARY TO GENERAL ELECTRIC COMPANY CT HISPEED SERIES ADVANCED DIAGNOSTICS REV 13 1-1-2 2202119 Service Tool Index (Alphabetical Order) The service tools provided are listed in Table 1–1, in alphabetical order. Note The Class C tools are filled in gray. ÍÍÍÍÍÍÍÍÍÍÍÍÍÍÍÍÍÍÍÍÍÍÍÍÍÍÍÍÍÍÍÍÍÍ ÍÍÍÍÍÍÍÍÍÍÍÍÍÍÍÍÍÍÍÍÍÍÍÍÍÍÍÍÍÍÍÍÍÍ Note The Class A tools, yet including the Class C sub menu, are filled in yellow stripe. Table 1–1 Service Tool Index (Alphabetical Order) Tool Description System Software V/R Section No. (for details) Application Shutdown Terminates the application software to enter the desktop menu. All 1-21 Audio Controls X–ray On Sound Params, Alert Sound Params, Autovoice Volume, CD Sound Volume All 1-2 Auto Image Verification N/A currently. N/A – Auto Scan You can perform continuous scans automatically with several protocols, but this is the tool for engineering evaluation, not for FE (field engineer). All – Automated Alignment Tube Rough ISO Alignment, Tube ISO Alignment, Radial Alignment, Bowtie Filter Alignment, Phantom Centering, Tube POR Alignment All 1-3 Auto DAS Linearity Test Tests the linearity of CAM board amplifiers. All 1-4 Auto Post Recon Test Tests that post recon operations are correctly performed on a specified raw data file. All 1-5 AW Logs (System Browser) Shows log files of ISO LOGS in System Browser. 5.50 or later 1-22 Calculator Provided functions: All – All – 5.50 or later – All – ÍÍÍÍÍÍÍÍÍ ÍÍÍÍÍÍÍÍÍÍÍÍÍÍÍÍÍ ÍÍÍÍÍÍ ÍÍÍÍÍ ÍÍÍÍÍÍÍÍÍ ÍÍÍÍÍÍÍÍÍÍÍÍÍÍÍÍÍ ÍÍÍÍÍÍ ÍÍÍÍÍ ÍÍÍÍÍÍÍÍÍ ÍÍÍÍÍÍÍÍÍÍÍÍÍÍÍÍÍ ÍÍÍÍÍÍ ÍÍÍÍÍ ÍÍÍÍÍÍÍÍÍÍÍÍÍÍÍÍÍÍÍÍÍÍÍÍÍÍÍÍÍÍÍÍ ÍÍÍÍÍ x, /, +, –, 1/x, x^2, SQR, sin, cos, tan, log, ln, y^x, x!, (, ), etc. Calendar Monthly display. Change Display IP Allows the remote (InSite) user to change the IP Address where GUI’s and icon’s will be displayed. For no use in a Field Engineer. CT Number Adjustment KV values only can be selected (80 kV, 120 kV, 140kV). It takes approx. 30 minutes to complete it. Refer to Functional Check/Adjustment. Note: If you do not click on Confirm in the scan confirm screen within 15 minutes, Time–out occurs. 1–3 SYSTEM PROPRIETARY TO GENERAL ELECTRIC COMPANY CT HISPEED SERIES ADVANCED DIAGNOSTICS REV 13 2202119 Table 1–1 Service Tool Index (Alphabetical Order) Tool Description System Software V/R Section No. (for details) DAS Data Transfer Test Tests that test pattern data is correctly sent to the operator console. All 1-6 DASM Diag Analyzes communication status between the HOST computer and DASM or between the HOST computer and camera. 5.00 or later 1-7 Detector Channel Information Shows the relation among Channel No., ring radius, CAM No., cable No., etc. All 1-8 FRU Report When entering this menu, the errors about TGP, OGP, and DAS are displayed. Then when entering the error code and clicking on Find, a list of suspicious parts to be replaced is displayed. 5.00 or later – Generator Test Retrieve JEDI Error Log, Saved RAM upload, Saved RAM download, kV Diagnostics, Heater Diagnostic, Rotor Diagnostic, (others) All 1-9 Generic System Analyzer View Log Files All 1-10 Tube Usage Log Tube Spits Log Bad Raw Log Format Raw Data Fan Data DAS Data Analysis View Raw Data View Vector Calculations getStats Allows you to know the Gantry revolution and tube spits. 5.50 or later 1-11 Gravity sag Allows you to perform a Gravity sag procedure easily. Refer to Functional Check/Adjustment, System, X–ray Alignment, Gravity sag. 4.00 or later – Heat Soak Scan protocols (Scan Group# 1 ∼ 7) are programmed for heat soak scans. All 1-12 1–4 SYSTEM PROPRIETARY TO GENERAL ELECTRIC COMPANY CT HISPEED SERIES ADVANCED DIAGNOSTICS REV 13 2202119 Table 1–1 Service Tool Index (Alphabetical Order) Tool H/W Diagnostics Description Diagnostics: System Software V/R Section No. (for details) All 1-13 4.00 or later 1-14 Diagnostics for operator console boards and devices are provided. Read first Cautions written in Section 1-13, H/W Diagnostics, when performing safety test. View Log: Displays diagnostics related logs. Image Profile The graphical profile data on selected line of the image can be displayed. Horizontal, vertical, and free direction of a line can be selected. Increment Exam# Increments the exam No. All – Install SMPTE image Installs the SMPTE image (and QA images for V/R 5.5 or later) to the OC. All – All 1-15 For procedures to install and display the images, refer to Functional Check/Adjustment, Introduction, Common Procedures, Basic Operation. MTF Survey Calculates the image spatial resolution performance data of the system. OC Hardware Info (System Browser) Shows log files of OC Info in System Browser. 5.50 or later 1-22 OC SYSLOG (System Browser) Shows log files of SYSLOG OC in System Browser. 5.50 or later 1-22 Offline Scan Technic – Scan Type All 1-16 All – Axial, Helical, Cine, Scout, Stationary, T/G Control Quick CT Number Adj. This menu performs the CT number adjustment with fewer scans than ‘CT Number Adjustment’. It takes approx. 5 minutes to complete it. Note: If you do not click on Confirm in the scan confirm screen within 15 minutes, Time–out occurs. Raw Data Function For raw data save/load using an MOD. All 1-17 Savestate Saves/restores scan protocols, calibration files, autovoice data, and other data to/from an MOD. All – Scan Analysis Analyzes the raw data so that the scan header or cal vector can be displayed. 4.10 or later 1-18 Selective Save Saves/restores selectively scan protocols, calibration files, or autovoice data, to/from an MOD. All – Service Calibration Auto Sequence 1 ∼ 5, Q Cal, XT Cal, AV Cal, DG Cal, Asymmetric Seq All 1-19 1–5 SYSTEM PROPRIETARY TO GENERAL ELECTRIC COMPANY CT HISPEED SERIES ADVANCED DIAGNOSTICS REV 13 2202119 Table 1–1 Service Tool Index (Alphabetical Order) Tool Description System Software V/R Section No. (for details) Service Manual Displays the contents of CT service CD–ROMs. 4.00 or later 1-20 Service Notepad Allows you to make/save a memo. 5.50 or later – The memo can be seen in the message log report (Section 1-1-6). In addition, this information is recorded in the Health page file so that it will be reported to the OLC via InSite. (Unix) Shell Unix Shell window is displayed. To terminate the shell window, enter exit. All – Shutdown Includes the two types of “Shutdown”. One is application shutdown, the other is system shutdown. All 1-21 SnapState Collects information for debug purpose. All – Software Version Shows the system name and software version. (e.g., ‘HiSpeed Series 5.01’) All – ÍÍÍÍÍÍÍÍÍ ÍÍÍÍÍÍÍÍÍÍÍÍÍÍÍÍÍ ÍÍÍÍÍÍ ÍÍÍÍÍ ÍÍÍÍÍÍÍÍÍ ÍÍÍÍÍÍÍÍÍÍÍÍÍÍÍÍÍ ÍÍÍÍÍÍ ÍÍÍÍÍ ÍÍÍÍÍÍÍÍÍÍÍÍÍÍÍÍÍÍÍÍÍÍÍÍÍÍÍÍÍÍÍÍ ÍÍÍÍÍ For V/R 5.5 or later only, the detailed information of all softwares installed in the system appears. When checking current software version only, see Home, OC Application Software. (Section 1-1-4) To terminate this window, enter Q. ÍÍÍÍÍÍÍÍÍ ÍÍÍÍÍÍÍÍÍÍÍÍÍÍÍÍÍ ÍÍÍÍÍÍ ÍÍÍÍÍ ÍÍÍÍÍÍÍÍÍ ÍÍÍÍÍÍÍÍÍÍÍÍÍÍÍÍÍ ÍÍÍÍÍÍ ÍÍÍÍÍ ÍÍÍÍÍÍÍÍÍ ÍÍÍÍÍ ÍÍÍÍÍÍÍÍÍÍÍÍÍÍÍÍÍÍÍÍÍÍÍÍÍÍ ÍÍÍÍÍÍÍÍÍÍÍÍÍÍÍÍÍÍÍÍÍÍÍ ÍÍÍÍÍÍ ÍÍÍÍÍ Storelog Saves core, log, and data file to the file, /usr/sc/log/ xxxx.xxx for troubleshooting. 5.50 or later – System Browser Shows the log files of GE System Log, SYSLOG_OC, IOS_LOGS, Tube_Usage, Run_time_stats, OC_Info, Config_Files, History_log, and Software_Health_Page. 4.10 or later 1-22 System Shutdown Terminate all softwares to shut down the system. 5.50 or later 1-21 Tube Pro. (NoFilm, Change) For Single Detector system ONLY: When the tube is replaced, use this program for adjustment. 6.00 or later 1-23 Tube Pro. (NoFilm, Mfg.) For Single Detector system ONLY: For manufacturing use. 6.00 or later 1-24 Tube Procedure (change) For Twin system ONLY: When the tube is replaced, use this program for adjustment. 5.00 or later 1-25 Tube Procedure (Mfg.) For Twin system ONLY: For manufacturing use. 5.00 or later 1-26 Tube Usage (System Browser) Shows log files of Tube Usage in System Browser. 5.50 or later 1-22 Update System Log Updates ‘Tube Usage’ log, ‘Tube Spits’ log, or ‘Bad Raw’ log. All 1-27 1–6 SYSTEM PROPRIETARY TO GENERAL ELECTRIC COMPANY CT HISPEED SERIES ADVANCED DIAGNOSTICS REV 13 2202119 Table 1–1 Tool Service Tool Index (Alphabetical Order) Description System Software V/R Section No. (for details) User Preference Sets ‘Axial image direction’, ‘Gantry direction’, etc. All 1-28 Vector Convert Vectors: Warmup Whole, Warmup History, Hilight, Air & Ptm All 1-29 Verify Options Shows the options which always have been installed. 5.50 or later – All – To terminate this windows, click on Cleanup in the Service desktop or select Quit from the pop–up menu of the left upper corner of the window. Verify Security Displays information of Security Level, Key Expiration Date, and UserID. used when the security key can not be recognized. Refer to Section 1-1-5. View H/W Diag Views Diag Log, P–ON Test Log, SYSLOG, or HINV inventory. 5.50 or later – Viewlog Views GE sys log files. The same log files as ones shown in the System browser are displayed. All – 1–7 SYSTEM CT HISPEED SERIES ADVANCED DIAGNOSTICS PROPRIETARY TO GENERAL ELECTRIC COMPANY REV 13 1-1-3 2202119 Service Desktop User Interface (For V/R 5.5x or later ONLY) When Starting Service Desktop: When clicking on Service icon to start the service desktop, the Image works browser also start up and the Service Desktop hides behind it. To display the Service Desktop fully, perform either of the followings: D Click on Start SV Desktop button or D Click on the border on the Service desktop Click button. Service Desktop Click border. Cleanup The Cleanup button on the bottom of the desktop cleans up any previously opened windows, and restores the desktop to its original state, rather than closing or dismissing each individual application visible on the Service Desktop. The Cleanup button should be selected whenever the user is done with the Service Desktop or whenever it is desired to get the desktops back to a known state. 1–8 SYSTEM CT HISPEED SERIES ADVANCED DIAGNOSTICS PROPRIETARY TO GENERAL ELECTRIC COMPANY REV 13 1-1-3 2202119 Service Desktop User Interface (For V/R 5.5x or later ONLY) (Continued) Using the Mouse on the Service Desktop: Use the mouse to access and operate diagnostics and tools, or open a shell and type/enter a UNIX command line. Use the mouse to make screen selections on the service desktop. Typical mouse button functions: Function Mouse Button to be used How? Window Resize Left button Move the mouse pointer at the border of the window, then press and hold the left button and drag the cursor to resize the window. Window Move Center button 1-1-4 Move the mouse pointer at the border of the window, then press and hold the center button and drag the cursor to move the window. Home (For V/R 5.5x or later ONLY) 1–9 SYSTEM CT HISPEED SERIES ADVANCED DIAGNOSTICS PROPRIETARY TO GENERAL ELECTRIC COMPANY REV 13 1-1-4 2202119 Home (For V/R 5.5x or later ONLY) (Continued) System Information Item Facility Meanings This information is Hospital Name set in System Configuration –> System setting. Suite Name This information is Host Name set in System Configuration –> Network setting. System Type This information is Model Name set in System Configuration –> System setting. System ID This information is Machine Number set in System Configuration –> System setting. IP Address This information is IP Address set in System Configuration –> Network setting. Access Level Software Installation Date When the security key is connected to the OC, “Class M” and its expiration date are displayed. Refer to Section 1-1-5, Security Key. This information is updated automatically when performing LFC or LFW. Note that this is NOT updated when installing the patch software only. DASM Camera When selecting System Configuration –> Camera Setting –> Laser Camera, “Laser Camera” is displayed. DICOM Network Cameras This information is Device Files set in System Configuration –> Camera Setting –> DICOM Printer. Installed Tube This is information recorded in the tube usage file. This is automatically reset when performing Update system log –> Tube Usage (section 1-27) at tube replacement. Tube Install Date This is information recorded in the tube usage file. This is automatically reset when performing Update system log –> Tube Usage (section 1-27) at tube replacement. Current System Status Item Meanings System Date To modify this information, use Application shutdown –> Date Setting. System Time To modify this information, use Application shutdown –> Date Setting. OC Application Software Next Patient Exam The current application software version is displayed. The next patient examination number is displayed. Recon Status Archive Status Network Status For a remote user only: The same information as the Scan top panel, illustrated on the left, are displayed in these columns. Filming Status 1–10 SYSTEM CT HISPEED SERIES ADVANCED DIAGNOSTICS PROPRIETARY TO GENERAL ELECTRIC COMPANY REV 13 1-1-4 2202119 Home (For V/R 5.5x or later ONLY) (Continued) System Health Information Item Meanings Total Gantry Revolutions Indicates the Gantry rotation numbers in “Status” column. This indication can be reset using getStats (section 1-11). The date when the counter was reset is displayed in “Information” column. The rotation number is slightly less than the mechanical Gantry rotation counter located near the TGP board (a few %), because this software counter does NOT read all of G pulse interrupt. The data of rotation number is sent to the OC just when the Gantry stops. Total Tube Spits Indicates total tube spits numbers currently. This is automatically reset when performing Update system log –> Tube spits (section 1-27) at tube replacement. IQ Performance Tool Status This tools give us advance notice for IQ performance change. For the system with V/R 5.5x or later, the two types of warm–up scan can be selected: D Tube Warm–up: performs tube several warm–up scans. These can achieve 13% case temperature. D Daily calibration (Warm up): performs conventional tube warm–up scans (tube warm–up scans:30% case and calibration scans) plus IQ performance measurement scans. (For detail scan protocol, refer to IQ performance Measurement scan described below.) So, whenever the daily calibration is performed, the IQ performance data are collected and analyzed automatically, and the results are stored in the file, then displayed on the “Status” column of the IQ Performance Tool Status. The “Information” means the date when the status has been determined. The three types of status are displayed: D GREEN: displayed when the result is WITHIN allowable specifications. (Also refer to IQ performance tool specifications.) D YELLOW: displayed when the result is OUTSIDE OF allowable specifications. There is a possibility to affect Image Quality. (Also refer to IQ performance tool specifications.) D RED: displayed when the result is OUTSIDE OF allowable specifications. A serious Image Quality problem might occur. (Also refer to IQ performance tool specifications.) Note The results are stored as a vector file, so that they can also be seen using Scan Analysis, DD file analysis function. (For mA Smudge and Scan Time Smudge Only, they can not be seen, because the files can NOT be made.) The files is stored up to 5MB. In excess of 5MB, the directory of the files will be cleaned up when executing this tool. Since the vector files of approx. 400 KB per daily calibration are created, 10 days’ data can be stored. However calculation in Scan Analysis reduces data to be stored. 1–11 SYSTEM CT HISPEED SERIES ADVANCED DIAGNOSTICS PROPRIETARY TO GENERAL ELECTRIC COMPANY REV 13 1-1-4 2202119 Home (For V/R 5.5x or later ONLY) (Continued) IQ Performance Measurement Scan The following scans are performed as IQ Performance Measurement scans. Item Scan Type Scan Time Thickness kV mA Focus Rotor X–ray Air Calibration 10mm Axial 1.0 10 120 30 Large ON ON Air Calibration 7mm Axial 1.0 7 120 40 Large ON ON Air Calibration 5mm Axial 1.0 5 120 60 Large ON ON Air Calibration 3mm Axial 1.0 3 120 100 Large ON ON Offset SD/Mean Axial 0.8 1 0 0 Large ON OFF Detector/DAS Linearity Stationary 1.0 3 120 60 Large ON ON Detector/DAS Linearity Stationary 1.0 3 120 200 Large ON ON Detector/DAS Linearity Stationary 3.0 3 120 70 Large ON ON AB Ratio Stationary 1.0 1 120 100 Small ON ON Z–axis stop movement Stationary 3.0 1 120 100 Small ON ON Note: The air calibration renewal data are used for calculating air calibration drift. 1–12 SYSTEM CT HISPEED SERIES ADVANCED DIAGNOSTICS PROPRIETARY TO GENERAL ELECTRIC COMPANY REV 13 1-1-4 2202119 Home (For V/R 5.5x or later ONLY) (Continued) IQ Performance Tool Specifications For equation for each item below, refer to IQ Performance Tool Analysis. Item Offset Mean Offset SD Meanings Green Yellow Red –1.0 ≤ Mean ≤ 1.0 –2.0 ≤ Mean ≤ 2.0 Mean < –2.0 or Mean >2.0 SD ≤ 2.0 SD ≤ 3.5 SD > 3.5 0.95 ≤ New/Old ≤ 1.05 0.90 ≤ New/Old ≤ 1.10 New/Old < 0.90 or New/Old > 1.10 mA–dependent DAS Differences between Linearity variation #25 and #26 (Center module) and be(Center section only) tween #27 and #26 ≤ 500 ppm (0.05%) ≤ 1000 ppm (0.1%) >1000 ppm (0.1%) mA–dependent DAS Linearity variation (Total) Difference among channels ≤ 1000 ppm (0.1%) ≤ 2000 ppm (0.2%) >2000 ppm (0.2%) Validity of offset Mean value. Validity of offset SD value. Air Cal Drift 10000 Stability of 10 mm air calibration. Air Cal Drift 7000 Stability of 7 mm air calibration. Air Cal Drift 5000 Stability of 5 mm air calibration. Air Cal Drift 3000 Stability of 3 mm air calibration. mA Smudge mA Band Specifications Scan Time Smudge Scan–time–dependent DAS Linearity variation (Center section only) Differences between #25 and #26 (Center module) and between #27 and #26 ≤ 500 ppm (0.05%) ≤ 1000 ppm (0.1%) >1000 ppm (0.1%) Scan Time Band Scan–time–dependent DAS Linearity variation (Total) Difference among channels ≤ 1000 ppm (0.1%) ≤ 2000 ppm (0.2%) >2000 ppm (0.2%) A/B ratio (Q channel 16 view smoothing) ≤± 5% ≤ ± 10% > ± 10% A/B ratio (Center channel 16 view smoothing) ≤ ± 20% ≤ ± 30% > ± 30% A/B ratio (Last channel 16 view smoothing) ≤ ± 20% ≤ ± 30% > ± 30% AB Ratio Q Channel (See Note below.) AB Ratio Center (See Note below.) AB Ratio Last (See Note below.) Note: The 1 ~ 250 View data are NOT used when calculating AB Ratio. 1–13 SYSTEM CT HISPEED SERIES ADVANCED DIAGNOSTICS PROPRIETARY TO GENERAL ELECTRIC COMPANY REV 13 1-1-4 2202119 Home (For V/R 5.5x or later ONLY) (Continued) IQ Performance Tool Analysis (How to calculate the status) D Offset Mean/Offset SD: Uses data of Offset SD/Mean scan (with Offset correction ON and with others OFF) . D Air Cal Drift: Uses data of air calibration 3mm~10mm. After completion of calculation for renewing air calibration data, the new Vector is compared with the reference Vector (that is a Calibration Vector acquired at last CT # Adjustment) using the following equation. New Vector / Reference Vector D mA Smudge: Uses data of Detector/DAS Linearity scan 60mA and 200mA to calculate linearity difference between #25 and #26 (Center) modules of the DAS/Detector and difference between #27 and #26 modules. How to Calculate: 1. The Mean Vector is calculated after performing the Offset and Reference Correction of each scan data. 2. Differences between modules are calculated using the following equations, then they are compared with specifications. Equation to calculate difference between #25 and #26 (Center) (#25•#26/#26): NJǒ ȍ 387 i+372 ǒ ȍ VecB Ǔ ȍ VecA ń ȍ VecB 387 VecA iń i i+372 ǒȍ 403 403 i _i+388 403 i i+388 ǓNj ȍ VecB Ǔ Vec A: 60mA mean vector, Vec B: 200mA mean vector 403 VecA iń i+388 i i+388 Equation to calculate difference between #27and #26 (Center) (#27•#26/#26): NJǒ ȍ 419 i+404 ǒ ȍ VecB Ǔ ȍ VecA ń ȍ VecB 419 VecA iń i i+404 ǒȍ 403 i _i+388 403 i+388 403 i+388 i ǓNj ȍ VecB Ǔ Vec A: 60mA mean vector, Vec B: 200mA mean vector 403 VecA iń i i+388 Difference between #26 and #27 Difference between #26 and #25 #25 #26 1–14 #27 SYSTEM PROPRIETARY TO GENERAL ELECTRIC COMPANY CT HISPEED SERIES ADVANCED DIAGNOSTICS REV 13 1-1-4 2202119 Home (For V/R 5.5x or later ONLY) (Continued) D Scan Time Smudge: Uses data of Detector/DAS Linearity scan 1sec and 3sec to calculate linearity difference between #25 and #26 (Center) modules of the DAS/Detector and difference between #27 and #26 modules. How to Calculate: Refer to mA Smudge other than Vec A and Vec B. (Vec A: 3 sec mean vector, Vec B: 1 sec mean vector) D mA Band: Uses data of Detector/DAS Linearity scan 60mA and 200mA to calculate linearity difference between adjacent modules for all channels. How to Calculate: 1. The Mean Vector is calculated after performing the Offset and Reference Correction of each scan data. 2. Difference between modules are calculated using the following equations, then they are compared with specifications. HPF (Vec A / Vec B) (Vec A: 60mA mean vector, Vec B: 200mA mean vector) D Scan Time Band: Uses data of Detector/DAS Linearity scan 1sec and 3sec to calculate linearity difference between adjacent modules for all channels. How to Calculate: Refer to mA Band other than Vec A and Vec B. (Vec A: 3 sec mean vector, Vec B: 1 sec mean vector) D AB Ratio Q Channel/Center/Last: Uses data of AB ratio scan. For Q cal channel, Center Channel, and Last Channel, (kA–B) / (kA+B) are calculated per view, then they are compared with specifications for16 view smoothing. The channels to be used: Q cal channel: 1~3 ch, Center Channel: 396~398 ch, Last Channel: 791~793 ch D Z–axis step movement: The motor pulse and Z–channel Vectors are only calculated and stored. 1–15 SYSTEM CT HISPEED SERIES ADVANCED DIAGNOSTICS PROPRIETARY TO GENERAL ELECTRIC COMPANY REV 13 1-1-5 2202119 Security Key To use the Class C service tools, remove the key cover, and connect the security key to the connector. See below. Some time (approximately 20 sec) is required for class C menus to become available, after any service tool operations. IMPORTANT NOTE: If the Class C menu are NOT displayed, click on ‘Verify Security’ in the Service Tool with the security key connected to the connector. Security Key Connector 1–16 SYSTEM PROPRIETARY TO GENERAL ELECTRIC COMPANY REV 13 1-1-6 CT HISPEED SERIES ADVANCED DIAGNOSTICS 2202119 Accessing the System Message Log To display the System Message Log Report, click the status message area on the desktop, then click on View Log. Click this message area. 1–17 SYSTEM PROPRIETARY TO GENERAL ELECTRIC COMPANY REV 13 1-2 CT HISPEED SERIES ADVANCED DIAGNOSTICS 2202119 AUDIO CONTROL Table 1–2 Audio Control Audio Adjustable Parameter X–ray On Sound Params Volume, Pitch, Length Alert Sound Params Volume, Pitch, Length Autovoice Volume Volume CD Sound Volume Gantry Volume, Operator Console Volume 1–18 SYSTEM CT HISPEED SERIES ADVANCED DIAGNOSTICS PROPRIETARY TO GENERAL ELECTRIC COMPANY REV 13 1-3 2202119 AUTOMATED ALIGNMENT ÍÍÍÍÍÍÍÍÍÍÍÍÍÍÍÍÍÍÍÍÍÍÍÍÍÍÍÍÍÍÍÍÍÍ ÍÍÍÍÍÍÍÍÍÍÍÍÍÍÍÍÍÍÍÍÍÍÍÍÍÍÍÍÍÍÍÍÍÍ ÍÍÍÍÍÍÍÍÍÍÍÍÍÍÍÍÍÍÍÍÍÍÍÍÍÍÍÍÍÍÍÍÍÍ Table 1–3 Automated Alignment Note The Menu filled in yellow stripe below are the Class C tool. Automated Alignment Menu (Sequence) Tube ISO Alignment Displayed Instruction Air Scan → Pin Scan [Adjust Tube position without Bowtie Filter] Tube Rough ISO Alignment Air Scan → Pin Scan [Adjust Tube position without Bowtie Filter] Radial Alignment Air Scan → Rad Pin Scan [Adjust Detector position without Bowtie Filter] Tube Alignment must be completed before Radial Alignment. Bowtie Filter Alignment Air Scan [without BTF] → Air Scan [with BTF] Adjust Bowtie Filter position. Twin Sys stem Phantom Centering – POR Alignment Filmless POR, Refer to Functional Check/Adjustment, System, X–ray alignment, POR for Twin System. BOW Alignment When POR is correctly adjusted, then filmless BOW (Beam–ON–Window) can be performed. Measure the three points of the channel bands and move the Detector to align the wave is just on the 0 line. In this adjustment, vertical axis is normalized in value so that center is 0 and Max, Min is 1 and –1. Refer to Functional Check/Adjustment, System, X–ray alignment, BOW for Twin System. ÈÈÈÈÈÈÈÈÈÈ ÈÈÈÈÈÈÈÈÈÈÈÈÈÈÈÈÈÈÈÈÈÈÈ ÈÈÈÈÈÈÈÈÈÈ ÈÈÈÈÈÈÈÈÈÈÈÈÈÈÈÈÈÈÈÈÈÈÈ ÈÈÈÈÈÈÈÈÈÈ ÈÈÈÈÈÈÈÈÈÈÈÈÈÈÈÈÈÈÈÈÈÈÈ ÈÈÈÈÈÈÈÈÈÈ ÈÈÈÈÈÈÈÈÈÈÈÈÈÈÈÈÈÈÈÈÈÈÈ ÈÈÈÈÈÈÈÈÈÈ ÈÈÈÈÈÈÈÈÈÈÈÈÈÈÈÈÈÈÈÈÈÈÈ ÈÈÈÈÈÈÈÈÈÈ ÈÈÈÈÈÈÈÈÈÈÈÈÈÈÈÈÈÈÈÈÈÈÈ ÈÈÈÈÈÈÈÈÈÈ ÈÈÈÈÈÈÈÈÈÈÈÈÈÈÈÈÈÈÈÈÈÈÈ ÈÈÈÈÈÈÈÈÈÈ ÈÈÈÈÈÈÈÈÈÈÈÈÈÈÈÈÈÈÈÈÈÈÈ ÈÈÈÈÈÈÈÈÈÈ ÈÈÈÈÈÈÈÈÈÈÈÈÈÈÈÈÈÈÈÈÈÈÈ ÈÈÈÈÈÈÈÈÈÈ ÈÈÈÈÈÈÈÈÈÈÈÈÈÈÈÈÈÈÈÈÈÈÈ ÈÈÈÈÈÈÈÈÈÈ ÈÈÈÈÈÈÈÈÈÈÈÈÈÈÈÈÈÈÈÈÈÈÈ ÈÈÈÈÈÈÈÈÈÈ ÈÈÈÈÈÈÈÈÈÈÈÈÈÈÈÈÈÈÈÈÈÈÈ ÈÈÈÈÈÈÈÈÈÈ ÈÈÈÈÈÈÈÈÈÈÈÈÈÈÈÈÈÈÈÈÈÈÈ ÈÈÈÈÈÈÈÈÈÈ ÈÈÈÈÈÈÈÈÈÈÈÈÈÈÈÈÈÈÈÈÈÈÈ Q–cal Channel Ratio Single Dettector System Fo or V/R 6.00 0 or later ONLY POR Refer to Functional Check/Adjustment, System, X–ray alignment, Q–cal Channel Ratio. Refer to the following instrucitons, Section 1-3-1. Air Scan (Small Focus) → Air Scan (Large Focus) For Small Focus: Tool Scan (Azimuth 0 deg) → Tool Scan (Azimuth 180 deg) For Large Focus: Tool Scan (Azimuth 0 deg) → Tool Scan (Azimuth 180 deg) Film POR Stationary Scan (Azimuth 0 deg.→ 180 deg) Refer to Functional Check/Adjustment, System, X–ray alignment, POR Except for Twin System. BOW Film BOW N/A Stationary Scan (Azimuth 0 deg.) Refer to Functional Check/Adjustment, System, X–ray alignment, BOW Except for Twin System. 1–19 SYSTEM CT HISPEED SERIES ADVANCED DIAGNOSTICS PROPRIETARY TO GENERAL ELECTRIC COMPANY REV 13 1-3 2202119 AUTOMATED ALIGNMENT (continued) Note The Tube Rough ISO Alignment and Radial alignment are rarely performed. Only when loosening the detector locking screw, they must be performed. 1-3-1 POR (For the Single Detector System ONLY) Special Tool D POR Tool (2168161) This program checks and adjusts the plane of rotation of the x–ray fan beam until it is perpendicular to the axis of Gantry rotation within the specification. 1. Set the POR Tool to the phantom holder. Verification of the POR Tool positioning (on the horizontal plane): a. Perform a scout scan on the POR Tool at Scout plane 0 degree. The scout image appear. b. Press on Grid On/Off button. c. Verify that the horizontal line and the edge of the POR Tool are parallel. See Illustration below. d. Verify that the POR Tool is placed at the center of the X axis. VERIFY THAT THESE LINES ARE PARALLEL POR–TOOL HORIZONTAL LINE CENTER OF THE X AXIS (X = 0 mm) 1–20 SYSTEM CT HISPEED SERIES ADVANCED DIAGNOSTICS PROPRIETARY TO GENERAL ELECTRIC COMPANY REV 13 1-3 2202119 AUTOMATED ALIGNMENT (continued) 1-3-1 POR (For the Single Detector System ONLY) (continued) Verification of the POR Tool positioning (on the vertical plane): e. Perform a scout scan on the POR Tool at Scout plane 90 degrees. f. Press on Grid On/Off button. g. Verify that the horizontal line and the POR Tool surface are parallel. See Illustration below. h. Verify that the POR Tool is placed at the center of the Y axis. HORIZONTAL LINE CENTER OF THE Y AXIS (Y = 0 mm) POR–TOOL SURFACE i. Verify that the POR Tool is not tilted along the Z axis (A–A’ in the illustration below). A’ If the POR–TOOL is tilted, the following scout image appears. A A A’ 1–21 SYSTEM CT HISPEED SERIES ADVANCED DIAGNOSTICS PROPRIETARY TO GENERAL ELECTRIC COMPANY REV 13 1-3 AUTOMATED ALIGNMENT (continued) 1-3-1 2. 2202119 POR (For the Single Detector System ONLY) (continued) Position the POR Tool at the scan center using localize function (Show Localizer). quired to be placed on the scan plane.) See the illustration below. (In this step a tool is re- X=0mm Y=0mm POR–TOOL 3. Position the POR Tool at the (scan center +170 mm) height. See the illustration below. Hold down the [Height] button to display the current height (ex. ‘–206’), and press the [Up] button to raise the Table by 170 mm (ex. Until the Display reads ‘–036’). If the Table can not be raised to the specified height due to the interlock function, switch ON (up) the S1–T3 Table dip switch on the TGP Board to disable the interlock function, and continue to raise the Table. In this case, be careful not to have the Table collide against anything. 170 mm Up CENTER OF SCAN PLANE 1–22 SYSTEM PROPRIETARY TO GENERAL ELECTRIC COMPANY CT HISPEED SERIES ADVANCED DIAGNOSTICS REV 13 1-3 2202119 AUTOMATED ALIGNMENT (continued) 1-3-1 POR (For the Single Detector System ONLY) (continued) 4. Press INLM button on the Gantry Display panel to reset the current tool position. 5. Remove the Bow–tie filter. 6. Move the cradle out from the Gantry to perform the air scan. 7. Select Service –> Service Adjustment –> Automated Alignment –> Tube POR Alignment –> OK. 8. Air Scan: Perform air scans, according to the instructions displayed. 9. Move the cradle IN to the 0 position set in step 4. 10. Azimuth 0 degree Scan: Perform tool scans, according to the instructions displayed. 11. Azimuth 180 degree Scan: Perform tool scans, according to the instructions displayed. 12. The tube travel appears on the screen. Move the tube according to the instructions displayed. For adjustment, refer to Functional Check / Adjustment, System, X–ray Alignment, Plane of Rotation. Repeat steps 8 to 11 until specification is within tolerance. ******************************* Displayed ******************************* Move the tube toward the Gantry by 23.81 mm. Press OK after adjusting the Tube Position. ************************************************************************ 1–23 SYSTEM CT HISPEED SERIES ADVANCED DIAGNOSTICS PROPRIETARY TO GENERAL ELECTRIC COMPANY REV 13 1-4 2202119 AUTO DAS LINEARITY TEST Note To perform this ’Auto DAS Linearity Test’, disconnect all of the flex cables (51 cables) connected between the detector and the DAS (disconnect them at the detector side). Refer to the Component Replacement manual. Table 1–4 Auto DAS Linearity Test Test Parameter to be Specified Detector Selection ([A Side] or [B Side]) Mode Selection ([High], [Medium], [Low]) Description For systems with twin detectors, select the ‘A Side’ or ‘B Side’ detector. For systems with a single detector, the ‘A Side’ only can be selected. ‘High’: Test of the CAM board linearity at amplification factors of X1 and X4, using a ‘High’ level test current. ‘Medium’: Test of the CAM board linearity at amplification factors of X4 and X16, using a ‘Medium’ level test current. ‘Low’: Test of the CAM board linearity at amplification factors of X16 and X64, using a ‘Low’ level test current. Usually, select all of ‘High’, ‘Medium’, and ‘Low’. Scan Type [Axial], [Stationary] Scan Time ‘Axial’: The gantry rotates while test data is collected. ‘Stationary’: The gantry does not rotate while test data is collected. Select a scan time, during which test data is collected. Test Execution After selecting the parameters in Table 1–4, click [Ok]. The linearity specification is 0.999 ∼ 1.001. Channels whose linearity data was found out of this specification are listed in the ‘Spec Out Ch#’ window. Click [Show Numerical] to numerically show linearity data of each channel in the ‘Numerical’ window. You can store the linearity data to a mean vector. 1–24 SYSTEM PROPRIETARY TO GENERAL ELECTRIC COMPANY CT HISPEED SERIES ADVANCED DIAGNOSTICS REV 13 1-5 2202119 AUTO POST RECON TEST This menu automatically tests the operation of post reconstruction for a number of times. First, select an ID of a raw data file on which post recon test is performed. And then, input the image ID which is correctly reconstructed from the selected raw data (called reference image). During the test, recon operation on the selected raw data is performed and then the resulted image is compared with the reference image to check if they are identical. This check is repeated for the number of times specified or until specified number of errors occur. IMPORTANT NOTE: For the V/R 5.xx System, do not select a helical image for this test. Only an axial image can be used for this test. Table 1–5 Auto Post Recon Test Test Parameter to be Specified Raw ID Image ID No. of Test Selectable Parameter Enter a raw data file ID directly, or select one from ‘Raw Browser.’ (Exam#, Series#, Acq#) Enter the image ID directly, or select one from ‘Image Browser.’ (Exam#, Series#, Image#) (arbitrary) (arbitrary) Until Errors Occur (The test will be terminated after the specified number of errors occur.) 1–25 SYSTEM PROPRIETARY TO GENERAL ELECTRIC COMPANY CT HISPEED SERIES ADVANCED DIAGNOSTICS REV 13 1-6 2202119 DAS DATA TRANSFER TEST Table 1–6 DAS Data Transfer Test Test Parameter to be Specified Test Mode: Bit by Bit Selectable Parameter Normal, Infinite Scan Mode Stationary Scan, Rotate Scan Scan Time 0.8 (or 0.7, if a 0.7 sec option is installed), 1.0, 1.5, 2.0, 3.0, 1.0 <–> 2.0 Alternate, Sequential (All) No. of Scan (arbitrary) No. of Test (arbitrary) (The total number of scans performed will be (No. of Scan) X (No. of Test).) (arbitrary) Until errors occur. (The test scans will be terminated after the specified number of errors occur.) Test Results [Result of Comparison] → [View Log]: Select either of the following to view test results previously performed: ‘Das Data Transfer Test Log1’ ‘Das Data Transfer Test Log2’ ‘Das Data Transfer Test Log3’ 1–26 SYSTEM PROPRIETARY TO GENERAL ELECTRIC COMPANY CT HISPEED SERIES ADVANCED DIAGNOSTICS REV 13 1-7 2202119 DASM DIAG This tool analyzes communication status between the HOST computer and DASM or between the HOST computer and camera. The following tests are performed continuously, then the results are displayed. D hinv: Displays hardware configuration information. D scsistat: Checks the SCSI bus, connectors, and SCSI ID. Make sure that DASM is powered and being run. D showdasm: This will query the DASM and provide you with configuration information for it. D rsp: Once this command is issued, ‘clrsp’, ‘rqs’, and ‘rsp’ programs are executed in this order. You can check if the DASM is properly connected to the laser camera. 1–27 SYSTEM CT HISPEED SERIES ADVANCED DIAGNOSTICS PROPRIETARY TO GENERAL ELECTRIC COMPANY REV 13 1-8 2202119 DETECTOR CHANNEL INFORMATION In this menu, the relation among the following is shown. D Detector channel No. D Ring radius D DAS transfer order D CAM No. D Cable No. D Module No. Table 1–7 Detector Channel Information Description Menu Detector Channel Number Select any of the following, and then, enter the channel No. in the box. ‘Active Channel’ (1 ∼ 793) ‘Ref1 Channel’ (1 ∼ 10) ‘Ref2 Channel’ (1 ∼ 10) ‘Q Channel’ (1 ∼ 3) MK1 MK2 VN VEM (1 ∼ 4) Radius DAS Transfer Order Enter the radius of a ring artifact. (0.00 mm ∼ 250.00mm) Enter the transfer order. (1 ∼ 868) 1–28 SYSTEM CT HISPEED SERIES ADVANCED DIAGNOSTICS PROPRIETARY TO GENERAL ELECTRIC COMPANY REV 13 1-9 2202119 GENERATOR TEST Click on Generator Test, the following message appears. Enter y to enter the Generator test. Table 1–8 Generator Test Command Retrieve Board Version Retrieve Software Version Clear Filament aging, Tube status Description JEDI software Version Version information of each board is sent to the operator console (OC) and displayed. All Software version information of the JEDI generator is sent to the OC and displayed. All Clears data of filament aging and statistics of the x–ray tube currently installed. All This command should be executed after the x–ray tube is replaced; do not execute this command for the currently used x–ray tube. Clear Error Log Clear generator tracking/trendiing database Error log retrieve (JEDI) Clears the error log data stored in the JEDI generator. All Clears the tracking/trending data stored in the JEDI genera- All tor. Retrieves the error log stored in the JEDI generator, and displays it. All The JEDI error log contains up to 60 error records and they are more detailed than the corresponding error information provided by the system. The date and time recorded in the log are generated in the generator (i.e., JEDI time). If the error log is not displayed due to some error, see the ‘JEDIerror.log’ or ‘JEDIerror.log.detail’ file in the /usr/g/service/log directory, as follows: 1. Select Unix Shell from the System Tools menu to open the winterm window. 2. Enter the following (underlined) in the window. cd /usr/g/service/log JEDIerror.log or JEDIerror.log.detail (detailed log) (continued) 1–29 SYSTEM CT HISPEED SERIES ADVANCED DIAGNOSTICS PROPRIETARY TO GENERAL ELECTRIC COMPANY REV 13 1-9 2202119 GENERATOR TEST (continued) Table 1–8 Generator Test (continued) Command Description JEDI software Version JEDI tracking/trending datum upload The tracking/trending data stored in the generator is sent to the OC. P5.xx or later Sends the JEDI firmware data to the generator. All Code Download (JEDI) This command is used when the generator firmware needed to be updated. At first, a data checksum is calculated and then the firmware data is sent to the generator, which takes approximately 12 hours. Error Definition file update Updates the error code definition information. This command should be executed after the Code Download (JEDI) command is executed, since error code Nos. are changed by the firmware update. TnT Definition file update Updates the TnT code definition information. This command should be executed after the Code Download (JEDI) command is executed, since TnT code Nos. are changed by the firmware update. P5.xx or later P5.xx or later Saved RAM data Upload The data stored in the generator is sent to the OC. All Saved RAM data Download Sends the saved generator data to the generator. All Tests the inverter operation with no main DC power input. All kV Diagnostic (Gates Drive Test) A delay time until the actual execution starts can be specified. Refer to Section 2–10 or 3–10–1 ‘Inverter Gate Command Diagnostics’, of X–ray Generator of this manual. kV Diagnostic (Primary power test) Tests the high voltage inverter operation with the inverter output shorted. All Refer to Section 2–11 or 3–10–2 ‘Inverter in Short Circuit Diagnostics’, of X–ray Generator of this manual. kV Diagnostic (no load kV) Tests the high voltage operation without making x–ray exposures. All Refer to Section 2–12 ‘No Load HV Diagnostics’ or Section 3–10–3 ‘No Load HV Diagnostic without Anode Rotation nor Filament Heating’, of X–ray Generator of this manual. (continued) 1–30 SYSTEM CT HISPEED SERIES ADVANCED DIAGNOSTICS PROPRIETARY TO GENERAL ELECTRIC COMPANY REV 13 1-9 2202119 GENERATOR TEST (continued) Table 1–8 Generator Test (continued) Command Heater Diagnostic Description Tests the filament heating operation. JEDI software Version All Refer to Section 2–8 ‘Heating Function Diagnostics’ or Section 3–8 ‘Heating without HV nor Rotation Diagnostic’, of X–ray Generator of this manual. Rotor Diagnostic Tests the x–ray tube rotor operation. All Refer to Section 2–9 ‘Rotation Function Diagnostics’ or Section 3–9 ‘Rotation without HV nor Filament Diagnostic’, of X–ray Generator of this manual. Set JEDI time Sets the generator date and time equal to the system ones. All To do this, do ‘get system time’, and then, ‘set JEDI time’. Checksum saved RAM Calculates a checksum of RAM. All This command should be executed after a software patch is performed using the Saved RAM data Download command. D Click [Apply] to send a selected command to the x–ray generator. 1–31 SYSTEM CT HISPEED SERIES ADVANCED DIAGNOSTICS PROPRIETARY TO GENERAL ELECTRIC COMPANY REV 13 2202119 1-10 GENERIC SYSTEM ANALYZER 1-10-1 View Log Files IMPORTANT NOTE: For the V/R 5.0x System, this function can NOT be used. (This is available for V/R 4.xx or lower or for V/R 5.5x or later.) IMPORTANT NOTE: For V/R 5.5x or later system , the Tube Usage Log menu is deleted. Use Tube Usage in Error Logs to display the tube usage log. Table 1–9 View Log Files View Log Files Menu Submenu Tube Usage Log Current Tube (Usage Log of the currently installed tube) After Installed (Usage Log of tubes previously used on the system) Tube Spits Log – Description This log includes the following data: 1. Total tube slice counts 2. Number of slices of cluster scans for each scan technique 3. Time of each helical/scout scan This log includes total spit counts along with time and date. A trend of spit occurrence frequency can be observed. Bad Raw Log – This file contains total counts of bad raw data files. Tube Usage Log D Use [ ↑ ] or [ ↓ ] keys to scroll the log lists. D [After Installed] → Previous Tube Usage Log files: Up to the following five log files ( for five tubes) can be displayed. ‘Sv Tube Usage.log.old1’ ‘Sv Tube Usage.log.old2’ ‘Sv Tube Usage.log.old3’ ‘Sv Tube Usage.log.old4’ ‘Sv Tube Usage.log.old5’ 1–32 SYSTEM PROPRIETARY TO GENERAL ELECTRIC COMPANY CT HISPEED SERIES ADVANCED DIAGNOSTICS REV 13 2202119 1-10 GENERIC SYSTEM ANALYZER (continued) 1-10-1 View Log Files (continued) Tube Spits Log Tube spits log is graphically displayed as below. The data indicates accumulated values. KV values used while spits occurred are indicated on the graph. Spits Log Data 10 9 8 7 6 5 4 3 2 1 0 No. of Slices 50000 Bad Raw Log Bad raw data file log is graphically displayed as below. 1 Bad Raw Log Data 0 –1.0 No. of Slices 50000 1–33 SYSTEM PROPRIETARY TO GENERAL ELECTRIC COMPANY CT HISPEED SERIES ADVANCED DIAGNOSTICS REV 13 2202119 1-10 GENERIC SYSTEM ANALYZER (continued) 1-10-2 Format Raw Data Table 1–10 Format Raw Data Format Raw Data Menu Submenu Fan Data Store to File, Numerical Display Stores or numerically displays raw data or vector data. The original raw data is converted into floating point number format with or without data correction or conversion applied. DAS Data Numerical Display Displays numerically raw data without any data correction or conversion applied; i.e., displays DAS data itself in hexadecimal format. A Side B Side Description For Twin System ONLY: GSA has a function to manipulate two raw data (A and B). So we can make mean file or raw file from each detector channel independently. It means, in every scan mode, the two raw data (A and B) are corrected and used for reconstruction. Raw Data File Selection 1. Select ‘Generic System Analyzer’ from ‘Diagnostics & analysis.’ 2. Select a raw data ID from the lists: a. Select first an Exam #. b. Select a Series #. c. Select an Acq #. If the selected series # above is for a helical scan, further select an Acq #. 1–34 SYSTEM CT HISPEED SERIES ADVANCED DIAGNOSTICS PROPRIETARY TO GENERAL ELECTRIC COMPANY REV 13 2202119 1-10 GENERIC SYSTEM ANALYZER (continued) 1-10-2 Format Raw Data (continued) Fan Data D Fan Data Format – Correction & Conversion: Select whether the following corrections or conversion are to be applied or not. – Offset File Correction: If ‘Yes’, the raw data is corrected by offset views (offset views are the first 64 views which are collected prior to x–ray exposure to gather offset data). – Reference Correction: If ‘Yes’, the raw data is corrected by reference channel data (reference channels receive direct x–rays, i.e., which have not passed through an object to be scanned). – Natural Log Conversion: If ‘Yes’, natural log operation is applied to the raw data. Then, the following data ‘Fan Data Averages’ are displayed: – Active Views Max of Max Min of Min Avg of Mean Avg of SD Offset Views Max of Max Min of Min Avg of Mean Avg of SD = = = = x.xxxxxx x.xxxxxx x.xxxxxx x.xxxxxx channel x view x channel x view x = = = = x.xxxxxx x.xxxxxx x.xxxxxx x.xxxxxx channel x view x channel x view x 1–35 SYSTEM PROPRIETARY TO GENERAL ELECTRIC COMPANY REV 13 CT HISPEED SERIES ADVANCED DIAGNOSTICS 2202119 1-10 GENERIC SYSTEM ANALYZER (continued) 1-10-2 Format Raw Data (continued) D Fan Data Format – File Data Type: Select either of the following data types (written in bold) to store it to a raw data file or a vector file, or to display (numerically) it. ‘Original’ is stored to a raw data file, and the others (‘Active Min’, ‘Active Max’, ...) are stored to a vector file. ‘Vector file’ means here a one–dimensional type file, on the other hand, a raw data file is a two–dimensional file; i.e., each channel has data for each view. – Original (Specify 1, 2, ... , or 6, as an ID No. A raw data file stored with this ID No. can be graphically viewed in ‘View Raw Data’ (Generic System Analyzer → Analysis → View Raw Data).) (For all the ones below, specify a number as a vector file No. A vector file stored with this number can be graphically viewed in ‘View Vector’ (Generic System Analyzer → Analysis → View Vector).) – Active Min (This vector consists of minimum values of each channel during active views.) – Active Max (This vector consists of maximum values of each channel during active views.) – Active Mean (This vector consists of mean values of each channel during active views.) – Active SD (This vector consists of standard deviation values of each channel during active views.) – Offset Min (This vector consists of minimum values of each channel during offset views.) – Offset Max (This vector consists of maximum values of each channel during offset views.) – Offset Mean (This vector consists of mean values of each channel during offset views.) – Offset SD (This vector consists of standard deviation values of each channel during offset views.) DAS Data D Select ‘Channel’ or ‘View.’ – ‘Channel’ is selected: Specify a channel No. Data for every view, of the specified channel, is numerically displayed in hexadecimal format. – ‘View’ is selected: Specify a view No. Data for every channel, of the specified view, is numerically displayed in hexadecimal format. 1–36 SYSTEM CT HISPEED SERIES ADVANCED DIAGNOSTICS PROPRIETARY TO GENERAL ELECTRIC COMPANY REV 13 2202119 1-10 GENERIC SYSTEM ANALYZER (continued) 1-10-3 Analysis Table 1–11 Analysis Analysis Menu Provided Functions View Raw Data Magnify, Minify, Gray Scale, Cursor, Numerical, Plot, Erase, ROI Graphics Displays data of a raw data file as shades. View Vector Magnify, Numerical, Plot, Erase Displays data of vector files as graphs. Calculations Vect/Vect. Op A+B, A–B, AXB, A/B, ln(A), HPF(A), LPF(A), Diff. Filter(A) Raw/Vect. Op A+B, A–B, AXB, A/B Raw/Raw Op A+B, A–B, AXB, A/B, ln(A), HPF(A), LPF(A), Diff. Filter(A) Description View Raw Data Before you use this menu, you have to store a raw data file in the ‘Fan Data’ menu (Diagnostics & analysis → Generic System Analyzer → Format Raw Data → Fan Data). 1. Select a raw data file from SvSupRaw1, SvSupRaw2, ... , SvSupRaw6. A raw data file is a two–dimensional type: each channel has data for each view. In this menu, data is shown as shades, i.e., gray scaling. Since the length of the vertical axis (view) is not enough for showing all the views, use the scroll bar to display the not–displayed upper or lower part of views. Channel 1 1000 1 View By scrolling, up to the 1037th view can be displayed. The actual number of channels or views varies according to a product model. 576 Scroll Bar 1–37 SYSTEM CT HISPEED SERIES ADVANCED DIAGNOSTICS PROPRIETARY TO GENERAL ELECTRIC COMPANY REV 13 2202119 1-10 GENERIC SYSTEM ANALYZER (continued) 1-10-3 2. Analysis(continued) You can use the following functions for the displayed raw data (shades). D [Magnify]: Scales up both horizontal (channel) and vertical (view) axes by a factor of any of 1, 2, ... , 9. D [Minify]: Select ‘Remove Odd View’ or ‘Remove Even View.’ D [Gray Scale]: Select ‘Auto range’ or ‘Manual range.’ D [Cursor]: Shows and sets a (+) cursor to the designated location (channel, view). The cursor can be dragged and set (by a second click). D [Numerical]: Use this after setting a cursor position. Displays values on the positions surrounding the cursor (eight positions). Cursor D [Plot]: Before selecting this function, show and set a cursor to a location of interest (channel, view) by [Cursor]. – Horizontal Profile: Data for each channel is graphically displayed for the specified view; i.e., shades on a horizontal line (on the specified view) are displayed by a graph. – Vertical Profile: Data of each view is graphically displayed for the specified channel; i.e., shades on a vertical line (on the specified channel) are displayed by a graph. ‘Auto Scale’ or ‘Manual Scale’ can be selected for the graph plotting. (For ‘Manual Scale’, enter ‘Minimum’ and ‘Maximum’ values.) D [Erase]: Erases graphs and/or the cursor. 1–38 SYSTEM CT HISPEED SERIES ADVANCED DIAGNOSTICS PROPRIETARY TO GENERAL ELECTRIC COMPANY REV 13 2202119 1-10 GENERIC SYSTEM ANALYZER (continued) 1-10-3 Analysis(continued) D [ROI Graphics]: ROI Graphics Menu: ‘Distance’, ‘Erase’, ‘Ellipse’, ‘Erase All’, ‘Rectangle’ The graphics Distance, Ellipse, and Rectangle can be dragged, sized, and numbered. Distance Ellipse Rectangle – Distance: Shows a length (distance) by a number of channels and a number of views. Number of Views Number of Channels – Ellipse or Rectangle: Shows the following values of the region inside the graphic. Mean, Standard Deviation (S. D.), 1–39 SYSTEM PROPRIETARY TO GENERAL ELECTRIC COMPANY CT HISPEED SERIES ADVANCED DIAGNOSTICS REV 13 2202119 1-10 GENERIC SYSTEM ANALYZER (continued) 1-10-3 Analysis(continued) View Vector Before you use this menu, you have to store a vector file in the ‘Fan Data’ menu (Diagnostics & analysis → Generic System Analyzer → Format Raw Data → Fan Data). 1. Select a vector file. 2. Click on [Plot] and select ‘Auto Scale’ or ‘Manual Scale’ to display a graph. Data of channels are displayed as a graph. ‘Vector File’ means a one–dimensional type file; a typical example is a mean file. Data Channel 3. You can use the following functions for the displayed graph. D [A], ["]: When the ‘Magnify’ function (refer to below) is used, the length of the horizontal axis is not enough for showing all the channels. Shift the graph in the right or left direction with these buttons to display the not–displayed right or left part of the graph. D [Magnify]: Scales up both horizontal (channel) and vertical (data) axes. D [Numerical]: Data for each channel is numerically displayed in the right bottom corner area of the monitor screen. D [Plot]: Select ‘Auto Scale’ or ‘Manual Scale.’ D [Erase]: Erases the graph currently displayed. 1–40 SYSTEM PROPRIETARY TO GENERAL ELECTRIC COMPANY CT HISPEED SERIES ADVANCED DIAGNOSTICS REV 13 2202119 1-10 GENERIC SYSTEM ANALYZER (continued) 1-10-3 Analysis(continued) Calculations 1. Select any of the following as a combination of data types which arithmetic operations are to be applied to. ‘Vect/Vect. Op’ ‘Raw/Vect. Op’ ‘Raw/Raw Op’ (Vect: Vector file, Raw: Raw data file) 2. Select a kind of operation (addition, subtraction, division, ...). 3. ‘Enter Output Vector (or Raw File) Number’ (Enter a number; a file with this identification No. will contain the calculation result.) 1–41 SYSTEM PROPRIETARY TO GENERAL ELECTRIC COMPANY CT HISPEED SERIES ADVANCED DIAGNOSTICS REV 13 2202119 1-11 GETSTATS 1-11-1 General Click on getStats. The following screen appears to know the Gantry revolution and tube spits. Show Tube Spits Count Shows total spits count and last updated date. Show Tube Spits Log File Shows total spits count, slice count, and spits count. Show Gantry Revolution Count Shows total Gantry revolution count, last updated date, and Gantry revolution count within a specific period. Reset Total Gantry Revolution Count Using this function, you can set the total Gantry revolution count to the number you desire. A comment can also be entered. Reset Gantry Revolution Count Using this function, you can set the Gantry revolution count to 0 (Zero). Show Total Gantry Revolution Count Log File Shows the number of Total Gantry revolution per day. (The data of 50 days are displayed.) Show Total Gantry Revolution Counter Reset History Shows the reset history of the total Gantry revolution count. 1–42 SYSTEM CT HISPEED SERIES ADVANCED DIAGNOSTICS PROPRIETARY TO GENERAL ELECTRIC COMPANY REV 13 2202119 1-11 getStats (Continued) 1-11-2 Command You can execute the same getStats function using command line. First run a shell, then enter: No. Item Command – getStats main menu getStats 2 Show Tube Spits Count getStats TUBE_SPITS tubeSpits tubeSpits –s 3 Show Tube Spits Log file getStats TUBE_SPITS_LOG tubeSpits –l 4 Show Gantry Revolution Count getStats GANTRY_REV revCounter –s 5 Reset Total Gantry Revolution Count revCounter TOTALRESET 6 Reset Gantry Revolution Count revCounter RESET 7 Show Total Gantry Revolution Count Log file (for 50 days) getStats GANTRY_REV 50 Show any Gantry Revolution Count Log file getStats GANTRY_REV [any number] – revCounter –l 50 revCounter –l [any number] – Show all Gantry Revolution Count Log file getStats GANTRY_REV_ALL revCounter –a 8 Show Total Gantry Revolution Counter Reset History getStats GANTRY_REV_HISTORY revCounter –h 1–43 SYSTEM CT HISPEED SERIES ADVANCED DIAGNOSTICS PROPRIETARY TO GENERAL ELECTRIC COMPANY REV 13 2202119 1-12 HEAT SOAK Prior to starting Heat Soak D The x–ray tube should be sufficiently cool. D If the ‘Cooling time too long’ error message is displayed, you will have to wait at least for 31 minutes to be able to start Heat Soak. Table 1–12 Heat Soak Scan Protocol #Scans (V4 Cooling) (V5 Cooling) Scan Group# 1 10 10 Scan Group# 2 10 20 Scan Group# 3 30 10 Scan Group# 4 30 20 Scan Group# 5 20 3 Scan Group# 6 15 – Scan Group# 7 5 – D Click [Report] to check the results, after performing heat soak scans. 1–44 SYSTEM PROPRIETARY TO GENERAL ELECTRIC COMPANY CT HISPEED SERIES ADVANCED DIAGNOSTICS REV 13 2202119 1-13 H/W DIAGNOSTICS CAUTION Unexpected x–ray exposure! After finishing tests in Diagnostics of H/W Diagnostics, power Off the system before rebooting the system. This is to avoid unexpected accidental x–ray exposure, because not all the hardware devices are initialized only by rebooting the system. Click on H/W Diagnostics, the following message appears. Click on YES to enter the H/W Diagnostics. 1–45 SYSTEM CT HISPEED SERIES ADVANCED DIAGNOSTICS PROPRIETARY TO GENERAL ELECTRIC COMPANY REV 13 2202119 1-13 H/W DIAGNOSTICS (continued) Table 1–13 H/W Diagnostics Menu Diagnostics H/W Diagnostics Submenu Interactive Test (Refer to below for how to reach this menu.) Description Provided Tests: Monitor Test, Keyboard Test, Audio Test, Misc Test (Hardware Inventory, SCSI Test, View SYSLOG, NPR LED, Safety Loop, Shutdown Test), Work Station Default Test (Refer to ‘Interactive Test – XXXXXX’ in Section 1-13-1 (Diagnostics) in this section.) Offline Test Provided Tests: NPR PCI TEST, DBPCI#0 PCI TEST, NPR INTERNAL TEST (Refer to ‘Offline Test’ in Section 1-13-1 (Diagnostics) in this section.) View Log* Function Test N/A currently. View Diag Log Displays the log of diagnostics results. View SYSLOG Displays the system log (from the latest system start–up to the present). View P–ON Test Log Displays P–ON Test results. H/W inventory Displays a list of main operator console hardware devices. Open File – *: Many of the ‘View Log’ submenus are included in ‘Diagnostics’; however, this ‘View Log’ can be used without terminating the application unlike ‘Diagnostics.’ 1–46 SYSTEM PROPRIETARY TO GENERAL ELECTRIC COMPANY CT HISPEED SERIES ADVANCED DIAGNOSTICS REV 13 2202119 1-13 H/W DIAGNOSTICS (continued) 1-13-1 Diagnostics 1. Click [Diagnostics] in the H/W Diagnostics menu, and then the following message is displayed: ******************************* Displayed ******************************* Attention This requires the application to be shutdown. Continue ? ************************************************************************ 2. Click [YES], and then some messages and windows are shown, and then the following message is displayed: ******************************* Displayed ******************************* Okay to power off the system now. Press any key to restart. ************************************************************************ 3. Switch OFF the power switch on the operator console (OC). 4. Wait for several minutes, and then, switch ON the power switch on the OC. 5. During the power–up sequence, the following screen will appear: Power on test DBPCI test DBPCI test : OK Errors : H/W diag Startup Shutdown 6. Promptly click [H/W diag]. 1–47 SYSTEM CT HISPEED SERIES ADVANCED DIAGNOSTICS PROPRIETARY TO GENERAL ELECTRIC COMPANY REV 13 2202119 1-13 H/W DIAGNOSTICS (continued) 1-13-1 Diagnostics (continued) 1-13-1-1 Interactive Test Misc Test – Hardware Inventory (hinv) Displays a list of operator console hardware devices which are identified by the operating system software. Refer to Table 1–14 which lists some of the displayed devices and their names. Table 1–14 Hardware Inventory (for System Software versions earlier than V4.00) Device Name Displayed Device Disk drive: unit 1** on SCSI controller 3 Raw data disk Disk drive: unit 2 on SCSI controller 3 Raw data disk* Optical disk: unit 6 on SCSI controller 1 MOD drive) Optical disk: unit 5 on SCSI controller 1 MOD drive* Common device: unit 4 on SCSI controller 1 Serial port expander (ST1800) Disk drive: unit 3 on SCSI controller 1 DASM* CDROM: unit 1 on SCSI controller 1 CD–ROM drive Disk drive: unit 2 on SCSI controller 0 System disk* Disk drive: unit 1 on SCSI controller 0 System disk PCI SCSI controller 3: Version ADAPTEC 7880 UW SCSI card (AHA–2940UW) Unknown Type PCI: Bus 2, Slot 6, Function 0, Vendor ID 0x10b5, Device ID 0x9060 DBPCI board Unknown Type PCI: Bus 2, Slot 5, Function 0, Vendor ID 0x10b5, Device ID 0x9061 NPR (NP Recon Engine) Assy Bit3 PCI Bridge Card: Bus 2, Slot 4 PCI extender card (on the backplane board) Bit3 PCI Bridge Card: Bus 1, Slot 4 PCI backplane controller card Bit3 PCI Bridge Card: Bus 0, Slot 4 PCI host card (within the host processor (O2)) Integral SCSI controller 1: Version ADAPTEC 7880 SCSI controller 1 included in the host processor (O2) Integral SCSI controller 0: Version ADAPTEC 7880 SCSI controller 0 included in the host processor (O2) *: Indicates that this is an optional device; otherwise (without *), this is a standard device. **: The number ‘unit 1’ indicates a SCSI device ID number; the set ID number should equal this unit number. (This description applies to other unit numbers.) 1–48 SYSTEM CT HISPEED SERIES ADVANCED DIAGNOSTICS PROPRIETARY TO GENERAL ELECTRIC COMPANY REV 13 2202119 1-13 H/W DIAGNOSTICS (continued) 1-13-1 Diagnostics (continued) Table 1–15 Hardware Inventory (for System Software V4.00 or later) Displayed Device Device Name Disk drive: unit 1** on SCSI controller 3 Raw data disk Disk drive: unit 2 on SCSI controller 3 Raw data disk* Optical disk: unit 6 on SCSI controller 1 MOD drive Optical disk: unit 5 on SCSI controller 1 MOD drive* Common device: unit 4 on SCSI controller 1 ST1800 (alternative to Serial Exp) Disk drive: unit 3 on SCSI controller 1 DASM* CDROM: unit 1 on SCSI controller 1 CD–ROM drive Disk drive: unit 2 on SCSI controller 0 System disk* Disk drive: unit 1 on SCSI controller 0 System disk PCI SCSI controller 3: Version ADAPTEC 7880 UW SCSI card (AHA–2940UW) Integral SCSI controller 1: Version ADAPTEC 7880 SCSI controller 1 included in the host processor (O2) Integral SCSI controller 0: Version ADAPTEC 7880 SCSI controller 0 included in the host processor (O2) Serial Exp: PCI Adapter ID (vendor 4277, device 36973) pci slot 5 (alternative to ST1800) *: Indicates that this is an optional device; otherwise (without *), this is a standard device. **: The number ‘unit 1’ indicates a SCSI device ID number; the set ID number should equal this unit number. (This description applies to other unit numbers.) 1–49 SYSTEM PROPRIETARY TO GENERAL ELECTRIC COMPANY CT HISPEED SERIES ADVANCED DIAGNOSTICS REV 13 2202119 1-13 H/W DIAGNOSTICS (continued) 1-13-1 Diagnostics (continued) Misc Test – SCSI Test Displays detailed information about the SCSI devices which are identified by the host processor. Verify that detailed information is displayed for each of the SCSi devices which are identified in the ‘Hardware Inventory’ (Diagnostics – Interactive Test – Misc Test – Hardware Inventory). Misc Test – View SYSLOG Opens a log viewer and displays SYSLOG. SYSLOG is a log file managed by the OS (operating system) and includes information on the host processor (O2) and also a part of status/error messages generated by device drivers (software) for the NPR (NP Recon Engine) and the DBPCI board. The SYSLOG only contains logs generated since the last start–up which occurred after the last 12 o’clock midnight. When it passes 12 o’clock midnight, the logs contained up to then are stored and the SYSLOG is initialized. The following log will be displayed (an example). ******************************* Displayed ******************************* Mar 9 15:19:46 6F:aoyagi syslogd: restart Mar 9 15:19:46 2A:aoyagi unix: IRIX Release 6.3 IP32 Version 12161207 System V Mar 9 15:19:46 2A:aoyagi unix: Copyright 1987–1996 Silicon Graphics, Inc. .................. Mar 9 15:19:46 5A:aoyagi unix: NOTICE: pcinre attach: Config.address is 0x80022800 Mar 9 15:19:46 5A:aoyagi unix: NOTICE: pcinre_attach: Configuration fields: Mar 9 15:19:46 5A:aoyagi unix: NOTICE: Vendor Id = 0x10b5, Device Id = 0x9061, Base_Reg = 0x81000000 .................. Mar 9 15:19:46 5A:aoyagi unix: NOTICE: pcindb attach: Config.address is 0x80032000 Mar 9 15:19:46 5A:aoyagi unix: NOTICE: pcindb_attach: Configuration fields: Mar 9 15:19:46 5A:aoyagi unix: NOTICE: Vendor Id = 0x10b5, Device Id = 0x9060, Base_Reg = 0x81400000 ************************************************************************ Verify that the underlined information is displayed; other than underlined may be different. If underlined information is displayed, it indicates that the DBPCI board and the NPR (NP Recon Engine) are initialized by the host processor. 1–50 SYSTEM CT HISPEED SERIES ADVANCED DIAGNOSTICS PROPRIETARY TO GENERAL ELECTRIC COMPANY REV 13 2202119 1-13 H/W DIAGNOSTICS (continued) 1-13-1 Diagnostics (continued) Misc Test – NPR LED Turns on LEDs on the NPRM (NP Recon Engine Master) board according to the dip switch (S1) setting on the board. Refer to the illustration below (if switch 2 is set to ON, for example, LED6 should light). 1 2 3 4 5 6 7 8 LED7 LED6 LED5 LED4 LED3 LED2 LED1 LED0 O N S1 is set according to the memory capacity and the number of NPRS (NP Recon Engine Slave) boards installed on the NPRM board. The LEDs turn On during approximately 30 seconds. Misc Test – Safety Loop This test turns On/Off the safety loop relay on the REAR CN1 board. CAUTION Unexpected hazards! Take appropriate precautions (steering clear of the gantry, etc.) against gantry/table movement or x–ray exposure before turning On the safety loop relay. And do not forget to turn Off the relay before exiting the test. Misc Test – Shutdown Test Tests the OC power off timer function of the FRONT PNL board. 1–51 SYSTEM PROPRIETARY TO GENERAL ELECTRIC COMPANY CT HISPEED SERIES ADVANCED DIAGNOSTICS REV 13 2202119 1-13 H/W DIAGNOSTICS (continued) 1-13-1 Diagnostics (continued) 1-13-1-2 Offline Test To select a test, refer to below: D Click [NPR] and [PCI TEST] to select ‘NPR PCI TEST’. D Click [DBPCI#0] and [PCI TEST] to select ‘DBPCI#0 PCI TEST’. D Click [NPR] and [INTERNAL TEST] to select ‘NPR INTERNAL TEST’. In ‘NPR INTERNAL TEST’, ‘Master DSP’ or ‘Slave DSP’ can be selected. Click [DETAIL] to check/set test parameters. Other selectable parameters: Parameter WHEN ERROR OCCUR TEST MODE Selection STOP, CONTINUE NORMAL, QUICK, MANUAL For more detailed information about Offline Test, refer to Section 2-3, Off–line Test, of the Operator Console tab. 1–52 SYSTEM PROPRIETARY TO GENERAL ELECTRIC COMPANY REV 13 CT HISPEED SERIES ADVANCED DIAGNOSTICS 2202119 1-14 IMAGE PROFILE The graphical profile data on selected line of the image can be displayed. Horizontal, vertical, and free direction of a line can be selected. Selections in Image Profile 1. Click on Browse in Functions selection. Application sort screen appears. 2. Upon application sort window, you can highlight an EXAM –> Exam. No. –> Series No., and click on Accept . The desired image appears in the screen. 3. Select the desired image profile type by pressing any of the following buttons: D Horizontal: The graphical profile data on the selected horizontal line is displayed. D Vertical: The graphical profile data on the selected vertical line is displayed. D Free: By selecting two given points, the graphical profile data is displayed. D FWHM: Full Width Half Maximum D Auto: sets area automatically for profile graphic representation. D Use FOV: D Smooth: Not available yet. 4. Drag a cursor on the displayed image. The graphical profile data is displayed. 5. To delete the lines, click on Erase. To exit from this program, click on Quit. 1–53 SYSTEM PROPRIETARY TO GENERAL ELECTRIC COMPANY REV 13 CT HISPEED SERIES ADVANCED DIAGNOSTICS 2202119 1-15 MTF SURVEY Image spatial resolution can be measured by scanning a wire existing within a GE Performance Phantom or equivaĆ lent, and analyzing the acquired image with this menu. The menu calculates MTF data by the two-dimensional Fourier Transform of the point spread function using pixel data around the wire, and displays the MTF curve. EvaluĆ ate the system spatial resolution performance by reading the curve. Special Tool D GE Performance Phantom (2102580) or equivalent Scanning the GE Performance Phantom 1. Set the GE Performance Phantom approximately at the scan center. 1–54 SYSTEM CT HISPEED SERIES ADVANCED DIAGNOSTICS PROPRIETARY TO GENERAL ELECTRIC COMPANY REV 13 2202119 1-15 MTF SURVEY (continued) 2. Adjust the position of the phantom so that the wire point within the phantom is positioned at the scan center: a. Perform axial scans with the following parameters (others: default): Recon FOV Scan Time (Sec) kV mA Thickness Focal Size 10 (Head) 2.0 120 150 10 L 10 (Body) 1.5 120 130 10 L b. Measure the distance between the wire point and the scan center. c. Shift the phantom so that the wire point is positioned at the scan center, according to the distances meaĆ sured at the above step. Use the up-down adjuster and right-left adjuster of the phantom holder (one turn: 1 mm movement). Y Wire Point X Scan Center d. Repeat steps a through c, until the wire point is positioned at the scan center within ±0.5 mm. If the image shows a white band over the wire point, as shown below, this indicates that the wire point is not yet positioned correctly at the scan center. White band 3. Record the image No. 1–55 SYSTEM CT HISPEED SERIES ADVANCED DIAGNOSTICS PROPRIETARY TO GENERAL ELECTRIC COMPANY REV 13 2202119 1-15 MTF SURVEY (continued) Mode – ‘Automatic’, ‘Manual’ 4. ‘Manual’: If you select ‘Manual’, proceed to step 5. ‘Automatic’: If you select ‘Automatic’, perform the following: a. Perform step 5. b. Proceed to step 9. If it does not seem to work well, try the ‘Manual’ mode. Image ID 5. Enter the image No. (Patient ID#.Exam#.Series#.Image#); or, select the image, using the [Browse] function. ‘Pin Center X’, ‘Pin Center Y’ 6. Enter X and Y values as follows. X and Y are the locations of the pin center existing within the phantom. a. Click [Locate]. The pencil cursor appears on the image field. b. Use the mouse to position the tip of the cursor on the center of the pin. See below: Pin c. Click the right button, and then, the location values are entered into the boxes. 1–56 SYSTEM PROPRIETARY TO GENERAL ELECTRIC COMPANY CT HISPEED SERIES ADVANCED DIAGNOSTICS REV 13 2202119 1-15 MTF SURVEY (continued) ‘Inner ROI’, ‘Outer ROI’ 7. Measure the ROI values, of an area within the pin and of an area encompassing the pin: a. Click [Measure] for ‘Inner ROI’. A circle cursor appears on the image field. b. Use the mouse to position the cursor within the pin and enter the value, as follows: i. Position the cursor, by moving the mouse while pressing the center button. ii. Adjust the cursor size, by moving the mouse while pressing the left button. iii. Enter the value into the box, by clicking the right button. c. Click [Measure] for ‘Outer ROI’. d. Perform step b. In this step, encompass the pin with the cursor. Advanced Settings – ‘Adjust’, ‘Use Default’ 8. Usually select ‘Use Default’. 1–57 SYSTEM CT HISPEED SERIES ADVANCED DIAGNOSTICS PROPRIETARY TO GENERAL ELECTRIC COMPANY REV 13 2202119 1-15 MTF SURVEY (continued) [Compute], [View Plot] 9. Click [Compute]. The MTF values are calculated. 10. Click [View Plot]. 11. Read the lp/cm values (on the horizontal axis) of the curve at 0.5, 0.1, and 0.05 (on the vertical axis), using the mouse. And enter the values in the ‘MTF lp/cm@50%’, ‘MTF lp/cm@10%’, ‘MTF lp/cm@5%’ boxes, respectively. Refer to below: 1 EXAMPLE 0.8 0.5 0.6 0.4 0.1 0.05 0.2 0 0 2 4 6 8 lp/cm@50% 10 lp/cm@5% lp/cm@10% [Submit] 12. Click [Submit] to record the data. (File name: /usr/g/service/log/mtf.report) 1–58 SYSTEM PROPRIETARY TO GENERAL ELECTRIC COMPANY CT HISPEED SERIES ADVANCED DIAGNOSTICS REV 13 2202119 1-16 OFFLINE SCAN Table 1–16 Offline Scan Parameter Group Parameter Selection Technic Scan Type Axial, Helical, Cine, Scout, Stationary, T/G Control (Refer to Section 1-16-1.) (others) Thickness [mm] – For the system with Asymmetric Option Installed only, this parameter is displayed. “10: 1” provides 10 mm and 1 mm slices. “10: 2” provides 10 mm and 2 mm slices. “6: 1” provides 6 mm and 1 mm slices. Scan Environment X Ray ON, OFF Rotor ON, OFF Data Collection ON, OFF DAS Mode Gantry Tilt [deg] Tech. for Scan Type (other scan parameters) NORMAL, PATTERN, DAS64L, DAS16L, DAS16M, DAS4M, DAS4H, DAS1H (arbitrary) – 1-16-1 T/G Control T/G Control The following mechanical controls of the gantry and table can be performed with this menu. After setting these parameters, click on Back to return to perform the 1st screen of Offline scan. D Table Pos. [mm]: The cradle is moved (horizontally) to a specified position. The cradle button on the keyboard lights during cradle movement. D Gantry Tilt [deg]: The gantry is tilted to a specified position. You have to press the tilt button on the keyboard after it lights and continue to press it until the gantry stops tilting. If a remote tilt option is not installed on the system, you have to press the tilt button on the gantry to execute the operation. D Azimuth [deg]: The gantry is rotated to a specified position. Collimator Control (For Twin System ONLY) After setting these parameters, click on Back to return to perform the 1st screen of Offline scan. D Auto Collimator: When set to ON, collimator tracking control during offline scan becomes available. D Position Change: When set to ON, the collimator can be moved to the desired position using the following parameters (Move mode and Pulse) . 1–59 SYSTEM CT HISPEED SERIES ADVANCED DIAGNOSTICS PROPRIETARY TO GENERAL ELECTRIC COMPANY REV 13 2202119 1-16 Offline Scan (Continued) D Move mode: When ‘Position Change’ is set to ON, this parameter can be available. – Abs.: (Absolute position change) moves the collimator from the reference position (zero position) held by the DAS to the desired position specified by ‘Pulse’ parameter. – Rel.: (Relative position change) moves the collimator from the current position held by the DAS to the desired position specified by ‘Pulse’ parameter. D Pulse: specifies the collimator travel from –8,192 to 8,191 pulses. (1 pulse = 2 micrometers) D Reset: When set to ON, the collimator position is reset. D CIF Mode: (For V/R 5.5 or later ONLY) The following operation can be performed according to the Function mode selected. X–ray ON selection must be required. IMPORTANT NOTE: When selecting Zigzag or Vibration mode, do not select Helical or Cine scan as a Scan Type. This is why one data only is acquired. CIF Mode Function Value Operation Normal 00 Normal Operation ZIGZAG 01 The collimator moves zigzag. This mode can be used in combination with a tracking mode. STEP A 02 The collimator moves in 20 pulse steps. STEP B 03 The collimator moves in 5 pulse steps. STEP C 04 The collimator moves + 10 pulse every one scan. STEP D 05 The collimator moves + 1 pulse every one scan. VIBRATION 10 The collimator vibrates, using for belt tension adjustment. After completion of this test, the Gantry must be reset. TEST A 11 The collimator moves 20 pulses of a reciprocating motion for test. (for a manufacturing test use) After completion of this test, the Gantry must be reset. TEST B 12 The collimator moves 140 pulses of a reciprocating motion for test. (for a manufacturing test use) After completion of this test, the Gantry must be reset. TEST C 13 The collimator moves [Home → 20 pulses] of a reciprocating motion for test. (for an endurance test use) After completion of this test, the Gantry must be reset. Value – Selected when selecting Function as a value. For example, if “01” is entered, the ZIGZAG function is selected. – 06–0F Reserved – 14–7F Reserved 1–60 SYSTEM CT HISPEED SERIES ADVANCED DIAGNOSTICS PROPRIETARY TO GENERAL ELECTRIC COMPANY REV 13 2202119 1-17 RAW DATA FUNCTIONS Table 1–17 Raw Data Functions Bar Menu Pulldown Menu File Exit Function Selection Save to MOD Restore/Delete from MOD Reserve/Release Initialize MOD Raw data Selection Whole Exam, Whole Series, Individual Raw Function Exits ‘Raw Data Functions.’ (Selected as default when ‘Raw Data Functions’ is selected.) Loads raw data files from the MOD to the system hard disk, or, deletes raw data files on the MOD. – Initializes an MOD inserted. Selects a raw data file, or, all the raw data files of a specified series No., or, all the raw data files of a specified exam No. (Note for Twin Systems only) For Twin systems, do not select ‘Individual Raw’ in the Raw data Selection menu, otherwise, problems may be caused for retro recon, etc. due to a Twin system algorithm related reason. This means that you should not handle individual raw data file. Instead, select ‘Whole Exam’ or ‘Whole Series’ in the menu. 1–61 SYSTEM PROPRIETARY TO GENERAL ELECTRIC COMPANY REV 13 CT HISPEED SERIES ADVANCED DIAGNOSTICS 2202119 1-18 SCAN ANALYSIS The scan analysis feature allows users to have interactive access to scan files collected on the scanner. Scan data to be viewed can come from either Patient Scanning or from service mode tools such as Diagnostic Data Collection or Calibration. Analysis is divided into three major areas of: SCAN ANALYSIS, dd FILE ANALYSIS, CAL FILE ANALYSIS, and Z– tracking (for Twin ONLY). dd FILE ANALYSIS and CAL FILE ANALYSIS is not yet available for this CT System. Each major section provides an File List Select interface similar to the Image Works List Select, Image Browser. Analysis List Select allows you to select the appropriate file of interest. Any of the normal scan files may be selected for processing within Scan Analysis including Axial, Helical, and Scout scans. Once the scan data of interest is selected you can select one of several processing options which include: Update, Scan Header, Cal Vectors, Plot MSD, Plot VVC, and Save Scan. Definitions within Scan Analysis D dd File (Diagnostic Data File): dd files are a result file from some type of operation on the scan data file. dd files are typically some form of view summed file that may have had some specific type of processing applied to it. For example, the processing applied to the raw data to calculate the position of the pin in ISO alignment results in a temporary file that is a view summed result that could be saved as a dd file. As long as two dd files have the same number of data elements in them the two files may be added, subtracted, multiplied, or divided with each other. D Means and Standard Deviation File (MSD): This is usually the result of combining two or more views mathematically which results in Mean Values for each channel in the views and an associated Standard Deviation for each channel in the views. In essence all of the user selected views in a scan file are summed together resulting in a single “master view” that contains the averaged data from all of the views. The mean values represent the average data value from the channels and the standard deviation values represent the amount of variability for that channels data values across all of the views. The higher the standard deviation the more the channel output varied from view to view. D Scan Header: This is the information contained within the Scan File that identifies the specific settings in affect when that scan file was created. The Scan Header includes information at several levels including: Exam, Series, and Scan. Information identifying the technique selections, scan time, acquisition mode, and many others may be found in the scan header. D Cal Vectors: Within Scan Analysis the Cal Vectors are only those vectors contained within the Scan Data File at the time that the scan was taken. D VVC (Views vs Channels): This is a way to graphically represent the data values from each channel for each view of data from the S–DAS as a shade of grey. The display will have the views stacked vertically and the channels arranged across the display horizontally. 1–62 SYSTEM PROPRIETARY TO GENERAL ELECTRIC COMPANY REV 13 CT HISPEED SERIES ADVANCED DIAGNOSTICS 2202119 1-18 SCAN ANALYSIS (continued) Starting the Scan Analysis Click on Scan Analysis. The following window appears. Selections in Scan Analysis Upon starting the Scan List Select window, you can highlight an EXAM –> SERIES –> SCAN, and perform the desired analysis feature by pressing any of the following buttons: D Update: The UPDATE selection will refresh the List Select Display if new scan files have been created since the Scan Analysis Tool was started. D Scan Header: The SCAN HEADER selection will open a scrolling text window that contains the header text information contained in select scan file. D Cal Vectors: The CAL VECTOR selection will open a window that allows you to select which of the calibration vectors in the selected scan file that you wish to look at. After the selections are made, OK will process the data requests and display the results. The resultant plots will be auto–scaled and in some cases the range of data displayed will be set automatically. This is to provide a reasonable initial view of the data. Always check the scale on the left hand side of the plot displays. Cursor reporting of data value and channel numbers is provided. 