Transcript
USER GUIDE
NAVISET GT-‐20 NAVISETGT-‐10 NAVISETGT-‐10 IRIDIUM Navigation Terminals
1. APPLICATION Navigation terminals “NAVISET” is designed to monitor the location of a mobile object, the data of fuel consumption and other telemetry (a state of inputs, data of digital interfaces and etc.), to transmit to the collection server. Terminal NAVISET is a solution for the most demanding users, designed for application to control vehicles, fuel consumption, security and etc. The universal interface allows integrating the device to any third-party software. Terminal NAVISET records data of coordinates and telemetry in the memory and transmits them to a data collection and processing server at specified period of time using the GPRS network of any GSM provider via the Internet. Unsent data to the server are stored in a non-volatile memory of the device («a black box») so even at complete discharge of the reserve storage battery; they will be stored and be transferred at switching on.
2. MODIFICATION Terminal NAVISEThas 3 modifications: UniversalGLONASS/GPS/GSMterminalisadeviseforthemostde mandingusers, designed for application to control vehicles, fuel NAVISETGT-20 consumption and security and hasan unsurpassed functional set. The devise allows to define location of the vehicle, to control fuel consumption, to protect the vehicle and to use the alarm button. The voice menu is convenient for control of external devices in real time. Data of the CAN bus of the car and of the connected camcorder are read out automatically. It is in addition possible to connect temperature sensors and to use TM keys for identification of drivers.
NAVISET GT-10 NAVISET GT-10 IRIDIUM
The universal hybrid GLONASS/GPS/GSM terminal, inheriting the functional capabilities of NAVISET GT20, has restrictions in the hardware (less inputs, built-in memory, absent of the slot for the SD memory and the internal interface connector) and the internal GSM antenna. Modification with support of IRIDIUM has the internal satellite transceiver for the IRIDIUM networks that allows to stay in touch in a zone of absence of a GSM networks covering and to transmit data directly through the satellite channel communication.
3. THE SPECIAL FEATURE: With NAVISET device you can easily use the following options and get all the information in real time: ■ Location of your vehicle ■ Control of fuel consumption ■ Connection of analog, digital and pulse sensors ■ Vehicle security ■ Alarm button + driver indentification ■ Voice communication with a driver (HF-1) + Chat with a driver (GARMIN + FMI interface) ■ Voice menu for external device control ■ Standard alarm option ■ Data of CAN (optionally K(L)-Line of vehicle buses ■ Snapshots of USB or RS232 camcorder ■ Built-in odometer ■ Temperature of 8 sensors ■ I-Button ■ Possibility to move abroad without GPRS roaming ■ Configuration and software update via USB or remotely via GPRS ■ GPRS or SMS operating ■ Connection a big variety of the periphery (tachographs, non-standard sensors)
3. BASIC ADVANTAGE: The main advantage of NAVISET navigation terminal is multi-functionality and accessibility to everyone: ■ Unique configuring technology of internal devise logic: events, timers, control and sending data based on condition execution, the floppy logic, allowing to coordinate all devise functions in the one logical concept. ■Present of 2 SIM cards allows to be sure of a communication stability with a device and to avoid expensive GPRS roaming in case of a location out of a mobile operator coverage area and in case of full absence of a GSM networks covering, modification of GT-10 Iridium transmit data directly through the satellite channel communication. ■ Due to the voice menu, you can easily control the engine operation, communicate with a driver, start the enginesand control arming and disarming moment. ■ Configuration and software update via USB interface or via the GPRS connection through the configuration program ■ Immunity supply voltage and voltage overloading is achieved using high-voltage regulator for current up to 2,5A, in conjunction with the two-level protection at the input. The supply voltage can get up to 60V in a standard mode and to 600V in pulse. ■ Monoblock version enhances reliability ■ Several operating modes to optimize date transmission expenses ■ Long operation period because of application of the original hardware components Our company has many years of experience, is keeping up to date and constantly expands the product functionality. All changes and innovations are reflected on our site.