1–63 SYSTEM PROPRIETARY TO GENERAL ELECTRIC COMPANY REV 13 CT HISPEED SERIES ADVANCED DIAGNOSTICS 2202119 1-18 SCAN ANALYSIS (continued) D Create MDS DD File: (For V/R 5.5x or later) This will calculate a view averaged “super view” for the selected views and store the results in a separate file on the systems disk. The display will report the path and filename of the file just created. Once created, dd File can be viewed or compared with other files to check for specific operating characteristics. D Plot MSD: Provides a set of view summed Means and Standard Deviation Plots of a scan file. The plotter is started to display the means vectors and the standard deviation vectors, computed across the entire scan for each detector macro row. There will be (4) mean and standard deviation plot sets in the display window. After Plot MSD is started, a preprocessing option selection window appears: – Offset Correction: This processing step removes from the scan data, the signal bias introduced by the acquisition electronics. This operation is performed on a channel by channel basis for each view. – Reference Normalization: Makes use of unobstructed (not blocked by the patient) detector cells at the end of the detector to adjust for fluctuations in the x–ray beam and effects of aperture size and mA. In the case where the reference channels are blocked, the system uses an estimated value for the processing. The steps for Reference Normalizing the scan data involves: Offset Correction for the Reference Channels, Dividing the Offset Corrected Scan Data by the Averaged Reference Channels for each view. – Log Conversion: The log operation is applied. – Convolved Data: This processing step mathematically filters the channel data to remove blurring affects that would occur when the views are back–projected. The affect is to ‘sharpen’ each channels data value within the view. Without the convolution step, some of the x–ray attenuation data for a particular channel ends up in the channels on either side of that particular channel. Convolution puts that adjacent channel contribution back into the channel data that it should have been in to begin with. Cursor reporting of data value and channel numbers is provided. For terminology and usage, refer to Generic System Analyzer. 1–64 SYSTEM PROPRIETARY TO GENERAL ELECTRIC COMPANY REV 13 CT HISPEED SERIES ADVANCED DIAGNOSTICS 2202119 1-18 SCAN ANALYSIS (continued) D PLOT VVC: The PLOT VVC selection provides Views–vs–Channels display of a grey scale representation for the selected scan file. Each view of data (or summed, compressed view) is represented on the display as a horizontal line. Each pixel in the line represents the data value for a particular channel from the DAS. After VVC is activated,a preprocessing option selection window appears: – Offset Correction: This processing step removes from the scan data, the signal bias introduced by the acquisition electronics. This operation is performed on a channel by channel basis for each view. – Reference Normalization: Makes use of unobstructed (not blocked by the patient) detector cells at the end of the detector to adjust for fluctuations in the x–ray beam and effects of aperture size and mA. In the case where the reference channels are blocked, the system uses an estimated value for the processing. The steps for Reference Normalizing the scan data involves: Offset Correction for the Reference Channels, Dividing the Offset Corrected Scan Data by the Averaged Reference Channels for each view. – Log Conversion: The log operation is applied. – FFT channel Data: The combination operation of Offset Correction, Reference Normalization, and Log Conversion is applied. – Convolved Data: This processing step mathematically filters the channel data to remove blurring affects that would occur when the views are back–projected. The affect is to ‘sharpen’ each channels data value within the view. Without the convolution step, some of the x–ray attenuation data for a particular channel ends up in the channels on either side of that particular channel. Convolution puts that adjacent channel contribution back into the channel data that it should have been in to begin with. (PLOT VVC, Continued) 1–65 SYSTEM PROPRIETARY TO GENERAL ELECTRIC COMPANY REV 13 CT HISPEED SERIES ADVANCED DIAGNOSTICS 2202119 1-18 SCAN ANALYSIS (continued) After selecting the box or line cursor using ‘region of Interest’ selection box, click [Plot now]. Once displayed, the window and level for the displayed data can be changed to better see variations in the data. CURSOR BEHAVIOR IN VVC: Cross hair Cursor reporting is provided for: Data Value, DAS Channel, Detector Channel, and View number. The cursor is moved across the display using the mouse. A selection box on the display allows selection of Line Cursors (Channel and View) and Box Cursors (Rectangle) which allow the selection of a Channel, View, or Group of channels and views for plotting. The line and box cursors can be moved around the screen to view specific areas of interest. When the mouse pointer cursor is moved over a line cursor the mouse cursor will change to a four pointer arrow. Pressing the left mouse button allows you to ‘drag’ the cursor across the display. For the box cursors, the box may be dragged using the left mouse button with the mouse cursor positioned over the box. The size and shape of the box can be changed by moving the mouse cursor over the Bottom or Right edges of the box. When over the Bottom or Right edges of the box you can press the left mouse button to drag the box edge up and down or left and right. With the Line (Channel and View) cursors the plotted data will represent all Channels for a selected View or all Views for a selected Channel. With the Box Cursors the resulting plot will be a view summed Means and Standard Deviation plot for the selected views and channels. D Save Scan This will save the selected scan file to a temporary disk location so that it can moved to MOD or transferred via FTP to another location. 1–66 SYSTEM PROPRIETARY TO GENERAL ELECTRIC COMPANY REV 13 CT HISPEED SERIES ADVANCED DIAGNOSTICS 2202119 1-18 SCAN ANALYSIS (continued) 1-18-1 Z–Axis Tracking The Z–AXIS TRACKING tool is a new TAB for the twin system ONLY, located within the Analysis Tool. The tool can be used to plot various tracking functions, using a Scan Data Set. For a scan data set, the analysis package can plot different data versus views in UN–FILTERED (the default) or FILTERED (20 pt. Boxcar) formats. 1–67 SYSTEM PROPRIETARY TO GENERAL ELECTRIC COMPANY REV 13 CT HISPEED SERIES ADVANCED DIAGNOSTICS 2202119 1-18 SCAN ANALYSIS (continued) 1-18-1 Z–Axis Tracking (continued) In the figures that follow, examples of “known” Tracking plots are shown. Since plots vary from system to system, the examples shown should be used only as guides. Compare your System’s plots and analyze them relative to the specification shown in each figure. The plots shown are UN–FILTERED views, which is the default option when they are plotted. A 20 point boxcar filter takes the 20 view average and then plots the data. A value is not considered to be out of specification, unless the limit is exceeded for a sustained interval of 100 views or more. In the cases where specifications are not given, consider plots informational only. To use the function “Save to File” , need to make a directory named “data” under root. Then after performing Save to File, plot data is displayed and text file will be stored into data directory as named “TrackingVsScan.txt” (about 15KB size). But it is not so useful because of text file. It is recommended to remove the directory “data” after checking the TrackingVsScan.txt file for system stability. D Collimator Position: The plot shows the Collimator Position during a scan. Collimator positions are stored in the Scan file (Raw Data). The vertical axis shows the pulse count of Z–Axis pulse motor (20mm/pulse). 1–68 SYSTEM PROPRIETARY TO GENERAL ELECTRIC COMPANY REV 13 CT HISPEED SERIES ADVANCED DIAGNOSTICS 2202119 1-18 SCAN ANALYSIS (continued) 1-18-1 Z–Axis Tracking (continued) D Z–Ratio: Z–RATIO Plot computes the Ratio of Q–Cal Channels A and B. The value is given by the following equation. Z_Ratio + K * A * B K*A)B A and B means Q–Cal channel average data of each detector plane. (K=Qcal channel ratio) Note When you make a plot, you may be asked to enter the channel number. This has no meaning, any input generates same plot. 1–69 SYSTEM PROPRIETARY TO GENERAL ELECTRIC COMPANY CT HISPEED SERIES ADVANCED DIAGNOSTICS REV 13 2202119 1-18 SCAN ANALYSIS (continued) 1-18-1 Z–Axis Tracking (continued) D Center Ratio: CENTER RATIO plot indicates the calculated Focal Spot position relative to the centerline, with the center position being 0. The focal spot moves during a scan due to mA, rotor wobble, gantry rotation wobble, and because of tube (target) heat. Center_Ch_Ratio + K * A * B K*A)B A and B means active channel data of each detector plane.(K=Q cal channel ratio) Note The Ref. channel Ratio can not be seen by this tool. 1–70 SYSTEM PROPRIETARY TO GENERAL ELECTRIC COMPANY REV 13 CT HISPEED SERIES ADVANCED DIAGNOSTICS 2202119 1-18 SCAN ANALYSIS (continued) 1-18-2 DD dd File List Select Overview dd math is a means for the user to apply mathematical operations: add, subtract, multiply, and divide to dd files, and calculate the channel to channel difference or ratio of means vs. standard deviation vectors of a dd file. It allows the user to specify the scaling factor for the output vector, and provides three output modes: plot, dd file, and view numbers. dd math is part of the dd analysis user interface. Scan Analysis is used to generate dd files that may then be manipulated and or examined using dd File Analysis. 1–71 SYSTEM PROPRIETARY TO GENERAL ELECTRIC COMPANY CT HISPEED SERIES ADVANCED DIAGNOSTICS REV 13 2202119 1-18 SCAN ANALYSIS (continued) 1-18-2 DD (Continued) Operating dd Math Function The dd math operation buttons will be insensitive if no files are selected into the dd math operation panel. 1. The user may start dd math operation(s) by selecting the file(s) and putting them into the selection field by clicking the button FILE #1 or FILE #2. If the selected file is not a dd file, the application will not put it into the dd math operation field. A message window will pop up and ask user to select a dd file. If only one file is selected and it is of the file type RTS dd file or MSD dd file, both Ch2Ch (Channel to Channel) and Ratio (RATIO OF MEANS VS. STDV) will become sensitive. If the selected file is not of the type MSD or RTS, only Ch2Ch will become sensitive. When two dd files are selected, + (ADD), – (SUBTRACT), x (MULTIPLY), and / (DIVIDE) become sensitive and Ch2Ch and Ratio will be insensitive. 2. The user can specify the output file name when the dd file output mode is set. Otherwise a default dd file name will be provided. 3. The default output scaling factor is 1.0. The user can set the scaling factor to any real number. 4. When the dd math operation buttons are sensitive, the user can select the desired button to start the dd math operation. dd Files Generation There are 18 different dd file types of six orientations. The orientations are View, Channel, RTS, CAL, Elements, and Header. Channel oriented means and standard deviation type dd files are the only type that can be created from scan data files in the Scan Analysis application. 1–72 SYSTEM PROPRIETARY TO GENERAL ELECTRIC COMPANY REV 13 CT HISPEED SERIES ADVANCED DIAGNOSTICS 2202119 1-18 SCAN ANALYSIS (continued) 1-18-2 DD (Continued) dd Math Functions dd math consists of the following functions: D Add D Subtract D Multiply D Divide D Channel to Channel (Ch2Ch) difference D Ratio of means vs. standard deviation Perform: add, subtract, multiply, divide, and channel to channel difference operations on dd files. These operations are only available for dd file types. Add, Subtract, Multiply, Divide Applies add, subtract, multiply, and divide between vectors in two dd files. The output file is a dd file with one of the following suffixes: D .add D .dif D .mul D .rat Operations can be performed on dd files in View orientation, Channel orientation, RTS orientation, and Cal orientation. Currently, no dd type restrictions are applied to operations between dd files, as long as the dd vectors have the same number of elements. If one file has a single vector and the other file has multiple vectors the mathematical operation will be applied multiple times using the single vector. Otherwise the mathematical operation will be applied component wise for the number of vectors in each file. Channel to Channel Difference Applies the following calculation to the data from the data set(s) in the dd files for View, RTS or Cal orientation. (X2–X1), (X3–X2), (X4–X3),...,(Xn–Xn–1) Where X is the data value for each channel. The output is channel to channel dd file with extension: .c2c 1–73 SYSTEM PROPRIETARY TO GENERAL ELECTRIC COMPANY CT HISPEED SERIES ADVANCED DIAGNOSTICS REV 13 2202119 1-18 SCAN ANALYSIS (continued) 1-18-2 DD (Continued) Ratio of Means vs. Standard Deviation Takes a MSD (means and standard deviation) or RTS (real time statistics) type of dd file, calculates the ratio of data in the means vector (1st set) to data in standard deviation vector (2nd set). The output file is a ratio type of dd file with the extension: .rat dd Math Output Mode Three output modes are supported in dd math: D Plot: Will plot the output dd vector using an on screen vector display. D DD File: Allows the user to specify the output dd file name with a full path or the file basename. If only base name is provided the program will use the default prefix and suffix for the output file. The created dd file will be shown in the dd file list. D View #’s (Numbers): Prints the numerical data of the dd vector(s) to the display window(s). For image file types and scan file types, it will display the VVC plots of the selected files. Other Functions in dd Analysis User Interface The dd math operation panel supports the following functions for various file types. D Update Refreshes the display in the dd panel. D Plot Plots the vector(s) of the selected files in the display window for the following file types: dd Files and Cal Files D Save (to) MOD / Restore (From) MOD Saves the selected files to the MOD and restores all the dd files from /MOD/ddfiles to /data directory. D Sort By Date or Sort by Type The user can perform these functions, except dd math operations, by simply selecting one or more files in the list select window, and clicking the function button. The following file types are supported in this panel. D dd File D Cal File D Data File 1–74 SYSTEM PROPRIETARY TO GENERAL ELECTRIC COMPANY CT HISPEED SERIES ADVANCED DIAGNOSTICS REV 13 2202119 1-19 SERVICE CALIBRATION Table 1–18 Service Calibration Service Calibration Menu (Sequence) Auto Sequence 1 Displayed Instruction Air Cal → Phantom Cal [for CAM Change & Routine Maintenance] Auto Sequence 2 Q Cal → Air Cal → Phantom Cal [for Tube/Collimator/Filter/Slice Thickness Change] Auto Sequence 3 Q Cal → XT Cal → AV Cal → Air Cal → Phantom Cal [for Detector Change] Auto Sequence 4 DG Cal → Air Cal → Phantom Cal [for DAS Change] Auto Sequence 5 Q Cal → XT Cal → AV Cal → DG Cal → Air Cal → Phantom Cal [for 1st Installation] Q Cal – XT Cal – AV Cal – DG Cal – Asymmetric Seq Q Cal → Air Cal → Phantom Cal [for Asymmetric Option installation] D For ‘Auto Sequence 1’ only, 80 kV, 120 kV, or 140 kV can be selected. Phantom Calibration for Twin System Because of the X–ray geometry, 10mm Calibration file will be unique vector, and system requires two thickness Cal. data for Phantom Calibration. 10mm Cal. data is not linear against other thickness Cal files (7, 5,3, etc.). 10mm Calibration 7mm Calibration Used for 10mm Cal. File only. Used for 7, 5,3,2 and 1mm Cal. File. 1–75 SYSTEM PROPRIETARY TO GENERAL ELECTRIC COMPANY CT HISPEED SERIES ADVANCED DIAGNOSTICS REV 13 2202119 1-20 SERVICE MANUAL The service documentations CD–ROM can be displayed on the CRT of the OC. 1. Insert the Service Documentation CD–ROM into the CD–ROM drive of the OC. 2. Click on Service icon, then select Service Manual. The start screen of the service manual is displayed on the CRT. Note If “Netscape: Not Recommended Browser” window appears, click on Close. 3. Click on (Proceed –>) Main Page to select the Service manuals to be displayed. 4. To exit from the service manual, click the button located at the left upper of screen, then select Close. The service manual CD–ROM will be ejected automatically from the drive. Note For V/R 5.5x or later system, the CD–ROM can not be automatically ejected. So, open a shell window and enter eject to eject the CD–ROM. Then enter exit to close the shell window. 1–76 SYSTEM CT HISPEED SERIES ADVANCED DIAGNOSTICS PROPRIETARY TO GENERAL ELECTRIC COMPANY REV 13 2202119 ÍÍÍÍÍÍÍÍÍÍÍÍÍÍÍÍÍÍÍÍÍÍÍÍÍÍÍÍÍÍÍÍÍÍ ÍÍÍÍÍÍÍÍÍÍÍÍÍÍÍÍÍÍÍÍÍÍÍÍÍÍÍÍÍÍÍÍÍÍ ÍÍÍÍÍÍÍÍÍÍÍÍÍÍÍÍÍÍÍÍÍÍÍÍÍÍÍÍÍÍÍÍÍÍ 1-21 SHUTDOWN Note The Menu filled in yellow stripe below are the Class C tool. 1-21-1 Application Shutdown Click on Application Shutdown to terminate the application software and enter the desktop menu. By using the desktop menu, perform the followings: System Software Version Desktop Menu Descriptions 2.5 3.x 4.0 4.1 or later Startup x x x x Terminates the desktop menu and starts up the application software. Date setting x x x x Sets the date and time. Reconfig x x x x Performs system configurations. Savestate x x x x Saves the system state data in a MOD. x x x Restores the system state data saved by ‘Savestate’ function. Restorestate Install Options x x x x Installs the option key MOD. List Options x x x x Displays options installed in the system. Install Software x x Installs revision–up or patch softwares. Install InSite x x Installs InSite Software. Install Patch x Installs revision–up or patch softwares. List S/W Package x Displays versions of Patch and application softwares. Shell x x x x Displays the UNIX shell window. You can use the UNIX commands. LFW x x x x To perform the LFW procedures. Logout x x x x Do not click on this button!! If clicked, enter ‘ctuser’ as a login ID and ‘suisei.’ as a password to return the desktop menu (or scan panel). Shutdown x x x x Terminates the OS to power OFF the system. ÍÍÍÍÍÍÍÍÍÍÍÍÍÍÍÍÍÍÍÍÍÍÍÍÍÍÍÍÍÍÍÍÍÍ ÍÍÍÍÍÍÍÍÍÍÍÍÍÍÍÍÍÍÍÍÍÍÍÍÍÍÍÍÍÍÍÍÍÍ ÍÍÍÍÍÍÍÍÍÍÍÍÍÍÍÍÍÍÍÍÍÍÍÍÍÍÍÍÍÍÍÍÍÍ 1-21-2 System Shutdown (For the system V/R 5.5 or later) – Class C Click on System Shutdown to shut down the system. The shut–down procedure starts with no inquiry. 1–77 SYSTEM PROPRIETARY TO GENERAL ELECTRIC COMPANY CT HISPEED SERIES ADVANCED DIAGNOSTICS REV 13 2202119 1-22 SYSTEM BROWSER The System Browser is intended to provide a single point user interface for the review of important system information to aid evaluation and troubleshooting. ÍÍÍÍÍÍÍÍÍÍÍÍÍÍÍÍÍÍÍÍÍÍÍÍÍÍÍÍÍÍÍÍÍÍ ÍÍÍÍÍÍÍÍÍÍÍÍÍÍÍÍÍÍÍÍÍÍÍÍÍÍÍÍÍÍÍÍÍÍ ÍÍÍÍÍÍÍÍÍÍÍÍÍÍÍÍÍÍÍÍÍÍÍÍÍÍÍÍÍÍÍÍÍÍ Note The Menu filled in yellow stripe below are the Class C tool. Viewer Selections In the Viewer Selection Area, the user may select one of several system information areas to review. This selection is made using the ‘Pull Down’ window labeled ‘View:’ D GE System Log gesyslog D SYSLOG OC OC computer IRIX Operating System Log D IOS LOGS Application software logs for: Image Browser, Image Database Read Server, Image Database Write Server, Image Server, DICOM Server, Image Acquisition Server, Networking Server, Film Composer Log, Printer Server, Archive, Display, Filming. D Tube Usage Tube slice count and use information for the current and previous X–Ray Tubes. ÍÍÍÍÍÍÍÍÍÍÍÍÍÍÍÍÍÍÍÍÍÍÍÍÍÍÍÍÍÍÍÍÍÍ ÍÍÍÍÍÍÍÍÍÍÍÍÍÍÍÍÍÍÍÍÍÍÍÍÍÍÍÍÍÍÍÍÍÍ D Run Time Statistics (Class C) Tube spits, NPR test result, DBPCI test result. D OC Info. System software version, Disk usage, Network info., Current Process, Hardware Inventory, OC route table. D Configuration Files OC Host Configuration File, OC Scan Hardware Configuration File. ÍÍÍÍÍÍÍÍÍÍÍÍÍÍÍÍÍÍÍÍÍÍÍÍÍÍÍÍÍÍÍÍÍÍ ÍÍÍÍÍÍÍÍÍÍÍÍÍÍÍÍÍÍÍÍÍÍÍÍÍÍÍÍÍÍÍÍÍÍ ÍÍÍÍÍÍÍÍÍÍÍÍÍÍÍÍÍÍÍÍÍÍÍÍÍÍÍÍÍÍÍÍÍÍ ÍÍÍÍÍÍÍÍÍÍÍÍÍÍÍÍÍÍÍÍÍÍÍÍÍÍÍÍÍÍÍÍÍÍ ÍÍÍÍÍÍÍÍÍÍÍÍÍÍÍÍÍÍÍÍÍÍÍÍÍÍÍÍÍÍÍÍÍÍ D History Log (Class C) Logs for calibration, analysis, test, etc. D Software Health Page (Class C) Files for JEDI error, IOS, etc. After the Major Area of interest is selected in the ‘View:’ window, you may select one or more of the items displayed in the ‘Option:’ window directly below the ‘View: Pull Down Window’. This allows more than one group of information to be viewed together. 1–78 SYSTEM PROPRIETARY TO GENERAL ELECTRIC COMPANY REV 13 CT HISPEED SERIES ADVANCED DIAGNOSTICS 2202119 1-22 SYSTEM BROWSER (continued) After the ‘Option:’ window selects have been made, you may get the selected information from the system by selecting the button directly to the right of the ‘Option:’ window. The Button name will change depending upon the type of information being selected. In the case of the GE System Log the button is labeled RETRIEVE BUFFER PAGE and if the selection had been Tube Usage the button selections would be SUMMARY, DETAIL, and CUMULATIVE. Each of the selections will be explained later in this description. In the Viewer Selection Area you may also enter an alpha–numeric text string to Search for in the currently Displayed information. ÍÍÍÍÍÍÍÍÍÍÍÍÍÍÍÍÍÍÍÍÍÍÍÍÍÍÍÍÍÍÍÍÍÍ ÍÍÍÍÍÍÍÍÍÍÍÍÍÍÍÍÍÍÍÍÍÍÍÍÍÍÍÍÍÍÍÍÍÍ ÍÍÍÍÍÍÍÍÍÍÍÍÍÍÍÍÍÍÍÍÍÍÍÍÍÍÍÍÍÍÍÍÍÍ ÍÍÍÍÍÍÍÍÍÍÍÍÍÍÍÍÍÍÍÍÍÍÍÍÍÍÍÍÍÍÍÍÍÍ ÍÍÍÍÍÍÍÍÍÍÍÍÍÍÍÍÍÍÍÍÍÍÍÍÍÍÍÍÍÍÍÍÍÍ ÍÍÍÍÍÍÍÍÍÍÍÍÍÍÍÍÍÍÍÍÍÍÍÍÍÍÍÍÍÍÍÍÍÍ Class C Functions D Histogram provides a bar graph histogram of the software processes reporting errors in the GE System Log. The size of the bars indicates the number of each item that was found in the log. D Selecting ‘Filter’ and then ‘Histogram’ provides a bar graph of errors in the GE System Log that contain specific alpha–numeric strings. The current strings are: Pri/Most, Pri/Soft, Abort, TAXI, DIP, Filter, Aperture, Converter, ICE CPU, temperature, watchdog, overrun. GE System Log The System Browser provides convenient viewing of the scanner primary message log /usr/g/service/log/gesys__oc.log After the user selects the GE System Log the entire log is read and divided into ‘pages’ of 1000 lines of messages. Each ‘page’ of the log is displayed in the ‘Option:’ window with the following format: Pg # :Day of Week mmm dd hh:mm:ss yyyy You may then select one or more of the ‘pages’ within the option window and then select ‘Retrieve Buffer Page’. This allows you to quickly move to a specific Date/Time of interest and avoid having to scroll through parts of the log that is not of current interest. Once the Buffer pages have been retrieved, you can search within the currently displayed pages for any alpha–numeric string entered in the Search Field and then selecting the Search Button. The search field is case sensitive. Depending upon the selections for: Next, Previous, First, Last the viewer will display the Next, Previous, First, or Last occurrence of the Search String. Selecting Search Again will take you to the Next or Previous occurrence if those selections had been made. The Search feature will also display how many of occurrences of the Search string where found in that section(s) of the log. The information is displayed in the User Message Area at the bottom of the window in the form of: Search Status: Found XX match(s) of 1–79 SYSTEM PROPRIETARY TO GENERAL ELECTRIC COMPANY REV 13 CT HISPEED SERIES ADVANCED DIAGNOSTICS 2202119 1-22 SYSTEM BROWSER (continued) ÍÍÍÍÍÍÍÍÍÍÍÍÍÍÍÍÍÍÍÍÍÍÍÍÍÍÍÍÍÍÍÍÍÍ ÍÍÍÍÍÍÍÍÍÍÍÍÍÍÍÍÍÍÍÍÍÍÍÍÍÍÍÍÍÍÍÍÍÍ ÍÍÍÍÍÍÍÍÍÍÍÍÍÍÍÍÍÍÍÍÍÍÍÍÍÍÍÍÍÍÍÍÍÍ ÍÍÍÍÍÍÍÍÍÍÍÍÍÍÍÍÍÍÍÍÍÍÍÍÍÍÍÍÍÍÍÍÍÍ ÍÍÍÍÍÍÍÍÍÍÍÍÍÍÍÍÍÍÍÍÍÍÍÍÍÍÍÍÍÍÍÍÍÍ ÍÍÍÍÍÍÍÍÍÍÍÍÍÍÍÍÍÍÍÍÍÍÍÍÍÍÍÍÍÍÍÍÍÍ ÍÍÍÍÍÍÍÍÍÍÍÍÍÍÍÍÍÍÍÍÍÍÍÍÍÍÍÍÍÍÍÍÍÍ ÍÍÍÍÍÍÍÍÍÍÍÍÍÍÍÍÍÍÍÍÍÍÍÍÍÍÍÍÍÍÍÍÍÍ ÍÍÍÍÍÍÍÍÍÍÍÍÍÍÍÍÍÍÍÍÍÍÍÍÍÍÍÍÍÍÍÍÍÍ ÍÍÍÍÍÍÍÍÍÍÍÍÍÍÍÍÍÍÍÍÍÍÍÍÍÍÍÍÍÍÍÍÍÍ ÍÍÍÍÍÍÍÍÍÍÍÍÍÍÍÍÍÍÍÍÍÍÍÍÍÍÍÍÍÍÍÍÍÍ ÍÍÍÍÍÍÍÍÍÍÍÍÍÍÍÍÍÍÍÍÍÍÍÍÍÍÍÍÍÍÍÍÍÍ ÍÍÍÍÍÍÍÍÍÍÍÍÍÍÍÍÍÍÍÍÍÍÍÍÍÍÍÍÍÍÍÍÍÍ ÍÍÍÍÍÍÍÍÍÍÍÍÍÍÍÍÍÍÍÍÍÍÍÍÍÍÍÍÍÍÍÍÍÍ ÍÍÍÍÍÍÍÍÍÍÍÍÍÍÍÍÍÍÍÍÍÍÍÍÍÍÍÍÍÍÍÍÍÍ ÍÍÍÍÍÍÍÍÍÍÍÍÍÍÍÍÍÍÍÍÍÍÍÍÍÍÍÍÍÍÍÍÍÍ ÍÍÍÍÍÍÍÍÍÍÍÍÍÍÍÍÍÍÍÍÍÍÍÍÍÍÍÍÍÍÍÍÍÍ ÍÍÍÍÍÍÍÍÍÍÍÍÍÍÍÍÍÍÍÍÍÍÍÍÍÍÍÍÍÍÍÍÍÍ ÍÍÍÍÍÍÍÍÍÍÍÍÍÍÍÍÍÍÍÍÍÍÍÍÍÍÍÍÍÍÍÍÍÍ ÍÍÍÍÍÍÍÍÍÍÍÍÍÍÍÍÍÍÍÍÍÍÍÍÍÍÍÍÍÍÍÍÍÍ ÍÍÍÍÍÍÍÍÍÍÍÍÍÍÍÍÍÍÍÍÍÍÍÍÍÍÍÍÍÍÍÍÍÍ ÍÍÍÍÍÍÍÍÍÍÍÍÍÍÍÍÍÍÍÍÍÍÍÍÍÍÍÍÍÍÍÍÍÍ Class C Histogram and Filter Function for GE System Log In addition to the standard viewing and search functions described above, the System Browser allows you to produce a Histogram of the entire gesyslog and display the results in a graphical, bar chart format. An additional feature is to first apply a fixed filter to the entire gesyslog and then produce a graphical histogram of the filtered results. Additional Histogram and Filter Functions are planned to be added in later software releases based upon your and engineering’s inputs. D Histogram If the ‘Histogram’ button is selected, the System Browser processes the entire gesyslog, not just the buffer pages currently being viewed. The current Histogram processing counts the number of times that individual software processes (programs) log messages to the gesyslog. The Histogram includes two different pieces of information for each line reported in the graph. – The name of the item(s) found during the generation of the Histogram. In this example the names of the processes reporting messages to the log are displayed next to the number of occurrences in the form . The process names are the names reported in the gesyslog Process: field. – A bar graph showing the relative number of occurrences for the found items in descending order from the most number found to the least number found. D Filter (Filtered Histogram) If the ‘Filter Check Box’ is selected and then the ‘Histogram Button’, the System Browser will first apply a filter to the gesyslog and then produce a Histogram of that result. The current fixed filter is a list of ‘key word strings’. In the future we will add additional filter sets based upon field and engineering inputs. SYSLOG – OC When you select either SYSLOG OC, the System Browser will display the IRX SYSLOG Files on the respective computer. These are the logs normally found at /var/adm on the OC system. Once again you may select one or more of the log files to view in the Options: window and then select the View File Button to retrieve and display the requested information. The Search and Next, Previous, First and Last functions operate the same as for the basic gesyslog viewer. IOS Logs The IOS log files are created and updated by various scanner application software processes. These processes include: Image Browser, Image Database Read Server, Image Database Write Server, Image Server, DICOM Server, Image Acquisition Server, Networking Server, Film Composer Log, Printer Server, Archive, Display, and Filming. The System Browser has the same operation and capabilities as those for viewing the IRIX SYSLOG files. 1–80 SYSTEM PROPRIETARY TO GENERAL ELECTRIC COMPANY CT HISPEED SERIES ADVANCED DIAGNOSTICS REV 13 2202119 1-22 SYSTEM BROWSER (continued) Tube Usage The System Browser is used to display information about the currently installed tube as well as previously installed tubes. The Tube Usage viewer provides three different levels of information viewing for Tube Usage: Summary, Details, and Cumulative. Note For Tube Warranty purposes ‘Warranty Effective Slices’ is the correct number to report upon tube unit failure. D Tube Usage Details Information The Tube Usage Details information identifies the selected Tube Unit and Site Information plus details on the types and number of scans taken on that tube unit. D Tube Usage Cumulative Information The Tube Usage Cumulative Information displays the totaled tube usage information for all tubes that have been installed on the system. ÍÍÍÍÍÍÍÍÍÍÍÍÍÍÍÍÍÍÍÍÍÍÍÍÍÍÍÍÍÍÍÍÍÍ ÍÍÍÍÍÍÍÍÍÍÍÍÍÍÍÍÍÍÍÍÍÍÍÍÍÍÍÍÍÍÍÍÍÍ ÍÍÍÍÍÍÍÍÍÍÍÍÍÍÍÍÍÍÍÍÍÍÍÍÍÍÍÍÍÍÍÍÍÍ ÍÍÍÍÍÍÍÍÍÍÍÍÍÍÍÍÍÍÍÍÍÍÍÍÍÍÍÍÍÍÍÍÍÍ ÍÍÍÍÍÍÍÍÍÍÍÍÍÍÍÍÍÍÍÍÍÍÍÍÍÍÍÍÍÍÍÍÍÍ Run Time Stats – Class C The system Browser allows you to display statistical information gather by different subsystems in the scanner. Unlike the other viewers only one category may be selected at a time for display. Currently the System Browser can display the following information under Run Time Stats:Tube spits, NPR test result, DBPCI test result. OC Info The title for this section may be a little misleading so take a look at the capabilities that the System Browser can provide to you in this area. The System Browser has the capability of running some of the routinely used IRIX commands used in gathering data about the system operation and configuration as well as reporting some of the specific scanner configuration files. Note that multi–select is available in the ‘Option:’ Window. Note also that the Search Function is available. The command results available in this area are: D System Software Revisions:showprods D Disk Usage: df D OC Network Sockets:netstat –ian D OC Route Table: netstat –r D OC Network Configuration:ifconfig D OC Current Processes Running:ps –aef D OC Hardware Inventory:hinv 1–81 SYSTEM PROPRIETARY TO GENERAL ELECTRIC COMPANY REV 13 CT HISPEED SERIES ADVANCED DIAGNOSTICS 2202119 1-22 SYSTEM BROWSER (continued) Config Files The System Browser has the capability of viewing some of the routinely referenced scanner configuration files used in gathering data about the system: Info file, OC host.cfg, OC scanrecon.cfg, OC option.cfg, etc.. ÍÍÍÍÍÍÍÍÍÍÍÍÍÍÍÍÍÍÍÍÍÍÍÍÍÍÍÍÍÍÍÍÍÍ ÍÍÍÍÍÍÍÍÍÍÍÍÍÍÍÍÍÍÍÍÍÍÍÍÍÍÍÍÍÍÍÍÍÍ ÍÍÍÍÍÍÍÍÍÍÍÍÍÍÍÍÍÍÍÍÍÍÍÍÍÍÍÍÍÍÍÍÍÍ ÍÍÍÍÍÍÍÍÍÍÍÍÍÍÍÍÍÍÍÍÍÍÍÍÍÍÍÍÍÍÍÍÍÍ ÍÍÍÍÍÍÍÍÍÍÍÍÍÍÍÍÍÍÍÍÍÍÍÍÍÍÍÍÍÍÍÍÍÍ ÍÍÍÍÍÍÍÍÍÍÍÍÍÍÍÍÍÍÍÍÍÍÍÍÍÍÍÍÍÍÍÍÍÍ ÍÍÍÍÍÍÍÍÍÍÍÍÍÍÍÍÍÍÍÍÍÍÍÍÍÍÍÍÍÍÍÍÍÍ ÍÍÍÍÍÍÍÍÍÍÍÍÍÍÍÍÍÍÍÍÍÍÍÍÍÍÍÍÍÍÍÍÍÍ ÍÍÍÍÍÍÍÍÍÍÍÍÍÍÍÍÍÍÍÍÍÍÍÍÍÍÍÍÍÍÍÍÍÍ ÍÍÍÍÍÍÍÍÍÍÍÍÍÍÍÍÍÍÍÍÍÍÍÍÍÍÍÍÍÍÍÍÍÍ History Log – Class C The System Browser has the capability of viewing some history log files: Alignment, Service Calibration, User calibration, CT number adjustment, Tube warmup, Gravity sag, Heat soak, Image analysis, JEDI diag, DAS transfer test, DAS linearity test, POST recon test, InSite activity, etc.. Software Health Page – Class C The System Browser has the capability of viewing some log files: JEDI error, assoc_out, caldate, corefilelist, ermes, gesys.log, hast_report, hiv_inv, ios logs, least 15, login_logout, message_report, module, OC_SYSLOG, process, readme, reli_number, reli_report, starup_shutdown, swHealthPage.log, swinfo, top15, etc.. 1–82 SYSTEM PROPRIETARY TO GENERAL ELECTRIC COMPANY CT HISPEED SERIES ADVANCED DIAGNOSTICS REV 13 2202119 1-23 TUBE PRO. (NOFILM, CHANGE) IMPORTANT NOTE: This procedure is provided for the single detector system. It will take approx. two hours to complete adjustments. 1. Select Service Menu → Tube Pro. (NoFilm, Change) 2. Tube procedure tool will execute. If you have already initialized Tube Filament Aging Data, click on OK. If it does not, click on Cancel then perform CLEAR FILAMENT AGING, using Service Menu –> Generator test. 3. Enter Tube Insert Serial Number (Not Housing Serial Number), then click on OK. 4. Follow the procedures that appear on the CRT screen. The following adjustments will be performed. D Tube POR Alignment: For detailed procedures, refer to FCA, System, X–ray alignment, POR Except for Twin System. D Tube BOW Alignment: For detailed procedures, refer to FCA, System, X–ray alignment, BOW Except for Twin System. D Tube ISO Alignment: For detailed procedures, refer to FCA, System, X–ray alignment, ISO Center Alignment. D Q calibration: For detailed procedures, refer to FCA, System, System Calibration, HiLight Calibration. D Bowtie Filter Alignment: For detailed procedures, refer to FCA, System, X–ray alignment, Filter Alignment. D Auto Sequence 1 (Air and Phantom cal): For detailed procedures, refer to Section 1-19 Service Calibration. D Quick CT # Adjustment 1–83 SYSTEM PROPRIETARY TO GENERAL ELECTRIC COMPANY REV 13 CT HISPEED SERIES ADVANCED DIAGNOSTICS 2202119 1-24 TUBE PRO. (NOFILM, MFG.) IMPORTANT NOTE: This procedure is provided for the single detector system. This tool can perform full calibrations as follows: (Mainly used at manufacturing line) D Tube POR Alignment D Tube BOW Alignment D Gravity SAG D Tube Rough ISO Alignment D Radial Alignment D Tube ISO Alignment D Q–cal D XT–cal D AV–cal D DG–cal D Bowtie Filter Alignment D Auto Sequence 1 (Air and Phantom Cal) D Quick CT # Adjustment 1–84 SYSTEM CT HISPEED SERIES ADVANCED DIAGNOSTICS PROPRIETARY TO GENERAL ELECTRIC COMPANY REV 13 2202119 1-25 TUBE PROCEDURE (CHANGE) IMPORTANT NOTE: This procedure is provided for the Twin detector system. Prior to starting Tube Procedure (change) 1. Checking the Aperture Home Position: a. Attach a tape as a mark onto the motor drive pulley to read a number of rotation of the collimator Z–axis drive motor. Mark (tape) Nearly aligned b. Press the OGP reset switch to drive the collimator Z–axis drive motor. Push this reset SW. OGP BOARD c. Verify that: –The aperture moves smoothly. –The mark, attached in step a, rotates approx. 3 times CW, 6 times CCW, and 3 times CW, then the aperture stop moving. d. Verify that the aperture front surface is NEARLY aligned with the front surface of the collimator case. (See the photograph above.) 1–85 SYSTEM CT HISPEED SERIES ADVANCED DIAGNOSTICS PROPRIETARY TO GENERAL ELECTRIC COMPANY REV 13 2202119 1-25 TUBE PROCEDURE (CHANGE) (continued) Checking for the Aperture Z–Axis Zigzag motion: a. Select Service –> Offline Scan. b. Perform one off–line scan (Stationary, 1sec,100mA, 1mm, Small Focus, T/G control → Auto Collimator:ON) with the bow–tie filter installed. (This scan is performed to move the collimator so that X–ray beam is evenly exposed for both A and B channels.) After scanning, do not exit from the Off–line scan screen. c. Set the Zigzag motion for the collimator aperture: D For V/R 5.5x or later system: Select Offline Scan –> T/G Control –> CIF mode –> ZIGZAG. 8 0 7 6 5 4 3 2 7 1 O N ON D For V/R 5.0x system: Switch OFF ‘Rotate’ breaker at the Gantry rear base and open the left DAS cover. Set the bit switch 3 of the SW2 to the ON position as shown. Then switch ON ‘Rotate’ breaker. SW2 2. BEAM TRACKING CONTROL d. Perform one off–line scan (Stationary, 1sec,100mA, 1mm, Small Focus, T/G control → Auto Collimator:OFF) with the bow–tie filter installed. e. Select Service –> Generic System Analyzer –> Format Raw Data –> A side. f. Select the raw data file (of the last scan performed in step d) from the Raw data browser lists. Perform Fan Data with the following settings, then click on OK: Offset File Correction Yes Reference Correction No Natural Log Conversion No Select Original as “Select Type of Data:”. Select Store to File. Enter 1 as “Mean Vector Number” and A ch as “File Comment”, then click on OK. 1–86 SYSTEM CT HISPEED SERIES ADVANCED DIAGNOSTICS PROPRIETARY TO GENERAL ELECTRIC COMPANY REV 13 2202119 1-25 TUBE PROCEDURE (CHANGE) (continued) g. Click on Select RawID... to return to the Fan Data Format screen, and select B side and repeat step f to make MeanFile 2 – B ch. h. Select Service Menu → Generic System Analyzer (GSA) → Analysis → Calculations → Raw/Raw. Op. i. Select A+B from ‘Select Operation:’. Select SvSupRaw 1–Ach as Raw Data File A. Select SvSupRaw 2–Bch as Raw Data File B. Enter 3 as “Output Raw File Number” and A + B as “Comment”, then click on OK. j. Repeat step i to make SvSupRaw 4 – A–B by selecting ‘A–B’ as ‘Select Operation:’. k. Select A/B from ‘Select Operation:’. l. Select SvSupRaw 4–A–B as Raw Data File A. Select SvSupRaw 3–A+B as Raw Data File B. m. Enter 5 as “Output Raw File Number” and A–B/A+B as “Comment”, then click on OK. n. Select Service Menu → Generic System Analyzer (GSA) → Analysis → View Raw Data. o. Select SvSupRaw 5– A–B/A+B as “Select SupRaw File:”. p. Click on [Cursor], then set the cursor to View=1 and Channel=826. q. Click on [Plot]. r. Select ‘Vertical Profile’. Select ‘Manual Scale.’ Enter –1 for Data Min. Enter 1 for Data Max. Click on OK. A graph like in Illustration below is drawn. Normal Abnormal An acute angle must be displayed. –1 –0.5 0 0.5 1–87 1 SYSTEM PROPRIETARY TO GENERAL ELECTRIC COMPANY CT HISPEED SERIES ADVANCED DIAGNOSTICS REV 13 2202119 1-25 TUBE PROCEDURE (CHANGE) (continued) s. Set the SW2 on the CIF Board to the original position (all to OFF) and install the DAS cover. t. Switch ON the ‘Rotate’ switch. Starting Tube Procedure (change) It will take approx. two hours to complete adjustments. 1. Select Service Menu → Tube Procedure (change) 2. Tube procedure tool will execute. If you have already initialized Tube Filament Aging Data, click on OK. If it does not, click on Cancel then perform CLEAR FILAMENT AGING, using Service Menu –> Generator test. 3. Enter Tube Insert Serial Number (Not Housing Serial Number), then click on OK. 4. Follow the procedures that appear on the CRT screen. The following adjustments will be performed. D POR Alignment: For detailed procedures, refer to FCA, System, X–ray alignment, POR for Twin System. D BOW Alignment: For detailed procedures, refer to FCA, System, X–ray alignment, BOW for Twin System. D Q cal Cannel Ratio: For detailed procedures, refer to FCA, System, X–ray alignment, Qcal Channel Ratio. D ISO Alignment: For detailed procedures, refer to FCA, System, X–ray alignment, ISO Center Alignment. D Q calibration: For detailed procedures, refer to FCA, System, System Calibration, HiLight Calibration. D Bowtie Filter Alignment: For detailed procedures, refer to FCA, System, X–ray alignment, Filter Alignment. D Auto Sequence 1: For detailed procedures, refer to Section 1-19 Service Calibration. D CT # Adjustment: For detailed procedures, refer to FCA, System, System Calibration, CT Number Adjustment. 1–88 SYSTEM PROPRIETARY TO GENERAL ELECTRIC COMPANY REV 13 CT HISPEED SERIES ADVANCED DIAGNOSTICS 2202119 1-26 TUBE PROCEDURE (MFG.) IMPORTANT NOTE: This procedure is provided for the Twin detector system. This tool can perform full calibrations as follows: (Mainly used at manufacturing line) D POR D BOW D Qcal channel Ratio D Gravity SAG D Rough ISO Alignment D Radial Alignment D ISO Alignment D Q–cal D XT–cal D AV–cal D DG–cal D Bowtie Filter Alignment D Auto Sequence 1 D CT Number Adjustment 1–89 SYSTEM PROPRIETARY TO GENERAL ELECTRIC COMPANY CT HISPEED SERIES ADVANCED DIAGNOSTICS REV 13 2202119 1-27 UPDATE SYSTEM LOG The following logs can be updated by this menu. D ‘Tube Usage’, ‘Tube Spits’, ‘Bad Raw’ NOTICE When updating system log(s), reboot the system to enable a newly created file. 1–90 SYSTEM PROPRIETARY TO GENERAL ELECTRIC COMPANY REV 13 CT HISPEED SERIES ADVANCED DIAGNOSTICS 2202119 1-28 USER PREFERENCE The following can be set in this menu. 1–91 SYSTEM PROPRIETARY TO GENERAL ELECTRIC COMPANY CT HISPEED SERIES ADVANCED DIAGNOSTICS REV 13 2202119 1-29 VECTOR CONVERT Table 1–19 Vector Convert Parameter to be Specified Generation Selectable Parameter Current, Previous, 2Before, 3Before, ... , 9Before (When ‘Warmup Whole’ is selected for ‘Vector’ only) (arbitrary) Store from Vector Warmup Whole, Warmup History, Hilight, Air & Ptm Item Mean, 1/Mean, SD, SD/Mean, Ratio, HPFratio, AP chk0, AP (When ‘Warmup History’ is se- chk90, AP chk180, AP chk270, stRatio, filstRatio lected for ‘Vector’ only) kV, Thickness, Cal.FOV, Focus (kV), (Thickness), (Cal.FOV), (Focus) (When ‘Air & Ptm’ is selected for ‘Vector’ only) How to Use 1. Specify the parameters described in Table 1–19. 2. Click [Convert vector]. 3. Click [Show contents]. The following is displayed. Table 1–20 Vector ‘Show contents’ Displayed Information Warmup Whole Date & Time Warmup History Date & Time Hilight Air & Ptm Date & Time, (others) Date & Time, beta, gamma, (others) 1–92 SYSTEM CT HISPEED SERIES ADVANCED DIAGNOSTICS PROPRIETARY TO GENERAL ELECTRIC COMPANY REV 10 2202119 SECTION 2 – MESSAGE DISPLAY 2-1 MESSAGE DESKTOP When an error occurs, the system gives an alert sound, and displays a message on the message bar. See Illustration 2–1. Click the message bar to display the message desktop and to see more messages if any. The screen only shows messages which are current. To see the message log, click [View Log]. Illustration 2–1 Message Desktop Monitor Screen Scan Display ImageWorks Service Shutdown Idle Attach in progress Network status Filming Status Message Bar Current Messages Clear View Log (dimmed) Close Memo Update (dimmed) Message Desktop 2–1 SYSTEM CT HISPEED SERIES ADVANCED DIAGNOSTICS PROPRIETARY TO GENERAL ELECTRIC COMPANY REV 10 2-1 2202119 MESSAGE DESKTOP (continued) Viewing Level Click [Select Viewing Level] to show a pop–up menu for a Viewing Level selection. Refer to Illustration 2–2 and Table 2–1. Illustration 2–2 Message Log Report Message Desktop Message Log Report Select Viewing Level Table 2–1 Viewing Level (Pop–up Menu) All Operator Selection of Viewing Level Description All messages are displayed. Messages for operators are displayed. Service Messages for service engineers are displayed. Support Messages for software engineers are displayed. 2–2 SYSTEM CT HISPEED SERIES ADVANCED DIAGNOSTICS PROPRIETARY TO GENERAL ELECTRIC COMPANY REV 10 2-2 2202119 ERROR LOG VIEWER MESSAGE FORMAT 1. Following is the general format of message which you can see on Error Log viewer. Error code is assigned as unique number in one software version but this may be different if software version is different. Host name of this system Process name which output this message Date Tue Apr 18 13:30:02 2000 Host:ctbay01 Proc:scanRx File:UIRx.cxx Line:10653 Function : Data Acquisition : OC Processing Start : Prospective Exam : 415 : Protocol : 1. Error:200109155 Error code which is assigned for this software Explanation 2. In case error is from Table/Gantry, including JEDI and DAS, there are 3 types of explanation format: (1) XG error On V/R4.10 or later, JEDI detail error code is on Error Log viewer(gesyslog) in case that error causes scan stop. It means errors higher than Class3 is displayed there. This is common between V/R4.xx software and V/R5.xx software. See X–ray Generator Section for detail. Fri Apr 28 18:25:02 2000 Host:ctbay10 Proc:tgp_out XG Error. Phase is 2 code is 50. Detail error code : 50–0212H Heater Error : MAINS_DROP detected.. 2–3 Error:186218 SYSTEM PROPRIETARY TO GENERAL ELECTRIC COMPANY CT HISPEED SERIES ADVANCED DIAGNOSTICS REV 10 2-2 2202119 ERROR LOG VIEWER MESSAGE FORMAT (continued) (2) Except XG Error on V/R4.13 or before You can find more detail explanation for each errors on Advanced Diagnostics TAB. What kind of errors happened. Wed Apr 12 13:38:45 2000 Host:ctbay07 Proc:tgp_out Cradle Error. SW/HW Error: TGP Error Detected. code is 2 Detail error code in Cradle Error. Error:186403 Who detects the error. ‘TGP Error Detected’ means TGP detects the error. (3) Except XG Error on V/R5.00 or later Error Code which is assigned to identify error is unique even if software version is different. All of errors have the information who detects error and detail explanation to help you understand the situation. What kind of errors happened. Error Code which is assigned to identify errors Fri Apr 28 20:30:07 2000 Host:ctbay10 Proc:tgp_out Cradle Error. Code:12–1030–02 Error detected by : TGP(TP) Cradle unlatch was detected on CRADLE CMD. Who detects the error Error:186327 Detail explanation of this error. 2–4 SYSTEM CT HISPEED SERIES ADVANCED DIAGNOSTICS PROPRIETARY TO GENERAL ELECTRIC COMPANY REV 10 2-2 2202119 ERROR LOG VIEWER MESSAGE FORMAT (continued) Error Code format is as below. Detail Error Code. Code:12 – 1030 – 02 Who detects the error. What kind of error happened Error or Information, 1 is Error and 0 is Information. List of code who detects the error. 11 12 13 20 30 40 TGP(MP) TGP(TP) TGP(GP) OGP CIF(DAS) kV Control(JEDI) 2–5 SYSTEM PROPRIETARY TO GENERAL ELECTRIC COMPANY blank CT HISPEED SERIES ADVANCED DIAGNOSTICS 2202119 2–6 SYSTEM CT HISPEED SERIES ADVANCED DIAGNOSTICS PROPRIETARY TO GENERAL ELECTRIC COMPANY REV 13 2202119 SECTION 3 – UNIX COMMANDS 3-1 UNIX COMMANDS FOR TROUBLESHOOTING For other Unix commands or detailed information, refer to Section 4, Irix Guide. 3-1-1 Disk Usage Information Enter the following command in the Unix shell to display the disk usage information. $ df 3-1-2 Recovery The following commands will restart the process without performing system shutdown. Description Command (in the Unix Shell) /usr/g/bin/restartDisplay If the display (autoview portion) process is crashed, it can be restarted with this command. (You can also use a command from the Display or ImageWorks desktop menu.) (from the ImageWorks desktop menu) If the browser process is crashed, it can be restarted with this command. restartBrowser 3-1-3 Software Problem → Just write SPR (Service Problem Report) with reproducible operation as detailed as possible. 3–1 SYSTEM CT HISPEED SERIES ADVANCED DIAGNOSTICS PROPRIETARY TO GENERAL ELECTRIC COMPANY REV 13 3-1-4 2202119 How to Collect Log (SnapState) Just do SnapState to collect all the necessary logs. (error logs, core files, timer logs, etc.) SnapState saves log files either hard disk or MOD. Select “Snap State” from Utility menu on Service desktop. Or, Enter the following command in shell. $ SnapState SnapState Option No Option Function same function as “–c”. –M Save to MOD automatically, no prompt. –a Run in fully automated mode (HAST). –c Use createTracebacks. This creates traceback file from core and remove core. –f Forced remove without save or information, use is NOT asked for permission. –h Describe usage of SnapState. –i Save log files only (InSite mode). –m Forces special message used by autostart and changes default answers to questions. –s Run in silent mode, no questions. –sl Storelog mode, no user input. –REMOVE –SAVE Forced remove with save and information. Forced save. Here is a list of files which SnapState stores. Store Path: /MOD/. ... in case of MOD /usr/sc/log/..tar ... in case of disk 3–2 SYSTEM PROPRIETARY TO GENERAL ELECTRIC COMPANY REV 13 3-1-4 CT HISPEED SERIES ADVANCED DIAGNOSTICS 2202119 How to Collect Log (SnapState) (continued) Files to be stored: /usr/g/bin/core* /usr/g/service/log/core* /usr/g/service/core/core* /usr/tmp/core* /usr/g/service /Sv* /usr/g/service /gesys_.log /usr/g/service /exam*.protocol (not available now) /usr/g/service /exam*.scan.request (not available now) /var/adm/SYSLOG /var/adm/crash/* /usr/g/ctuser/logfiles/*log /tmp/*.log* (result of /usr/g/srtools/getLogScanRecon) /tmp/recon_q* (result of /usr/g/srtools/getLogScanRecon) /tmp/rawctrl* (result of /usr/g/srtools/getLogScanRecon) /tmp/acq.req (result of /usr/g/srtools/RawPrmtrDisp) /tmp/scan.req (result of /usr/g/srtools/ScanPrmtrDisp) /tmp/recon.req (result of /usr/g/srtools/ReconPrmtrDisp) ps.info (result of ‘ps –efl’) df.info (result of ‘df’) hw.info (result of ‘hinv’) dasm.info (result of ‘showdasm’) SHOWPRODS (result of ‘showprods’) /VERSION 3–3 SYSTEM CT HISPEED SERIES ADVANCED DIAGNOSTICS PROPRIETARY TO GENERAL ELECTRIC COMPANY REV 13 3-1-4 2202119 How to Collect Log (SnapState) (continued) Table 3–1 Log Files Category Generator Directory Filename Description /usr/g/service/log/ generatorTest.log It is log file of generatorTest. /usr/g/service/log/ JEDIerror.log It is made by ‘Error log retrieve’ in generatorTest. It includes only retrieved data from JEDI. /usr/g/service/log/ JEDIerror.log.detail It is made by ‘Error log retrieve’ in generatorTest. It is derived from JEDIerror.log with detail error description. /usr/g/service/log/ SvTubeUsage.log Tube Usage file of current one. SvTubeUsage.log.old1 Last Tube Usage file. There are files from old1 to old5. It means system can have last 5 tube usage log files. New one will be created by using ‘create’ function. /usr/g/service/log/SvTubeSpits01/ 0x.log Tube Spits Log file. 01.log is spits log file for 1st 10kslices. Sequential files, ex, 02.log, 03.log, etc will be created along with slice increase. SVTubeSpits02 directory will be created when TubeSpitsLog are created by using ‘create’ function. Bad Raw Log /usr/g/service/log/SvBadRaw01/ 0x.log Bad Raw log file. Management is same as Tube Spits Log file. Do not have create functionality. Results of Diagnostics /usr/g/service/log/ das_test_log Log of DAS Transfer Test /usr/g/service/log/ postrectest_image_err.log* Log of Auto Post Recon Test /usr/g/insite/ modemsetup.log Log of Modem setup (result of installmodem) /var/adm/ pppd.log* PPP daemon /usr/g/insite/ProDiags/ ProDiags_.log Prodiags /usr/g/insite/ProDiags/healthpage/ results directory. Healthpage (does not produce any logs but the healthpage itself is generated in) /usr/g/service/log/ poweron.log Power On Test Log. Overwritten when power on test is proceeded. /usr/g/diag/log hw_TestLogs Summary of Off LineTest result. Results are appended, not overwritten. This file is automatically divided and create .bak file when the size is over 50kByte at the start timing of Off Line Test. /usr/g/service/log/ gesys_hostname.log Error log file which can be observed on Message Viewer. This file is automatically divided and create compressed gz file when the size is over 3 or 4 MBytes at bootup. /var/adm/ install.report Log file of software installation. /var/adm/ SYSLOG System Log file which is related to OS. Tube Core File /usr/g/ctuser/logfiles Log files which is related to IOS. 3–4 SYSTEM PROPRIETARY TO GENERAL ELECTRIC COMPANY CT HISPEED SERIES ADVANCED DIAGNOSTICS REV 13 3-1-5 2202119 How to Display History Log (For V/R 4.13 or later) The history log files are stored under /usr/g/config/history directory. Displaying these files allows you to understand what kind of activities has been done on the system. The history log to be stored: D D D D D D D D D D D D D D D D D CTnumAdj.log alignment.log serviceCal.log DASlinear.log gsag.log serviceMenu.log DASxfer.log heatSoak.log updateLog.log MTFsurvey.log iipenv.log.Z userCal.log SelectSaveState.log jediDiag.log warmUp.log TubeProcedure.log postRecon.log To display the contents of these file, use tail command. Following is an example for alignment.log. Tail command with –xx option will be useful to see latest status. xx is the number of lines from the bottom of the file. $ tail –10 alignment.log Thu Feb Thu Feb Thu Feb Thu Feb Thu Feb Thu Feb Thu Feb Thu Feb Thu Feb Thu Feb 1 11:40:52 2001;Phantom centering;Move Phantom RIGHT 0.13 mm (< 0.15) 1 11:40:56 2001;Air scan;start 1 11:41:16 2001;alignment.log;End 1 14:30:47 2001;alignment.log;Start 1 14:30:58 2001;Air scan;start 1 14:32:47 2001;Phantom centering;Move Phantom DOWN 0.73 mm (< 0.15) 1 14:32:47 2001;Phantom centering;Move Phantom RIGHT 1.55 mm (< 0.15) 1 14:33:31 2001;Phantom centering;Move Phantom DOWN 0.27 mm (< 0.15) 1 14:33:31 2001;Phantom centering;Move Phantom RIGHT 0.12 mm (< 0.15) 1 14:33:49 2001;alignment.log;End 3–5 SYSTEM PROPRIETARY TO GENERAL ELECTRIC COMPANY CT HISPEED SERIES ADVANCED DIAGNOSTICS REV 13 3-1-6 2202119 How to Use MOD You have to initialize MOD if it is new one. You can initialize either mkfsMOD command or Initialize MOD under Raw Functions. You can not initialize Image MOD by using the above command to avoid accidental image data loss. Before you use MOD, you should mount MOD using mountMOD command. $ mountMOD Then MOD is mounted on /MOD directory. You can copy files or log to MOD using standard unix command. Before eject MOD, you should unmount MOD using unmountMOD. $ unmountMOD You can not unmount it if you are working on /MOD directory. In this case, change the working directory and retry. 3-1-7 How to Display Cooling Trend At the present, no tube anode/case temperature are not displayed on the screen. However, you can set it by running the following scripts after perform application shutdown. $ /usr/g/srtools/setCoolingTrend Then start up the system. After start–up, enter the following command to display console window. $ startconsole Tube Anode and Case temperature is displayed on the console window. Note: This is for debug use only and not designed for customer use. To turn it off, run the following scripts after application shutdown and start up the system again. $ /usr/g/srtools/unsetCoolingTrend 3–6 SYSTEM PROPRIETARY TO GENERAL ELECTRIC COMPANY CT HISPEED SERIES ADVANCED DIAGNOSTICS REV 13 2202119 Using the Tube Temperature (For Version 6.xx or later system) The tube temperature view can be used without performing application shutdown. 1. Select Service –> shell. 2. Enter tubeTempViewer. The following window appears so that you can find about current Anode and Case temperatures. 3. Click on Quit to terminate the Tube Temperature Viewer. 3-1-8 How to Rise the Tube Temperature to 100 % To reset a cooling algorithm, rise the tube temperature (Case and Anode) to 100%. Enter the following command in shell. $ TubeTempMax Note Once the temperature rises to 100%, you must wait approximately 20 minutes for scanning. 3-1-9 How to Install SMPTE and QA Images There is functions to install these images for reference. Select Install SMPTE from Utility Menu on Service Desktop. Then both images are installed. SMPTE Image Exam# 1000, 1 image, Set WW = 1024 WL = 300 to see. QA Images Exam# 273, 6 images. Note: In fact this is not right image for QA Images. 3–7 SYSTEM PROPRIETARY TO GENERAL ELECTRIC COMPANY REV 13 CT HISPEED SERIES ADVANCED DIAGNOSTICS 2202119 3-1-10 How to Change AutoVoice, X–ray Buzzer Sounds On Service desktop, select Audio Control under Service Adjustment Menu. You can adjust the following parameters. X–ray Buzzer: Volume, Pitch, Length Alert Buzzer: Volume, Pitch, Length AutoVoice: Volume CD sound: Volume 3-1-11 How to Change Image Direction On Service desktop, select User Preferences under Utilities Menu. You can change the following parameters. * is default. AXIAL IMAGE DIRECTION: From Gantry Front, From Gantry Back, *From Head Front, From Head Back APEX SCOUT DIRECTION: Gantry Upper, Gantry Lower, *Head Upper, Head Lower LATERAL SCOUT DIRECTION: GAntry Left, Gantry Right, *Head Left, Head Right After you change this preferences, you need to restart the system to take an effect. 3-1-12 How to Change Image Annotation There are four levels of annotation Full, Partial, None, Customize You can change it in Annotation Level on Display Preferences on Display desktop. For information, the followings are site specific one and normally they are set during LFC or reconfig by service engineer. It is stored in /usr/g/config/ host.cfg. Hospital Name, Station Name 3–8 SYSTEM PROPRIETARY TO GENERAL ELECTRIC COMPANY CT HISPEED SERIES ADVANCED DIAGNOSTICS REV 13 2202119 3-1-13 How to Change Display Gamma Sometimes you need to change display gamma level to make film image close to what you see on the display. $ gamma Default gamma value is 1.7 and you may need to change it to value between 1.0 and 1.7. You need to be root user to change it. 3-1-14 How to Restart Process You can confirm the state f process by using cupShutdown command. cupShutdown command output is displayed on the console window. So before doing this command, you should start the console window using ‘startconsole’ command. To check state of precess: $ cupShutdown dump To stop the process $ cupShutdown stop To start the process $ cupShutdown start To restart (stop & start) process $ cupShutdown restart Keep in mind that some of process such as UIF process may not start up correctly. All the process except patient UIF may be able to be restarted by this command. 3-1-15 How to Delete All Recon Queues Sometimes we need to clean up all recon queues for some troubleshooting. Please keep in mind that this operation deletes all the recon queues including prospective, retrospective recons. $ cd /usr/g/reon_q $ rm –f reon_q* And restart the system. 3–9 SYSTEM PROPRIETARY TO GENERAL ELECTRIC COMPANY REV 13 CT HISPEED SERIES ADVANCED DIAGNOSTICS 2202119 3-1-16 How to Change Exhibition Mode, Stand Alone Mode This is special mode for exhibition or demo console. This feature is not fully guaranteed, so please use it on your own risk. And DO NOT TRY it on the customer machine, or you will be in trouble. You can control table/gantry and pretend to take scan (DynePlan etc.). But no x–ray is exposed and no autoview is done. To turn it on, $ /usr/g/srtools/setWithoutAutoView And restart the system. To turn it off, $ /usr/g/srtools/unsetWithoutAutoView And restart the system. To turn it on, $ /usr/g/srtools/setScanSimulator And restart the system. To turn it off, $ /usr/g/srtools/unsetScanSimulator 3–10 SYSTEM PROPRIETARY TO GENERAL ELECTRIC COMPANY CT HISPEED SERIES ADVANCED DIAGNOSTICS REV 13 2202119 3-1-17 How to Perform Z–axis Collimation Diagnostics You can check if the collimator correctly moves in Z–axis direction. 1. Move the mouse in the shell window, then type the following responses to the indicated prompts: collimatorDiag > Collimator Works! > Verify that: – The aperture moves smoothly. – The collimator performs initial operation: The drive motor pulley rotates CW 3 times, then CCW 6 times, and lastly CW 3 times, then the aperture stop moving. – “Collimator Works!” is displayed. > exit (To terminate the unix shell window.) Collimator Z–axis drive motor 3–11 SYSTEM PROPRIETARY TO GENERAL ELECTRIC COMPANY blank CT HISPEED SERIES ADVANCED DIAGNOSTICS 2202119 3–12 SYSTEM CT HISPEED SERIES ADVANCED DIAGNOSTICS PROPRIETARY TO GENERAL ELECTRIC COMPANY REV 11 2202119 SECTION 4 – IRIX GUIDE NOTICE This Section for Reference Only Not under Revision Control 4-1 INTRODUCTION Do not be afraid to try an old Sun UNIX command. Some of these still work in the SGI environment. Conventions Bold Face: Cross referenced links and system messages or prompts. Italics: Variables you need to fill the real thing in for (e. g., filename). Normal: Command syntax, purpose descriptions and paths. No path – means that the executable is contained in the usr/g/bin directory and can be executed from anywhere. (login useraccount) indicates who you have to be to perform the command listed, when none is indicated, you can run the command from any user account. Table 4–1 User Accounts and Passwords User Account Password insite 2getin root #bigguy ctuser (OC Only) suisei. service no password 4–1 SYSTEM CT HISPEED SERIES ADVANCED DIAGNOSTICS PROPRIETARY TO GENERAL ELECTRIC COMPANY REV 11 4-2 2202119 IRIX OPERATING COMMANDS Table 4–2 Irix Operating Commands Command Purpose !! Repeat last command issued (see history). !X Repeat command indicated by number for X. (see history). !X Repeat last command issued from history list which begins with letter(s) indicated by X (see history). +c Terminate current process. +d Logout of user account. +z End input. alias Display a list of all aliased commands. arp –a Display current arp (address resolution protocol) cache in memory. Will let you know who is in the current network routing table. cd /directoryname/directoryname/ . . . Change current working directory to that specified in /directoryname/directoryname/ . . . chmod XXX filename Change the permissions to XXX for filename. XXX is an octal number whose value determines read, write and executable status bits for a files permissions. drwxrwxrwx owneraccount size date filename – 111 111 111 ==> chmod 777 filename The first four bits are owner permissions, second are group permissions, and the third is everyone’s permissions. chown useraccount filename Change filename ownership to useraccount. cp /path/filename /path/filename Copy the designated file to the destination indicated. date MMddhhmmyy Set the date and time as specified: MM is month, dd is day, hh is hour, mm is minute, yy is year. Must be root. df –k Display disk partition sizes. Will also display mounted file systems. dkstat Provide ongoing I/O statistics for all SCSI devices. du Display block size of current directory. du –sk Display block size of current directory and its contents. eject SCSI Id Ejects the SCSI Id specified. find / –name “filename” –print Locate filename and print its path searching the entire directory structure for which this account has permissions (login as root to catch them all). 4–2 SYSTEM CT HISPEED SERIES ADVANCED DIAGNOSTICS PROPRIETARY TO GENERAL ELECTRIC COMPANY REV 11 2202119 Table 4–2 Irix Operating Commands (continued) Command Purpose fsck Run disk maintenance, answer yes to all questions it asks. If it asks questions, reboot when it is complete and repeat until it runs clean (login root). If system boots to single user UNIX (#): #cd /etc #fsck Output – questions are likely. #reboot (see cd). ftp internet address File transfer protocol. Will connect to host designated by internet address. Login will be required. Most file system navigation will function normally. Other commands available include: • get filename–transfer filename from internet address to current directory on log host. • put filename–transfer filename to internet address from log host. • bye–logout of internet address and exit ftp. • ?–display all available commands fx Disk utility. Can be used to slip bad blocks. See Using fx to Slip Bad Blocks. grep text filename Search filename for any occurrences of text and print the line that contains it. Can also be used as a destination for a pipe as in: ps –ef | grep text history Provides a list of all commands issued since login for current account. Use in conjunction with repeat command feature (!) to reissue same command. kill processid Terminate process indicated by processid (see ps – ef). killall processname Sends a shutdown signal to all software processes e if no process name is specified or to the named process. ln –s destinationfilename filename Create a symbolic link between destinationfilename and filename. All output from filename will go to destinationfilename. ls –alR List current and all subdirectory contents. mkdir directoryname Create directoryname as a branch from the current directory. more textfilename Show the contents of textfilename a page at a time. Can also act as the destination of a pipe as in: tail –100 SYSLOG | more. 4–3 SYSTEM CT HISPEED SERIES ADVANCED DIAGNOSTICS PROPRIETARY TO GENERAL ELECTRIC COMPANY REV 11 2202119 Table 4–2 Irix Operating Commands (continued) Purpose Command mount device directory This will display a table of mounted file systems with no device directory designation. By specifying a device and directory name, you can create a virtual partition that will allow you to work with the media in the device. (see umount) netstat –ain View network performance statistics. Collision rates from 3 to 5% will cause system performance degradation. netstat –r View physically connected hosts on your net and the current network routing tables. Destination – direct connection (no router) Gateway – gate to destination Flags: • U – up • H – host • G – gateway • Note: current log host will show no flags. refcnt – current number of active uses per route Use – number of packets sent per route nvram Display current prom monitor settings. ping Host Function is similar to spray. Send a 64 byte packet to Host and have it return that packet. Provide statistics on status of transmission. prtvtoc Print out the root disk label. prtvtoc /dev/rdsk/dksod[n]s0 Display partitions, sizes and SCSI controller information for SCSI disk. Must be root. ([n] is the SCSI device number). ps –ef Display running software processes. ps –ef | grep ‘whoami‘ | more Display all processes your current user account owns that are running. pwd Display current directory path. reboot Shutdown and restart IRIX. rm –r directoryname Delete directory contents and then directoryname. rm filename Delete filename. sum filename This command will generate a checksum value for filename. Use it to verify that the file you have remote copied or transmitted is the same as the original. Sum will produce the same result if it is. swap –s View available system swap space. tail –f textfilename Displays an ongoing update of textfilename. Useful for observing system startup as in: tail –f gesys__OC0.log 4–4 SYSTEM CT HISPEED SERIES ADVANCED DIAGNOSTICS PROPRIETARY TO GENERAL ELECTRIC COMPANY REV 11 2202119 Table 4–2 Irix Operating Commands (continued) Command Purpose tail –X textfilename Show the last X lines of textfilename. telnet internetaddress Attempt to log into remote host designated by internetaddress. top –i second Display processes having the highest CPU usage updating every second. touch filename Create filename of zero length. umount filesystemname or directoryname This command will release a directory or file system. Use it to release a 3rd party mount chewing that is virtually chewing up root partition space. See mount and df. w What user accounts are active and what actions are they performing. Will show how long the ctuser c–shell has been up. whoami Print current userid. 4–5 SYSTEM CT HISPEED SERIES ADVANCED DIAGNOSTICS PROPRIETARY TO GENERAL ELECTRIC COMPANY REV 11 4-3 2202119 LOG FILES Table 4–3 Log Files Log File Host Path Description analysis.0 OC /var/adm/crash Provides a summary of all of the CPU activity, failure reason and executable involved in a CPU Panic. View it using more. aqslog OC /usr/g/ctuser/logfiles Acquisition server log file. View it using tail or more. arslog OC /usr/g/ctuser/logfiles Archive server log file. View it using tail or more. browserlog OC /usr/g/ctuser/logfiles Browser client log file. View it using tail or more. dbrlog OC /usr/g/ctuser/logfiles Image database read server log file. View it using tail or more. dbwlog OC /usr/g/ctuser/logfiles Image database write server log file. View it using tail or more. dcslog OC /usr/g/ctuser/logfiles Dicom server log file. View it using tail or more. dks1d1s[n] OC /etc/fscklogs Contains the results of the fsck performed at startup for SCSI device indicated by [n]. (see CT/i Devices). gesys__OC0.log OC /usr/g/service/log This is the same log you would get at in applications by hitting the message bar. Examine it at IRIX level using the viewlog command. Just about everything reports here, so it is the logical place to start troubleshooting. host.cfg OC /usr/g/config Host configuration file. Use more to view this file. Not all parameters are used from this file. 4–6 SYSTEM CT HISPEED SERIES ADVANCED DIAGNOSTICS PROPRIETARY TO GENERAL ELECTRIC COMPANY REV 11 2202119 Table 4–3 Log Files (continued) Log File Host Path Description imslog OC /usr/g/ctuser/logfiles Image server log file. View it using tail or more. INFO OC /usr/g/config/INFO This file contains the system environment information. Use more to examine its contents to verify your answers to the installation procedure in reconfig. netlog OC /usr/g/ctuser/logfiles Network server log file. View it using tail or more. prslog OC /usr/g/ctuser/logfiles Print server log file. View it using tail or more. userprefs.cfg OC /usr/g/config Contains hardware configuration information supplied by you during the software LFC and by the system during initial polling of devices in the system. View it using more. Use grep to search for specific parameters. grep scanDiskDevice ScanHardware.cfg SvTubeUsage.log OC /usr/g/service/log Contains technique and scan types used on system since last software LFC. Use scanReport to view it. SdCRHosts OC /usr/g/ctuser/Prefs This file contains all of of the hosts adopted at applications. Use it to find the IP addresses of other hosts you can telnet to, like AWWs. SYSLOG OC /var/adm This is where IRIX hardware and operating system software errors are reported. Here you will find the reasons for CPU malfunctions, SCSI errors, and indications of system start ups. Use more or tail to view this text file. 4–7 SYSTEM CT HISPEED SERIES ADVANCED DIAGNOSTICS PROPRIETARY TO GENERAL ELECTRIC COMPANY REV 11 2202119 SCRIPTS AND EXECUTABLES 4-4 Table 4–4 Scripts and Executables Script/Executable Host Path Purpose cleanMon OC No Path login: ctuser Shut applications and IRIX down. See shutdown procedure for apps only. endsession OC No Path Logout of current desktop and return to the login window. exitScript OC No Path login: ctuser Checks the status of applications and executes endsession if apps are down. gattention message OC No Path Put a gatttention box on the monitor containing the text in message. halt OC No Path login: root Shut operating system software down. hinv OC No Path Display hardware configuration information. For more information, use the hard_Conf command. mkfsMOD OC No Path login: root Create a new file system on the MaxOptics disk side currently installed in the drive. This will clear out everything on the disk. mountMOD OC No Path Make the MaxOptics a virtual partition on the disk drive. Normal file functions to the /MOD directory (like cp, cd, ls, etc) will now function on the optical drive. reconfig OC No Path login: root Change site info, regen databases, etc. SnapState OC No Path Store all logs to the MOD for later review. Run to assist with resolution of software issues. showdasm OC No Path Path: ctuser This will query the DASM and provide you with configuration information for it. 4–8 SYSTEM CT HISPEED SERIES ADVANCED DIAGNOSTICS PROPRIETARY TO GENERAL ELECTRIC COMPANY REV 11 2202119 Table 4–4 Scripts and Executables (continued) Script/Executable Host Path Purpose showprods | grep NP OC No Path List the revision of the system software. startMon OC No Path login: ctuser Start applications processes. start_SMPTE OC No Path login: ctuser Installs the SMPTE pattern in the browser. unmountMOD OC No Path Release the MaxOptics MOD’s virtual partition. viewlog OC /usr/g/insite/bin login: insite Display gesys__OC0.log with viewing controls. 4–9 SYSTEM CT HISPEED SERIES ADVANCED DIAGNOSTICS PROPRIETARY TO GENERAL ELECTRIC COMPANY REV 11 4-5 2202119 VI EDITOR Table 4–5 vi Editor Command Effect vi filename Enter vi editor and load filename for editing. h Move cursor left one character. Cannot be in insert character mode; exits this mode and returns to cursor control mode. j Move cursor down one line. Cannot be in insert character mode; exits this mode and returns to cursor control mode. k Move cursor up one line. Cannot be in insert character mode; exits this mode and returns to cursor control mode. l Move cursor right one character. Cannot be in insert character mode; exits this mode and returns to cursor control mode. i Insert characters where the cursor is. Hit to exit insert character mode. a Insert characters after the current cursor position. Hit to exit insert character mode. o Insert characters on the next line. Hit to exit insert character mode. :q! Quit without saving changes. ZZ Save changes and exit. x Delete current character. dd Delete current line. :w Save. :wq Save and exit. 4–10 SYSTEM CT HISPEED SERIES ADVANCED DIAGNOSTICS PROPRIETARY TO GENERAL ELECTRIC COMPANY REV 5 2202119 SECTION 5 – SOFTWARE STRUCTURE 5-1 SOFTWARE STRUCTURE DIAGRAM Illustration 5–1 Software Structure Diagram UIF e/r IOS event_router ImageReceive RTImageReceive ScanReconMgr RTScoutReceive recon.req Trend/Forecast ReconCtrl acq.req Cooling DMA AcqCtrl scan.req ReconJob ScanCtrl Recon Engine NPRM, NPRS RawMgr RawLoad tgp_in tgp_out RawStore RawStoreSlave ScbxHandler Command Raw Disk Status Keyboard Scan Start / Stop / Abort keys DBPCI Board DAS Data Table/Gantry DAS 5–1 SYSTEM PROPRIETARY TO GENERAL ELECTRIC COMPANY CT HISPEED SERIES ADVANCED DIAGNOSTICS REV 5 5-2 5-2-1 2202119 SOFTWARE MODULE DESCRIPTION UIF: User Interface D ScanRx → Scan operations: New Patient → Patient information input View Edit → Scan change screen GraphicRx → Localize planning D ExamRxDisplay → Image Display AutoView AutoFilm D RetroRecon → Retro Recon View Edit, GraphicRetro 5-2-2 IOS: Imaging and Operating System This system registers image data from ImageReceive, RTImageReceive, or RTScoutReceive, to Informix Database, and displays them on Browser. Application → Browser, Viewer, and all which are started on the Browser. Server → imserver (vacant image space) dbserver (image registration) arserver (Archive: save/restore to/from MOD) prserver (Filming) netserver (Network) 5-2-3 ScanReconMgr: Scan Recon Manager ScanReconMgr controls Cooling, Scan, Raw data, or Recon. Functions D Communicates with external subsystems such are UIF (User Interface), applications, etc., according to predetermined protocols. D Converts parameter blocks made and sent from UIF, applications, etc. into the parameter blocks (ScanPar, ReconPar, ToolPar, or RAW Par) which are used by each subsystem controller. D Communicates with each subsystem controller sequentially, using the parameters described above. D Interfaces messages sent from the Scan/Recon subsystems to external subsystems D Performs other functions. 5–2 SYSTEM PROPRIETARY TO GENERAL ELECTRIC COMPANY CT HISPEED SERIES ADVANCED DIAGNOSTICS REV 5 5-2-4 2202119 ScanCtrl: Scan Control ScanCtrl controls the keyboard and Table/Gantry, and performs scans, by sequentially controlling tgp_in, tgp_out, Cooling, Scan Box, etc. Functions D Assigns scan parameters derived from ScanPar sent from ScanReconMgr to each slice (image). D Communicates with tgp_out, Cooling, and Scan Box for each slice (image). D Performs controls according to the operator scan key operations sent from the Scan Box. D Sends scan requests sequentially, synchronizing them with the timings of Inter scan delay, Voice. etc. D Sends Trend (HV On/Off) requests to Cooling, and sends Display update requests to UIF. D Sends scan progress status (Scan Start, End, Pause, etc.) to ScanReconMgr. D ScbxHandler Controls the keyboard operations (except AN and Ten keys). D tgp_in Receives status data from Table/Gantry. D tgp_out Sends commands to Table/Gantry. 5-2-5 tgp_in, tgp_out Sends or receives commands/status to/from the firmware of the scan subsystems (Table, Gantry, Tube, or Generator). Functions D Converts TgpPar into command packets for the TGP firmware. D Communicates with the TGP via serial lines. D Controls ISD. D Converts status data sent from the TGP into messages, and sends them to ScanCtrl or stores them to Error log file. 5–3 SYSTEM PROPRIETARY TO GENERAL ELECTRIC COMPANY CT HISPEED SERIES ADVANCED DIAGNOSTICS REV 5 5-2-6 2202119 AcqCtrl: Acquisition Control Functions D Decodes RawPar. D Executes Raw reserve requests. D Makes Raw data headers from RawPar sent form ScanReconMgr, and executes write requests of raw data files on the raw data disk. D Writes Cal/Decon data to raw data files. 5-2-7 RawMgr: Raw Manager RawMgr handles scan data, and controls RawCtrTable and address for raw data files. Functions D Saves/loads scan data to/from MOD. D Writes status of Reserve/Protect/RawDataStore of raw data to RawCtrlTable. D Writes Raw headers to raw data files. D Requests RawStore to store raw data files. D Requests RawLoad to load Cal/Decon data to Recon Engine. D Handles Protect/Unprotect for raw data files. D Extracts required information from each raw data file. 5-2-8 RawLoad: Raw Load Functions D Reads and loads raw data files from the raw data disk to the Recon Engine, according the Raw data load requests form RawMgr. 5–4 SYSTEM PROPRIETARY TO GENERAL ELECTRIC COMPANY REV 5 5-2-9 CT HISPEED SERIES ADVANCED DIAGNOSTICS 2202119 RawStore/RawStoreSlave Functions D When it (RawStore) receives Raw data store requests, it sets the DAS Buffer to a state where it (DAS Buffer) can accept raw data transfer. D When it receives transfer requests from the DAS Buffer device driver, it reads raw data files from the DAS Buffer and writes them to the raw data disk. D Requests extra data transfer to the DAS Buffer for Scan End. 5-2-10 ReconCtrl: Recon Control Functions D Enters ReconPar sent from ScanReconMgr into Recon Queue. D Controls the Recon Queue. D Controls On/Off of Recon wait protect for raw data files. D Controls Start, Cancel, etc. for ReconJob. 5-2-11 ReconJob: Recon Job Functions D Loads raw data files, Cal/Decon data, etc. to Recon Engine, according to the recon parameters from ReconCtrl. D Controls Recon Start, Cancel, etc. for the Recon Engine. 5–5 SYSTEM PROPRIETARY TO GENERAL ELECTRIC COMPANY CT HISPEED SERIES ADVANCED DIAGNOSTICS REV 5 2202119 5-2-12 ImageReceive, RTImageReceive, RTScoutReceive Functions D Reads image data from the Recon Engine. D Converts Image headers. D Requests image registration from the Image database control process. D ImageReceive: Image Receive Reads reconstructed images from the Recon Engine, adds headers to them, and stores them. D RTImageReceive: Realtime Image Receive Reads realtime–reconstructed (Smart Recon) images from the Recon Engine, adds headers to them, and stores them. D RTScoutReceive: Realtime Scout Receive Reads reconstructed scout images from the Recon Engine, adds headers to them, and stores them. 5-2-13 ToolCtrl: Tool Control This ToolCtrl is not a memory–resident program. The ScanReconMgr starts/ends this program, when the Service UIF requests the start/end of ToolCtrl. Functions D Executes off–line applications (except recon) such as service tools, which require the operation of the Recon Engine. D Loads data to the Recon Engine, saves the resulted data to the disk, etc. 5–6 SYSTEM CT HISPEED SERIES ADVANCED DIAGNOSTICS PROPRIETARY TO GENERAL ELECTRIC COMPANY REV 9 2202119 SECTION 6 – TROUBLESHOOTING 6-1 COMMUNICATION BETWEEN OC, TGP, OGP, CIF AND JEDI Communications between OC, TGP, OGP, CIF(DAS) and kV Control(JEDI) are tested during Wake–up communication sequence. You can diagnose the communication failure by utilize this functionality. Illustration 6–1 Communication Block Digram (1 ) OC (2 ) TGP (MP) OGP (6 ) (2 ) TGP (GP) 6-1-1 (3 ) (2 ) (4 ) (5 ) (3 ) (4 ) TGP (TP) kV Ctl (JEDI) CIF (DAS) Theory of Wake–up Communication (1) OC will start Wake–up communication by sending SysConfig CMD to TGP(MP). The purpose of this is to make sure about communication between each processors and to make each processors know the current system configuration. The starting timing is one of followings: – Just after OC is booted–up – Just after receiving SysConfig Request from TGP(MP). TGP(MP) keeps sending SysConfig Request to OC after booted–up until it receives SysConfig CMD from OC. – When OC found the contents of SysConfig is changed. If OC sends SysConfig CMD to TGP(MP) 3 times without successful, OC gives up communication and output error message on gesyslog as below. Failed to get response of system config. Code is 3 Even under this sitation, OC looks booted–up correctly except error above. But the time moving from New Patient Screen to Scan Edit Screen becomes extremely slowed down, which takes around 1 minutes. Also, Confirm button is never activated. 6–1 SYSTEM PROPRIETARY TO GENERAL ELECTRIC COMPANY CT HISPEED SERIES ADVANCED DIAGNOSTICS REV 9 6-1 2202119 COMMUNICATION BETWEEN OC, TGP, OGP, CIF AND JEDI (continued) (2) After TGP(MP) receives SysConfig CMD, it sends SysConfig CMD to TGP(GP), TGP(TP) and OGP and wait for the response from each processor. TGP(TP) and TGP(GP) reply for TGP(MP) by sending TG Status. (3) After OGP receives SysConfig CMD, it sends SysConfig CMD to kV Control(JEDI) and CIF(DAS).. OGP will wait for their reply. (4) KV Control(JEDI) and CIF will reply for OGP by sending TG Status. TG Status will include error infor- mation if there are. In case OGP cannot receive reply from kV Control or CIF in time, OGP put error information on the TG Status which will be send to TGP(MP). (5) OGP will send TG Status to TGP(MP) after it receives TG Staus both from kV Control and CIF or after timeout is detected to receive reply. (6) TGP(MP) will send TG Status to OC after it receives TG Status from all of TGP(TP), TGP(GP) and OGP or after timeout is detected to receive reply. 6-1-2 Error Messages and Troubleshooting Following is the error messages on gesyslog related to Wake–up communication. You can diagnose the communication failure from followings: Table 6–1 Code (Only on V/R5.00 or later) N/A 11–1010–03 11–1013–03 11–1012–03 20–0014–02 20–0030–07 30–0101–01 30–0101–02 20–1030–04 20–1030–06 Troubleshooting Error Messages (V/R4.13 or before) Explanation(Messages on V/R5.00 or later) Failure Failed to get response Failed to get response of system config. of system config. SP is not wake up. TGP(MP) did not receive any reply from OGP in response to SysConfig CMD. GP is not wake up. TGP(MP) did not receive any reply from TGP(GP) in response to SysConfig CMD. TP is not wakeup. TGP(MP) did not receive any reply from TGP(TP) in response to SysConfig CMD. JEDI Wakeup time out. OGP did not receive any reply from JEDI in response to SysConfig CMD nor JEDI Capability Request CMD. DAS Wakeup Time OGP did not receive any reply from CIF in Out. response to SysConfig. N/A Only for NX/i CIF received unspecified Qcal Ratio Data from OC on SysConfig. N/A Only for NX/i CIF could not receive all Qcal Ratio Data from OC on SysConfig. Mismatch DIPSW3 on OGP is mismatched with SysDIPSW(SW3) and sys- Config CMD which was sent from TGP. tem config. System Config Error OGP received unspecified SysConfig from TGP. OC <–> TGP 6–2 TGP <–> OGP TGP inside TGP inside OGP <–> kV Control OGP <–> CIF OGP <–> CIF OGP <–> CIF DIPSW3 setting of OGP Unmatched between OGP and OC software SYSTEM PROPRIETARY TO GENERAL ELECTRIC COMPANY REV 9 6-2 CT HISPEED SERIES ADVANCED DIAGNOSTICS 2202119 DAS DATA PATH Data from Detector is sampled synchronized with DAS TRIG signal. So DAS Data Path Trouble Shooting can be separated into DAS TRIG signal trouble shooting and DAS Data troube shooting. DAS TRIG signal is one of pre–requisite for DAS Data transfer. Refer to Illustration 6–2. 6-2-1 Pre–requisite Communication path from OC to CIF, through TGP, Slip Ring and OGP, should be confirmed to work before this trouble shooting. You can check the result of Wake–up communication for brief confirmation. 6–3 SYSTEM PROPRIETARY TO GENERAL ELECTRIC COMPANY CT HISPEED SERIES ADVANCED DIAGNOSTICS REV 9 6-2 6-2-2 2202119 DAS DATA PATH (continued) DAS TRIG Signal Troubleshooting There are 3 sources of DAS TRIG signal. 1st one is Azimuth encoder, 2nd is Cradle encoder, 3rd is OGP itself and last one is TGP. Each sources are selected by OGP and TGP depend on the Scan Type except TGP as below : Azimuth Encoder Cradle Encoder OGP TGP : selected on Axial Scan, Helical and Cine Scan : selected on Scout Scan ; selected on Stationary Scan : selected in case reset switch is pushed on TGP. As described above, DAS TRIG signal line is used to send RESET from TGP to OGP. If you encounter the trouble related to DAS TRIG signal, it is recommended to try various scan type and resetting OGP through TGP to identify which path is in failure as followings: (1) At first, proceed Stationary Scan using Off Line Scan. To make it simplify, data pattern can be set as DAS pattern, Rotor and X–ray Off and Current Azimuth is suggested. In case you found the failure, most probable failure is CIF and cabling between CIF and OGP. (2) Secondly, proceed Scout Scan using Off Line Scan. DAS pattern and Rotor Off is suggested. In case it does not work, try (4) to check signal line between TGP and OGP. If it does work, most probable failure is on Cradle Encoder and cabling between this and TGP. On TBLCON BD, there are not any components for DAS TRIG, but just connect from CN9 to CN1. On TBL BD, there are one component to change the signal type. (3) Next, proceed Axial Scan using Off Line Scan. DAS pattern and Rotor Off is suggested. In case it does not work, try (4) to check signal line between TGP and OGP. If it does work, most probable failure is on Servo Amp and cabling between Azimuth Encoder and TGP. On SUB BD there are not any components for DAS TRIG, but just connect from CN5 to CN2. (4) If you found problem in (2) or (3), try to reset OGP by pushing RESET switch on TGP and check OGP is corrected reset. After reset correctly, OGP shoud go to IDLE status, which is DS6 on OGP blinks. If OGP is not reset, DAS TRIG signal line between TGP and OGP has the problem. Between them, there are cable between TGP and Signal Brush board, Slip Ring, Signal CONN board and cable between Signal CONN and OGP. In this case, it is suggested to change Signal CONN board tentatively at first because there is another one on backside of Slip Ring, which is exactly the same and not used. 6–4 SYSTEM CT HISPEED SERIES ADVANCED DIAGNOSTICS PROPRIETARY TO GENERAL ELECTRIC COMPANY REV 9 6-2 2202119 DAS DATA PATH (continued) Illustration 6–2 LBB DAS Data and DAS TRIG Signal Flow Gantry Rotating CAM DDP DDP CIF DAS Data OC 401 CN1 402 CN3 RF XMT DTRF RF RCV J3 Optic fiber J2 J2 DASIFN J9 J3 DBPCI Optic fiber Axial/Helical/Cine Scan 403 CN2 OGP CN8 TGP CN6 SIG BRSH BD SIG CON SUB BD CN5 CN1 Servo Amp CN10 CN2 Azimuth Encoder CN7 CN11 Stationary Scan (DAS TRIG is generated by OGP) CN1 TBL BD CN2 CN1 TBLCON CN9 Cradle Encoder Gantry Stationary Scout Scan DAS TRIG Signal Applicable only to Twin Systems 6–5 SYSTEM Table PROPRIETARY TO GENERAL ELECTRIC COMPANY blank CT HISPEED SERIES ADVANCED DIAGNOSTICS 2202119 6–6 SYSTEM CT HISPEED SERIES ADVANCED DIAGNOSTICS PROPRIETARY TO GENERAL ELECTRIC COMPANY REV 9 6-2 2202119 DAS DATA PATH (continued) 6-2-3 DAS Data Troubleshooting For DAS Data trouble shooting, LED indication of each components are beneficial. it is recommended that to confirm data path on rotating side using stationary scan at first. Proceed rotation scan as next step to confirm data path on Slip Ring. Following is the LED status to help you identify whether DAS Data is coming or not. These status is based on Off Line Scan with Rotor Off, DAS Data as Normal mode. LED of RF RCV is not based on DAS Data but based on carrier wave. So RF Output LED does not change even in the case DAS Data is not available. But when carrier wave is sent correctly, DAS Data can be sent correctly in most of the case through Slip Ring because of error correction mechanism between DTRF and DASIFN. Refer to LED Description Section on Diagnostic TAB for detail of each LEDs DTRF Assy IDLE Scan +5V CONERR Lit Lit DSON Lit DSIN Lit DAS data does not come Lit Lit in short duration at first Lit in short duration at first FECERR CSTRB ACK Lit DXFER Lit Lit when cable from DAS is disconneted. RF XMIT(Only for ETC Slip Ring) LED IDLE Scan GREEN GREEN DAS data does not come RED when optic cable from DTRF is disconnected RF RCV(Only for ETC Slip Ring) Power LED AGC Center RF Output IDLE Scan GREEN (RED if RF Shoe is not connected) Lit if aligned in center Change depend on RF output power GREEN (RED if RF Shoe is not connected) Lit if aligned in center Change depend on RF output power 6–7 DAS data does not come GREEN (RED if RF Shoe is not connected) Lit if aligned in center Change depend on RF output power SYSTEM CT HISPEED SERIES ADVANCED DIAGNOSTICS PROPRIETARY TO GENERAL ELECTRIC COMPANY REV 9 2202119 6-2 DAS DATA PATH (continued) DASIFN IDLE +5V VLTN FECERR VSIZE DSRST DSCLR DAS data does not come Lit Lit Scan Lit Lit during scan (slightly lit if scan time is slow) DSREQ DSACK DSERR Lit during scan (slightly lit if scan time is slow) VIEW ENDNG FIFO1FF FIFO2FF Lit OFF during Scan (Lit when preparing Scan) Lit IDLE Scan DAS data does not come FPGACONFIG DBPCI T_OVER E_OVER TREQ ERR LINT RESET DSACK FIFO DBMEN DSREQ PCIREQ SLAVE slightly lit Lit slightly lit Blink 6–8 SYSTEM PROPRIETARY TO GENERAL ELECTRIC COMPANY REV 9 6-2 6-2-4 CT HISPEED SERIES ADVANCED DIAGNOSTICS 2202119 DAS DATA PATH (continued) Data Path Troubleshooting under Intermittent Failure In case DAS data itself is coming to OC with errors below, this means intermittent failure occurs during transferring raw data. (1) ‘Corrected View Number of BADRAW’ which means bad views were found but it was successfully corrected during reconstruction process. (2) ‘Uncorrected View Number of BADRAW’ which means bad views were found and it cannot be correct. Image was not displayed as the result. To identify the failure under this situation, data encoding/decoding theory is useful. Next page shows the summery of data format and what kind of information is appeared on LED or View End Mark. Please refer to DASIFN Section on Advanced Theory Of Operation for detail. In case you can find the bit errors constantly on specific position like below, failure should be on parallel data line. Example below indicates 3rd bit in one set of 16 bits is always zero 0000 1111 0222 3333 4444 5555 4666 7777 8888 9999 8aaa Parallel data line failure occurs on CIF, DTRF, DASIFN, DBPCI, cabling between CIF and DTRF or between DASIFN and DBPCI. It may happen most possibly on DBPCI because there are most complex circuit to handle parallel signal. 6–9 SYSTEM PROPRIETARY TO GENERAL ELECTRIC COMPANY blank CT HISPEED SERIES ADVANCED DIAGNOSTICS 2202119 6–10 SYSTEM CT HISPEED SERIES ADVANCED DIAGNOSTICS PROPRIETARY TO GENERAL ELECTRIC COMPANY REV 9 6-2 2202119 DAS DATA PATH (continued) Illustration 6–3 Data Path Troubleshooting under Intermittent Failure Bypassing Slip Ring Parallel Data from DAS Parallel Data to DBPCI DTRF Optic fiber Parallel Data DAS data/view RF XMT RF RCV DASIFN Optic fiber Encoded Serial Data VEM Encoded Data Check Bytes Encoded Data Parallel Data Check VEM Bytes DAS data/view Encoded DAS Data/view Errors encountered when encoding on DTRF VEM VEM : View End Mark Errors encountered when decoding on DASIFN FEC Encoding Error FEC Encoding Error Indicated on FECERR LED of DTRF Status is cleared when hardware reset Possible failure is on upper stream than DTRF (This means DASIFN received ENDNG from DTRF) Indicated on ENDNG LED of DASIFN Status is cleared when next scan start Possible failure is on upper stream than DTRF FEC Correction Error To identify which one is failed in Slip Ring and DTRF/DASIFN, you can bypass Slip Ring by following procedure. 1. Disconnect the optic fiber from DTRF. 2. Connect optic fiber which is from DASIFN directly with DTRF as showed above in dotted line. Be sure that Rotation Switch on lower backside of gantry is off and use stationary scan with current azimuth for testing. 6–11 (This means DASIFN cannot correct errors and this view cannot be used.) Indicated on FECERR LED of DASIFN and VEM Status is cleared when next scan start for LED VEM can be displayed using GSA. Possible failure is between DTRF and DASIFN. Most possibly failed on RF RCV including adjustment. View Size Error Indicated on VSIZE LED of DASIFN and VEM Status is cleared when next scan start for LED VEM can be displayed using GSA. Possible failure is between DTRF and DASIFN. Most possibly failed on RF RCV including adjustment Fatal Error Indicated on DSERR LED of DASIFN and VEM Status is cleared when next scan start for LED SYSTEM PROPRIETARY TO GENERAL ELECTRIC COMPANY blank CT HISPEED SERIES ADVANCED DIAGNOSTICS 2202119 6–12 SYSTEM CT HISPEED SERIES ADVANCED DIAGNOSTICS PROPRIETARY TO GENERAL ELECTRIC COMPANY REV 11 2202119 SECTION 7 – RING VALUE MEASUREMENT CT HiSpeed Series has the program which calculates named “Ring Value”. It takes from 0 to positive number (0 is best). It will become the reference number for measurement of Image quality. This section discusses the procedure how to measure the Ring Value. For example of usage, if customer has a problem of patient image quality, check the Active Mean DAS count using GSA, then according to the DAS Count, select the scan technique and measure the Ring Value. 1. Perform the phantom scanning with the following Scan Technique Table. Memorize the Exam number. Common Configuration: Large (42cm.) Phantom set to Scan center. 2i mode scan. Recon FOV is 50cm. Active Mean DAS Count KV TH mA Scan Time Measured Value Reference Value (It is not Spec.) 0 ∼ 500 120 3 100 1 < 3.988 500 ∼ 1000 120 3 130 1.5 < 3.543 1000 ∼ 1500 120 5 130 2 < 1.497 1500 ∼ 2000 120 5 150 2 < 0.762 2000 ∼ 120 5 200 2 < 0.504 2. Go to Service Desktop and open shell. 3. Type “phantomAnalysis” on the shell prompt, then program runs. 4. Press “Select Image” button to select the scanned image. See Illustration (next page). 5. Enter the phantom size as 42cm. See Illustration (next page). 6. Then press RV button. See Illustration (next page). 7. Scroll the right area, then Averaged Total Ring Value is found. See Illustration (next Page). 8. To close the phantomAnalysis screen, press “EXIT” button. See Illustration (next page). 7–1 SYSTEM CT HISPEED SERIES ADVANCED DIAGNOSTICS PROPRIETARY TO GENERAL ELECTRIC COMPANY REV 11 2202119 Illustration 7–1 Phantom Analysis Screen Step 7: Step 7: Scroll here. Record this number as Ring Value. Step 6: Step 5: Press this button. Enter “42” here. Step 4: Step 8: Press this button. Press this button. 7–2 SYSTEM CT HISPEED SERIES ADVANCED DIAGNOSTICS PROPRIETARY TO GENERAL ELECTRIC COMPANY REV 10 2202119 OPERATOR CONSOLE TABLE OF CONTENTS SECTION PAGE SECTION 1 – LED DESCRIPTION . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 1-1 1-2 1-3 1–1 BOARDS ON NEST . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . BOARDS ON CONNECTOR BOX . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . UNITS ON PERIPHERAL BOX . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 1-3-1 DASM–VDB (2191523) . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 1-3-2 DASM–LCAM (2191524) . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 1-3-3 DASM II–VDB (2191523–3) . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 1-3-4 DASM II–LCAM (2191524–2) . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . OTHER BOARDS . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 1–1 1–7 1–8 1–8 1–12 1–15 1–24 1–33 SECTION 2 – TEST PROGRAMS . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 2–1 1-4 2-1 2-2 2-3 SYSTEM POWER–UP SEQUENCE . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . POWER–ON TEST . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . OFF–LINE TEST . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 2-3-1 General . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 2-3-2 Running Off–Line Test . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 2-3-3 Viewing the Log File . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 2-3-4 Editing Off–line Test Program . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 2-3-5 Off–line Test Time . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . HARDWARE TO BE USED IN HARDWARE DIAGNOSTICS . . . . . . . . . . . . . . . . . . . . 2-4-1 Interactive Test . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 2-4-2 Off–line NPR Test . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 2-4-3 Off–line DBPCI Test . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 2–1 2–2 2–3 2–3 2–4 2–7 2–8 2–11 2–13 2–13 2–15 2–18 SECTION 3 – HOST PROCESSOR TROUBLESHOOTING . . . . . . . . . . . . . . . . . . . . . . . . . . . 3–1 2-4 3-1 3-2 3-3 3-4 3-5 PROBLEM DIAGNOSIS . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . DIAGNOSTIC TESTS . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . RECOVERING FROM SYSTEM CRASH . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . DISABLING THE SYSTEM MAINTENANCE PASSWORD . . . . . . . . . . . . . . . . . . . . . . INTEGRATED DIAGNOSTIC ENVIRONMENT (IDE) TESTS ON THE O2 . . . . . . . . 3–1 3–3 3–4 3–7 3–9 SECTION 4 – NPR (RECON ENGINE) TROUBLESHOOTING . . . . . . . . . . . . . . . . . . . . . . . . 4–1 4-1 4-2 4-3 4-4 OVERVIEW . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . DIAGNOSTICS FOR NPRM AND NPRS . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . DIAGNOSTICS FOR NPRM AND DBPCI . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . AUTO POST RECON TEST . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . i 4–1 4–2 4–15 4–21 OPERATOR CONSOLE CT HISPEED SERIES ADVANCED DIAGNOSTICS PROPRIETARY TO GENERAL ELECTRIC COMPANY blank 2202119 ii OPERATOR CONSOLE PROPRIETARY TO GENERAL ELECTRIC COMPANY CT HISPEED SERIES ADVANCED DIAGNOSTICS REV 10 2202119 SECTION 1 – LED DESCRIPTION 1-1 BOARDS ON NEST Table 1–1 LED NPRIF LED Description Description DS1 (PCORQ) Lights while the NPRIF board issues a request to the NPRM board to access the CM (Communication Memory). DS2 (PCOAK) Lights while NPRM returns Acknowledge of the request (described above) to NPRIF. (Both DS1 and DS2 LEDs light while NPRIF accesses the CM) DS3 (PGM0RQ) Lights while NPRIF issues a request to NPRM to access the GM (Global Memory). DS4 (PGM0AK) Lights while NPRM returns Acknowledge of the request (described above) to NPRIF. (Both DS3 and DS4 LEDs light while NPRIF accesses the GM) DS5 (PZ00RQ) Lights while NPRIF issues a request to NPRM to access the IM (DSP Internal Memory). DS6 (PZ00AK) Lights while NPRM returns Acknowledge of the request (described above) to NPRIF. (Both DS5 and DS6 LEDs light while NPRIF accesses the IM) DS7 (IMT2Z) Lights while NPRIF issues an interrupt to NPRM. DS8 (OINTRQ) Lights while NPRM issues an interrupt to the host processor. DS9 (BSERR) Lights when non–existent or non–defined addresses are accessed. DS10 (LSERR) Lights when LSERR# output from the PCI interface chip is active. At this time, Target Abort or Master Abort is occurring on the PCI bus. DS11 (NPRRST) Lights when NPRIF and NPRM/NPRS board(s) which are connected to NPRIF are reset. DS12 (VCC) Lights while DC power is supplied. 1–1 OPERATOR CONSOLE PROPRIETARY TO GENERAL ELECTRIC COMPANY REV 10 1-1 CT HISPEED SERIES ADVANCED DIAGNOSTICS 2202119 BOARDS ON NEST (continued) Table 1–2 LED PCIREQ Slave DBPCI LED Description Description Lights when the local bus access is requested by Slave or DMA during PCI access. Lights during PCI Slave access. DBMEN Lights when the DBM (DAS Buffer Memory) is enabled to take in DAS data. DSREQ Lights when the DASIFN board requests data transfer. DSACK Lights when notifying DASIFN that data has been transferred to the DBPCI board. FIFO Lights when the FIFO stores data whose quantity is half its capacity. LINT Lights when an INTA interrupt is issued to the PCI9060. Reset Lights while DBPCI is reset. TREQ Lights upon TREQ (Transfer Request). E_OVR Lights upon DAS Error Overflow. Goes off upon Reset. PWR Lights while +5 V power is supplied. 1–2 OPERATOR CONSOLE CT HISPEED SERIES ADVANCED DIAGNOSTICS PROPRIETARY TO GENERAL ELECTRIC COMPANY REV 10 1-1 2202119 BOARDS ON NEST (continued) Table 1–3 NPRM LED Description LED LED7–0 Description See Illustration 1–1. MS00 Lights when the master DSP is requesting access of GM. (Master DSP MS00 signal) MS10 Lights when the master DSP is requesting access of PM. (Master DSP MS10 signal) MS30 Lights when the master DSP is requesting access of i860cont, INTREQ REG, CM, or Comm. REG. (Master DSP MS30 signal) ACK1 Goes off during a wait cycle by the hardware. (Master DSP ACK signal) POWER Lights while 5 V power is supplied. PZ0AK Lights when the host processor (PCI) is accessing the master DSP. PGMAK Lights when the host processor (PCI) is accessing GM. PCMAK Lights when the host processor (PCI) is accessing CM. CMR Lights when the master DSP is accessing CM. ZXLM Lights when the master DSP is requesting access of the slave DSP PM. ZXIM Lights when the master DSP is requesting access of the slave DSP IM. Z0LBG Lights when the master DSP is using the GM bus. Z1LBG Lights when DSP#1 is using the GM bus. Z2LBG Lights when DSP#2 is using the GM bus. Z3LBG Lights when DSP#3 is using the GM bus. Z4LBG Lights when DSP#4 is using the GM bus. Z5LBG Lights when DSP#5 is using the GM bus. Z6LBG Lights when DSP#6 is using the GM bus. Z7LBG Lights when DSP#7 is using the GM bus. Z8LBG Lights when DSP#8 is using the GM bus. Z9LBG Lights when DSP#9 is using the GM bus. Z10LBG Lights when DSP#10 is using the GM bus. Z11LBG Lights when DSP#11 is using the GM bus. Z12LBG Lights when DSP#12 is using the GM bus. Z13LBG Lights when DSP#13 is using the GM bus. Z14LBG Lights when DSP#14 is using the GM bus. Z15LBG Lights when DSP#15 is using the GM bus. Z16LBG Lights when DSP#16 is using the GM bus. 1–3 OPERATOR CONSOLE CT HISPEED SERIES ADVANCED DIAGNOSTICS PROPRIETARY TO GENERAL ELECTRIC COMPANY REV 10 2202119 Illustration 1–1 NPRM LED DSP Status LED7–0 Boot Up Phase 1: Complete Boot Up DMA 2: Initialize DSP’ Register 3: Initialize Communication Memory 4: Initialize Internal Memory OFF ÉÉ ÉÉ 5: Set Config Status Block 6: Initialize Communication Register 7: Complete Boot Up Slave DSP 8: Initialize Link Port Register É ÉÉ É ÉÉÉÉ É ÉÉ É ON ON or OFF 9: Complete Boot Up Program Running / Idle Phase Idling Status ÉÉÉÉ É ÉÉÉ ÉÉ É ÉÉÉÉ É ÉÉÉÉ É É É ÉÉ É ÉÉ ÉÉ É ÉÉ ÉÉ ÉÉ É ÉÉ ÉÉ É ÉÉ ÉÉ É ÉÉ É ÉÉ ÉÉ É ÉÉ É ÉÉÉ ÉÉ É ÉÉ É ÉÉ ÉÉ ÉÉ É ÉÉÉÉ ÉÉ ÉÉ É (Blinking) Program Running Status Slave DSP’s Interrupt PCI’s Interrupt External DMA Running Link Port DMA Running LP5 LP4 LP2 LP0 Error ÉÉÉÉ É ÉÉ Bus Error Abort by PCI 1–4 OPERATOR CONSOLE CT HISPEED SERIES ADVANCED DIAGNOSTICS PROPRIETARY TO GENERAL ELECTRIC COMPANY REV 10 1-1 2202119 BOARDS ON NEST (continued) Table 1–4 NPRS LED Description LED Description F3–0 See Illustration 1–2. MS0 Lights when the slave DSP is requesting access of GM. (Slave DSP MS00 signal) MS1 Lights when the slave DSP is requesting access of PM. (Slave DSP MS10 signal) ACK Goes off during a wait cycle by the hardware. (Slave DSP ACK signal) HBG0 Lights when the slave DSP is not using the bus because the master DSP requests access of the slave DSP. Illustration 1–2 NPRS LED DSP Status LED (F3–0) Boot Up Phase 1: Complete Boot Up DMA 2: Initialize DSP’ Register 3: Initialize Private Memory 4: Initialize Internal Memory OFF 5: Initialize Link Port Register 6: Complete Boot Up ÉÉ ÉÉ É ÉÉ ÉÉÉ ÉÉ ÉÉ É ÉÉ ÉÉ ÉÉ ÉÉÉ ÉÉ ÉÉ É ÉÉ É Program Running / Idle Phase Idling Status ÉÉ ÉÉ ON ON or OFF (Blinking) Program Running Status External DMA Running Link Port DMA Running LP2 LP0 Error Bus Error Abort by Master DSP 1–5 OPERATOR CONSOLE PROPRIETARY TO GENERAL ELECTRIC COMPANY CT HISPEED SERIES ADVANCED DIAGNOSTICS REV 10 1-1 2202119 BOARDS ON NEST (continued) Table 1–5 PCI Backplane LED Description LED POWER ON Description Lights while power is supplied. Illustration 1–3 PCI Backplane PS3 (P11) (P12) POWER ON LED (P9) (P8) 1–6 OPERATOR CONSOLE PROPRIETARY TO GENERAL ELECTRIC COMPANY REV 10 1-2 CT HISPEED SERIES ADVANCED DIAGNOSTICS 2202119 BOARDS ON CONNECTOR BOX Table 1–6 DASIFN or DASIFN2 LED Description LED +5V VLTN Description Lights while +5 V Power is supplied. Lights while Taxi Violation occurs. FECERR Lights when a FEC Correction error occurs. VSIZE Lights when a View Size Correction occurs. DSRST Lights when _DSRST is active. DSCLR Lights when _DSCLR is active. DSREQ Lights when _DSREQ is active. DSACK Lights when _DSACK is active. DSERR Lights when _DSERR is active. VIEW Lights every transfer view. ENDNG Lights when receiving View END NG CMD. FIFO1FF Lights when FIFO1 is full. FIFO2FF Lights when FIFO2 is full. FPGACONFIG Lights during configurating the FPGA. 1–7 OPERATOR CONSOLE CT HISPEED SERIES ADVANCED DIAGNOSTICS PROPRIETARY TO GENERAL ELECTRIC COMPANY REV 10 1-3 1-3-1 2202119 UNITS ON PERIPHERAL BOX DASM–VDB (2191523) Table 1–7 DASM–VDB LED Description LED Image Ready Image Transfer Power Description Indicates that an image has been processed, and is stable at the VDB video output. Indicates that an image in the DASM is being processed and transferred to the VDB frame buffer. Note that the video image is not available at the output port during this internal transfer. This light indicates that the DASM–VDB is powered up. If this light does not illuminate at power–up, you should first check the power cable connections. CPU This light indicates that the DASM CPU is active and operating properly. It flashes continuously (blinks on an off) following power–up. SCSI This light indicates activity on the SCSI bus, such as commands sent or data received. Personality Module Interface This light indicates activity in the DASM–VDB personality module, such as data received. Illustration 1–4 DASM–VDB Image Transfer VIDEO Image Ready PIXEL CLOCK CAMERA CONTROL VDB Module DASM Module Power 1–8 CPU (1) SCSI (2) Personality Module (4) Interface OPERATOR CONSOLE PROPRIETARY TO GENERAL ELECTRIC COMPANY REV 10 1-3 CT HISPEED SERIES ADVANCED DIAGNOSTICS 2202119 UNITS ON PERIPHERAL BOX (continued) Powering On The following sequence occurs in the LED’s when the power switch is turned on: 1. The Power LED comes on. 2. The octal SCSI ID flashes briefly. The Least Significant Bit is next to the Power LED. Note that if the SCSI ID is zero, no LEDs flash. 3. The three LEDs which represent an octal value flash once and go out. 4. Once the power–up sequence completes, the DASM CPU LED (second light from left) blinks regularly, indicating that the CPU is active and functioning normally. Start Up Sequence When the DASM–VDB interface module is powering up, it performs start–up diagnostics and other related actions. At power–up, the DASM unit performs the following tests: D EPROM checksum test D MFP 68901 access test (the Multi Function Peripheral chip controls the serial port, timing, and I/O) D SCSI register access test D Static RAM test D Dynamic RAM test D DMA test When the DASM CPU LED blinks continuously at about two flashes per second, the initialization sequence is complete, and the continuous self–test is in progress. The self–test runs until a SCSI command (a write to block 0 on the DASM) is sent by the host. This test signals an error condition by blinking the CPU, SCSI, and Personal Module Interface LEDs in tandem, continuously. 1–9 OPERATOR CONSOLE CT HISPEED SERIES ADVANCED DIAGNOSTICS PROPRIETARY TO GENERAL ELECTRIC COMPANY REV 10 1-3 2202119 UNITS ON PERIPHERAL BOX (continued) Start Up Problems To report diagnostic conditions, the LEDs on the DASM–VDB front panel have a corresponding binary presentation. The illustration 1–4 shows the value assigned to each LED (CPU, SCSI, Personal Module Interface LEDs). DASM LED Error Codes Using LEDs 1, 2, and 4 (CPU, SCSI, Personal Module Interface LEDs), a binary code signals any of the conditions listed in Table 1–8. The Power LED is not used to report diagnostic conditions. The three LEDs permit a combined total of only seven error codes. To overcome this limitation, the codes are defined as a series of one or more patterns. Each pattern begins with all LEDs flashing briefly, to indicate the start of the number sequence that follows. For example, to display error code 12 (Failed SCSI Interface Test), the CPU LED displays the first digit (1), stopping briefly before the SCSI LED displays the second digit (2), as shown in Illustration 1–5. The display of each digit lasts approximately four times the duration of the initial binary “7” (that if, the flash of all LEDs). The patter then repeats. Only the significant digits for each error condition are listed in Table 1–8. Note: The first error stops the start–up sequence immediately. Illustration 1–5 LED Error Code Sequence + All Flash Short + “1” Long 1–10 = 12 “2” Long OPERATOR CONSOLE PROPRIETARY TO GENERAL ELECTRIC COMPANY REV 10 1-3 CT HISPEED SERIES ADVANCED DIAGNOSTICS 2202119 UNITS ON PERIPHERAL BOX (continued) Table 1–8 DASM Start–up Error Conditions Value Significance 1 Failed To Set Timer 2 Failed To Set Baud Rate 3 Failed To Access Receiver Status Reg. For Serial I/O 4 Failed To Start Refresh Clock 5 Failed In Set Up Of Serial I/O 6 Checksum Failed 7 Failed Static RAM Test 11 Failed I/O RAM Test 12 Failed SCSI Interface Test 13 Failed To Start VRTXE Operating System 21 Bus Error 22 Address Error 23 Illegal Instruction 24 Undefined MFP (MC68901) Interrupt 25 Zero–divide – Through Trace Trap Level 5 26 Chk, Trapv, Privilege, Or Trace Interrupt 31 Unknown Interrupt 1–11 OPERATOR CONSOLE CT HISPEED SERIES ADVANCED DIAGNOSTICS PROPRIETARY TO GENERAL ELECTRIC COMPANY REV 10 1-3 1-3-2 2202119 UNITS ON PERIPHERAL BOX (continued) DASM–LCAM (2191524) Table 1–9 DASM–LCAM LED Description LED Power Description This light indicates that the DASM–LCAM is powered up. If this light does not illuminate at power–up, you should first check the power cable connections. CPU This light indicates that the DASM CPU is active and operating properly. It flashes continuously (blinks on an off) following power–up. SCSI This light indicates activity on the SCSI bus, such as commands sent or data received. Personality Module Interface This light indicates activity in the DASM–LCAM personality module, such as data received. Illustration 1–6 DASM–LCAM Power 1–12 CPU (1) SCSI (2) Personality Module (4) Interface OPERATOR CONSOLE PROPRIETARY TO GENERAL ELECTRIC COMPANY REV 10 1-3 CT HISPEED SERIES ADVANCED DIAGNOSTICS 2202119 UNITS ON PERIPHERAL BOX (continued) Powering On The following sequence occurs in the LED’s when the power switch is turned on: 1. The Power LED comes on. 2. The octal SCSI ID flashes briefly. The Least Significant Bit is next to the Power LED. Note that if the SCSI ID is zero, no LEDs flash. 3. The three LEDs which represent an octal value flash once and go out. 4. Once the power–up sequence completes, the DASM CPU LED (second light from left) blinks regularly, indicating that the CPU is active and functioning normally. Start Up Sequence Start Up Sequence When the DASM–LCAM interface module is powering up, it performs start–up diagnostics and other related actions. At power–up, the DASM unit performs the following tests: D EPROM checksum test D MFP 68901 access test (the Multi Function Peripheral chip controls the serial port, timing, and I/O) D SCSI register access test D Static RAM test D Dynamic RAM test D DMA test When the DASM CPU LED blinks continuously at about two flashes per second, the initialization sequence is complete, and the continuous self–test is in progress. The self–test runs until a SCSI command (a write to block 0 on the DASM) is sent by the host. This test signals an error condition by blinking the CPU, SCSI, and Personal Module Interface LEDs in tandem, continuously. 1–13 OPERATOR CONSOLE PROPRIETARY TO GENERAL ELECTRIC COMPANY REV 10 1-3 CT HISPEED SERIES ADVANCED DIAGNOSTICS 2202119 UNITS ON PERIPHERAL BOX (continued) Start Up Problems To report diagnostic conditions, the LEDs on the DASM–LCAM front panel have a corresponding binary presentation. The illustration 1–6 shows the value assigned to each LED (CPU, SCSI, Personal Module Interface LEDs). DASM LED Error Codes Using LEDs 1, 2, and 4 (CPU, SCSI, Personal Module Interface LEDs), a binary code signals any of the conditions listed in Table 1–8. The Power LED is not used to report diagnostic conditions. The three LEDs permit a combined total of only seven error codes. To overcome this limitation, the codes are defined as a series of one or more patterns. Each pattern begins with all LEDs flashing briefly, to indicate the start of the number sequence that follows. For example, to display error code 12 (Failed SCSI Interface Test), the CPU LED displays the first digit (1), stopping briefly before the SCSI LED displays the second digit (2), as shown in Illustration 1–5. The display of each digit lasts approximately four times the duration of the initial binary “7” (that if, the flash of all LEDs). The patter then repeats. Only the significant digits for each error condition are listed in Table 1–8. Note: The first error stops the start–up sequence immediately. 1–14 OPERATOR CONSOLE CT HISPEED SERIES ADVANCED DIAGNOSTICS PROPRIETARY TO GENERAL ELECTRIC COMPANY REV 10 1-3-3 1-3-3-1 2202119 DASM II–VDB (2191523–3) DASM II–VDB LED Indicators The DASM II–VDB front panel has six LEDs, which are used for status and error information. These lights are illustrated below: PIF SCSI CPU PWR XMIT RDY 4 2 1 From left to right, the lights indicate the following: D RDY Image Ready light indicates that an image has been transferred, and is stable at the VDB video output. D XMIT Image Transmit light indicates that an image is being transferred from the Common Memory to the VDB Field Memory. Note that a printable video image is not available during an image transfer. D PIF Personality Interface light activity, in the VDB application, coincides with the image transmit function. D SCSI This light indicates the host is accessing the DASM via the SCSI bus, such as commands sent or data received. D CPU This light indicates that the DASM CPU is active and operating properly. It flashes continuously ( “blinks” on and off) following power–up. D PWR Power Light indicates that the DASM is powered. If this light does not illuminate at power–up, you should first check the power cord connections. 1–15 OPERATOR CONSOLE PROPRIETARY TO GENERAL ELECTRIC COMPANY CT HISPEED SERIES ADVANCED DIAGNOSTICS REV 10 1-3-3-2 2202119 Start–up Sequence When the DASM II–VDB is powering up, it performs start–up diagnostics and other related actions. At power–up, the DASM Controller performs the following tests: D EPROM checksum test D MFP 68901 access test (the Multi Function Peripheral chip controls the serial port, timing, and I/O) D SCSI register access test D Static RAM test D Dynamic RAM test D DMA test When the DASM CPU LED blinks continuously at about two flashes per second, the initialization sequence is complete. If an error occurs, the error condition is reported by blinking the CPU, SCSI, and PIF LEDs in tandem followed by an error code. Powering On The following sequence occurs on the front panel’s LEDs when the power switch is turned on: 1. The Power LED lights. 2. The octal SCSI ID flashes briefly. The Least Significant Bit is next to the Power LED. Note that if the SCSI ID is zero, no LEDs flash. 3. The three LEDs flash once and go out. 4. Once the power–up sequence completes, the DASM CPU LED (second light from right) blinks regularly, indicating that the CPU is active and functioning normally. 1–16 OPERATOR CONSOLE CT HISPEED SERIES ADVANCED DIAGNOSTICS PROPRIETARY TO GENERAL ELECTRIC COMPANY REV 10 2202119 1-3-3-3 Self–Test Options Once the start–up sequence is complete, the resident software reads the state of the DIP switch labeled SW1 on the DASM II–VDB board to determine whether further tests are enabled. To access SW1 you must first remove the top cover. Upon locating SW1 you will notice the numbers 0, 1, and 2 silk screened on the printed circuit board. The way Self–Test executes is determined by the setting shown below: Switch Position Continuous Mode Serial Loop– back Single Pass Single Pass w/ Memory Debug Mode 0 Closed Closed Open Open Open 1 Closed Open Closed Closed Open 2 Closed Closed Closed Open Open D Continuous Mode: Is the default setting. After executing the start–up diagnostic, the resident software will continuously run the VDB self–test. Self–test will continue until the first SCSI command is received by the DASM. D Serial Loop Test: In this mode the VDB tests the RS422 Driver and Receiver. Prior to executing this, a special loop–back connector on the front panel of the VDB, without the loop–back connector the test will fail. The loop–back connector is made by simply adding two wires to a 25–pin Male ‘D’ connector: (pin 8 to pin 9) and (pin 21 to pin 22). D Single Pass: The start–up diagnostics execute once, as described in 1-3-3-2 Start–up Sequence. Please be aware that when position 0 is open error and other messages encountered during start–up diagnostics are directed to the serial port. Otherwise the errors are encoded on the LEDs. D Single Pass w/Memory: Is controlled by Bit 2. When open the DASM exercises the entire DRAM during the start–up diagnostics. The Single Pass w/Memory test can take several minutes to complete, this is why it is normally disabled. D Debug Mode: When position 1 is open the program jumps to the I/O Monitor when a diagnostic error occurs. The I/O Monitor gives the basic tools to debug the hardware. Opening positions 0 and 2 allows the technician access to the start–up diagnostic suite via the serial port. 1–17 OPERATOR CONSOLE CT HISPEED SERIES ADVANCED DIAGNOSTICS PROPRIETARY TO GENERAL ELECTRIC COMPANY REV 10 1-3-3-4 2202119 Start–up Problem To report diagnostic conditions, the LEDs on the DASM II–VDB front panel have a corresponding binary representation. The illustration 1–7 below shows the value assigned to each LED. The section after the figure explains how the LEDs represent error codes. Note that this sections deals with error codes related to the DASM Controller, where Section 1-3-3-5, VDB Error Codes, explains the method used to report an error from the VDB diagnostic. DASM Controller LED Error Codes Using LEDs 2 and 4, a binary code signals any of the conditions listed in Table 1–10. The Power light and PIF LEDs are not used to report diagnostic conditions. The three LEDs permit a combined total of only seven error codes. To overcome this limitation, the codes are defined as a series of one or more patterns. Each pattern begins with all LEDs flashing briefly, to indicate the start of the number sequence that follows. For example, to display error code 12 (Failed SCSI Interface Test), the CPU LED displays the first digit (1), stopping briefly before the SCSI LED displays the second digit (2), as shown in Illustration 1–7. Illustration 1–7 LED Error Code Sequence + All Flash Short + “1” Long = 12 “2” Long The display of each digit lasts approximately four times the duration of the initial binary “7” (that is, the flash of all LEDs). The pattern then repeats. Only the significant digits for each error condition are listed in Table 1–8. Note: The first error stops the start–up sequence immediately. 1–18 OPERATOR CONSOLE PROPRIETARY TO GENERAL ELECTRIC COMPANY REV 10 CT HISPEED SERIES ADVANCED DIAGNOSTICS 2202119 1-3-3-4 Start–up Problem (Continued) Table 1–10 DASM Controller Start–up Error Conditions Value Significance 1 Failed To Set Timer 2 Failed To Set Baud Rate 3 Failed To Access Receiver Status Reg. For Serial I/O 4 Failed To Start Refresh Clock 5 Failed In Set Up Of Serial I/O 6 Checksum Failed 7 Failed Static RAM Test 11 Failed I/O RAM Test 12 Failed SCSI Interface Test 13 Failed To Start VRTXE Operating System 21 Bus Error 22 Address Error 23 Illegal Instruction 24 Undefined MFP (MC68901) Interrupt 25 Zero–divide – Through Trace Trap Level 5 26 Chk, Trapv, Privilege, Or Trace Interrupt 31 Unknown Interrupt 1–19 OPERATOR CONSOLE CT HISPEED SERIES ADVANCED DIAGNOSTICS PROPRIETARY TO GENERAL ELECTRIC COMPANY REV 10 1-3-3-5 2202119 VDB Error Codes The following sequence is used to signal an error during the VDB portion of the Self–test. First, all three LEDs blink together for the duration of a single pass. This requires approximately 10–15 seconds. Then the specific error code blinks twice before the next pass begins, with all three LEDs blinking together as before. The bit pattern of the error codes appears as a series of LEDs being turned on and off. The low order bit is first. When two LEDs blink together, the bit value is 1. When only one LED blinks, the bit value is 0. To see an example of an error code displayed in this way, do the following: D Remove the loop–back connector from the front panel of the DASM II–VDB. D SW 1 position 0 is closed. D SW 1 position 1 is open. D Now cycle the AC power on the DASM D When the first pass of the DASM self–test has completed, the LED display begins. The expected error is 5 (RS–422 port fail), and the LED sequence is: Least significant first: bit 0 = 2 LEDs on = 1 Value 1 bit 1 = 1 LED on = 0 bit 2 = 2 LEDs on = 1 Value 4 bit 3 = 1 LED on =0 Table 1–11 Serial Error Codes in LEDs LED sequence, from left to right Checksum 1211 checksum of EPROM Serial 2121 RS422 test–needs loop–back connector DMA_setup 1112 Tests DASM Block Image_verify 2112 tests full image transfer DASM Block 2222 nonspecific failure. SCSI to host is needed 1–20 OPERATOR CONSOLE CT HISPEED SERIES ADVANCED DIAGNOSTICS PROPRIETARY TO GENERAL ELECTRIC COMPANY REV 10 2202119 1-3-3-6 RUN–TIME Error Codes These codes may be found in the DASM Response Block byte 128, when the error bit (bit 2, where bit 0 is first) is set in Response Block byte 0. Only the first of multiple errors is stored in Response Block byte 128. Reading the Response Block clears the error. Note that the status “invalid command” is returned to the user directly in bit 0 of the SCSI status byte; it is not logged in the Response Block. Table 1–12 Error DASM Run Time Error Codes Hex Meaning General Error Codes E_PARAM 81 Bad parameter to valid command E_NO_FF 82 No 0xFF terminator in command E_TMO 83 Timeout E_PIF_SELF 84 Peripheral interface self–test error E_PIFNOTRDY 85 Peripheral device not ready E_OVRRUN 86 Data overrun E_UNDRUN 87 Data under run E_COM_LINK 88 Communications link error between DASM and PIF E_DRAM 8A Error in I/O RAM (Note: This is a warning, which is available in the trace buffer in the DASM response block. During a warning, byte 128 is not updated.) E_EPROM 8B EPROM checksum error E_MFP 8C Error in the MC68901 I/O and timer chip E_SBIC 8D Error in access to SCSI bus interface chip E_NOTIMER 8E No timer available (all in use) E_INTERN 8F Internal system software error E_INV_MSG B0 Invalid / unexpected message from device E_BAD_S B1 Invalid S–record (from load routine) E_ODD_ADR B2 Odd address passed to function E_BOUNDS B3 I/O request overlapped buffer boundary E_DIRECTION B4 I/O request direction is invalid E_NOT_NXT B5 I/O request for data is out of sequence E_AVAIL_CT B6 I/O request exceed available data count E_PARITY B7 Parity error E_PIF_REV B8 No PIF revision level supplied E_TIMER_ID B9 Timer id error (Continued) 1–21 OPERATOR CONSOLE CT HISPEED SERIES ADVANCED DIAGNOSTICS PROPRIETARY TO GENERAL ELECTRIC COMPANY REV 10 2202119 1-3-3-6 RUN–TIME Error Codes (Continued) Table 1–12 Error DASM Run Time Error Codes (Continued) Hex Meaning M_REJECTED 95 Message was ected by partner M_BADREPLY 96 Unexpected reply was received E_NOTREADY 97 Camera is not ready E_TIMEOUT 98 EXEC Function did not complete in time E_TOOLONG 99 Received telegram has too many characters E_UNEXPECTED 9A Laser camera replied with an unexpected telegram E_BADPARAM 9B Bad parameter from host found in CMDBLK VRTX Error Codes E_VRTX C1–F4 VRTX error range – C1 Task ID invalid – C2 No task control block available – C3 No Memory available – C4 No Memory block – C5 Mailbox in use – C6 Message of Zero – C7 Buffer full – C8 WAITC is in progress – C9 Invalid system call – CA Timeout – CB No Message present – CC Queue ID error – CD Queue Full – CE Partition ID error – CF Fatal initialization error – D0 No character present – D1 Invalid configuration parameter at Init – D2 Invalid parameter to PCREATE/PEXTEND – E0 No component vector table – E1 Invalid component (Continued) 1–22 OPERATOR CONSOLE CT HISPEED SERIES ADVANCED DIAGNOSTICS PROPRIETARY TO GENERAL ELECTRIC COMPANY REV 10 1-3-3-6 2202119 RUN–TIME Error Codes (Continued) Table 1–12 DASM Run Time Error Codes (Continued) Error Hex Meaning – E2 Invalid opcode for component – F0 No control block available – F1 Event flag group or semaphore ID error – F2 Tasks pending on event flag group or semaphore – F3 Event flag group or semaphore is deleted – F4 Event flag group already set or overflow 1–23 OPERATOR CONSOLE CT HISPEED SERIES ADVANCED DIAGNOSTICS PROPRIETARY TO GENERAL ELECTRIC COMPANY REV 10 1-3-4 1-3-4-1 2202119 DASM II–LCAM (2191524–2) DASM II–LCAM LED Indicators The DASM II–LCAM front panel has four LEDs, which are used for status and error information. These lights are illustrated below: PIF SCSI CPU PWR 4 2 1 From left to right, the lights indicate the following: D PIF Personality Interface light indicates a data transfer from the Common Memory to the LCAM circuitry. D SCSI This light indicates the host is accessing the DASM via the SCSI bus, such as commands sent or data received. D CPU This light indicates that the DASM CPU is active and operating properly. It flashes continuously ( “blinks” on and off) following power–up. D PWR Power Light indicates that the DASM is powered. If this light does not illuminate at power–up, you should first check the power cord connections. 1–24 OPERATOR CONSOLE PROPRIETARY TO GENERAL ELECTRIC COMPANY CT HISPEED SERIES ADVANCED DIAGNOSTICS REV 10 1-3-4-2 2202119 Start–up Sequence When the DASM II–LCAM is powering up, it performs start–up diagnostics and other related actions. At power–up, the DASM Controller performs the following tests: D EPROM checksum test D MFP 68901 access test (the Multi Function Peripheral chip controls the serial port, timing, and I/O) D SCSI register access test D Static RAM test D Dynamic RAM test D DMA test When the DASM CPU LED blinks continuously at about two flashes per second, the initialization sequence is complete. If an error occurs, the error condition is reported by blinking the CPU, SCSI, and PIF LEDs in tandem followed by an error code. Powering On The following sequence occurs on the front panel’s LEDs when the power switch is turned on: 1. The Power LED lights. 2. The octal SCSI ID flashes briefly. The Least Significant Bit is next to the Power LED. Note that if the SCSI ID is zero, no LEDs flash. 3. The three LEDs flash once and go out. 4. Once the power–up sequence completes, the DASM CPU LED (second light from right) blinks regularly, indicating that the CPU is active and functioning normally. 1–25 OPERATOR CONSOLE CT HISPEED SERIES ADVANCED DIAGNOSTICS PROPRIETARY TO GENERAL ELECTRIC COMPANY REV 10 1-3-4-3 2202119 Self–Test Options Once the start–up sequence is complete, the resident software reads the state of the DIP switch labeled SW1 on the DASM II–LCAM board to determine whether further tests are enabled. To access SW1 you must first remove the top cover. Upon locating SW1 you will notice the numbers 0, 1, and 2 silk screened on the printed circuit board. SW1 1 2 3 4 –Open– 2 1 0 SP The way Self–Test executes is determined by the setting shown below: Switch Position Single Pass Continuous Mode Single Pass w/Memory Debug Mode 0 Closed Open Closed Open 1 Closed Closed Closed Open 2 Closed Closed Open Open Note: SW1 position marked “SP” is not used. D Single Pass: Is the default setting, and is the only setting allowed when connected to a laser camera.The start–up diagnostics execute once, as described in 1-3-4-2 Start–up Sequence. D Continuous Mode: After executing the start–up diagnostic, the resident software will continuously run the LCAM self–test. Self–test will continue until the first SCSI command is received by the DASM. Please be aware that when position 0 is open error and other messages encountered during start–up diagnostics are directed to the serial port. Otherwise the errors are encoded on the LEDs. D Single Pass w/Memory: Is controlled by Bit 2. When setting to “open”, the DASM exercises the entire DRAM during the start–up diagnostics. The Single Pass w/Memory test can take several minutes to complete, this is why it is normally disabled. D Debug Mode: When position 1 is open, the program jumps to the I/O Monitor when a diagnostic error occurs. The I/O Monitor gives the basic tools to debug the hardware. Opening positions 0 and 2 allows the technician access to the start–up diagnostic suite via the serial port. 1–26 OPERATOR CONSOLE CT HISPEED SERIES ADVANCED DIAGNOSTICS PROPRIETARY TO GENERAL ELECTRIC COMPANY REV 10 1-3-4-4 2202119 Start–up Problem To report diagnostic conditions, the LEDs on the DASM II–LCAM front panel have a corresponding binary representation. The illustration 1–8 below shows the value assigned to each LED. The section after the figure explains how the LEDs represent error codes. Note that this sections deals with error codes related to the DASM Controller, where Section 1-3-4-5, LCAM Error Codes, explains the method used to report an error from the LCAM diagnostic. DASM Controller LED Error Codes Using LEDs 2 and 4, a binary code signals any of the conditions listed in Table 1–13. The Power light and PIF LEDs are not used to report diagnostic conditions. The three LEDs permit a combined total of only seven error codes. To overcome this limitation, the codes are defined as a series of one or more patterns. Each pattern begins with all LEDs flashing briefly, to indicate the start of the number sequence that follows. For example, to display error code 12 (Failed SCSI Interface Test), the CPU LED displays the first digit (1), stopping briefly before the SCSI LED displays the second digit (2), as shown in Illustration 1–8. Illustration 1–8 LED Error Code Sequence + All Flash Short + “1” Long = 12 “2” Long The display of each digit lasts approximately four times the duration of the initial binary “7” (that is, the flash of all LEDs). The pattern then repeats. Only the significant digits for each error condition are listed in Table 1–13. Note: The first error stops the start–up sequence immediately. 1–27 OPERATOR CONSOLE PROPRIETARY TO GENERAL ELECTRIC COMPANY REV 10 CT HISPEED SERIES ADVANCED DIAGNOSTICS 2202119 1-3-4-4 Start–up Problem (Continued) Table 1–13 DASM Controller Start–up Error Conditions Value Significance 1 Failed To Set Timer 2 Failed To Set Baud Rate 3 Failed To Access Receiver Status Reg. For Serial I/O 4 Failed To Start Refresh Clock 5 Failed In Set Up Of Serial I/O 6 Checksum Failed 7 Failed Static RAM Test 11 Failed I/O RAM Test 12 Failed SCSI Interface Test 13 Failed To Start VRTXE Operating System 21 Bus Error 22 Address Error 23 Illegal Instruction 24 Undefined MFP (MC68901) Interrupt 25 Zero–divide – Through Trace Trap Level 5 26 Chk, Trapv, Privilege, Or Trace Interrupt 31 Unknown Interrupt 1–28 OPERATOR CONSOLE PROPRIETARY TO GENERAL ELECTRIC COMPANY CT HISPEED SERIES ADVANCED DIAGNOSTICS REV 10 1-3-4-5 2202119 LCAM Error Codes The following sequence is used to signal an error during the LCAM portion of the Self–test. First, all three LEDs blink together for the duration of a single pass. This requires approximately 10–15 seconds. Then the specific error code blinks twice before the next pass begins, with all three LEDs blinking together as before. The bit pattern of the error codes appears as a series of LEDs being turned on and off. The low order bit is first. When two LEDs blink together, the bit value is 1. When only one LED blinks, the bit value is 0. The Self–test runs in continuous mode when SW 1 position 0 is “open”. A single failure will cause a error code to flash repreatedly on the LEDs. Although, other errors may occur during testing only the first one is displayed forever. First all LEDs will blink together several times indicates a problem. Next, the error code is displayed serially, twice in the two leftmost LEDs. The pattern is binary and takes 4 blinks for the complete code. When the two LEDs blink together, the bit value is 1, when only blinks the bit is 0. The bit order is low to high. Record the blink pattern in the number of LEDs blinking, 1 or 2. Record them RIGHT to LEFT, to make them easier to interpret. 1 2 1 2 Subtract 1 from each digit to obtain the bit value. 0 1 0 1 The value of the code is 5. Error code meanings: 1: DMA time–out Bypass active 2: data error. Bypass active 3: data error. ROI active 4: data error. Bypass, ROI active 5: DMA time–out. Swap & bypass active 6: data error. Swap & bypass active 7: data error. Swap active 8: data error. Swap & ROI active 9: data error. Swap, ROI active 14:SRAM LUT error No others are defined. 1–29 OPERATOR CONSOLE CT HISPEED SERIES ADVANCED DIAGNOSTICS PROPRIETARY TO GENERAL ELECTRIC COMPANY REV 10 2202119 1-3-4-6 RUN–TIME Error Codes These codes may be found in the DASM Response Block byte 128, when the error bit (bit 2, where bit 0 is first) is set in Response Block byte 0. Only the first of multiple errors is stored in Response Block byte 128. Reading the Response Block clears the error. Note that the status “invalid command” is returned to the user directly in bit 0 of the SCSI status byte; it is not logged in the Response Block. Table 1–14 Error DASM Run Time Error Codes Hex Meaning General Error Codes E_PARAM 81 Bad parameter to valid command E_NO_FF 82 No 0xFF terminator in command E_TMO 83 Timeout E_PIF_SELF 84 Peripheral interface self–test error E_PIFNOTRDY 85 Peripheral device not ready E_OVRRUN 86 Data overrun E_UNDRUN 87 Data under run E_COM_LINK 88 Communications link error between DASM and PIF E_DRAM 8A Error in I/O RAM (Note: This is a warning, which is available in the trace buffer in the DASM response block. During a warning, byte 128 is not updated.) E_EPROM 8B EPROM checksum error E_MFP 8C Error in the MC68901 I/O and timer chip E_SBIC 8D Error in access to SCSI bus interface chip E_NOTIMER 8E No timer available (all in use) E_INTERN 8F Internal system software error E_INV_MSG B0 Invalid / unexpected message from device E_BAD_S B1 Invalid S–record (from load routine) E_ODD_ADR B2 Odd address passed to function E_BOUNDS B3 I/O request overlapped buffer boundary E_DIRECTION B4 I/O request direction is invalid E_NOT_NXT B5 I/O request for data is out of sequence E_AVAIL_CT B6 I/O request exceed available data count E_PARITY B7 Parity error E_PIF_REV B8 No PIF revision level supplied E_TIMER_ID B9 Timer id error (Continued) 1–30 OPERATOR CONSOLE CT HISPEED SERIES ADVANCED DIAGNOSTICS PROPRIETARY TO GENERAL ELECTRIC COMPANY REV 10 2202119 1-3-4-6 RUN–TIME Error Codes (Continued) Table 1–12 Error DASM Run Time Error Codes (Continued) Hex Meaning M_REJECTED 95 Message was ected by partner M_BADREPLY 96 Unexpected reply was received E_NOTREADY 97 Camera is not ready E_TIMEOUT 98 EXEC Function did not complete in time E_TOOLONG 99 Received telegram has too many characters E_UNEXPECTED 9A Laser camera replied with an unexpected telegram E_BADPARAM 9B Bad parameter from host found in CMDBLK VRTX Error Codes E_VRTX C1–F4 VRTX error range – C1 Task ID invalid – C2 No task control block available – C3 No Memory available – C4 No Memory block – C5 Mailbox in use – C6 Message of Zero – C7 Buffer full – C8 WAITC is in progress – C9 Invalid system call – CA Timeout – CB No Message present – CC Queue ID error – CD Queue Full – CE Partition ID error – CF Fatal initialization error – D0 No character present – D1 Invalid configuration parameter at Init – D2 Invalid parameter to PCREATE/PEXTEND – E0 No component vector table – E1 Invalid component (Continued) 1–31 OPERATOR CONSOLE CT HISPEED SERIES ADVANCED DIAGNOSTICS PROPRIETARY TO GENERAL ELECTRIC COMPANY REV 10 1-3-4-6 2202119 RUN–TIME Error Codes (Continued) Table 1–12 DASM Run Time Error Codes (Continued) Error Hex Meaning – E2 Invalid opcode for component – F0 No control block available – F1 Event flag group or semaphore ID error – F2 Tasks pending on event flag group or semaphore – F3 Event flag group or semaphore is deleted – F4 Event flag group already set or overflow 1–32 OPERATOR CONSOLE CT HISPEED SERIES ADVANCED DIAGNOSTICS PROPRIETARY TO GENERAL ELECTRIC COMPANY REV 10 OTHER BOARDS Table 1–15 NAA1 LED Description LED POWER (LED1) Description Lights while power is supplied. Illustration 1–9 NAA1 POWER LED1 CN4 CN2 1–33 CN3 CN1 1-4 2202119 OPERATOR CONSOLE PROPRIETARY TO GENERAL ELECTRIC COMPANY blank CT HISPEED SERIES ADVANCED DIAGNOSTICS 2202119 1–34 OPERATOR CONSOLE PROPRIETARY TO GENERAL ELECTRIC COMPANY CT HISPEED SERIES ADVANCED DIAGNOSTICS REV 11 2202119 SECTION 2 – TEST PROGRAMS 2-1 SYSTEM POWER–UP SEQUENCE The power–ON test program is used for OC self–diagnostics during the Power up sequence. This test program has two categories; Power On Test and Off–line Test (Detailed Power On test). The Off–line test includes more detailed tests than power–on Test, and takes longer to run. The power–on Test is normally selected automatically when powering ON the system. The Off–line test can be used by the field engineer to perform a more detailed analysis in the event of an error occurring on the system. The power–on test is described in Section 2-2. Even if errors occur during the power–on test, the test continues to be executed until it finishes, and the test log window appears. You can confirm the problem by reviewing test log, then select either of the following: D [H/W diag] : Go to [H/W diag Main Menu] for OFF–LINE test Note For more detail, refer to 2-3 Off–line Test. D [Startup] : The error is skipped and the power–on sequence proceeds so that the start–up screen will be shown on the CRT monitor. Note When the start–up screen does NOT appear even if using the [Startup] command, the system must be shutdown using [shutdown] button in the desktop menu. D [Shutdown] : The system runs the shutdown sequence, resulting in the system powered OFF automatically. 2–1 OPERATOR CONSOLE PROPRIETARY TO GENERAL ELECTRIC COMPANY REV 11 2-2 CT HISPEED SERIES ADVANCED DIAGNOSTICS 2202119 POWER–ON TEST The power–on test is automatically executed after the operating system becomes ready and before the system software starts. If you want to manually start the power–on Test, execute ‘Application Shutdown’ from the System Tools menu, and execute the following command in the Unix shell. > poweron The following tests are performed during the power–on test. D hinv Test: Checks that the devices which are listed in the reference file created during the Reconfig procedure are identified as correctly installed on the operator console. D SCSI Test: Performs ‘inquiry’ and ‘self–test’ on each SCSI device. A read and write test on the media is not performed. The tested devices are those which were listed during the Reconfig procedure. D NPR Test: Performs an access test on memory devices installed on the NPR (NP Recon Engine) boards. As for NPRS boards, only the NPRS1 board is tested. Perform the off–line test ( described in Section 2-3) to test other NPRS boards. D DBPCI Test: Performs an access test on the DAS Buffer Memory and registers. 2–2 OPERATOR CONSOLE PROPRIETARY TO GENERAL ELECTRIC COMPANY CT HISPEED SERIES ADVANCED DIAGNOSTICS REV 11 2-3 2202119 OFF–LINE TEST NOTICE When the interactive test or off–line test is completed, the system MUST be powered OFF ([Exit] –> [OK]) to avoid accidental X–ray Exposure. That is because system reboot can NOT activate the system reset line. 2-3-1 General This is a test to verify that access to memory/register of NPR or DBPCI boards is performed with no error. In off–line mode, the following two modes exists. D Stop mode: The test will stop when error occurs. D Continue mode: The test will proceed without stop when error occurs. The error occurred can be checked by viewing error log after test. However, there is a much possibility that Memory/Register have been overwritten, so that you can NOT confirm which the error occurred in read phase or in write phase. Each mode above contains the following three test methods. (You can edit them whenever you want.) – Normal: All of the test items can be run. It takes approx. 60 minutes for the longest time. (This depends on hardware configuration.) – Quick: A part of the test items can be run. It takes shorter than “Normal” to complete. It takes approx. 50 minutes for the longest time. (This depends on hardware configuration.) – Manual: The test items can be manually selected to run the tests for the specific item to be desired. The default setting is the same one as “Normal”. NOTICE Do not use the manual test until you perfectly understand each test items in the manual test. Some memories or registers contain access prohibitive areas. If you change this area accidentally, the system hung–up often occurred. 2–3 OPERATOR CONSOLE PROPRIETARY TO GENERAL ELECTRIC COMPANY CT HISPEED SERIES ADVANCED DIAGNOSTICS REV 11 2-3-2 2202119 Running Off–Line Test 1. Select [Service] –> [Diagnostics & analysis] –> [H/W Diagnostics] –> [Offline Test] . The Off–line test menu appears. 2. Select either [Stop] or [Continue] in response to “WHEN ERROR OCCUR”. 3. Select from among three mode; NORMAL, QUICK, or MANUAL in response to “TEST MODE”. Usually, select [Stop] and [Quick]. See Illustration 2–1. Illustration 2–1 Parameter Selection Select 4. When [Quick] is selected, go to step 7. When [Normal] or [Manual] is selected, go to next step. 5. Select either [NPR] or [DBPCI] to determine which board can be tested. D NPR: NPRM, NPRS, and NPRIF 2–4 OPERATOR CONSOLE PROPRIETARY TO GENERAL ELECTRIC COMPANY CT HISPEED SERIES ADVANCED DIAGNOSTICS REV 11 2-3-2 6. 2202119 Running Off–Line Test (Continued) Select either [PCI TEST] or [INTERNAL TEST]. D PCI test: This test accesses NPR (GM, CM, and Master DSP’s IM) and DBPCI (DBM and all registers) from PCI (System) bus. D Internal test: Check whether or not the DPI0 on the NPR board can be accessed to each memory. Note Each test has the edit window to select programs to be desired. For brief information of this program to be edited, refer to 2-3-4 Editing Off–line Test Program. 7. Click on [RUN] to start off–line test. See Illustration 2–2. While executing tests, “Running” appears on the left lower button (Result/View Log button). This off–line test checks hardware, NPR PCI –> NPR Internal –> DBPCI#0 –> DBPCI#1, in this order. Illustration 2–2 Run the Test Click to run the test Note When aborting the Off–Line test on the way, press the [Stop Now] button. 2–5 OPERATOR CONSOLE PROPRIETARY TO GENERAL ELECTRIC COMPANY CT HISPEED SERIES ADVANCED DIAGNOSTICS REV 11 2-3-2 8. 2202119 Running Off–Line Test (Continued) Verify that “Pass” appears on the Result/View Log button after completing the test. Note If “Error” appears, click on this [Error] button to open the NPR log viewer and display the detailed information (device driver permission, etc...). This error log will be deleted when performing the next test or shuting down the system. See also the tables in Section 2-4, Hardware to be Used in Hardware Diagnostics. 9. To return to [H/W Diag Main Menu], click on [Back]. 2–6 OPERATOR CONSOLE PROPRIETARY TO GENERAL ELECTRIC COMPANY CT HISPEED SERIES ADVANCED DIAGNOSTICS REV 11 2-3-3 2202119 Viewing the Log File The log files can be opened without entering the H/W Diagnostics. Therefore, the system does not need to be shut down even if the log file viewer is terminated. In this program, the following menu can be seen to display each log file: D Diag View Log: For viewing the general log file for Diagnostics test D View P–ON Test Log: For viewing the result of power–ON test D H/W inventory: For viewing the result of hinv D View SYSLOG: For viewing the system log since the latest system start–up 1. Select [Service] –> [Diagnostics & analysis] –> [H/W Diagnostics] –> [View Log] . The log file selection menu appears. 2. Select the related menu. 3. Click on [Back] to return to Service menu. 2–7 OPERATOR CONSOLE PROPRIETARY TO GENERAL ELECTRIC COMPANY CT HISPEED SERIES ADVANCED DIAGNOSTICS REV 11 2-3-4 2202119 Editing Off–line Test Program When clicking on [Detail], the following menu appears. Using this menu, you can run the test or edit the off–line test program one by one. The editing information can be seen in the view screen: Illustration 2–3 Off–line test run/edit menu EDIT AREA PROGRAM DISPLAY EDIT AREA PROGRAM DISPLAY Set Default: returns to the program setting to the default one, so that the information edited are canceled. 2–8 OPERATOR CONSOLE CT HISPEED SERIES ADVANCED DIAGNOSTICS PROPRIETARY TO GENERAL ELECTRIC COMPANY REV 11 2-3-4 2202119 Editing Off–line Test Program (Continued) In the Program display area, the test items (programs) can be seen. To edit these programs, use the edit area above the program display screen. NOTICE The personnel familiar with this program ONLY can edit these program. If others edit them, the wrong tests would be performed or the system would hung–up. Note For DBPCI (both Normal and Quick), the internal test does NOT exist. The Illustration 2–4 is the example (Normal–NPR–Internal) of programs to be displayed (and to be edited). Illustration 2–4 Meaning of Program (PCI Detail) Driver No.: Test loop No. 00: NPR 10 : DBPCI#0 Size 11 : DBPCI#1 5 1 MemoryBitWalk 10 0 400000 0 0 Line No. Offset address Initial shift Test Program: Polarity MemoryBitWalk : PIO, bitwalk MemoryFill : PIO, constant increment/ decrement MemoryDMA : DMA transmission RegTest : PI0 access to each register 2–9 OPERATOR CONSOLE CT HISPEED SERIES ADVANCED DIAGNOSTICS PROPRIETARY TO GENERAL ELECTRIC COMPANY REV 11 2-3-4 2202119 Editing Off–line Test Program (Continued) Illustration 2–5 Meaning of Program (NPR Internal Detail) mst : executed by master DSP slv : executed by slave DSP Test loop No. Test target : gm (global memory), pm (private memory), cm (communication memory), sim (slave internal memory), and spm (slave private memory) Start slave No. : slave DSP No. to start IM test Slave count : slave DSP count to perform IM test 1 1 mst gm – – MemoryFill 00 0 1000000 0 0 Line No. Offset address Driver No.: Test Program: 00: NRP Size (Fill memory size) Fill Data pattern MemoryBitWalk : PIO, bitwalk MemoryFill : PIO, constant increment/ decrement Transmission mode 0: constant 1: increment 2: decrement 2–10 OPERATOR CONSOLE CT HISPEED SERIES ADVANCED DIAGNOSTICS PROPRIETARY TO GENERAL ELECTRIC COMPANY REV 11 2-3-5 2202119 Off–line Test Time Time required to Off–line test depends on the hardware configuration. The following tables can be used as a reference to estimate test time. GM=32 MB, NPRS= 0 to 8 boards GM=32MB NPRS Normal Mode Quick Mode 0 1 2 4 8 NPR PCI 0:27:09 0:27:09 0:27:09 0:27:09 0:27:09 NPR Internal 0:06:19 0:07:15 0:08:06 0:10:01 0:14:33 DBPCI 0:03:37 0:03:37 0:03:37 0:03:37 0:03:37 SUM 0:37:05 0:38:01 0:38:52 0:40:47 0:45:19 NPR PCI 0:03:40 0:03:40 0:03:40 0:03:40 0:03:40 NPR Internal 0:00:40 0:01:29 0:02:13 0:03:54 0:07:58 DBPCI 0:00:33 0:00:33 0:00:33 0:00:33 0:00:33 SUM 0:04:53 0:05:42 0:06:26 0:08:07 0:12:11 0 1 2 4 8 NPR PCI 0:54:18 0:54:18 0:54:18 0:54:18 0:54:18 NPR Internal 0:12:01 0:13:24 0:14:43 0:17:29 0:18:47 DBPCI 0:07:14 0:07:14 0:07:14 0:07:14 0:07:14 SUM 1:13:33 1:14:56 1:16:15 1:19:01 1:20:19 NPR PCI 0:07:20 0:07:20 0:07:20 0:07:20 0:07:20 NPR Internal 0:01:14 0:02:26 0:03:39 0:06:14 0:12:03 DBPCI 0:01:06 0:01:06 0:01:06 0:01:06 0:01:06 SUM 0:09:40 0:10:52 0:12:05 0:14:40 0:20:29 GM=64 MB, NPRS= 0 to 8 boards GM=64MB NPRS Normal Mode Quick Mode 2–11 OPERATOR CONSOLE PROPRIETARY TO GENERAL ELECTRIC COMPANY blank CT HISPEED SERIES ADVANCED DIAGNOSTICS 2202119 2–12 OPERATOR CONSOLE CT HISPEED SERIES ADVANCED DIAGNOSTICS PROPRIETARY TO GENERAL ELECTRIC COMPANY REV 11 2-4 2202119 HARDWARE TO BE USED IN HARDWARE DIAGNOSTICS The following tables shows the hardware configuration to be used in the Hardware Diagnostics. 2-4-1 Interactive Test Refer to Functional check/Adjustment for details of this test. Table 2–1 Interactive Test Monitor Monitor Keyboard Scan Key O2 video VSPL Monitor Cable f f f 141, Monitor O2 serial O2 KB Rear CN1 Keyboard f f 133, KB f f 134, KB f f 103 Key PCI DBPCI Cradle f f f KB Tilt f f f KB KB Reset f f f f f O2 SCSI DBPCI Rear CN1 NAA1 Audio O2 PCI O2 audio 131, 133, KB, PCI CDROM Volume f f f f 131, 138, PCI mod/freq/ width f f f f 131, 138, PCI Xray ON f f f f 131, 138, PCI Alert ON f f f f 131, 138, PCI f f 136, 138 f f f f f Auto Voice f CD Player Play back f f Note WS: Workstation, KB: Keyboard, HINV: Hardware inventory, SYSLOG: System Log 2–13 OPERATOR CONSOLE f 137, 147, 148 131, 138, PCI CT HISPEED SERIES ADVANCED DIAGNOSTICS PROPRIETARY TO GENERAL ELECTRIC COMPANY REV 11 2-4-1 2202119 Interactive Test (Continued) Table 2–1 Interactive Test (Continued) MISC O2 SCSI Device PCI Device NPSC HINV f f f f SYSLOG f SCSI f NPR LED f f Safety Loop f f f Shutdown f f f WS Default Mouse NPR DBPCI Rear CN1 Front PNL 146, 147, 148, PCI f f PCI f O2 Rear CN2 Mouse f f f 146, 147, 148 f PCI 131, PCI Y 131, 143, PCI 140, Mouse Monitor Monitor Audio Auto Voice Note WS: Workstation, KB: Keyboard, HINV: Hardware inventory, SYSLOG: System Log 2–14 f OPERATOR CONSOLE CT HISPEED SERIES ADVANCED DIAGNOSTICS PROPRIETARY TO GENERAL ELECTRIC COMPANY REV 11 2-4-2 2202119 Off–line NPR Test Table 2–2 Off–line NPR Test Program Name MemoryBitWalk MemoryDMA PCI Brid ge All All NPRIF PCI chip Target NPRM INT2 MDS DSP P GM CM Master f f f GM f f f CM f f f IM f f f GM f f f CM f f f IM f f f GM f f DMA C NPR PCI MemoryFill O2 PM NPRS LP INT2 PCI CR SDS P (GM) SPM LP CR PCI f f f Y f f f f f f f Y Note MDSP: Master DSP, GM: Global Memory, PM: Private Memory, SIM: Slave Internal Memory, CR: Communication Register, SDSP: Slave DSP, CM: Communication Memory, LP: Link Port, SPM: Slave Private Memory, INT2: Interrupt To 2–15 OPERATOR CONSOLE INT 2DS P Master CT HISPEED SERIES ADVANCED DIAGNOSTICS PROPRIETARY TO GENERAL ELECTRIC COMPANY REV 11 2202119 Table 2–2 Program Name Off–line NPR Test (Continued) MemoryFill MemoryBitWalk PCI Brid ge All All NPRIF PCI chip Target NPRM INT2 MDS DSP P GM CM PM NPRS LP Master INT2 PCI CR SDS P (GM) SPM LP CR PCI f f f f f f f GM f f f f f f f f CM f f f f f f f f PM f f f f f f f SIM f f f f f f f f SPM f f f f f f f f GM f f f f f f f f CM f f f f f f f f PM f f f f f f f SIM f f f f f f f f SPM f f f f f f f f LP f f f f f f f NPR Internal Master O2 f f f f INT 2DS P Master f f f f f f f f f f f f f f Register Link Port f f f f f Note MDSP: Master DSP, GM: Global Memory, PM: Private Memory, SIM: Slave Internal Memory, CR: Communication Register, SDSP: Slave DSP, CM: Communication Memory, LP: Link Port, SPM: Slave Private Memory, INT2: Interrupt To 2–16 OPERATOR CONSOLE f CT HISPEED SERIES ADVANCED DIAGNOSTICS PROPRIETARY TO GENERAL ELECTRIC COMPANY REV 11 2202119 Table 2–2 Slave Off–line NPR Test (Continued) O2 PCI Brid ge All All NPRIF PCI chip NPRM INT2 MDS DSP P GM CM LP INT2 PCI CR SDS P (GM) SPM Program Name Target MemoryFill GM f f f f f f f f f f f PM f f f f f f f f f f f GM f f f f f f f f f f f PM f f f f f f f f f f f MemoryBitWalk Master PM NPRS LP CR PCI Master f f f f f f f f f f Register Note MDSP: Master DSP, GM: Global Memory, PM: Private Memory, SIM: Slave Internal Memory, CR: Communication Register, SDSP: Slave DSP, CM: Communication Memory, LP: Link Port, SPM: Slave Private Memory, INT2: Interrupt To 2–17 INT 2DS P OPERATOR CONSOLE CT HISPEED SERIES ADVANCED DIAGNOSTICS PROPRIETARY TO GENERAL ELECTRIC COMPANY REV 11 2-4-3 2202119 Off–line DBPCI Test Table 2–3 Off–line DBPCI Test Program Name O2 PCI Bridge All All DBPCI PCI chip DBM DA Regs TREQ Regs DBMEN Target PCI INT2PCI PCI f f f f MemoryFill DBM f f f f MemoryBitWalk DBM f f f f MemoryDMA DBM f f DMAC f Register DA Regs f f f TREQ Regs f f f DBMEN f f f f f f f f f f f f f f Note DBM: DAS Buffer Memory, DA Regs: DAS Address Counter Registers, TREQ Regs: Transfer Request Counter Registers, DBMEN: DBM Enable, INT2: Interrupt To, PCI Bridge: PCI Host card + (plus) PCI Backplane + (plus) BP Controller card 2–18 OPERATOR CONSOLE CT HISPEED SERIES ADVANCED DIAGNOSTICS PROPRIETARY TO GENERAL ELECTRIC COMPANY REV 11 2202119 SECTION 3 – HOST PROCESSOR TROUBLESHOOTING 3-1 PROBLEM DIAGNOSIS If you suspect there is a problem with your hardware, use the flowchart (Illustration 3–1) to help isolate and solve the problem. To view the flowchart, use the magnification function. See also Diagnostic Tests (Section 3-2). POSSIBLE SOLUTION POSSIBLE CAUSE SYMPTOM Illustration 3–1 No LED Yes No Diagnostic Flow Chart #1 Solid red LED Yes No Solid amber LED Blinking amber LED No Yes Yes No No boot tune Solid green LED No Yes No B Yes “ No power to system “ Power supply failure “ CPU module failure “ System board failure “ Memory diagnostic failure “ Volume set too low “ Headphones plugged in “ Speaker failure “ Check power connections “ Re–seat CPU module “ Re–seat CPU module “ Re–seat DIMMS on system board “ Verify slots 1 and 2 are populated “ Re–seat DIMMs on system board “ Turn up volume “ Check if headphones are connected “ System diagnostics successful Yes Error code message ? “ Record message “ Replace power supply “ Replace CPU module “ Replace system board “ Replace DIMMs 3–1 “ Replace system board “ Replace chassis OPERATOR CONSOLE CT HISPEED SERIES ADVANCED DIAGNOSTICS PROPRIETARY TO GENERAL ELECTRIC COMPANY REV 11 PROBLEM DIAGNOSIS (continued) Solid green LED No display B Solid green LED No keyboard Keyboard prompt on display No Yes Solid green LED No mouse Mouse prompt on display No Yes Yes “ Keyboard not connected “ Keyboard failure “ System board failure “ “ “ “ “ “ “ “ “ “ Check keyboard connection “ Check mouse connection “ Check keyboard connection Error code message? Yes “ Record message “ Replace monitor cable “ Replace monitor “ Replace system board No “ Replace keyboard “ Replace system board Mouse not connected Keyboard not connected Mouse failure Keyboard failure System board failure Error code message? Yes “ Record message No “ Replace mouse “ Replace system board 3–2 Solid green LED No CD–ROM No Yes “ Monitor not connected “ Monitor not turned on “ Monitor in power saving mode “ Monitor brightness too low “ Cable failure “ Monitor failure “ System board failure Check monitor connections Turn on monitor Check monitor LED Adjust monitor brightness Solid green LED No system drive No Yes “ System drive not inserted all the way “ System drive failure “ CD–ROM drive not connected “ CD–ROM drive failure “ Check that system drive locking lever is pushed up all the way “ Check CD–ROM connections Error code message? Yes “ Record message No “ Replace system drive SYMPTOM Diagnostic Flow Chart #2 Error code message? Yes “ Record message No POSSIBLE CAUSE Illustration 3–2 POSSIBLE SOLUTION 3-1 2202119 “ Replace CD–ROM drive OPERATOR CONSOLE PROPRIETARY TO GENERAL ELECTRIC COMPANY REV 11 3-2 CT HISPEED SERIES ADVANCED DIAGNOSTICS 2202119 DIAGNOSTIC TESTS There are three types of software diagnostics tests provided on the O2 workstation. Each is described below: D Power–On Tests D IDE Tests Power–On Test These run automatically on the major hardware components of the workstation each time it is turned on. If the tests find a faulty part, the LED on the front of the system will be red and there will probably be an error message. See also Problem Diagnosis (Section 3-1). IDE Tests The Interactive Diagnostic Environment (IDE) tests are more comprehensive than the Confidence Tests, and take longer (as long as 30–45 minutes) to run. See Integrated Diagnostic Environment (IDE) Tests on the SBC (O2) (Section 3-5). 3–3 OPERATOR CONSOLE PROPRIETARY TO GENERAL ELECTRIC COMPANY REV 11 3-3 CT HISPEED SERIES ADVANCED DIAGNOSTICS 2202119 RECOVERING FROM SYSTEM CRASH In most cases, your system will recover from a system crash automatically if you reboot the system. If, however, you have lost data on your system disk, and you cannot communicate with your system using the mouse or keyboard, or over the network, follow these instructions. The instructions assume you have a backup tape of your system that has been made using the System Manager backup tool, or with the /usr/sbin/Backup script. You also need a CD with your current IRIX operating system level. If you are recovering data from a tape on a remote tape device, you need to know the hostname, tape device name, and IP address of the remote system. 