5. Specification SPECIFICATION Supply voltage, V (constant current) Protection of exceeding input voltage, V Protectionof input voltage transient, V Current consumption at a power supply voltage of 12 V peaked, in a registration and call mode average, in an operating mode of server connection average, in an operating mode of server connection, battery charge Back up battery Peak current of output circuit load, А Maximum length of a loop 1-Wire, m Reaction time of the button (sensor), msec Quantity of inputs: input for a frequency measurement of a meander input for a pulse counting analog input0-5V analog input0-36V discrete cut off input buswire1-Wire Quantity of outputs (open collector) Quantityofdigitalinterface RS-232interface RS-485 interface CAN interface Quantity of SIM card Voice interface for PTT connection Voice Bluetooth Voice menu Sensor of space position change(accelerometer) The temperature measurement sensor inside the device «Black box» for storage of event logs, snapshots and sound files Interface for communication with the PC Automatic updates via GPRS Configuration GSM chip WiFi chip SATELITE chipIridium GPS/GPS+GLONASS chip Indicator of GSM, GLONASS, power, operation, № SIMcard Antenna connector Data-transfer time, sec Slot less RTC (real time clock) Transmitter frequency range, mHz Average operating time of storage battery, hours Temperature range, °C Operability, altitude Humidity Overall size, мм
GT-‐20
GT-‐10
GT-‐10 IRIDIUM
7,5…50 55 600 1000 1350 150 173 170 175 Li-Po 1100mA 3х1, 1х0,5 10 50 8 2 2 2 8 8 1 4 2 2 1 1 2 + optionally + + + 650000 174000 points points USB 2.0 + USB/GPRS SIM900R optionally SBD9603 MSSG2217 + SMA 20-60 optionally 900/1800 8 - 40 … + 85 0-9999 0...90% (0...35 °C); 0...70% (35...55 °C) 150х65х29
6. ASSIGNMENT OF INTERFACES AND DESCRIPTION OF OUTPUTS 6.1 NAVISETGT-‐20 DEVICE The device is in a plastic case with a mounted possibility on clamps, with an efficient microcontroller and GSM modem. The microcontroller completes all actions for the collection and processing the signals. All electronic components are placed on the printed circuit board, mounted to the base. All interface contacts are involved and have the following significance: The following interfaces are presented in Figure 1: (1) -‐ Connector of GSM antenna, SL-‐S3-‐SMA-‐FEMALE type (2) – Connector of GLONASS, GPS or GLONASS / GPS antenna, SMA-‐FEMALE type (3) -‐ Status indicators of the device operation and the selected SIM card. Descriptions of the status see Table 5. (4) – Interface connector for power supply and peripheries. Figure 2. Switching the digital interfaces with a help of SW1 is described in Table 4. (5) -‐ The connector of the computer USB interface for configuring, change of firmware.
Figure 1.Description of interfaces
Figere 2.Contactor description of the interface connector Connection of power, sensors and other periphery is carried out through interface connector (4) Figure 2. For this use the mating connector with connected wires to appropriate contacts. More inforemation see in descriptionofcontactorfunctions (Table 2).All contacts of interfaces are involved and have the following functional: Table 2.Descriptionofcontactorfunctions Contactor +12V GND IN1 IN2 IN3 IN4 IN5 IN6 IN7 IN8 TX2/CAN-‐H RX2/CAN-‐L TX1/485-‐A RX1/485-‐B OUT1
Functionalarea Power input for connection to car's lighter socket General power wire Analog/discrete input 0-‐5В, 0-‐36V, frequency (meander) of 0 to 10 kHz Analog/discrete input 0-‐5В, 0-‐36V, frequency (meander) of 0 to 10 kHz Analog/discrete input0-‐36V Analog/discrete input0-‐36V Analog/discrete input0-‐36V Analog/discrete input0-‐36V, button of operator call Analog/discrete input0-‐36V, arming/disarming Analog/discrete input0-‐36V, control the ignition RS232 interface or CAN line. The selection by the SW-‐1 switching RS232 interface or CAN line. The selection by the SW-‐1 switching RS232 or RS485 interface. The selection by the SW-‐1 switching RS232 or RS485 interface. The selection by the SW-‐1 switching PGM output -‐ impedance,closed-‐loop, inversion
OUT2
PGM output -‐ impedance, closed-‐loop, inversion
OUT3
PGM output -‐ impedance, closed-‐loop, inversion
OUT4
PGM output -‐ impedance, closed-‐loop, inversion
EXT SPEAK SKP OUT 1-‐WIRE GND EXT IND MIC
Output of voice informer Output to a dynamic of external garniture (HF-‐1) Input for TM and temperature sensor connection General input for external garniture (HF-‐1) Status display of signal communication via external garniture, Call-‐Button is applied with using garniture HF-‐1 Input for microphone connection of external garniture (HF-‐1)
Input universal circuits are intended for connection of analog, impulse, discrete sensors. All inputs are classified by an executed functionality (table 3).