1. Use a pen tip or an unwound paper clip to press the RESET button located on the front panel (Illustration 3–3). Illustration 3–3 Pressing the Reset Button SiliconGraphics 2. When you see the System Startup notifier (Illustration 3–4), click STOP FOR MAINTENANCE or press ESC. Illustration 3–4 System Startup Notifier 3–4 OPERATOR CONSOLE PROPRIETARY TO GENERAL ELECTRIC COMPANY REV 11 3-3 3. CT HISPEED SERIES ADVANCED DIAGNOSTICS 2202119 RECOVERING FROM SYSTEM CRASH (continued) From the System Maintenance menu, choose RECOVER SYSTEM, or type 4 on the keyboard. The System Recovery Menu appears (Illustration 3–5). Illustration 3–5 System Recovery Menu 4. If you have a CD–ROM drive connected to your system and the IRIX CD, click LOCAL CD–ROM. Then click ACCEPT to start. Insert the CD when prompted. The system takes five minutes or more to copy the information. If you don REMOTE DIRECTORY. 5. When a notifier appears asking you for the remote hostname, type the system’s name, a colon (:), and the full pathname of the CD–ROM drive, followed by /dist. For example, to access a CD–ROM drive. On the system mars, you would type: mars:/CDROM/dist After everything is copied from the CD to the system disk, you can restore your data from a recent full backup tape. The backup must be one that has been made using the System Manager backup tool, or with the /usr/sbin/ Backup script. Tip: If you need to check something on your system during the restore process, you can get a shell prompt by typing sh at most question prompts. 6. If you have a local tape device, you see this message: Restore will be from OK? ([Y]es, [N]o): [Y] tapename is the name of the local tape device. 3–5 OPERATOR CONSOLE PROPRIETARY TO GENERAL ELECTRIC COMPANY CT HISPEED SERIES ADVANCED DIAGNOSTICS REV 11 3-3 7. 2202119 RECOVERING FROM SYSTEM CRASH (continued) If you have a remote (network) tape device, when no tape device is found, or when you answered ‘No’ to the question in the previous step, you see this message: Remote or local restore ([r]emote, [l]ocal): – If you answer ‘remote,’ you have chosen to restore from the network, and you must know the hostname, tape device name, and IP address of the remote system. You also need to know the IP address of your system. The IP address, such as 192.0.2.1, always has four components separated by periods. – If you answer ‘local,’ you have chosen a tape device that is connected to your system, and you are prompted to enter the name of the tape device. 8. When you see the following message, remove the CD–ROM, insert your most recent full backup tape, then press ENTER. Insert the first backup tape in the drive, then press , [q]uit (from recovery), [r]estart: There is a pause while the program retrieves several files from the tape describing the system state at the time the backup was made. Then you see this message: Erase /x filesystem and make new one (y,n)? [n] It prompts you for every file system that was known at the time of the backup. Read the following to decide whether to answer y or n. – If you answer n for no, the system tries to salvage as many files as possible. Then it uses your backup tape to replace the files it could not salvage. Usually you should answer no, especially if your backup tape is not very recent. If the file systems were badly damaged, or the backup was from a different level operating system, you may need to answer yes. – – If you answer y for yes, the system erases the file system and copies everything from your backup tape to the disk. The system loses any information on that file system that you created between now and when you made your backup tape. 9. You see this message: Starting recovery from tape. After two or three minutes, the names of the files that the system is copying to the disk start scrolling. When the recovery is complete, you see this message: Recovery complete, restarting system. Note If your backup tapes were old, or you were changing your operating system level, you should reinstall the operating system from the IRIX CD that came with your system after system recovery is complete. When you see the Startup System notifier, press ESC, or click STOP FOR MAINTENANCE. Then click Install System Software. 3–6 OPERATOR CONSOLE PROPRIETARY TO GENERAL ELECTRIC COMPANY CT HISPEED SERIES ADVANCED DIAGNOSTICS REV 11 3-4 2202119 DISABLING THE SYSTEM MAINTENANCE PASSWORD If you are in the System Maintenance menu, and you choose INSTALL SYSTEM SOFTWARE, RUN DIAGNOSTICS, RECOVER SYSTEM, or ENTER COMMAND MONITOR, you may be prompted for a password. If you do not know the password, you can disable it by installing a jumper (a small cap that connects two pins) on the system board inside the workstation. The system board is located in the system module. To install the jumper, you must first remove the system module and the PCI tray. Follow these steps: 1. Turn off the workstation by pressing the power button on the front. 2. Remove the system module by releasing the lever on the extreme left as you face the rear of the workstation and sliding the module out. See Section 1–6 System Module, of OC Tabl of the Component Replacement manual. 3. Release and remove the PCI tray. See Section 1–8 PCI Tray, of OC Tabl of the Component Replacement manual. NOTICE Before touching any of the components, attach the wrist strap to your wrist and to a metal part of the chassis. 4. Remove the jumper from the system board in the location shown in Illustration 3–6. You must remove the jumper if you choose to reset the PROM password. Illustration 3–6 Removing the Jumper Jumper 3–7 OPERATOR CONSOLE PROPRIETARY TO GENERAL ELECTRIC COMPANY REV 11 3-4 5. CT HISPEED SERIES ADVANCED DIAGNOSTICS 2202119 DISABLING THE SYSTEM MAINTENANCE PASSWORD (continued) Reinstall the jumper in the location shown in Illustration 3–7. Illustration 3–7 Installing the Jumper 6. Remove the wrist strap. 7. Reinstall the PCI tray in the system module. 8. Reinstall the system module by sliding it into the chassis. 3–8 OPERATOR CONSOLE PROPRIETARY TO GENERAL ELECTRIC COMPANY CT HISPEED SERIES ADVANCED DIAGNOSTICS REV 11 3-5 2202119 INTEGRATED DIAGNOSTIC ENVIRONMENT (IDE) TESTS ON THE SBC (O2) The IDE tests on the O2 are stand alone tests that must be run at the boot PROM level. To run the O2 IDE tests from the OC, the user must first shut down applications. Next, cu into the SBC by opening a UNIX shell and typing: cu sbc. Once a serial connection has been established, the O2 must be shut down and re– started. Do this by logging into the SBC as root and typing the ‘halt’ command. Press ENTER when prompted to restart the SBC. When the system begins start–up, a message appears giving the user the option of performing system maintenance. Press ESC at this prompt to get to the System Maintenance Menu. Choose Option 3, Run Diagnostics. A hardware probe will be conducted and a default set of test scripts will be run automatically. This set takes approximately 10 minutes to execute. Pass and failure information is updated to the screen. When you run the tests, the following error message may appear. However, ignore this message. I2C register test HARDWARE FAILURE DMA test error. INITIATION OF THE O2 IDE TESTS {ctuser@baya_oc}[2] su – Password: You have mail. baya_oc 1# cu sbc Connected login: root Password: IRIX Release 6.5IP32 baya_sbc Copyright 1987–1998 Silicon Graphics, Inc. All Rights Reserved. Last login: Wed Jun 17 08:49:49 CDT 1998 on ttyd1 You have mail. TERM = (vt100) baya_sbc 1# halt Shutdown started. Wed Jun 17 08:52:17 CDT 1998 Broadcast Message from root (ttyd1) on baya_sbc Wed Jun 17 08:52:17 1998 THE SYSTEM IS BEING SHUT DOWN! Log off now. INIT: New run level: 0 The system is shutting down. Please wait. Jun 17 08:52:45 automount[217]: exiting 3–9 OPERATOR CONSOLE PROPRIETARY TO GENERAL ELECTRIC COMPANY CT HISPEED SERIES ADVANCED DIAGNOSTICS REV 11 3-5 2202119 INTEGRATED DIAGNOSTIC ENVIRONMENT (IDE) TESTS ON THE O2 (continued) Running power–on diagnostics... Okay to power off the system now. Press any key to restart. Starting up the system... To perform system maintenance instead, press System Maintenance Menu 1) Start System 2) Install System Software 3) Run Diagnostics 4) Recover System 5) Enter Command Monitor Option? 3 Starting diagnostic program... Press to return to the menu. SGI Version 6.5 IP32 IDE field April 30, 1998 System: IP32 Processor: 200 or 250 Mhz R5000, with FPU Primary I–cache size: 32 Kbytes Primary D–cache size: 32 Kbytes Memory size: 128 Mbytes Graphics: CRM, Rev C Network: DP83840–0 PCI Bus: MACE–PCI(0) SCSI Disk: scsi(0)disk(1) SCSI Disk: scsi(1)disk(1) Ide included scripts are ’ip32 cpu graphics fast_mem memory • 3–10 OPERATOR CONSOLE PROPRIETARY TO GENERAL ELECTRIC COMPANY CT HISPEED SERIES ADVANCED DIAGNOSTICS REV 11 3-5 2202119 INTEGRATED DIAGNOSTIC ENVIRONMENT (IDE) TESTS ON THE O2 (continued) Other Error Message If the following error occurs, it indicates that the diagnostics start–up disk is set to disk(2). pci(0)scsi(0)disk(2)rdisk(0)partition(X) /stand/ide:no such device In this case, enter the following in the Enter Command Monitor (command input screen): >resetenv Enter the following to confirm this response:OSloadPartition=pci(0)scsi(0)disk(1)rdisk(0)partion(0). >printenv Then, run the tests again. 3–11 OPERATOR CONSOLE PROPRIETARY TO GENERAL ELECTRIC COMPANY blank CT HISPEED SERIES ADVANCED DIAGNOSTICS 2202119 3–12 OPERATOR CONSOLE CT HISPEED SERIES ADVANCED DIAGNOSTICS PROPRIETARY TO GENERAL ELECTRIC COMPANY REV 10 2202119 SECTION 4 – NPR (RECON ENGINE) TROUBLESHOOTING 4-1 OVERVIEW The Service menu contains the diagnostics for the recon system (NPRIF, NPRM, NPRS boards, and its related circuitry, such as DBPCI board, etc.) This section describes how to use the diagnostics. The descriptions in this section are more detailed ones than those in Section 2-3, Off–line Test. Illustration 4–1 Troubleshooting Recon System Trouble occurs in the recon system. Error occurred in Power–on Test. If you fall into a loop in this flowchart, call On–line Center. Y N The system normally booted up? N Y N Error occurred in Offline Test. Y Error occurred in Auto Post Recon Test. Y N Perform the diagnostics described in this section. The trouble may be attributed to other than the recon system. If bad images are the problem, these units might be defective: DASIFN, DBPCI, DTRF, DAS. (If more than one NPRS board are defective, you may follow this way.) N Is there NPRS Board whose F0 LED is not blinking? The system did not boot up, due to other causes than the recon system. Y Replace the NPRS whose F0 LED is not blinking. Trouble fixed? N Illustration 4–1 shows a flowchart for troubleshooting the recon system. Following the flowchart, if you find that an NPRS board seems to be malfunctioning, exchange the board with some other NPRS board which is installed on another slot. And then, repeat the test, and you may be able to judge more correctly whether the exchanged board is defective or not. In this case, if the exchanged board seems to be operating normally, or an other board seems to be malfunctioning, the NPRM board might be defective. 4–1 OPERATOR CONSOLE PROPRIETARY TO GENERAL ELECTRIC COMPANY REV 10 4-2 CT HISPEED SERIES ADVANCED DIAGNOSTICS 2202119 DIAGNOSTICS FOR NPRM AND NPRS Select [Service] → [Diagnostics & analysis] → [H/W Diagnostics] → [Offline Test], to display the Off Line Test Menu. Illustration 4–2 H/W Diag Main Menu and Off Line Test Menu Select Offline Test. Select STOP, QUICK, NPR, INTERNAL TEST, and click RUN. 4–2 OPERATOR CONSOLE PROPRIETARY TO GENERAL ELECTRIC COMPANY CT HISPEED SERIES ADVANCED DIAGNOSTICS REV 10 4-2 2202119 DIAGNOSTICS FOR NPRM AND NPRS (continued) Illustration 4–3 shows an example of a test result display after clicking the [RUN] button. For each program description, refer to Section 2-3-4, ‘Editing Off–line Test Program.’ Illustration 4–3 Test Result Display Program1 : MemoryPIOre Board : npr Line List : 1 1 MemoryFill 00 0 40000 0 0 clear : PASS Program2 : MemoryPIOre Board : npr Line List : 2 1 MemoryFill 00 400000 40000 ffffffff 0 fill : PASS Program3 : MemoryPIOre Board : npr Line List : 3 1 MemoryFill 00 800000 40000 0 1 incr : PASS Program4 : MemoryPIOre Board : npr Line List : 4 1 MemoryFill 00 c00000 40000 ffffffff –1 decr : PASS Program7 : MemoryDMA Board : npr Line List : 7 1 MemoryDMA 00 0 1000000 1 0 0 : PASS Program8 : MemoryDMA Board : npr Line List : 8 1 MemoryDMA 00 0 1000000 2 0 0 : PASS . . . 4–3 OPERATOR CONSOLE CT HISPEED SERIES ADVANCED DIAGNOSTICS PROPRIETARY TO GENERAL ELECTRIC COMPANY REV 10 4-2 2202119 DIAGNOSTICS FOR NPRM AND NPRS (continued) Table 4–1 shows that, for each test program, a board (NPRIF, NPRM, NPRS, or DBPCI) which is considered to be defective is indicated by ‘O’ if the test program failed. Table 4–1 NPR – Internal Test NPRIF NPRM NPRS DBPCI f Program1 : MemoryPIOre Board : npr Line List : 1 1 MemoryFill 00 0 40000 0 0 clear : PASS f Program2 : MemoryPIOre Board : npr Line List : 2 1 MemoryFill 00 400000 40000 ffffffff 0 fill : PASS f Program3 : MemoryPIOre Board : npr Line List : 3 1 MemoryFill 00 800000 40000 0 1 incr : PASS f Program4 : MemoryPIOre Board : npr Line List : 4 1 MemoryFill 00 c00000 40000 ffffffff –1 decr : PASS f Program7 : MemoryDMA Board : npr Line List : 7 1 MemoryDMA 00 0 1000000 1 0 0 : PASS f Program8 : MemoryDMA Board : npr Line List : 8 1 MemoryDMA 00 0 1000000 2 0 0 : PASS f Program10 : MemoryPIOre Board : npr Line List : 10 1 MemoryFill 00 9080000 40000 0 0 clear : PASS f Program11 : MemoryPIOre Board : npr Line List : 11 1 MemoryFill 00 9300000 20000 0 0 clear : PASS 4–4 OPERATOR CONSOLE CT HISPEED SERIES ADVANCED DIAGNOSTICS PROPRIETARY TO GENERAL ELECTRIC COMPANY REV 10 4-2 2202119 DIAGNOSTICS FOR NPRM AND NPRS (continued) Table 4–1 NPR – Internal Test (continued) NPRIF NPRM NPRS DBPCI f Program1 : MemoryFill DSP : mst Line List : 1 1 mst gm – – MemoryFill 00 0 4000 0 0 : PASS Program2 : MemoryFill DSP : mst Line List : 2 1 mst gm – – MemoryFill 00 400000 4000 ffffffff 0 : PASS f f Program3 : MemoryFill DSP : mst Line List : 3 1 mst gm – – MemoryFill 00 800000 4000 0 1 : PASS Program4 : MemoryFill DSP : mst Line List : 4 1 mst gm – – MemoryFill 00 C00000 4000 ffffffff 2 : PASS f f Program5 : MemoryFill DSP : mst Line List : 5 1 mst pm – – MemoryFill 00 0 1000 0 0 : PASS f Program6 : MemoryFill DSP : mst Line List : 6 1 mst cm – – MemoryFill 00 4000 C000 0 0 : PASS f Program7 : MemoryFill DSP : mst Line List : 7 1 mst sim 1 2 MemoryFill 00 C4000 1C000 0 0 : PASS f Program8 : MemoryFill DSP : mst Line List : 8 1 mst spm 1 2 MemoryFill 00 0 1000 0 0 : PASS f Program9 : MemoryFill DSP : slv Line List : 9 1 slv gm 1 2 MemoryFill 00 0 4000 0 0 : PASS f Program10 : MemoryFill DSP : slv Line List : 10 1 slv pm 1 2 MemoryFill 00 0 1000 0 0 : PASS f Program11 : LpTest DSP : mst Line List : 11 1 mst lp 1 – LpTest 00 – – – – : PASS f Program12 : MemoryFill DSP : mst Line List : 12 1 mst gm – – MemoryFill 00 0 1000000 0 0 : PASS f Program1 : MemoryFill DSP : mst Line List : 1 1 mst gm – – MemoryFill 00 0 2000000 0 0 : PASS Program2 : MemoryFill DSP : mst Line List : 2 1 mst gm – – MemoryFill 00 0 2000000 ffffffff 0 : PASS f f Program3 : MemoryFill DSP : mst Line List : 3 1 mst gm – – MemoryFill 00 0 2000000 0 1 : PASS Program4 : MemoryFill DSP : mst Line List : 4 1 mst gm – – MemoryFill 00 0 2000000 ffffffff 2 : PASS 4–5 f OPERATOR CONSOLE CT HISPEED SERIES ADVANCED DIAGNOSTICS PROPRIETARY TO GENERAL ELECTRIC COMPANY REV 10 4-2 2202119 DIAGNOSTICS FOR NPRM AND NPRS (continued) Table 4–1 NPR – Internal Test (continued) NPRIF NPRM NPRS DBPCI f Program5 : MemoryFill DSP : mst Line List : 5 1 mst pm – – MemoryFill 00 0 100000 0 0 : PASS f Program6 : MemoryFill DSP : mst Line List : 6 1 mst pm – – MemoryFill 00 0 100000 ffffffff 0 : PASS f Program7 : MemoryFill DSP : mst Line List : 7 1 mst pm – – MemoryFill 00 0 100000 0 1 : PASS f Program8 : MemoryFill DSP : mst Line List : 8 1 mst pm – – MemoryFill 00 0 100000 ffffffff 2 : PASS f Program9 : MemoryFill DSP : mst Line List : 9 1 mst cm – – MemoryFill 00 4000 C000 0 0 : PASS Program10 : MemoryFill DSP : mst Line List : 10 1 mst cm – – MemoryFill 00 4000 C000 ffffffff 0 : PASS f f Program11 : MemoryFill DSP : mst Line List : 11 1 mst cm – – MemoryFill 00 4000 C000 0 1 : PASS Program12 : MemoryFill DSP : mst Line List : 12 1 mst cm – – MemoryFill 00 4000 C000 ffffffff 2 : PASS f f Program13 : MemoryFill DSP : mst Line List : 13 1 mst spm 1 4 MemoryFill 00 0 100000 0 0 : PASS Program14 : MemoryFill DSP : mst Line List : 14 1 mst spm 1 4 MemoryFill 00 0 100000 ffffffff 0 : PASS f f Program15 : MemoryFill DSP : mst Line List : 15 1 mst spm 1 4 MemoryFill 00 0 100000 0 1 : PASS Program16 : MemoryFill DSP : mst Line List : 16 1 mst spm 1 4 MemoryFill 00 0 100000 ffffffff 2 : PASS Program17 : MemoryFill DSP : mst Line List : 17 1 mst sim 1 4 MemoryFill 00 A0000 20000 0 0 : PASS Program18 : MemoryFill DSP : mst Line List : 18 1 mst sim 1 4 MemoryFill 00 A0000 20000 ffffffff 0 : PASS Program19 : MemoryFill DSP : mst Line List : 19 1 mst sim 1 4 MemoryFill 00 A0000 20000 0 1 : PASS 4–6 f f f f OPERATOR CONSOLE CT HISPEED SERIES ADVANCED DIAGNOSTICS PROPRIETARY TO GENERAL ELECTRIC COMPANY REV 10 4-2 2202119 DIAGNOSTICS FOR NPRM AND NPRS (continued) Table 4–1 NPR – Internal Test (continued) NPRIF NPRM NPRS DBPCI f Program1 : MemoryPIOre Board : npr Line List : 1 1 MemoryFill 00 0 40000 0 0 clear : PASS f Program2 : MemoryPIOre Board : npr Line List : 2 1 MemoryFill 00 400000 40000 ffffffff 0 fill : PASS f Program3 : MemoryPIOre Board : npr Line List : 3 1 MemoryFill 00 800000 40000 0 1 incr : PASS f Program4 : MemoryPIOre Board : npr Line List : 4 1 MemoryFill 00 c00000 40000 ffffffff –1 decr : PASS f Program7 : MemoryDMA Board : npr Line List : 7 1 MemoryDMA 00 0 1000000 1 0 0 : PASS f Program8 : MemoryDMA Board : npr Line List : 8 1 MemoryDMA 00 0 1000000 2 0 0 : PASS f Program10 : MemoryPIOre Board : npr Line List : 10 1 MemoryFill 00 9080000 40000 0 0 clear : PASS f Program11 : MemoryPIOre Board : npr Line List : 11 1 MemoryFill 00 9300000 20000 0 0 clear : PASS f Program1 : MemoryFill DSP : mst Line List : 1 1 mst gm – – MemoryFill 00 0 4000 0 0 : PASS Program2 : MemoryFill DSP : mst Line List : 2 1 mst gm – – MemoryFill 00 400000 4000 ffffffff 0 : PASS f f Program3 : MemoryFill DSP : mst Line List : 3 1 mst gm – – MemoryFill 00 800000 4000 0 1 : PASS Program4 : MemoryFill DSP : mst Line List : 4 1 mst gm – – MemoryFill 00 C00000 4000 ffffffff 2 : PASS f f Program5 : MemoryFill DSP : mst Line List : 5 1 mst pm – – MemoryFill 00 0 1000 0 0 : PASS f Program6 : MemoryFill DSP : mst Line List : 6 1 mst cm – – MemoryFill 00 4000 C000 0 0 : PASS Program7 : MemoryFill DSP : mst Line List : 7 1 mst sim 1 2 MemoryFill 00 C4000 1C000 0 0 : PASS f f Program8 : MemoryFill DSP : mst Line List : 8 1 mst spm 1 2 MemoryFill 00 0 1000 0 0 : PASS 4–7 OPERATOR CONSOLE CT HISPEED SERIES ADVANCED DIAGNOSTICS PROPRIETARY TO GENERAL ELECTRIC COMPANY REV 10 4-2 2202119 DIAGNOSTICS FOR NPRM AND NPRS (continued) Table 4–1 NPR – Internal Test (continued) NPRIF NPRM NPRS DBPCI f Program9 : MemoryFill DSP : slv Line List : 9 1 slv gm 1 2 MemoryFill 00 0 4000 0 0 : PASS f Program10 : MemoryFill DSP : slv Line List : 10 1 slv pm 1 2 MemoryFill 00 0 1000 0 0 : PASS f Program11 : LpTest DSP : mst Line List : 11 1 mst lp 1 – LpTest 00 – – – – : PASS f Program12 : MemoryFill DSP : mst Line List : 12 1 mst gm – – MemoryFill 00 0 1000000 0 0 : PASS f Program1 : MemoryFill DSP : mst Line List : 1 1 mst gm – – MemoryFill 00 0 2000000 0 0 : PASS Program2 : MemoryFill DSP : mst Line List : 2 1 mst gm – – MemoryFill 00 0 2000000 ffffffff 0 : PASS f f Program3 : MemoryFill DSP : mst Line List : 3 1 mst gm – – MemoryFill 00 0 2000000 0 1 : PASS Program4 : MemoryFill DSP : mst Line List : 4 1 mst gm – – MemoryFill 00 0 2000000 ffffffff 2 : PASS f f Program5 : MemoryFill DSP : mst Line List : 5 1 mst pm – – MemoryFill 00 0 100000 0 0 : PASS f Program6 : MemoryFill DSP : mst Line List : 6 1 mst pm – – MemoryFill 00 0 100000 ffffffff 0 : PASS f Program7 : MemoryFill DSP : mst Line List : 7 1 mst pm – – MemoryFill 00 0 100000 0 1 : PASS f Program8 : MemoryFill DSP : mst Line List : 8 1 mst pm – – MemoryFill 00 0 100000 ffffffff 2 : PASS f Program9 : MemoryFill DSP : mst Line List : 9 1 mst cm – – MemoryFill 00 4000 C000 0 0 : PASS Program10 : MemoryFill DSP : mst Line List : 10 1 mst cm – – MemoryFill 00 4000 C000 ffffffff 0 : PASS f f Program11 : MemoryFill DSP : mst Line List : 11 1 mst cm – – MemoryFill 00 4000 C000 0 1 : PASS 4–8 OPERATOR CONSOLE PROPRIETARY TO GENERAL ELECTRIC COMPANY REV 10 4-2 CT HISPEED SERIES ADVANCED DIAGNOSTICS 2202119 DIAGNOSTICS FOR NPRM AND NPRS (continued) How to Identify Defective NPRS – I Among the NPR – Internal Test programs, Table 4–2 lists a collection of test programs, each of which performs a test for each DSP (Digital Signal Processor–two DSPs are equipped on one NPRS board) and indicates the result of each test by ‘PASS’ or ‘ERROR’. Therefore, by reading when ‘ERROR’ appears, a defective NPRS board can be identified. See Illustration 4–4. Table 4–2 Test Programs – I No 1 Test Name Program7 : MemoryFill DSP : mst Line List : 7 1 mst sim 1 2 MemoryFill 00 C4000 1C000 0 0 : PASS 2 Program8 : MemoryFill DSP : mst Line List : 8 1 mst spm 1 2 MemoryFill 00 0 1000 0 0 : PASS 3 Program13 : MemoryFill DSP : mst Line List : 13 1 mst spm 1 4 MemoryFill 00 0 100000 0 0 : PASS 4 Program14 : MemoryFill DSP : mst Line List : 14 1 mst spm 1 4 MemoryFill 00 0 100000 ffffffff 0 : PASS 5 Program15 : MemoryFill DSP : mst Line List : 15 1 mst spm 1 4 MemoryFill 00 0 100000 0 1 : PASS 6 Program16 : MemoryFill DSP : mst Line List : 16 1 mst spm 1 4 MemoryFill 00 0 100000 ffffffff 2 : PASS 7 Program17 : MemoryFill DSP : mst Line List : 17 1 mst sim 1 4 MemoryFill 00 A0000 20000 0 0 : PASS 8 Program18 : MemoryFill DSP : mst Line List : 18 1 mst sim 1 4 MemoryFill 00 A0000 20000 ffffffff 0 : PASS 9 Program19 : MemoryFill DSP : mst Line List : 19 1 mst sim 1 4 MemoryFill 00 A0000 20000 0 1 : PASS 10 Program20 : MemoryFill DSP : mst Line List : 20 1 mst sim 1 4 MemoryFill 00 A0000 20000 ffffffff 2 : PASS 11 Program33 : MemoryBitWalk DSP : mst Line List : 33 1 mst spm 1 4 MemoryBitWalk 00 0 100000 0 0 : PASS 4–9 OPERATOR CONSOLE PROPRIETARY TO GENERAL ELECTRIC COMPANY REV 10 4-2 CT HISPEED SERIES ADVANCED DIAGNOSTICS 2202119 DIAGNOSTICS FOR NPRM AND NPRS (continued) Table 4–2 Test Programs – I (continued) No Test Name 12 Program34 : MemoryBitWalk DSP : mst Line List : 34 1 mst spm 1 4 MemoryBitWalk 00 0 100000 0 1 : PASS 13 Program35 : MemoryBitWalk DSP : mst Line List : 35 1 mst spm 1 4 MemoryBitWalk 00 0 100000 31 0 : PASS 14 Program36 : MemoryBitWalk DSP : mst Line List : 36 1 mst spm 1 4 MemoryBitWalk 00 0 100000 31 1 : PASS 15 Program37 : MemoryBitWalk DSP : mst Line List : 37 1 mst sim 1 4 MemoryBitWalk 00 A0000 20000 0 0 : PASS 16 Program38 : MemoryBitWalk DSP : mst Line List : 38 1 mst sim 1 4 MemoryBitWalk 00 A0000 20000 0 1 : PASS 17 Program39 : MemoryBitWalk DSP : mst Line List : 39 1 mst sim 1 4 MemoryBitWalk 00 A0000 20000 31 0 : PASS 18 Program40 : MemoryBitWalk DSP : mst Line List : 40 1 mst sim 1 4 MemoryBitWalk 00 A0000 20000 31 1 : PASS 4–10 OPERATOR CONSOLE PROPRIETARY TO GENERAL ELECTRIC COMPANY REV 10 4-2 CT HISPEED SERIES ADVANCED DIAGNOSTICS 2202119 DIAGNOSTICS FOR NPRM AND NPRS (continued) In the test result example shown in Illustration 4–4, in Program 17, all the (four) tests passed. However, in Program 18, the fourth test failed (as shown by an arrow); this indicates that the #2 NPRS board is defective, since one NPRS board has two DSPs, and a test is executed on each DSP. (This test example is for a recon system where two NPRS boards are installed.) Illustration 4–4 Test Result Example Program17 : MemoryFill DSP : mst Line List : 17 1 mst sim 1 4 MemoryFill 00 A0000 20000 0 0 : PASS PASS PASS PASS Program18 : MemoryFill DSP : mst Line List : 18 1 mst sim 1 4 MemoryFill 00 A0000 20000 ffffffff 0 : PASS PASS (The first and second tests are executed on #1 NPRS, and the third and fourth are on #2 NPRS.) PASS ERROR DSP No : 0x0, ERR FLAG: 0x1 address0: 0x20A28000, rd_data0: 0xFFFFFF00, orgdata0: 0xFFFFFFFF address1: 0x20A28001, rd_data1: 0xFFFFFF00, orgdata1: 0xFFFFFFFF address2: 0x20A28002, rd_data2: 0xFFFFFF00, orgdata2: 0xFFFFFFFF address3: 0x20A28003, rd_data3: 0xFFFFFF00, orgdata3: 0xFFFFFFFF address4: 0x20A28004, rd_data4: 0xFFFFFF00, orgdata4: 0xFFFFFFFF 4–11 OPERATOR CONSOLE PROPRIETARY TO GENERAL ELECTRIC COMPANY REV 10 4-2 CT HISPEED SERIES ADVANCED DIAGNOSTICS 2202119 DIAGNOSTICS FOR NPRM AND NPRS (continued) How to Identify Defective NPRS – II Table 4–3 lists a collection of another test programs. With these test programs, unlike the test programs listed in Table 4–2, a defective NPRS board can not be identified by reading when ‘ERROR’ appears. The way to identify a defective NPRS board, if any of these test programs failed, is explained in the following. Table 4–3 Test Programs – II No 1 Test Name Program9 : MemoryFill DSP : slv Line List : 9 1 slv gm 1 4 MemoryFill 00 0 4000 0 0 : PASS 2 Program10 : MemoryFill DSP : slv Line List : 10 1 slv pm 1 4 MemoryFill 00 0 1000 0 0 : PASS 3 Program41 : MemoryFill DSP : slv Line List : 41 1 slv gm 1 4 MemoryFill 00 0 2000000 0 0 : PASS 4 Program42 : MemoryFill DSP : slv Line List : 42 1 slv gm 1 4 MemoryFill 00 0 2000000 ffffffff 0 : PASS 5 Program43 : MemoryFill DSP : slv Line List : 43 1 slv gm 1 4 MemoryFill 00 0 2000000 0 1 : PASS 6 Program44 : MemoryFill DSP : slv Line List : 44 1 slv gm 1 4 MemoryFill 00 0 2000000 ffffffff 2 : PASS 7 Program45 : MemoryFill DSP : slv Line List : 45 1 slv pm 1 4 MemoryFill 00 0 100000 0 0 : PASS 8 Program46 : MemoryFill DSP : slv Line List : 46 1 slv pm 1 4 MemoryFill 00 0 100000 ffffffff 0 : PASS 9 Program47 : MemoryFill DSP : slv Line List : 47 1 slv pm 1 4 MemoryFill 00 0 100000 0 1 : PASS 10 Program48 : MemoryFill DSP : slv Line List : 48 1 slv pm 1 4 MemoryFill 00 0 100000 ffffffff 2 : PASS 4–12 OPERATOR CONSOLE PROPRIETARY TO GENERAL ELECTRIC COMPANY REV 10 4-2 CT HISPEED SERIES ADVANCED DIAGNOSTICS 2202119 DIAGNOSTICS FOR NPRM AND NPRS (continued) Illustration 4–5 Editing Test As shown in Illustration 4–5, click [DETAIL] in the Off Line Test menu. Then, the menu appears as shown in Illustration 4–6. 4–13 OPERATOR CONSOLE CT HISPEED SERIES ADVANCED DIAGNOSTICS PROPRIETARY TO GENERAL ELECTRIC COMPANY REV 10 4-2 2202119 DIAGNOSTICS FOR NPRM AND NPRS (continued) Assume that the recon system has two NPRS boards, and that No. 41 test program failed. Illustration 4–6 Test Edit Window Select the test program No. which failed, by [PRIOR] or [NEXT]. (Sliding switch can be used also to select the test program.) The number of DSPs equipped on NPRS boards. In this example, the number is 4. (NPRS boards: 2, and 2 DSPs per NPRS) The test program starts from this DSP. In this example, the test starts from #1 DSP. (#1 DSP and #2 DSP are on #1 NPRS, and #3 DSP and #4 DSP are on #2 NPRS.) For example, by setting ‘Start Slv No’ to 3, and setting ‘Slv Count’ to 2, the program only tests the two DSPs on the #2 NPRS board; the program does not test the #1 NPRS. Thus, by changing the ‘Start Slv No’ and ‘Slv Count’, a defective NPRS board can be identified. 4–14 OPERATOR CONSOLE PROPRIETARY TO GENERAL ELECTRIC COMPANY CT HISPEED SERIES ADVANCED DIAGNOSTICS REV 10 4-3 2202119 DIAGNOSTICS FOR NPRM AND DBPCI NPRM Diagnostics Illustration 4–7 Running NPR – PCI Test Select STOP, QUICK, NPR, PCI TEST, and click RUN. Table 4–4 shows an example of a test result display after clicking the [RUN] button. Table 4–4 Test Result Display Program1 : MemoryPIOre Board : npr Line List : 1 1 MemoryFill 00 0 2000000 0 0 clear : PASS Program2 : MemoryPIOre Board : npr Line List : 2 1 MemoryFill 00 0 2000000 ffffffff 0 fill : PASS Program3 : MemoryPIOre Board : npr Line List : 3 1 MemoryFill 00 0 2000000 0 1 incr : PASS Program4 : MemoryPIOre Board : npr Line List : 4 1 MemoryFill 00 0 2000000 ffffffff –1 decr : PASS 4–15 OPERATOR CONSOLE CT HISPEED SERIES ADVANCED DIAGNOSTICS PROPRIETARY TO GENERAL ELECTRIC COMPANY REV 10 4-3 2202119 DIAGNOSTICS FOR NPRM AND DBPCI (continued) Table 4–5 shows that, for each test program, a board (NPRIF, NPRM, NPRS, or DBPCI) which is considered to be defective is indicated by ‘O’ if the test program failed. As shown in this table, the NPRM board may be defective if any of the NPR – PCI test programs failed. Table 4–5 NPR – PCI Test NPRIF NPRM NPRS DBPCI f Program1 : MemoryPIOre Board : npr Line List : 1 1 MemoryFill 00 0 2000000 0 0 clear : PASS f Program2 : MemoryPIOre Board : npr Line List : 2 1 MemoryFill 00 0 2000000 ffffffff 0 fill : PASS f Program3 : MemoryPIOre Board : npr Line List : 3 1 MemoryFill 00 0 2000000 0 1 incr : PASS f Program4 : MemoryPIOre Board : npr Line List : 4 1 MemoryFill 00 0 2000000 ffffffff –1 decr : PASS f Program5 : MemoryPIOre Board : npr Line List : 5 1 MemoryBitWalk 00 0 2000000 0 0 0 : PASS f Program6 : MemoryPIOre Board : npr Line List : 6 1 MemoryBitWalk 00 0 2000000 0 1 1 : PASS f Program7 : MemoryPIOre Board : npr Line List : 7 1 MemoryBitWalk 00 0 2000000 31 0 63 : PASS f Program8 : MemoryPIOre Board : npr Line List : 8 1 MemoryBitWalk 00 0 2000000 31 1 64 : PASS f Program9 : MemoryDMA Board : npr Line List : 9 1 MemoryDMA 00 0 2000000 0 0 0 : PASS f Program10 : MemoryDMA Board : npr Line List : 10 1 MemoryDMA 00 0 2000000 0 ffffffff 0 : PASS f Program11 : MemoryDMA Board : npr Line List : 11 1 MemoryDMA 00 0 2000000 0 0 1 : PASS f Program12 : MemoryDMA Board : npr Line List : 12 1 MemoryDMA 00 0 2000000 0 ffffffff –1 : PASS f Program13 : MemoryDMA Board : npr Line List : 13 1 MemoryDMA 00 0 2000000 1 0 0 : PASS 4–16 OPERATOR CONSOLE CT HISPEED SERIES ADVANCED DIAGNOSTICS PROPRIETARY TO GENERAL ELECTRIC COMPANY REV 10 4-3 2202119 DIAGNOSTICS FOR NPRM AND DBPCI (continued) Table 4–5 NPR – PCI Test (continued) NPRIF NPRM NPRS DBPCI f Program14 : MemoryDMA Board : npr Line List : 14 1 MemoryDMA 00 0 2000000 2 0 0 : PASS f Program15 : MemoryDMA Board : npr Line List : 15 1 MemoryDMA 00 0 2000000 0 0 0 : PASS f Program16 : MemoryPIOre Board : npr Line List : 16 1 MemoryFill 00 9080000 40000 0 0 clear : PASS f Program17 : MemoryPIOre Board : npr Line List : 17 1 MemoryFill 00 9080000 40000 ffffffff 0 fill : PASS f Program18 : MemoryPIOre Board : npr Line List : 18 1 MemoryBitWalk 00 9080000 40000 0 0 0 : PASS f Program19 : MemoryPIOre Board : npr Line List : 19 1 MemoryBitWalk 00 9080000 40000 0 1 1 : PASS f Program20 : MemoryPIOre Board : npr Line List : 20 1 MemoryFill 00 9300000 20000 0 0 clear : PASS f Program21 : MemoryPIOre Board : npr Line List : 21 1 MemoryFill 00 9300000 20000 ffffffff 0 fill : PASS f Program22 : MemoryPIOre Board : npr Line List : 22 1 MemoryBitWalk 00 9300000 20000 0 0 0 : PASS f Program23 : MemoryPIOre Board : npr Line List : 23 1 MemoryBitWalk 00 9300000 20000 0 1 1 : PASS 4–17 OPERATOR CONSOLE PROPRIETARY TO GENERAL ELECTRIC COMPANY CT HISPEED SERIES ADVANCED DIAGNOSTICS REV 10 4-3 2202119 DIAGNOSTICS FOR NPRM AND DBPCI (continued) DBPCI Diagnostics Illustration 4–8 Running DBPCI#0 – PCI Test Select STOP, QUICK, DBPCI#0, PCI TEST, and click RUN. Table 4–6 shows an example of a test result display after clicking the [RUN] button. Table 4–6 Test Result Display Program1 : MemoryPIOdb Board : dbpci#0 Line List : 1 1 MemoryFill 10 0 400000 0 0 clear : PASS Program2 : MemoryPIOdb Board : dbpci#0 Line List : 2 1 MemoryFill 10 0 400000 ffffffff 0 fill : PASS Program3 : MemoryPIOdb Board : dbpci#0 Line List : 3 1 MemoryFill 10 0 400000 0 1 incr : PASS Program4 : MemoryPIOdb Board : dbpci#0 Line List : 4 1 MemoryFill 10 0 400000 ffffffff –1 decr : PASS 4–18 OPERATOR CONSOLE CT HISPEED SERIES ADVANCED DIAGNOSTICS PROPRIETARY TO GENERAL ELECTRIC COMPANY REV 10 4-3 2202119 DIAGNOSTICS FOR NPRM AND DBPCI (continued) Table 4–7 shows that, for each test program, a board (NPRIF, NPRM, NPRS, or DBPCI) which is considered to be defective is indicated by ‘O’ if the test program failed. As shown in this table, the DBPCI board may be defective if any of the DBPCI#0 – PCI test programs failed. Table 4–7 DBPCI#0 – PCI Test NPRIF NPRM NPRS DBPCI f Program1 : MemoryPIOdb Board : dbpci#0 Line List : 1 1 MemoryFill 10 0 400000 0 0 clear : PASS f Program2 : MemoryPIOdb Board : dbpci#0 Line List : 2 1 MemoryFill 10 0 400000 ffffffff 0 fill : PASS f Program3 : MemoryPIOdb Board : dbpci#0 Line List : 3 1 MemoryFill 10 0 400000 0 1 incr : PASS f Program4 : MemoryPIOdb Board : dbpci#0 Line List : 4 1 MemoryFill 10 0 400000 ffffffff –1 decr : PASS f Program5 : MemoryPIOdb Board : dbpci#0 Line List : 5 1 MemoryBitWalk 10 0 400000 0 0 0 : PASS f Program6 : MemoryPIOdb Board : dbpci#0 Line List : 6 1 MemoryBitWalk 10 0 400000 0 1 1 : PASS f Program7 : MemoryPIOdb Board : dbpci#0 Line List : 7 1 MemoryBitWalk 10 0 400000 31 0 63 : PASS f Program8 : MemoryPIOdb Board : dbpci#0 Line List : 8 1 MemoryBitWalk 10 0 400000 31 1 64 : PASS f Program9 : MemoryDMA Board : dbpci#0 Line List : 9 1 MemoryDMA 10 0 400000 0 0 0 : PASS f Program10 : MemoryDMA Board : dbpci#0 Line List : 10 1 MemoryDMA 10 0 400000 0 ffffffff 0 : PASS f Program11 : MemoryDMA Board : dbpci#0 Line List : 11 1 MemoryDMA 10 0 400000 0 0 1 : PASS f Program12 : MemoryDMA Board : dbpci#0 Line List : 12 1 MemoryDMA 10 0 400000 0 ffffffff –1 : PASS f Program13 : MemoryDMA Board : dbpci#0 Line List : 13 1 MemoryDMA 10 0 400000 1 0 0 : PASS 4–19 OPERATOR CONSOLE CT HISPEED SERIES ADVANCED DIAGNOSTICS PROPRIETARY TO GENERAL ELECTRIC COMPANY REV 10 4-3 2202119 DIAGNOSTICS FOR NPRM AND DBPCI (continued) Table 4–7 DBPCI#0 – PCI Test (continued) NPRIF NPRM NPRS DBPCI f Program14 : MemoryDMA Board : dbpci#0 Line List : 14 1 MemoryDMA 10 0 400000 2 0 0 : PASS f Program15 : MemoryDMA Board : dbpci#0 Line List : 15 1 MemoryDMA 10 0 400000 0 0 0 : PASS Program16 : RegTestdb Board : dbpci#0 Line List : 16 1 RegTest 10 0 /usr/g/diag/data/bitwalk.dat 3fffffc 0 0 : PASS Program17 : RegTestdb Board : dbpci#0 Line List : 17 1 RegTest 10 4 /usr/g/diag/data/bitwalk.dat 3fffffc 0 0 : PASS Program18 : RegTestdb Board : dbpci#0 Line List : 18 1 RegTest 10 8 /usr/g/diag/data/bitwalk.dat 3fffffc 0 0 : PASS Program19 : RegTestdb Board : dbpci#0 Line List : 19 1 RegTest 10 10 /usr/g/diag/data/bitwalk.dat 3fffffc 0 0 : PASS Program20 : RegTestdb Board : dbpci#0 Line List : 20 1 RegTest 10 14 /usr/g/diag/data/bitwalk.dat 3fffffc 0 0 : PASS Program21 : RegTestdb Board : dbpci#0 Line List : 21 1 RegTest 10 20 /usr/g/diag/data/onoff.dat 1 0 0 : PASS 4–20 f f f f f f OPERATOR CONSOLE PROPRIETARY TO GENERAL ELECTRIC COMPANY CT HISPEED SERIES ADVANCED DIAGNOSTICS REV 10 4-4 2202119 AUTO POST RECON TEST If no error occurs in the power–up test or in Off Line Test described in Section 4-2 or 4-3, perform this Auto Post Recon Test. Select [Service] → [Diagnostics & analysis] → [Auto Post Recon Test], to display the Auto Post Recon Test menu. Illustration 4–9 Auto Post Recon Test Menu Click [Select Image ID], and [Image Browser], to display the image browser. In the image browser, select an image to be test–reconstructed, and then, click Accept. The image should have been reconstructed by the STND mode. Enter 1000. The recon operation will be repeated 1000 times. The recon test will be continued until an error occurs this setting times (or until the number of tests reaches the ‘No. of Test’ setting). After setting the parameters above, click OK (displayed below the above menu screen), and then, the Scan & Recon Parameters check display as in Illustration 4–10 appears. 4–21 OPERATOR CONSOLE PROPRIETARY TO GENERAL ELECTRIC COMPANY REV 10 4-4 CT HISPEED SERIES ADVANCED DIAGNOSTICS 2202119 AUTO POST RECON TEST (continued) Illustration 4–10 Recon Mode Check Check that the ‘Recon Mode’ is STND, otherwise, select an other image whose recon mode is STND, since an error will occur depending on the parameters such are STND+, Shoulder Arti = On, DFOV values. After checking the parameters above, click Confirm (displayed below the above check screen), and then, the recon test is executed and the result is displayed as in Illustration 4–11. 4–22 OPERATOR CONSOLE PROPRIETARY TO GENERAL ELECTRIC COMPANY CT HISPEED SERIES ADVANCED DIAGNOSTICS REV 10 4-4 2202119 AUTO POST RECON TEST (continued) Illustration 4–11 Test Result Display Each time if an error occurs, this number increases by 1. Error image information is displayed. If an error occurs in this recon test, the recon system is considered to be defective. In this case, however, since this recon test can not identify which unit is defective, you will have to execute the Off Line Test described in Section 4-2 or 4-3 again. If you can not identify a defective unit with the Off Line Test, you may have to troubleshoot other cause than the recon system. Check the raw data, for example. 4–23 OPERATOR CONSOLE PROPRIETARY TO GENERAL ELECTRIC COMPANY blank CT HISPEED SERIES ADVANCED DIAGNOSTICS 2202119 4–24 OPERATOR CONSOLE CT HISPEED SERIES ADVANCED DIAGNOSTICS PROPRIETARY TO GENERAL ELECTRIC COMPANY REV 13 2202119 TABLE/GANTRY TABLE OF CONTENTS SECTION PAGE SECTION 1 – LED DESCRIPTION . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 1–1 SECTION 2 – POWER–ON TEST . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 2–1 2-1 TGP BOARD POWER–ON TEST . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 2-1-1 Gantry Processor . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 2-1-2 Table Processor . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 2-1-3 Management Processor . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . OGP BOARD POWER–ON TEST . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 2–1 2–2 2–3 2–4 2–5 SECTION 3 – OFF–LINE TEST . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 3–1 2-2 3-1 TGP BOARD OFF–LINE TEST . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 3-1-1 Gantry Processor . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 3-1-2 Table Processor . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 3-1-3 Management Processor . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 3–1 3–2 3–3 3–6 SECTION 4 – ERROR MESSAGE . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 4–1 4-1 4-2 4-3 4-4 4-5 ERROR MESSAGE . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 4–1 ERRORS DETECTED BY TGP BOARD (FOR EARLIER THAN SYSTEM VERSION 6) ......................................................................... 4–3 ERRORS DETECTED BY TGP BOARD (FOR SYSTEM VERSION 6 OR LATER) . 4–18 ERRORS DETECTED BY OGP BOARD . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 4–35 ERRORS DETECTED BY DAS . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 4–48 i TABLE/GANTRY CT HISPEED SERIES ADVANCED DIAGNOSTICS PROPRIETARY TO GENERAL ELECTRIC COMPANY blank 2202119 ii TABLE/GANTRY PROPRIETARY TO GENERAL ELECTRIC COMPANY CT HISPEED SERIES ADVANCED DIAGNOSTICS REV 10 2202119 SECTION 1 – LED DESCRIPTION Table 1–1 LED (B)CONERR DTRF or DTRF2 LED Description Description Lights when an FPGA Configuration error occurs. (B)DSON Lights when ‘_DSON’ is active. (B)DSIN Lights when ‘_DSIN’ is active. +5V (B)DXFER ACK Lights while +5 VDC is supplied. Lights when ‘DXFER’ is active. Lights when ‘ACK’ is active. (DTRF and 2233745 DTRF2) Always OFF. (2233745–2 DTRF2) (B)CSTRB (B)FECERR Lights when a Taxi command (START, ENDOK, or ENDNG) is issued. Lights when an FEC encode error occurs. 1–1 TABLE/GANTRY PROPRIETARY TO GENERAL ELECTRIC COMPANY CT HISPEED SERIES ADVANCED DIAGNOSTICS REV 10 2202119 Table 1–2 TGP LED Description LED CHANGE Description Lights when adjustment data is not stored during the gantry or table adjustment. SVALM Lights when the servo amplifier (for gantry rotation) is in an alarm state. The type of the alarm is indicated on the LED on the amplifier; or, lights also when AC 200 V power is not supplied to the amplifier. ERRM Lights when detecting an error concerning processor communication or scan operations. Goes off when the TGP board is powered off or reset. ERRG Lights when detecting an error concerning gantry rotation operations. Goes off when the TGP board is powered off or reset. ERRT Lights when detecting an error concerning table or tilt operations. Goes off when the TGP board is powered off or reset. XGRAY Lights when the safety loop is closed on the TGP board, which indicates that the TGP board grants the power supply to the x–ray generator. LPM Blinks in a one–second cycle, indicating the interval timer operation for communication and scan operations. RQM Lights when the TGP board receives commands from the operator console and is executing them. MNM (Not used) GSF Lights when the rotation safety switches for gantry covers are set and the TGP board grants gantry rotation. LPG Blinks in a one–second cycle, indicating the interval timer operation for gantry rotation operations. RQG Lights when the TGP board receives commands on gantry rotation from the operator console and is executing them. TRG Indicates trigger pulses sent to the OGP board. LPT Blinks in a one–second cycle, indicating the interval timer operation for table and gantry tilt operations. RQT Lights when the TGP board receives commands on table or gantry tilt operations from the operator console and is executing them. MNT Lights when the table or gantry (tilt) is operated by the gantry panel switches. 1–2 TABLE/GANTRY PROPRIETARY TO GENERAL ELECTRIC COMPANY CT HISPEED SERIES ADVANCED DIAGNOSTICS REV 10 2202119 Table 1–3 OGP LED Description LED Description DS1 (TEST) Lights when an error occurs. DS2 (RINGS) MP–SP communication error. (MP: Management Processor on TGP board; SP: Scan Processor on OGP board) DS3 (DENTG) DENTG monitor. DS4 (EXPCMD) EXPCMD monitor. DS5(REQS) Lights during a task request. DS6 (LOOPS) Blinks at intervals of 0.5 sec. DS7 (ERRS) Lights when an error occurs. See also the following table showing which LED’s light when an error occurs. Table 1–4 Error and LED on OGP Board Error LED (The following LED’s light when the error written to the left occurs) RAM check error ERRS, LOOPS ROM check error ERRS Hang up (detected by the watchdog timer) ERRS, LOOPS, REQS, RINGS, TEST Hardware error while OGP receives data ERRS, RINGS ACK, NACK timeout ERRS, RINGS NACK detected for three times ERRS NACK transmitted ERRS Aperture error ERRS OGP event error ERRS Scan error ERRS XG processor communication error ERRS The ERRS LED goes off when the x–ray tube rotor starts to rotate. The RINGS LED will not go off until the OGP board is reset. 1–3 TABLE/GANTRY CT HISPEED SERIES ADVANCED DIAGNOSTICS PROPRIETARY TO GENERAL ELECTRIC COMPANY REV 10 2202119 Table 1–5 RF XMT LED Description LED LED1 Description Lights while power is supplied. The light color becomes red, when the RF XMT is not receiving data from the DTRF board. The light color becomes green, when the RF XMT is receiving data from the DTRF board (where, data is either das data during scans or sync pattern data during standby). Illustration 1–1 RF XMT LED1 Table 1–6 XMT LED Description LED Description POWER (green) Lights while power is supplied. SIGNAL Lights when data is prerent. (Transitin detector) Illustration 1–2 XMT SIGNAL POWER TRANSMITTER 1–4 TABLE/GANTRY CT HISPEED SERIES ADVANCED DIAGNOSTICS PROPRIETARY TO GENERAL ELECTRIC COMPANY REV 10 2202119 Table 1–7 RF RCV LED Description LED Power LED Description Lights (in green) while power is supplied to the RF shoe. (Power is supplied from the RF RCV to the RF shoe via a coaxial cable. The LED does not light if the cable is not correctly connected to the RF shoe, or if power is not supplied to the RF RCV itself.) AGC Center LED Lights (in green) when the level of the RF output power from the RF shoe is in the middle within the proper range. RF Output LEDs These LEDs are the indicator for the RF output power from the RF shoe. D Any one of the ten LEDs lights, normally according to gantry rotation. D LED colors: Right and left ends: red Middle two: green Others: yellow D When any LED on ‘Normal’ positions lights, it indicates that the RF output power is normal. D When any LED on ‘Service’ positions lights, it indicates that the RF output power is too weak or too strong. (In this case, inspect the RF shoe positioning, the power supply for the rotational gantry, or RF slip ring parts on the rotative side, etc.) Illustration 1–3 RF RCV Power LED AGC Center LED Power Low High RF Output LEDs Service Normal Service 1–5 TABLE/GANTRY CT HISPEED SERIES ADVANCED DIAGNOSTICS PROPRIETARY TO GENERAL ELECTRIC COMPANY REV 10 2202119 Table 1–8 RCV LED Description LED Description POWER (green) Lights while power is supplied. SIGNAL Lights when data is prerent. (Transitin detector) Illustration 1–4 RCV SIGNAL POWER RECEIVER 1–6 TABLE/GANTRY CT HISPEED SERIES ADVANCED DIAGNOSTICS PROPRIETARY TO GENERAL ELECTRIC COMPANY REV 10 2202119 Table 1–9 TEMP CONT LED Description LED Description ±0.5° C (LED1) Lights when the detector temperature is now ±0.5° C from the set temperature. ±2.0° C (LED2) Lights when the detector temperature is now ±2.0° C from the set temperature. HIGH ERR Lights when the detector temperature exceeds 40° C (error). (LED3) LOW ERR Lights when the thermistor is not connected. (LED4) SET ERR (LED5) HEATER Lights when the set temperature is not normal in the variable set temperature mode. Lights when the heater is turned on. (LED6) LOOP Normally blinks. Goes off when the microprocessor is hung–up. (LED7) Illustration 1–5 TEMP CONT ±0.5° C LED1 CN1 ±2.0° C LED2 HIGH ERR LED3 CN2 LOW ERR LED4 SET ERR LED5 HEATER 7 LEDs LED6 LOOP LED7 1–7 TABLE/GANTRY CT HISPEED SERIES ADVANCED DIAGNOSTICS PROPRIETARY TO GENERAL ELECTRIC COMPANY REV 10 2202119 Table 1–10 Servo Amp LED Description 7–segment LED Description – Servo Off 0 Servo On 1 Overcurrent 2 Overload 3 Overspeed 5 Abnormal driver temperature 6 Abnormal encoder 7 Abnormal driving power 9 Abnormal EEPROM Illustration 1–6 Servo Amp 7–segment LED CN1 CN2 CN3 TB2 1–8 TABLE/GANTRY CT HISPEED SERIES ADVANCED DIAGNOSTICS PROPRIETARY TO GENERAL ELECTRIC COMPANY REV 10 2202119 Table 1–11 Step Motor Driver LED Description LED Power LED Description Lights while power is supplied. Illustration 1–7 Step Motor Driver CN3 CN1 CN2 Power LED Table 1–12 IMS Motor Driver LED Description LED Ready (green) Alarm (red) Description Lights when servo operation is enabled. Lights in an alarm state. Illustration 1–8 IMS Motor Driver READY LED CN5 ALARM LED CN1 CN2 CN3 CN4 1–9 TABLE/GANTRY PROPRIETARY TO GENERAL ELECTRIC COMPANY blank CT HISPEED SERIES ADVANCED DIAGNOSTICS 2202119 1–10 TABLE/GANTRY CT HISPEED SERIES ADVANCED DIAGNOSTICS PROPRIETARY TO GENERAL ELECTRIC COMPANY REV 1 2202119 SECTION 2 – POWER–ON TEST 2-1 TGP BOARD POWER–ON TEST The TGP board includes the following three microprocessors. Processor Main Function Gantry Processor Controls gantry rotation. Table Processor Controls table and cradle operations and gantry tilt operation. Controls the gantry display, and interfaces the gantry panel switches. Management Processor Communicates with the operator console and the OGP board on the gantry rotative frame. Controls the IMS (Intermediate Support). After powering on or resetting the TGP board, each processor performs ROM based power–on tests in parallel, as described in Table 2–1. Table 2–1 TGP Power–on Test Gantry Processor Table Processor Management Processor RAM Check RAM Check RAM Check ↓ ↓ ↓ ROM Check ROM Check ROM Check ↓ ↓ Gantry Rotation Check and Azimuth Counter Initialization Gantry Display and Switch LED Check – ↓ – Gantry Tilt and Table Up/down Relay Check – (See Section 2-1-1 for details.) (See Section 2-1-2 for details.) (See Section 2-1-3 for details.) 2–1 TABLE/GANTRY PROPRIETARY TO GENERAL ELECTRIC COMPANY CT HISPEED SERIES ADVANCED DIAGNOSTICS REV 1 2-1-1 2202119 Gantry Processor RAM Check 1. The gantry processor (U87) performs read/write checks of its internal RAM, the external RAM (U92), and the dual port RAM (U77). 2. If a RAM check error occurs, the processor will stay in a hang up state, with the ERRG, LPG, RQG LED’s lighting on the TGP board. If no error occurs, the processor proceeds to the following step. ROM Check 3. The processor performs a data sum check on addresses 0 ∼ BFFF of the external ROM (U112). 4. If a ROM check error occurs, the processor will stay in a hang up state, with the ERRG, LPG, RQG LED’s lighting. If no error occurs, the LPG LED blinks, and the processor proceeds to the following step. Gantry Rotation Check and Azimuth Counter Initialization 5. The gantry processor starts rotating the gantry to check that the operation can be normally performed. a. If the SYS–OFF–MNL service switch (SW1) on the TGP board is set to OFF, the system waits until the switch is set to SYS or MNL, with the RQG and LPG LED’s alternately blinking. b. If power is not supplied to the servo amplifier, the rotation check is terminated, with the ERRG LED lighting. If any other abnormal conditions/operations are found, the rotation check is terminated. To start the rotation check anew, resolve the problems, and power on or reset the TGP board. 6. The gantry rotates at 15 sec/Rev, and the processor initializes the gantry azimuth counter with the GPLS1 signal. a. If the initialization of the counter is not performed within 25 sec, the rotation is terminated, with the ERRG LED lighting. 2–2 TABLE/GANTRY PROPRIETARY TO GENERAL ELECTRIC COMPANY CT HISPEED SERIES ADVANCED DIAGNOSTICS REV 1 2-1-2 2202119 Table Processor RAM Check 1. The table processor (U42) performs read/write checks of its internal RAM, the external RAM (U64), and the dual port RAM (U48). 2. If a RAM check error occurs, the processor will stay in a hang up state, with the ERRT, LPT, RQT, MNT LED’s lighting on the TGP board. If no error occurs, the processor proceeds to the following step. ROM Check 3. The processor performs a data sum check on addresses 0 ∼ DFFF of the external ROM (U68). 4. If a ROM check error occurs, the processor will stay in a hang up state, with the ERRT, RQT, MNT LED’s lighting. If no error occurs, the LPT LED blinks, and the processor proceeds to the following step. Gantry Display and Switch LED Check 5. The processor sequentially displays test characters (numbers) on the gantry display, and at the same time, sequentially lights gantry panel switch LED’s. Refer to the Rotational Operation section of Gantry, of the Functional Check / Adjustment manual. Gantry Tilt and Table Up/down Relay Check The gantry tilt or table up/down operation is performed by a pump/valve mechanism which is powered by AC 115 V. This power is conveyed through two relays connected in series on SUB BD. Refer to Illustration 2–1. With these connections, if one relay of the two failed (that is, always closed), the power flow can be cut off by the other relay. This check verifies these relay operations. 6. The processor closes one relay which is controlled by the enable lines, and verifies that the gantry tilt or table up/down does not take place. If the operation takes place, the other relay (direct) is considered to be failed (closed), since any key on the gantry switch panel is not pressed while the relay (enable) is activated; and an error message is displayed on the operator console (OC). 7. An LED blinks on the gantry switch panel, and then press the key with the LED blinking. If the corresponding operation takes place, the other relay (enable) is considered to be failed (closed), since the processor does not activate the relay (enable) while the key is pressed; and an error message is displayed on the OC. 2–3 TABLE/GANTRY CT HISPEED SERIES ADVANCED DIAGNOSTICS PROPRIETARY TO GENERAL ELECTRIC COMPANY REV 1 2-1-2 2202119 Table Processor (continued) Illustration 2–1 Safety by Double Relays SUB Board AC 115 V Gantry Tilt or Table Up/Down Direct Gantry Panel Switch Enable Table Processor TGP Board 2-1-3 Management Processor RAM Check 1. The management processor (U88) performs read/write checks of its internal RAM, the external RAM (U62), and the dual port RAM (U48, U77). 2. If a RAM check error occurs, the processor will stay in a hang up state, with one of ERRM, LPM, RQM, MNM LED’s lighting on the TGP board. If no error occurs, the processor proceeds to the following step. ROM Check 3. The processor performs a data sum check on addresses 0 ∼ BFFF of the external ROM (U111). 4. If a ROM check error occurs, the processor will stay in a hang up state, with the ERRM, RQM, MNM LED’s lighting. If no error occurs, the LPM LED blinks. 2–4 TABLE/GANTRY PROPRIETARY TO GENERAL ELECTRIC COMPANY CT HISPEED SERIES ADVANCED DIAGNOSTICS REV 1 2-2 2202119 OGP BOARD POWER–ON TEST The OGP board is equipped on the gantry rotative frame and includes a microprocessor called Scan Processor, and mainly performs the following controls in scan sequence, according to commands from the Management processor on the TGP board. D Scan control D DAS control D X–ray generator (JEDI) control D Aperture control D Positioning light control After powering on or resetting the OGP board, the scan processor performs ROM based power–on tests (RAM check → ROM check), as described below. RAM Check 1. The scan processor performs read/write checks of the external RAM and its internal RAM. 2. If a RAM check error occurs, the processor will stay in a hang up state, with the ERRS, LOOPS LED’s lighting on the OGP board. If no error occurs, the processor proceeds to the following step. ROM Check 3. The processor performs a data sum check of the external ROM. 4. If a ROM check error occurs, the processor will stay in a hang up state, with the ERRS LED lighting. If no error occurs, the LOOPS LED blinks. 2–5 TABLE/GANTRY PROPRIETARY TO GENERAL ELECTRIC COMPANY blank CT HISPEED SERIES ADVANCED DIAGNOSTICS 2202119 2–6 TABLE/GANTRY CT HISPEED SERIES ADVANCED DIAGNOSTICS PROPRIETARY TO GENERAL ELECTRIC COMPANY REV 12 2202119 SECTION 3 – OFF–LINE TEST 3-1 TGP BOARD OFF–LINE TEST Each of the TGP board processors (Gantry processor, Table processor, and Management processor) has its own off–line tests. These off–line tests are mainly used for adjustments or checks of the gantry or table subsystems. 1. To perform the off–line tests, set one of the following dip switch to ON for the corresponding processor. Refer to the Gantry/Table section of Switch/Jumper Setting of Boards/Devices, of the Functional Check / Adjustment manual. Dip Switch Processor G6 Gantry Processor T6 Table Processor M6 Management Processor CAUTION Do not perform off–line tests of two or three processors simultaneously. 2. Each off–line test consists of test programs as described in Table 3–1. The test program Nos. are displayed on the gantry Height display. Press the TEST1 switch on the TGP board to select a test program, as the test program No. increases every time the switch is pressed. Test program Nos. other than described in Table 3–1 are not defined or should not be used. On the Position display, data is displayed according to each test. 3. To restore the normal operations of the processors, set the corresponding dip switch to OFF. Table 3–1 TGP Off–line Test Test Program No. Gantry Processor Table Processor Management Processor 400, 401 000 ∼ 013 700 014 ∼ 020 022 ∼ 024 035 ∼ 037 (See Section 3-1-1 for each test program.) (See Section 3-1-2 for each test program.) 3–1 (See Section 3-1-3 for each test program.) TABLE/GANTRY CT HISPEED SERIES ADVANCED DIAGNOSTICS PROPRIETARY TO GENERAL ELECTRIC COMPANY REV 12 3-1-1 2202119 Gantry Processor Table 3–2 Gantry Processor Off–line Tests Test Program No. 400 Description Displays gantry azimuth in 0.1 deg. The x–ray tube home position (at 12 o’clock position) is defined as 180 deg., i.e., 1800. This test is used when ‘gantry rotation velocity offset’ is adjusted. 401 Displays gantry rotation speed in 1 msec/Rev. Used when ‘gantry rotation speed’ is adjusted. 3–2 TABLE/GANTRY CT HISPEED SERIES ADVANCED DIAGNOSTICS PROPRIETARY TO GENERAL ELECTRIC COMPANY REV 12 3-1-2 2202119 Table Processor Table 3–3 Table Processor Off–line Tests (No. 000 ∼ 013) Test Program No. Description 000 Used when FWD 30 deg. tilt angle is adjusted. 001 Used when BWD 30 deg. tilt angle is adjusted. 002 Displays output values of the analog–to–digital converter for the tilt angle potentiometer. By pressing the Range key, displays the tilt angle in 0.1 deg. The FWD 30.5 deg. position is defined as 0. 003 Used when the cradle Out limit position is adjusted. 004 Used when the cradle In limit position is adjusted. 005 Displays output values of the analog–to–digital converter for the cradle position potentiometer. By pressing the Range key, displays the cradle position in 0.5 mm. The Out mechanical limit position is defined as 0. 006 Used when the IMS (Intermediate Support) Out limit position is adjusted. 007 Used when the IMS In limit position is adjusted. 008 Displays output values of the analog–to–digital converter for the IMS position potentiometer. By pressing the Range key, displays the IMS position in 0.5 mm. The Out mechanical limit position is defined as 0. 009 Used when the table Down limit position is adjusted. 010 Used when the table Up limit position is adjusted. 011 Displays output values of the analog–to–digital converter for the table height position potentiometer. By pressing the Range key, displays the table height position in 0.5 mm. The Down mechanical limit position is defined as 1. 012 Used when ‘cradle compensation’ is adjusted. 013 (For TGP board of 2284399–*, or, 2156510–5 or later only) Used when compensating the incorrect interlock operation of table up/down and gantry tilt due to the incorrect height alignment of the gantry and table. 3–3 TABLE/GANTRY CT HISPEED SERIES ADVANCED DIAGNOSTICS PROPRIETARY TO GENERAL ELECTRIC COMPANY REV 12 3-1-2 2202119 Table Processor (continued) Table 3–4 Table Processor Off–line Tests (No. 014 ∼ 021) Test Program No. 014 Description Sets the cradle travel speed to 2 ∼ 150 mm/sec in increments of 2 mm/sec. Cradle Drive: Half–step drive. Operation: Press the In and Fast keys simultaneously to set faster speeds; or press the Out and Fast keys simultaneously to set slower speeds. Press the In or Out key to move the cradle in the In or Out direction. 015 Sets the cradle travel speed to 2 ∼ 44 mm/sec in increments of 2 mm/sec. Cradle Drive: Micro–step drive. Operation: Same as for Test Program No. 014. 016 Sets the cradle travel speed to 0.715 ∼ 42.86 mm/sec in increments of 0.715 mm/sec for helical scans (Scan Time: 0.7 sec). Cradle Drive, Operation: Same as for Test Program No. 015. 017 Sets the cradle travel speed to 0.625 ∼ 37.5 mm/sec in increments of 0.625 mm/sec for helical scans (Scan Time: 0.8 sec). Cradle Drive, Operation: Same as for Test Program No. 015. 018 Sets the cradle travel speed to 0.5 ∼ 30 mm/sec in increments of 0.5 mm/sec for helical scans (Scan Time: 1 sec). Cradle Drive, Operation: Same as for Test Program No. 015. 019 Sets the cradle travel speed to 0.33 ∼ 20 mm/sec in increments of 0.33 mm/sec for helical scans (Scan Time: 1.5 sec). Cradle Drive, Operation: Same as for Test Program No. 015. 020 Sets the cradle travel speed to 0.25 ∼ 15 mm/sec in increments of 0.25 mm/sec for helical scans (Scan Time: 2 sec). Cradle Drive, Operation: Same as for Test Program No. 015. 021 Not defined. 3–4 TABLE/GANTRY CT HISPEED SERIES ADVANCED DIAGNOSTICS PROPRIETARY TO GENERAL ELECTRIC COMPANY REV 12 3-1-2 2202119 Table Processor (continued) Table 3–5 Table Processor Off–line Tests (No. 022 ∼ 037) Test Program No. Description 022 Displays counts of the cradle position encoder pulses while the gantry rotates from the home position to the home position during helical scans (Helical interval check). (1 pulse: 0.1 mm) 023 Displays outputs of the up/down counter for the cradle position encoder pulses. (1 pulse: 0.1 mm) 024 Displays outputs of the up/down counter for the IMS (Intermediate Support) position encoder pulses. (1 pulse: 0.1 mm) 025 ∼ 034 035 Not defined. (For TGP board of 2284399–*, or, 2156510–5 or later only) Used when setting the lowest table height allowed. 036 (For TGP board of 2284399–*, or, 2156510–5 or later only) Used when setting the most extended cradle In–position allowed. 037 (For TGP board of 2284399–*, or, 2156510–6 or later only) Used when adjusting the cradle position control according to the positioning light position. 3–5 TABLE/GANTRY CT HISPEED SERIES ADVANCED DIAGNOSTICS PROPRIETARY TO GENERAL ELECTRIC COMPANY REV 12 3-1-3 2202119 Management Processor Table 3–6 Management Processor Off–line Test Test Program No. 700 Description Displays operation status of the management processor while the processor receives commands from the operator console and is executing them; as defined below: bit7 bit6 bit5 bit4 bit3 bit2 0 Com. req. Tilt mode Cradle Gantry Apt mode mode mode bit1 bit0 XG mode Scan mode The above is displayed as a tetra–number (increases like 0, 1, 2, 3, 11, 12, 13, 21, ...). Example: If Gantry Mode, Aperture Mode, and XG Mode are requested, the following will be displayed: Height: 700 Pos.: 0032 3–6 TABLE/GANTRY PROPRIETARY TO GENERAL ELECTRIC COMPANY CT HISPEED SERIES ADVANCED DIAGNOSTICS REV 13 2202119 SECTION 4 – ERROR MESSAGE 4-1 ERROR MESSAGE The errors described in Table 4–1 through 4–53 are detected by the TGP, OGP, or CIF board. When an error occurs, the error information is sent to the operator console (OC) using the Status communication. Error with no Error Message If either of the following errors occur, the microprocessor on the TGP or OGP board are forced to run in an infinite loop, and no error message is sent to the OC. D RAM, ROM check error: These checks are performed during a power–up sequence. D Processor hang up: This is detected by the watchdog timer at intervals of 10.9 msec. 4–1 TABLE/GANTRY PROPRIETARY TO GENERAL ELECTRIC COMPANY REV 13 4-1 CT HISPEED SERIES ADVANCED DIAGNOSTICS 2202119 ERROR MESSAGE (continued) Error Class The errors detected by the TGP, OGP, or CIF board are either classified as Error Class, or Information Class, according to below: D Error: If an error of this ‘Error’ class occurs during a scan, the scan is aborted, and an error message is displayed on the OC monitor. D Information (written as ‘Infor.’ in Table 4–1 ∼ 4–53): If an error of this ‘Information’ class occurs during a scan, the scan will be continued, and an error message is not displayed on the OC monitor. Communication via Slip Rings (RS422) The scan processor on the OGP board communicates with the management processor on the TGP board via slip rings. Normally, when one of the two processors receives communication data from the other processor, the receiving processor checks a checksum data, and sends back an ACK message to the sender, if the data is OK; otherwise, sends back a NACK message. When the sender receives this NACK message, it resends the data. If this repeats three times (three NACK’s), the communication is regarded as an error. If the receiver does not send ACK nor NACK within a specified time, this also is regarded as an error communication. 4–2 TABLE/GANTRY CT HISPEED SERIES ADVANCED DIAGNOSTICS PROPRIETARY TO GENERAL ELECTRIC COMPANY REV 13 4-2 2202119 ERRORS DETECTED BY TGP BOARD (FOR EARLIER THAN SYSTEM VERSION 6) Note For systems with system software version 6 or later, see Section 4-3, Errors Detected by TGP Board (for System Version 6 or Later). Table 4–1 Error Code Code 0D 11–1001–0D Table 4–2 Scan Error Name Interlock X–ray. Class Description Potential Cause / FRU Error TGP received SCAN CMD while relay(RL1) in Gantry Rear Switch Box is energized. 1. Other equipment connected with relay(RL1) is unexpectedly active(H).; 2. Cable connection between RL1 and other equipment(M). Class Description Potential Cause / FRU Helical Scan Error Error Code Code Name 11 12–1001–11 Cradle Out of Limit. (TP) Error Cradle position out of limit on Helical SCAN CMD. 1. Cradle Potentiometer; 2. IMS potentiometer 12 12–1001–12 Cradle Unlatch. (TP) Error Cradle unlatch was detected on Helical SCAN CMD. 1. Accidental push on Latch Switch.; 2. Cabling between Latch Switch and TGP including TBLCON BD and TBL BD. 13 12–1001–13 Cradle Slip. (TP) Error Cradle slip was detected during Helical Scan. 1. Patient movement during Helical Scan or some obstacles on bottom of cradle or cradle roller.; 2. Cradle Encoder 14 10–0001–14 Undefined Infor. – – 15 12–1001–15 Cradle Start Position Error. (TP) Error Cradle start position is out of specification on Helical Scan. Cradle Stepping Motor Belt or Cradle Stepping Motor 16 12–1001–16 Interval Position Error. (TP) Error Cradle Interval is out of specification on Helical 1. Patient movement during Helical Scan or Scan. some obstacles on bottom of cradle or cradle roller.; 2. Cradle Encoder (continued) 4–3 TABLE/GANTRY CT HISPEED SERIES ADVANCED DIAGNOSTICS PROPRIETARY TO GENERAL ELECTRIC COMPANY REV 13 4-2 2202119 ERRORS DETECTED BY TGP BOARD (FOR EARLIER THAN SYSTEM VERSION 6) (continued) Table 4–2 Helical Scan Error (continued) Error Code Code 17 12–1001–17 Cradle Move Time Out. (TP) Error Cradle acceleration/deceleration time out. Or total cradle movement time out on Helical Scan. 1. Patient movement at the beginning of Helical Scan.; 2. Cradle Stepping Motor Belt or Cradle Stepping Motor 18 12–1001–18 OC Command Error. (TP) Error TGP(MP) received unspecified Helical SCAN CMD from OC. Take a best guess and good luck. 19 11–1001–19 SCINITREQ Time Out. (MP) Error TGP(MP) did not receive SCINTREQ from TGP(TP) on Helical Scan. Cradle Stepping Motor Belt or Cradle Stepping Motor 1A 11–1001–1A OGP Com Not Ready in 1 sec. (MP) Error Communication with OGP is not ready after 1sec during Helical SCAN CMD. TGP 1B 11–1001–1B TP Com Not Ready in 1 sec. (MP) Error Communication with TGP(TP) is not ready after 1sec during Helical SCAN CMD. TGP 1C 10–0001–1C Undefined Infor. – – 1D 10–0001–1D Undefined Infor. – – 1E 10–0001–1E Undefined Infor. – – 1F 12–1001–1F Cradle Potentio Error. (TP) Error Unexpected input from Cradle Potentiometer during Helical Scan. Cradle Potentiometer or Cabling between TGP and Cradle Potentiometer. Name Class Description 4–4 Potential Cause / FRU TABLE/GANTRY CT HISPEED SERIES ADVANCED DIAGNOSTICS PROPRIETARY TO GENERAL ELECTRIC COMPANY REV 13 4-2 2202119 ERRORS DETECTED BY TGP BOARD (FOR EARLIER THAN SYSTEM VERSION 6) (continued) Table 4–3 Scout Scan Error Error Code Code 41 12–1001–41 Cradle Out of Limit. (TP) Error Cradle position out of limit on Scout SCAN CMD. 1. Cradle Potentiometer; 2. IMS potentiometer 42 12–1001–42 Cradle Unlatch. (TP) Error Cradle unlatch was detected on Scout SCAN CMD. 1. Accidental push on Latch Switch.; 2. Cabling between Latch Switch and TGP including TBLCON BD and TBL BD. 43 12–1001–43 Cradle Slip. (TP) Error Cradle slip was detected during Scout Scan. 1. Patient movement during Scout Scan or some obstacles on bottom of cradle or cradle roller.; 2. Cradle Encoder 44 10–0001–44 Undefined Infor. – – 45 12–1001–45 Cradle Start Position Error. (TP) Error Cradle start position is out of specification on Scout Scan. Cradle Stepping Motor Belt or Cradle Stepping Motor 46 10–0001–46 Undefined Infor. – – 47 12–1001–47 Cradle Move Time Out. (TP) Error Cradle acceleration/deceleration time out. Or Cradle Stepping Motor Belt or Cradle Stepping total cradle movement time out on Scout Scan. Motor 48 10–0001–48 Undefined Infor. – – 49 11–1001–49 SCINITREQ Time Out. (MP) Error TGP(MP) did not receive SCINTREQ from TGP(TP) on Scout Scan. TGP 4A 11–1001–4A OGP Com Not Ready in 1 sec. (MP) Error Communication with OGP is not ready after 1sec during Scout SCAN CMD. TGP 4B 11–1001–4B TP Com Not Ready in 1 sec. (MP) Error Communication with TP is not ready after 1sec TGP during Scout SCAN CMD. 4C 11–1001–4C Offset Scan Time Out. (MP) Error TGP did not receive OFFSET END from OGP on Scout Scan. Name Class Description Potential Cause / FRU OGP or TGP/OGP interface which includes Slip Ring. (continued) 4–5 TABLE/GANTRY CT HISPEED SERIES ADVANCED DIAGNOSTICS PROPRIETARY TO GENERAL ELECTRIC COMPANY REV 13 4-2 2202119 ERRORS DETECTED BY TGP BOARD (FOR EARLIER THAN SYSTEM VERSION 6) (continued) Table 4–3 Scout Scan Error (continued) Error Code Code 4D 10–0001–4D Undefined Infor. – – 4E 11–1001–4E Scout Scan Time Out. (MP) Error TGP did not receive SCAN END from OGP on Scout Scan. OGP or TGP/OGP interface which includes Slip Ring. 4F 12–1001–4F Cradle Potentio Error. (TP) Error Unexpected input from Cradle Potentiometer during Scout Scan. Cradle Potentiometer or Cabling between TGP and Cradle Potentiometer. Name Class Description 4–6 Potential Cause / FRU TABLE/GANTRY CT HISPEED SERIES ADVANCED DIAGNOSTICS PROPRIETARY TO GENERAL ELECTRIC COMPANY REV 13 4-2 2202119 ERRORS DETECTED BY TGP BOARD (FOR EARLIER THAN SYSTEM VERSION 6) (continued) Table 4–4 Fluoro Scan Error Error Code Code 51 10–0001–51 Undefined Infor. – – 52 10–0001–52 Undefined Infor. – – 53 10–0001–53 Undefined Infor. – – 54 10–0001–54 Undefined Infor. – – 55 10–0001–55 Undefined Infor. – – 56 10–0001–56 Undefined Infor. – – 57 10–0001–57 Undefined Infor. – – 58 11–1001–58 XRAY–on timeout. (MP) Error mA/kV status was not received from OGP in response to Fluoro SCAN CMD. JEDI(kV control or CT–IF), or interface between JEDI and OGP. 59 11–1001–59 XRAY–off timeout. (MP) Error mA/kV status from OGP did not stop when X–ray Foot SW is off during Fluoro Scan. JEDI(kV control) 5A 11–1001–5A OGP Com is not ready in 1sec. (MP) Error Communication with OGP is not ready after 1sec during Fluoro SCAN CMD. TGP 5B 10–0001–5B Undefined Infor. – – 5C 11–1001–5C Fluoro scan command in normal mode. (MP) Error Fluoro SCAN CMD is received from OC when NFIX is not in Fluoro mode. NFIX or TGP/NFIX interface 5D 11–1001–5D X–SW is not on for 1sec before scan command. (MP) Error Fluoro SCAN CMD is received from OC after X–ray Foot SW is off. NFIX or Cabling between TGP and NFIX 5E 11–1001–5E Scan command has come while GNTRY button is pushed . (MP) Error Fluoro SCAN CMD is received while Gantry button is pushed. Take a best guess and good luck. 5F 10–0001–5F Undefined Infor. – – Name Class Description 4–7 Potential Cause / FRU TABLE/GANTRY CT HISPEED SERIES ADVANCED DIAGNOSTICS PROPRIETARY TO GENERAL ELECTRIC COMPANY REV 13 4-2 2202119 ERRORS DETECTED BY TGP BOARD (FOR EARLIER THAN SYSTEM VERSION 6) (continued) Table 4–5 Gantry Req Error Error Code Code Name Class 1 13–1002–01 Gantry Request Command Error. (GP) Error Unspecified GNTRY CMD was received from OC. Mismatched version between TGP firmware and OC software. 2 13–1002–02 Gantry Set Time Out in 20 sec. (GP) Error Gantry position or rotation speed is not ready in 20sec after GNTRY CMD from OC. 1. Servo Amp; 2. Axial Motor 3 13–1002–03 Axial Motor Over Heat. (GP) Error Axial Motor over heat is detected. 1. Axial Motor; 2. SUB BD 4 13–1002–04 Servo Amp Alarm. (GP) Error Servo Amp alarm is detected. 1. Too many acceleration/deceleration in short duration.; 2. Servo Amp; 3. Axial Motor 5 13–1002–05 Gantry Not System Mode. (GP) Error Switch of TGP is not set as system mode. Switch of TGP is not set as system mode. 6 13–1002–06 Gantry Rotate Not Response. (GP) Error No feedback from Axial motor encoder was detected after Gantry rotation request. 1. Service Switch on SUB BD is set.; 2. 24V Power Supply; 3. Servo Amp; 4. Axial Motor; 5. Cabling between Axial Motor and TGP 7 13–1002–07 Gantry Rotate Over Speed. (GP) Error Gantry rotation speed is over specification. 1. Rotation Speed Adjustment; 2. Servo Amp; 3. TGP 8 13–1002–08 Gantry Rotate Under Speed. (GP) Error Gantry rotation speed is under specification. 1. Rotation Speed Adjustment; 2. Servo Amp; 3. TGP 9 13–1002–09 Cover Safty SW Open. (GP) Error Gantry Cover Switch is open and Axial Motor is not powered. 1. Alignment between Gantry cover and Gantry Cover Switch; 2. Gantry Cover Switch and its cabling to TGP A 13–1002–0A Dynamic Break On. (GP) Error GNTRY CMD was received while Axial Motor dynamic break working. Take a best guess and good luck. B 13–1002–0B Gantry Init Error or Position Error. (GP) Error Gantry was not initialized correctly. Or azimuth counter on TGP is overflow. 1. G–Pulse1(M); 2. TGP; 3. Cabling between G–Pulse1 and TGP Description Potential Cause / FRU (continued) 4–8 TABLE/GANTRY CT HISPEED SERIES ADVANCED DIAGNOSTICS PROPRIETARY TO GENERAL ELECTRIC COMPANY REV 13 4-2 2202119 ERRORS DETECTED BY TGP BOARD (FOR EARLIER THAN SYSTEM VERSION 6) (continued) Table 4–5 Gantry Req Error (continued) Error Code Code C 10–0002–0C Undefined Infor. – – D 10–0002–0D Undefined Infor. – – E 11–1002–0E Gantry 130sec(180s at Smartview) timer is timeout on TGP. (MP) Error Gantry continues to rotate over 130sec without 1. Cabling between TGP and OC; 2. OC could GNTRY CMD nor SCAN CMD from OC. not send GNTRY CMD nor SCAN CMD to TGP. F 11–1002–0F Gantry init timeout ack=100ms rdy=7sec. (MP) Error TGP did not receive reply from OGP in response to Gantry initialize request. Name Class Description 4–9 Potential Cause / FRU 1. G–Pulse2; 2. OGP or TGP/OGP interface which includes Slip Ring. TABLE/GANTRY CT HISPEED SERIES ADVANCED DIAGNOSTICS PROPRIETARY TO GENERAL ELECTRIC COMPANY REV 13 4-2 2202119 ERRORS DETECTED BY TGP BOARD (FOR EARLIER THAN SYSTEM VERSION 6) (continued) Table 4–6 Gantry Req Error Code2 Error Code Code 1 13–1002–11 Over Current. Over Current Error was detected on Servo Amp. 1. Servo AMP; 2. Axial Motor 2 13–1002–12 Over Load. Over Load Error was detected on Servo Amp. 1. Gantry acceleration/deceleration too frequent.; 2. Servo AMP; 3. Axial Motor 3 13–1002–13 Over Speed. Over Speed Error was detected on Servo Amp. Servo AMP 4 10–0002–14 Undefined – – 5 13–1002–15 Abnormal Servo Amp Temparature. Servo Amp. Temperature is out of specification. Servo AMP 6 13–1002–16 Abnormal Encorder Output from Axial Motor Encoder is out of specification. 1. Axial Motor; 2. Servo Amp 7 13–1002–17 Abnormal Driving Power. Driving Power of Servo Amp is out of specification. 1. Servo AMP; 2. Axial Motor 8 10–0002–18 Undefined – – 9 13–1002–19 Abnormal EEPROM. Abnormal EEPROM error was detected on Servo Amp. 1. Servo AMP A 10–0002–1A Undefined Infor. – – B 10–0002–1B Undefined Infor. – – C 10–0002–1C Undefined Infor. – – D 10–0002–1D Undefined Infor. – – E 10–0002–1E Undefined Infor. – – F 10–0002–1F Undefined Infor. – – Name Class Infor. Infor. Description 4–10 Potential Cause / FRU TABLE/GANTRY CT HISPEED SERIES ADVANCED DIAGNOSTICS PROPRIETARY TO GENERAL ELECTRIC COMPANY REV 13 4-2 2202119 ERRORS DETECTED BY TGP BOARD (FOR EARLIER THAN SYSTEM VERSION 6) (continued) Table 4–7 Cradle Req Error Error Code Code 1 12–1030–01 Cradle Out of Limit. Cradle position out of limit on CRADLE CMD. 1. Cradle Potentiometer; 2. IMS Potentiometer 2 12–1030–02 Cradle Unlatch. Cradle unlatch was detected on CRADLE CMD. 1. Accidental push on Latch Switch.; 2. Cabling between Latch Switch and TGP including TBLCON BD and TBL BD. 3 12–1003–03 Cradle Slip. Cradle slip was detected in response to CRADLE CMD. 1. Patient movement during cradle movement or some obstacles on bottom of cradle or cradle roller.; 2. Cradle Encoder 4 10–0003–04 Undefined – – 5 12–1003–05 Out of Scannable Range. Scannable range is zero because table position is too low. 1. Table position is too low. Raise table to higher position.; 2. Table Height Potentiometer 6 10–0003–06 Undefined – – 7 12–1003–07 Cradle Move Time Out. Cradle acceleration/deceleration time out. Or total cradle movement time out in response to CRADLE CMD. Cradle Stepping Motor Belt or Cradle Stepping Motor 8 10–0003–08 Undefined Infor. – – 9 10–0003–09 Undefined Infor. – – A 10–0003–0A Undefined Infor. – – B 10–0003–0B Undefined Infor. – – C 10–0003–0C Undefined Infor. – – D 10–0003–0D Undefined Infor. – – E 10–0003–0E Undefined Infor. – – F 12–1003–0F Cradle Potentio Error. Unexpected input from Cradle Potentiometer in response to CRADLE CMD. Cradle Potentiometer or Cabling between TGP and Cradle Potentiometer. Name Class Infor. Infor. Description 4–11 Potential Cause / FRU TABLE/GANTRY CT HISPEED SERIES ADVANCED DIAGNOSTICS PROPRIETARY TO GENERAL ELECTRIC COMPANY REV 13 4-2 2202119 ERRORS DETECTED BY TGP BOARD (FOR EARLIER THAN SYSTEM VERSION 6) (continued) Table 4–8 Tilt Req Error Error Code Code 1 12–1004–01 Out of Tilt Range. Error Out of Tilt range on TILT CMD. Tilt Potentiometer or IMS Potentiometer 2 12–1004–02 Touch Sensor On. Error Gantry Touch Sensor ON was detected during remote tilt. Bring tilt position back by a few angle to recover. 1. Gantry Touch Sensor; 2. FCV BD or RCV BD 3 12–1004–03 Already Home Key On or FWD/BWD Key On. Error TILT CMD was received from OC during Home/FWD/BWD is ON. – 4 12–0004–04 Home Key On or FWD/BWD(COUNTER DIRECTION) Key On. Error Home/FWD/BWD is pushed during remote–tilting. And Home/FWD/BWD was prioritized as the result. – 5 12–0004–05 FWD/BWD(SAME DIRECTION) Key Off. Error Home/FWD/BWD is released during remote– tilting and Home/FWD/BWD was prioritized as the result. – 6 12–1004–06 Interlock or Movement Error. Error Interlock was detected during remote–tilting. Tilt Potentiometer or IMS Potentiometer 7 12–1004–07 OCTILT Line Off. Error OCTILT line from OC was detected OFF but TILT STOP CMD from OC was not received. 1. OC could not send Tilt Stop CMD to TGP in time.; 2. OC Keyboard. 