Table 3 -‐ The contactor functions Functional area/ Inputs
Analog mode, the measurement voltage 0-36V Analog mode, the measurement voltage 0-5V Frequency Impulse, accumulation of impulses(меандр) Impulse ++ (increment) Impulse -‐ -‐ (decrement) Motometer
Discrete, activates in a specified voltage range Discrete, connection of the call button
Discrete, arming/disarming (security) Discrete, ignition control
1 + + + + + -‐ -‐ + -‐ -‐ -‐
2 + + + + -‐ + -‐ + -‐ -‐ -‐
3 + -‐ -‐ -‐ -‐ -‐ -‐ + -‐ -‐ -‐
4 + -‐ -‐ -‐ -‐ -‐ -‐ + -‐ -‐ -‐
5 + -‐ -‐ -‐ -‐ -‐ + + -‐ -‐ -‐
6 + -‐ -‐ -‐ -‐ -‐ -‐ + + -‐ -‐
7 + -‐ -‐ -‐ -‐ -‐ -‐ + -‐ + -‐
8 + -‐ -‐ -‐ -‐ -‐ -‐ + -‐ -‐ +
Analog input, voltage measurement 0-‐36V – a voltage measurement of an input and conversion to a digital form via 10 bit analog-‐digital converter. The measurement range is from 0 to 36V. Value is transferred in volts with a fractional part and multiple of 0,1V. Analog input, voltage measurement 0-‐5BV – a voltage measurement of an input and conversion to a digital form via 10 bit analog-‐digital converter. The measurement range is from 0 to 36V. Value is transferred in volts with a fractional part and multiple of 0,1V. Impulse, accumulation of impulses -‐ in case of the positive impulse of an input, it is prodiced an increase of the impulse counter at 1 unit. To achieve the amount of 65535, the counter is nullified, and counting begins anew. Value of the counter is transferred in an explicit form. Impulse ++ (increment) – operate combined with an impulse input -‐ -‐ (decrement). When impulse is recieved on increment input (++) value of the counter is increased, when impulse is recieved on decrement input (-‐-‐) value of the counter is decreased. Thereby explicit value of the counter is always equal to a difference of impulses of ++ input and -‐-‐ input. Impulse -‐ -‐ (decrement) – operate combined with an impulse input++ (increment). Whenimpulseisreceivedonincrementinput (++)value of the counter is increased, when impulse is recieved on decrement input (-‐-‐) value of the counter is decreased. Thereby explicit value of the counter is always equal to a difference of impulses of ++ input and -‐-‐ input. The motometer – an input function intending for the accounting of the vehicle engine operation time (an operating time of the vehicle and the working hours of the driver). In case of the positive voltage of an input the motometer increases per every second by 1 unit. To achieve the amount of 65535, the counter is nullified, and counting begins anew. Value of the counter is transferred in an explicit form (sec). Discrete, activates in the specified voltage range – this function is available to all inputs. For a choice of the active and passive level in a configurator, set the processing logic and transition points.See the section "Device Configuring". Discrete, connection of the call button – in case of the positive potential of an input (input №6) the device dials up of number specified in CONNECTION 1(section "Settings of Connections"). For use of this function it is recommended to connect NAVISET HF-‐1 which in addition to basic functions, has operator call button.