8 12–1004–08 Tilt Req TimeOut 68 sec. Error Total tilting time from start tilting to end was over specified duration. Tilt Valve or Tilt Pump 9 10–0004–09 Undefined Infor. – – A 10–0004–0A Undefined Infor. – – B 10–0004–0B Undefined Infor. – – Name Class Description Potential Cause / FRU (continued) 4–12 TABLE/GANTRY CT HISPEED SERIES ADVANCED DIAGNOSTICS PROPRIETARY TO GENERAL ELECTRIC COMPANY REV 13 4-2 2202119 ERRORS DETECTED BY TGP BOARD (FOR EARLIER THAN SYSTEM VERSION 6) (continued) Table 4–8 Tilt Req Error (continued) Error Code Code C 10–0004–0C Undefined Infor. – – D 10–0004–0D Undefined Infor. – – E 10–0004–0E Undefined Infor. – – F 10–0004–0F Undefined Infor. – – Table 4–9 Name Class Description Potential Cause / FRU Manual Table Error Error Code Code Name Class Description 1 12–1005–01 Single fault in T/G movement, Please call service. Error Tilt BWD/FWD movement or Table UP/DWN movement is detected during key switch test on Gantry initialization. 1. KEY SW L or R on Gantry Cover may have the falure and stay ON.; 2. SUB BD 2 10–0005–02 Undefined Infor. – – 3 10–0005–03 Undefined Infor. – – 4 10–0005–04 Undefined Infor. – – 5 10–0005–05 Undefined Infor. – – 6 12–1005–06 IMS POTENTIO error. Error Unexpected input from IMS Potentiometer dur- IMS Potentiometer or Cabling between TGP ing manual IMS movement. and IMS Potentiometer. 7 12–1005–07 CRADLE POTENTIO error. Error Unexpected input from Cradle Potentiometer during manual cradle movement. 4–13 Potential Cause / FRU Cradle Potentiometer or Cabling between TGP and Cradle Potentiometer. TABLE/GANTRY CT HISPEED SERIES ADVANCED DIAGNOSTICS PROPRIETARY TO GENERAL ELECTRIC COMPANY REV 13 4-2 2202119 ERRORS DETECTED BY TGP BOARD (FOR EARLIER THAN SYSTEM VERSION 6) (continued) Table 4–10 Scan Processor Communication Error Error Code Code 1 11–1010–01 Nack Detected 3 Times. Error TGP(MP) received the message ’Not Acknowl- TGP or OGP edged’ from OGP more than 3 times. 2 11–1010–02 Ack/Nack Time Out. Error TGP(MP) did not receive neither ACK nor NACK from OGP. OGP or TGP/OGP interface which includes Slip Ring. 3 11–1010–03 SP is not wake up. Error TGP(MP) did not receive any reply from OGP in response to SysConfig CMD. OGP or TGP/OGP interface which includes Slip Ring. 4 10–0010–04 Undefined Infor. – – 5 10–0010–05 Undefined Infor. – – 6 10–0010–06 Undefined Infor. – – 7 10–0010–07 Undefined Infor. – – Name Class Description 4–14 Potential Cause / FRU TABLE/GANTRY CT HISPEED SERIES ADVANCED DIAGNOSTICS PROPRIETARY TO GENERAL ELECTRIC COMPANY REV 13 4-2 2202119 ERRORS DETECTED BY TGP BOARD (FOR EARLIER THAN SYSTEM VERSION 6) (continued) Table 4–11 Gantry Processor Communication Error Error Code Code 1 11–1013–01 Nack Detected 3 Times. Error TGP(MP) received the message ’Not Acknowl- TGP edged’ from TGP(GP) more than 3 times. 2 11–1013–02 Ack/Nack Time Out. Error TGP(MP) did not receive neither ACK nor NACK from TGP(GP). TGP 3 11–1013–03 GP is not wake up. Error TGP(MP) did not receive any reply from TGP(GP) in response to SysConfig CMD. Gantry Initialization did not complete correctly.; 1. TGP; 2. G–Pulse1; 3. Cabling between TGP and G–Pluse1; 4. Servo Amp or Axial Motor 4 11–0013–04 Undefined Infor. – – 5 11–0013–05 Undefined Infor. – – 6 11–0013–06 Undefined Infor. – – 7 11–0013–07 Undefined Infor. – – Name Class Description 4–15 Potential Cause / FRU TABLE/GANTRY CT HISPEED SERIES ADVANCED DIAGNOSTICS PROPRIETARY TO GENERAL ELECTRIC COMPANY REV 13 4-2 2202119 ERRORS DETECTED BY TGP BOARD (FOR EARLIER THAN SYSTEM VERSION 6) (continued) Table 4–12 Table Processor Communication Error Error Code Code 1 11–1012–01 Nack Detected 3 Times. Error TGP(MP) received the message ’Not Acknowl- TGP edged’ from TGP(TP) more than 3 times. 2 11–1012–02 Ack/Nack Time Out. Error TGP(MP) did not receive neither ACK nor NACK from TGP(TP). TGP 3 11–1012–03 TP is not wakeup. Error TGP(MP) did not receive any reply from TGP(TP) in response to SysConfig CMD. TGP 4 11–0012–04 Undefined Infor. – – 5 11–0012–05 Undefined Infor. – – 6 11–0012–06 Undefined Infor. – – 7 11–0012–07 Undefined Infor. – – Table 4–13 Name Class Description Potential Cause / FRU TGP Task Time Out Error Error Code Code Name Class 1 11–10F0–01 Scan Mode Time Out. Error TGP(MP) did not receive any reply from OGP in response to SCAN CMD. OGP or TGP/OGP interface which includes Slip Ring. 2 11–10F0–02 XG Mode Time Out. Error TGP(MP) did not receive any reply from OGP in response to XG CMD. OGP or TGP/OGP interface which includes Slip Ring. 3 11–10F0–03 Aperture Mode Time Out. Error TGP(MP) did not receive any reply from OGP in response to APERTURE CMD. OGP or TGP/OGP interface which includes Slip Ring. Description Potential Cause / FRU (continued) 4–16 TABLE/GANTRY CT HISPEED SERIES ADVANCED DIAGNOSTICS PROPRIETARY TO GENERAL ELECTRIC COMPANY REV 13 4-2 2202119 ERRORS DETECTED BY TGP BOARD (FOR EARLIER THAN SYSTEM VERSION 6) (continued) Table 4–14 TGP Task Time Out Error Error Code Code 4 11–10F0–04 Gantry Mode Time Out. Error TGP(MP) did not receive any reply from TGP(GP) in response to GNTRY CMD. TGP 5 11–10F0–05 Cradle Mode Time Out. Error TGP(MP) did not receive any reply from TGP(TP) in response to CRADLE CMD. TGP 6 11–10F0–06 Tilt Mode Time Out. Error TGP(MP) did not receive any reply from TGP(TP) in response to TILT CMD. TGP 7 11–10F0–07 Test Mode Time Out. Error TGP(MP) did not receive any reply from OGP in response to TEST MODE CMD. OGP or TGP/OGP interface which includes Slip Ring. Table 4–15 Error Code Code 1 11–10F1–01 Table 4–16 Error Code Code 1 11–10F2–01 Name Class Description Potential Cause / FRU TGP not System Name TGP Not System. Class Error Description Potential Cause / FRU TGP is not set as System Mode. Set TGP switch(SW1) correctly. Safety Loop Open Name SAFETY LOOP OPEN. Class Description Error mA/kV status was not received from OGP during X–ray ON. Or X–ray OFF Status was not received correctly from OGP. Safety Loop was opened by TGP as the result. 4–17 Potential Cause / FRU JEDI(kV control or CT–IF) or interface between JEDI and TGP including OGP and Slip Ring. TABLE/GANTRY CT HISPEED SERIES ADVANCED DIAGNOSTICS PROPRIETARY TO GENERAL ELECTRIC COMPANY REV 13 4-3 2202119 ERRORS DETECTED BY TGP BOARD (FOR SYSTEM VERSION 6 OR LATER) Table 4–17 Scan Error Error Code Code 01 11–1001–01 Gantry–Transporter position is not initialized. Error TGP received SCAN CMD before initializing gantry transporter. Bring gantry transporter back to out end position. Scan operation before gantry position initializing. 02 11–1001–02 Table is not CT mode. Error ”TABLE READY” signal from Table is open on SCAN CMD Table system is powered off. Angles of Table– rotations are not directed to CT. Lateral position of Table top is not in center of Gantry–aperture. 03 11–1001–03 Table is moving during scan. Error ”TABLE MOVE” signal from Table is open on SCAN CMD Table movement button is pushed or Table movement is not locked during CT scanning. 04 11–1001–04 ”STOP CT” signal comes from Table on scan process. Error ”STOP CT” signal from the table is open on SCAN CMD. Reset the table from Emergency Stop status. STOP button of the Table is pushed. 05 11–1001–05 Undefined Infor. Undefined Error 06 11–1001–06 Undefined Infor. Undefined Error 07 11–1001–07 Undefined Infor. Undefined Error 08 11–1001–08 Undefined Infor. Undefined Error 09 11–1001–09 Undefined Infor. Undefined Error 0A 11–1001–0A Undefined Infor. Undefined Error 0B 11–1001–0B Undefined Infor. Undefined Error 0C 11–1001–0C Undefined Infor. Undefined Error 0D 11–1001–0D Interlock X–ray. Error TGP received SCAN CMD while relay(RL1) in Gantry Rear Switch Box is energized. Unexpected door interlock may cause this. 0E 11–1001–0E Undefined Infor. Undefined Error 0F 11–1001–0F Undefined Infor. Undefined Error Name Class Description 4–18 Potential Cause / FRU 1. Other equipment connected with relay(RL1) is unexpectedly active(H).; 2. Cable connection between RL1 and other equipment(M). TABLE/GANTRY CT HISPEED SERIES ADVANCED DIAGNOSTICS PROPRIETARY TO GENERAL ELECTRIC COMPANY REV 13 4-3 2202119 ERRORS DETECTED BY TGP BOARD (FOR SYSTEM VERSION 6 OR LATER) (continued) Table 4–18 Helical Scan Error Error Code Code 11 12–1001–11 Cradle Out of Limit. (TP) Error Cradle position out of limit on Helical SCAN CMD. 1. Cradle Potentiometer; 2. IMS potentiometer 12 12–1001–12 Cradle Unlatch. (TP) Error Cradle unlatch was detected on Helical SCAN CMD. 1. Accidental push on Latch Switch.; 2. Cabling between Latch Switch and TGP including TBLCON BD and TBL BD. 13 12–1001–13 Cradle Slip. (TP) Error Cradle slip was detected during Helical Scan. 1. Patient movement during Helical Scan or some obstacles on bottom of cradle or cradle roller.; 2. Cradle Encoder 14 10–0001–14 Undefined Infor. Undefined Error 15 12–1001–15 Cradle Start Position Error. (TP) Error Cradle start position is out of specification on Helical Scan. 16 12–1001–16 Interval Position Error. (TP) Error Cradle Interval is out of specification on Helical 1. Patient movement during Helical Scan or Scan. some obstacles on bottom of cradle or cradle roller.; 2. Cradle Encoder 17 12–1001–17 Cradle Move Time Out. (TP) Error Cradle acceleration/deceleration time out. Or total cradle movement time out on Helical Scan. 1. Patient movement at the beginning of Helical Scan.; 2. Cradle Stepping Motor Belt or Cradle Stepping Motor 18 12–1001–18 OC Command Error. (TP) Error TGP(TP) received unspecified Helical SCAN CMD from OC. Take a best guess and good luck. 19 11–1001–19 SCINITREQ Time Out. (MP) Error TGP(MP) did not receive SCINTREQ from TGP(TP) on Helical Scan. Cradle Stepping Motor Belt or Cradle Stepping Motor 1A 11–1001–1A OGP Com Not Ready in 1 sec. (MP) Error Communication with OGP is not ready after 1sec during Helical SCAN CMD. TGP 1B 11–1001–1B TP Com Not Ready in 1 sec. (MP) Error Communication with TGP(TP) is not ready after 1sec during Helical SCAN CMD. TGP 1C 10–0001–1C Undefined Infor. Undefined Error Name Class Description Potential Cause / FRU Cradle Stepping Motor Belt or Cradle Stepping Motor (continued) 4–19 TABLE/GANTRY CT HISPEED SERIES ADVANCED DIAGNOSTICS PROPRIETARY TO GENERAL ELECTRIC COMPANY REV 13 4-3 2202119 ERRORS DETECTED BY TGP BOARD (FOR SYSTEM VERSION 6 OR LATER) (continued) Table 4–2 Helical Scan Error (continued) Error Code Code 1D 12–1001–1D Transporter Servo Alarm detected Error Servo Amp alarm is detected at the transporter. Any foreign objects on rails or linear guide, Servo Amp & Motor wiring, Brake is held. 1E 12–1001–1E Over Run Switch or Touch Sensor detected Error Over run limit switch of transporter or Gantry Touch Sensor ON was detected during Helical scan. Bring transporter position back by a few distance to recover. Anything touches on touch sensor during Helical scan. Gantry was located to overrun position manually. Any foreign objects on Overrun sensor. 1F 12–1001–1F Cradle Potentio Error. (TP) Error Unexpected input from Cradle Potentiometer during Helical Scan. Cradle Potentiometer or Cabling between TGP and Cradle Potentiometer. Name Class Description 4–20 Potential Cause / FRU TABLE/GANTRY CT HISPEED SERIES ADVANCED DIAGNOSTICS PROPRIETARY TO GENERAL ELECTRIC COMPANY REV 13 4-3 2202119 ERRORS DETECTED BY TGP BOARD (FOR SYSTEM VERSION 6 OR LATER) (continued) Table 4–19 Axial Scan Error Error Code Code 21 11–1001–21 OC Command Error. (MP) Error TGP(MP) received unspecified Respiratory SCAN CMD from OC. 22 11–1001–22 Gate Pulse Timeout. (MP) Error Respiratory Signal Timeout. (Continue H–LEV- TGP,NFIX,CONNECTION BOX, (Respiratory EL) Monitor) 23 11–1001–23 Gate Pulse Timeout. (MP) Error Respiratory Signal Timeout. (not detect rising edge) 24 11–1001–24 Undefined Infor. Undefined Error 25 11–1001–25 Undefined Infor. Undefined Error 26 11–1001–26 Undefined Infor. Undefined Error 27 11–1001–27 Undefined Infor. Undefined Error 28 11–1001–28 Undefined Infor. Undefined Error 29 11–1001–29 Undefined Infor. Undefined Error 2A 11–1001–2A OGP Com Not Ready in 1 sec. (MP) Error Communication with OGP is not ready after 1sec during Respiratory SCAN CMD. 2B 11–1001–2B Undefined Infor. Undefined Error 2C 11–1001–2C Undefined Infor. Undefined Error 2D 11–1001–2D Undefined Infor. Undefined Error 2E 11–1001–2E Undefined Infor. Undefined Error 24 11–1001–2F Undefined Infor. Undefined Error Name Class Description 4–21 Potential Cause / FRU Mismatched version between TGP firmware and OC software. TGP,NFIX,CONNECTION BOX, (Respiratory Monitor) TGP TABLE/GANTRY CT HISPEED SERIES ADVANCED DIAGNOSTICS PROPRIETARY TO GENERAL ELECTRIC COMPANY REV 13 4-3 2202119 ERRORS DETECTED BY TGP BOARD (FOR SYSTEM VERSION 6 OR LATER) (continued) Table 4–20 Scout Scan Error Error Code Code 41 12–1001–41 Cradle Out of Limit. (TP) Error Cradle position out of limit on Scout SCAN CMD. 1. Cradle Potentiometer; 2. IMS potentiometer 42 12–1001–42 Cradle Unlatch. (TP) Error Cradle unlatch was detected on Scout SCAN CMD. 1. Accidental push on Latch Switch.; 2. Cabling between Latch Switch and TGP including TBLCON BD and TBL BD. 43 12–1001–43 Cradle Slip. (TP) Error Cradle slip was detected during Scout Scan. 1. Patient movement during Scout Scan or some obstacles on bottom of cradle or cradle roller.; 2. Cradle Encoder 44 10–0001–44 Undefined Infor. Undefined Error 45 12–1001–45 Cradle Start Position Error. (TP) Error Cradle start position is out of specification on Scout Scan. Cradle Stepping Motor Belt or Cradle Stepping Motor 46 12–1001–46 Over Run Switch or Touch Sensor detected Error Over run limit switch of transporter or Gantry Touch Sensor ON was detected during Scout scan. Bring transporter position back by a few distance to recover. Anything touches on touch sensor during Scout scan. Gantry was located to overrun position manualy. Any foreign objects on Overrun sensor._-__-_ 47 12–1001–47 Cradle Move Time Out. (TP) Error Cradle acceleration/deceleration time out. Or Cradle Stepping Motor Belt or Cradle Stepping total cradle movement time out on Scout Scan. Motor 48 12–1001–48 Transporter Servo Alarm Error Servo Amp alarm is detected at the transporter. Any foreign objects on rails or linear guide, Servo Amp & Motor wireing, Brake is held._-_ 49 11–1001–49 SCINITREQ Time Out. (MP) Error TGP(MP) did not receive SCINTREQ from TGP(TP) on Scout Scan. TGP 4A 11–1001–4A OGP Com Not Ready in 1 sec. (MP) Error Communication with OGP is not ready after 1sec during Scout SCAN CMD. TGP 4B 11–1001–4B TP Com Not Ready in 1 sec. (MP) Error Communication with TP is not ready after 1sec TGP during Scout SCAN CMD. Name Class Description Potential Cause / FRU (continued) 4–22 TABLE/GANTRY CT HISPEED SERIES ADVANCED DIAGNOSTICS PROPRIETARY TO GENERAL ELECTRIC COMPANY REV 13 4-3 2202119 ERRORS DETECTED BY TGP BOARD (FOR SYSTEM VERSION 6 OR LATER) (continued) Table 4–3 Scout Scan Error (continued) Error Code Code Name Class Description 4C 11–1001–4C Offset Scan Time Out. (MP) Error TGP did not receive OFFSET END from OGP on Scout Scan. 4D 10–0001–4D Undefined Infor. Undefined Error 4E 11–1001–4E Scout Scan Time Out. (MP) Error TGP did not receive SCAN END from OGP on Scout Scan. OGP or TGP/OGP interface which includes Slip Ring. 4F 12–1001–4F Cradle Potentio Error. (TP) Error Unexpected input from Cradle Potentiometer during Scout Scan. Cradle Potentiometer or Cabling between TGP and Cradle Potentiometer. 4–23 Potential Cause / FRU OGP or TGP/OGP interface which includes Slip Ring. TABLE/GANTRY CT HISPEED SERIES ADVANCED DIAGNOSTICS PROPRIETARY TO GENERAL ELECTRIC COMPANY REV 13 4-3 2202119 ERRORS DETECTED BY TGP BOARD (FOR SYSTEM VERSION 6 OR LATER) (continued) Table 4–21 Fluoro Scan Error Error Code Code 51 10–0001–51 Undefined Infor. Undefined Error 52 10–0001–52 Undefined Infor. Undefined Error 53 10–0001–53 Undefined Infor. Undefined Error 54 10–0001–54 Undefined Infor. Undefined Error 55 10–0001–55 Undefined Infor. Undefined Error 56 10–0001–56 Undefined Infor. Undefined Error 57 10–0001–57 Undefined Infor. Undefined Error 58 11–1001–58 XRAY–on timeout. (MP) Error mA/kV status was not received from OGP in response to Fluoro SCAN CMD. JEDI(kV control or CT–IF), or interface between JEDI and OGP. 59 11–1001–59 XRAY–off timeout. (MP) Error mA/kV status from OGP did not stop when X–ray Foot SW is off during Fluoro Scan. JEDI(kV control) 5A 11–1001–5A OGP Com is not ready in 1sec. (MP) Error Communication with OGP is not ready after 1sec during Fluoro SCAN CMD. TGP 5B 10–0001–5B Undefined Infor. Undefined Error 5C 11–1001–5C Fluoro scan command in normal mode. (MP) Error Fluoro SCAN CMD is received from OC when NFIX is not in Fluoro mode. NFIX or TGP/NFIX interface 5D 11–1001–5D X–SW is not on for 1sec before scan command. (MP) Error Fluoro SCAN CMD is received from OC after X–ray Foot SW is off. NFIX or Cabling between TGP and NFIX 5E 11–1001–5E Scan command has come while GNTRY button is pushed . (MP) Error Fluoro SCAN CMD is received while Gantry button is pushed. Take a best guess and good luck. 5F 10–0001–5F Undefined Infor. Undefined Error Name Class Description 4–24 Potential Cause / FRU TABLE/GANTRY CT HISPEED SERIES ADVANCED DIAGNOSTICS PROPRIETARY TO GENERAL ELECTRIC COMPANY REV 13 4-3 2202119 ERRORS DETECTED BY TGP BOARD (FOR SYSTEM VERSION 6 OR LATER) (continued) Table 4–22 Gantry Req Error Error Code Code Name Class 1 13–1002–01 Gantry Request Command Error. (GP) Error Unspecified GNTRY CMD was received from OC. Mismatched version between TGP firmware and OC software. 2 13–1002–02 Gantry Set Time Out in 20 sec. (GP) Error Gantry position or rotation speed is not ready in 20sec after GNTRY CMD from OC. 1. Servo Amp; 2. Axial Motor 3 13–1002–03 Axial Motor Over Heat. (GP) Error Axial Motor over heat is detected. 1. Axial Motor; 2. SUB BD 4 13–1002–04 Servo Amp Alarm. (GP) Error Servo Amp alarm is detected. 1. Too many acceleration/deceleration in short duration.; 2. Servo Amp; 3. Axial Motor 5 13–1002–05 Gantry Not System Mode. (GP) Error Switch of TGP is not set as system mode. Switch of TGP is not set as system mode. 6 13–1002–06 Gantry Rotate Not Response. (GP) Error No feedback from Axial motor encoder was detected after Gantry rotation request. 1. Service Switch on SUB BD is set.; 2. 24V Power Supply; 3. Servo Amp; 4. Axial Motor; 5. Cabling between Axial Motor and TGP 7 13–1002–07 Gantry Rotate Over Speed. (GP) Error Gantry rotation speed is over specification. 1. Rotation Speed Adjustment; 2. Servo Amp; 3. TGP 8 13–1002–08 Gantry Rotate Under Speed. (GP) Error Gantry rotation speed is under specification. 1. Rotation Speed Adjustment; 2. Servo Amp; 3. TGP 9 13–1002–09 Cover Safty SW Open. (GP) Error Gantry Cover Switch is open and Axial Motor is not powered. 1. Alignment between Gantry cover and Gantry Cover Switch; 2. Gantry Cover Switch and its cabling to TGP A 13–1002–0A Dynamic Break On. (GP) Error GNTRY CMD was received while Axial Motor dynamic break working. Take a best guess and good luck. B 13–1002–0B Gantry Init Error or Position Error. (GP) Error Gantry was not initialized correctly. Or azimuth counter on TGP is overflow. 1. G–Pulse1(M); 2. TGP; 3. Cabling between G–Pulse1 and TGP C 10–0002–0C Undefined Infor. Undefined Error Description Potential Cause / FRU (continued) 4–25 TABLE/GANTRY CT HISPEED SERIES ADVANCED DIAGNOSTICS PROPRIETARY TO GENERAL ELECTRIC COMPANY REV 13 4-3 2202119 ERRORS DETECTED BY TGP BOARD (FOR SYSTEM VERSION 6 OR LATER) (continued) Table 4–5 Gantry Req Error (continued) Error Code Code D 10–0002–0D Undefined Infor. Undefined Error E 11–1002–0E Gantry 130sec(180s at Smartview) timer is timeout on TGP. (MP) Error Gantry continues to rotate over 130sec without 1. Cabling between TGP and OC; 2. OC could GNTRY CMD nor SCAN CMD from OC. not send GNTRY CMD nor SCAN CMD to TGP. F 11–1002–0F Gantry init timeout ack=100ms rdy=7sec. (MP) Error TGP did not receive reply from OGP in response to Gantry initialize request. Name Class Description 4–26 Potential Cause / FRU 1. G–Pulse2; 2. OGP or TGP/OGP interface which includes Slip Ring. TABLE/GANTRY CT HISPEED SERIES ADVANCED DIAGNOSTICS PROPRIETARY TO GENERAL ELECTRIC COMPANY REV 13 4-3 2202119 ERRORS DETECTED BY TGP BOARD (FOR SYSTEM VERSION 6 OR LATER) (continued) Table 4–23 Error Code Code 1 Gantry Req Error Code2 Name Class Description 13–1002–11 Over Current. Error Over Current Error was detected on Servo Amp. 1. Servo AMP; 2. Axial Motor 2 13–1002–12 Over Load. Error Over Load Error was detected on Servo Amp. 1. Gantry acceleration/deceleration too frequent.; 2. Servo AMP; 3. Axial Motor 3 13–1002–13 Over Speed. Error Over Speed Error was detected on Servo Amp. Servo AMP 4 10–0002–14 Undefined Informaiton Undefined Error 5 13–1002–15 Abnormal Servo Amp Temparature. Error Servo Amp. Temperature is out of specification. Servo AMP 6 13–1002–16 Abnormal Encorder Error Output from Axial Motor Encoder is out of specification. 1. Axial Motor; 2. Servo Amp 7 13–1002–17 Abnormal Driving Power. Error Driving Power of Servo Amp is out of specification. 1. Servo AMP; 2. Axial Motor 8 10–0002–18 Undefined Infor. Undefined Error 9 13–1002–19 Abnormal EEPROM. Error Abnormal EEPROM error was detected on Servo Amp. A 10–0002–1A Undefined Infor. Undefined Error B 10–0002–1B Undefined Infor. Undefined Error C 10–0002–1C Undefined Infor. Undefined Error D 10–0002–1D Undefined Infor. Undefined Error E 10–0002–1E Undefined Infor. Undefined Error F 10–0002–1F Undefined Infor. Undefined Error 4–27 Potential Cause / FRU 1. Servo AMP TABLE/GANTRY CT HISPEED SERIES ADVANCED DIAGNOSTICS PROPRIETARY TO GENERAL ELECTRIC COMPANY REV 13 4-3 2202119 ERRORS DETECTED BY TGP BOARD (FOR SYSTEM VERSION 6 OR LATER) (continued) Table 4–24 Cradle Req Error Error Code Code 1 12–1030–01 Cradle Out of Limit. Error Cradle position out of limit on CRADLE CMD. 1. Cradle Potentiometer; 2. IMS Potentiometer 2 12–1030–02 Cradle Unlatch. Error Cradle unlatch was detected on CRADLE CMD. 1. Accidental push on Latch Switch.; 2. Cabling between Latch Switch and TGP including TBLCON BD and TBL BD. 3 12–1003–03 Cradle Slip. Error Cradle slip was detected in response to CRADLE CMD. 1. Patient movement during cradle movement or some obstacles on bottom of cradle or cradle roller.; 2. Cradle Encoder 4 10–0003–04 Undefined Infor. Undefined Error 5 12–1003–05 Out of Scannable Range. Error Scannable range is zero because table position is too low. 6 10–0003–06 Undefined Infor. Undefined Error 7 12–1003–07 Cradle Move Time Out. Error Cradle acceleration/deceleration time out. Or total cradle movement time out in response to CRADLE CMD. 8 10–0003–08 Undefined Infor. Undefined Error 9 12–1003–09 ”STOP CT” signal comes from Table during transport process Error ”STOP CT” signal from the table is opening on Transport–CMD. / Reset the table from Emergency Stop status. STOP button of the Table is pushed. A 12–1003–0A Gantry–Transporter position is not initialized. Error TGP received Transport–CMD before initializing gantry transporter. Bring gantry transporter back to out end position. Gantry movement operation from Operator’s console before gantry position initializating. B 12–1003–0B Touch Sensor detected Error Gantry Touch Sensor ON was detected on transport–CMD. Bring transporter position back by a few distance to recover. Touch sensor on gantry or transporter. Anything touches on touch sensor during Gantry moving operation from Operator’s console. Name Class Description Potential Cause / FRU 1. Table position is too low. Raise table to higher position.; 2. Table Height Potentiometer Cradle Stepping Motor Belt or Cradle Stepping Motor (continued) 4–28 TABLE/GANTRY CT HISPEED SERIES ADVANCED DIAGNOSTICS PROPRIETARY TO GENERAL ELECTRIC COMPANY REV 13 4-3 2202119 ERRORS DETECTED BY TGP BOARD (FOR SYSTEM VERSION 6 OR LATER) (continued) Table 4–24 Cradle Req Error (continued) Error Code Code C 12–1003–0C Transporter Servo Alarm detected Error Servo Amp alarm is detected at the transporter. Any foreign objects on rails or linear guide, Servo Amp & Motor wiring, Brake is held. D 12–1003–0D Over Run Switch Error Over run limit switch of transporter was detected on transport. Gantry was located to overrun position manually. Any foreign objects on the overrun limit switch. E 10–0003–0E Undefined Infor. Undefined Error F 12–1003–0F Cradle Potentio Error. Error Unexpected input from Cradle Potentiometer in response to CRADLE CMD. Name Class Description 4–29 Potential Cause / FRU Cradle Potentiometer or Cabling between TGP and Cradle Potentiometer. TABLE/GANTRY CT HISPEED SERIES ADVANCED DIAGNOSTICS PROPRIETARY TO GENERAL ELECTRIC COMPANY REV 13 4-3 2202119 ERRORS DETECTED BY TGP BOARD (FOR SYSTEM VERSION 6 OR LATER) (continued) Table 4–25 Tilt Req Error Error Code Code 1 12–1004–01 Out of Tilt Range. Error Out of Tilt range on TILT CMD. Tilt Potentiometer or IMS Potentiometer 2 12–1004–02 Touch Sensor On. Error Gantry Touch Sensor ON was detected during remote tilt. Bring tilt position back by a few angle to recover. 1. Gantry Touch Sensor; 2. FCV BD or RCV BD 3 12–1004–03 Already Home Key On or FWD/BWD Key On. Error TILT CMD was received from OC during Home/FWD/BWD is ON. 4 12–0004–04 Home Key On or FWD/BWD(COUNTER DIRECTION) Key On. Infor. Home/FWD/BWD is pushed during remote–tilting. And Home/FWD/BWD was prioritized as the result. 5 12–0004–05 FWD/BWD(SAME DIRECTION) Key Off. Infor. Home/FWD/BWD is released during remote–tilting and Home/FWD/BWD was prioritized as the result. 6 12–1004–06 Interlock or Movement Error. Error Interlock was detected during remote–tilting. Tilt Potentiometer or IMS Potentiometer 7 12–1004–07 OCTILT Line Off. Error OCTILT line from OC was detected OFF but TILT STOP CMD from OC was not received. 1. OC could not send Tilt Stop CMD to TGP in time.; 2. OC Keyboard. 8 12–1004–08 Tilt Req TimeOut 68 sec. Error Total tilting time from start tilting to end was over specified duration. Tilt Valve or Tilt Pump 9 10–0004–09 Undefined Infor. Undefined Error A 10–0004–0A Undefined Infor. Undefined Error B 10–0004–0B Undefined Infor. Undefined Error C 10–0004–0C Undefined Infor. Undefined Error D 10–0004–0D Undefined Infor. Undefined Error E 10–0004–0E Undefined Infor. Undefined Error F 10–0004–0F Undefined Infor. Undefined Error Name Class Description 4–30 Potential Cause / FRU TABLE/GANTRY CT HISPEED SERIES ADVANCED DIAGNOSTICS PROPRIETARY TO GENERAL ELECTRIC COMPANY REV 13 4-3 2202119 ERRORS DETECTED BY TGP BOARD (FOR SYSTEM VERSION 6 OR LATER) (continued) Table 4–26 Manual Table Error Error Code Code 1 12–1005–01 Single fault in T/G movement, Please call service. Error Tilt BWD/FWD movement or Table UP/DWN movement is detected during key switch test on Gantry initialization. 1. KEY SW L or R on Gantry Cover may have the falure and stay ON.; 2. SUB BD 2 12–1005–02 Reference position error Error Reference position detection is out of order. Obstacles on Out Limit Switch or Reference position Limit Switch. Adjustment of reference position is not done correctly . Adjustment should be done in slow speed. 3 12–1005–03 Table does not reset relative position. Error CT does not receive ”Table all zero” after resetting the reference position of CT Table does not send the signal of ”Table All Zero”. Jumper switch is not correct. 4 12–1005–04 Transporter Servo Alarm detected Error Servo Amp alarm is detected at the transporter. Any foreign objects on rails or linear guide, Servo Amp & Motor wiring, Brake is held. 5 12–1005–05 Over Run Switch or Touch Sensor detected Error Over run limit switch of transporter or Gantry Touch Sensor ON was detected during manual movement. Bring transporter position back by a few distance to recover. Anything touches on touch sensor during manual movement. Gantry was located to overrun position manually. Any foreign objects on Overrun sensor. 6 12–1005–06 IMS POTENTIO error. Error Unexpected input from IMS Potentiometer dur- IMS Potentiometer or Cabling between TGP ing manual IMS movement. and IMS Potentiometer. 7 12–1005–07 CRADLE POTENTIO error. Error Unexpected input from Cradle Potentiometer during manual cradle movement. Name Class Description 4–31 Potential Cause / FRU Cradle Potentiometer or Cabling between TGP and Cradle Potentiometer. TABLE/GANTRY CT HISPEED SERIES ADVANCED DIAGNOSTICS PROPRIETARY TO GENERAL ELECTRIC COMPANY REV 13 4-3 2202119 ERRORS DETECTED BY TGP BOARD (FOR SYSTEM VERSION 6 OR LATER) (continued) Table 4–27 Scan Processor Communication Error Error Code Code 1 11–1010–01 Nack Detected 3 Times. Error TGP(MP) received the message ’Not Acknowl- TGP or OGP edged’ from OGP more than 3 times. 2 11–1010–02 Ack/Nack Time Out. Error TGP(MP) did not receive neither ACK nor NACK from OGP. OGP or TGP/OGP interface which includes Slip Ring. 3 11–1010–03 SP is not wake up. Error TGP(MP) did not receive any reply from OGP in response to SysConfig CMD. OGP or TGP/OGP interface which includes Slip Ring. 4 10–0010–04 Undefined Infor. Undefined Error 5 10–0010–05 Undefined Infor. Undefined Error 6 10–0010–06 Undefined Infor. Undefined Error 7 10–0010–07 Undefined Infor. Undefined Error Table 4–28 Name Class Description Potential Cause / FRU Gantry Processor Communication Error Error Code Code Name Class Description 1 11–1013–01 Nack Detected 3 Times. Error TGP(MP) received the message ’Not Acknowl- TGP edged’ from TGP(GP) more than 3 times. 2 11–1013–02 Ack/Nack Time Out. Error TGP(MP) did not receive neither ACK nor NACK from TGP(GP). TGP 3 11–1013–03 GP is not wake up. Error TGP(MP) did not receive any reply from TGP(GP) in response to SysConfig CMD. Gantry Initialization did not complete correctly.; 1. TGP; 2. G–Pulse1; 3. Cabling between TGP and G–Pluse1; 4. Servo Amp or Axial Motor 4 11–0013–04 Undefined Infor. Undefined Error 5 11–0013–05 Undefined Infor. Undefined Error 6 11–0013–06 Undefined Infor. Undefined Error 7 11–0013–07 Undefined Infor. Undefined Error 4–32 Potential Cause / FRU TABLE/GANTRY CT HISPEED SERIES ADVANCED DIAGNOSTICS PROPRIETARY TO GENERAL ELECTRIC COMPANY REV 13 4-3 2202119 ERRORS DETECTED BY TGP BOARD (FOR SYSTEM VERSION 6 OR LATER) (continued) Table 4–29 Table Processor Communication Error Error Code Code 1 11–1012–01 Nack Detected 3 Times. Error TGP(MP) received the message ’Not Acknowl- TGP edged’ from TGP(TP) more than 3 times. 2 11–1012–02 Ack/Nack Time Out. Error TGP(MP) did not receive neither ACK nor NACK from TGP(TP). TGP 3 11–1012–03 TP is not wakeup. Error TGP(MP) did not receive any reply from TGP(TP) in response to SysConfig CMD. TGP 4 11–1012–04 Undefined Infor. Undefined Error 5 11–1012–05 Undefined Infor. Undefined Error 6 11–1012–06 Undefined Infor. Undefined Error 7 11–1012–07 Undefined Infor. Undefined Error Name Class Description 4–33 Potential Cause / FRU TABLE/GANTRY CT HISPEED SERIES ADVANCED DIAGNOSTICS PROPRIETARY TO GENERAL ELECTRIC COMPANY REV 13 4-3 2202119 ERRORS DETECTED BY TGP BOARD (FOR SYSTEM VERSION 6 OR LATER) (continued) Table 4–30 TGP Task Time Out Error Error Code Code Name Class 1 11–10F0–01 Scan Mode Time Out. Error TGP(MP) did not receive any reply from OGP in response to SCAN CMD. OGP or TGP/OGP interface which includes Slip Ring. 2 11–10F0–02 XG Mode Time Out. Error TGP(MP) did not receive any reply from OGP in response to XG CMD. OGP or TGP/OGP interface which includes Slip Ring. 3 11–10F0–03 Aperture Mode Time Out. Error TGP(MP) did not receive any reply from OGP in response to APERTURE CMD. OGP or TGP/OGP interface which includes Slip Ring. 4 11–10F0–04 Gantry Mode Time Out. Error TGP(MP) did not receive any reply from TGP(GP) in response to GNTRY CMD. TGP 5 11–10F0–05 Cradle Mode Time Out. Error TGP(MP) did not receive any reply from TGP(TP) in response to CRADLE CMD. TGP 6 11–10F0–06 Tilt Mode Time Out. Error TGP(MP) did not receive any reply from TGP(TP) in response to TILT CMD. TGP 7 11–10F0–07 Test Mode Time Out. Error TGP(MP) did not receive any reply from OGP in response to TEST MODE CMD. OGP or TGP/OGP interface which includes Slip Ring. Table 4–31 Error Code Code 1 11–10F1–01 Table 4–32 Error Code Code 1 11–10F2–01 Description Potential Cause / FRU TGP not System Name TGP Not System. Class Error Description Potential Cause / FRU TGP is not set as System Mode. Set TGP switch(SW1) correctly. Safety Loop Open Name SAFETY LOOP OPEN. Class Description Error mA/kV status was not received from OGP during X–ray ON. Or X–ray OFF Status was not received correctly from OGP. Safety Loop was opened by TGP as the result. 4–34 Potential Cause / FRU JEDI(kV control or CT–IF) or interface between JEDI and TGP including OGP and Slip Ring. TABLE/GANTRY CT HISPEED SERIES ADVANCED DIAGNOSTICS PROPRIETARY TO GENERAL ELECTRIC COMPANY REV 13 4-4 2202119 ERRORS DETECTED BY OGP BOARD Table 4–33 XG Processor Communication Error Error Code Code 1 20–1014–01 XG Command Error Error XG CMD, sent from OGP, was rejected by JEDI because of unspecified mA/kV/focus/ scan time request. 2 20–0014–02 JEDI Wakeup time out. Infor. OGP did not receive any reply from JEDI in JEDI(kV control or CT–IF), or interface beresponse to SysConfig CMD nor JEDI Capabil- tween JEDI and OGP. ity Request CMD. 3 20–1014–03 No answer of mAkV. Error OGP did not receive reply from JEDI in response to mA/kV setup request. JEDI(kV control or CT–IF), or interface between JEDI and OGP. 4 20–0014–04 Received message with unknown ID. Infor. OGP received unspecified message from JEDI. Mismatched firmware version between JEDI(kV control) and OGP. 5 20–1014–05 CAN BUS OFF Status. Error CAN bus between JEDI and OGP becomes OFF Status because of too many communication Errors. JEDI(kV control or CT–IF), or interface between JEDI and OGP. 6 20–0014–06 CAN BUS Warning status. Infor. Some retries happened on CAN bus between JEDI and OGP and CAN bus becomes WARNING Status as the result. JEDI(kV control or CT–IF), or interface between JEDI and OGP. 7 20–0014–07 Return to normal from bus warning Infor. CAN bus between JEDI and OGP successfully – moved to NORMAL Status from OFF Status. Name Class Description 4–35 Potential Cause / FRU Mismatched firmware version between JEDI(kV control) and OGP. TABLE/GANTRY CT HISPEED SERIES ADVANCED DIAGNOSTICS PROPRIETARY TO GENERAL ELECTRIC COMPANY REV 13 4-4 2202119 ERRORS DETECTED BY OGP BOARD (continued) Table 4–34 Aperture Error Error Code Code Name 1 20–1020–01 Aperture Request Command Error. Error OGP received unspecified Aperture width from 1. DIPSW3 Setting of OGP; 2. Mismatched TGP(MP). version between OGP firmware and OC software. 2 20–1020–02 Aperture Reset Error. Error OGP could not detect Aperture reset position. 1. Aperture Assy; 2. Aperture Motor Driver; 3. Cabling between OGP and Aperture Photo Sensor or between OGP and Motor Driver 3 20–1020–03 Encorder Pulse Out of Range. Error Encoder pulse input from Aperture is out of specification while setting Aperture width. 1. Aperture Assy; 2. Aperture Motor Driver; 3. Cabling between OGP and Aperture Photo Sensor or between OGP and Motor Driver 4 20–1020–04 Z–AXIS control failed Error OGP did not receive READY status from CIF for z–axis collimator control or OGP detected Aperture is not ready. 1. CIF or interface between CIF and OGP.; 2. Motor Driver for z–axis control; 3. Photo Sensor for z–axis control; 4. Firmware version of OGP and CIF. 2D 20–0020–05 Undefined Infor. – – 2D 20–0020–06 Undefined Infor. – – 2D 20–0020–07 Undefined Infor. – – Class Description 4–36 Potential Cause / FRU TABLE/GANTRY CT HISPEED SERIES ADVANCED DIAGNOSTICS PROPRIETARY TO GENERAL ELECTRIC COMPANY REV 13 4-4 2202119 ERRORS DETECTED BY OGP BOARD (continued) Table 4–35 OGP Event Error Error Code Code 1 20–1030–01 Rotor On/Off Time Out. Error OGP did not receive any reply from JEDI in response to Rotor ON/OFF request. 1. Cabling between JEDI(kV control; CT–IF) and OGP; 2. Fuse on AC/DC; 3. AC/DC, LVPS, Rotor board or Heater Board 2 20–1030–02 DAS Trigger Error. Error DAS Trigger was out of specification during scan. Or no DAS Trigger was detected after GANTINTREQ. 1. Rotation Speed Adjustment.; 2. Cabling for DAS Trigger including Slip Ring. 3 20–1030–03 G–Pulse2 Error Error DAS Trigger in one rotation was out of specification during scan. Or no G–Pulse2 was detected. G–Pulse2 4 20–1030–04 Mismatch DIPSW(SW3) and system config. Error DIPSW3 on OGP is mismatched with SysCon- DIPSW3 setting on OGP fig CMD which was sent from TGP. 5 20–1030–05 3 times NACK Detected. Error OGP received the message ’Not Acknowledged’ from TGP or CIF more than 3 times. 1. TGP or CIF; 2. OGP 6 20–1030–06 System Config Error Error OGP received unspecified SysConfig from TGP. Mismatched version between OGP firmware and OC software 7 20–0030–07 DAS Wakeup Time Out. Infor. OGP did not receive any reply from CIF in response to SysConfig. CIF or interface between CIF and OGP. Name Class Description 4–37 Potential Cause / FRU TABLE/GANTRY CT HISPEED SERIES ADVANCED DIAGNOSTICS PROPRIETARY TO GENERAL ELECTRIC COMPANY REV 13 4-4 2202119 ERRORS DETECTED BY OGP BOARD (continued) Table 4–36 Axial Scan Error Error Code Code 21 20–1001–21 Scan Request Commamd Error. Error OGP received unspecified Axial Scan CMD from TGP. Mismatched version between OGP firmware and OC software. 22 20–1001–22 Offset Scan Time Out. Error DAS trigger for Offset Scan, generated by Axial Motor Encoder and measured in reference to G–Pulse2,. is out of specification or Offset Scan did not start or end in time on Axial Scan. 1. G–Pulse2; 2. Axial Motor Encoder or interface between this encoder and OGP including Slip Ring. 23 20–1001–23 X–ray On Response Time Out Error HV ON was not activated by JEDI on Axial Scan after EXPCMD was activated by OGP. High possibility on JEDI in case with XG error.; In case without XG Error, JEDI(kV control or CT–IF) and interface between JEDI and OGP 24 20–1001–24 X–ray Off Response Time Out Error HV ON was not inactivated by JEDI on Axial Scan after EXPCMD was inactivated by OGP. High possibility on JEDI in case with XG error.; In case without XG Error, JEDI(kV control or CT–IF) and interface between JEDI and OGP 25 20–1001–25 XG Ready Response Time Out. Error OGP did not receive XG Ready from JEDI on Axial Scan. High possibility on JEDI in case with XG error.; In case without XG Error, JEDI(kV control or CT–IF) and interface between JEDI and OGP 26 20–1001–26 DAS Trigger Less. Error DAS trigger of one rotation, between G– Pulse2, is under specification on Axial Scan. 1. G–Pulse2; 2. Axial Motor Encoder or interface between this encoder and OGP including Slip Ring. 27 20–1001–27 DAS Trigger Many Error DAS trigger of one rotation, between G– Pulse2, is over specification on Axial Scan. 1. G–Pulse2; 2. Axial Motor Encoder or interface between this encoder and OGP including Slip Ring. 28 20–1001–28 Aperture Error. Error Aperture width is out of specification on Axial Scan. 1. Aperture Assy; 2. Aperture Motor Driver; 3. Cabling between OGP and Aperture Photo Sensor or between OGP and Motor Driver Name Class Description Potential Cause / FRU (continued) 4–38 TABLE/GANTRY CT HISPEED SERIES ADVANCED DIAGNOSTICS PROPRIETARY TO GENERAL ELECTRIC COMPANY REV 13 4-4 2202119 ERRORS DETECTED BY OGP BOARD (continued) Table 4–36 Axial Scan Error (continued) Error Code Code Name Class Description 29 20–1001–29 Not Gantry Initialized. Error OGP received Axial SCAN CMD from TGP before DAS Trigger initialization by G–Pulse2. 2A 20–1001–2A EXPCMD On Backup Timer Error. Error The active time of EXPCMD is over Axial Scan 1. Rotation Speed Adjustment; 2. G–Pulse2; 3. time. JEDI 2B 20–1001–2B EXPCMD Unstable Error HV ON was activated by JEDI on Axial Scan when EXPCMD is not activated by OGP. 2C 20–1001–2C Scan Start Time Out. Error OGP could not detect count–up of DAS Trig1. OGP; 2. Axial Motor Encoder or interface ger after received Axial SCAN CMD from TGP. between this encoder and OGP including Slip Ring. 2D 20–0001–2D Undefined Infor. – – 2E 20–0001–2E Undefined Infor. – – 2F 20–1001–2F FPGA Counter Error Error DAS Trigger read out error on Axial Scan. OGP 4–39 Potential Cause / FRU G–Pulse2 1. OGP; 2. JEDI; 3. Cabling between JEDI(kV control; CT–IF) and OGP TABLE/GANTRY CT HISPEED SERIES ADVANCED DIAGNOSTICS PROPRIETARY TO GENERAL ELECTRIC COMPANY REV 13 4-4 2202119 ERRORS DETECTED BY OGP BOARD (continued) Table 4–37 Stationary Scan Error Error Code Code 31 20–1001–31 Scan Request Commamd Error. Error OGP received unspecified Stationary Scan CMD from TGP. Mismatched version between OGP firmware and OC software. 32 20–1001–32 Offset Scan Time Out. Error Offset Scan did not start or end in specified duration on Stationary Scan. This is measured by internal timer of OGP. OGP 33 20–1001–33 X–ray On Response Time Out Error HV ON was not activated by JEDI on Stationary Scan after EXPCMD was activated by OGP. High possibility on JEDI in case with XG error.; In case without XG Error, JEDI(kV control or CT–IF) and interface between JEDI and OGP 34 20–1001–34 X–ray Off Response Time Out Error HV ON was not inactivated by JEDI on Stationary Scan after EXPCMD was inactivated by OGP. High possibility on JEDI in case with XG error.; In case without XG Error, JEDI(kV control or CT–IF) and interface between JEDI and OGP 35 20–1001–35 XG Ready Response Time Out. Error OGP did not receive XG Ready from JEDI on Stationary Scan. High possibility on JEDI in case with XG error.; In case without XG Error, JEDI(kV control or CT–IF) and interface between JEDI and OGP 36 20–1001–36 DAS Trigger Less. Error DAS trigger, generated and measured by inter- OGP nal timer of OGP, is under specification on Stationary Scan. 37 20–1001–37 DAS Trigger Many Error DAS trigger, generated and measured by inter- OGP nal timer of OGP is over specification on Stationary Scan. 38 20–1001–38 Aperture Error. Error Aperture width is out of specification on Stationary Scan. Name Class Description Potential Cause / FRU 1. Aperture Assy; 2. Aperture Motor Driver; 3. Cabling between OGP and Aperture Photo Sensor or between OGP and Motor Driver (continued) 4–40 TABLE/GANTRY CT HISPEED SERIES ADVANCED DIAGNOSTICS PROPRIETARY TO GENERAL ELECTRIC COMPANY REV 13 4-4 2202119 ERRORS DETECTED BY OGP BOARD (continued) Table 4–38 Stationary Scan Error (continued) Error Code Code 39 20–0001–39 Undefined Infor. – – 3A 20–1001–3A EXPCMD On Backup Timer Error. Error The active time of EXPCMD is over Stationary Scan time. 1. OGP; 2. JEDI 3B 20–1001–3B EXPCMD Unstable Error HV ON was activated by JEDI on Stationary Scan when EXPCMD is not activated by OGP. 1. OGP; 2. JEDI; 3. Cabling between JEDI(kV control; CT–IF) and OGP 3C 20–1001–3C Scan Start Time Out. Error OGP could not detect count–up of DAS Trigger after received Stationary SCAN CMD from TGP. DAS Trigger is generated by OGP internally. OGP 3D 20–0001–3D Undefined Infor. – – 3E 20–0001–3E Undefined Infor. – – 3F 20–1001–3F FPGA Counter Error Error DAS Trigger read out error on Stationary Scan. OGP Name Class Description 4–41 Potential Cause / FRU TABLE/GANTRY CT HISPEED SERIES ADVANCED DIAGNOSTICS PROPRIETARY TO GENERAL ELECTRIC COMPANY REV 13 4-4 2202119 ERRORS DETECTED BY OGP BOARD (continued) Table 4–39 Helical Scan Error Error Code Code 11 20–1001–11 Scan Request Commamd Error. Error OGP received unspecified Helical Scan CMD from TGP. Mismatched version between OGP firmware and OC software. 12 20–1001–12 Offset Scan Time Out. Error Offset Scan did not start or end in specified duration on Helical Scan. OGP 13 20–1001–13 X–ray On Response Time Out Error HV ON was not activated by JEDI on Helical Scan after EXPCMD was activated by OGP. High possibility on JEDI in case with XG error.; In case without XG Error, JEDI(kV control or CT–IF) and interface between JEDI and OGP 14 20–1001–14 X–ray Off Response Time Out Error HV ON was not inactivated by JEDI on Helical Scan after EXPCMD was inactivated by OGP. High possibility on JEDI in case with XG error.; In case without XG Error, JEDI(kV control or CT–IF) and interface between JEDI and OGP 15 20–1001–15 XG Ready Response Time Out. Error OGP did not receive XG Ready from JEDI on Helical Scan. High possibility on JEDI in case with XG error.; In case without XG Error, JEDI(kV control or CT–IF) and interface between JEDI and OGP 16 20–1001–16 DAS Trigger Less. Error DAS trigger of one rotation, between G– Pulse2, is under specification on Helical Scan. 1. G–Pulse2; 2. Axial Motor Encoder or interface between this encoder and OGP including Slip Ring. 17 20–1001–17 DAS Trigger Many Error DAS trigger of one rotation, between G– Pulse2, is over specification on Helical Scan. 1. G–Pulse2; 2. Axial Motor Encoder or interface between this encoder and OGP including Slip Ring. 18 20–1001–18 Aperture Error. Error Aperture width is out of specification on Helical 1. Aperture Assy; 2. Aperture Motor Driver; 3. Scan. Cabling between OGP and Aperture Photo Sensor or between OGP and Motor Driver 19 20–1001–19 Not Gantry Initialized. Error OGP received Helical SCAN CMD from TGP before DAS Trigger initialization by G–Pulse2. Name Class Description Potential Cause / FRU G–Pulse2 (continued) 4–42 TABLE/GANTRY CT HISPEED SERIES ADVANCED DIAGNOSTICS PROPRIETARY TO GENERAL ELECTRIC COMPANY REV 13 4-4 2202119 ERRORS DETECTED BY OGP BOARD (continued) Table 4–39 Helical Scan Error (continued) Error Code Code Name Class 1A 20–1001–1A EXPCMD On Backup Timer Error. Error The active time of EXPCMD is over Helical Scan time. 1. Rotation Speed Adjustment; 2. G–Pulse2; 3. JEDI 1B 20–1001–1B EXPCMD Unstable Error HV ON was activated by JEDI on Helical Scan when EXPCMD is not activated by OGP. 1. OGP; 2. JEDI; 3. Cabling between JEDI(kV control; CT–IF) and OGP 1C 20–1001–1C Scan Start Time Out. Error OGP did not receive SCINTREQ from TGP in specified duration. OGP could not start scanning as the result. TGP or interface between OGP and TGP including Slip Ring. 1D 20–0001–1D Undefined Infor. – – 1E 20–0001–1E Undefined Infor. – – 1F 20–1001–1F FPGA Counter Error Error DAS Trigger read out error on Helical Scan. OGP Description 4–43 Potential Cause / FRU TABLE/GANTRY CT HISPEED SERIES ADVANCED DIAGNOSTICS PROPRIETARY TO GENERAL ELECTRIC COMPANY REV 13 4-4 2202119 ERRORS DETECTED BY OGP BOARD (continued) Table 4–40 Scout Scan Error Error Code Code 41 20–1001–41 Scan Request Commamd Error. Error OGP received unspecified command from TGP on Scout Scan. Take a best guess and good luck. 42 20–1001–42 Offset Scan Time Out. Error Offset Scan did not start or end in specified duration on Scout Scan, This is measured by internal timer of OGP. OGP 43 20–1001–43 X–ray On Response Time Out. Error HV ON was not activated by JEDI on Scout Scan after EXPCMD was activated by OGP. High possibility on JEDI in case with XG error.; In case without XG Error, JEDI(kV control or CT–IF) and interface between JEDI and OGP 44 20–1001–44 X–ray Off Response Time Out. Error HV ON was not inactivated by JEDI on Scout Scan after EXPCMD was inactivated by OGP. High possibility on JEDI in case with XG error.; In case without XG Error, JEDI(kV control or CT–IF) and interface between JEDI and OGP 45 20–1001–45 XG Ready Response Time Out. Error OGP did not receive XG Ready from JEDI on Scout Scan. High possibility on JEDI in case with XG error.; In case without XG Error, JEDI(kV control or CT–IF) and interface between JEDI and OGP 46 20–1001–46 DAS Trigger Less. Error DAS trigger, generated by cradle encoder and measured by internal timer of OGP, is under specification on Scout Scan. 1. Cradle Encoder; 2. Cradle Speed Adjustment; 3. Interface between OGP and Cradle Encoder including Slip Ring and TGP. 47 20–1001–47 DAS Trigger Many. Error DAS trigger, generated by cradle encoder and measured by internal timer of OGP is over specification on Scout Scan. 1. Cradle Encoder; 2. Cradle Speed Adjustment; 3. Interface between OGP and Cradle Encoder including Slip Ring and TGP. 48 20–1001–48 Aperture Error. Error Aperture width is out of specification on Scout Scan. 1. Aperture Assy; 2. Aperture Motor Driver; 3. Cabling between OGP and Aperture Photo Sensor or between OGP and Motor Driver Name Class Description Potential Cause / FRU (continued) 4–44 TABLE/GANTRY CT HISPEED SERIES ADVANCED DIAGNOSTICS PROPRIETARY TO GENERAL ELECTRIC COMPANY REV 13 4-4 2202119 ERRORS DETECTED BY OGP BOARD (continued) Table 4–40 Scout Scan Error (continued) Error Code Code 49 20–1001–49 Not gantry Initialized Error OGP received Scout SCAN CMD from TGP before DAS Trigger initialization. G–Pulse2 4A 20–1001–4A EXPCMD On Backup Timer Error Error The active time of EXPCMD is over Scout Scan time. 1. Cradle Speed Adjustment; 2. JEDI 4B 20–1001–4B EXPCMD Unstable Error HV ON was activated by JEDI on Scout Scan when EXPCMD is not activated by OGP. 1. OGP; 2. JEDI; 3. Cabling between JEDI(kV control; CT–IF) and OGP 4C 20–1001–4C Scan start Time Out. Error OGP did not detect count–up of DAS Trigger after received Scout SCAN CMD from TGP. DAS Trigger is generated by Cradle Encoder. 1. Cradle Encoder; 2. Interface between OGP and Cradle Encoder including Slip Ring and TGP. 2D 20–0001–4D Undefined Infor. – – 2D 20–0001–4E Undefined Infor. – – 2D 20–0001–4F Undefined Infor. – – Name Class Description 4–45 Potential Cause / FRU TABLE/GANTRY CT HISPEED SERIES ADVANCED DIAGNOSTICS PROPRIETARY TO GENERAL ELECTRIC COMPANY REV 13 4-4 2202119 ERRORS DETECTED BY OGP BOARD (continued) Table 4–41 Fluoro Scan Error Error Code Code 51 20–1001–51 Scan Request Commamd Error. Error OGP received unspecified command from TGP on Fluoro Scan. Take a best guess and good luck. 52 20–1001–52 Offset Scan Time Out. Error Offset Scan did not start or end in specified duration on Fluoro Scan. OGP 53 20–1001–53 X–ray On Response Time Out. Error HV ON was not activated by JEDI on Fluoro Scan after EXPCMD was activated by OGP. High possibility on JEDI in case with XG error.; In case without XG Error, JEDI(kV control or CT–IF) and interface between JEDI and OGP 54 20–1001–54 X–ray Off Response Time Out. Error HV ON was not inactivated by JEDI on Fluoro Scan after EXPCMD was inactivated by OGP. High possibility on JEDI in case with XG error.; In case without XG Error, JEDI(kV control or CT–IF) and interface between JEDI and OGP 55 20–1001–55 XG Ready Response Time Out. Error OGP did not receive XG Ready from JEDI on Fluoro Scan. High possibility on JEDI in case with XG error.; In case without XG Error, JEDI(kV control or CT–IF) and interface between JEDI and OGP 56 20–1001–56 DAS Trigger Less. Error DAS trigger of one rotation, between G– Pulse2, is under specification on Fluoro Scan. 1. G–Pulse2; 2. Axial Motor Encoder or interface between this encoder and OGP including Slip Ring. 57 20–1001–57 DAS Trigger Many. Error DAS trigger of one rotation, between G– Pulse2, is over specification on Fluoro Scan. 1. G–Pulse2; 2. Axial Motor Encoder or interface between this encoder and OGP including Slip Ring. 58 20–1001–58 Aperture Error. Error Aperture width is out of specification on Fluoro Scan. 1. Aperture Assy; 2. Aperture Motor Driver; 3. Cabling between OGP and Aperture Photo Sensor or between OGP and Motor Driver Name Class Description Potential Cause / FRU (continued) 4–46 TABLE/GANTRY CT HISPEED SERIES ADVANCED DIAGNOSTICS PROPRIETARY TO GENERAL ELECTRIC COMPANY REV 13 4-4 2202119 ERRORS DETECTED BY OGP BOARD (continued) Table 4–41 Error Code Code 59 20–1001–59 5A Fluoro Scan Error (continued) Name Class Description NOT Gantry Initialized. Error OGP received Fluoro SCAN CMD from TGP before DAS Trigger initialization by G–Pulse2. G–Pulse2 20–1001–5A EXPCMD On Backup Timer Error. Error The active time of EXPCMD is over Fluoro Scan time. 1. Rotation Speed Adjustment; 2. G–Pulse2; 3. JEDI 5B 20–1001–5B EXPCMD Unstable Error HV ON was activated by JEDI on Fluoro Scan when EXPCMD is not activated by OGP. 1. OGP; 2. JEDI; 3. Cabling between JEDI(kV control; CT–IF) and OGP 5C 20–1001–5C Scan Start Time Out. Error OGP could not detect count–up of DAS Trigger after received Fluoro SCAN CMD from TGP. 1. OGP; 2. Axial Motor Encoder or interface between this encoder and OGP including Slip Ring. 5D 20–1001–5D HV ON command time out. Error X–ray Foot SW was inactivated on Fluoro Scan before receiving X–ray Foot SW OFF Status from TGP. 1. TGP or interface between TGP and OGP including Slip Ring 5E 20–1001–5E Fluoro Scan Backup Timer _-_Time Out. Error OGP detected HV ON time out during Tap Mode or Continuous Mode. High possibility on JEDI or Rotation Speed Adjustment in case with XG error.; In case without XG Error, JEDI(kV control or CT–IF) and interface between JEDI and OGP. 5F 20–1001–5F FPGA Counter Error Error DAS Trigger read out error on Fluoro Scan. OGP 4–47 Potential Cause / FRU TABLE/GANTRY CT HISPEED SERIES ADVANCED DIAGNOSTICS PROPRIETARY TO GENERAL ELECTRIC COMPANY REV 13 4-5 2202119 ERRORS DETECTED BY DAS Table 4–42 Error Code Code 1 30–1010–01 2 DAS Error Class Description Zero Detect. Error Zero DAS data was detected. 1. CAM; 2. CIF; 2. DDP 30–0010–02 Over Range Infor. DAS data Over Range was detected. 1. Reduce scan technic.; 2. CAM, CIF or DDP 3 30–0010–03 Undefined Infor. – – 4 30–0010–04 Undefined Infor. – – 5 30–0010–05 Undefined Infor. – – 6 30–0010–06 Undefined Infor. – – 7 30–1010–07 Communication error Error Unexpected length or checksum of command was detected during communication between CIF and OGP. 1. Cable connection between OGP and DAS; 2. OGP or CIF Table 4–43 Error Code Name Potential Cause / FRU Z CH CAL Error (Z–axis Collimator) Code Name Class Description Potential Cause / FRU 0101 30–0101–01 – Infor. CIF received unspecified Qcal Ratio Data from Mismatched version between CIF and OC OC on SysConfig. software. 0102 30–0101–02 – Infor. CIF could not receive all Qcal Ratio Data from OC on SysConfig. 4–48 Interface between CIF and OC including Slip Ring. TABLE/GANTRY CT HISPEED SERIES ADVANCED DIAGNOSTICS PROPRIETARY TO GENERAL ELECTRIC COMPANY REV 13 4-5 2202119 ERRORS DETECTED BY DAS (continued) Table 4–44 Error Code Beam Tracking Para Error (Z–axis Collimator) Code Name Class Description Potential Cause / FRU 0201 30–1102–01 – Error CIF received unspecified Aperture width from OC on XG CMD. Mismatched version between CIF and OC software. 0202 30–1102–02 – Error CIF could not find Qcal Ratio Data for current Aperture on XG CMD. Failed to receive all Qcal Ratio Data from OC during SysConfig.; Or mismatched version between CIF and OC software. 0301 30–1103–01 – Error CIF received unspecified Scan Time from OC on Scan CMD. Mismatched version between CIF and OC software. Table 4–45 Error Code Home Positioning Error (Z–axis Collimator) Code Name Class Description Potential Cause / FRU 1101 30–1111–01 – Error BWD and FWD Limit–Photo–Sensors were interrupted at the same time during Home Positioning. 1. BWD or FWD Limit–Photo–Sensor(H); 2. Cabling between Limit–Photo–Sensor and CIF. 1102 30–1111–02 – Error BWD Limit–Photo–Sensor was unexpectedly interrupted during Home Positioning. 1. BWD and FWD Limit–Photo–Sensor is connected conversely with CIF.; 2. Z–Axis Motor movement is reversed. 1103 30–1111–03 – Error On Home Positioning, FWD Limit–Photo–Sensor remains interrupted when CIF drives Z– Axis Motor to BWD direction. 1. Z–Axis Motor Driver; 2. Z–Axis Motor; 3. Cabling between Z–Axis Motor and CIF; 4. BWD and FWD Limit–Photo–Sensor is connected conversely with CIF. (continued) 4–49 TABLE/GANTRY CT HISPEED SERIES ADVANCED DIAGNOSTICS PROPRIETARY TO GENERAL ELECTRIC COMPANY REV 13 4-5 2202119 ERRORS DETECTED BY DAS (continued) Table 4–45 Error Code Home Positioning Error (Z–axis Collimator) (continued) Code Name Class Description Potential Cause / FRU 1104 30–1111–04 – Error On Home Positioning, CIF cannot detect FWD Limit–Photo–Sensor interruption even after it drives Z–Axis Motor to FWD limit. 1105 30–1111–05 – Error On Home Positioning, CIF cannot detect BWD 1. Z–Axis Motor Driver; 2. Z–Axis Motor; 3. Limit–Photo–Sensor interruption when it drives BWD Limit–Photo–Sensor; 4. Ball Screw Z–Axis Motor from FWD limit to BWD limit. 1106 30–1111–06 – Error The number of pulses for Z–Axis Motor is over specification when moving from FWD limit to BWD limit on Home Positioning. 1. Position of BWD or FWD Limit–Photo–Sensor; 2. Jumper Setting of Z–Axis Motor Driver; 3. Ball Screw 1107 30–1111–07 – Error The number of pulses for Z–Axis Motor is under specification when moving from FWD limit to BWD limit on Home Positioning. 1. Position of BWD or FWD Limit–Photo–Sensor; 2. Jumper Setting of Z–Axis Motor Driver 1108 30–1111–08 – Error During Home Positioning, FWD Limit–Photo– Sensor was interrupted when moving from BWD limit to Home Position. Take a best guess and good luck. 4–50 1. Z–Axis Motor Driver; 2. Z–Axis Motor; 3. Cabling between Z–Axis Motor and CIF; 4. BWD and FWD Limit–Photo–Sensor is connected conversely with CIF. TABLE/GANTRY CT HISPEED SERIES ADVANCED DIAGNOSTICS PROPRIETARY TO GENERAL ELECTRIC COMPANY REV 13 4-5 2202119 ERRORS DETECTED BY DAS (continued) Table 4–46 Error Code Preset Positioning Error (Z–axis Collimator) Code Name Class Description Potential Cause / FRU 1201 30–1112–01 – Error FWD Limit–Photo–Sensor was interrupted dur- In case with error on Home Positioning, FWD ing Preset Positioning. Limit–Photo–Sensor or Cabling between Sensor and CIF.; In case without error on Home Positioning, Preset CMD from OC may be incorrect. 1202 30–1112–02 – Error BWD Limit–Photo–Sensor was interrupted dur- In case with error on Home Positioning, BWD ing Preset Positioning. Limit–Photo–Sensor or Cabling between Sensor and CIF.; In case without error on Home Positioning, Preset CMD from OC may be incorrect. Table 4–47 Error Code Beam Tracking Out of Limit (Z–axis Collimator) Code Name Class Description Potential Cause / FRU 2101 30–0121–01 – Infor. FWD Limit–Photo–Sensor was interrupted dur- In case with error on Home Positioning, FWD ing Beam Tracking. Limit–Photo–Sensor or Cabling between Sensor and CIF.; In case without error on Home Positioning, Qcal CH data from DDP may not be normal by Qcal Obs or z–axis miss–alignment of Tube or Detector.. 2102 30–0121–02 – Infor. BWD Limit–Photo–Sensor was interrupted dur- In case with error on Home Positioning, BWD ing Beam Tracking. Limit–Photo–Sensor or Cabling between Sensor and CIF.; In case without error on Home Positioning, Qcal CH data from DDP may not be normal by Qcal Obs or z–axis miss–alignment of Tube or Detector.. 4–51 TABLE/GANTRY CT HISPEED SERIES ADVANCED DIAGNOSTICS PROPRIETARY TO GENERAL ELECTRIC COMPANY REV 13 4-5 2202119 ERRORS DETECTED BY DAS (continued) Table 4–48 Error Code 2201 Code 30–1122–01 Table 4–49 Error Code Offset View Error (Z–axis Collimator) Name Class Error – Description Potential Cause / FRU The number of Offset View is out of specification. In case with raw data correction error detected by OC, Cabling for DAS Trigger including Slip Ring.; In case without this error, CIF may be failed. FIFO Overview Error (Z–axis Collimator) Code Name Class Description Potential Cause / FRU 2301 30–1123–01 – Error CIF detected DDP FIFO Overflow during Qcal CH data collection(Offset view). – 2302 30–0123–02 – Infor. CIF detected DDP FIFO Overflow during Qcal CH data collection(Active view). – Table 4–50 Error Code Beam Tracking Calc Error (Z–axis Collimator) Code Name Class Description Potential Cause / FRU 3101 30–1131–01 – Error Unexpected result of Beam Tracking calculation. – 3102 30–1131–02 – Error Unexpected result of Beam Tracking calculation. – 4–52 TABLE/GANTRY CT HISPEED SERIES ADVANCED DIAGNOSTICS PROPRIETARY TO GENERAL ELECTRIC COMPANY REV 13 4-5 2202119 ERRORS DETECTED BY DAS (continued) Table 4–51 Error Code Internal Error (Z–axis Collimator) Code Name Class Description Potential Cause / FRU 3201 30–1132–01 – Error CIF Internal Error. – 3202 30–1132–02 – Error CIF Internal Error. – Table 4–52 Error Code 4101 Code 30–0141–01 Table 4–53 Error Code Z CH Count (Z–axis Collimator) Name – Class Infor. Description Potential Cause / FRU Beam Tracking was paused because CIF detected Qcal CH Data is under specification. Qcal CH Obstruction or tube spits. Beam Tracking Hold/Resume (Z–axis Collimator) Code Name Class Description Potential Cause / FRU 4201 30–0142–01 – Infor. Beam Tracking was paused because CIF detected Qcal CH obstruction. Qcal CH Obstruction 4202 30–0142–02 – Infor. Beam Tracking was resumed because Qcal CH returned to normal from obstruction. – 4–53 TABLE/GANTRY PROPRIETARY TO GENERAL ELECTRIC COMPANY blank CT HISPEED SERIES ADVANCED DIAGNOSTICS 2202119 4–54 TABLE/GANTRY CT HISPEED SERIES ADVANCED DIAGNOSTICS PROPRIETARY TO GENERAL ELECTRIC COMPANY REV 9 2202119 DAS / DETECTOR TABLE OF CONTENTS SECTION PAGE SECTION 1 – CHANNEL – RING RADIUS TABLE . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 1-1 1–1 DETECTOR/DAS CHANNEL – RING RADIUS CROSS REFERENCE . . . . . . . . . . . 1–1 SECTION 2 – LED DESCRIPTION . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 2–1 i DAS/DETECTOR CT HISPEED SERIES ADVANCED DIAGNOSTICS PROPRIETARY TO GENERAL ELECTRIC COMPANY blank 2202119 ii DAS/DETECTOR PROPRIETARY TO GENERAL ELECTRIC COMPANY CT HISPEED SERIES ADVANCED DIAGNOSTICS REV 10 2202119 SECTION 1 – CHANNEL – RING RADIUS TABLE 1-1 DETECTOR/DAS CHANNEL – RING RADIUS CROSS REFERENCE Table 1–1 through 1–16 are Detector/DAS Channel – Ring Radius Cross Reference. In these tables: D CH#: Detector/DAS Channel No. D FC#: Flex Cable No. D CB#: CAM Board No. – Single: for the dectecor of NP, NP+, NP++ systems – Twin – A: for the A side detector of Twin systems – Twin – B: for the B side detector of Twin systems D PN#: Pin No. of the flex cable connector: Actually in Table 1–1 through 1–16, Channel Nos. are shown. See Illustration 1–1 or 1–2. D R (mm): Radius of image artifact in mm 1–1 DAS/DETECTOR CT HISPEED SERIES ADVANCED DIAGNOSTICS PROPRIETARY TO GENERAL ELECTRIC COMPANY REV 10 1-1 2202119 DETECTOR/DAS CHANNEL – RING RADIUS CROSS REFERENCE (Continued) Illustration 1–1 DAS/Detector Connector Pin Assignment (NP, NP+, and NP++) ËËËËËËËËËËËËË ËËËËËËËËËËËË ËËËËËËËËËËËËË ËËËËËËËËËËËËË ËËËËËËËËËËËË ËËËËËËËËËËËË ËËËËËËËËËËËËË ËËËËËËËËËËËË ËËËËËËËËËËËËË ËËËËËËËËËËËËË ËËËËËËËËËËËË ËËËËËËËËËËËË ËËËËËËËËËËËËË ËËËËËËËËËËËË ËËËËËËËËËËËËË ËËËËËËËËËËËË ËËËËËËËËËËËËË ËËËËËËËËËËËË Cable #1 Detector 24 Pins Flex Cables Cable #51 Flex Cable CAM Boards #1~#9 CAM Boards #19~#27 CAM Boards #10~#18 d c b a 1 2 3 4 5 6 a b c d 1 CH 7 CH 8 CH 9 CH10 2 CH 5 CH 6 CH11 CH12 3 CH 3 CH 4 CH13 CH14 4 CH 1 CH 2 CH15 CH16 5 FG FG SG SG 6 FG FG SG SG 1–2 DAS/DETECTOR CT HISPEED SERIES ADVANCED DIAGNOSTICS PROPRIETARY TO GENERAL ELECTRIC COMPANY REV 10 1-1 2202119 DETECTOR/DAS CHANNEL – RING RADIUS CROSS REFERENCE (Continued) Illustration 1–2 DAS/Detector Connector Pin Assignment (Twin) Cable #1 Detector ËËËËËËËËËËËËËË ËËËËËËËËËËËËË ËËËËËËËËËËËËËË ËËËËËËËËËËËËË ËËËËËËËËËËËËËË ËËËËËËËËËËËËË ËËËËËËËËËËËËËË ËËËËËËËËËËËËË ËËËËËËËËËËËËËË ËËËËËËËËËËËËË ËËËËËËËËËËËËËË ËËËËËËËËËËËËË ËËËËËËËËËËËËËË ËËËËËËËËËËËËË ËËËËËËËËËËËËËË ËËËËËËËËËËËËË ËËËËËËËËËËËËË Flex Cable Flex Cables Cable #51 48 Pins CAM Boards #1~#18 CAM Boards #37~#54 CAM Boards #19~#36 D C B A 1 2 3 4 5 6 7 8 9 10 11 12 A B C D 1 2SG 2SG 2SG 2SG 2 2SG 2SG 2SG 2SG 3 A–1ch B–1ch A–16ch B–16ch 4 A–2ch B–2ch A–15ch B–15ch 5 A–3ch B–3ch A–14ch B–14ch 6 A–4ch B–4ch A–13ch B–13ch 7 A–5ch B–5ch A–12ch B–12ch 8 A–6ch B–6ch A–11ch B–11ch 9 A–7ch B–7ch A–10ch B–10ch 10 A–8ch B–8ch A–9ch B–9ch 11 FG FG FG FG 12 FG FG FG FG 1–3 DAS/DETECTOR CT HISPEED SERIES ADVANCED DIAGNOSTICS PROPRIETARY TO GENERAL ELECTRIC COMPANY REV 10 2202119 Table 1–1 Channel – Ring Radius (#1 ~#50) CB# CH# FC# PN# R (mm) Single Twin – A Twin – B 1 1 2 3 2 1 2 3 4 14 249.7 4 15 3 1 2 249.1 3 4 16 4 2 248.5 2 3 4 1 5 248.0 2 2 3 4 2 247.4 6 2 2 3 4 3 246.8 7 2 2 3 4 4 246.2 8 2 2 3 4 5 245.6 9 2 2 3 4 6 245.0 10 2 2 3 4 7 244.5 11 2 2 3 4 8 243.9 12 2 2 3 4 9 243.3 13 2 2 3 4 10 242.7 14 2 2 3 4 11 242.1 15 2 2 3 4 12 241.5 16 2 2 3 4 13 240.9 17 2 2 3 4 14 240.4 18 2 2 3 4 15 239.8 19 2 2 3 4 16 239.2 20 3 3 5 6 1 238.6 21 3 3 5 6 2 238.0 22 3 3 5 6 3 237.4 23 3 3 5 6 4 236.8 24 3 3 5 6 5 236.2 25 3 3 5 6 6 235.6 26 3 3 5 6 7 235.1 27 3 3 5 6 8 234.5 28 3 3 5 6 9 233.9 29 3 3 5 6 10 233.3 30 3 3 5 6 11 232.7 31 3 3 5 6 12 232.1 32 3 3 5 6 13 231.5 33 3 3 5 6 14 230.9 34 3 3 5 6 15 230.3 35 3 3 5 6 16 229.7 36 4 3 5 6 1 229.1 37 4 3 5 6 2 228.5 38 4 3 5 6 3 227.9 39 4 3 5 6 4 227.3 40 4 3 5 6 5 226.8 41 4 3 5 6 6 226.2 42 4 3 5 6 7 225.6 43 4 3 5 6 8 225.0 44 4 3 5 6 9 224.4 45 4 3 5 6 10 223.8 46 4 3 5 6 11 223.2 47 4 3 5 6 12 222.6 48 4 3 5 6 13 222.0 49 4 3 5 6 14 221.4 50 4 3 5 6 15 220.8 1–4 DAS/DETECTOR CT HISPEED SERIES ADVANCED DIAGNOSTICS PROPRIETARY TO GENERAL ELECTRIC COMPANY REV 10 Table 1–2 2202119 Channel – Ring Radius (#51 ~#100) CB# CH# FC# PN# R (mm) Single Twin – A Twin – B 51 4 3 5 52 5 4 7 8 16 220.2 8 1 53 5 4 219.6 7 8 2 54 5 219.0 4 7 8 3 55 218.4 5 4 7 8 4 217.8 56 5 4 7 8 5 217.2 57 5 4 7 8 6 216.6 58 5 4 7 8 7 216.0 59 5 4 7 8 8 215.4 60 5 4 7 8 9 214.8 61 5 4 7 8 10 214.2 62 5 4 7 8 11 213.6 63 5 4 7 8 12 213.0 64 5 4 7 8 13 212.4 65 5 4 7 8 14 211.8 66 5 4 7 8 15 211.2 67 5 4 7 8 16 210.6 68 6 4 7 8 1 210.0 69 6 4 7 8 2 209.3 70 6 4 7 8 3 208.7 71 6 4 7 8 4 208.1 72 6 4 7 8 5 207.5 73 6 4 7 8 6 206.9 74 6 4 7 8 7 206.3 75 6 4 7 8 8 205.7 76 6 4 7 8 9 205.1 77 6 4 7 8 10 204.5 78 6 4 7 8 11 203.9 79 6 4 7 8 12 203.3 80 6 4 7 8 13 202.7 81 6 4 7 8 14 202.1 82 6 4 7 8 15 201.5 83 6 4 7 8 16 200.8 84 7 5 9 10 1 200.2 85 7 5 9 10 2 199.6 86 7 5 9 10 3 199.0 87 7 5 9 10 4 198.4 88 7 5 9 10 5 197.8 89 7 5 9 10 6 197.2 90 7 5 9 10 7 196.6 91 7 5 9 10 8 196.0 92 7 5 9 10 9 195.4 93 7 5 9 10 10 194.7 94 7 5 9 10 11 194.1 95 7 5 9 10 12 193.5 96 7 5 9 10 13 192.9 97 7 5 9 10 14 192.3 98 7 5 9 10 15 191.7 99 7 5 9 10 16 191.1 100 8 5 9 10 1 190.5 1–5 DAS/DETECTOR CT HISPEED SERIES ADVANCED DIAGNOSTICS PROPRIETARY TO GENERAL ELECTRIC COMPANY REV 10 Table 1–3 2202119 Channel – Ring Radius (#101 ~#150) CB# CH# FC# PN# R (mm) Single Twin – A Twin – B 101 8 5 9 102 8 5 9 10 2 189.8 10 3 103 8 5 189.2 9 10 4 104 8 188.6 5 9 10 5 105 188.0 8 5 9 10 6 187.4 106 8 5 9 10 7 186.8 107 8 5 9 10 8 186.2 108 8 5 9 10 9 185.5 109 8 5 9 10 10 184.9 110 8 5 9 10 11 184.3 111 8 5 9 10 12 183.7 112 8 5 9 10 13 183.1 113 8 5 9 10 14 182.5 114 8 5 9 10 15 181.8 115 8 5 9 10 16 181.2 116 9 6 11 12 1 180.6 117 9 6 11 12 2 180.0 118 9 6 11 12 3 179.4 119 9 6 11 12 4 178.7 120 9 6 11 12 5 178.1 121 9 6 11 12 6 177.5 122 9 6 11 12 7 176.9 123 9 6 11 12 8 176.3 124 9 6 11 12 9 175.6 125 9 6 11 12 10 175.0 126 9 6 11 12 11 174.4 127 9 6 11 12 12 173.8 128 9 6 11 12 13 173.2 129 9 6 11 12 14 172.5 130 9 6 11 12 15 171.9 131 9 6 11 12 16 171.3 132 10 6 11 12 1 170.7 133 10 6 11 12 2 170.1 134 10 6 11 12 3 169.4 135 10 6 11 12 4 168.8 136 10 6 11 12 5 168.2 137 10 6 11 12 6 167.6 138 10 6 11 12 7 166.9 139 10 6 11 12 8 166.3 140 10 6 11 12 9 165.7 141 10 6 11 12 10 165.1 142 10 6 11 12 11 164.4 143 10 6 11 12 12 163.8 144 10 6 11 12 13 163.2 145 10 6 11 12 14 162.6 146 10 6 11 12 15 161.9 147 10 6 11 12 16 161.3 148 11 7 13 14 1 160.7 149 11 7 13 14 2 160.1 150 11 7 13 14 3 159.4 1–6 DAS/DETECTOR CT HISPEED SERIES ADVANCED DIAGNOSTICS PROPRIETARY TO GENERAL ELECTRIC COMPANY REV 10 Table 1–4 2202119 Channel – Ring Radius (#151 ~#200) CB# CH# FC# PN# R (mm) Single Twin – A Twin – B 151 11 7 13 152 11 7 13 14 4 158.8 14 5 153 11 7 158.2 13 14 6 154 11 157.5 7 13 14 7 155 156.9 11 7 13 14 8 156.3 156 11 7 13 14 9 155.7 157 11 7 13 14 10 155.0 158 11 7 13 14 11 154.4 159 11 7 13 14 12 153.8 160 11 7 13 14 13 153.2 161 11 7 13 14 14 152.5 162 11 7 13 14 15 151.9 163 11 7 13 14 16 151.3 164 12 7 13 14 1 150.6 165 12 7 13 14 2 150.0 166 12 7 13 14 3 149.4 167 12 7 13 14 4 148.7 168 12 7 13 14 5 148.1 169 12 7 13 14 6 147.5 170 12 7 13 14 7 146.9 171 12 7 13 14 8 146.2 172 12 7 13 14 9 145.6 173 12 7 13 14 10 145.0 174 12 7 13 14 11 144.3 175 12 7 13 14 12 143.7 176 12 7 13 14 13 143.1 177 12 7 13 14 14 142.4 178 12 7 13 14 15 141.8 179 12 7 13 14 16 141.2 180 13 8 15 16 1 140.5 181 13 8 15 16 2 139.9 182 13 8 15 16 3 139.3 183 13 8 15 16 4 138.6 184 13 8 15 16 5 138.0 185 13 8 15 16 6 137.4 186 13 8 15 16 7 136.7 187 13 8 15 16 8 136.1 188 13 8 15 16 9 135.5 189 13 8 15 16 10 134.8 190 13 8 15 16 11 134.2 191 13 8 15 16 12 133.5 192 13 8 15 16 13 132.9 193 13 8 15 16 14 132.3 194 13 8 15 16 15 131.6 195 13 8 15 16 16 131.0 196 14 8 15 16 1 130.4 197 14 8 15 16 2 129.7 198 14 8 15 16 3 129.1 199 14 8 15 16 4 128.5 200 14 8 15 16 5 127.8 1–7 DAS/DETECTOR CT HISPEED SERIES ADVANCED DIAGNOSTICS PROPRIETARY TO GENERAL ELECTRIC COMPANY REV 10 Table 1–5 2202119 Channel – Ring Radius (#201 ~#250) CB# CH# FC# PN# R (mm) Single Twin – A Twin – B 201 14 8 15 202 14 8 15 16 6 127.2 16 7 203 14 8 126.5 15 16 8 204 14 125.9 8 15 16 9 205 125.3 14 8 15 16 10 124.6 206 14 8 15 16 11 124.0 207 14 8 15 16 12 123.4 208 14 8 15 16 13 122.7 209 14 8 15 16 14 122.1 210 14 8 15 16 15 121.4 211 14 8 15 16 16 120.8 212 15 9 17 18 1 120.2 213 15 9 17 18 2 119.5 214 15 9 17 18 3 118.9 215 15 9 17 18 4 118.2 216 15 9 17 18 5 117.6 217 15 9 17 18 6 117.0 218 15 9 17 18 7 116.3 219 15 9 17 18 8 115.7 220 15 9 17 18 9 115.0 221 15 9 17 18 10 114.4 222 15 9 17 18 11 113.8 223 15 9 17 18 12 113.1 224 15 9 17 18 13 112.5 225 15 9 17 18 14 111.8 226 15 9 17 18 15 111.2 227 15 9 17 18 16 110.5 228 16 9 17 18 1 109.9 229 16 9 17 18 2 109.3 230 16 9 17 18 3 108.6 231 16 9 17 18 4 108.0 232 16 9 17 18 5 107.3 233 16 9 17 18 6 106.7 234 16 9 17 18 7 106.0 235 16 9 17 18 8 105.4 236 16 9 17 18 9 104.8 237 16 9 17 18 10 104.1 238 16 9 17 18 11 103.5 239 16 9 17 18 12 102.8 240 16 9 17 18 13 102.2 241 16 9 17 18 14 101.5 242 16 9 17 18 15 100.9 243 16 9 17 18 16 100.3 244 17 10 19 20 1 99.6 245 17 10 19 20 2 99.0 246 17 10 19 20 3 98.3 247 17 10 19 20 4 97.7 248 17 10 19 20 5 97.0 249 17 10 19 20 6 96.4 250 17 10 19 20 7 95.7 1–8 DAS/DETECTOR CT HISPEED SERIES ADVANCED DIAGNOSTICS PROPRIETARY TO GENERAL ELECTRIC COMPANY REV 10 Table 1–6 2202119 Channel – Ring Radius (#251 ~#300) CB# CH# FC# PN# R (mm) Single Twin – A Twin – B 251 17 10 19 252 17 10 19 20 8 95.1 20 9 253 17 10 94.4 19 20 10 254 17 93.8 10 19 20 11 255 93.2 17 10 19 20 12 92.5 256 17 10 19 20 13 91.9 257 17 10 19 20 14 91.2 258 17 10 19 20 15 90.6 259 17 10 19 20 16 89.9 260 18 10 19 20 1 89.3 261 18 10 19 20 2 88.6 262 18 10 19 20 3 88.0 263 18 10 19 20 4 87.3 264 18 10 19 20 5 86.7 265 18 10 19 20 6 86.0 266 18 10 19 20 7 85.4 267 18 10 19 20 8 84.7 268 18 10 19 20 9 84.1 269 18 10 19 20 10 83.5 270 18 10 19 20 11 82.8 271 18 10 19 20 12 82.2 272 18 10 19 20 13 81.5 273 18 10 19 20 14 80.9 274 18 10 19 20 15 80.2 275 18 10 19 20 16 79.6 276 19 11 21 22 1 78.9 277 19 11 21 22 2 78.3 278 19 11 21 22 3 77.6 279 19 11 21 22 4 77.0 280 19 11 21 22 5 76.3 281 19 11 21 22 6 75.7 282 19 11 21 22 7 75.0 283 19 11 21 22 8 74.4 284 19 11 21 22 9 73.7 285 19 11 21 22 10 73.1 286 19 11 21 22 11 72.4 287 19 11 21 22 12 71.8 288 19 11 21 22 13 71.1 289 19 11 21 22 14 70.5 290 19 11 21 22 15 69.8 291 19 11 21 22 16 69.2 292 20 11 21 22 1 68.5 293 20 11 21 22 2 67.9 294 20 11 21 22 3 67.2 295 20 11 21 22 4 66.6 296 20 11 21 22 5 65.9 297 20 11 21 22 6 65.3 298 20 11 21 22 7 64.6 299 20 11 21 22 8 64.0 300 20 11 21 22 9 63.3 1–9 DAS/DETECTOR CT HISPEED SERIES ADVANCED DIAGNOSTICS PROPRIETARY TO GENERAL ELECTRIC COMPANY REV 10 Table 1–7 2202119 Channel – Ring Radius (#301 ~#350) CB# CH# FC# PN# R (mm) Single Twin – A Twin – B 301 20 11 21 302 20 11 21 22 10 62.7 22 11 303 20 11 62.0 21 22 12 304 20 61.4 11 21 22 13 305 60.7 20 11 21 22 14 60.1 306 20 11 21 22 15 59.4 307 20 11 21 22 16 58.7 308 21 12 23 24 1 58.1 309 21 12 23 24 2 57.4 310 21 12 23 24 3 56.8 311 21 12 23 24 4 56.1 312 21 12 23 24 5 55.5 313 21 12 23 24 6 54.8 314 21 12 23 24 7 54.2 315 21 12 23 24 8 53.5 316 21 12 23 24 9 52.9 317 21 12 23 24 10 52.2 318 21 12 23 24 11 51.6 319 21 12 23 24 12 50.9 320 21 12 23 24 13 50.3 321 21 12 23 24 14 49.6 322 21 12 23 24 15 49.0 323 21 12 23 24 16 48.3 324 22 12 23 24 1 47.7 325 22 12 23 24 2 47.0 326 22 12 23 24 3 46.3 327 22 12 23 24 4 45.7 328 22 12 23 24 5 45.0 329 22 12 23 24 6 44.4 330 22 12 23 24 7 43.7 331 22 12 23 24 8 43.1 332 22 12 23 24 9 42.4 333 22 12 23 24 10 41.8 334 22 12 23 24 11 41.1 335 22 12 23 24 12 40.5 336 22 12 23 24 13 39.8 337 22 12 23 24 14 39.2 338 22 12 23 24 15 38.5 339 22 12 23 24 16 37.8 340 23 13 25 26 1 37.2 341 23 13 25 26 2 36.5 342 23 13 25 26 3 35.9 343 23 13 25 26 4 35.2 344 23 13 25 26 5 34.6 345 23 13 25 26 6 33.9 346 23 13 25 26 7 33.3 347 23 13 25 26 8 32.6 348 23 13 25 26 9 32.0 349 23 13 25 26 10 31.3 350 23 13 25 26 11 30.6 1–10 DAS/DETECTOR CT HISPEED SERIES ADVANCED DIAGNOSTICS PROPRIETARY TO GENERAL ELECTRIC COMPANY REV 10 Table 1–8 2202119 Channel – Ring Radius (#351 ~#400) CB# CH# FC# PN# R (mm) Single Twin – A Twin – B 351 23 13 25 352 23 13 25 26 12 30.0 26 13 353 23 13 29.3 25 26 14 354 23 28.7 13 25 26 15 355 28.0 23 13 25 26 16 27.4 356 24 13 25 26 1 26.7 357 24 13 25 26 2 26.1 358 24 13 25 26 3 25.4 359 24 13 25 26 4 24.8 360 24 13 25 26 5 24.1 361 24 13 25 26 6 23.4 362 24 13 25 26 7 22.8 363 24 13 25 26 8 22.1 364 24 13 25 26 9 21.5 365 24 13 25 26 10 20.8 366 24 13 25 26 11 20.2 367 24 13 25 26 12 19.5 368 24 13 25 26 13 18.9 369 24 13 25 26 14 18.2 370 24 13 25 26 15 17.5 371 24 13 25 26 16 16.9 372 25 14 27 28 1 16.2 373 25 14 27 28 2 15.6 374 25 14 27 28 3 14.9 375 25 14 27 28 4 14.3 376 25 14 27 28 5 13.6 377 25 14 27 28 6 13.0 378 25 14 27 28 7 12.3 379 25 14 27 28 8 11.6 380 25 14 27 28 9 11.0 381 25 14 27 28 10 10.3 382 25 14 27 28 11 9.7 383 25 14 27 28 12 9.0 384 25 14 27 28 13 8.4 385 25 14 27 28 14 7.7 386 25 14 27 28 15 7.1 387 25 14 27 28 16 6.4 388 26 14 27 28 1 5.7 389 26 14 27 28 2 5.1 390 26 14 27 28 3 4.4 391 26 14 27 28 4 3.8 392 26 14 27 28 5 3.1 393 26 14 27 28 6 2.5 394 26 14 27 28 7 1.8 395 26 14 27 28 8 1.1 396 26 14 27 28 9 0.5 397 26 14 27 28 10 0.2 398 26 14 27 28 11 0.8 399 26 14 27 28 12 1.5 400 26 14 27 28 13 2.1 1–11 DAS/DETECTOR CT HISPEED SERIES ADVANCED DIAGNOSTICS PROPRIETARY TO GENERAL ELECTRIC COMPANY REV 10 Table 1–9 2202119 Channel – Ring Radius (#401 ~#450) CB# CH# FC# PN# R (mm) Single Twin – A Twin – B 401 26 14 27 402 26 14 27 28 14 2.8 28 15 403 26 14 3.4 27 28 16 404 27 4.1 15 29 30 1 405 4.8 27 15 29 30 2 5.4 406 27 15 29 30 3 6.1 407 27 15 29 30 4 6.7 408 27 15 29 30 5 7.4 409 27 15 29 30 6 8.0 410 27 15 29 30 7 8.7 411 27 15 29 30 8 9.3 412 27 15 29 30 9 10.0 413 27 15 29 30 10 10.7 414 27 15 29 30 11 11.3 415 27 15 29 30 12 12.0 416 27 15 29 30 13 12.6 417 27 15 29 30 14 13.3 418 27 15 29 30 15 13.9 419 27 15 29 30 16 14.6 420 28 15 29 30 1 15.2 421 28 15 29 30 2 15.9 422 28 15 29 30 3 16.6 423 28 15 29 30 4 17.2 424 28 15 29 30 5 17.9 425 28 15 29 30 6 18.5 426 28 15 29 30 7 19.2 427 28 15 29 30 8 19.8 428 28 15 29 30 9 20.5 429 28 15 29 30 10 21.1 430 28 15 29 30 11 21.8 431 28 15 29 30 12 22.5 432 28 15 29 30 13 23.1 433 28 15 29 30 14 23.8 434 28 15 29 30 15 24.4 435 28 15 29 30 16 25.1 436 29 16 31 32 1 25.7 437 29 16 31 32 2 26.4 438 29 16 31 32 3 27.0 439 29 16 31 32 4 27.7 440 29 16 31 32 5 28.4 441 29 16 31 32 6 29.0 442 29 16 31 32 7 29.7 443 29 16 31 32 8 30.3 444 29 16 31 32 9 31.0 445 29 16 31 32 10 31.6 446 29 16 31 32 11 32.3 447 29 16 31 32 12 32.9 448 29 16 31 32 13 33.6 449 29 16 31 32 14 34.2 450 29 16 31 32 15 34.9 1–12 DAS/DETECTOR CT HISPEED SERIES ADVANCED DIAGNOSTICS PROPRIETARY TO GENERAL ELECTRIC COMPANY REV 10 Table 1–10 2202119 Channel – Ring Radius (#451 ~#500) CB# CH# FC# PN# R (mm) Single Twin – A Twin – B 451 29 16 31 452 30 16 31 32 16 35.6 32 1 453 30 16 36.2 31 32 2 454 30 36.9 16 31 32 3 455 37.5 30 16 31 32 4 38.2 456 30 16 31 32 5 38.8 457 30 16 31 32 6 39.5 458 30 16 31 32 7 40.1 459 30 16 31 32 8 40.8 460 30 16 31 32 9 41.4 461 30 16 31 32 10 42.1 462 30 16 31 32 11 42.8 463 30 16 31 32 12 43.4 464 30 16 31 32 13 44.1 465 30 16 31 32 14 44.7 466 30 16 31 32 15 45.4 467 30 16 31 32 16 46.0 468 31 17 33 34 1 46.7 469 31 17 33 34 2 47.3 470 31 17 33 34 3 48.0 471 31 17 33 34 4 48.6 472 31 17 33 34 5 49.3 473 31 17 33 34 6 49.9 474 31 17 33 34 7 50.6 475 31 17 33 34 8 51.2 476 31 17 33 34 9 51.9 477 31 17 33 34 10 52.5 478 31 17 33 34 11 53.2 479 31 17 33 34 12 53.9 480 31 17 33 34 13 54.5 481 31 17 33 34 14 55.2 482 31 17 33 34 15 55.8 483 31 17 33 34 16 56.5 484 32 17 33 34 1 57.1 485 32 17 33 34 2 57.8 486 32 17 33 34 3 58.4 487 32 17 33 34 4 59.1 488 32 17 33 34 5 59.7 489 32 17 33 34 6 60.4 490 32 17 33 34 7 61.0 491 32 17 33 34 8 61.7 492 32 17 33 34 9 62.3 493 32 17 33 34 10 63.0 494 32 17 33 34 11 63.6 495 32 17 33 34 12 64.3 496 32 17 33 34 13 64.9 497 32 17 33 34 14 65.6 498 32 17 33 34 15 66.2 499 32 17 33 34 16 66.9 500 33 18 35 36 1 67.5 1–13 DAS/DETECTOR CT HISPEED SERIES ADVANCED DIAGNOSTICS PROPRIETARY TO GENERAL ELECTRIC COMPANY REV 10 Table 1–11 2202119 Channel – Ring Radius (#501 ~#550) CB# CH# FC# PN# R (mm) Single Twin – A Twin – B 501 33 18 35 502 33 18 35 36 2 68.2 36 3 503 33 18 68.8 35 36 4 504 33 69.5 18 35 36 5 505 70.1 33 18 35 36 6 70.8 506 33 18 35 36 7 71.4 507 33 18 35 36 8 72.1 508 33 18 35 36 9 72.7 509 33 18 35 36 10 73.4 510 33 18 35 36 11 74.0 511 33 18 35 36 12 74.7 512 33 18 35 36 13 75.3 513 33 18 35 36 14 76.0 514 33 18 35 36 15 76.6 515 33 18 35 36 16 77.3 516 34 18 35 36 1 77.9 517 34 18 35 36 2 78.6 518 34 18 35 36 3 79.2 519 34 18 35 36 4 79.9 520 34 18 35 36 5 80.5 521 34 18 35 36 6 81.2 522 34 18 35 36 7 81.8 523 34 18 35 36 8 82.5 524 34 18 35 36 9 83.1 525 34 18 35 36 10 83.8 526 34 18 35 36 11 84.4 527 34 18 35 36 12 85.1 528 34 18 35 36 13 85.7 529 34 18 35 36 14 86.4 530 34 18 35 36 15 87.0 531 34 18 35 36 16 87.7 532 35 19 37 38 1 88.3 533 35 19 37 38 2 89.0 534 35 19 37 38 3 89.6 535 35 19 37 38 4 90.2 536 35 19 37 38 5 90.9 537 35 19 37 38 6 91.5 538 35 19 37 38 7 92.2 539 35 19 37 38 8 92.8 540 35 19 37 38 9 93.5 541 35 19 37 38 10 94.1 542 35 19 37 38 11 94.8 543 35 19 37 38 12 95.4 544 35 19 37 38 13 96.1 545 35 19 37 38 14 96.7 546 35 19 37 38 15 97.4 547 35 19 37 38 16 98.0 548 36 19 37 38 1 98.6 549 36 19 37 38 2 99.3 550 36 19 37 38 3 99.9 1–14 DAS/DETECTOR CT HISPEED SERIES ADVANCED DIAGNOSTICS PROPRIETARY TO GENERAL ELECTRIC COMPANY REV 10 Table 1–12 2202119 Channel – Ring Radius (#551 ~#600) CB# CH# FC# PN# R (mm) Single Twin – A Twin – B 551 36 19 37 552 36 19 37 38 4 100.6 38 5 553 36 19 101.2 37 38 6 554 36 101.9 19 37 38 7 555 102.5 36 19 37 38 8 103.2 556 36 19 37 38 9 103.8 557 36 19 37 38 10 104.4 558 36 19 37 38 11 105.1 559 36 19 37 38 12 105.7 560 36 19 37 38 13 106.4 561 36 19 37 38 14 107.0 562 36 19 37 38 15 107.7 563 36 19 37 38 16 108.3 564 37 20 39 40 1 108.9 565 37 20 39 40 2 109.6 566 37 20 39 40 3 110.2 567 37 20 39 40 4 110.9 568 37 20 39 40 5 111.5 569 37 20 39 40 6 112.2 570 37 20 39 40 7 112.8 571 37 20 39 40 8 113.4 572 37 20 39 40 9 114.1 573 37 20 39 40 10 114.7 574 37 20 39 40 11 115.4 575 37 20 39 40 12 116.0 576 37 20 39 40 13 116.6 577 37 20 39 40 14 117.3 578 37 20 39 40 15 117.9 579 37 20 39 40 16 118.6 580 38 20 39 40 1 119.2 581 38 20 39 40 2 119.8 582 38 20 39 40 3 120.5 583 38 20 39 40 4 121.1 584 38 20 39 40 5 121.8 585 38 20 39 40 6 122.4 586 38 20 39 40 7 123.0 587 38 20 39 40 8 123.7 588 38 20 39 40 9 124.3 589 38 20 39 40 10 125.0 590 38 20 39 40 11 125.6 591 38 20 39 40 12 126.2 592 38 20 39 40 13 126.9 593 38 20 39 40 14 127.5 594 38 20 39 40 15 128.1 595 38 20 39 40 16 128.8 596 39 21 41 42 1 129.4 597 39 21 41 42 2 130.0 598 39 21 41 42 3 130.7 599 39 21 41 42 4 131.3 600 39 21 41 42 5 132.0 1–15 DAS/DETECTOR CT HISPEED SERIES ADVANCED DIAGNOSTICS PROPRIETARY TO GENERAL ELECTRIC COMPANY REV 10 Table 1–13 2202119 Channel – Ring Radius (#601 ~#650) CB# CH# FC# PN# R (mm) Single Twin – A Twin – B 601 39 21 41 602 39 21 41 42 6 123.6 42 7 603 39 21 133.2 41 42 8 604 39 133.9 21 41 42 9 605 134.5 39 21 41 42 10 135.1 606 39 21 41 42 11 135.8 607 39 21 41 42 12 136.4 608 39 21 41 42 13 137.0 609 39 21 41 42 14 137.7 610 39 21 41 42 15 138.3 611 39 21 41 42 16 138.9 612 40 21 41 42 1 139.6 613 40 21 41 42 2 140.2 614 40 21 41 42 3 140.8 615 40 21 41 42 4 141.5 616 40 21 41 42 5 142.1 617 40 21 41 42 6 142.7 618 40 21 41 42 7 143.4 619 40 21 41 42 8 144.0 620 40 21 41 42 9 144.6 621 40 21 41 42 10 145.3 622 40 21 41 42 11 145.9 623 40 21 41 42 12 146.5 624 40 21 41 42 13 147.2 625 40 21 41 42 14 147.8 626 40 21 41 42 15 148.4 627 40 21 41 42 16 149.1 628 41 22 43 44 1 149.7 629 41 22 43 44 2 150.3 630 41 22 43 44 3 150.9 631 41 22 43 44 4 151.6 632 41 22 43 44 5 152.2 633 41 22 43 44 6 152.8 634 41 22 43 44 7 153.5 635 41 22 43 44 8 154.1 636 41 22 43 44 9 154.7 637 41 22 43 44 10 155.4 638 41 22 43 44 11 156.0 639 41 22 43 44 12 156.6 640 41 22 43 44 13 157.2 641 41 22 43 44 14 157.9 642 41 22 43 44 15 158.5 643 41 22 43 44 16 159.1 644 42 22 43 44 1 159.7 645 42 22 43 44 2 160.4 646 42 22 43 44 3 161.0 647 42 22 43 44 4 161.6 648 42 22 43 44 5 162.2 649 42 22 43 44 6 162.9 650 42 22 43 44 7 163.5 1–16 DAS/DETECTOR CT HISPEED SERIES ADVANCED DIAGNOSTICS PROPRIETARY TO GENERAL ELECTRIC COMPANY REV 10 Table 1–14 2202119 Channel – Ring Radius (#651 ~#700) CB# CH# FC# PN# R (mm) Single Twin – A Twin – B 651 42 22 43 652 42 22 43 44 8 164.1 44 9 653 42 22 164.7 43 44 10 654 42 165.4 22 43 44 11 655 166.0 42 22 43 44 12 166.6 656 42 22 43 44 13 167.2 657 42 22 43 44 14 167.9 658 42 22 43 44 15 168.5 659 42 22 43 44 16 169.1 660 43 23 45 46 1 169.7 661 43 23 45 46 2 170.4 662 43 23 45 46 3 171.0 663 43 23 45 46 4 171.6 664 43 23 45 46 5 172.2 665 43 23 45 46 6 172.8 666 43 23 45 46 7 173.5 667 43 23 45 46 8 174.1 668 43 23 45 46 9 174.7 669 43 23 45 46 10 175.3 670 43 23 45 46 11 176.0 671 43 23 45 46 12 176.6 672 43 23 45 46 13 177.2 673 43 23 45 46 14 177.8 674 43 23 45 46 15 178.4 675 43 23 45 46 16 179.1 676 44 23 45 46 1 179.7 677 44 23 45 46 2 180.3 678 44 23 45 46 3 180.9 679 44 23 45 46 4 181.5 680 44 23 45 46 5 182.1 681 44 23 45 46 6 182.8 682 44 23 45 46 7 183.4 683 44 23 45 46 8 184.0 684 44 23 45 46 9 184.6 685 44 23 45 46 10 185.2 686 44 23 45 46 11 185.8 687 44 23 45 46 12 186.5 688 44 23 45 46 13 187.1 689 44 23 45 46 14 187.7 690 44 23 45 46 15 188.3 691 44 23 45 46 16 188.9 692 45 24 47 48 1 189.5 693 45 24 47 48 2 190.1 694 45 24 47 48 3 190.8 695 45 24 47 48 4 191.4 696 45 24 47 48 5 192.0 697 45 24 47 48 6 192.6 698 45 24 47 48 7 193.2 699 45 24 47 48 8 193.8 700 45 24 47 48 9 194.4 1–17 DAS/DETECTOR CT HISPEED SERIES ADVANCED DIAGNOSTICS PROPRIETARY TO GENERAL ELECTRIC COMPANY REV 10 Table 1–15 2202119 Channel – Ring Radius (#701 ~#750) CB# CH# FC# PN# R (mm) Single Twin – A Twin – B 701 45 24 47 702 45 24 47 48 10 195.1 48 11 703 45 24 195.7 47 48 12 704 45 196.3 24 47 48 13 705 196.9 45 24 47 48 14 197.5 706 45 24 47 48 15 198.1 707 45 24 47 48 16 198.7 708 46 24 47 48 1 199.3 709 46 24 47 48 2 199.9 710 46 24 47 48 3 200.5 711 46 24 47 48 4 201.2 712 46 24 47 48 5 201.8 713 46 24 47 48 6 202.4 714 46 24 47 48 7 203.0 715 46 24 47 48 8 203.6 716 46 24 47 48 9 204.2 717 46 24 47 48 10 204.8 718 46 24 47 48 11 205.4 719 46 24 47 48 12 206.0 720 46 24 47 48 13 206.6 721 46 24 47 48 14 207.2 722 46 24 47 48 15 207.8 723 46 24 47 48 16 208.4 724 47 25 49 50 1 209.0 725 47 25 49 50 2 209.6 726 47 25 49 50 3 210.3 727 47 25 49 50 4 210.9 728 47 25 49 50 5 211.5 729 47 25 49 50 6 212.1 730 47 25 49 50 7 212.7 731 47 25 49 50 8 213.3 732 47 25 49 50 9 213.9 733 47 25 49 50 10 214.5 734 47 25 49 50 11 215.1 735 47 25 49 50 12 215.7 736 47 25 49 50 13 216.3 737 47 25 49 50 14 216.9 738 47 25 49 50 15 217.5 739 47 25 49 50 16 218.1 740 48 25 49 50 1 218.7 741 48 25 49 50 2 219.3 742 48 25 49 50 3 219.9 743 48 25 49 50 4 220.5 744 48 25 49 50 5 221.1 745 48 25 49 50 6 221.7 746 48 25 49 50 7 222.3 747 48 25 49 50 8 222.9 748 48 25 49 50 9 223.5 749 48 25 49 50 10 224.1 750 48 25 49 50 11 224.7 1–18 DAS/DETECTOR CT HISPEED SERIES ADVANCED DIAGNOSTICS PROPRIETARY TO GENERAL ELECTRIC COMPANY REV 10 Table 1–16 2202119 Channel – Ring Radius (#751 ~#793) CB# CH# FC# PN# R (mm) Single Twin – A Twin – B 751 48 25 49 752 48 25 49 50 12 225.3 50 13 753 48 25 225.9 49 50 14 754 48 226.5 25 49 50 15 755 227.0 48 25 49 50 16 227.6 756 49 26 51 52 1 228.2 757 49 26 51 52 2 228.8 758 49 26 51 52 3 229.4 759 49 26 51 52 4 230.0 760 49 26 51 52 5 230.6 761 49 26 51 52 6 231.2 762 49 26 51 52 7 231.8 763 49 26 51 52 8 232.4 764 49 26 51 52 9 233.0 765 49 26 51 52 10 233.6 766 49 26 51 52 11 234.2 767 49 26 51 52 12 234.8 768 49 26 51 52 13 235.4 769 49 26 51 52 14 235.9 770 49 26 51 52 15 236.5 771 49 26 51 52 16 237.1 772 50 26 51 52 1 237.7 773 50 26 51 52 2 238.3 774 50 26 51 52 3 238.9 775 50 26 51 52 4 239.5 776 50 26 51 52 5 240.1 777 50 26 51 52 6 240.7 778 50 26 51 52 7 241.2 779 50 26 51 52 8 241.8 780 50 26 51 52 9 242.4 781 50 26 51 52 10 243.0 782 50 26 51 52 11 243.6 783 50 26 51 52 12 244.2 784 50 26 51 52 13 244.8 785 50 26 51 52 14 245.3 786 50 26 51 52 15 245.9 787 50 26 51 52 16 246.5 788 51 27 53 54 1 247.1 789 51 27 53 54 2 247.7 790 51 27 53 54 3 248.3 791 51 27 53 54 4 248.8 792 51 27 53 54 5 249.4 793 51 27 53 54 6 250.0 1–19 DAS/DETECTOR PROPRIETARY TO GENERAL ELECTRIC COMPANY blank CT HISPEED SERIES ADVANCED DIAGNOSTICS 2202119 1–20 DAS/DETECTOR CT HISPEED SERIES ADVANCED DIAGNOSTICS PROPRIETARY TO GENERAL ELECTRIC COMPANY REV 5 2202119 SECTION 2 – LED DESCRIPTION Table 2–1 CIF Board LED Description LED DS1 – 8 (8 LEDs) Description Blinks while the microprocessor is normally operating (not hung–up). Illustration 2–1 CIF Board DS1 – 8 (8 LEDs) 2–1 DAS/DETECTOR PROPRIETARY TO GENERAL ELECTRIC COMPANY blank CT HISPEED SERIES ADVANCED DIAGNOSTICS 2202119 2–2 DAS/DETECTOR CT HISPEED SERIES ADVANCED DIAGNOSTICS PROPRIETARY TO GENERAL ELECTRIC COMPANY REV 11 2202119 X–RAY GENERATOR TABLE OF CONTENTS SECTION PAGE SECTION 1 – LED DESCRIPTION . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 1-1 1-2 1-3 1-4 1-5 1-6 1-7 1-8 1-9 KV MEASURE BOARD . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 1-1-1 Illustration . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . FILAMENT BOARD 1 INV . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 1-2-1 Illustration . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . ROTATION BOARD HIGH SPEED . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 1-3-1 Illustration . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 1-3-2 Indicators . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . LV POWER SUPPLY 3 PH BOARD . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 1-4-1 Illustration . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . GATE COMMAND BOARD . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 1-5-1 Illustration . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . DUAL SNUB BOARD . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 1-6-1 Illustration . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . IF BOARD NP . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . KV CONTROL BOARD . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 1-8-1 Illustration . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 1-8-2 Indicators . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . AC/DC THREE PHASE BOARD . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 1-9-1 Illustration . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . SECTION 2 – ERRORS, DIAGNOSTICS & TROUBLESHOOTING 2-1 2-2 2-3 2-4 2-5 2-6 2-7 2-8 2-9 2-10 2-11 2-12 (NP, NP+, NP+ TWIN) INTRODUCTION . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . POWER ON DIAGNOSTICS . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . ERROR CODE LIST . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . ERROR REPORTING . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . DIAGNOSTICS . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 2-5-1 Detailed Error Description & Troubleshooting Guide . . . . . . . . . . . . . . . . . . . WARNING ERRORS . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . OTHER FAILURES . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . HEATING FUNCTION DIAGNOSTICS . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . ROTATION FUNCTION DIAGNOSTICS . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . INVERTER GATE COMMAND DIAGNOSTICS . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . INVERTER IN SHORT CIRCUIT DIAGNOSTICS . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . NO LOAD HV DIAGNOSTICS . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . i 1–1 1–1 1–1 1–2 1–2 1–3 1–3 1–4 1–5 1–5 1–6 1–6 1–7 1–7 1–8 1–9 1–9 1–10 1–11 1–11 2–1 2–1 2–1 2–3 2–7 2–8 2–8 2–28 2–30 2–32 2–33 2–34 2–36 2–39 X–RAY GENERATOR CT HISPEED SERIES ADVANCED DIAGNOSTICS PROPRIETARY TO GENERAL ELECTRIC COMPANY REV 11 2202119 TABLE OF CONTENTS SECTION PAGE SECTION 3 – ERRORS, DIAGNOSTICS & TROUBLESHOOTING 3-1 3-2 3-3 3-4 (NP++, NP++ TWIN) 3–1 INTRODUCTION . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . POWER ON DIAGNOSTICS . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . ERROR CODE LIST . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . ERROR REPORTING . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 3-4-1 NP Generator Error Reporting . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 3-4-2 Tiger Generator Error Reporting (not for NP++ and Ebisu systems) . . . . . . DIAGNOSTICS . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 3-5-1 Detailed Error Description & Troubleshooting Guide . . . . . . . . . . . . . . . . . . . 3-5-1-1 Errors . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . WARNING ERRORS . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . OTHER FAILURES . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . HEATING WITHOUT HV NOR ROTATION DIAGNOSTIC . . . . . . . . . . . . . . . . . . . . . . ROTATION WITHOUT HV NOR FILAMENT DIAGNOSTIC . . . . . . . . . . . . . . . . . . . . . HV POWER DIAGNOSTICS . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 3-10-1 Inverter Gate Command Diagnostic . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 3-10-2 Inverter in Short Circuit Diagnostic . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 3-10-3 No Load HV Diagnostic without Anode Rotation nor Filament Heating . . . . TROUBLESHOOTING AIDS . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 3–1 3–1 3–3 3–8 3–8 3–8 3–9 3–9 3–10 3–32 3–34 3–35 3–36 3–38 3–38 3–40 3–43 3–45 SECTION 4 – ERRORS, DIAGNOSTICS & TROUBLESHOOTING (FOR P5.4 OR LATER JEDI SOFTWARE) . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 4–1 3-5 3-6 3-7 3-8 3-9 3-10 3-11 4-1 4-2 4-3 4-4 4-5 4-6 4-7 4-8 4-9 4-10 4-11 INTRODUCTION . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . POWER ON DIAGNOSTICS . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . ERROR CODE LIST . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . ERROR REPORTING . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 4-4-1 NP Generator Error Reporting . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 4-4-2 Tiger Generator Error Reporting (not for NP++ and Ebisu systems) . . . . . . DIAGNOSTICS . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 4-5-1 Detailed Error Description & Troubleshooting Guide . . . . . . . . . . . . . . . . . . . 4-5-1-1 Errors . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . WARNING ERRORS . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . OTHER FAILURES . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . HEATING WITHOUT HV NOR ROTATION DIAGNOSTIC . . . . . . . . . . . . . . . . . . . . . . ROTATION WITHOUT HV NOR FILAMENT DIAGNOSTIC . . . . . . . . . . . . . . . . . . . . . HV POWER DIAGNOSTICS . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 4-10-1 Inverter Gate Command Diagnostic . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 4-10-2 Inverter in Short Circuit Diagnostic . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 4-10-3 No Load HV Diagnostic without Anode Rotation nor Filament Heating . . . . TROUBLESHOOTING AIDS . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . ii 4–1 4–1 4–3 4–8 4–8 4–8 4–9 4–9 4–10 4–33 4–35 4–36 4–37 4–39 4–39 4–41 4–45 4–47 X–RAY GENERATOR PROPRIETARY TO GENERAL ELECTRIC COMPANY CT HISPEED SERIES ADVANCED DIAGNOSTICS REV 11 2202119 SECTION 1 – LED DESCRIPTION 1-1 KV MEASURE BOARD 1-1-1 Illustration CAUTION This board forms part of the oil seal of the High Voltage Tank. It can only be removed at the factory. The Field Replaceable Unit (FRU) is the complete HV Tank. LF C SF 1–1 X–RAY GENERATOR CT HISPEED SERIES ADVANCED DIAGNOSTICS PROPRIETARY TO GENERAL ELECTRIC COMPANY REV 11 1-2 2202119 FILAMENT BOARD 1 INV 1-2-1 Illustration DANGER HIGH VOLTAGE: DO NOT GO INTO GENERATOR UNTIL INDICATOR DS3 GOES OUT. DC 160v LF Common SF DS3 – Green – +160v DC present 160v DS4 – Yellow – Inverter Output Running DC 0 SF_LF – Yellow – Small Focus / Large Focus Relay Feedback ON – Yellow – Inverter Command ON RST – Red – Board being reset or powered up DS2 – Yellow – Status LED DS1 – Yellow – Status LED 1–2 X–RAY GENERATOR CT HISPEED SERIES ADVANCED DIAGNOSTICS PROPRIETARY TO GENERAL ELECTRIC COMPANY REV 11 1-3 2202119 ROTATION BOARD HIGH SPEED 1-3-1 Illustration DANGER HIGH VOLTAGE: DO NOT GO INTO GENERATOR UNTIL INDICATOR DS6 AND DS7 (NEON–ORANGE) GO OUT. Auxiliary DC bus Common Main DS6 DC bus 1–3 X–RAY GENERATOR CT HISPEED SERIES ADVANCED DIAGNOSTICS PROPRIETARY TO GENERAL ELECTRIC COMPANY REV 11 1-3-2 2202119 Indicators INDICATOR COLOR INDICATES: RESET Red BOARD BEING RESET OR POWERED UP INV_ON Yellow THE INVERTER IS RUNNING DS1 Green PRESENCE OF +15 V SUPPLY DS2 Green PRESENCE OF –15 V SUPPLY DS3 Green PRESENCE OF +5 V SUPPLY DS4–DS5 Yellow BOARD STATUS DS6 Neon (orange) FAN VAC POWER SUPPLY PRESENT DS7 Neon (orange) DC BUS PRESENT 1–4 X–RAY GENERATOR CT HISPEED SERIES ADVANCED DIAGNOSTICS PROPRIETARY TO GENERAL ELECTRIC COMPANY REV 11 1-4 2202119 LV POWER SUPPLY 3 PH BOARD 1-4-1 Illustration HIGH VOLTAGE AND HOT SURFACE: DO NOT TOUCH BOARD UNTIL INDICATOR NE1 (NEON – ORANGE) GOES OUT. DANGER DC bus – 400 + 400 NE1 – Orange – indicates presence of DC Bus 160V DC 0 DS2 – Green – 160 VDC DS1 – Red – Mains Drop 1–5 X–RAY GENERATOR CT HISPEED SERIES ADVANCED DIAGNOSTICS PROPRIETARY TO GENERAL ELECTRIC COMPANY REV 11 GATE COMMAND BOARD Illustration DANGER DS300 CAUTION HIGH VOLTAGE: DO NOT TOUCH BOARD UNTIL DS300 ON THIS BOARD AND DS1 ON DUAL SNUB BOARD ARE OUT. Hot surface on transformer T300 and heat sink. DS300 – Neon (Orange) – Presence of voltage on DC bus for Flyback Converter to create power supplies for both Gate Commands DC bus DS201 DS201 – Green – Presence of +20 V Supply on high IGBT* Gate Command DS202 DS200 – Yellow – High IGBT* (Q200) Gate Command running DS200 DS202 – Green – Presence of –10 V Supply on high IGBT* Gate Command Inverter ILP current feedback ILR DS101 – Green – Presence of +20 V Supply on low IGBT* Gate Command DS102 DS100 –Yellow–Low IGBT* (Q100) Gate Command running DS101 1-5-1 DS100 1-5 2202119 DS102 – Green – Presence of –10 V Supply on low IGBT* Gate Command * Insulated Gate Bipolar Transistor 1–6 X–RAY GENERATOR PROPRIETARY TO GENERAL ELECTRIC COMPANY CT HISPEED SERIES ADVANCED DIAGNOSTICS REV 11 1-6 2202119 DUAL SNUB BOARD 1-6-1 Illustration DANGER HIGH VOLTAGE: DO NOT GO INTO GENERATOR UNTIL INDICATOR DS1 (NEON – ORANGE) GOES OUT. DS1 – Neon (Orange) – Indicates presence of voltage on DC Bus 1–7 X–RAY GENERATOR PROPRIETARY TO GENERAL ELECTRIC COMPANY REV 11 1-7 CT HISPEED SERIES ADVANCED DIAGNOSTICS 2202119 IF BOARD NP Service Laptop System I/F System I/F 1–8 X–RAY GENERATOR PROPRIETARY TO GENERAL ELECTRIC COMPANY REV 11 1-8 1-8-1 CT HISPEED SERIES ADVANCED DIAGNOSTICS 2202119 KV CONTROL BOARD Illustration 1–9 X–RAY GENERATOR CT HISPEED SERIES ADVANCED DIAGNOSTICS PROPRIETARY TO GENERAL ELECTRIC COMPANY REV 11 1-8-2 2202119 Indicators INDICATOR COLOR INDICATES: CONF Red FIELD PROGRAMMABLE GATE ARRAY (FPGA) CONFIGURATION NOT ACCOMPLISHED OK Yellow INVERTER GATE POWER SUPPLY OK TX_TAV Yellow TRANSMIT TO SERVICE LAPTOP RX_TAV Yellow RECEIVE FROM SERVICE LAPTOP T_CAN_X Yellow SYSTEM CAN BUS TRANSMIT R_CAN_X Yellow SYSTEM CAN BUS RECEIVE HALT Red MICROPROCESSOR HALTED RESET Red BOARD BEING RESET S0 TO S7 Yellow STATUS LED IN APPLICATION MODE THESE LEDS FLASH IN SEQUENCE CONTINUOUSLY DS1 Green –15V SUPPLY DS2 Green +15V SUPPLY 1–10 X–RAY GENERATOR CT HISPEED SERIES ADVANCED DIAGNOSTICS PROPRIETARY TO GENERAL ELECTRIC COMPANY REV 11 1-9 2202119 AC/DC THREE PHASE BOARD 1-9-1 Illustration DANGER CAUTION HIGH VOLTAGE: DO NOT GO INTO GENERATOR UNTIL DS1 (NEON – ORANGE) GOES OUT. Some components on this board can become very hot. DC Bus to inverter DC Bus out F1 – Fuse – Protects (on DC Bus): LV Power Supply 3 Phase Board Rotor Board High Speed Gate Command Board Type: 15 A, 600 VDC DS1 – Neon (Orange) – Indicates presence of voltage on the DC Bus. 1–11 X–RAY GENERATOR PROPRIETARY TO GENERAL ELECTRIC COMPANY blank CT HISPEED SERIES ADVANCED DIAGNOSTICS 2202119 1–12 X–RAY GENERATOR CT HISPEED SERIES ADVANCED DIAGNOSTICS PROPRIETARY TO GENERAL ELECTRIC COMPANY REV 11 2202119 SECTION 2 – ERRORS, DIAGNOSTICS & TROUBLESHOOTING (NP, NP+, NP+ Twin) Note This section is used for NP, NP+, and NP+ Twin systems. However, for the p5.4 or later JEDI software, use Section 4 (ERRORS, DIAGNOSTICS & TROUBLESHOOTING (for p5.4 or later JEDI Software)). For NP++ and NP++ Twin systems, use Section 3 (ERRORS, DIAGNOSTICS & TROUBLESHOOTING (NP++, NP++ Twin)). 2-1 INTRODUCTION This diagnostics section is to introduce the JEDI generator with the following information: Power–On diagnostics LED indication. List all the potential error codes that can be issued by JEDI Generator. Provide error code explanation, potential cause and recommended action. List of diagnostics aids and explanation of diagnostics. 2-2 POWER ON DIAGNOSTICS Refer to theory of operation for power–on sequence. This paragraph in this section is to provide meaning of boards’ LED status. The LED display status is offering useful information at a glance to proceed to error code based troubleshooting. Whenever in doubt, a simple step is to watch the LED status display on the kV control board, than the Rotation and Heater. kV control LED status: – During Power On Diagnostics : kV control board S0..................S7     S0.........................S7 ⊗⊗⊗⊗⊗⊗⊗ The 8 LED’s (S0...S7) are lit successively in both directions (as indicated by the arrows): the power up diagnostics are completed, kV control board is up and running. 2–1 X–RAY GENERATOR PROPRIETARY TO GENERAL ELECTRIC COMPANY REV 11 CT HISPEED SERIES ADVANCED DIAGNOSTICS 2202119 S0.....................S7 ⊗⊗⊗⊗ One out of two is lit: Data base checksum problem. An error code is logged. Refer to error code description. S0.........................S7 ⊗⊗   S7, S6, S5 are lit along with either S0 or S1 or S2 (depending of the type of FPGA down One out of two is lit: Data base checksum problem. An error code is logged. Refer to error code description. – When an application error occurs (Not PRD) ⊗⊗⊗⊗k ⊗k ⊗ The simplified error code is displayed on the Leds. They blink; when the error is cleared ( by a return to the standby mode for example ), the 8 LEDs are lit successively. Heater board LED status: (See LED Description) After the power on diagnostics, heater board LEDs DS1 and DS2 are lit successively. Any different status correspond to an abnormal situation. An error code is logged. Refer to error code description. Rotation board LED status: (See LED Description) After the power on diagnostics, rotation board LED DS5 is blinking. Any different status correspond to an abnormal situation. An error code is logged. Refer to error code description. 2–2 X–RAY GENERATOR CT HISPEED SERIES ADVANCED DIAGNOSTICS PROPRIETARY TO GENERAL ELECTRIC COMPANY REV 11 2-3 2202119 ERROR CODE LIST The error code list and associated short description is presented below. simplified error code 30 Description Error Error Code Description Class Tube Spits 2 2 2 2 2 0301H 0302H 0303H 0304H 0305H Tube spit (kV+ and kV– dropped) Tube spit (kV+ has dropped) Tube spit (kV– has dropped) Tube spit (kV regulation error) FPGA problem (restarting safety signal) 40 Rotation Error 4 4 4 4 4 4 4 4 4 4 4 0101H 0102H 0103H 0104H 0105H 0106H 0107H 0109H 0110H 0111H 0149H No CAN message received within 5 secs Database not correct Rotation current overload Rotation Openload Rotation Phases unbalanced Rotation Phases error Rotation Inverter permanent overcurrent MAINS_DROP has failed PRD error (Z3Z4=bitmap) F0 main frequency problem Unknown Rotation error 50 Heater Error 4 4 4 4 4 4 4 4 4 4 4 4 4 4 4 0201H 0203H 0204H 0205H 0206H 0207H 0208H 0210H 0211H 0212H 0213H 0214H 0215H 0216H 0221H 0222H 0223H 0224H 0248H 0249H No CAN message received within 5 secs Inverter overcurrent (HW detected) Open circuit (HW detected) Inverter short circuit (HW detected) Filament too high for Pre–heat Filament current too high Filament too hot Current over estimated (short circuit) Current under estimated (open circuit) MAINS_DROP detected PRD error (Z3Z4=bitmap) Stay too long in Boost Filament selection error current feedback not null when inverter off Filament database tube 1 error Filament database tube 2 error Filament database tube 3 error Filament database tube 4 error Unknown Heater LF error Unknown Heater SF error 4 2–3 X–RAY GENERATOR CT HISPEED SERIES ADVANCED DIAGNOSTICS PROPRIETARY TO GENERAL ELECTRIC COMPANY REV 11 simplified error code 60 70 2202119 Description Error Error Description 3 0306H No kV Feedback on anode 3 3 3 3 3 3 3 3 3 3 3 3 3 3 3 3 2 3 3 3 3 3 3 3 3 3 0307H 0308H 0309H 0310H 0311H 0312H 0313H 0314H 0316H 0317H 0318H 0319H 0320H 0323H 0401H 0402H 0403H 0504H 0801H 0802H 0803H 1406H 1407H 1408H 1409H 1410H No kV Feedback on cathode No kV Feedback on anode and cathode kV detected during kV diag kV max detected ILP current not OK ILR current not OK ILR max current detected ILR current timeout Spit Max error Spit Ratio error kV did not reach 75% after 20ms kV unbalanced detected FPGA problem (safety signal) ILP and ILR currents not OK No mA feedback mA scale error mA accuracy exceeded 5% Inverter Gate Power Supply failed Exposure backup mAs exceeded Exposure backup time exceeded Exp cmd while gene not ready time counter error mAs counter error AEC counter error mAs meter saturated FPGA Locked 4 0501H DC bus out of range 4 4 4 4 4 4 4 4 4 4 4 0503H Inverter Gate Power Supply error 0505H Mains power supply has dropped during exposure 0506H DC bus 1 phase precharge error 0507H DC bus 1 phase discharge error 0549H Unknown LVPS error 0553H Detected +160V too high 0557H Detected +160V too low 0563H Detected +15V too high 0567H Detected +15V too low 0573H Detected –15V too strong 0577H Detected –15V too weak Class Exposure errors Power Supply errors 2–4 X–RAY GENERATOR CT HISPEED SERIES ADVANCED DIAGNOSTICS PROPRIETARY TO GENERAL ELECTRIC COMPANY REV 11 simpliDescription Error Error fied error Class code 80 Hardware error 4 0180H 4 0181H 4 0280H 4 0281H 4 0322H 4 0601H 4 0602H 4 0902H 4 1402H 4 1403H 4 1404H 4 1405H 90 Application errors 2202119 Description Rotor board communication problem Rotor board has reset Heater board communication problem Heater board has reset kV ref ADC / DAC failed RTL error External CAN bus off tube Fan supply error Internal CAN bus off Connectic Fault FPGA configuration problem Tank sensor problem 4 0701H Saved RAM checksum pb 4 4 0702H 0704H Software problem Rotor/Heater hold too long 100 Com errors 4 4 4 4 4 0603H 0604H 0605H 0606H 1301H Debug screen com error Database download error TAV com error MPC/Madrid com error ADC Board com error 110 Thermal error 5 5 3 0804H 0903H 1454H Tank Thermal Error Tube exceeded 70degC Jedi inverter temperature too high 10 Rotor Warning 1 1 1 1 1 1 1 1 1 1 1 1 1 1 1 0151H 0152H 0153H 0154H 0155H 0156H 0157H 0158H 0159H 0160H 0161H 0162H 0163H 0164H 0199H CAN Domain command number error CAN Domain request with no transfer init CAN Domain Toggle bit error CAN Domain : less than 2 data to download CAN Domain Abort received & applied Bad index in config upload Tube switch while rotor not off Acceleration cmd while no tube selected Acceleration cmd while database not OK Database download while rotor speeding Acceleration command not OK Rotor acceleration while in error No CAN message received within 4 secs Rotation Inverter overcurrent (< 3 times) Unknown rotation warning 2–5 X–RAY GENERATOR CT HISPEED SERIES ADVANCED DIAGNOSTICS PROPRIETARY TO GENERAL ELECTRIC COMPANY REV 11 simplified error code 20 25 27 2202119 Description Error Error Description 1 0251H Received command is not OK 1 1 1 1 1 1 1 1 1 1 1 1 1 0252H 0253H 0254H 0255H 0256H 0257H 0258H 0259H 0260H 0261H 0262H 0263H 0299H Heater command not OK No CAN message received within 4 secs Heater inverter overcurrent (inverter1) (<3 times) Filament open circuit (inverter1) (<3 times) Heater Inverter short circuit (inverter1) (<3times) Tube switch while filaments not OFF CAN Domain command number error CAN Domain request with no transfer init CAN Domain Toggle bit error CAN Domain : less than 2 data to download CAN Domain Abort received & applied Database download while heater not cut Unknown Heater warning 1 0550H No more warn +160V too low or too high 1 1 1 1 1 1 1 1 1 0551H 0555H 0560H 0561H 0565H 0570H 0571H 0575H 0599H Detected +160V too high Detected +160V too low No more warn +15V too low or too high Detected +15V too high Detected +15V too low No more warn –15V too low or too high Detected –15V too strong Detected –15V too weak Unknown LVPS warning 1 1401H Saved RAM power supply limit reached 1 0703H Watchdog reset has just occurred Class Heater Warning Low Voltage Power supply Warnings Application warnings 2–6 X–RAY GENERATOR PROPRIETARY TO GENERAL ELECTRIC COMPANY CT HISPEED SERIES ADVANCED DIAGNOSTICS REV 11 2-4 2202119 ERROR REPORTING Np system only gets the simplified error code from the Jedi generator. The Np system errorlog adds to the simplified error code the following information : D error message (refer to the Np system documentation) D system phase : state of the system when the error occurred. Take care, the system state may be different to the generator phase (refer to the Np system documentation) D system time : date and time when the error occurred. Take care, the system time may be different to the generator time Whenever a generator error is logged in the system errorlog file and displayed on the operator console, the Jedi errorlog upload functionality is available to get more detailed information about the error. This function must be performed from the operator console. The simplified error code must be used to find the Jedi error code in the Jedi errorlog file. Having these two information, look at the Jedi trouble shooting table to find the FRU to replace. Error codes can also be read by connecting the laptop 2–7 X–RAY GENERATOR PROPRIETARY TO GENERAL ELECTRIC COMPANY CT HISPEED SERIES ADVANCED DIAGNOSTICS REV 11 2-5 2202119 DIAGNOSTICS This chapter describes diagnostics tools based on error codes and specific diagnostics. WARNING 2-5-1 Before any manual intervention, ensure the main power is off. Apply lock out–tag out procedure for your own safety when manipulating inside the equipment is required. Detailed Error Description & Troubleshooting Guide The table below provides guidelines to troubleshoot Generator problems based on error code. For each code, there is : – Associated message and additional explanation related to the error occurrence. – List potential cause, in the order of expected probability. – Recommended action, with, in some cases, link to some more information as indicated where cases apply, such as to run some specific diagnostics. Codes are sorted by ascending order both for simplified code and error code. Refer to the theory of operation for error code structure. Information about associated data structure is located at the end of each error code subset whenever it applies. Whenever wiring, cabling, LED check is mentioned in the recommended actions, refer to the LED Description or to Illustration 2–1. 2–8 X–RAY GENERATOR PROPRIETARY TO GENERAL ELECTRIC COMPANY REV 11 CT HISPEED SERIES ADVANCED DIAGNOSTICS 2202119 Errors Tube spits detection Errors (Code 30) Class 2 Error code Message/explanation Potential cause 30– 0301H Tube spit (kV+ and kV– dropped) kV drop/spit detected x–ray tube spit. 30– 0302H Tube spit (kV+ has dropped) kV drop/spit detected on Anode side 1. Anode side Tube spit. 2. Anode HV cable 3. HV tank 30– 0303H Tube spit (kV– has dropped) kV drop/spit detected on cathode side 1. Cathode side Tube spit. 2. Cathode HV cable 3. HV tank –Check HV cables and contacts –Tube problem. (Cathode side) –Check cable by interchanging them. –Run Open load kV test. (See diagnostic section) –Otherwise, HV tank 30– 0304H kV regulation error This is a slow speed safety circuit in case of “smooth” spits. 1 smooth HV tube spits 2 kV control board (HV regulation problem) 3 too much line impedance 4 half of AC/DC capacitors open 5 Inverter (parallel inductor or filtering capacitors) 6 HV tank –Run inverter diagnostics (See diagnostic section) –Run Open load kV test. (See diagnostic section) –Troubleshoot tube and contacts of HV cable. –Check DC bus voltage. 30– 0305H Re–starting safety. (unknown reason) Error occurring on safety line, while No root error present at the error inputs (Err 0301 to 0304). This is probably due to transient interference (Spikes). 1. External unknown cause. 2. kV control board. –Do a power and Grounding Check. Verify cabling and contacts. –If permanent or too systematic, replace kV control board. Report to engineering. 2–9 Recommended action/ Troubleshooting guide –If too frequent, and varies with HV, replace x–ray tube. Run Open load kV test. (See diagnostic section) –Check HV cables and contacts –Tube problem. (Anode side) –Check cable by interchanging them. –Run Open load kV test. (See diagnostic section) –Otherwise, HV tank. X–RAY GENERATOR PROPRIETARY TO GENERAL ELECTRIC COMPANY CT HISPEED SERIES ADVANCED DIAGNOSTICS REV 11 2202119 Anode Rotation errors (Code 40) Class 4 Error code Message/explanation Potential cause 40– 0101H No CAN message received within 5 sec’s The rotation board has not received any signal from the kV control main software for the last 5 sec., interpreted as a loss of communication 1. kV Control main software lost 2. kV control or Rotation board driver failure 3. Bad contact on one of the pin on the CAN bus line connector 40– 0102H Data base not correct. The firmware of the rotation board has detected that the data base received from the kV control board has wrong data. Rotation current overload Rotation board has detected Main or auxiliary rotation current too high compared to the max. Tube motor current. Rotation current openload Rotation board detected that no current is flowing to the motor. 1. Wrong kV control data base. It can only happen at power up. –Reload NVRam data base. –ultimate is to replace rotation board. 1. Rotation board 2. Rotation board capacitors 3. Wrong data base (improbable) Check wiring from rotation board to tube. If no cabling problem, run Rotation diagnostic to differentiate between rotation board and phase shift capacitors.(See diagnostic section). Check wiring from rotation board to tube. If no cabling problem, run Rotation diagnostic to differentiate between rotation board and phase shift capacitors.(See diagnostic section). 40– 0103H 40– 0104H 40– 0105H Rotation phases unbalanced The amplitude difference of the current bwtween main and auxiliary is too large. 40– 0106H Rotation phase error The rotation board has detected that the current in the anode stator does not shyow the correct phase shift between main and auxiliary. 1. Tube stator winding is open circuit: x–ray tube 2. Incorrect wiring (Open) 3. No DC bus on rotation board 4. Rotation board 5. Rotation board phase capacitors (improbable) 1. One rotation wire missing 2. Rotation board 3. Rotation board phase capacitors inverted or wrong value 4. Wrong tube configuration database 1. Rotation board 2. Rotation board phase capacitors inverted or wrong value 2–10 Recommended action/ Troubleshooting guide –Unlikely to happen. This is a debug error. –Retry –Re initialise and retry – Check wiring from rotation board to tube. – If no cabling problem, run Rotation diagnostic to differentiate between rotation board and phase shift capacitors. (See diagnostic section) – Check capacitors wiring. – Verify none is in short circuit. If no wiring problem, run Rotation diagnostic to differentiate between rotation board and phase shift capacitors. (See diagnostic section) X–RAY GENERATOR CT HISPEED SERIES ADVANCED DIAGNOSTICS PROPRIETARY TO GENERAL ELECTRIC COMPANY REV 11 Error code 40– 0107H 40– 0108H 40– 0109H 40– 0110H 40– 0111H 40– 0149H 2202119 Message/explanation Potential cause Rotation Inverter permanent overcurrent An overcurrent has been detected and 3 restart have been tried unsuccessfully within a single rotation state Rotation command error. Rotation board has informed kV control board that the command was erroneous; this is a DEBUG error. MAINS_DROP has failed The firmware of the rotation board has detected the mains_drop signal activation and transmitted error to kV control 1. Rotation board 2. Tube stator winding in short circuit –> x–ray tube 3. Wiring incorrect (shorted) PRD error Firmware checksum, RAM test and EPLD access are performed at power up or reset. FO main frequency problem. EPLD has not applied the inverter start command. Unknown Rotation error. The main software received an error from rotation board with no other code assocxiated. Recommended action/ Troubleshooting guide –Check wiring from rotation board to tube. –Troubleshoot tube windings –Replace rotation board No hardware failure None 1. Interference (spikes) 2. Mains drop 3. Cable or connector contact in DC bus between power unit and auxiliary unit 4. Rotation board Rotation board –Do a power and grounding check. –If systematic, replace rotation board Rotation board – Retry – Replace rotation board Software problem – No action – Report if too frequent. Replace rotation board. Associated data structure (refer to error code description section) : PRD error : component failure : 0001H=RAM 0002H=RAM stack 0200H=EPLD 8000H=program checksum rotation database error : 2 bytes data, each value points to a specific parameter found as being erroneous 2–11 X–RAY GENERATOR PROPRIETARY TO GENERAL ELECTRIC COMPANY REV 11 CT HISPEED SERIES ADVANCED DIAGNOSTICS 2202119 other errors : rotation state : 0=inverter OFF 1=acceleration 0 to low speed 2=acceleration 0 to high speed 3=acceleration low speed to high 4=low speed run 5=high speed run 6=high speed to low speed brake 7=brake reverse 8=brake DC 2–12 X–RAY GENERATOR PROPRIETARY TO GENERAL ELECTRIC COMPANY CT HISPEED SERIES ADVANCED DIAGNOSTICS REV 11 2202119 Filament Heater errors(Code 50) Class 4 Error code Message/explanation Potential cause 50– 0201H No CAN message received within 5 sec’s The Heater board has not received any command from the kV control main software for the last 5 sec., interpreted as a loss of communication 1. kV Control main software lost 2. kV control or Heater board driver failure 3. Bad contact on one of the pin on the CAN bus line connector 50– 0203H Heater inverter permanent overcurrent. Issued by the heater board when an overcurrent has been detected and 3 restarts have been tried without success within 100 ms Filament permanent open circuit. Issued by the heater board when an open has been detected and 3 restarts have been tried without success within 100 ms 1. Heater board –Restart. If persistent, replace Heater board 1. X–ray tube filament open 2. Heater to HV tank cable 3. Cathode HV cable or pin contacts 4. Open circuit in filament transformer inside HV Tank. –Switch on the other filament: if no error is reported, heater board is working properly. Check heater board to HV Tank to tube connections. If OK, test with Ohm– meter HV Tank heater transformers (primary and secondary) and filament impedance. Order accordingly If the same error is reported, check the connections as above. If all are right, replace heater board 50– 0205H Heater Inverter permanent short circuit (HW limit) Issued by the heater board when a short circuit has been detected and 3 restarts have been tried without success within 100 ms 1. Heater board –Restart. If persistent, replace Heater board 50– 0206H Filament current too high for “Pre–Heat” This is the result of an integrated value of the RMS current measurement on Heater board comparison with max. Tube value in data base. 1. Tube data base or calibration 2. Heater board –It’s unlikely, but reload NVRam database. –Replace heater board. 50– 0204H 2–13 Recommended action/ Troubleshooting guide –Unlikely to happen. This is a debug error. –Retry –Re initialise and retry. X–RAY GENERATOR CT HISPEED SERIES ADVANCED DIAGNOSTICS PROPRIETARY TO GENERAL ELECTRIC COMPANY REV 11 2202119 Error code Message/explanation 50– 0207H Potential cause Filament current too high for “Boost” Same as above Filament current too high for “Heat” Same as above Heater command error Heater board has informed kV control board that the command was erroneous; this is a DEBUG error. Current over estimated fork RMS filament current measurement (every 0.5 msec.) on heater board is too high Current under estimated fork RMS filament current measurement (every 0.5 m sec.) on heater board is too low 1. Tube data base or calibration 2. Heater board 1. Tube data base or calibration 2. Heater board No hardware failure 50– 0212H MAINS_DROP detected. The firmware of the Heater board has detected the mains_drop signal activation and has transmitted error to kV control 50– 0213H PRD error Firmware checksum, RAM test and EPLD access are performed at power up or reset. Boost too long on inverter1. Boost command stayed longer than 400ms Filament selection error. The relay on the Heater board selecting the filament is in the wrong position with respect to the selection 1. Interference (spikes) 2. Mains drop 3. Cable or connector contact in DC bus between power unit and auxiliary unit 4. Heater board 1. Heater board 2. No –15v on Heater board 50– 0208H 50– 0209H 50– 0210H 50– 0211H 50– 0214H 50– 0215H Recommended action/ Troubleshooting guide Same as above Same as above None Heater board Replace heater board 1. Open circuit 2. Heater board –Switch on the other filament: if no error is reported, heater board is working properly. Check heater board to HV Tank to tube connections. If OK, test with Ohm–meter HV Tank heater transformers (primary and secondary) and filament impedance. Order accordingly If the same error is reported, check the connections as above. If all are right, change heater board –Do a power and grounding check. –If systematic, replace heater board – Check presence of –15V : proceed to the recommended action discribed under error 70–0577H – Replace heater board. May be a loss of communication during boost. Retry. It will probably be followed by another communication code. Heater board Replace heater board 2–14 X–RAY GENERATOR CT HISPEED SERIES ADVANCED DIAGNOSTICS PROPRIETARY TO GENERAL ELECTRIC COMPANY REV 11 Error code 50– 0216H 50– 0221H 0222H 0223H 0224H 50– 0248H 0249H 2202119 Message/explanation Potential cause Measured current while in- Heater board verter OFF Inverter current has been measured while the inverter was not commanded Filament Database not 1. Wrong kV control data correct base. It can only The firmware of the heater happen at power up. board has detected that the Received Data base from kV control contains erroneous data for Tube 1, 2, 3, or 4. Unknown heater error The main software received an error from heater board with no error code associated. Software problem. Recommended action/ Troubleshooting guide Replace heater board –Reload NVRam data base. –ultimate is to replace Heater board. – No action – Report if too frequent. Associated data structure (refer to error code description section) : PRD error : component failure : 0001H=RAM 0002H=RAM stack 0200H=EPLD 8000H=program checksum Filament database error : 2 bytes bitmap ( LSByte=small focus, MSByte=large focus) Each bit points to an erroneous parameter other errors : 1 byte bitmap with the following structure : bit7 (MSB) focus selected 0=small focus selected 1=large focus selected bit6 bit5 bit4 tube selected 1=tube 1 selected 2=tube 2 3=tube 3 4=tube 4 bit3 bit2 small focus state 0=inverter OFF 1=preheat 2=boost 3=heat 2–15 bit1 bit0 (LSB) large focus state 0=inverter OFF 1=preheat 2=boost 3=heat X–RAY GENERATOR PROPRIETARY TO GENERAL ELECTRIC COMPANY CT HISPEED SERIES ADVANCED DIAGNOSTICS REV 11 2202119 Exposure errors (Code 60) Class 3 Error code 60– 0306H 60– 0307H 60– 0308H 60– 0309H 60– 0310H 60– 0311H Message/explanation Potential cause No kV feedback on anode side kv measured <12kV 0,5ms after start of exposure on anode side only No kV feedback on cathode side kv measured <12kV 0,5ms after start of exposure on cathode side only No kV Feedback (on anode and cathode) kv measured <12kV 0,5ms after start of exposure on both anode and cathode. kV detected during kV diagnostics. KV measured during inverter diagnostics while no kV must be generated. kV MAX detected kV reached 160 kv during exposure ILP current not OK. The current in the parallel resonant circuit of the inverter did not rise at the beginning of the exposure. 1. HV cable short circuit 2. HV tank 3. kV control board (less probable) 60– 0312H ILR current not OK The current in the serial resonant circuit of the inverter did not rise at the beginning of the exposure. 60– 0313H Inverter max. ILR current detected. This is a hardware detection of maximum current in serial resonant circuit. 1. HV cable short circuit 2. HV tank 3. kV control board (less probable) 1. HV tank 2. kV control board Recommended action/ Troubleshooting guide –Troubleshoot HV cables : run no load kV diagnostic along with inverting HV cables If HV cables are right, replace HV Tank –Troubleshoot HV cables : run no load kV diagnostic along with inverting HV cables If HV cables are right, replace HV Tank –Verify flat cable connections and sitting between kV control and HV tank. – Replace HV Tank Improper setup before the diagnostic is run. See HV power diagnostic section. kV control Replace kV control board 1. Inverter LC resonant circuit (Inverter coil assy, capa inverter assy.) 2. Inverter 3. kV control See above run HV power diagnostics 1 Casing spit (Tube) 2 HV tank 3 kV control – Check Tube – Check HV cable – run HV power diagnostics 2–16 run HV power diagnostics X–RAY GENERATOR PROPRIETARY TO GENERAL ELECTRIC COMPANY CT HISPEED SERIES ADVANCED DIAGNOSTICS REV 11 Class 3 Error code 60– 0314H 60– 0316H 60– 0317H 60– 0318H 60– 0319H 60– 0320H 60– 0323H 60– 0401H 2202119 Message/explanation Potential cause ILR Current time out. The current resonant frequency is lower than expected Spit Max error. kV control has detected the number of tube spits during exposure has reached the limit (see theory of operation, software section) Spit Ratio error. kV control has detected the rate of tube spits during exposure has reached the limit (see theory of operation, software section) kV did not reach 75% after 20ms. Indicates that there were no HV ON signal generated for exposure time count–up 1. kV control 2. Inverter 3. Current measurement circuit. reasonably x–ray tube kV unbalanced detected. Detects that there is more than 12kV difference between kV+ and kV – FPGA problem; Safety hit with unknown reason No error at the inputs while checking for error source. ILP and ILR current not OK No inverter current measures at the beginning of the exposure Recommended action/ Troubleshooting guide run HV power diagnostics –Try again at various kV/mA to confine problem. –Troubleshoot HV section. (x–ray tube, cable, HV tank) –Diagnose based on tube history. reasonably x–ray tube –Try again at various kV/mA to confine problem. –Troubleshoot HV section. (x–ray tube, cable, HV tank) –Diagnose based on tube history. 1. kV control Replace kV control. 1. HV tank 2. KV control Replace HV tank 1. This may be due to transient interference (Spikes). 2. SW bug Do a power and Grounding Check. Verify cabling and contacts. If permanent or too systematic, replace kV control board. Report to engineering run HV power diagnostics 1. Inverter LC resonant circuit. (Inverter coil assy, capa inverter assy.) 2. Inverter kV control board No mA feedback 1. HV tank mA measurement func2. kV control board tion: 3. x–ray tube (filament kV control has detected no open) mA feedback 20 ms after the beginning of the exposure. 2–17 – Disconnect HV Tank to kV control flat cable and verify with an Ohm– meter the accuracy of the 5 Ohms resistor on the HV Tank mA measure. If it is far out of range (4.9 – 5.1 ohm including DVM accuracy), replace HV Tank. – Verify filament impedance – Replace kV control board X–RAY GENERATOR PROPRIETARY TO GENERAL ELECTRIC COMPANY CT HISPEED SERIES ADVANCED DIAGNOSTICS REV 11 Error code 2202119 Message/explanation Potential cause 60– 0402H mA scale error mA has been measured to be either too low or too high with respect to mA demand 20 ms after the beginning of the exposure 1. kV control board 2. default filament currents not correctly adjusted 3. HV Tank (improbable) 60– 0403H (Class 2 error) mA accuracy exceeded 5% Measured mA every 50 msec exceeded 5% of mA demand. This error is logged, but does not stop the exposure. Inverter Gate Power Supply error gate supply voltage has dropped below the level required to drive the IGBTs properly Exposure backup time exceeded. The exposure command last longer than the duration that was loaded by the system (Backup time + 5%.) 1. tube spit 60– 0504H 60– 0802H 60– 0803H Exp cmd while gene not ready. generator received an exposure command while not in ready state 60– 1406H Time counter error. Error found in verifying the counter normal operation. FPGA locked. FPGA detected an error and did not allow start exposure after exposure command symbol was received 60– 1410H Recommended action/ Troubleshooting guide – If the tube has just been replaced or installed, run many exposures until the filament correction adjusts the default filament drive values. – If the error occurs after a while on a system : Disconnect HV Tank to kV control flat cable and verify with an Ohm– meter the accuracy of the 5 Ohms resistor on the HV Tank mA measure. If it is out of range, replace HV Tank else replace kV control board no action 1. Inverter (gate command board) 2. kV control board 3. generator input voltage too low or line impedance too high 1. System 2. System–generator cable 3. I/F board : exposure line stuck to the active state run HV power diagnostics 1. Inverter too hot, exposure parameters not OK 2. Software problem 3. Cable / communication problem 4. External cause (Spikes) kV control board If problem is persistent, check heater, anode rotation and system to generator preparation command to find the root cause for the generator not to be ready 1. Software problem 2 kV control If persistent, replace kV control 2–18 –Retry, changing parameters and duration – disconnect system–generator cable in different places and check exposure command line voltage Replace kV control Board X–RAY GENERATOR CT HISPEED SERIES ADVANCED DIAGNOSTICS PROPRIETARY TO GENERAL ELECTRIC COMPANY REV 11 2202119 Power supply (Code 70) Class 4 Error code Message/explanation Potential cause 70– 0501H DC bus out if range (<400 or >850) 70– 0503H Inverter Gate Power Supply error 1. mains problem (Too low or too high) 2. One phase missing at generator input 1. Mains 2. Cable pb 3. Gate command board (Inverter) 4. kV control 70– 0505H Mains power supply has dropped During exposure unknown None 70– 0549H Unknown LVPS error The main software received an LVPS error with no error code associated. Detected +160V too high +160V is higher than 225V (measured on heater board) Software problem – No action – Report if too frequent. 1. LVPS 2. Heater board 70– 0557H Detected +160V too low +160V is lower than 110V (measured on heater board) 1. LVPS 2. Heater board 70– 0563H Detected +15V too high +15V is higher than 17.3V (measured on heater board) 1. LVPS open circuit 2. Heater board Verify that the DC bus on LVPS board is in an acceptable range (CF1/CF2) If no, verify AC/DC fuse and AC input voltage. Check 160V on CF2/1 on heater board. If OK, replace heater board Else, disconnect the CF2 cable and measure again on the LVPS side. If voltage is wrong, replace LVPS board. Verify that the DC bus on LVPS board is in an acceptable range (CF1/CF2) If no, verify AC/DC fuse and AC input voltage. Check 160V on CF2/1 on heater board. If OK, replace heater board Else, disconnect the CF2 cable and measure again on the LVPS side. If voltage is wrong, replace LVPS board. Verify that the DC bus on LVPS board is in an acceptable range (CF1/CF2) If no, verify AC/DC fuse and AC input voltage. Check 15V on heater board (J3, pin4). If OK, replace heater board. Else, disconnect the control bus cable from the LVPS board and check the pin2 of the connector : if voltage is wrong replace LVPS board. 70– 0553H 2–19 Recommended action/ Troubleshooting guide –Check mains line 3 phases incoming voltage. –Verify line impedance if mains is low. run HV power diagnostics X–RAY GENERATOR PROPRIETARY TO GENERAL ELECTRIC COMPANY REV 11 Class 4 Error code CT HISPEED SERIES ADVANCED DIAGNOSTICS 2202119 Message/explanation Potential cause 70– 0567H Detected +15V too low +15V is lower than 13V (measured on heater board) 1. LVPS open circuit 2. Heater board 3. rotation (short circuit) kV control (short circuit) (improbable) 70– 0573H Detected –15V too high –15V is lower than –17.3V (measured on heater board) 1. LVPS open circuit 2. Heater board 70– 0577H Detected –15V too low –15V is higher than –13V (measured on heater board) 1. 2. 3. 4. LVPS (open circuit) Heater board rotation (short circuit) kV control (short circuit) (improbable) 2–20 Recommended action/ Troubleshooting guide Verify that the DC bus on LVPS board is in an acceptable range (CF1/CF2) If no, verify AC/DC fuse and AC input voltage. Check 15V on heater board (J3, pin4). If OK, replace heater board. If voltage=0, check the continuity on heater board between (J3, pin4) and (J1,pin2).If no continuity, replace heater board Else, disconnect the control bus cable from the LVPS board and check the pin2 of the connector : if voltage is wrong replace LVPS board. Else, check pin2 of the control bus cable when disconnecting the cable from each board successively to isolate the board inducing a voltage drop Verify that the DC bus on LVPS board is in an acceptable range (CF1/CF2) If no, verify AC/DC fuse and AC input voltage. Check –15V on heater board (J3, pin3). If OK, replace heater board. Else, disconnect the control bus cable from the LVPS board and check the pin3 of the connector : if voltage is wrong replace LVPS board. Verify that the DC bus on LVPS board is in an acceptable range (CF1/CF2) If no, verify AC/DC fuse and AC input voltage. Check –15V on heater board (J3, pin3). If OK, replace heater board. If voltage=0, check the continuity on heater board between (J3, pin3) and (J1,pin3).If no continuity, replace heater board Else, disconnect the control bus cable from the LVPS board and check the pin3 of the connector : if voltage is wrong replace LVPS board. Else, check pin3 of the control bus cable when disconnecting the cable from each board successively to isolate the board inducing a voltage drop X–RAY GENERATOR PROPRIETARY TO GENERAL ELECTRIC COMPANY REV 11 CT HISPEED SERIES ADVANCED DIAGNOSTICS 2202119 Hardware errors (Code 80) Class 4 Error code Message/explanation Potential cause 80– 0180H Rotation board communication problem. kV control board communication Watch Dog with Rotation board popped up because it did not get reply from Rotation board. 1. Rotation board 2. Control bus cable 3. kV control 80– 0181H Rotation board has reset. kV control has detected the Rotation board has reset. KV control will reload rotation data base. Heater board communication problem kV control board communication Watch Dog with Heater board popped up because it did not get reply from Heater board. 1. Rotation board 2. Interference (Spikes) –Reinitialize system, retry. –If persistent, replace Rotation board or check power and grounding. 1. Heater board 2. Control bus cable 3. kV control A/Check that heater firmware is running (DS1/2 Led are lit successively). If no : 1/verify heater board 5V : J3/pin2. If wrong : verify +15V/–15V (J3, pin3,4) : if they are right, change rotation board, else go to +/–15V errors troubleshooting 2/ verify that RST Led is not lit. If it is lit, disconnect successively the control bus cable from LVPS to rotation and kV control to find the board which is holding the reset line and replace it. If after disconnecting all the boards, the Led remains lit, replace heater board 3/ else replace heater boardB/Verify the flat cable between kV control and auxiliary module is correctly connected until the heater board C/else replace kV control board 80– 0280H 2–21 Recommended action/ Troubleshooting guide A/Check that rotation firmware is running (DS5 Led is blinking). If no : 1/verify rotation board 5V : Led DS3 is lit. If no : verify DS1/DS2 Leds : if they are lit, replace rotation board, else go to +/–15V errors troubleshooting 2/ verify that RESET Led is not lit. If it is lit, disconnect successively the control bus cable from heater and kV control to find the board which is holding the reset line and replace it. If after disconnecting all the boards, the Led remains lit, replace rotation board 3/ else replace rotation board B/Verify the flat cable between kV control and auxiliary module is correctly connected to the Rotation board C/else replace kV control X–RAY GENERATOR PROPRIETARY TO GENERAL ELECTRIC COMPANY CT HISPEED SERIES ADVANCED DIAGNOSTICS REV 11 Error code 2202119 Message/explanation Potential cause 80– 0281H Heater board has reset. KV control has detected the heater board has reset. KV control will reload rotation data base. 1. Heater board 2. Interference (Spikes) 80– 0321H KV conversion error KV feedback measured while no KV generated KV control board Replace KV control board 80– 0322H kV ref ADC / DAC failed kV control DAC and ADC capability are permanently tested for coherency. KV control board Only if this error is repetitive and comes alone (Not following other errors), replace kV control board. 80– 0601H RTL error (+ associated data to check which of the 4 RTL lines) Real Time Lines show a wrong state. RTL’s are tested on a regular basis in stand by. –Check communication cable –Check system communication power supply (if any) –Check system interface to kV control flat cable –replace system interface board –replace kV control board 80– 0602H External CAN bus off 1. system communication power supply (for isolated communications) 2. system communication cable 3. system interface board 4. system interface to kV control flat cable 5. kV control board 1. system communication power supply (for isolated communications) 2. system communication cable 3. system interface board 4. system interface to kV control flat cable 5. kV control board 80– 0902H Tube Fan supply error. Rotation board has detected that a wrong voltage is applied to the tube fan 1. No 115V tube cooling supply 2. Rotation board –Check presence of the AC voltage (DS6 neon) at the input of the Rotation board. If ok, replace the rotation board 80– 1402H Internal CAN bus off Can device on kV control board detected abnormal level on it’s 2 line and sent error to the CPU 3. kV control 4. Control bus cable 3. Heater, Rotation Check a short circuit on CAN pins of the control bus cable. Short circuit may be either on boards or connector / cable. If no fault detected, replace kV control 2–22 Recommended action/ Troubleshooting guide –Reinitialize system, retry. –If persistent, replace board or check power and grounding. –Check communication cable –Check system communication power supply (if any) –Check system interface to kV control flat cable –replace system interface board –replace kV control board X–RAY GENERATOR PROPRIETARY TO GENERAL ELECTRIC COMPANY CT HISPEED SERIES ADVANCED DIAGNOSTICS REV 11 Error code 80– 1403H 80– 1404H 80– 1405H 2202119 Message/explanation Potential cause kV control board. Recommended action/ Troubleshooting guide Check connection of the following cables : kV control to system I/F board, kV control to HV tank, HV tank to inverter. Replace kV control board. Connection Fault One of the flat cable connector is not connected in Generator. FPGA configuration problem. Detected during power up. The kV control main software cannot load the FPGA. Tank temperature sensor problem. Means that t° value of the HV tank is < 10°C Multiple, but likely improbable. kV control HV tank Replace kV control Replace HV Tank 2–23 X–RAY GENERATOR CT HISPEED SERIES ADVANCED DIAGNOSTICS PROPRIETARY TO GENERAL ELECTRIC COMPANY REV 11 2202119 Application errors(Code 90) Class 4 Error code Message/explanation Potential cause NV RAM checksum pb. Generator kV control board has detected corruption in the NV Ram verification (After power up) Software problem. 1. Database problem 2. External cause (Spikes) 3. kV control 1. Software or Data Base problem. 2. kV control board failure. –Reload the Data base –Reload the software and database If no improvement : –Replace kV control board 90– 0703H Watchdog reset has just occurred. This error is logged when the CPU of the kV control board is reset by it’s Watch Dog timer. 1. Software or Data Base problem. 2. kV control board failure. –Reload the Data base –Reload the software and database If no improvement : –Replace kV control board 90– 0704H Rotation/Heater hold too long. Will pop up if preparation command from the system is maintained longer than 3 minutes. Software problem. No action 90– 0701H 90– 0702H 2–24 Recommended action/ Troubleshooting guide If persistent : –Reload the Data base. If no improvement : –Replace kV control board and reload the data base. X–RAY GENERATOR CT HISPEED SERIES ADVANCED DIAGNOSTICS PROPRIETARY TO GENERAL ELECTRIC COMPANY REV 11 2202119 Communication errors(code 100) Class 4 Error code 100– 0603H 100– 0604H 100– 0605H Message/explanation Potential cause Debug screen com. error Engineering use Database download error Generator has detected a problem during data base download TAV communication error. Generator has detected a communication problem between the I/F and the service laptop (When generator is controlled by the laptop) 1. Database file incorrect 2. Transmission problem Retry Check data base file Potential laptop incompatibility 1. Software / laptop problem 2. Cable problem Retry 2–25 Recommended action/ Troubleshooting guide X–RAY GENERATOR PROPRIETARY TO GENERAL ELECTRIC COMPANY REV 11 CT HISPEED SERIES ADVANCED DIAGNOSTICS 2202119 Thermal errors(code 110) Class 5 Error code Message/explanation Potential cause 110– 0804H Tank Thermal Error HV tank temperature measurement has reached 60 degree C 1. HV tank too hot; normal error 2. HV tank 3. kV control 110– 0903H 70 degree C thermal safety error 70° loop detected open 1. X–ray tube too hot; normal error 2. Cooling problem 3. Wiring problem 4. Sensor problem (Tube) 5. rotation board 2–26 Recommended action/ Troubleshooting guide –Wait for error clearance –If persistent while HV Tank is cool : 1/check flat cable connection between HV Tank and kV control board 2/ Check presence of –15v (LED DS1 on kV control board) 3/replace HV tank 4/replace kV control –Wait for error clearance –If persistent : 1/Check tube cooling (Fan), troubleshoot 115 volts from PDU to Fans, through Rotation board; check tube thermal sensor 2/ short circuit the sensor feedback on rotation board connector and verify that error disappears. If no, replace rotation board X–RAY GENERATOR DC bus, 400 ... 800 V * Heater board DC bus, 400 ... 800 V DS 1 DS 3 +M– DC bus, 160V (120 to 200V –15v +15v * DS 1 Gate command board LVPS * DS 300 NE 1 2–27 AC/DC OGP 12V Pin1, 9 J2, 3 NP/IF DS 1, 2 –15v, +15v –15v, +15v kV ctrl ”VCC”: +5v –15v +15v + – DS 2 * Rotation board DS 3, 2, 1 +5, –15, +15 DS 7 DS 6 JEDI Visual Power Supply Distribution F1 INVERTER. & LLC.circuit PROPRIETARY TO GENERAL ELECTRIC COMPANY REV 11 Neon’s LEDs Illustration 2–1 * * * EMC Flt. 3ph, 380 – 480 VAC 115V AC Connection on Gantry base, slip ring, Gantry rotate 2202119 X–RAY GENERATOR K1 PDU CT HISPEED SERIES ADVANCED DIAGNOSTICS C B 1 PROPRIETARY TO GENERAL ELECTRIC COMPANY CT HISPEED SERIES ADVANCED DIAGNOSTICS REV 11 2-6 2202119 WARNING ERRORS Warning errors are the result of automated and regular background monitoring for either software events or voltages threshold overtaking. Those errors are merely for engineering usage and do not indicate any hardware error failure. However, as they are logged into the Generator Err_log file, just as the previous list of error, they are listed here to help error sorting out. Should too many of them are seen when viewing error log, it is advised to report them via CQA, since the equipment is still operating. 10 20 Rotation Warning Heater Warning 0151H CAN Domain command number error 0152H 0153H 0154H 0155H 0156H 0157H 0158H 0159H 0160H 0161H 0162H 0163H 0164H 0199H CAN Domain request with no transfer init CAN Domain Toggle bit error CAN Domain : less than 2 data to download CAN Domain Abort received & applied Bad index in config upload Tube switch while rotor not off Acceleration cmd while no tube selected Acceleration cmd while database not OK Database download while rotor speeding Acceleration command not OK Rotor acceleration while in error No CAN message received within 4 secs Rotation Inverter overcurrent (< 3 times) Unknown rotation warning 0251H 0252H 0253H 0254H 0255H 0256H 0257H 0258H 0259H 0260H 0261H 0262H 0263H 0299H Received command is not OK Heater command not OK No CAN message received within 4 secs Heater inverter overcurrent (inverter1) (<3 times) Filament open circuit (inverter1) (<3 times) Heater Inverter short circuit (inverter1) (<3times) Tube switch while filaments not OFF CAN Domain command number error CAN Domain request with no transfer init CAN Domain Toggle bit error CAN Domain : less than 2 data to download CAN Domain Abort received & applied Database download while heater not cut Unknown heater warning 2–28 X–RAY GENERATOR PROPRIETARY TO GENERAL ELECTRIC COMPANY CT HISPEED SERIES ADVANCED DIAGNOSTICS REV 11 25 27 2202119 Low Voltage Power Supply Warnings Application warnings 0550H No more warn +160V too low or too high 0555H 0560H 0561H 0565H 0570H 0571H 0575H 0599H Detected +160V too low No more warn +15V too low or too high Detected +15V too high Detected +15V too low No more warn –15V too low or too high Detected –15V too strong Detected –15V too weak Unknown LVPS warning 1401H Saved RAM power supply limit reached This message is the result of a computation that is made by the software based on the Date for a period of approximately 7 years 2–29 X–RAY GENERATOR PROPRIETARY TO GENERAL ELECTRIC COMPANY CT HISPEED SERIES ADVANCED DIAGNOSTICS REV 11 2-7 2202119 OTHER FAILURES Error Message / excode planation System GENERATOR does not reply to the system Potential cause Recommended action Troubleshooting guide 1. 2. 3. 4. Perform the troubleshooting in the following way : 1/kV control Leds S0–S7 are lit successively : refer to system communication errors (code 06xx H) 2/Leds S0–S7 show a specific pattern : refer to PRD errors section 3/Led RESET is lit : board is maintained in reset either by the system or by a system I/F failure or kV control failure 4/Led HALT is lit : replace kV control 5/No Led is lit : verify that +5V on kV control board (J6, pin2).is present. If yes, replace kV control. If no : 6/ verify if +15V/–15V is present (Leds DS1/DS2). If yes : verify that mains_drop line is not stopping the kV control software (mains_drop active) : 6–1/ check if DS1 LED on LVPS board is lit. If yes, replace LVPS board. 6–2/ disconnect Heater board control bus cable. Check if kV control software starts. If yes, replace Heater board. 6–3/ Disconnect Rotation board control bus cable and connect it directly to LVPS board. Check if kV control software starts. If yes, replace rotation board. 6–4/ else, replace kV control board if no : 7/ Verify if +15V/–15V is present on rotation board (DS1/DS2) and the 160V is present on the heater board (DS3). If yes : check the control bus cable to the kV control board. If no error, change the kV control board. If no : 8/ Verify if the LVPS DC input is right. If no, check AC/DC fuse and input line If yes : 9/disconnect all output cables from the LVPS board. Verify the +15V/–15V/160V output. If right : reconnect each board successively to find the one stucking the 15V to ground. If wrong, replace LVPS board No power on Generator EMC filter AC/DC– Diode bridge Cable between AC/DC and LVPS 5. LVPS down 6. CAN cable problem 7. kV control 8. CT interface 9. Rotation board 10. Heater board 11. Inverter in short circuit 12. Generator to system cable 2–30 X–RAY GENERATOR CT HISPEED SERIES ADVANCED DIAGNOSTICS PROPRIETARY TO GENERAL ELECTRIC COMPANY REV 11 2202119 3 phases CB1 breaker trips in PDU 1. Short circuit on Generator : IGBT in short circuit ACDC or bridge rectifier in short circuit EMC filter in short circuit Software or 1. After software download: Data base cor- –Incorrect or uncompleted rupt download –Checksum problem 1/ Disconnect DC bus cables between AC/DC and inverter (on AC/DC side) 2/ Check if these cables are in short circuit. If yes, replace inverter if no, 3/ Disconnect AC line cables between EMC and AC/DC (on EMC side) 4/ Check if these cables are in short circuit. If yes, replace AC/DC FRU if no : 5/ Disconnect AC line input from EMC board. Check EMC for short circuit between phases. If short circuit, replace EMC board. Retry download 2–31 X–RAY GENERATOR PROPRIETARY TO GENERAL ELECTRIC COMPANY CT HISPEED SERIES ADVANCED DIAGNOSTICS REV 11 2-8 2202119 HEATING FUNCTION DIAGNOSTICS Purpose : The purpose of this test is to drive the heater inverter(s) on both filaments and all the tubes connected to the generator in order to identify a faulty heater FRU or a wrong connection between heater board, HV Tank and tube(s). HV function and Rotation function are disabled during this test. Pre–requisites : D kV control board alive and running : S0–S7 Leds are lit successively or a combination of them blink D heater board alive and running : DS1 and DS2 Leds are lit successively D heater DC supply present : DS3 Led is lit Test type : No manual interaction Sequence : Once selected the tube the test is running on , start the diagnostic. The following sequence runs on the small focus and then on the large focus : D 5 seconds preheat D 0,4s boost D 5s heat ( focal spot max current – 1Amp ) There is 10s stop time between each focal spot run During the test , the heater safeties are checked the same way than in application mode Error codes reporting : Refer to the troubleshooting table 2–32 X–RAY GENERATOR CT HISPEED SERIES ADVANCED DIAGNOSTICS PROPRIETARY TO GENERAL ELECTRIC COMPANY REV 11 2-9 2202119 ROTATION FUNCTION DIAGNOSTICS Purpose : The purpose of this test is to drive the rotation inverter(s) in high speed mode (for application supporting high speed mode ) and low speed mode on all the tubes connected to the generator in order to identify a faulty rotation FRU or a faulty dephasing capacitors FRU or a wrong connection between rotation board and tube. HV function and Heater function are disabled during this test. Pre–requisites : D kV control board alive and running : S0–S7 Leds are lit successively or a combination of them blink D rotation board alive and running : DS5 Led blinking D rotation DC supply present : DS7 neon is lit D cabling between rotation board and tube checked Test type : No manual interaction, no loop on Sequence : Once selected the tube the test is running on , start the diagnostic. The following sequence runs in low speed mode and then in high speed mode (if high speed mode allowed) : D acceleration ( time depends on tube type ) D 2s run D brake ( time depends on tube type ) There is 2s stop time between each speed mode. During the test , the rotation safeties are checked the same way than in application mode Error codes reporting : error code 0103H 0104H 0105H 0106H 0103H 0104H 0105H 0106H associated data associated data points only to high speed mode conclusion Power–off. Check if rotation board K2 relay is short circuiting the rotor capacitors. If yes replace the rotation board. If no replace the rotor capacitors associated data points to both high speed and low speed mode – Check presence of –15v (LED DS2 on rotation board). If not, proceed to the recommended action described under error 70–0577 – replace the rotation board For the other error codes, refer to the troubleshooting table 2–33 X–RAY GENERATOR PROPRIETARY TO GENERAL ELECTRIC COMPANY CT HISPEED SERIES ADVANCED DIAGNOSTICS REV 11 2202119 2-10 INVERTER GATE COMMAND DIAGNOSTICS Purpose : The purpose of this test is to verify that the HV power inverter drive is working properly. The IGBTs gate drive supply and the IGBTs gate drive is verified. At the same time verification is made that no inverter currents nor High voltage are measured. This test is performed without DC voltage applied to the inverter so that no Xray is generated. Anode rotation and filament drive are not activated during this test. Pre–requisites : D generator input line in an acceptable range ( 380V–10% to 480V+10% for 3–phase AC input ) D kV control board alive and running : S0–S7 Leds are lit successively or a combination of them blink D inverter gate_cmd board DC supply present : DS300 neon is lit Test type : Manual operation is required. Sequence : 1/ Disconnect the 2 DC bus cables from the AC/DC board ( see LED Description ) 2/ Power on the generator 3/ Push the TGP board reset switch, or OGP board reset switch. 4/ Verify that the DS1 neon on inverter dual snubbers board is not lit 5/ Start the diagnostic and verify : D error reported on the operator console D inverter gate_cmd board Leds DS101, DS 102, DS201, DS202 are lit : IGBTs gate drive supply is working properly 6/ Press the exposure switch (10s exposure is taken after a 10 sec. delay). 7/ During the “exposure”, verify : D error reported on the operator console D inverter gate_cmd board Leds DS100 and DS200 are lit : IGBTs gate drive is working properly 8/ Release the exposure switch 9/ Power off the generator 10/ Reconnect the 2 DC bus cables from the AC/DC board (see LED Description ) 2–34 X–RAY GENERATOR PROPRIETARY TO GENERAL ELECTRIC COMPANY CT HISPEED SERIES ADVANCED DIAGNOSTICS REV 11 2202119 Error reporting : Error DS1 neon lit DS300 neon off 0301/0302/0303/0304/0309/03 10/0311/0312/0313/0314/0319 /0323 (H) 0320 0501 0503 0504 one of DS101/DS102/DS201/DS202 LEDs off while no error reported DS100 and/or DS200 LEDs off Conclusion Check that DC bus cables have been removed Check the gate_cmd supply cable between AC/DC and gate_cmd board Check that DC bus cables have been removed. If yes, replace kV control board if problem persists, replace Kv control board kV control or inverter fault, replace inverter first kV control or inverter fault, replace inverter first kV control or inverter fault, replace inverter first Replace inverter Check cabling between kV control, HV Tank and gate_cmd board. If cabling is right, kV control or inverter fault, replace inverter first 2–35 X–RAY GENERATOR PROPRIETARY TO GENERAL ELECTRIC COMPANY REV 11 CT HISPEED SERIES ADVANCED DIAGNOSTICS 2202119 2-11 INVERTER IN SHORT CIRCUIT DIAGNOSTICS Purpose : The purpose of this test is to verify that the HV power inverter is working properly. The inverter is commanded at a fixed frequency and is loaded with a short circuit. Verification is made that the inverter currents are correctly set. . At the same time verification is made that no High voltage is measured. This test is performed without connecting the HV Tank to the inverter so that no Xray is generated. Anode rotation and filament drive are not activated during this test. Pre–requisites : D generator input line in an acceptable range ( 380V–10% to 480V+10% for 3–phase AC input ) D kV control board alive and running : S0–S7 Leds are lit successively or a combination of them blink D inverter gate_cmd board DC supply present : DS300 neon is lit D inverter dual snubber board DC supply present : DS1 neon is lit D Inverter gate command diagnostic passed without failure Test type : Manual operation is required. Sequence : 1/ Disconnect the HV Tank primary cables from the inverter (see the X–ray Generator Components section of X–ray Generator, of the Component Replacement manual). Take care not to disconnect at the same time the parallel inductor cable which is tightened with the HV Tank primary cables Put the short circuit cable ( included in the first aid kit ) between the the two capacitors as shown : 2–36 X–RAY GENERATOR PROPRIETARY TO GENERAL ELECTRIC COMPANY CT HISPEED SERIES ADVANCED DIAGNOSTICS REV 11 2202119 Check that the parallel inductor cable do not remain unscrewed. 2/ Power on the generator 3/ Push the TGP board reset switch, or OGP board reset switch. 4/ Verify that the DS1 neon on inverter dual snubbers board is lit 5/ Verify that the DS300 neon on inverter gate_cmd board is lit 6/ Start the diagnostic and verify that no error is reported on the operator console 7/ Press the exposure switch (500ms exposure is taken) 8/ Release the exposure switch 9/ verify error reported on the console 10/ After exiting the test, power off the generator 11/ Remove the short circuit cable, reconnect the HV Tank primary cables (see the X–ray Generator Components section of X–ray Generator, of the Component Replacement manual). Verify that the parallel inductor cable is connected. Error reporting : error DS1 neon off DS300 neon off Conclusion Check that DC bus cables between AC/DC and inverter Check the gate_cmd supply cable between AC/DC and gate_cmd board 0301/0302/0303/0304/0309/03 Check that HV Tank primary cables have been removed. 10/0319 (H) If yes, replace kV control board 0311 No Ilp current detected. See note 2 0312 No Ilr current detected. See note 3 0313 replace kV control board 0314 Ilr current resonant frequency is lower than expected. See note 4 0320 if problem persists, replace kV control board 0323 Both Ilr and Ilp currents not detected. See note 1 0501 kV control or inverter can be faulty 0503 kV control or inverter can be faulty 0504 kV control or inverter can be faulty 0505 Isolation fault between inverter components and ground. Check inverter inductors. If no faulty component, kV control or inverter can be faulty note 1 : Ilp and Ilr currents not detected 1/ Check the –15V (Led DS1) on kV control board (see LED Description). If it is not lit, refer to “other failures” section. Else : 2/ Power off the generator. Wait until all neons are off 3/ Check that the currents transformers (capacitor set) to gate_cmd board cable is correctly connected. If yes : 4/ Check that the inverter inductors are correctly connected. If yes : 5/ Check that the gate_cmd to HV Tank cable and HV Tank to kV control cables are correctly connected. If yes, change the inverter 6/ Reconnect all the cables 2–37 X–RAY GENERATOR PROPRIETARY TO GENERAL ELECTRIC COMPANY CT HISPEED SERIES ADVANCED DIAGNOSTICS REV 11 2202119 note 2 : Ilp current not detected 1/ Power off the generator. Wait until all neons are off 2/ Check that the parallel inductor is correctly connected. If yes : 3/ Check that the parallel inductor impedance is 0 Ohms. If no : replace inverter. If yes : 4/ Disconnect the currents transformers to gate_cmd board cable. Check that the parallel current transformer impedance is 0. If no : change the capacitor set. Else : 5/ Check that the gate_cmd to HV Tank cable and HV Tank to kV control cables are correctly connected. If yes : 6/ Disconnect the HV Tank to kV control cable. Check that the impedance between pin20 and pin21 of J2 of HV Tank is 3,3Ohms. If no change the inverter. If yes : 7/ either the fault is at the capacitor set level or at the kV control level. 