Discrete, arming/disarming – input function using in case of use of the device as the security alarm system. Change of a mode is made by impulse. Current status "ARMED" or "DISARMED" is transferred to the server in the field of STATUS (see the data transfer protocol description). Discrete, ignition control – connect to the jumper IGNITION, serves to transfer data of the current position (position ON) of the ignition key in the vehicle. Connection to any of the inputs is selected by general contact GND. Buttons, sealed contact, circuit breakers and other passive sensors are directly connected to the device. Active devices (fuel level sensors and others), need an additional power supply before connecting these sensors, please read the instructions for each of them. The Naviset GT-‐20 device has two SIM cards on the processor board. To install the SIM card unscrew 4 fixing screws and remove the processor board out of the device case. See Figure 3. To install accurately move upper cover of holder to the side of edge board, tilt, set the SIM card, close and move to the latching.
Figure 3. Configuration of SIM card holders TheusercanswitchtheinterfaceswithahelpofSW1 (4). DescribtionoftheSW1 statefortheswitching the needed state is in the Table 4. Table 4.Describtionofdevise display operation № SW 1 2 3 4 5 6 7 8 9 10
PORT 1 RS232 OFF OFF OFF ON ON ON
RS485 ON ON ON OFF OFF OFF
PORT 2 RS232 ON ON OFF OFF
Example: You need that the PORT 1 willRS485 and PORT 2 willCAN. SW 1 – ON; 2 – ON; 3 – ON; 4 – OFF; 5 – OFF; 6 – OFF;
CAN OFF OFF ON ON
7 – OFF; 8 – OFF; 9 – ON; 10 – ON. Describtionofdisplayoperationis in the Table 5. Table 5. Description of the display device
Indicator SAT
illuminate -‐ continuously
Indicator SIM no SIM card
Indicator PWR No external power
Indicator CPU
External indicator No voice connection
One flash per 2 seconds
Coordinatesarevalid Serverconnection -‐
Two flashes per 2 seconds Three flashes per 3 seconds
Coordinatesare not valid
no connection with a server
-‐
Normal operation mode No external -‐ power, operation via storage battery Uploadermode -‐
Antenna circuit, there is no communication with the receiver Satellite initialization
-‐
-‐
-‐
Connection is set
Four flashes Initialization of -‐ Connection -‐ per 2 GSM module with PC is set seconds Five flashes -‐ -‐ -‐ -‐ Incoming call per 2 seconds Goes out 2 -‐ -‐ -‐ -‐ Outcoming times in 2 call seconds No -‐ -‐ No external -‐ illuminate power Micro SD a map is used for operation as a black box for storage of a track, photos, events and the log record of events registration. Maximum size is 32gb.
6.2 NAVISETGT-‐10, NAVISETGT-‐10 IRIDIUMdevise The device is a plastic case with a mounted possibility on clamps, with a efficient microcontroller and GSM modem. The microcontroller completes all actions for the collection and processing the signals. All electronic components are placed on the printed circuit board, mounted to the base.
Figure 4. Description of interfaces (1) – ConnectorGLONASS, GPSorGLONASS / GPSantenna, SMA-FEMALEtype (2) – ConnectorIRIDIUM antenna, SMA-FEMALEtype (3) – Status indicators of the device operation and the selected SIM card. Descriptions of the status see Table 8 and 9. (4) – Cable input for connection of a supply and the periphery, the Figure 5. (5) – TheconnectorofthecomputerUSBinterfaceforconfiguring, changeoffirmware.