8/ Reconnect all the cables note 3 : Ilr current not detected 1/ Power off the generator. Wait until all neons are off 2/ Check that the inductors are correctly connected. If yes : 3/ Disconnect the currents transformers to gate_cmd board cable. Check that the serial current transformer impedance is 0. If no : change capacitor set. Else : 4/ Check that the gate_cmd to HV Tank cable and HV Tank to kV control cables are correctly connected. If yes : 5/ Disconnect the HV Tank to kV control cable. Check that the impedance between pin20 and pin21 of J2 of HV Tank is 5 Ohms. If no change inverter. If yes : 6/ either the fault is at the capacitor set level or at the kV control level. 7/ Reconnect all the cables note 4 : Ilr current resonant frequency is lower than expected 1/ Power off the generator. Wait until all neons are off 2/ Check that the inductors are correctly connected. If yes : 3/ Check that the resonant capacitor and filtering capacitors are not open. If they are : replace the capacitor set. Else : 4/ Disconnect the currents transformers to gate_cmd board cable. Check that the parallel current transformer impedance is 0. If no : change the capacitor set. Else : 5/ either the fault is at the capacitor set level or at the kV control level. 6/ Reconnect all the cables 2–38 X–RAY GENERATOR PROPRIETARY TO GENERAL ELECTRIC COMPANY REV 11 CT HISPEED SERIES ADVANCED DIAGNOSTICS 2202119 2-12 NO LOAD HV DIAGNOSTICS Purpose : The purpose of this test is to verify that the HV power inverter and HV tank are working properly. The exposure is taken as in application mode except that no filament drive nor anode rotation is running. Verification is made that the inverter currents are correctly set and that kV regulation is operating properly. As no filament drive is applied, no XRays are generated. This test also allow to separate generator from HV cable or x–ray tube problem by running it with or without the HV cables plugged on the HV tank. Pre–requisites : D generator input line in an acceptable range ( 380V–10% to 480V+10% for 3–phase AC input ) D kV control board alive and running : S0–S7 Leds are lit successively or a combination of them blink D inverter gate_cmd board DC supply present : DS300 neon is lit D inverter dual snubber board DC supply present : DS1 neon is lit D Inverter gate command diagnostic passed without failure D Inverter in short circuit diagnostic passed without failure D HV Receptacles must be filled with oil if HV cables are removed. Test type : Manual operation is required. Sequence : 1. Power on the generator 2. Push the TGP board reset switch, or OGP board reset switch. 3. Start the diagnostic and verify : – error reported on the operator console – inverter gate_cmd board Leds DS101, DS 102, DS201, DS202 are lit : IGBTs gate drive supply is working properly 4. Select kV (default = 80) and exp.time (default = 1s). 5. Press the exposure switch 6. During the “exposure”, verify : – error reported on the operator console 7. Release the exposure switch 8. Power off the generator Error reporting : See troubleshooting table 2–39 X–RAY GENERATOR PROPRIETARY TO GENERAL ELECTRIC COMPANY blank CT HISPEED SERIES ADVANCED DIAGNOSTICS 2202119 2–40 X–RAY GENERATOR CT HISPEED SERIES ADVANCED DIAGNOSTICS PROPRIETARY TO GENERAL ELECTRIC COMPANY REV 13 2202119 SECTION 3 – ERRORS, DIAGNOSTICS & (NP++, NP++ Twin) TROUBLESHOOTING Note This section is used for NP++ and NP++ Twin systems. However, for the p5.4 or later JEDI software, use Section 4 (ERRORS, DIAGNOSTICS & TROUBLESHOOTING (for p5.4 or later JEDI Software)). For NP, NP+, and NP+ Twin systems, use Section 2 (ERRORS, DIAGNOSTICS & TROUBLESHOOTING (NP, NP+, NP+ Twin)). 3-1 INTRODUCTION This diagnostics section is to introduce the JEDI generator with the following information: Power–On diagnostics LED indication. List all the potential error codes that can be issued by JEDI Generator. Provide error code explanation, potential cause and recommended action. List of diagnostics aids and explanation of diagnostics. 3-2 POWER ON DIAGNOSTICS Refer to theory of operation for power–on sequence. This paragraph in this section is to provide meaning of boards’ LED status. The LED display status is offering useful information at a glance to proceed to error code based troubleshooting. Whenever in doubt, a simple step is to watch the LED status display on the kV control board, than the Rotation and Heater. kV control LED status: – During Power On Diagnostics : kV control board S0.........................S7 ⊗⊗⊗⊗⊗⊗⊗     The 8 LED’s (S0...S7) are lit successively: the power up diagnostics are completed, kV control board is up and running. 3–1 X–RAY GENERATOR PROPRIETARY TO GENERAL ELECTRIC COMPANY CT HISPEED SERIES ADVANCED DIAGNOSTICS REV 13 2202119 S0.....................S7 ⊗⊗⊗⊗ One out of two is lit: Data base checksum problem. An error code is logged. Refer to error code description. S0.........................S7 ⊗⊗   S7, S6, S5 are lit along with either S0 or S1 or S2 (depending of the type of FPGA download error): FPGA download problem. An error code is logged. Refer to error code description. – When an application error occurs (Not PRD) ⊗⊗⊗⊗k ⊗k ⊗ The simplified error code is displayed on the Leds. They blink; when the error is cleared ( by a return to the standby mode for example ), the 8 LEDs are lit successively. Heater board LED status: (See central listing) After the power on diagnostics, heater board LEDs DS1 and DS2 are lit successively. Any different status corresponds to an abnormal situation. An error code is logged. Refer to error code description. Rotation board LED status: (See central listing) After the power on diagnostics, rotation board LED DS5 is blinking. Any different status corresponds to an abnormal situation. An error code is logged. Refer to error code description. 3–2 X–RAY GENERATOR CT HISPEED SERIES ADVANCED DIAGNOSTICS PROPRIETARY TO GENERAL ELECTRIC COMPANY REV 13 3-3 2202119 ERROR CODE LIST The error code list and associated short description is presented below. simplified error code 30 Description 40 Rotation Error 4 4 4 4 4 4 4 4 4 4 4 4 0101H 0102H 0103H 0104H 0105H 0106H 0107H 0109H 0110H 0111H 0112H 0149H No CAN message received within 5 secs Database not correct Rotation current overload Rotation Openload Rotation Phases unbalanced Rotation Phases error Rotation Inverter permanent overcurrent MAINS_DROP has failed PRD error (Z3Z4=bitmap) F0 main frequency problem Rotor HW/FW Config error Unknown rotation error 50 Heater Error 4 4 4 4 4 4 4 4 4 4 4 4 4 4 4 0201H 0203H 0204H 0205H 0206H 0207H 0208H 0210H 0211H 0212H 0213H 0214H 0215H 0216H 0221H 0222H 0223H 0224H 0248H 0249H No CAN message received within 5 secs inverter overcurrent (HW detected) open circuit (HW detected) Inverter short circuit (HW detected) Filament current too high Filament too high for Boost Filament too hot Current over estimated (short circuit) Current under estimated (open circuit) MAINS_DROP detected PRD error (Z3Z4=bitmap) Stay too long in Boost Filament selection error current feedback not nul when inverter off Filament database tube 1 error Filament database tube 2 error Filament database tube 3 error Filament database tube 4 error Unknown heater LF error Unknown heater SF error Tube Spits Error Error Clas s 2 2 2 2 2 2 code 4 Description 0301H Tube spit (kV+ and kV– dropped) 0302H Tube spit (kV+ has dropped) 0303H Tube spit (kV– has dropped) 0304H Tube spit (kV regulation error) 0305H FPGA problem (restarting safety signal) 0324H Spits detected ((1:anode 2:cathode 4:both 8:kVregul) 3–3 X–RAY GENERATOR CT HISPEED SERIES ADVANCED DIAGNOSTICS PROPRIETARY TO GENERAL ELECTRIC COMPANY REV 13 2202119 Description simplified error code 60 70 Exposure errors Power Supply errors Error Error Description Clas s 3 code 0306H No kV Feedback on anode 3 3 3 3 3 3 3 3 3 3 3 3 3 3 3 2 3 3 3 3 3 3 3 3 3 3 0307H 0308H 0309H 0310H 0311H 0312H 0313H 0314H 0316H 0317H 0318H 0319H 0320H 0401H 0402H 0403H 0504H 0801H 0802H 0803H 1411H 1407H 1408H 1409H 0323H 1410H No kV Feedback on cathode No kV Feedback on anode and cathode kV detected during kV diag kV max detected ILP current not OK ILR current not OK ILR max current detected ILR current timeout Spit Max error Spit Ratio error kV did not reach 75% after 20ms kV unbalanced detected FPGA problem (safety signal) No mA feedback mA scale error mA accuracy exceeded 5% Inverter Gate Power Supply failed Exposure backup mAs exceeded Exposure backup time exceeded Exp cmd while gene not ready time counter error mAs counter error AEC counter error mAs meter saturated ILP and ILR current not OK FPGA locked 4 4 4 4 4 4 4 4 4 4 4 4 0501H DC bus out of range 0503H Inverter Gate Power Supply error 0505H Mains power supply has dropped during exposure 0506H DC bus 1 phase precharge error 0507H DC bus 1 phase discharge error 0577H Detected –15V too weak 0573H Detected –15V too strong 0567H Detected +15V too low 0563H Detected +15V too high 0557H Detected +160V too low 0553H Detected +160V too high 0549H Unknown LVPS error 3–4 X–RAY GENERATOR CT HISPEED SERIES ADVANCED DIAGNOSTICS PROPRIETARY TO GENERAL ELECTRIC COMPANY REV 13 2202119 Description simplified error code 80 Error Error Clas s Hardware error 4 4 4 4 4 4 4 4 4 4 4 4 code Description 0180H 0181H 0280H 0281H 0322H 0601H 0602H 0902H 1402H 1403H 1404H 1405H Rotation board communication problem Rotation board has reset Heater board communication problem Heater board has reset kV ref ADC / DAC failed RTL error External CAN bus off tube Fan supply error Internal CAN bus off Connectic Fault FPGA configuration problem Tank sensor problem 90 Application errors 4 4 4 4 0701H 0702H 0704H 0705H Saved RAM checksum pb Software problem Rotation/Heater hold too long System or database configuration error 100 Com errors 4 4 4 4 4 0603H 0604H 0605H 0606H 1301H Debug screen com error Database download error TAV com error MPC/Madrid com error AEC board com error 3–5 X–RAY GENERATOR CT HISPEED SERIES ADVANCED DIAGNOSTICS PROPRIETARY TO GENERAL ELECTRIC COMPANY REV 13 2202119 Description simplified error code 110 10 Thermal error Rotation Warning Error Error Description Clas s 5 5 3 5 5 code 0804H 0903H 1454H 0111H 0805H Tank Thermal Error Tube exceeded 70degC Jedi inverter temperature too high 0 HEMIT Thermal error Inverter Thermal Error 1 0151H CAN Domain command number error 1 1 1 1 1 1 1 1 1 1 1 1 1 1 0152H 0153H 0154H 0155H 0156H 0157H 0158H 0159H 0160H 0161H 0162H 0163H 0164H 0199H CAN Domain request with no transfer init CAN Domain Toggle bit error CAN Domain : less than 2 data to download CAN Domain Abort received & applied Bad index in config upload Tube switch while Rotation not off Acceleration cmd while no tube selected Acceleration cmd while database not OK Database download while Rotation speeding Acceleration command not OK Rotation acceleration while in error No CAN message received within 4 secs Rotation Inverter overcurrent (< 3 times) Unknown rotation warning 3–6 X–RAY GENERATOR CT HISPEED SERIES ADVANCED DIAGNOSTICS PROPRIETARY TO GENERAL ELECTRIC COMPANY REV 13 simplified error code 20 2202119 Description Heater Warning Error Error Description Clas s 1 code 0251H Received command is not OK 1 1 1 1 1 1 1 1 1 1 1 1 1 0252H 0253H 0254H 0255H 0256H 0257H 0258H 0259H 0260H 0261H 0262H 0263H 0299H Heater command not OK No CAN message received within 4 secs Heater inverter overcurrent (inverter1) (<3 times) Filament open circuit (inverter1) (<3 times) Heater Inverter short circuit (inverter1) (<3times) Tube switch while filaments not OFF CAN Domain command number error CAN Domain request with no transfer init CAN Domain Toggle bit error CAN Domain : less than 2 data to download CAN Domain Abort received & applied Database download while heater not cut Unknown Heater warning 25 Low Voltage Power Supply Warnings 1 1 1 1 1 1 1 1 1 1 1 1 1 0570H 0570H 0560H 0560H 0550H 0550H 0575H 0571H 0565H 0561H 0555H 0551H 0599H No more warn –15V too low No more warn –15V too high No more warn +15V too low No more warn +15V too high No more warn +160V too low No more warn +160V too high Detected –15V too weak Detected –15V too strong Detected +15V too low Detected +15V too high Detected +160V too low Detected +160V too high Unknown LVPS warning 27 Application warnings 1 1 1401H 0703H Saved RAM power supply limit reached Watchdog reset has just occurred 3–7 X–RAY GENERATOR PROPRIETARY TO GENERAL ELECTRIC COMPANY REV 13 3-4 3-4-1 CT HISPEED SERIES ADVANCED DIAGNOSTICS 2202119 ERROR REPORTING NP Generator Error Reporting Np system only gets the simplified error code from the Jedi Generator. The Np system errorlog adds to the simplified error code the following information: D error message (refer to the Np system documentation) D system phase : state of the system when the error occurred. Take care, the system state is different of the Generator phase (refer to the Np system documentation) D system time : date and time when the error occurred. Take care, the system time is different of the Generator time Whenever a Generator error is logged in the system errorlog file and displayed on the operator console, the Jedi errorlog upload functionality is available to get more detailed information about the error. This function must be performed from the operator console. The simplified error code must be used to find the Jedi error code in the Jedi errorlog file. Having these two information, look at the Jedi trouble–shooting table to find the FRU to replace. Error codes can also be read by connecting the service laptop. 3-4-2 Tiger Generator Error Reporting (not for NP++ and Ebisu systems) Tiger console only displays the simplified error code from the Jedi Generator. Whenever a Generator error is displayed on the operator console, the Jedi errorlog upload functionality is available to get more detailed information about the error. This function must be performed from the service laptop. The simplified error code must be used to find the Jedi error code in the Jedi errorlog file. Having these two information, look at the Jedi trouble shooting table to find the FRU to replace. 3–8 X–RAY GENERATOR PROPRIETARY TO GENERAL ELECTRIC COMPANY CT HISPEED SERIES ADVANCED DIAGNOSTICS REV 13 3-5 2202119 DIAGNOSTICS This chapter describes diagnostics tools based on error codes and specific diagnostics. WARNING 3-5-1 Before any manual intervention, ensure the main power is off. Apply lock out–tag out procedure for your own safety when manipulating inside the equipment is required. Detailed Error Description & Troubleshooting Guide The first part details errors, while the warning errors are listed in a second part of this chapter. The table below provides guidelines to troubleshoot Generator problems based on error code. For each code, there is: –Associated message and additional explanation related to the error occurrence. –List potential cause, in the order of expected probability. –Recommended action, with, in some cases, link to some more information as indicated where cases apply, such as to run some specific diagnostics. Codes are sorted by ascending order both for simplified code and error code. Refer to the theory of operation for error code structure. Information about associated data structure is located at the end of each error code subset whenever it applies. Whenever wiring, cabling, LED check is mentioned in the recommended actions, refer to the central listing. 3–9 X–RAY GENERATOR PROPRIETARY TO GENERAL ELECTRIC COMPANY REV 13 3-5-1-1 CT HISPEED SERIES ADVANCED DIAGNOSTICS 2202119 Errors Tube spits detection Errors (Code 30) Class 2 Error code 30–0324 H data=4* Message/explanation Potential cause Tube spit (kV+ and kV– dropped) kV drop/spit detected x–ray tube spit. 30–0324 H data=1* (see Note) Tube spit (kV+ has dropped) kV drop/spit detected on Anode side 1. Anode side Tube spit. 2. Anode HV cable 3. HV tank 30–0324 H data=2* (see Note) Tube spit (kV– has dropped) kV drop/spit detected on cathode side 1. Cathode side Tube spit. 2. Cathode HV cable 3. HV tank 30–0324 H data=8* (see Note) kV regulation error This is a slow speed safety circuit in case of “smooth” spits. (“smooth” means that the recovery of kV is slow) 30–0305 H Re–starting safety. (unknown reason) Error occurring on safety line, while No root error present at the error inputs (Err 0301 to 0304). This is probably due to transient interference (Spikes). 1. smooth HV tube spits 2. kV control board (HV regulation problem) 3. too much line impedance (between the power distribution board and Jedi) 4. half of AC/DC capacitors open 5. Inverter (parallel inductor or filtering capacitors) 6. HV tank 1. External unknown cause. 2. kV control board. 3–10 Recommended action/ Troubleshooting guide –If too frequent, and varies with HV, replace x–ray tube. Run Open load kV test. (See diagnostic section) Usual in Performix tubes. If too frequent: –Check HV cables and contacts –Tube problem. (Anode side) –Check cable by interchanging them. –Run Open load kV test. (See diagnostic section) –Otherwise, HV tank. Usual in Performix tubes. If too frequent: –Check HV cables and contacts –Tube problem. (Cathode side) –Check cable by interchanging them. –Run Open load kV test. (See diagnostic section) –Otherwise, HV tank –Run inverter diagnostics (See diagnostic section) –Run Open load kV test. (See diagnostic section) –Troubleshoot tube and contacts of HV cable. –Check DC bus voltage. –Do a power and Grounding Check. Verify cabling and contacts. –If permanent or too systematic, replace kV control board. Report to engineering. X–RAY GENERATOR CT HISPEED SERIES ADVANCED DIAGNOSTICS PROPRIETARY TO GENERAL ELECTRIC COMPANY REV 13 2202119 * Note to the error 30 0324H: The generator sends only one message of error for all the spits (0324H) at the end of the exposure. During the same exposure we may have different kind of spits. In the data of this error we can distinguish between the different spits: 1: Spit in anode side 2: Spit in cathode side 4: Spit in both sides 8: kV regulation error. For a exposure with anode and both sides spit, the data will be “5”. These data can be displayed in the OC in decimal or in hexadecimal base. Spits code detail See data (Z6[#H]) of XG error code 324H. Transfer #H to Binary data. Contents are as follows. code bit3 bit2 bit1 bit0 KV Regulation Error Insert Spits Cathode side arching Anode side arching 1 0 0 0 1 2 0 0 1 0 3 0 0 1 1 4 0 1 0 0 5 0 1 0 1 6 0 1 1 0 7 0 1 1 1 8 1 0 0 0 9 1 0 0 1 A 1 0 1 0 B 1 0 1 1 C 1 1 0 0 D 1 1 0 1 E 1 1 1 0 F 1 1 1 1 ex.) (0324H)Spits (1:anode 2: cathode 4: both 8: kVregul) (Z6[CH]:Z7[0H]) Z6[CH] –> C Hex –> 1100 Bin –> KV regulation + Insert 3–11 X–RAY GENERATOR PROPRIETARY TO GENERAL ELECTRIC COMPANY CT HISPEED SERIES ADVANCED DIAGNOSTICS REV 13 2202119 Anode Rotation errors (Code 40) Class 4 Error Message/explanation code 40–010 No CAN message re1H ceived within 5 sec’s The rotation board has not received any signal from the kV control main software for the last 5 sec., interpreted as a loss of communication 40–010 Data base not correct. 2H The firmware of the rotation board has detected that the data base received from the kV control board has wrong data. 40–010 Rotation current overload 3H Rotation board has detected Main or auxiliary Rotation current too high compared to the max. Tube motor current. 40–010 Rotation current openload 4H Rotation board detected that no current is flowing to the motor. Potential cause 1. kV Control main software lost 2. kV control or Rotation board driver failure 3. Bad contact on one of the pin on the CAN bus line connector Recommended action/ Troubleshooting guide –Unlikely to happen. This is a debug error. –Retry –Re initialise and retry 1. Wrong kV control data base. It can only happen at power up. –Reload NVRam database. –ultimate is to replace Rotation board. 1. Rotation board Rotation board capacitors 2. Wrong data base (improbable) Check wiring from rotation board to HEMIT and HV from HEMIT to tube. If no cabling problem, run Rotation diagnostic.(See diagnostic section). 1. Tube stator winding is open circuit: x–ray tube 2. Incorrect wiring (Open) 3. No DC bus on Rotation board 4. Rotation board 5. Rotation board phase capacitors (improbable) Check wiring from rotation board to HEMIT and HV from HEMIT to tube. If no cabling problem, run Rotation diagnostic.(See diagnostic section) 3–12 X–RAY GENERATOR PROPRIETARY TO GENERAL ELECTRIC COMPANY REV 13 Class 4 Error Message/explanation code 40–010 Rotation Phases unbal5H anced The amplitude difference of the current between main and auxiliary is too large. 40–010 Rotation phase error 6H The Rotation board has detected that the current in the anode stator does not show the correct phase shift between main and auxiliary. CT HISPEED SERIES ADVANCED DIAGNOSTICS 2202119 Potential cause 1. One Rotation wire missing 2. Rotation board Rotation board phase capacitors inverted or wrong value 3. Wrong tube configuration data base 4. Tube problem (stator) 5. HV cable between HEMIT and tube 1. Rotation board 2. Tube problem (stator) 3. HV cable between HEMIT and tube 3–13 Recommended action/ Troubleshooting guide Check wiring from rotation board to HEMIT and HV from HEMIT to tube. If no cabling problem, run Rotation diagnostic.(See diagnostic section) – Check wiring from rotation board to HEMIT and HV from HEMIT to tube. Verify none is in short circuit. If no wiring problem, run Rotation diagnostic. (See diagnostic section) X–RAY GENERATOR PROPRIETARY TO GENERAL ELECTRIC COMPANY CT HISPEED SERIES ADVANCED DIAGNOSTICS REV 13 Error Message/explanation code 40–010 Rotation Inverter perma7H nent overcurrent An overcurrent has been detected and 3 restart have been tried unsuccessfully within a single rotation state 40–010 MAINS_DROP has failed 9H The firmware of the rotation board has detected the mains_drop signal activation and transmitted error to kV control 40–011 PRD error(Z3Z4=bitmap) 0H Firmware checksum, RAM test and EPLD access are performed at power up or reset. 40–011 F0 main frequency prob1H lem. EPLD has not applied the inverter start command 40– Rotor HW/FW Config er0112H ror 40–014 Unknown rotation error. 9H The main software received an error from rotation board with no error code associated 2202119 Potential cause 1. Rotation board 2. Tube stator winding in short circuit –> HEMIT 3. Wiring incorrect (shorted) Recommended action/ Troubleshooting guide –Check wiring from rotation board to tube. –Troubleshoot tube windings –Replace Rotation board 1. Interference (spikes) 2. Mains drop 3. Cable or connector contact in DC bus between power unit and auxiliary unit 4. Rotation board Rotation board –Do a power and grounding check. –If systematic, replace Rotation board Rotation board –Retry –Replace Rotation board. Rotation board Download official data base (NPv3) If the problem persists, change rotor No action. Software problem Replace Rotation board. Associated data structure: PRD error: component failure : 0001H=RAM 0002H=RAM stack 0200H=EPLD 8000H=program checksum 3–14 X–RAY GENERATOR PROPRIETARY TO GENERAL ELECTRIC COMPANY REV 13 CT HISPEED SERIES ADVANCED DIAGNOSTICS 2202119 Rotation database error: 2 bytes data, each value points to a specific parameter found as being erroneous Other errors: rotation state : 0=inverter OFF 1=acceleration 0 to low speed 2=acceleration 0 to high speed 3=acceleration low speed to high 4=low speed run 5=high speed run 6=high speed to low speed brake 7=brake reverse 8=brake DC 3–15 X–RAY GENERATOR PROPRIETARY TO GENERAL ELECTRIC COMPANY CT HISPEED SERIES ADVANCED DIAGNOSTICS REV 13 2202119 Filament Heater errors (Code 50) Class 4 Error Message/explanation code 50–020 No CAN message re1H ceived within 5 sec’s The Heater board has not received any command from the kV control main software for the last 5 sec., interpreted as a loss of communication 50–020 Heater inverter permanent 3H overcurrent.(SW limit) Issued by the heater board when an overcurrent has been detected and 3 restarts have been tried without success within 100 ms 50–020 Filament permanent open 4H circuit. Issued by the heater board when an open has been detected and 3 restarts have been tried without success within 100 ms 50–020 Heater Inverter permanent 5H short circuit (HW limit) Issued by the heater board when a short circuit has been detected and 3 restarts have been tried without success within 100 ms 50– Filament current too high 0206H on inverter 1 for “Pre– Heat” This is the result of an integrated value of the RMS current measurement on Heater board comparison with max. Tube value in data base. Potential cause 1. kV Control main software lost 2. kV control or Heater board driver failure 3. Bad contact on one of the pin on the CAN bus line connector Recommended action/ Troubleshooting guide –Unlikely to happen. This is a debug error. –Retry –Re initialise and retry. 1. Heater board –Restart. If persistent, replace Heater board 1. X–ray tube filament open 2. Heater to HV tank cable 3. Cathode HV cable or pin contacts 4. Open circuit in filament transformer inside HV Tank. –Switch on the other filament: if no error is reported, heater board is working properly. Check heater board to HV Tank to tube connections. If OK, test with Ohm– meter HV Tank heater transformers (primary and secondary) and filament impedance. Order accordingly If the same error is reported, check the connections as above. If all are right, replace heater board –Restart. If persistent, replace Heater board 1. Heater board 1. Tube data base or calibration 2. Heater board 3–16 –It’s unlikely, but reload NVRam database. –Replace heater board. X–RAY GENERATOR PROPRIETARY TO GENERAL ELECTRIC COMPANY CT HISPEED SERIES ADVANCED DIAGNOSTICS REV 13 Error code 50– 0207H 2202119 Message/explanation Filament current too high on inverter 1for “Boost” Same as above 50– Filament current too 0208H high on inverter 1for “Heat” Same as above 50–021 Current over estimated 0H fork range RMS filament current measurement (every 0.5 m sec.) on heater board is too low 50–021 Current under estimated 1H fork/ range RMS filament current measurement (every 0.5 msec.) on heater board is too high 50– MAINS_DROP detected. 0212H The firmware of the Heater board has detected the mains_drop signal activation and has transmitted error to kV control Potential cause 1. Tube data base or calibration 2. Heater board 1. Tube data base or calibration 2. Heater board 1. short circuit 2. Heater board Recommended action/ Troubleshooting guide Same as above Same as above –Switch on the other filament: if no error is reported, heater board is working properly. Check heater board to HV Tank to tube connections. If OK, test with Ohm–meter HV Tank heater transformers (primary and secondary) and filament impedance. Order accordingly If the same error is reported, check the connections as above. If all are right, change heater board Replace heater board 1. Open circuit 2. Heater board 1. Interference (spikes) 2. Mains drop 3. Cable or connector contact in DC bus between power unit and auxiliary unit 4. Heater board Heater board 50–021 PRD error 3H Firmware checksum, RAM test and EPLD access are performed at power up or reset. 50– Boost too long on inverMay be a loss of commu0214H ter1. nication during boost. Boost command stayed longer than 400ms 50– Filament selection error. Heater board 0215H The relay on the Heater board selecting the filament is in the wrong position with respect to the selection 3–17 –Do a power and grounding check. –If systematic, replace heater board Replace heater board. Retry. It will probably be followed by another communication code. Replace heater board X–RAY GENERATOR CT HISPEED SERIES ADVANCED DIAGNOSTICS PROPRIETARY TO GENERAL ELECTRIC COMPANY REV 13 Error code 50– 0216H 50– 0221H 0222H 0223H 0224H 50– 0248H 50– 0249H 2202119 Message/explanation Potential cause Current feedback not nul when inverter OFF Inverter current has been measured while the inverter was not commanded Filament Database not correct The firmware of the heater board has detected that the Received Data base from kV control contains erroneous data for Tube 1, 2, 3, or 4. Unknown heater LF error The main software received an error from heater board with no error code associated Unknown heater SF error The main software received an error from heater board with no error code associated Heater board Recommended action/ Troubleshooting guide Replace heater board 1. Wrong kV control data base. It can only happen at power up. –Reload NVRam data base. –ultimate is to replace Heater board. 1. software problem No action 1. software problem No action Associated data structure: PRD error : component failure : 0001H=RAM 0002H=RAM stack 0200H=EPLD 8000H=program checksum Filament database error : 2 bytes bitmap ( LSByte=small focus, MSByte=large focus) Each bit points to an erroneous parameter other errors : 1 byte bitmap with the following structure : bit6 bit5 bit4 bit7 (MSB) focus selected tube selected 0=small focus selected 1=tube 1 selected 1=large focus selected 2=tube 2 3=tube 3 4=tube 4 bit3 bit2 small focus state 0=inverter OFF 1=preheat 2=boost 3=heat 3–18 bit1 bit0 (LSB) large focus state 0=inverter OFF 1=preheat 2=boost 3=heat X–RAY GENERATOR PROPRIETARY TO GENERAL ELECTRIC COMPANY CT HISPEED SERIES ADVANCED DIAGNOSTICS REV 13 2202119 Exposure errors (Code 60) Class 3 Error Message/explanation code 60–030 No kV feedback on anode 6H side kv measured <12kV 0,5ms after start of exposure on anode side only 60–030 No kV feedback on cath7H ode side kv measured <12kV 0,5ms after start of exposure on cathode side only 60–030 No kV Feedback (on 8H anode and cathode) kv measured <12kV 0,5ms after start of exposure on both anode and cathode. 60–030 kV detected during kV 9H diagnostics. KV measured during inverter diagnostics while no kV must be generated. 60–031 kV MAX detected 0H kV reached 160 kv during exposure 60–031 ILP current not OK. 1H The current in the parallel resonant circuit of the inverter did not rise at the beginning of the exposure. Potential cause 1. HV cable short circuit 2. HV tank 3. kV control board (less probable) 1. HV cable short circuit 2. HV tank 3. kV control board (less probable) 1. HV tank 2. kV control board Recommended action/ Troubleshooting guide –Troubleshoot HV cables : run no load kV diagnostic along with inverting HV cables If HV cables are right, replace HV Tank –Troubleshoot HV cables : run no load kV diagnostic along with inverting HV cables If HV cables are right, replace HV Tank –Verify flat cable connections and sitting between kV control and HV tank. – Replace HV Tank Improper setup before the diagnostic is run. See HV power diagnostic section. kV control Replace kV control board 1. Inverter LC resonant circuit (Inverter coil assy, capa inverter assy, current transformers.) 2. Inverter 3. kV control See above run HV power diagnostics 60–031 ILR current not OK 2H The current in the serial resonant circuit of the inverter did not rise at the beginning of the exposure. 60–031 Inverter max. ILR cur1 Tube (it can be cas3H rent detected. ing spits, errors This is a hardware 0302H and 0303H) detection of maximum 2 HV tank current in serial reso3 kV control nant circuit. 3–19 run HV power diagnostics run HV power diagnostics X–RAY GENERATOR PROPRIETARY TO GENERAL ELECTRIC COMPANY CT HISPEED SERIES ADVANCED DIAGNOSTICS REV 13 (*) for N P (*) for N P Class 3 Error Message/explanation code 60–031 ILR Current time out. 4H The current resonant frequency is lower than expected 60–031 Spit Max error. 6H kV control has detected the number of tube spits during exposure has reached the limit (see theory of operation, software section) 60–031 Spit Ratio error. 7H kV control has detected the rate of tube spits during exposure has reached the limit (see theory of operation, software section) 60–031 kV did not reach 75% af8H ter 20ms. Indicates that there were no HV ON signal generated for exposure time count–up 60–031 kV unbalanced detected. 9H Detects that there is more than 12kV difference between kV+ and kV – 60–032 FPGA problem; Safety hit 0H with unknown reason No error at the inputs while checking for error source. 60–032 ILP and ILR current not 3H OK No inverter current measures at the beginning of the exposure 60–040 No mA feedback 1H mA measurement function: kV control has detected no mA feedback 20 ms after the beginning of the exposure. 2202119 Potential cause 1. kV control 2. Inverter 3. Current measurement circuit. reasonably x–ray tube Recommended action/ Troubleshooting guide run HV power diagnostics –Try again at various kV/mA to confine problem. –Troubleshoot HV section. (x–ray tube, cable, HV tank) –Diagnose based on tube history. reasonably x–ray tube –Try again at various kV/mA to confine problem. –Troubleshoot HV section. (x–ray tube, cable, HV tank) –Diagnose based on tube history. 1. kV control Replace kV control. HV tank Replace HV tank 1. This may be due to transient interference (Spikes). 2. SW bug Do a power and Grounding Check. Verify cabling and contacts. If permanent or too systematic, replace kV control board. Report to engineering run HV power diagnostics 1. Inverter LC resonant circuit. (Inverter coil assy, capa inverter assy, current transformers.) 2. Inverter kV control board 1. HV tank 2. kV control board 3. x–ray tube (filament open) 4. Cathode HV cable short–circuited 5. Misconnection between HV+ and HV– after a tank replacement 3–20 – Disconnect HV Tank to kV control flat cable and verify with an Ohm– meter the accuracy of the 5 Ohms resistor on the HV Tank mA measure. If it is far out of range, (4.9 to 5.1 Ohm, including DVM accuracy) replace HV Tank. – Verify filament impedance – Replace kV control board – After a tank replacement, verify the HV cable connection. X–RAY GENERATOR PROPRIETARY TO GENERAL ELECTRIC COMPANY CT HISPEED SERIES ADVANCED DIAGNOSTICS REV 13 Error Message/explanation code 60–040 mA scale error 2H mA has been measured to be either too low or too high with respect to mA demand 20 ms after the beginning of the exposure 60–040 mA accuracy exceeded 3H 5% (Class Measured mA every 50 2 error) msec exceeded 5% of mA demand. This error is logged, but does not stop the exposure. 60–050 Inverter Gate Power Sup4H ply error gate supply voltage has dropped below the level required to drive the IGBTs properly N 60–080 Exposure backup mAs exot 1H ceeded on The exposure command C last so long that the maxiT mum mAs allowed has been reached 60–080 Exposure backup time ex2H ceeded. The exposure command last longer than the duration that was loaded by the system (Backup time + 5%.) 60–080 Exp cmd while gene not 3H ready. Generator received an exposure command while not in ready state 60–140 Time counter error. 6H Error found in verifying the counter normal operation. 2202119 Potential cause 1. kV control board 2. default filament currents not correctly adjusted 3. HV Tank (improbable) 1. tube spit Recommended action/ Troubleshooting guide – If the tube has just been replaced or installed, run many exposures until the filament correction adjusts the default filament drive values. – If the error occurs after a while on a system : Disconnect HV Tank to kV control flat cable and verify with an Ohm– meter the accuracy of the 5 Ohms resistor on the HV Tank mA measure. If it is out of range, replace HV Tank else replace kV control board no action 1. Inverter (gate command board) 2. kV control board 3. Generator input voltage too low or line impedance too high 1. exposure command line stuck to the active state run HV power diagnostics 1. System 2. System–Generator cable 3. I/F board : exposure line stuck to the active state –Retry, changing parameters and duration – disconnect system–Generator cable in different places and check exposure command line voltage 1. Software bug/problem 2. Cable / communication problem 3. External cause (Spikes) kV control board If problem is persistent, check heater, anode rotation and system to Generator preparation command to find the root cause for the Generator not to be ready Replace kV control Board 3–21 X–RAY GENERATOR PROPRIETARY TO GENERAL ELECTRIC COMPANY CT HISPEED SERIES ADVANCED DIAGNOSTICS REV 13 N ot C T N ot C T N ot C T 2202119 Error Message/explanation code 60–140 mAs counter error. 7H Error found in verifying the counter normal operation. Potential cause 60–140 AEC counter error. 8H If there is no AEC feedback in AEC station exposure. 60–140 mAs meter saturated. 9H A check is done on mAs counter operation at the beginning of exposure and found the mAs meter with unrealistic value. 60 Time counter error 1411H 60–141 FPGA locked. 0H FPGA detected an error and did not allow start exposure after exposure command signal was received. 60 ILP and ILR current not 0323H OK 1. ION chamber 2. AEC cable, connection 3. AEC board Run AEC diagnostics (See diagnostic section) 1. kV control Replace kV control Kv control Replace Kv control 1. software bug 2. kV control If persistent replace kV control 1. Inverter LC resonant circuit (Inverter coil assy, capa inverter assy, current transformers.) 2. Inverter 3. kV control run HV power diagnostics kV control board 3–22 Recommended action/ Troubleshooting guide Replace kV control Board X–RAY GENERATOR CT HISPEED SERIES ADVANCED DIAGNOSTICS PROPRIETARY TO GENERAL ELECTRIC COMPANY REV 13 2202119 Power supply (Code 70) Class 4 Error Message/explanation code 70–050 DC bus out if range (<400 1H or >850) Potential cause 1. mains problem (Too low or too high) 2. One phase missing at Generator input 70–050 Inverter Gate Power Sup- 1. Mains 3H ply error (checked at prep) 2. Cable pb 3. Gate command board (Inverter) 4. kV control 70–050 Mains power supply has unknown 5H dropped During exposure N ot N P 70–050 DC bus 1 phase pre– 6H charge error. Found DC bus did not reach 400V after 10 sec. Charge relay is not activated and pre–charge relay drops. 1. 2. 3. 4. 5. Pre–charge resistor Relay ACDC module LVPS kV control board N ot N P 70–050 DC bus 1 phase discharge ACDC 7H error. Found that DC bus voltage is > 30 V before pre– charge. 3–23 Recommended action/ Troubleshooting guide –Check mains line 3 phases incoming voltage. –Verify line impedance if mains is low. run HV power diagnostics None WARNING!: Potential residual voltage. Make sure all the NEON are off. Verify with a DVM, range 400VDC that there is no voltage on the capacity bench before any intervention –Verify LED on LVPS –Listen to relay clicking at power on. –Check resistor Replace ACDC module. X–RAY GENERATOR PROPRIETARY TO GENERAL ELECTRIC COMPANY REV 13 Class 4 Error Message/explanation code 70–057 Detected –15V too low 7H –15V is higher than –13V (measured on heater board) CT HISPEED SERIES ADVANCED DIAGNOSTICS 2202119 Potential cause 1. 2. 3. 4. LVPS (open circuit) Heater board rotation (short circuit) kV control (short circuit) (improbable) 70–057 Detected –15V too high 3H –15V is lower than –17.3V (measured on heater board) 1. LVPS open circuit 2. Heater board 70–056 Detected +15V too low 7H +15V is lower than 13V (measured on heater board) 1. LVPS open circuit 2. Heater board 3. rotation (short circuit) kV control (short circuit) (improbable) 3–24 Recommended action/ Troubleshooting guide Verify that the DC bus on LVPS board is in an acceptable range (CF1/CF2) If no, verify AC/DC fuse and AC input voltage. Check –15V on heater board (J3, pin3). If OK, replace heater board. If voltage=0, check the continuity on heater board between (J3, pin3) and (J1,pin3).If no continuity, replace heater board Else, disconnect the control bus cable from the LVPS board and check the pin3 of the connector: if voltage is wrong replace LVPS board. Else, check pin3 of the control bus cable when disconnecting the cable from each board successively to isolate the board inducing a voltage drop Verify that the DC bus on LVPS board is in an acceptable range (CF1/CF2) If no, verify AC/DC fuse and AC input voltage. Check –15V on heater board (J3, pin3). If OK, replace heater board. Else, disconnect the control bus cable from the LVPS board and check the pin3 of the connector: if voltage is wrong replace LVPS board. Verify that the DC bus on LVPS board is in an acceptable range (CF1/CF2) If no, verify AC/DC fuse and AC input voltage. Check 15V on heater board (J3, pin4). If OK, replace heater board. If voltage=0, check the continuity on heater board between (J3, pin4) and (J1,pin2).If no continuity, replace heater board Else, disconnect the control bus cable from the LVPS board and check the pin2 of the connector : if voltage is wrong replace LVPS board. Else, check pin2 of the control bus cable when disconnecting the cable from each board successively to isolate the board inducing a voltage drop X–RAY GENERATOR PROPRIETARY TO GENERAL ELECTRIC COMPANY REV 13 CT HISPEED SERIES ADVANCED DIAGNOSTICS 2202119 Error Message/explanation code 70–056 Detected +15V too high 3H +15V is higher than 17.3V (measured on heater board) Potential cause 70–055 Detected +160V too low 7H +160V is lower than 110V (measured on heater board) 1. LVPS 2. Heater board 70–055 Detected +160V too high 3H +160V is higher than 225V (measured on heater board) 1. LVPS 2. Heater board 70–054 Unknown LVPS error 9H The main software received a LVPS error with no error code associated 1. Software problem 1. LVPS open circuit 2. Heater board 3–25 Recommended action/ Troubleshooting guide Verify that the DC bus on LVPS board is in an acceptable range (CF1/CF2) If no, verify AC/DC fuse and AC input voltage. Check 15V on heater board (J3, pin4). If OK, replace heater board. Else, disconnect the control bus cable from the LVPS board and check the pin2 of the connector : if voltage is wrong replace LVPS board. Verify that the DC bus on LVPS board is in an acceptable range (CF1/CF2) If no, verify AC/DC fuse and AC input voltage. Check 160V on CF2/1 on heater board. If OK, replace heater board Else, disconnect the CF2 cable and measure again on the LVPS side. If voltage is wrong, replace LVPS board. Verify that the DC bus on LVPS board is in an acceptable range (CF1/CF2) If no, verify AC/DC fuse and AC input voltage. Check 160V on CF2/1 on heater board. If OK, replace heater board Else, disconnect the CF2 cable and measure again on the LVPS side. If voltage is wrong, replace LVPS board. No action X–RAY GENERATOR PROPRIETARY TO GENERAL ELECTRIC COMPANY REV 13 CT HISPEED SERIES ADVANCED DIAGNOSTICS 2202119 Hardware errors (Code 80) Class 4 Error Message/explanation code 80–018 Rotation board commu0H nication problem. kV control board communication Watch Dog with Rotation board popped up because it did not get reply from Rotation board. 80–018 Rotation board has reset. 1H kV control has detected the Rotation board has reset. KV control will reload Rotation data base. Potential cause 1. Rotation board 2. Control bus cable 3. kV control 1. Rotation board 2. Interference (Spikes) 3–26 Recommended action/ Troubleshooting guide A/Check that rotation firmware is running (DS5 Led is blinking). If no : 1/verify rotation board 5V : Led DS3 is lit. If no : verify DS1/DS2 Leds : if they are lit, replace rotation board, else go to +/–15V errors troubleshooting 2/ verify that RESET Led is not lit. If it is lit, disconnect successively the control bus cable from heater and kV control to find the board which is holding the reset line and replace it. If after disconnecting all the boards, the Led remains lit, replace rotation board 3/ else replace rotation board B/Verify the flat cable between kV control and auxiliary module is correctly connected to the Rotation board C/else replace kV control –Reinitialize system, retry. –If persistent, replace Rotation board or check power and grounding. X–RAY GENERATOR PROPRIETARY TO GENERAL ELECTRIC COMPANY REV 13 CT HISPEED SERIES ADVANCED DIAGNOSTICS 2202119 Error Message/explanation code 80–028 Heater board communica0H tion problem kV control board communication Watch Dog with Heater board popped up because it did not get reply from Heater board. Potential cause 80–028 Heater board has reset. 1H KV control has detected the heater board has reset. KV control will reload Rotation data base. 80–032 kV ref ADC / DAC failed 2H kV control DAC and ADC capability are permanently tested for coherency. 80–060 RTL error (+ associated 1H data to check which of the 4 RTL lines) Real Time Lines show a wrong state. RTL’s are tested on a regular basis in stand by. 1. Heater board 2. Interference (Spikes) 1. Heater board 2. Control bus cable 3. kV control Recommended action/ Troubleshooting guide A/Check that heater firmware is running (DS1/2 Led are lit successively). If no : 1/verify heater board 5V : J3/pin2. If wrong : verify +15V/–15V (J3, pin3,4) : if they are right, change rotation board, else go to +/–15V errors troubleshooting 2/ verify that RST Led is not lit. If it is lit, disconnect successively the control bus cable from LVPS to rotation and kV control to find the board which is holding the reset line and replace it. If after disconnecting all the boards, the Led remains lit, replace heater board 3/ else replace heater board B/Verify the flat cable between kV control and auxiliary module is correctly connected until the heater board C/else replace kV control board –Reinitialize system, retry. –If persistent, replace board or check power and grounding. KV control board Only if this error is repetitive and comes alone (Not following other errors), replace kV control board. 1. system communication power supply (for isolated communications) 2. system communication cable 3. system interface board 4. system interface to kV control flat cable 5. kV control board –Check communication cable –Check system communication power supply (if any) –Check system interface to kV control flat cable –replace system interface board –replace kV control board 3–27 X–RAY GENERATOR PROPRIETARY TO GENERAL ELECTRIC COMPANY CT HISPEED SERIES ADVANCED DIAGNOSTICS REV 13 2202119 Error Message/explanation code 80–060 External CAN bus off 2H Potential cause 80–090 Tube Fan supply error. 2H Rotation board has detected that a wrong voltage is applied to the tube fan 80–140 Internal CAN bus off 2H Can device on kV control board detected abnormal level on it’s 2 line and sent error to the CPU 1. No 115V tube cooling supply 2. Rotation board –Check presence of the AC voltage (DS6 neon) at the input of the Rotation board. If ok, replace the rotation board 1. kV control 2. Control bus cable 3. Heater or Rotation 80–140 Connection Fault 3H One of the flat cable connector is not connected in Generator. 80–140 FPGA configuration prob4H lem. Detected during power up. The kV control main software cannot load the FPGA. 80–140 Tank temperature sensor 5H problem. Means that t° value of the HV tank is < 10°C Multiple, but likely improbable. kV control board. Check a wrong contact short circuit on CAN lines, pins 5 & 6, of the control bus cable. Short circuit may be either on Boards or connector/ cable. If no fault detected, replace kV control Check connection of the following cables : kV control to system I/F board, kV control to HV tank, HV tank to inverter. Replace kV control board. kV control HV tank Replace kV control Replace HV Tank 1. system communication power supply (for isolated communications) 2. system communication cable 3. system interface board 4. system interface to kV control flat cable 5. kV control board 3–28 Recommended action/ Troubleshooting guide –Check communication cable –Check system communication power supply (if any) –Check system interface to kV control flat cable –replace system interface board –replace kV control board X–RAY GENERATOR CT HISPEED SERIES ADVANCED DIAGNOSTICS PROPRIETARY TO GENERAL ELECTRIC COMPANY REV 13 2202119 Application errors (Code 90) Class 4 Error Message/explanation code 90–070 NV RAM checksum pb. 1H Generator kV control board has detected corruption in the NV Ram verification (After power up) 0702H Software problem. 0704H 0705H Rotation/Heater hold too long. Will pop up if preparation command from the system is maintained longer than 3 minutes. System or database configuration error The identifier of the system and the database are not compatible Potential cause 1. Database problem 2. External cause (Spikes) 3. kV control Recommended action/ Troubleshooting guide If persistent : –Reload the Data base. If no improvement : –Replace kV control board and reload the data base. 1. Software or Data Base problem. 2. kV control board failure. –Reload the Data base –Reload the software and database If no improvement : –Replace kV control board Software problem. No action 1. Database problem Download the Data base – Check system software release (OC) 3–29 X–RAY GENERATOR CT HISPEED SERIES ADVANCED DIAGNOSTICS PROPRIETARY TO GENERAL ELECTRIC COMPANY REV 13 2202119 Communication errors(code 100) Class 4 Error Message/explanation code 100–06 Debug screen com. error 03H 100–06 Database download error 04H Generator has detected a problem during data base download 100–06 TAV communication error. 05H Generator has detected a communication problem between the I/F and the service laptop (When Generator is controlled by the laptop) no 100–06 MPC/Madrid communicat 06H tion error. N No reply from the console. P (This error message can be seen using the service laptop) no 100–13 AEC board communicat 01H tion error. N P Potential cause Recommended action/ Troubleshooting guide Engineering use 1. Database file incorrect 2. Transmission problem Retry Check data base file Potential laptop incompatibility 1. Software / laptop problem 2. Cable problem Retry 1. Cable, connection problem between Generator and the console. 2. Interface board 3. Console problem –verify the console is powered . –Verify EMIT LED on the interface board. –Verify cabling, connection. –Verify communication with the service computer operates. 1. Verify cables connection 2. AEC board 3. Interface board – 3–30 X–RAY GENERATOR PROPRIETARY TO GENERAL ELECTRIC COMPANY REV 13 CT HISPEED SERIES ADVANCED DIAGNOSTICS 2202119 Thermal errors(code 110) Class 5 Error Message/explanation code 110–08 Tank Thermal Error 04H HV tank temperature measurement has reached 60 degree C Potential cause 1. HV tank too hot; normal error 2. HV tank 3. kV control 110–09 70 degree C thermal safe03H ty error 70° loop detected open 1. X–ray tube too hot; normal error 2. Cooling problem 3. Wiring problem 4. Sensor problem (Tube) 5. rotation board 110–14 Jedi inverter tempera54H ture too high 1. Parameters kV, mA and time exceeded allowed use 2. software bug 1. HEMIT tank 2. DC Disch board (HEMIT assy) 3. Rotation board 110– 0111H HEMIT Thermal error 110– 0805H Inverter thermal error Software bug 3–31 Recommended action/ Troubleshooting guide –Wait for error clearance –If persistent while HV Tank is cool : 1/check LED DS1 on kV control (top and right of board). If it is off, change kV control 2/check flat cable connection between HV Tank and kV control board 3/replace HV tank 4/replace kV control –Wait for error clearance –If persistent : 1/Check tube cooling (Fan), troubleshoot 115 volts from PDU to Fans, through Rotation board; check tube thermal sensor 2/ short circuit the sensor feedback on rotation board connector and verify that error disappears. If no, replace rotation board – Wait cooling time – change kv–ctrl board (if trouble always present, report to service) –Wait for error clearance –If persistent: 1/ Check 2A fuse on DC Disch 2/ Short circuit the sensor feedback of the HEMIT. If problem disappears, replace the HEMIT. 2/ Replace DC–Disch 3/ short circuit the sensor feedback on rotation board connector and verify that error disappears. If no, replace rotation board Download software and database again If the problem persists, change kV control X–RAY GENERATOR PROPRIETARY TO GENERAL ELECTRIC COMPANY CT HISPEED SERIES ADVANCED DIAGNOSTICS REV 13 3-6 2202119 WARNING ERRORS Warning errors are the result of automated and regular background monitoring for either software events or voltages threshold overtaking. Those errors are merely for engineering usage and do not indicate any hardware error failure. However, as they are logged into the Generator Err_log file, just as the previous list of error, they are listed here to help error sorting out. Should too many of them are seen when viewing error log, it is advised to report them via CQA, since the equipment is still operating. 10 20 Rotation Warn- 0151H ing 0152H 0153H 0154H 0155H 0156H 0157H 0158H 0159H 0160H 0161H 0162H 0163H 0164H 0199H Heater Warning CAN Domain command number error CAN Domain request with no transfer init CAN Domain Toggle bit error CAN Domain : less than 2 data to download CAN Domain Abort received & applied Bad index in config upload Tube switch while Rotation not off Acceleration cmd while no tube selected Acceleration cmd while database not OK Database download while Rotation speeding Acceleration command not OK Rotation acceleration while in error No CAN message received within 4 secs Rotation Inverter overcurrent (< 3 times) Unknown rotation warning 0251H Received command is not OK 0252H 0253H 0254H 0255H 0256H 0257H 0258H 0259H 0260H 0261H 0262H 0263H Heater command not OK No CAN message received within 4 secs Heater inverter overcurrent (inverter1) (<3 times) Filament open circuit (inverter1) (<3 times) Heater Inverter short circuit (inverter1) (<3times) Tube switch while filaments not OFF CAN Domain command number error CAN Domain request with no transfer init CAN Domain Toggle bit error CAN Domain : less than 2 data to download CAN Domain Abort received & applied Database download while heater not cut 3–32 X–RAY GENERATOR PROPRIETARY TO GENERAL ELECTRIC COMPANY CT HISPEED SERIES ADVANCED DIAGNOSTICS REV 13 2202119 25 Low Voltage Power Supply Warnings 0570H 0570H 0560H 0560H 0550H 0550H 0575H 0571H 0565H 0561H 0555H 0551H 0599H 27 Application warnings 1401H No more warn –15V too low No more warn –15V too high No more warn +15V too low No more warn +15V too high No more warn +160V too low No more warn +160V too high Detected –15V too weak Detected –15V too strong Detected +15V too low Detected +15V too high Detected +160V too low Detected +160V too high Unknown LVPS warning Saved RAM power supply limit reached This message is the result of a computation that is made by the software based on the Date for a period of approximately 7 years 0703H Watchdog reset has just occurred – 1 if it often occurs, change kv–ctrl (if real reset of the board) – 2 if it always occurs, report to service 3–33 X–RAY GENERATOR PROPRIETARY TO GENERAL ELECTRIC COMPANY REV 13 3-7 CT HISPEED SERIES ADVANCED DIAGNOSTICS 2202119 OTHER FAILURES Error Message / Potential cause code explanation System GENERATOR 1. No power on the Generdoes not reply ator. to the system 2. EMC filter 3. AC/DC– Diode bridge 4. Cable between AC/DC and LVPS 5. LVPS down 6. CAN cable problem 7. kV control 8. CT interface 9. Rotation board 10. Heater board 11. Inverter in short circuit 12. Generator to system cable. 3 phases CB1 breaker trips in PDU 1. Short circuit on the Generator : n IGBT in short circuit n ACDC or bridge rectifier in short circuit n EMC filter in short circuit Software or Data base corrupt 1. After software download: –Incorrect or uncompleted download –Checksum problem 3–34 Recommended action Troubleshooting guide Perform the troubleshooting in the following way : 1/kV control Leds S0–S7 are lit successively : refer to communication errors troubleshooting 2/Leds S0–S7 show a specific pattern : refer to PRD errors section 3/Led RESET is lit : board is maintained in reset either by the system or by a system I/F failure or kV control failure 4/Led HALT is lit : replace kV control 5/No Led is lit : verify that +5V on kV control board (J6, pin2).is present. If yes, replace kV control. If no : 6/ verify if +15V/–15V is present (Leds DS1/DS2). If yes, replace kV control. If no : 7/ Verify if +15V/–15V is present on rotation board (DS1/DS2) and the 160V is present on the heater board (DS3). If yes : check the control bus cable to the kV control board. If no error, change the kV control board. If no : 8/ Verify if the LVPS DC input is right. If no, check AC/DC fuse and input line If yes : 9/disconnect all output cables from the LVPS board. Verify the +15V/–15V/160V output. If right : reconnect each board successively to find the one stucking the 15V to ground. If wrong, replace LVPS board ( 1/ Disconnect DC bus cables between AC/DC and inverter (on AC/DC side) 2/ Check if these cables are in short circuit. If yes, replace inverter if no, 3/ Disconnect AC line cables between EMC and AC/DC (on EMC side) 4/ Check if these cables are in short circuit. If yes, replace AC/DC FRU if no : 5/ Disconnect AC line input from EMC board. Check EMC for short circuit between phases. If short circuit, replace EMC board. Retry download X–RAY GENERATOR PROPRIETARY TO GENERAL ELECTRIC COMPANY CT HISPEED SERIES ADVANCED DIAGNOSTICS REV 13 3-8 2202119 HEATING WITHOUT HV NOR ROTATION DIAGNOSTIC Purpose : The purpose of this test is to drive the heater inverter(s) on both filaments and all the tubes connected to the Generator in order to identify a faulty heater FRU or a wrong connection between heater board, HV Tank and tube(s). Pre–requisites : D kV control board alive and running : S0–S7 Leds are lit successively or a combination of them blink D heater board alive and running : DS1 and DS2 Leds are lit successively D heater DC supply present : DS3 Led is lit Test type : No manual interaction Sequence : Once selected the tube the test is running on , start the diagnostic. The following sequence runs on the small focus and then on the large focus : D 5 seconds preheat D 0,4s boost D 5s heat ( focal spot max current – 1Amp ) There is 10s stop time between each focal spot run During the test , the heater safeties are checked the same way than in application mode Error codes reporting : Refer to the troubleshooting table 3–35 X–RAY GENERATOR PROPRIETARY TO GENERAL ELECTRIC COMPANY CT HISPEED SERIES ADVANCED DIAGNOSTICS REV 13 3-9 2202119 ROTATION WITHOUT HV NOR FILAMENT DIAGNOSTIC Purpose : The purpose of this test is to drive the rotation inverter(s) in high speed mode (for application supporting high speed mode ) and low speed mode on all the tubes connected to the Generator in order to identify a faulty rotation FRU or a faulty dephasing capacitors FRU or a wrong connection between rotation board, HEMIT and tube. Pre–requisites: D kV control board alive and running : S0–S7 Leds are lit successively or a combination of them blink D rotation board alive and running : DS5 Led blinking D rotation DC supply present : DS7 neon is lit D cabling between rotation board and tube checked Test type: No manual interaction, no loop on Sequence: Once selected the tube the test is running on, start the diagnostic. The following sequence runs in low speed mode and then in high speed mode (if high speed mode allowed) : D acceleration ( time depends on tube type ) D 2s run D brake ( time depends on tube type ) There is 2s stop time between each speed mode. During the test , the rotation safeties are checked the same way than in application mode 3–36 X–RAY GENERATOR PROPRIETARY TO GENERAL ELECTRIC COMPANY REV 13 CT HISPEED SERIES ADVANCED DIAGNOSTICS 2202119 Error codes reporting : error code associated data 0103H associated data points only to high 0104H speed mode 0105H 0106H 0107H 0109H associated data points to both high 0111H speed and low speed mode 0112H associated data points to both high speed and low speed mode conclusion Power–off. Check cabling. If problem, replace the rotation board. If the problem persists, replace the HEMIT tank. See note * Check cabling. If problem, replace the rotation board Download official data base (NPv3). If the problem persists, change rotor. For the other error codes, refer to the troubleshooting table *Note: Before replacing the rotation board, check the impedance of the primary and secondary of the HEMIT. In order to do a correct measure, check before the impedance of the cables of the multimeter. • The impedance of the primary is measured between two pins of the connector J1 of the Bouchon board in the HEMIT (3 measures). The value is low, between 0.8 ohm and 1.6 ohm. • If the impedance is too low (short –circuit) replace the HEMIT • If the impedance is too high (open circuit) replace the HEMIT • The impedance of the secondary. Measure between two pins of the HV connector marked as “ST”. (large, small and common). For the three measures the value should be between 0.8 ohm and 1.6 ohm. • If the impedance is too low (short –circuit) replace the HEMIT • If the impedance is too high (open circuit) replace the HEMIT 3–37 X–RAY GENERATOR PROPRIETARY TO GENERAL ELECTRIC COMPANY REV 13 CT HISPEED SERIES ADVANCED DIAGNOSTICS 2202119 3-10 HV POWER DIAGNOSTICS 3-10-1 Inverter Gate Command Diagnostic Purpose : The purpose of this test is to verify that the HV power inverter drive is working properly. The IGBTs gate drive supply and the IGBTs gate drive is verified. At the same time verification is made that no inverter currents nor High voltage are measured. This test is performed without DC voltage applied to the inverter so that no Xray is generated. Anode rotation and filament drive are not activated during this test. Pre–requisites : D Generator input line in an acceptable range ( 380V–10% to 480V+10% for 3–phase AC input ) D kV control board alive and running : S0–S7 Leds are lit successively or a combination of them blink D inverter gate_cmd board DC supply present : DS300 neon is lit Test type : Manual operation is required. Sequence : 1/ Disconnect the 2 DC bus cables from the AC/DC board ( see central listing ) 2/ Power on the Generator 3/ Push the TGP board reset switch, or OGP board reset switch. 4/ Verify that the DS1 neon on inverter dual snubbers board is not lit 5/ Start the diagnostic and verify : – error reported on the operator console – inverter gate_cmd board Leds DS101, DS 102, DS201, DS202 are lit : IGBTs gate drive supply is working properly 6/ Press the exposure switch (10s exposure is taken after 10 sec delay) 7/ During the “exposure”, verify : – error reported on the operator console – inverter gate_cmd board Leds DS100 and DS200 are lit : IGBTs gate drive is working properly 8/ Release the exposure switch 9/ Power off the Generator 10/ Reconnect the 2 DC bus cables from the AC/DC board (see central listing ) 3–38 X–RAY GENERATOR PROPRIETARY TO GENERAL ELECTRIC COMPANY CT HISPEED SERIES ADVANCED DIAGNOSTICS REV 13 Error reporting : error DS1 neon lit DS300 neon off 0301/ 0302/ 0303/ 0304/ 0309/ 0310/ 0311/ 0312/ 0313/ 0314/ 0319/ 0323 (H) 0320 0501 0503 0504 one of DS101/DS102/DS201/DS202 Leds off while no error reported DS100 and/or DS200 Leds off 2202119 Conclusion Check that DC bus cables have been removed Check the gate_cmd supply cable between AC/DC and gate_cmd board Check that DC bus cables have been removed. If yes, replace kV control board if problem persists, replace Kv control board kV control or inverter fault, replace inverter first kV control or inverter fault, replace inverter first kV control or inverter fault, replace inverter first Replace inverter Check cabling between kV control, HV Tank and gate_cmd board. If cabling is right, kV control or inverter fault, replace inverter first 3–39 X–RAY GENERATOR PROPRIETARY TO GENERAL ELECTRIC COMPANY REV 13 CT HISPEED SERIES ADVANCED DIAGNOSTICS 2202119 3-10-2 Inverter in Short Circuit Diagnostic Purpose : The purpose of this test is to verify that the HV power inverter is working properly. The inverter is commanded at a fixed frequency and is loaded with a short circuit. Verification is made that the inverter currents are correctly set. . At the same time verification is made that no High voltage is measured. This test is performed without connecting the HV Tank to the inverter so that no Xray is generated. Anode rotation and filament drive are not activated during this test. Pre–requisites : D Generator input line in an acceptable range ( 380V–10% to 480V+10% for 3–phase AC input ) D kV control board alive and running : S0–S7 Leds are lit successively or a combination of them blink D inverter gate_cmd board DC supply present : DS300 neon is lit D inverter dual snubber board DC supply present : DS1 neon is lit D Inverter gate command diagnostic passed without failure Test type : Manual operation is required. 3–40 X–RAY GENERATOR PROPRIETARY TO GENERAL ELECTRIC COMPANY CT HISPEED SERIES ADVANCED DIAGNOSTICS REV 13 2202119 Sequence : 1/ Disconnect the HV Tank primary cables from the inverter ( see HV Tank D/R job card ). Take care not to disconnect at the same time the parallel inductor cable which is tightened with the HV Tank primary cables Put the short circuit cable (included in the first aid kit ) between the the two capacitors as shown (in red, the cable): Parallel inductor 1/ The parallel inductor must be connected 2/ Power on the Generator 3/ Push the TGP board reset switch, or OGP board reset switch. 4/ Verify that the DS1 neon on inverter dual snubbers board is lit 5/ Verify that the DS300 neon on inverter gate_cmd board is lit 6/ Start the diagnostic and verify that no error is reported on the operator console 7/ Press the exposure switch (500ms exposure is taken) 8/ Release the exposure switch 9/ verify error reported on the console 10/ After exiting the test, power off the Generator 11/ Remove the short circuit cable, reconnect the HV Tank primary cables ( see HV Tank D/R job card ). Verify that the parallel inductor cable is connected. 3–41 X–RAY GENERATOR PROPRIETARY TO GENERAL ELECTRIC COMPANY CT HISPEED SERIES ADVANCED DIAGNOSTICS REV 13 2202119 Error reporting : error DS1 neon off DS300 neon off Conclusion Check that DC bus cables between AC/DC and inverter Check the gate_cmd supply cable between AC/DC and gate_cmd board 0301/ 0302/ 0303/ 0304/ 0309/ Check that HV Tank primary cables have been removed. 0310/ 0319 (H) If yes, replace kV control board 0311 No Ilp current detected. See note 2 0312 No Ilr current detected. See note 3 0313 replace kV control board 0314 Ilr current resonant frequency is lower than expected. See note 4 0320 if problem persists, replace kV control board 0323 Both Ilr and Ilp currents not detected. See note 1 0501 kV control or inverter can be faulty 0503 kV control or inverter can be faulty 0504 kV control or inverter can be faulty 0505 Isolation fault between inverter components and ground. Check inverter inductors. If no faulty component, kV control or inverter can be faulty Note 1 : Ilp and Ilr currents not detected 1/ Check the –15V (Led DS1) on kV control board (see central listing). If it is not lit, refer to “other failures” section. Else : 2/ Power off the Generator. Wait until all neons are off 3/ Check that the currents transformers (capacitor set) to gate_cmd board cable is correctly connected. If yes : 4/ Check that the inverter inductors are correctly connected. If yes : 5/ Check that HV Tank is correctly connected to the capacitors set. If yes : 6/ Check that the gate_cmd to HV Tank cable and HV Tank to kV control cables are correctly connected. If yes, replace the inverter 7/ Reconnect all the cables Note 2 : Ilp current not detected 1/ Power off the Generator. Wait until all neons are off 2/ Check that the parallel inductor is correctly connected. If yes : 3/ Check that the parallel inductor impedance is 0 Ohms. If no : replace inverter. If yes : 4/ Check that inverter capacitors (capacitors set) are not broken. If yes, replace the capacitor set. Else : 5/ Disconnect the currents transformers to gate_cmd board cable. Check that the parallel current transformer impedance is 0. If no : replace the capacitor set. Else : 6/ Check that the gate_cmd to HV Tank cable and HV Tank to kV control cables are correctly connected. If yes : 7/ Disconnect the HV Tank to kV control cable. Check that the impedance between pin20 and pin21 of J2 of HV Tank is 3,3Ohms. If no replace the inverter. If yes : replace kV control board. 8/ Reconnect all the cables 3–42 X–RAY GENERATOR PROPRIETARY TO GENERAL ELECTRIC COMPANY REV 13 CT HISPEED SERIES ADVANCED DIAGNOSTICS 2202119 Note 3 : Ilr current not detected 1/ Power off the Generator. Wait until all neons are off 2/ Check that the inductors are correctly connected. If yes : 3/ Disconnect the currents transformers to gate_cmd board cable. Check that the serial current transformer impedance is 0. If no : replace capacitor set. Else : 4/ Check that inverter capacitors (capacitors set) are not broken. If yes, replace the capacitor set. Else : 5/ Check that the gate_cmd to HV Tank cable and HV Tank to kV control cables are correctly connected. If yes : 6/ Disconnect the HV Tank to kV control cable. Check that the impedance between pin20 and pin21 of J2 of HV Tank is 5 Ohms. If no replace inverter. If yes : replace kV control board. 7/ Reconnect all the cables Note 4 : Ilr current resonant frequency is lower than expected 1/ Power off the Generator. Wait until all neons are off 2/ Check that the inductors are correctly connected. If yes : 3/ Check that inverter capacitors (capacitors set) are not broken. If yes : replace the capacitor set. Else : 4/ Disconnect the currents transformers to gate_cmd board cable. Check that the parallel current transformer impedance is 0. If no : replace the capacitor set. Else : replace kV control board. 5/ Reconnect all the cables 3-10-3 No Load HV Diagnostic without Anode Rotation nor Filament Heating Purpose : The purpose of this test is to verify that the HV power inverter and HV tank are working properly. The exposure is taken as in application mode except that no filament drive nor anode rotation is running. Verification is made that the inverter currents are correctly set and that kV regulation is operating properly. As no filament drive is applied, no XRays are generated. This test also allow to separate Generator from HV cable or x–ray tube problem by running it with or without the HV cables plugged on the HV tank. (*) Pre–requisites : D Generator input line in an acceptable range ( 380V–10% to 480V+10% for 3–phase AC input ) D kV control board alive and running : S0–S7 Leds are lit successively or a combination of them blink D inverter gate_cmd board DC supply present : DS300 neon is lit D inverter dual snubber board DC supply present : DS1 neon is lit D Inverter gate command diagnostic passed without failure D Inverter in short circuit diagnostic passed without failure D (*) HV receptacles must be filled with oil if HV cables are removed. Test type : Manual operation is required. 3–43 X–RAY GENERATOR PROPRIETARY TO GENERAL ELECTRIC COMPANY REV 13 CT HISPEED SERIES ADVANCED DIAGNOSTICS 2202119 Sequence : 1/ Power on the Generator 2/ Push the TGP board reset switch, or OGP board reset switch. 3/ Start the diagnostic and verify : – error reported on the operator console – inverter gate_cmd board Leds DS101, DS 102, DS201, DS202 are lit : IGBTs gate drive supply is working properly 4/select kV (Default = 80 kV) and exposure time (Default = 1 sec.) 5/ Press the exposure switch (500ms exposure is taken) 6/ During the “exposure”, verify : – error reported on the operator console 7/ Release the exposure switch 8/ Power off the Generator Error reporting : See troubleshooting table 3–44 X–RAY GENERATOR CT HISPEED SERIES ADVANCED DIAGNOSTICS PROPRIETARY TO GENERAL ELECTRIC COMPANY REV 13 2202119 3-11 TROUBLESHOOTING AIDS Illustration 3–1 Generator Visual Power Supply Distribution L: Neon’s Z: LED’s DC bus, 400 ...800 V. L Heater board DC bus, 400 ...800 V. DS 1 DS 3 Z +M – INVERTER. & LLC.circuit L DC bus, 160V (120 to 200 V). +15 V – 15 V F1 DS 1 Gate command board DS 300 LVPS L NE 1 L AC/DC NP I/F DS 1 , 2 –15v, +15v kV ctrl “VCC“ + 5 V Z DS 2 +15 V – 15 V ZZ OGP 12V ≅ ZZZ DS 3, 2, 1 +5, –15, +15 +15 V – 15 V + – Rotor Board L DS 7 L DS 6 EMC Flt. 3ph, 380 – 480VAC C B 1 DC Disch (HEMIT assy) Z DS1 K1 ZDS2 PDU 3–45 115V AC ZDS3 LDS4 X–RAY GENERATOR PROPRIETARY TO GENERAL ELECTRIC COMPANY blank CT HISPEED SERIES ADVANCED DIAGNOSTICS 2202119 3–46 X–RAY GENERATOR CT HISPEED SERIES ADVANCED DIAGNOSTICS PROPRIETARY TO GENERAL ELECTRIC COMPANY REV 11 2202119 SECTION 4 – ERRORS, DIAGNOSTICS & TROUBLESHOOTING (for p5.4 or later JEDI Software) Note For earlier than the p5.4 JEDI software, use Section 2 (ERRORS, DIAGNOSTICS & TROUBLESHOOTING (NP, NP+, NP+ Twin)) or Section 3 (ERRORS, DIAGNOSTICS & TROUBLESHOOTING (NP++, NP++ Twin)). 4-1 INTRODUCTION This diagnostics section is to introduce the JEDI generator with the following information: Power–On diagnostics LED indication. List all the potential error codes that can be issued by JEDI Generator. Provide error code explanation, potential cause and recommended action. List of diagnostics aids and explanation of diagnostics. 4-2 POWER ON DIAGNOSTICS Refer to theory of operation for power–on sequence. This paragraph in this section is to provide meaning of boards’ LED status. The LED display status is offering useful information at a glance to proceed to error code based troubleshooting. Whenever in doubt, a simple step is to watch the LED status display on the kV control board, than the Rotation and Heater. kV control LED status: – During Power On Diagnostics : kV control board S0.........................S7 ⊗⊗⊗⊗⊗⊗⊗     The 8 LED’s (S0...S7) are lit successively: the power up diagnostics are completed, kV control board is up and running. 4–1 X–RAY GENERATOR PROPRIETARY TO GENERAL ELECTRIC COMPANY REV 11 CT HISPEED SERIES ADVANCED DIAGNOSTICS 2202119 S0.....................S7 ⊗⊗⊗⊗ One out of two is lit: Data base checksum problem. An error code is logged. Refer to error code description. S0.........................S7 ⊗⊗   S7, S6, S5 are lit along with either S0 or S1 or S2 (depending of the type of FPGA download error): FPGA download problem. An error code is logged. Refer to error code description. – When an application error occurs (Not PRD) ⊗⊗⊗⊗k ⊗k ⊗ The simplified error code is displayed on the Leds. They blink; when the error is cleared ( by a return to the standby mode for example ), the 8 LEDs are lit successively. Heater board LED status: (See central listing) After the power on diagnostics, heater board LEDs DS1 and DS2 are lit successively. Any different status corresponds to an abnormal situation. An error code is logged. Refer to error code description. Rotation board LED status: (See central listing) After the power on diagnostics, rotation board LED DS5 is blinking. Any different status corresponds to an abnormal situation. An error code is logged. Refer to error code description. 