Connection of supply, sensors and other periphery is produced inside device case. For this purpose it is necessary to turn off 4 fixing bolts and to take device circuit board from the case. See Figure 5. Two interface connector are located on a circuit board:
Figure 5.Сarrier socket description for external periphery
(1) – Plug for connection of fuel level sensor (digital, analog, frequency, impulse), digital temperature sensors DallasSemiconductorDS1820, electronic keys of Touch Memory DS1990A, external actuation device including lock of the engine, camcorder and other periphery. The power is connected to two extreme contacts. (2) – Plug for connection of heandsfree HF-‐1 (3) – Plug for connection IRIDIUM antenna. Beforetheconnectionmakesurethatantenna approaches for using in the current operating conditions (terrestrial stationary object, terrestrial mobile, high speed air or other). (4) – Plug for connection GLONASS antenna. Moredescriptionofconnector functionssee the Table 6. Table 6. Description of connector functions Сarrier socket 1 IN1 IN2 IN3/RX 1-‐Wire GND 485А IN4 IN5 485B 1-‐Wire OUT1 OUT2 OUT3 GND GND 12/24В Сarrier socket2 MIC SPK IND 4,2B GND
Functionalarea Analog input 0-‐5В, 0-‐36V, frequency Digital, analog input0-‐36V Digital,discrete input, RS232-‐RX DS1820 temperature sensorsand I-‐Button key contactor General power wire, minus RS485interface. Line А Pulse input (inverting) increment (++) Pulse input (inverting) decrement (-‐-‐) RS485 interface. Line B DS1820 temperature sensorsand I-‐Button key contactor PGM output -‐ impedance,closed-‐loop, inversion PGM output -‐ impedance, closed-‐loop, inversion PGM output -‐ impedance, замкнут, инверсия General power wire, minus General power wire, minus Power input for vehicle network connection Functionalarea Output of an external PTT microphone connection Output of an external PTT speaker connection Status display of voice connection Output of a PTT power General power wire, minus
Universal input circuits are designed for analog, impulse, discrete sensors. All inputs are classified on the executed functionality, described in Table 7. Table 7 - The contactor functions Functional area/ Inputs
Analog mode, the measurement voltage 0-36V Analog mode, the measurement voltage 0-5V Frequency Impulse, accumulation of impulses, meander Impulse ++ (increment) Impulse -‐ -‐ (decrement) Motometer
Discrete, activates in a specified voltage range Discrete, connection of the call button
Discrete, arming/disarming (security) Discrete, ignitioncontrol RS232 RX input
1 + + + + -‐ -‐ -‐ + -‐ -‐ -‐ -‐
2 + -‐ -‐ -‐ -‐ -‐ -‐ + + -‐ -‐ -‐
3 -‐ -‐ -‐ -‐ -‐ -‐ -‐ + -‐ -‐ -‐ +
4 -‐ -‐ -‐ -‐ + -‐ -‐ + -‐ -‐ -‐ -‐
5 -‐ -‐ -‐ -‐ -‐ + + + -‐ -‐ -‐ -‐
Analog input, voltage measurement 0-‐36V – a voltage measurement of an input and conversion to a digital form via 10 bit analog-‐digital converter. The measurement range is from 0 to 36V. Value is transferred in volts with a fractional part and multiple of 0,1V. Analog input, voltage measurement 0-‐5BV – a voltage measurement of an input and conversion to a digital form via 10 bit analog-‐digital converter. The measurement range is from 0 to 36V. Value is transferred in volts with a fractional part and multiple of 0,1V. Impulse, accumulation of impulses -‐ in case of the positive impulse of an input, it is prodiced an increase of the impulse counter at 1 unit. To achieve the amount of 65535, the counter is nullified, and counting begins anew. Value of the counter is transferred in an explicit form. Impulse ++ (increment) – operate combined with an impulse input -‐ -‐ (decrement). When impulse is recieved on increment input (++) value of the counter is increased, when impulse is recieved on decrement input (-‐-‐) value of the counter is decreased. Thereby explicit value of the counter is always equal to a difference of impulses of ++ input and -‐-‐ input. Impulse -‐ -‐ (decrement) – operate combined with an impulse input ++ (increment). Whenimpulseisreceivedonincrementinput (++)value of the counter is increased, when impulse is recieved on decrement input (-‐-‐) value of the counter is decreased. Thereby explicit value of the counter is always equal to a difference of impulses of ++ input and -‐-‐ input. The motometer – an input function intending for the accounting of the vehicle engine operation time (an operating time of the vehicle and the working hours of the driver). In case of the positive voltage of an input the motometer increases per every second by 1 unit. To achieve the amount of 65535, the counter is nullified, and counting begins anew. Value of the counter is transferred in an explicit form (sec). Discrete, activates in the specified voltage range – this function is available to all inputs. For a choice of the active and passive level in a configurator, set the processing logic and transition points.See the section "Device Configuring". Discrete, connection of the call button – in case of the positive potential of an input (input №6) the device dials up of number specified in CONNECTION 1(section "Settings of Connections"). For use of this function it is recommended to connect NAVISET HF-‐1 which in addition to basic functions, has operator call button. Discrete, arming/disarming – input function using in case of use of the device as the security alarm system. Change of a mode is made by impulse. Current status "ARMED" or "DISARMED" is transferred to the server in the field of STATUS (see the data transfer protocol description). Discrete, ignition control – connect to the jumper IGNITION, serves to transfer data of the current position (position ON) of the ignition key in the vehicle. Connection to any of the inputs is selected by general contact GND. Buttons, sealed contact, circuit breakers and other passive sensors are directly connected to the device. Active devices (fuel level sensors and others), need an additional power supply before connecting these sensors, please read the instructions for each of them.