4–2 X–RAY GENERATOR PROPRIETARY TO GENERAL ELECTRIC COMPANY CT HISPEED SERIES ADVANCED DIAGNOSTICS REV 11 4-3 2202119 ERROR CODE LIST The error code list and associated short description is presented below. simplified error code 30 Description 40 Rotation Error 4 4 4 4 4 4 4 4 4 4 4 4 4 4 4 0101H 0102H 0103H 0104H 0105H 0106H 0107H 0109H 0110H 0111H 0112H 0113H 0114H 0115H 0149H No CAN message received within 5 secs Database not correct Rotation current overload Rotation Openload Rotation Phases unbalanced Rotation Phases error Rotation Inverter permanent overcurrent MAINS_DROP has failed PRD error (Z3Z4=bitmap) F0 main frequency problem Rotor HW/FW Config error IUVW short circuit error HV cable short circuit error HV cable open error Unknown rotation error 50 Heater Error 4 4 4 4 4 4 4 4 4 4 4 4 4 4 4 0201H 0203H 0204H 0205H 0206H 0207H 0208H 0210H 0211H 0212H 0213H 0214H 0215H 0216H 0221H 0222H 0223H 0224H 0248H 0249H No CAN message received within 5 secs inverter overcurrent (HW detected) open circuit (HW detected) Inverter short circuit (HW detected) Filament current too high Filament too high for Boost Filament too hot Current over estimated (short circuit) Current under estimated (open circuit) MAINS_DROP detected PRD error (Z3Z4=bitmap) Stay too long in Boost Filament selection error current feedback not null when inverter off Filament database tube 1 error Filament database tube 2 error Filament database tube 3 error Filament database tube 4 error Unknown heater LF error Unknown heater SF error Tube Spits Error Class 2 2 2 2 2 2 4 Error Description code 0301H Tube spit (kV+ and kV– dropped) 0302H Tube spit (kV+ has dropped) 0303H Tube spit (kV– has dropped) 0304H Tube spit (kV regulation error) 0305H FPGA problem (restarting safety signal) 0324H Spits detected ((1:anode 2:cathode 4:both 8:kVregul) 4–3 X–RAY GENERATOR CT HISPEED SERIES ADVANCED DIAGNOSTICS PROPRIETARY TO GENERAL ELECTRIC COMPANY REV 11 simplified error code 60 70 2202119 Description Exposure errors Power Supply errors Error Error Class code 3 0306H Description No kV Feedback on anode 3 3 3 3 3 3 3 3 3 3 3 3 3 3 3 2 3 3 3 3 3 3 3 3 3 3 3 3 3 0307H 0308H 0309H 0310H 0311H 0312H 0313H 0314H 0316H 0317H 0318H 0319H 0320H 0401H 0402H 0403H 0504H 0801H 0802H 0803H 1411H 1407H 1408H 1409H 1410H 0323H 0321H 1420H 1421H No kV Feedback on cathode No kV Feedback on anode and cathode kV detected during kV diag kV max detected ILP current not OK ILR current not OK ILR max current detected ILR current timeout Spit Max error Spit Ratio error kV did not reach 75% after 20ms kV unbalanced detected FPGA problem (safety signal) No mA feedback mA scale error mA accuracy exceeded 5% Inverter Gate Power Supply failed Exposure backup mAs exceeded Exposure backup time exceeded Exp cmd while gene not ready time counter error mAs counter error AEC counter error mAs meter saturated FPGA locked ILP and ILR current not OK Spit retry failed (TD computing) Tomo cut too early Time cut instead tomo 4 4 4 4 4 4 4 4 4 4 4 4 0501H DC bus out of range 0503H Inverter Gate Power Supply error 0505H Mains power supply has dropped during exposure 0506H DC bus 1 phase precharge error 0507H DC bus 1 phase discharge error 0577H Detected –15V too weak 0573H Detected –15V too strong 0567H Detected +15V too low 0563H Detected +15V too high 0557H Detected +160V too low 0553H Detected +160V too high 0549H Unknown LVPS error 4–4 X–RAY GENERATOR CT HISPEED SERIES ADVANCED DIAGNOSTICS PROPRIETARY TO GENERAL ELECTRIC COMPANY REV 11 2202119 simplified Description Error Error error code Class code 80 Hardware error 4 0180H 4 0181H 4 0280H 4 0281H 4 0322H 4 0601H 4 0602H 4 0902H 4 1402H 4 1403H 4 1404H 4 1405H 1406H 4 Description Rotation board communication problem Rotation board has reset Heater board communication problem Heater board has reset kV ref ADC / DAC failed RTL error External CAN bus off tube Fan supply error Internal CAN bus off Connectic Fault FPGA configuration problem Tank sensor problem Inverter sensor problem 90 Application errors 4 4 4 4 0701H 0702H 0704H 0705H Saved RAM checksum pb Software problem Rotation/Heater hold too long System or database configuration error 100 Com errors 4 4 4 4 4 0603H 0604H 0605H 0606H 1301H Debug screen com error Database download error TAV com error MPC/Madrid com error AEC board com error 110 Thermal error 5 5 5 5 3 0804H 0805H 0903H 0904H 1454H Tank Thermal Error Inverter Thermal Error Tube exceeded 70degC HEMIT thermal error Jedi inverter temperature too high 120 Manipul. error 5 5 5 1500H 1501H 1502H Tomo brightness not good Release exposure switch AEC does not cut exposure 4–5 X–RAY GENERATOR CT HISPEED SERIES ADVANCED DIAGNOSTICS PROPRIETARY TO GENERAL ELECTRIC COMPANY REV 11 2202119 simplified Description Error Error error code Class code 10 Rotation Warn1 0151H ing 1 0152H 1 0153H 1 0154H 1 0155H 1 0156H 1 0157H 1 0158H 1 0159H 1 0160H 1 0161H 1 0162H 1 0163H 1 0164H 1 0199H 20 Heater Warning Description CAN Domain command number error CAN Domain request with no transfer init CAN Domain Toggle bit error CAN Domain : less than 2 data to download CAN Domain Abort received & applied Bad index in config upload Tube switch while Rotation not off Acceleration cmd while no tube selected Acceleration cmd while database not OK Database download while Rotation speeding Acceleration command not OK Rotation acceleration while in error No CAN message received within 4 secs Rotation Inverter overcurrent (< 3 times) Unknown rotation warning 1 0251H Received command is not OK 1 1 1 1 1 1 1 1 1 1 1 1 1 0252H 0253H 0254H 0255H 0256H 0257H 0258H 0259H 0260H 0261H 0262H 0263H 0299H Heater command not OK No CAN message received within 4 secs Heater inverter overcurrent (inverter1) (<3 times) Filament open circuit (inverter1) (<3 times) Heater Inverter short circuit (inverter1) (<3times) Tube switch while filaments not OFF CAN Domain command number error CAN Domain request with no transfer init CAN Domain Toggle bit error CAN Domain : less than 2 data to download CAN Domain Abort received & applied Database download while heater not cut Unknown Heater warning 4–6 X–RAY GENERATOR CT HISPEED SERIES ADVANCED DIAGNOSTICS PROPRIETARY TO GENERAL ELECTRIC COMPANY REV 11 simplified error code 25 27 2202119 Description Low Voltage Power Supply Warnings Application warnings Error Class 1 1 1 1 1 1 1 1 1 1 1 1 1 Error code 0570H 0570H 0560H 0560H 0550H 0550H 0575H 0571H 0565H 0561H 0555H 0551H 0599H Description No more warn –15V too low No more warn –15V too high No more warn +15V too low No more warn +15V too high No more warn +160V too low No more warn +160V too high Detected –15V too weak Detected –15V too strong Detected +15V too low Detected +15V too high Detected +160V too low Detected +160V too high Unknown LVPS warning 1 1 1401H 0703H Saved RAM power supply limit reached Watchdog reset has just occurred 4–7 X–RAY GENERATOR PROPRIETARY TO GENERAL ELECTRIC COMPANY REV 11 4-4 4-4-1 CT HISPEED SERIES ADVANCED DIAGNOSTICS 2202119 ERROR REPORTING NP Generator Error Reporting Np system only gets the simplified error code from the Jedi Generator. The Np system errorlog adds to the simplified error code the following information: D error message (refer to the Np system documentation) D system phase : state of the system when the error occurred. Take care, the system state is different of the Generator phase (refer to the Np system documentation) D system time : date and time when the error occurred. Take care, the system time is different of the Generator time Whenever a Generator error is logged in the system errorlog file and displayed on the operator console, the Jedi errorlog upload functionality is available to get more detailed information about the error. This function must be performed from the operator console. The simplified error code must be used to find the Jedi error code in the Jedi errorlog file. Having these two information, look at the Jedi trouble–shooting table to find the FRU to replace. Error codes can also be read by connecting the service laptop. 4-4-2 Tiger Generator Error Reporting (not for NP++ and Twin systems) Tiger console only displays the simplified error code from the Jedi Generator. Whenever a Generator error is displayed on the operator console, the Jedi errorlog upload functionality is available to get more detailed information about the error. This function must be performed from the service laptop. The simplified error code must be used to find the Jedi error code in the Jedi errorlog file. Having these two information, look at the Jedi trouble shooting table to find the FRU to replace. 4–8 X–RAY GENERATOR PROPRIETARY TO GENERAL ELECTRIC COMPANY CT HISPEED SERIES ADVANCED DIAGNOSTICS REV 11 4-5 2202119 DIAGNOSTICS This chapter describes diagnostics tools based on error codes and specific diagnostics. WARNING 4-5-1 Before any manual intervention, ensure the main power is off. Apply lock out–tag out procedure for your own safety when manipulating inside the equipment is required. Detailed Error Description & Troubleshooting Guide The first part details errors, while the warning errors are listed in a second part of this chapter. The table below provides guidelines to troubleshoot Generator problems based on error code. For each code, there is: –Associated message and additional explanation related to the error occurrence. –List potential cause, in the order of expected probability. –Recommended action, with, in some cases, link to some more information as indicated where cases apply, such as to run some specific diagnostics. Codes are sorted by ascending order both for simplified code and error code. Refer to the theory of operation for error code structure. Information about associated data structure is located at the end of each error code subset whenever it applies. Whenever wiring, cabling, LED check is mentioned in the recommended actions, refer to the central listing. 4–9 X–RAY GENERATOR PROPRIETARY TO GENERAL ELECTRIC COMPANY REV 11 4-5-1-1 CT HISPEED SERIES ADVANCED DIAGNOSTICS 2202119 Errors Tube spits detection Errors (Code 30) Class 2 Error code 30–0324 H data=4* Message/explanation Potential cause Tube spit (kV+ and kV– dropped) kV drop/spit detected x–ray tube spit. 30–0324 H data=1* (see Note) Tube spit (kV+ has dropped) kV drop/spit detected on Anode side 1. Anode side Tube spit. 2. Anode HV cable 3. HV tank 30–0324 H data=2* (see Note) Tube spit (kV– has dropped) kV drop/spit detected on cathode side 1. Cathode side Tube spit. 2. Cathode HV cable 3. HV tank 30–0324 H data=8* (see Note) kV regulation error This is a slow speed safety circuit in case of “smooth” spits. 30–0305 H Re–starting safety. (unknown reason) Error occurring on safety line, while No root error present at the error inputs (Err 0301 to 0304). This is probably due to transient interference (Spikes). 1. smooth HV tube spits 2. kV control board (HV regulation problem) 3. too much line impedance 4. half of AC/DC capacitors open 5. Inverter (parallel inductor or filtering capacitors) 6. HV tank 1. External unknown cause. 2. kV control board. 4–10 Recommended action/ Troubleshooting guide Usual in tubes. If too frequent, and varies with HV: replace x–ray tube. – Run open load kV test. (See diagnostic section) If too frequent: – Check HV cables and contacts – Tube problem. (Anode side) – Check cable by interchanging them. – Run Open load kV test. (See diagnostic section) – Otherwise, HV tank. If too frequent: – Check HV cables and contacts – Tube problem. (Cathode side) – Check cable by interchanging them. – Run Open load kV test. (See diagnostic section) – Otherwise, HV tank –Run inverter diagnostics (See diagnostic section) –Run Open load kV test. (See diagnostic section) –Troubleshoot tube and contacts of HV cable. –Check DC bus voltage. –Do a power and Grounding Check. Verify cabling and contacts. –If permanent or too systematic, replace kV control board. Report to engineering. X–RAY GENERATOR CT HISPEED SERIES ADVANCED DIAGNOSTICS PROPRIETARY TO GENERAL ELECTRIC COMPANY REV 11 2202119 * Note to the error 30 0324H: The generator sends only one message of error for all the spits (0324H) at the end of the exposure. During the same exposure we may have different kind of spits. In the data of this error we can distinguish between the different spits: 1: Spit in anode side 2: Spit in cathode side 4: Spit in both sides 8: kV regulation error. For a exposure with anode and both sides spit, the data will be “5”. These data can be displayed in the OC in decimal or in hexadecimal base. Spits code detail See data (Z6[#H]) of XG error code 324H. Transfer #H to Binary data. Contents are as follows. code bit3 bit2 bit1 bit0 KV Regulation Error Insert Spits Cathode side arching Anode side arching 1 0 0 0 1 2 0 0 1 0 3 0 0 1 1 4 0 1 0 0 5 0 1 0 1 6 0 1 1 0 7 0 1 1 1 8 1 0 0 0 9 1 0 0 1 A 1 0 1 0 B 1 0 1 1 C 1 1 0 0 D 1 1 0 1 E 1 1 1 0 F 1 1 1 1 ex.) (0324H)Spits (1:anode 2: cathode 4: both 8: kVregul) (Z6[CH]:Z7[0H]) Z6[CH] –> C Hex –> 1100 Bin –> KV regulation + Insert 4–11 X–RAY GENERATOR PROPRIETARY TO GENERAL ELECTRIC COMPANY CT HISPEED SERIES ADVANCED DIAGNOSTICS REV 11 2202119 Anode Rotation errors (Code 40) Class 4 Error Message/explanation code 40–010 No CAN message re1H ceived within 5 sec’s The rotation board has not received any signal from the kV control main software for the last 5 sec., interpreted as a loss of communication 40–010 Data base not correct. 2H The firmware of the rotation board has detected that the data base received from the kV control board has wrong data. 40–010 Rotation current overload 3H Rotation board has detected Main or auxiliary Rotation current too high compared to the max. Tube motor current. 40–010 Rotation current openload 4H Rotation board detected that no current is flowing to the motor. Potential cause 1. kV Control main software lost 2. kV control or Rotation board driver failure 3. Bad contact on one of the pin on the CAN bus line connector Recommended action/ Troubleshooting guide –Unlikely to happen. This is a debug error. –Retry –Re initialise and retry 1. Wrong kV control data base. It can only happen at power up. –Reload NVRam database. –ultimate is to replace Rotation board. 1. Rotation board 2. Rotation board phase capacitor short circuited (not for NP++) 3. Wrong data base (improbable) Check wiring from rotation board to tube (cable from rotation board to HEMIT and HV cable from HEMIT to tube for NP++). If no cabling problem, run Rotation diagnostic to differentiate between rotation board and phase shift capacitors (not for NP++).(See diagnostic section). Check wiring from rotation board to tube (cable from rotation board to HEMIT and HV cable from HEMIT to tube for NP++. See Rotation diagnosis). Check DC bus cables from AC–DC board to rotation board Check that phases capacitors are correctly connected (not for NP++) If no cabling problem, run Rotation diagnostic to differentiate between rotation board and phase shift capacitors (not for NP++).(See diagnostic section). 1. Tube stator winding is open circuit: x–ray tube 2. Incorrect wiring (Open) 3. No DC bus on Rotation board 4. Rotation board 5. Rotation board phase capacitor not connected (not for NP++ and improbable) 4–12 X–RAY GENERATOR PROPRIETARY TO GENERAL ELECTRIC COMPANY REV 11 Class 4 Error Message/explanation code 40–010 Rotation Phases unbal5H anced The amplitude difference of the current between main and auxiliary is too large. 40–010 Rotation phase error 6H The Rotation board has detected that the current in the anode stator does not show the correct phase shift between main and auxiliary. CT HISPEED SERIES ADVANCED DIAGNOSTICS 2202119 Potential cause 1. One Rotation wire missing 2. Rotation board 3. Rotation board phase capacitors inverted or wrong value or not connected (not for NP++) 4. Wrong tube configuration data base 5. Tube problem (stator) 6. HV cable between HEMIT and tube (only for NP++) 1. Rotation board 2. Tube problem (stator) 3. HV cable between HEMIT and tube (only for NP++) 4. Rotation board phase capacitors inverted or wrong value (not for NP++) 4–13 Recommended action/ Troubleshooting guide Check wiring from rotation board to tube (cable from rotation board to HEMIT and HV cable from HEMIT to tube for NP++. See Rotation diagnosis). Check that phases capacitors are correctly connected (not for NP++) If no cabling problem, run Rotation diagnostic to differentiate between rotation board and phase shift capacitors (not for NP++).(See diagnostic section). Check wiring from rotation board to tube (cable from rotation board to HEMIT and HV cable from HEMIT to tube for NP++). Check that phases capacitors are correctly connected (not for NP++) Verify none is in short circuit. If no wiring problem, run Rotation diagnostic. (See diagnostic section) X–RAY GENERATOR PROPRIETARY TO GENERAL ELECTRIC COMPANY CT HISPEED SERIES ADVANCED DIAGNOSTICS REV 11 NP++ NP++ NP++ 2202119 Error Message/explanation code 40–010 Rotation Inverter perma7H nent overcurrent An overcurrent has been detected and 3 restart have been tried unsuccessfully within a single rotation state 40–010 MAINS_DROP has failed 9H The firmware of the rotation board has detected the mains_drop signal activation and transmitted error to kV control 40–011 PRD error(Z3Z4=bitmap) 0H Firmware checksum, RAM test and EPLD access are performed at power up or reset. 40–011 F0 main frequency prob1H lem. EPLD has not applied the inverter start command 40– Rotor HW/FW Config er0112H ror 40– IUVW short circuit error 0113H (only for NP++) 40– HV cable short circuit er0114H ror (only for NP++) 40– 0115H HV cable open error (only for NP++) 40–014 Unknown rotation error. 9H The main software received an error from rotation board with no error code associated Potential cause 1. Rotation board 2. Tube stator winding in short circuit –> cable (NP) or HEMIT (only for NP++) 3. Wiring incorrect (shorted) 1. Interference (spikes) 2. Mains drop 3. Cable or connector contact in DC bus between power unit and auxiliary unit 4. Rotation board Rotation board Recommended action/ Troubleshooting guide –Check wiring from rotation board to tube. –Troubleshoot tube windings –Replace Rotation board –Do a power and grounding check. –If systematic, replace Rotation board Replace Rotation board. Rotation board –Retry –Replace Rotation board. Rotation board Download official data base If the problem persists, change rotor – Retry – Change rotation board – Check HV cable impedance – Change tube – Change Hemit IUVW signal shortcircuited on rotation board Short circuit on: – Tube stator – Hemit secondary – Anode HV cable Or bearings of tube broken Open circuit on: – Tube stator – Hemit secondary – Anode HV cable Software problem 4–14 – Check HV cable connection and impedance. Replace if open. – Check tube stator impedance – Check Hemit secondary impedance. Replace HEMIT if open. No action. X–RAY GENERATOR PROPRIETARY TO GENERAL ELECTRIC COMPANY REV 11 CT HISPEED SERIES ADVANCED DIAGNOSTICS 2202119 Associated data structure: PRD error: component failure : 0001H=RAM 0002H=RAM stack 0200H=EPLD 8000H=program checksum Rotation database error: 2 bytes data, each value points to a specific parameter found as being erroneous Other errors: rotation state : 0=inverter OFF 1=acceleration 0 to low speed 2=acceleration 0 to high speed 3=acceleration low speed to high 4=low speed run 5=high speed run 6=high speed to low speed brake 7=brake reverse 8=brake DC 4–15 X–RAY GENERATOR PROPRIETARY TO GENERAL ELECTRIC COMPANY CT HISPEED SERIES ADVANCED DIAGNOSTICS REV 11 2202119 Filament Heater errors (Code 50) Class 4 Error Message/explanation code 50–020 No CAN message re1H ceived within 5 sec’s The Heater board has not received any command from the kV control main software for the last 5 sec., interpreted as a loss of communication 50–020 Heater inverter permanent 3H overcurrent.(SW limit) Issued by the heater board when an overcurrent has been detected and 3 restarts have been tried without success within 100 ms 50–020 Filament permanent open 4H circuit. Issued by the heater board when an open has been detected and 3 restarts have been tried without success within 100 ms 50–020 Heater Inverter permanent 5H short circuit (HW limit) Issued by the heater board when a short circuit has been detected and 3 restarts have been tried without success within 100 ms 50– Filament current too high 0206H on inverter 1 for “Pre– Heat” This is the result of an integrated value of the RMS current measurement on Heater board comparison with max. Tube value in data base. Potential cause 1. kV Control main software lost 2. kV control or Heater board driver failure 3. Bad contact on one of the pin on the CAN bus line connector Recommended action/ Troubleshooting guide –Unlikely to happen. This is a debug error. –Retry –Re initialise and retry. 1. Heater board –Restart. If persistent, replace Heater board 1. X–ray tube filament open 2. Heater to HV tank cable 3. Cathode HV cable or pin contacts 4. Open circuit in filament transformer inside HV Tank. –Switch on the other filament: if no error is reported, heater board is working properly. Check heater board to HV Tank to tube connections. If OK, test with Ohm– meter HV Tank heater transformers (primary and secondary) and filament impedance. Order accordingly If the same error is reported, check the connections as above. If all are right, replace heater board –Restart. If persistent, replace Heater board 1. Heater board 1. Tube data base or calibration 2. Heater board 4–16 –It’s unlikely, but reload NVRam database. –Replace heater board. X–RAY GENERATOR PROPRIETARY TO GENERAL ELECTRIC COMPANY CT HISPEED SERIES ADVANCED DIAGNOSTICS REV 11 Error code 50– 0207H 2202119 Message/explanation Filament current too high on inverter 1for “Boost” Same as above 50– Filament current too 0208H high on inverter 1for “Heat” Same as above 50–021 Current over estimated 0H fork range RMS filament current measurement (every 0.5 m sec.) on heater board is too low 50–021 Current under estimated 1H fork/ range RMS filament current measurement (every 0.5 msec.) on heater board is too high 50– MAINS_DROP detected. 0212H The firmware of the Heater board has detected the mains_drop signal activation and has transmitted error to kV control 50–021 PRD error 3H Firmware checksum, RAM test and EPLD access are performed at power up or reset. 50– Boost too long on inver0214H ter1. Boost command stayed longer than 400ms 50– Filament selection error. 0215H The relay on the Heater board selecting the filament is in the wrong position with respect to the selection Potential cause 1. Tube data base or calibration 2. Heater board 1. Tube data base or calibration 2. Heater board 1. short circuit 2. Heater board Recommended action/ Troubleshooting guide Same as above Same as above –Switch on the other filament: if no error is reported, heater board is working properly. Check heater board to HV Tank to tube connections. If OK, test with Ohm–meter HV Tank heater transformers (primary and secondary) and filament impedance. Order accordingly If the same error is reported, check the connections as above. If all are right, change heater board Replace heater board 1. Open circuit 2. Heater board 1. Interference (spikes) 2. Mains drop 3. Cable or connector contact in DC bus between power unit and auxiliary unit 4. Heater board Heater board –Do a power and grounding check. –If systematic, replace heater board May be a loss of communication during boost. Retry. It will probably be followed by another communication code. Heater board Replace heater board 4–17 Replace heater board. X–RAY GENERATOR CT HISPEED SERIES ADVANCED DIAGNOSTICS PROPRIETARY TO GENERAL ELECTRIC COMPANY REV 11 Error code 50– 0216H 50– 0221H 0222H 0223H 0224H 50– 0248H 50– 0249H 2202119 Message/explanation Potential cause Current feedback not null when inverter OFF Inverter current has been measured while the inverter was not commanded Filament Database not correct The firmware of the heater board has detected that the Received Data base from kV control contains erroneous data for Tube 1, 2, 3, or 4. Unknown heater LF error The main software received an error from heater board with no error code associated Unknown heater SF error The main software received an error from heater board with no error code associated Heater board Recommended action/ Troubleshooting guide Replace heater board 1. Wrong kV control data base. It can only happen at power up. –Reload NVRam data base. –ultimate is to replace Heater board. 1. software problem No action 1. software problem No action Associated data structure: PRD error : component failure : 0001H=RAM 0002H=RAM stack 0200H=EPLD 8000H=program checksum Filament database error : 2 bytes bitmap ( LSByte=small focus, MSByte=large focus) Each bit points to an erroneous parameter other errors : 1 byte bitmap with the following structure : bit7 (MSB) bit6 bit5 bit4 focus selected tube selected 0=small focus selected 1=tube 1 selected 1=large focus selected 2=tube 2 3=tube 3 4=tube 4 bit3 bit2 small focus state 0=inverter OFF 1=preheat 2=boost 3=heat 4–18 bit1 bit0 (LSB) large focus state 0=inverter OFF 1=preheat 2=boost 3=heat X–RAY GENERATOR PROPRIETARY TO GENERAL ELECTRIC COMPANY CT HISPEED SERIES ADVANCED DIAGNOSTICS REV 11 2202119 Exposure errors (Code 60) Class 3 Error Message/explanation code 60–030 No kV feedback on anode 6H side kv measured <12kV 0,5ms after start of exposure on anode side only 60–030 No kV feedback on cath7H ode side kv measured <12kV 0,5ms after start of exposure on cathode side only 60–030 No kV Feedback (on 8H anode and cathode) kv measured <12kV 0,5ms after start of exposure on both anode and cathode. 60–030 kV detected during kV 9H diagnostics. KV measured during inverter diagnostics while no kV must be generated. 60–031 kV MAX detected 0H kV reached 160 kv during exposure 60–031 ILP current not OK. 1H The current in the parallel resonant circuit of the inverter did not rise at the beginning of the exposure. 60–031 ILR current not OK 2H The current in the serial resonant circuit of the inverter did not rise at the beginning of the exposure. 60–031 Inverter max. ILR cur3H rent detected. This is a hardware detection of maximum current in serial resonant circuit. Potential cause 1. HV cable short circuit 2. HV tank 3. kV control board (less probable) 1. HV cable short circuit 2. HV tank 3. kV control board (less probable) 1. HV tank 2. kV control board Recommended action/ Troubleshooting guide –Troubleshoot HV cables : run no load kV diagnostic along with inverting HV cables If HV cables are right, replace HV Tank –Troubleshoot HV cables : run no load kV diagnostic along with inverting HV cables If HV cables are right, replace HV Tank –Verify flat cable connections and sitting between kV control and HV tank. – Replace HV Tank Improper setup before the diagnostic is run. See HV power diagnostic section. kV control Replace kV control board 1. Inverter LC resonant circuit (Inverter coil assy, capa inverter assy, current transformers.) 2. Inverter 3. kV control See above run HV power diagnostics 1 Tube (it can be casing spits, error 0324H data=1 or 2) 2 HV tank 3 kV control 4 inv LC resonant circuit run HV power diagnostics in order to determine if it is associated to tube If during the test, you have kV unbalance, see error 0319H. 4–19 run HV power diagnostics X–RAY GENERATOR PROPRIETARY TO GENERAL ELECTRIC COMPANY CT HISPEED SERIES ADVANCED DIAGNOSTICS REV 11 (*) for NP (*) for NP 2202119 Class 3 Error Message/explanation code 60–031 ILR Current time out. 4H The current resonant frequency is lower than expected 60–031 Spit Max error. 6H kV control has detected the number of tube spits during exposure has reached the limit (see theory of operation, software section) Potential cause 1. kV control 2. Inverter 3. Current measurement circuit. reasonably x–ray tube 60–031 Spit Ratio error. 7H kV control has detected the rate of tube spits during exposure has reached the limit (see theory of operation, software section) reasonably x–ray tube 60–031 kV did not reach 75% af8H ter 20ms. Indicates that there were no HV ON signal generated for exposure time count–up 60–031 kV unbalanced detected. 9H Detects that there is more than 12kV difference between kV+ and kV – 60–032 FPGA problem; Safety hit 0H with unknown reason No error at the inputs while checking for error source. 60–032 ILP and ILR current not 3H OK No inverter current measures at the beginning of the exposure 1. kV control Recommended action/ Troubleshooting guide run HV power diagnostics –Try again at various kV/mA to confine problem. – if it is associated to kV regul out spit detection, check mains input voltage connection –Troubleshoot HV section. (x–ray tube, cable, HV tank) –Diagnose based on tube history. –Try again at various kV/mA to confine problem. – if it is associated to kV regul out spit detection, check mains input voltage connection –Troubleshoot HV section. (x–ray tube, cable, HV tank) –Diagnose based on tube history. Replace kV control. HV tank –Try again at various mA to confirm problem. Replace HV tank 1. This may be due to transient interference (Spikes). 2. SW bug Do a power and Grounding Check. Verify cabling and contacts. If permanent or too systematic, replace kV control board. Report to engineering run HV power diagnostics 1. Inverter LC resonant circuit. (Inverter coil assy, capa inverter assy, current transformers.) 2. Inverter 3. kV control board 4–20 X–RAY GENERATOR PROPRIETARY TO GENERAL ELECTRIC COMPANY CT HISPEED SERIES ADVANCED DIAGNOSTICS REV 11 Not on CT 2202119 Error Message/explanation code 60–040 No mA feedback 1H mA measurement function: kV control has detected no mA feedback 20 ms after the beginning of the exposure. Potential cause 60–040 mA scale error 2H mA has been measured to be either too low or too high with respect to mA demand 20 ms after the beginning of the exposure 4. kV control board 5. default filament currents not correctly adjusted 6. HV Tank (improbable) 60–040 mA accuracy exceeded 3H 5% (Class Measured mA every 50 2 error) msec exceeded 5% of mA demand. This error is logged, but does not stop the exposure. 60–050 Inverter Gate Power Sup4H ply error gate supply voltage has dropped below the level required to drive the IGBTs properly 60–080 Exposure backup mAs ex1H ceeded The exposure command last so long that the maximum mAs allowed has been reached 60–080 Exposure backup time ex2H ceeded. The exposure command last longer than the duration that was loaded by the system (Backup time + 5%.) 2. tube spit 6. HV tank 7. kV control board 8. x–ray tube (filament open or short circuited) 9. Cathode HV cable short–circuited 10.Misconnection between HV+ and HV– after a tank replacement 11. heater function Recommended action/ Troubleshooting guide – Disconnect HV Tank to kV control flat cable and verify with an Ohm– meter the accuracy of the 5 Ohms resistor on the HV Tank mA measure. If it is far out of range, (4.9 to 5.1 Ohm, including DVM accuracy) replace HV Tank. – Verify filament impedance – Verify filament drive (heater) – Replace kV control board – After a tank replacement, verify the HV cable connection. – If the tube has just been replaced or installed, run many exposures until the filament correction adjusts the default filament drive values. – If the error occurs after a while on a system : Disconnect HV Tank to kV control flat cable and verify with an Ohm– meter the accuracy of the 5 Ohms resistor on the HV Tank mA measure. If it is out of range, replace HV Tank else replace kV control board no action 4. Inverter (gate command board) 5. kV control board 6. Generator input voltage too low or line impedance too high 2. exposure command line stuck to the active state run HV power diagnostics 4. System 5. System–Generator cable 6. I/F board : exposure line stuck to the active state –Retry, changing parameters and duration – disconnect system–Generator cable in different places and check exposure command line voltage 4–21 X–RAY GENERATOR PROPRIETARY TO GENERAL ELECTRIC COMPANY CT HISPEED SERIES ADVANCED DIAGNOSTICS REV 11 Not CT Not CT Not CT for NP Not NP Not NP 2202119 Error Message/explanation code 60–080 Exp cmd while gene not 3H ready. Generator received an exposure command while not in ready state 60–141 Time counter error. 1H Error found in verifying the counter normal operation. 60–140 mAs counter error. 7H Error found in verifying the counter normal operation. 60–140 AEC counter error. 8H If there is no AEC feedback in AEC station exposure. 60–140 mAs meter saturated. 9H A check is done on mAs counter operation at the beginning of exposure and found the mAs meter with unrealistic value. 60–141 FPGA locked. 0H FPGA detected an error and did not allow start exposure after exposure command signal was received. 60 Spit retry failed (only for 0321H NP/NP+) 60 0323H ILP and ILR current not OK 60 1420H 60 1421H Tomo cut too early (only for RAD) Time cut instead tomo (only for RAD) Potential cause 1. Software bug/problem 2. Cable / communication problem 3. External cause (Spikes) kV control board Recommended action/ Troubleshooting guide If problem is persistent, check heater, anode rotation and system to Generator preparation command to find the root cause for the Generator not to be ready Replace kV control Board kV control board Replace kV control Board 1. ION chamber 2. AEC cable, connection 3. AEC board Run AEC diagnostics (See diagnostic section) 1. kV control Replace kV control 1. software bug 2. kV control If persistent replace kV control 1. Tube (most probable) 2. HV cables 3. HV tank If this error is associated to spit detection on anode side, same time, (0324h data 1), change tube else run no load HV diagnostics. run HV power diagnostics 1. Inverter LC resonant circuit (Inverter coil assy, capa inverter assy, current transformers.) 2. Inverter 3. kV control Positioner cut exposure before programmed time Positioner does not cut exposure 4–22 positioner trouble positioner trouble X–RAY GENERATOR CT HISPEED SERIES ADVANCED DIAGNOSTICS PROPRIETARY TO GENERAL ELECTRIC COMPANY REV 11 2202119 Power supply (Code 70) Class 4 Error Message/explanation code 70–050 DC bus out if range (<400 1H or >850) 70–050 Inverter Gate Power Sup3H ply error (checked at prep) 70–050 Mains power supply has 5H dropped During exposure Potential cause 1. mains problem (Too low or too high) 2. One phase missing at Generator input 1. Mains 2. Cable pb 3. Gate command board (Inverter) 4. kV control unknown Not NP 70–050 DC bus 1 phase pre– 6H charge error. Found DC bus did not reach 400V after 10 sec. Charge relay is not activated and pre–charge relay drops. 1. 2. 3. 4. 5. Pre–charge resistor Relay ACDC module LVPS kV control board Not NP 70–050 DC bus 1 phase discharge 7H error. Found that DC bus voltage is > 30 V before pre– charge. ACDC 4–23 Recommended action/ Troubleshooting guide –Check mains line 3 phases incoming voltage. –Verify line impedance if mains is low. run HV power diagnostics None WARNING!: Potential residual voltage. Make sure all the NEON are off. Verify with a DVM, range 400VDC that there is no voltage on the capacity bench before any intervention –Verify LED on LVPS –Listen to relay clicking at power on. –Check resistor Replace ACDC module. X–RAY GENERATOR PROPRIETARY TO GENERAL ELECTRIC COMPANY REV 11 Class 4 Error Message/explanation code 70–057 Detected –15V too low 7H –15V is higher than –13V (measured on heater board) CT HISPEED SERIES ADVANCED DIAGNOSTICS 2202119 Potential cause 1. 2. 3. 4. LVPS (open circuit) Heater board rotation (short circuit) kV control (short circuit) (improbable) 70–057 Detected –15V too high 3H –15V is lower than –17.3V (measured on heater board) 1. LVPS open circuit 2. Heater board 70–056 Detected +15V too low +15V is lower than 13V 7H (measured on heater board) 1. LVPS open circuit 2. Heater board 3. rotation (short circuit) kV control (short circuit) (improbable) 4–24 Recommended action/ Troubleshooting guide Verify that the DC bus on LVPS board is in an acceptable range (CF1/CF2) If no, verify AC/DC fuse and AC input voltage. Check –15V on heater board (J3, pin3). If OK, replace heater board. If voltage=0, check the continuity on heater board between (J3, pin3) and (J1,pin3).If no continuity, replace heater board Else, disconnect the control bus cable from the LVPS board and check the pin3 of the connector: if voltage is wrong replace LVPS board. Else, check pin3 of the control bus cable when disconnecting the cable from each board successively to isolate the board inducing a voltage drop Verify that the DC bus on LVPS board is in an acceptable range (CF1/CF2) If no, verify AC/DC fuse and AC input voltage. Check –15V on heater board (J3, pin3). If OK, replace heater board. Else, disconnect the control bus cable from the LVPS board and check the pin3 of the connector: if voltage is wrong replace LVPS board. Verify that the DC bus on LVPS board is in an acceptable range (CF1/CF2) If no, verify AC/DC fuse and AC input voltage. Check 15V on heater board (J3, pin4). If OK, replace heater board. If voltage=0, check the continuity on heater board between (J3, pin4) and (J1,pin2).If no continuity, replace heater board Else, disconnect the control bus cable from the LVPS board and check the pin2 of the connector : if voltage is wrong replace LVPS board. Else, check pin2 of the control bus cable when disconnecting the cable from each board successively to isolate the board inducing a voltage drop X–RAY GENERATOR PROPRIETARY TO GENERAL ELECTRIC COMPANY REV 11 CT HISPEED SERIES ADVANCED DIAGNOSTICS 2202119 Error Message/explanation code 70–056 Detected +15V too high +15V is higher than 17.3V 3H (measured on heater board) Potential cause 70–055 Detected +160V too low 7H +160V is lower than 110V (measured on heater board) 1. LVPS 2. Heater board 70–055 Detected +160V too high 3H +160V is higher than 225V (measured on heater board) 1. LVPS 2. Heater board 70–054 Unknown LVPS error 9H The main software received a LVPS error with no error code associated 1. Software problem 1. LVPS open circuit 2. Heater board 4–25 Recommended action/ Troubleshooting guide Verify that the DC bus on LVPS board is in an acceptable range (CF1/CF2) If no, verify AC/DC fuse and AC input voltage. Check 15V on heater board (J3, pin4). If OK, replace heater board. Else, disconnect the control bus cable from the LVPS board and check the pin2 of the connector : if voltage is wrong replace LVPS board. Verify that the DC bus on LVPS board is in an acceptable range (CF1/CF2) If no, verify AC/DC fuse and AC input voltage. Check 160V on CF2/1 on heater board. If OK, replace heater board Else, disconnect the CF2 cable and measure again on the LVPS side. If voltage is wrong, replace LVPS board. Verify that the DC bus on LVPS board is in an acceptable range (CF1/CF2) If no, verify AC/DC fuse and AC input voltage. Check 160V on CF2/1 on heater board. If OK, replace heater board Else, disconnect the CF2 cable and measure again on the LVPS side. If voltage is wrong, replace LVPS board. No action X–RAY GENERATOR PROPRIETARY TO GENERAL ELECTRIC COMPANY REV 11 CT HISPEED SERIES ADVANCED DIAGNOSTICS 2202119 Hardware errors (Code 80) Class 4 Error Message/explanation code 80–018 Rotation board commu0H nication problem. kV control board communication Watch Dog with Rotation board popped up because it did not get reply from Rotation board. 80–018 Rotation board has reset. 1H kV control has detected the Rotation board has reset. KV control will reload Rotation data base. Potential cause 1. Rotation board 2. Control bus cable 3. kV control 1. Rotation board 2. Interference (Spikes) 4–26 Recommended action/ Troubleshooting guide A/Check that rotation firmware is running (DS5 Led is blinking). If no : 1/verify rotation board 5V : Led DS3 is lit. If no : verify DS1/DS2 Leds : if they are lit, replace rotation board, else go to +/–15V errors troubleshooting 2/ verify that RESET Led is not lit. If it is lit, disconnect successively the control bus cable from heater and kV control to find the board which is holding the reset line and replace it. If after disconnecting all the boards, the Led remains lit, replace rotation board 3/ else replace rotation board B/Verify the flat cable between kV control and auxiliary module is correctly connected to the Rotation board C/else replace kV control –Reinitialize system, retry. –If persistent, replace Rotation board or check power and grounding. X–RAY GENERATOR PROPRIETARY TO GENERAL ELECTRIC COMPANY REV 11 CT HISPEED SERIES ADVANCED DIAGNOSTICS 2202119 Error Message/explanation code 80–028 Heater board communica0H tion problem kV control board communication Watch Dog with Heater board popped up because it did not get reply from Heater board. Potential cause 80–028 Heater board has reset. 1H KV control has detected the heater board has reset. KV control will reload Rotation data base. 80–032 kV ref ADC / DAC failed 2H kV control DAC and ADC capability are permanently tested for coherency. 80–060 RTL error (+ associated 1H data to check which of the 4 RTL lines) Real Time Lines show a wrong state. RTL’s are tested on a regular basis in stand by. 1. Heater board 2. Interference (Spikes) 1. Heater board 2. Control bus cable 3. kV control Recommended action/ Troubleshooting guide A/Check that heater firmware is running (DS1/2 Led are lit successively). If no : 1/verify heater board 5V : J3/pin2. If wrong : verify +15V/–15V (J3, pin3,4) : if they are right, change rotation board, else go to +/–15V errors troubleshooting 2/ verify that RST Led is not lit. If it is lit, disconnect successively the control bus cable from LVPS to rotation and kV control to find the board which is holding the reset line and replace it. If after disconnecting all the boards, the Led remains lit, replace heater board 3/ else replace heater board B/Verify the flat cable between kV control and auxiliary module is correctly connected until the heater board C/else replace kV control board –Reinitialize system, retry. –If persistent, replace board or check power and grounding. KV control board Only if this error is repetitive and comes alone (Not following other errors), replace kV control board. 1. system communication power supply (for isolated communications) 2. system communication cable 3. system interface board 4. system interface to kV control flat cable 5. kV control board –Check communication cable –Check system communication power supply (if any) –Check system interface to kV control flat cable –replace system interface board –replace kV control board 4–27 X–RAY GENERATOR PROPRIETARY TO GENERAL ELECTRIC COMPANY CT HISPEED SERIES ADVANCED DIAGNOSTICS REV 11 2202119 Error Message/explanation code 80–060 External CAN bus off 2H Potential cause 80–090 Tube Fan supply error. 2H Rotation board has detected that a wrong voltage is applied to the tube fan 80–140 Internal CAN bus off 2H Can device on kV control board detected abnormal level on it’s 2 line and sent error to the CPU 1. No 115V tube cooling supply 2. Rotation board –Check presence of the AC voltage (DS6 neon) at the input of the Rotation board. If ok, replace the rotation board 1. kV control 2. Control bus cable 3. Heater or Rotation 80–140 Connection Fault 3H One of the flat cable connector is not connected in Generator. 80–140 FPGA configuration prob4H lem. Detected during power up. The kV control main software cannot load the FPGA. 80–140 Tank temperature sensor 5H problem. Means that t° value of the HV tank is < 10°C 80–140 Inverter temperature sensor problem (not imple6H mented). Multiple, but likely improbable. kV control board. Check a wrong contact short circuit on CAN lines, pins 5 & 6, of the control bus cable. Short circuit may be either on Boards or connector/ cable. If no fault detected, replace kV control Check connection of the following cables : kV control to system I/F board, kV control to HV tank, HV tank to inverter. Replace kV control board. kV control HV tank Replace kV control Replace HV Tank kV control Replace kV control 1. system communication power supply (for isolated communications) 2. system communication cable 3. system interface board 4. system interface to kV control flat cable 5. kV control board 4–28 Recommended action/ Troubleshooting guide –Check communication cable –Check system communication power supply (if any) –Check system interface to kV control flat cable –replace system interface board –replace kV control board X–RAY GENERATOR CT HISPEED SERIES ADVANCED DIAGNOSTICS PROPRIETARY TO GENERAL ELECTRIC COMPANY REV 11 2202119 Application errors (Code 90) Class 4 Error Message/explanation code 90–070 NV RAM checksum pb. 1H Generator kV control board has detected corruption in the NV Ram verification (After power up) 0702H Software problem. 0704H 0705H Rotation/Heater hold too long. Will pop up if preparation command from the system is maintained longer than 3 minutes. System or database configuration error The identifier of the system and the database are not compatible Potential cause 1. Database problem 2. External cause (Spikes) 3. kV control Recommended action/ Troubleshooting guide If persistent : –Reload the Data base. If no improvement : –Replace kV control board and reload the data base. 1. Software or Data Base problem. 2. kV control board failure. –Reload the Data base –Reload the software and database If no improvement : –Replace kV control board Software problem. No action 1. Database problem Download the Data base – Check system software release (OC) 4–29 X–RAY GENERATOR CT HISPEED SERIES ADVANCED DIAGNOSTICS PROPRIETARY TO GENERAL ELECTRIC COMPANY REV 11 2202119 Communication errors(code 100) not NP not NP Class 4 Error Message/explanation code 100–06 Debug screen com. error 03H 100–06 Database download error Generator has detected a 04H problem during data base download 100–06 TAV communication error. 05H Generator has detected a communication problem between the I/F and the service laptop (When Generator is controlled by the laptop) 100–06 MPC/Madrid communica06H tion error. No reply from the console. (This error message can be seen using the service laptop) 100–13 AEC board communica01H tion error. Potential cause Recommended action/ Troubleshooting guide Engineering use 1. Database file incorrect 2. Transmission problem Retry Check data base file Potential laptop incompatibility 1. Software / laptop problem 2. Cable problem Retry 1. Cable, connection problem between Generator and the console. 2. Interface board 3. Console problem –verify the console is powered . –Verify EMIT LED on the interface board. –Verify cabling, connection. –Verify communication with the service computer operates. 1. Verify cables connection 2. AEC board 3. Interface board – 4–30 X–RAY GENERATOR PROPRIETARY TO GENERAL ELECTRIC COMPANY REV 11 CT HISPEED SERIES ADVANCED DIAGNOSTICS 2202119 Thermal errors(code 110) Class 5 Error Message/explanation code 110–08 Tank Thermal Error 04H HV tank temperature measurement has reached 60 degree C for Np/Np+ or 66 degree c for Np++ 110– 0805H Inverter thermal error Potential cause 1. HV tank too hot; normal error 2. HV tank 3. kV control Software bug 110–09 70 degree C thermal safe03H ty error 70° loop detected open 1. X–ray tube too hot; normal error 2. Cooling problem 3. Wiring problem 4. Sensor problem (Tube) 5. rotation board 110– 0904H 1. HEMIT tank 2. DC Disch board (HEMIT assy) 3. Rotation board HEMIT Thermal error (only for NP++) 110–14 Jedi inverter tempera54H ture too high 1. Parameters kV, mA and time exceeded allowed use 2. software bug 4–31 Recommended action/ Troubleshooting guide –Wait for error clearance –If persistent while HV Tank is cool : 1/check LED DS1 on kV control (top and right of board). If it is off, change kV control 2/check flat cable connection between HV Tank and kV control board 3/replace HV tank 4/replace kV control Download software and database again If the problem persists, change kV control –Wait for error clearance –If persistent : 1/Check tube cooling (Fan), troubleshoot 115 volts from PDU to Fans, through Rotation board; check tube thermal sensor 2/ short circuit the sensor feedback on rotation board connector and verify that error disappears. If no, replace rotation board –Wait for error clearance –If persistent: 1/ Check 2A fuse on DC Disch 2/ Short circuit the sensor feedback of the HEMIT. If problem disappears, replace the HEMIT. 3/ Replace DC–Disch 4/ short circuit the sensor feedback on rotation board connector and verify that error disappears. If no, replace rotation board – Wait cooling time – change kv–ctrl board (if trouble always present, report to service) X–RAY GENERATOR CT HISPEED SERIES ADVANCED DIAGNOSTICS PROPRIETARY TO GENERAL ELECTRIC COMPANY REV 11 2202119 Manipulation errors(code 120) not CT not CT not CT Class 5 Error Message/explanation code 120–15 Tomo brightness not good 00H (RAD) 120–15 Release exposure switch 01H (RAD) 120–15 AEC does not cut expo02H sure (RAD) Potential cause kV not correctly set during exposure switch is released backup parameters (mAs, ...) cut exposure 4–32 Recommended action/ Troubleshooting guide change kV no action – change parameters (kV, mAs) – change AEC X–RAY GENERATOR PROPRIETARY TO GENERAL ELECTRIC COMPANY CT HISPEED SERIES ADVANCED DIAGNOSTICS REV 11 4-6 2202119 WARNING ERRORS Warning errors are the result of automated and regular background monitoring for either software events or voltages threshold overtaking. Those errors are merely for engineering usage and do not indicate any hardware error failure. However, as they are logged into the Generator Err_log file, just as the previous list of error, they are listed here to help error sorting out. Should too many of them are seen when viewing error log, it is advised to report them via CQA, since the equipment is still operating. 10 20 Rotation Warn- 0151H ing 0152H 0153H 0154H 0155H 0156H 0157H 0158H 0159H 0160H 0161H 0162H 0163H 0164H 0199H Heater Warning CAN Domain command number error CAN Domain request with no transfer init CAN Domain Toggle bit error CAN Domain : less than 2 data to download CAN Domain Abort received & applied Bad index in config upload Tube switch while Rotation not off Acceleration cmd while no tube selected Acceleration cmd while database not OK Database download while Rotation speeding Acceleration command not OK Rotation acceleration while in error No CAN message received within 4 secs Rotation Inverter overcurrent (< 3 times) Unknown rotation warning 0251H Received command is not OK 0252H 0253H 0254H 0255H 0256H 0257H 0258H 0259H 0260H 0261H 0262H 0263H Heater command not OK No CAN message received within 4 secs Heater inverter overcurrent (inverter1) (<3 times) Filament open circuit (inverter1) (<3 times) Heater Inverter short circuit (inverter1) (<3times) Tube switch while filaments not OFF CAN Domain command number error CAN Domain request with no transfer init CAN Domain Toggle bit error CAN Domain : less than 2 data to download CAN Domain Abort received & applied Database download while heater not cut 4–33 X–RAY GENERATOR PROPRIETARY TO GENERAL ELECTRIC COMPANY CT HISPEED SERIES ADVANCED DIAGNOSTICS REV 11 2202119 25 Low Voltage Power Supply Warnings 0570H 0570H 0560H 0560H 0550H 0550H 0575H 0571H 0565H 0561H 0555H 0551H 0599H 27 Application warnings 1401H No more warn –15V too low No more warn –15V too high No more warn +15V too low No more warn +15V too high No more warn +160V too low No more warn +160V too high Detected –15V too weak Detected –15V too strong Detected +15V too low Detected +15V too high Detected +160V too low Detected +160V too high Unknown LVPS warning Saved RAM power supply limit reached This message is the result of a computation that is made by the software based on the Date for a period of approximately 7 years 0703H Watchdog reset has just occurred – 1 if it often occurs, change kv–ctrl (if real reset of the board) – 2 if it always occurs, report to service 4–34 X–RAY GENERATOR PROPRIETARY TO GENERAL ELECTRIC COMPANY CT HISPEED SERIES ADVANCED DIAGNOSTICS REV 11 4-7 2202119 OTHER FAILURES Error Message / Potential cause code explanation System GENERATOR 13. No power on the does not reply Generator. to the system 14. EMC filter 15. AC/DC– Diode bridge 16. Cable between AC/ DC and LVPS 17. LVPS down 18. CAN cable problem 19. kV control 20. CT interface 21. Rotation board 22. Heater board 23. Inverter in short circuit 24. Generator to system cable. 3 phases CB1 breaker trips in PDU 2. Short circuit on the Generator : n IGBT in short circuit n ACDC or bridge rectifier in short circuit n EMC filter in short circuit Software or Data base corrupt 1. After software download: –Incorrect or uncompleted download –Checksum problem 4–35 Recommended action Troubleshooting guide Perform the troubleshooting in the following way : 1/kV control Leds S0–S7 are lit successively : refer to communication errors troubleshooting 2/Leds S0–S7 show a specific pattern : refer to PRD errors section 3/Led RESET is lit : board is maintained in reset either by the system or by a system I/F failure or kV control failure 4/Led HALT is lit : replace kV control 5/No Led is lit : verify that +5V on kV control board (J6, pin2).is present. If yes, replace kV control. If no : 6/ verify if +15V/–15V is present (Leds DS1/DS2). If yes, replace kV control. If no : 7/ Verify if +15V/–15V is present on rotation board (DS1/DS2) and the 160V is present on the heater board (DS3). If yes : check the control bus cable to the kV control board. If no error, change the kV control board. If no : 8/ Verify if the LVPS DC input is right. If no, check AC/DC fuse and input line If yes : 9/disconnect all output cables from the LVPS board. Verify the +15V/–15V/160V output. If right : reconnect each board successively to find the one stucking the 15V to ground. If wrong, replace LVPS board ( 1/ Disconnect DC bus cables between AC/DC and inverter (on AC/DC side) 2/ Check if these cables are in short circuit. If yes, replace inverter if no, 3/ Disconnect AC line cables between EMC and AC/DC (on EMC side) 4/ Check if these cables are in short circuit. If yes, replace AC/DC FRU if no : 5/ Disconnect AC line input from EMC board. Check EMC for short circuit between phases. If short circuit, replace EMC board. Retry download X–RAY GENERATOR PROPRIETARY TO GENERAL ELECTRIC COMPANY CT HISPEED SERIES ADVANCED DIAGNOSTICS REV 11 4-8 2202119 HEATING WITHOUT HV NOR ROTATION DIAGNOSTIC Purpose : The purpose of this test is to drive the heater inverter(s) on both filaments and all the tubes connected to the Generator in order to identify a faulty heater FRU or a wrong connection between heater board, HV Tank and tube(s). Pre–requisites : D kV control board alive and running : S0–S7 Leds are lit successively or a combination of them blink D heater board alive and running : DS1 and DS2 Leds are lit successively D heater DC supply present : DS3 Led is lit Test type : No manual interaction Sequence : Once selected the tube the test is running on , start the diagnostic. The following sequence runs on the small focus and then on the large focus : D 5 seconds preheat D 0,4s boost D 5s heat ( focal spot max current – 1Amp ) There is 10s stop time between each focal spot run During the test , the heater safeties are checked the same way than in application mode D Run JEDI ERROR LOG RETRIEVE to see the Error Code. Error codes reporting : Refer to the troubleshooting table 4–36 X–RAY GENERATOR PROPRIETARY TO GENERAL ELECTRIC COMPANY CT HISPEED SERIES ADVANCED DIAGNOSTICS REV 11 4-9 2202119 ROTATION WITHOUT HV NOR FILAMENT DIAGNOSTIC Purpose : The purpose of this test is to drive the rotation inverter(s) in high speed mode (for application supporting high speed mode ) and low speed mode on all the tubes connected to the Generator in order to identify a faulty rotation FRU or a faulty dephasing capacitors FRU or a wrong connection between rotation board, HEMIT (only for NP++) and tube. Pre–requisites: D kV control board alive and running : S0–S7 Leds are lit successively or a combination of them blink D rotation board alive and running : DS5 Led blinking D rotation DC supply present : DS7 neon is lit D cabling between rotation board and tube checked (including HEMIT connections for NP++ only) Test type: No manual interaction, no loop on Sequence: Once selected the tube the test is running on, start the diagnostic. The following sequence runs in low speed mode and then in high speed mode (if high speed mode allowed) : D acceleration ( time depends on tube type ) D 2s run D brake ( time depends on tube type ) There is 2s stop time between each speed mode. During the test , the rotation safeties are checked the same way than in application mode D Run ERROR LOG RETRIEVE to see the Error Code. 4–37 X–RAY GENERATOR PROPRIETARY TO GENERAL ELECTRIC COMPANY REV 11 CT HISPEED SERIES ADVANCED DIAGNOSTICS 2202119 Error codes reporting for generators without HEMIT: Refer to the troubleshooting table Error codes reporting for generators with HEMIT (only for NP++): error code associated data conclusion 0103H associated data points only to high Power–off. Check cabling. If problem, replace the 0104H speed mode rotation board. If the problem persists, replace the 0105H HEMIT tank. See note * 0106H 0107H 0109H associated data points to both high Check cabling. If problem, replace the rotation board speed and low speed mode 0111H 0112H associated data points to both high Download official data base (NPv3). If the problem speed and low speed mode persists, change rotor. 40– HV cable short circuit error There is a short circuit in the High voltage line between Open circuit on: Hemit and tube. The actions are: 0114H – Tube stator – Check HV cable impedance (Hemit ST to Tube +) – Hemit secondary – Change tube –Anode HV cable – Change Hemit • Or bearings of tube broken (**). 40– HV cable open error There is an open circuit in the High voltage line 0115H between Hemit and tube. The actions are: – Check HV cable connection and impedance – Check tube stator impedance – Check Hemit secondary impedance. Replace HEMIT if open. For the other error codes, refer to the troubleshooting table *Note: Before replacing the rotation board, check the impedance of the primary and secondary of the HEMIT. In order to do a correct measure, check before the impedance of the cables of the multimeter. • The impedance of the primary is measured between two pins of the connector J1 of the Bouchon board in the HEMIT (3 measures). The value is low, between 0.8 ohm and 1.6 ohm. • If the impedance is too low (short –circuit) replace the HEMIT • If the impedance is too high (open circuit) replace the HEMIT • The impedance of the secondary. Measure between two pins of the HV connector marked as “ST”. (large, small and common). For the three measures the value should be between 0.8 ohm and 1.6 ohm. • If the impedance is too low (short –circuit) replace the HEMIT • If the impedance is too high (open circuit) replace the HEMIT 4–38 X–RAY GENERATOR PROPRIETARY TO GENERAL ELECTRIC COMPANY CT HISPEED SERIES ADVANCED DIAGNOSTICS REV 11 2202119 4-10 HV POWER DIAGNOSTICS 4-10-1 Inverter Gate Command Diagnostic Purpose : The purpose of this test is to verify that the HV power inverter drive is working properly. The IGBTs gate drive supply and the IGBTs gate drive is verified. At the same time verification is made that no inverter currents nor High voltage are measured. This test is performed without DC voltage applied to the inverter so that no Xray is generated. Anode rotation and filament drive are not activated during this test. Pre–requisites : D Generator input line in an acceptable range ( 380V–10% to 480V+10% for 3–phase AC input ) D kV control board alive and running : S0–S7 Leds are lit successively or a combination of them blink D inverter gate_cmd board DC supply present : DS300 neon is lit Test type : Manual operation is required. Sequence : 1/ Disconnect the 2 DC bus cables from the AC/DC board ( see central listing ) 2/ Power on the Generator 3/ Push the TGP board reset switch, or OGP board reset switch. 4/ Verify that the DS1 neon on inverter dual snubbers board is not lit 5/ Start the diagnostic and verify : – error reported on the operator console – inverter gate_cmd board Leds DS101, DS 102, DS201, DS202 are lit : IGBTs gate drive supply is working properly 6/ Press the exposure switch (10s exposure is taken after 10 sec delay) 7/ During the “exposure”, verify : – error reported on the operator console – inverter gate_cmd board Leds DS100 and DS200 are lit : IGBTs gate drive is working properly 8/ Release the exposure switch 9/ Run ERROR LOG RETRIEVE to see the Error Code. 10/ Power off the Generator 11/ Reconnect the 2 DC bus cables from the AC/DC board (see central listing ) 4–39 X–RAY GENERATOR PROPRIETARY TO GENERAL ELECTRIC COMPANY CT HISPEED SERIES ADVANCED DIAGNOSTICS REV 11 Error reporting : error DS1 neon lit DS300 neon off 0301/ 0302/ 0303/ 0304/ 0309/ 0310/ 0311/ 0312/ 0313/ 0314/ 0319/ 0323 (H) 0320 0501 0503 0504 one of DS101/DS102/DS201/DS202 Leds off while no error reported DS100 and/or DS200 Leds off 2202119 Conclusion Check that DC bus cables have been removed Check the gate_cmd supply cable between AC/DC and gate_cmd board Check that DC bus cables have been removed. If yes, replace kV control board if problem persists, replace Kv control board kV control or inverter fault, replace inverter first kV control or inverter fault, replace inverter first kV control or inverter fault, replace inverter first Replace inverter Check cabling between kV control, HV Tank and gate_cmd board. If cabling is right, kV control or inverter fault, replace inverter first 4–40 X–RAY GENERATOR PROPRIETARY TO GENERAL ELECTRIC COMPANY CT HISPEED SERIES ADVANCED DIAGNOSTICS REV 11 2202119 4-10-2 Inverter in Short Circuit Diagnostic Purpose : The purpose of this test is to verify that the HV power inverter is working properly. The inverter is commanded at a fixed frequency and is loaded with a short circuit. Verification is made that the inverter currents are correctly set. . At the same time verification is made that no High voltage is measured. This test is performed without connecting the HV Tank to the inverter so that no Xray is generated. Anode rotation and filament drive are not activated during this test. Pre–requisites : D Generator input line in an acceptable range ( 380V–10% to 480V+10% for 3–phase AC input ) D kV control board alive and running : S0–S7 Leds are lit successively or a combination of them blink D inverter gate_cmd board DC supply present : DS300 neon is lit D inverter dual snubber board DC supply present : DS1 neon is lit D Inverter gate command diagnostic passed without failure Test type : Manual operation is required. 4–41 X–RAY GENERATOR PROPRIETARY TO GENERAL ELECTRIC COMPANY CT HISPEED SERIES ADVANCED DIAGNOSTICS REV 11 2202119 Sequence : 1/ Disconnect the HV Tank primary cables from the inverter ( see HV Tank D/R job card ). Take care not to disconnect at the same time the parallel inductor cable which is tightened with the HV Tank primary cables Put the short circuit cable (included in the first aid kit ) between the the two capacitors as shown (in red, the cable): (NP++ Configuration) Parallel inductor 4–42 X–RAY GENERATOR PROPRIETARY TO GENERAL ELECTRIC COMPANY CT HISPEED SERIES ADVANCED DIAGNOSTICS REV 11 2202119 (NP/NP+/ESR Configuration) Parallel inductor 1/ The parallel inductor must be connected 2/ Power on the Generator 3/ Push the TGP board reset switch, or OGP board reset switch. 4/ Verify that the DS1 neon on inverter dual snubbers board is lit 5/ Verify that the DS300 neon on inverter gate_cmd board is lit 6/ Start the diagnostic and verify that no error is reported on the operator console 7/ Press the exposure switch (500ms exposure is taken) 8/ Release the exposure switch 9/ verify error reported on the console 10/ Run ERROR LOG RETRIEVE to see the Error Code. 11/ After exiting the test, power off the Generator 12/ Remove the short circuit cable, reconnect the HV Tank primary cables ( see HV Tank D/R job card ). Verify that the parallel inductor cable is connected. 4–43 X–RAY GENERATOR PROPRIETARY TO GENERAL ELECTRIC COMPANY CT HISPEED SERIES ADVANCED DIAGNOSTICS REV 11 Error reporting : error DS1 neon off DS300 neon off 0301/ 0302/ 0303/ 0304/ 0309/ 0310/ 0319 (H) 0311 0312 0313 0314 0320 0323 0501 0503 0504 0505 2202119 Conclusion Check that DC bus cables between AC/DC and inverter Check the gate_cmd supply cable between AC/DC and gate_cmd board Check that HV Tank primary cables have been removed. If yes, replace kV control board No Ilp current detected. See note 2 No Ilr current detected. See note 3 replace kV control board Ilr current resonant frequency is lower than expected. See note 4 if problem persists, replace kV control board Both Ilr and Ilp currents not detected. See note 1 kV control or inverter can be faulty kV control or inverter can be faulty kV control or inverter can be faulty Isolation fault between inverter components and ground. Check inverter inductors. If no faulty component, kV control or inverter can be faulty Note 1 : Ilp and Ilr currents not detected 1/ Check the –15V (Led DS1) on kV control board (see central listing). If it is not lit, refer to “other failures” section. Else : 2/ Power off the Generator. Wait until all neons are off 3/ Check that the currents transformers (capacitor set) to gate_cmd board cable is correctly connected. If yes : 4/ Check that the inverter inductors are correctly connected. If yes : 5/ Check that HV Tank is correctly connected to the capacitors set. If yes : 6/ Check that the gate_cmd to HV Tank cable and HV Tank to kV control cables are correctly connected. If yes, replace the inverter 7/ Reconnect all the cables Note 2 : Ilp current not detected 1/ Power off the Generator. Wait until all neons are off 2/ Check that the parallel inductor is correctly connected. If yes : 3/ Check that the parallel inductor impedance is 0 Ohms. If no : replace inverter. If yes : 4/ Check that inverter capacitors (capacitors set) are not broken. If yes, replace the capacitor set. Else : 5/ Disconnect the currents transformers to gate_cmd board cable. Check that the parallel current transformer impedance is 0. If no : replace the capacitor set. Else : 6/ Check that the gate_cmd to HV Tank cable and HV Tank to kV control cables are correctly connected. If yes : 7/ Disconnect the HV Tank to kV control cable. Check that the impedance between pin20 and pin21 of J2 of HV Tank is 3,3Ohms. If no replace the inverter. If yes : replace kV control board. 8/ Reconnect all the cables 4–44 X–RAY GENERATOR PROPRIETARY TO GENERAL ELECTRIC COMPANY CT HISPEED SERIES ADVANCED DIAGNOSTICS REV 11 2202119 Note 3 : Ilr current not detected 1/ Power off the Generator. Wait until all neons are off 2/ Check that the inductors are correctly connected. If yes : 3/ Disconnect the currents transformers to gate_cmd board cable. Check that the serial current transformer impedance is 0. If no : replace capacitor set. Else : 4/ Check that inverter capacitors (capacitors set) are not broken. If yes, replace the capacitor set. Else : 5/ Check that the gate_cmd to HV Tank cable and HV Tank to kV control cables are correctly connected. If yes : 6/ Disconnect the HV Tank to kV control cable. Check that the impedance between pin20 and pin21 of J2 of HV Tank is 5 Ohms. If no replace inverter. If yes : replace kV control board. 7/ Reconnect all the cables Note 4 : Ilr current resonant frequency is lower than expected 1/ Power off the Generator. Wait until all neons are off 2/ Check that the inductors are correctly connected. If yes : 3/ Check that inverter capacitors (capacitors set) are not broken. If yes : replace the capacitor set. Else : 4/ Disconnect the currents transformers to gate_cmd board cable. Check that the parallel current transformer impedance is 0. If no : replace the capacitor set. Else : replace kV control board. 5/ Reconnect all the cables 4-10-3 No Load HV Diagnostic without Anode Rotation nor Filament Heating Purpose : The purpose of this test is to verify that the HV power inverter and HV tank are working properly. The exposure is taken as in application mode except that no filament drive nor anode rotation is running. Verification is made that the inverter currents are correctly set and that kV regulation is operating properly. As no filament drive is applied, no XRays are generated. This test also allow to separate Generator from HV cable or x–ray tube problem by running it with or without the HV cables plugged on the HV tank. (*) Pre–requisites : D Generator input line in an acceptable range ( 380V–10% to 480V+10% for 3–phase AC input ) D kV control board alive and running : S0–S7 Leds are lit successively or a combination of them blink D inverter gate_cmd board DC supply present : DS300 neon is lit D inverter dual snubber board DC supply present : DS1 neon is lit D Inverter gate command diagnostic passed without failure D Inverter in short circuit diagnostic passed without failure D (*) HV receptacles must be filled with oil if HV cables are removed. Test type : Manual operation is required. 4–45 X–RAY GENERATOR PROPRIETARY TO GENERAL ELECTRIC COMPANY REV 11 CT HISPEED SERIES ADVANCED DIAGNOSTICS 2202119 Sequence : 1/ Power on the Generator 2/ Push the TGP board reset switch, or OGP board reset switch. 3/ Start the diagnostic and verify : – error reported on the operator console – inverter gate_cmd board Leds DS101, DS 102, DS201, DS202 are lit : IGBTs gate drive supply is working properly 4/select kV (Default = 80 kV) and exposure time (Default = 1 sec.) 5/ Press the exposure switch (500ms exposure is taken) 6/ During the “exposure”, verify : – error reported on the operator console 7/ Release the exposure switch 8/ Run ERROR LOG RETRIEVE to see the Error Code. 9/ Power off the Generator Error reporting : See troubleshooting table 4–46 X–RAY GENERATOR CT HISPEED SERIES ADVANCED DIAGNOSTICS PROPRIETARY TO GENERAL ELECTRIC COMPANY REV 11 2202119 4-11 TROUBLESHOOTING AIDS Illustration 4–1 Generator Visual Power Supply Distribution L: Neon’s Z: LED’s DC bus, 400 ...800 V. L Heater board DC bus, 400 ...800 V. DS 1 DS 3 Z +M – INVERTER. & LLC.circuit L DC bus, 160V (120 to 200 V). +15 V – 15 V F1 DS 1 Gate command board DS 300 LVPS L NE 1 L AC/DC NP I/F DS 1 , 2 –15v, +15v kV ctrl “VCC“ + 5 V Z DS 2 +15 V – 15 V ZZ OGP 12V ≅ ZZZ DS 3, 2, 1 +5, –15, +15 +15 V – 15 V + – Rotor Board L DS 7 L DS 6 EMC Flt. 3ph, 380 – 480VAC C B 1 DC Disch (HEMIT assy) Z DS1 (only for NP++) K1 ZDS2 PDU 4–47 115V AC ZDS3 LDS4 X–RAY GENERATOR PROPRIETARY TO GENERAL ELECTRIC COMPANY blank CT HISPEED SERIES ADVANCED DIAGNOSTICS 2202119 4–48 X–RAY GENERATOR CT HISPEED SERIES ADVANCED DIAGNOSTICS PROPRIETARY TO GENERAL ELECTRIC COMPANY REV 5 2202119 FUNCTIONAL DIAGRAM TABLE OF CONTENTS SECTION PAGE SECTION 1 – EMERGENCY . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 1–1 SECTION 2 – SAFETY LOOP . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 2–1 SECTION 3 – GANTRY ROTATION . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 3–1 SECTION 4 – TILT FWD/BWD . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 4–1 SECTION 5 – CRADLE IN/OUT . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 5–1 SECTION 6 – IMS IN/OUT . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 6–1 SECTION 7 – TABLE UP/DOWN . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 7–1 SECTION 8 – AUTO VOICE . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 8–1 FUNCTIONAL DIAGRAM i CT HISPEED SERIES ADVANCED DIAGNOSTICS PROPRIETARY TO GENERAL ELECTRIC COMPANY blank FUNCTIONAL DIAGRAM 2202119 ii CT HISPEED SERIES ADVANCED DIAGNOSTICS PROPRIETARY TO GENERAL ELECTRIC COMPANY REV 5 2202119 SECTION 1 – EMERGENCY PDU GANTRY 24V RMT CNT BD FRONT RIGHT TGP BD CN3 J2 1 Safety Loop J4 E–OFF SW CN2 1 3 3 2 6 6 K11 2 REAR LEFT REAR RIGHT FCV BD RSW BD K15 EMRGL3 CN3 CN1 CN2 0 0 1 1 1 2 J1 1 FRONT EMRG–R U145 J3 6 5 3 CN8 4 CN1 0 0 1 1 LSW BD CN1 CN4 OC 0 1 1 1 2 FRONT EMRG–L EMRGL4 6 REAR CN1 PANEL 5 3 4 J15 CN9 J10 Thermal SW 1 2 Thermal SW 1 2 J17 A20 0 1 0 1 RCV BD A19 CN1 CN10 KEYBOARD EMRG SW FUNCTIONAL DIAGRAM 1–1 CN10 1 1 2 2 CN2 0 REAR SW OPTION PROPRIETARY TO GENERAL ELECTRIC COMPANY blank FUNCTIONAL DIAGRAM CT HISPEED SERIES ADVANCED DIAGNOSTICS 2202119 1–2 PROPRIETARY TO GENERAL ELECTRIC COMPANY CT HISPEED SERIES ADVANCED DIAGNOSTICS REV 5 2202119 SECTION 2 – SAFETY LOOP OC Rear CN1 w/Panel RMT CNT BD Assy J3 J15 9 9 10 10 J1 J2 A25 4 1 PDU A25 DBPCI J3 Driver Resister PCI Back Plane TGP BD Assy BP Controller Card CN2 1 PCI Host Card 4 (CN23) HOST CPU GANTRY FUNCTIONAL DIAGRAM 2–1 Safety Loop 1 4 (CN24) 1 4 PROPRIETARY TO GENERAL ELECTRIC COMPANY blank FUNCTIONAL DIAGRAM CT HISPEED SERIES ADVANCED DIAGNOSTICS 2202119 2–2 CT HISPEED SERIES ADVANCED DIAGNOSTICS PROPRIETARY TO GENERAL ELECTRIC COMPANY REV 5 2202119 SECTION 3 – GANTRY ROTATION (*1) CN2 TGP BD ASSY CN10 0 1 2 3 4 5 6 7 8 9 10 11 12 13 14 15 16 CN5 To OC Signal Brush DGCOM–H DGCOM–L GDCOM–H GDCOM–L 2 14 3 15 CN7 GDTRIG–H GDTRIG–L 4 5 SUB BD ASSY CN2 CN5 0 1 2 3 4 5 6 7 8 9 10 11 12 13 14 15 16 CN1 0 1 2 3 4 5 6 7 8 9 10 11 12 13 14 15 16 17 18 19 OGP SERVO AMP 0 1 2 3 4 5 6 7 8 9 10 11 12 13 14 15 16 17 18 19 CN1 A B C D G F H J K L M T S R CN2 1 2 3 4 5 6 7 8 9 10 11 12 13 14 (*1) BRK u v w N L CN1 CN13 1 2 3 CN14 ROTATE 3 4 3 4 1 2 NF3 3 4 3 4 1 2 CN6 1 2 3 4 1 2 3 CN7 Rotate Counter 1 2 3 4 CN8 1 2 Cover SW Assy BUZZER FUNCTIONAL DIAGRAM SERVO MOTOR 1 2 OPT SW Encoder 1C–BRK2 3–1 From PDU 200V PROPRIETARY TO GENERAL ELECTRIC COMPANY blank FUNCTIONAL DIAGRAM CT HISPEED SERIES ADVANCED DIAGNOSTICS 2202119 3–2 PROPRIETARY TO GENERAL ELECTRIC COMPANY REV 5 2202119 SECTION 4 – TILT FWD/BWD FUNCTIONAL DIAGRAM CT HISPEED SERIES ADVANCED DIAGNOSTICS 4–1 PROPRIETARY TO GENERAL ELECTRIC COMPANY blank FUNCTIONAL DIAGRAM CT HISPEED SERIES ADVANCED DIAGNOSTICS 2202119 4–2 CT HISPEED SERIES ADVANCED DIAGNOSTICS PROPRIETARY TO GENERAL ELECTRIC COMPANY REV 5 2202119 SECTION 5 – CRADLE IN/OUT FCV SW BD Front/Right CN1 S7 S8 S9 OUT TEMP+5V OUT_R TGP CN1 CN4 28 11 28 11 K1 FAST FAST 12 12 IN IN_R 10 10 TBL BD CN8 34 36 +5V IN 34 36 19 16 20 18 35 37 OUT_R SWEN5V FAST IN_R GND 19 16 20 18 35 37 CN1 TP µp CN1 TBL CONT BD CN2 CN1 CN9 16 STEPSEL 16 6 CDPLSA 6 6 CDPLSA 18 CONTPLS 18 7 CDPLSB 7 7 CDPLSB 19 CINPLS 19 8 CDPLSC 8 8 CDPLSC ENCODER E 1 +5V 4 DGND 6 SGND SW BD Front/Left CN3 CN1 S7 S8 OUT CN3 TEMP+5V OUT_R 28 11 28 11 FAST 12 12 A/D FAST 4 CPPOT–H 4 21 CPPOT–H 21 1 CPPOT–H 5 CPPOT–M 5 22 CPPOT–M 22 2 CPPOT–M 6 CPPOT–L 6 23 CPPOT–L 23 3 CPPOT–L C–POT 4 S9 IN IN_R 10 10 LATCH SW COUTENC CINENC CN8 SW BD Rear/Right RCV CN1 S7 S8 S9 S10 OUT TEMP+5V OUT_R CN1 CN4 28 11 28 11 K1 K2 FAST FAST 12 12 IN_R 10 10 RENBL 26 14 26 14 IN RENBL CN9 34 36 +5V IN 19 16 20 18 35 37 OUT_R SWEN5V FAST IN_R DGND 34 36 19 16 20 18 35 37 28 LATCH 28 24 ONLACH 24 26 CDPLS–A 26 27 CDPLS–B 27 12 14 13 15 +5V +5V DGND DGND 12 14 13 15 5 Latch SW 5 S8 21(23) DGND 20(22) +5V TEMP+5V OUT_R CN3 28 11 28 11 GDTRIG OUT 21(23) 20(22) CN1 1 2 3 4 5 6 7 8 CINPLS–H CINPLS–L COUTPLS–H COUTPLS–L HOFF–H HOFF–L STEPSEL–H STEPLEL–L 12 1 A 2 B 3 A 4 B CN3 CN5 1 GND 12 2 24V PS1 S9 IN To OGP – IN_R 10 10 +S 26 14 –S RENBL 26 14 L + S10 RENBL From/To OC FUNCTIONAL DIAGRAM LEFT CN2 1 2 3 4 5 6 7 8 4 16 2 14 3 15 FAST FAST 5 Latch SW K3 Stepping Motor Driver SW BD Rear/Left S7 RIGHT 25 CN3 CN1 4 +5V 5–1 CRADLE–H –L OGCOM–H –L GOCOM–H –L N AC115V MOTOR M PROPRIETARY TO GENERAL ELECTRIC COMPANY blank FUNCTIONAL DIAGRAM CT HISPEED SERIES ADVANCED DIAGNOSTICS 2202119 5–2 CT HISPEED SERIES ADVANCED DIAGNOSTICS PROPRIETARY TO GENERAL ELECTRIC COMPANY REV 5 2202119 SECTION 6 – IMS IN/OUT SW BD Front/Right FCV BD CN1 S7 S9 S10 OUT IN CN4 TEMP+5V OUT_R 28 11 28 11 IN_R 10 10 IMS_R 26 14 26 14 IMS TGP BD CN1 TBL BD CN8 34 36 19 18 22 16 35 37 +5V IN +5V IN OUT_R IN_R IMS_R SWENBL GND GND CN1 34 36 19 16 20 18 35 37 Servo Amp CN1 8 9 10 11 12 13 14 15 29 32 33 IPPOT–H IPPOT–M IPPOT–L IMSALM IMSSVE ALMRST IINPLS IOUTPLS TBLSEL IMSPLS–A IMSPLS–B CN4 8 9 10 11 12 13 14 15 29 32 33 0 1 2 3 4 5 6 7 8 9 IINPLS–H IINPLS–L IOUTPLS–H IOUTPLS–L AMP+5V ALARM SVE–H SVE–L ALMPST SGND 0 1 2 3 4 5 6 7 8 9 CN2 CN39 SW BD Front/Left CN1 S7 S9 IN CN3 TEMP+5V OUT_R 28 11 28 11 IN_R 10 10 IMS_R 26 14 26 14 IMS CN38 CN4 1 2 3 4 1 2 3 M IMS MOTOR CN2 12 13 or or 2 3 4 9 10 11 25 26 27 14 15 IMSPLS–C IMSPLS–A IMSPLS–B IPPOT–H IPPOT–M IPPOT–L +5V DGND S10 OUT 9 10 11 12 or 14 CN1 CN4 Touch SW Right (IMS) CN42 1 3 4 6 CN6 1 1 2 3 4 1 2 3 7 8 IPPOT–L IPPOT–M IMPOT–H IMS POT. 2 3 CN44 1 3 4 6 Touch SW Left (IMS) CN10 1 2 3 4 5 6 CN45 1 3 4 6 CN7 1 2 3 7 8 CN47 1 3 4 6 TBL CONN BD FUNCTIONAL DIAGRAM 6–1 +5V IMSPLS–B IMSPLS–A DGND IMSPLS–C SGND E IMS ENCODER PROPRIETARY TO GENERAL ELECTRIC COMPANY blank FUNCTIONAL DIAGRAM CT HISPEED SERIES ADVANCED DIAGNOSTICS 2202119 6–2 CT HISPEED SERIES ADVANCED DIAGNOSTICS PROPRIETARY TO GENERAL ELECTRIC COMPANY REV 5 2202119 SECTION 7 – TABLE UP/DOWN SW BD Front/Right FCV BD CN1 S6 S11 UP TEMP+5V UP_R TGP CN4 28 16 28 16 CN1 K1 DOWN DOWN_R 17 17 SUB BD CN8 34 36 +5V IN 34 36 24 16 25 35 37 UPR SWEN5V DOWNR GND 24 16 25 35 37 CN10 CN2 CN4 RTN AC115V µP 28 UPE 28 29 DNE 29 UP 26 UP 26 DN 27 DN 27 17 DNTSW 17 23 DNTCH 23 14 +5V 14 15 GND 15 20 +24 20 4 3 RTN AC115V K19 2 1 V TABLE VALVE P TABLE PUMP K18 SW BD Front/Right CN1 S6 S11 UP TEMP+5V UP_R CN3 28 16 28 16 DOWN DOWN_R 17 17 21 SW BD Rear/Right(Option) S11 S10 UP TEMP+5V UP_R 28 16 CN1 K1 RearEnable +5VSW RENBL 17 26 14 CN9 34 36 K2 24 16 25 35 37 DOWN DOWN_R K7 K15 21 17 26 14 +5V IN UPR SWEN5V DOWNR GND CN11 34 36 24 16 25 35 37 A/D CN1 0 1 2 HPOT–H HPOT–M HPOT–L 0 1 2 20 22 +5V 20 22 21 23 DGND 21 23 CN1 AC115V RTN TBL BD CN4 28 16 GND RCV BD CN1 S6 K12 Table/Tilt 6 8 PDU SW1 TBL CONN BD CN2 CN1 17 18 19 CN5 17 18 19 HPOT–H HPOT–M HPOT–L 1 2 3 1 SGND 4 3 H–POT 2 CN6 4 5 6 Touch Sensor 4 5 6 Touch Sensor CN7 SW BD Rear/Right(Option) CN1 S6 UP TEMP+5V UP_R CN3 28 16 28 16 CN8 S11 S10 DOWN DOWN_R RearEnable +5VSW RENBL FUNCTIONAL DIAGRAM 17 17 26 14 26 14 36 7–1 36 0 13/15 1 0 13/15 1 DNTCH1 DGND DNTSCON 1 2 3 6 1 2 3 4 1 2 3 4 Touch Sensor R L PROPRIETARY TO GENERAL ELECTRIC COMPANY blank FUNCTIONAL DIAGRAM CT HISPEED SERIES ADVANCED DIAGNOSTICS 2202119 7–2 CT HISPEED SERIES ADVANCED DIAGNOSTICS PROPRIETARY TO GENERAL ELECTRIC COMPANY REV 5 2202119 SECTION 8 – AUTO VOICE Rear CN1 Host CPU (O2) Key Board J17 A13 B9 J5 System Module Key BD KBMIC KBMIC RTN TALK ON KB MIC B9 B10 Foot Switch J16 Hard Disk Audio Modulu Low Pass Filter J6 Audio L In R 3 1 1 2 3 NC NO NAA1 Assy J7 Audio L Out R AUTO VOICE 3 1 CN2 J9 1 Low Pass Filter 2 3 Low Pass Filter 4 LEFT LEFT RTN RIGHT RIGHT RTN PreAmp 1 CN1 1 2 OC Speaker SP+ SP– 2 3 4 TGP BD NAA2 Assy FCV BD 6V CN5 J14 DBPCI A5 A6 X–RAY ON ALERT ON A21 A21 Tone Gen. IC Tone Gen. IC Elec. Volume J1 J4 8 9 10 11 12 13 22 23 24 25 PAT SPK PAT MIC +12V +12V +12V +12V +12V RTN +12V RTN +12V RTN +12V RTN CN6 CN4 8 9 10 11 12 13 22 23 24 25 1 2 Audio +12V Out Audio GND Out MIC OUT LOUT+ LOUT– THI IN+ THI IN– SPI+ SPI– B7 A7 B5 A5 B2 A2 CN1 CN9 CN3 PreAmp 1 2 3 MIC OUT 38 39 1 2 TBL BD FUNCTIONAL DIAGRAM 8–1 CN7 3 1 4 Mic. RCV BD 38 39 CN7 1 2 3 PreAmp SPI+ SPI– CN11 1 2 3 CN1 CN6 6 7 10 11 16 17 CN8 CN2 1 2 CN40 1 2 Table Speaker 1 2 3 CN7 3 1 4 Mic. PROPRIETARY TO GENERAL ELECTRIC COMPANY blank FUNCTIONAL DIAGRAM CT HISPEED SERIES ADVANCED DIAGNOSTICS 2202119 8–2 GE Medical Systems: Telex 3797371 P.O. Box 414, Milwaukee, Wisconsin 53201 U.S.A. (Asia, Pacific, Latin America, North America) GE Medical Systems – Europe: Telex 698626 283, rue de la Miniére, B.P. 34, 78533 Buc Cedex, France