Table 8. Description of the display device
Indicator SAT
Indicator SIM
Illuminate continuously
-‐
no SIM card
Coordinatesarevali One flash per 2 seconds Serverconnection d Two flashes per 2 seconds
Coordinatesarenot no connection with valid a server
Indicator PWR Indicator CPU There is an Normal operation external power mode
-‐
there is no external power,operation via storage battery
-‐
Uploadermode
-‐
Three flashes per 3 seconds
Antenna circuit, there is no communication with the receiver
-‐
-‐
Four flashes per 2 seconds
Satelliteinitializatio n
GSM module Initialization
-‐
a computerconnect ion
Table 9. Discribtion of Iridium display operation GT-‐10 Signals about the operation via SIM 2. Algorithm
GT-‐10 IRIDIUM Constantly burnsatthetimeof session and data transmission installation through the satellite IRIDIUM network.
of operation is as the operation of GSM display in table 1. The Naviset GT-‐10 device has two SIM cards on the bottom side of the processor board. To install the SIM card unscrew 4 fixing screws and remove the processor board out of the device case. See Figure 6. To install accurately move upper cover of holder to the antenna connector, tilt, set the SIM card into the slot cover, close and move to the opposite direction of antenna connector.
Figure 6. Configuration of SIM card holders
7. CONNECTION OF THE ADDITIONAL PERIPHERY 7.1 Connection of heandsfreeHF-‐1 HeandsfreeNavisetHF-‐1 is intended for operation as a part of Naviset GT-‐10 and Naviset GT-‐20 terminals for providing with communication between the driver and the operator. The device consists of the amplifier with the imternal operator call button and an external PTT button. You can connect HF-‐1 to navigation terminals of third-‐party, including with a differential output. Amplifier module is set in a place convenient for the driver, the press-‐to-‐talk button is connected to it via the connector intended for these purposes.During the operator call, automatically connection is produced through definite time interval of an automatic answer for a call. For a call of the operator the driver short-‐time push a call-‐button, located on the amplifier, and waits for connection of a call. To speake with operator, press the PTT button. The button is released for message listening of the operator. Open the device case, turned off 2 screws. Make connection to the navigation terminal according to the diagram provided on a figure 7 or 8. Fix a device in a place convenient for the driver, connect a PTT button. In the navigation terminal specify telephone number of the operator on which will be dialup in case of pushing call button on the amplifier. The connection diagram to the Naviset GT-‐10 terminal is given in a figure 7. The connection diagram to the Naviset GT-‐20 terminal is given in a figure 8. Recommend for connection to use a wire of UTP-‐5 (twisted pair cable) of long at least 2 meters for an exception of appearance of GSM transmitter pickup to the amplifier.
Figure 7.Connection diagram to NavisetGT-10
Figure 8.Connection diagram to NavisetGT-20 For operation of HF-1 in a confugurator specify telephone number of operator.Seepart 000
7.2 CONNECTION OF FUEL LEVEL SENSOR It is possible simultaneously to connect different types of fuel level sensors to devices. More details are in Table 10. Table 10. Number of connected sensors to devices Type of fuel level sensor Analog 0-‐36V Analog 0-‐5V Frequency Impulse, accumulationofimpulses, meander Impulse ++ (increment) + Impulse -‐ -‐ (decrement) Digital RS-‐232 DigitalRS-‐485
GT-‐10 2 pcs 1 pcs 1 pcs 1 pcs 1 pcs 1 pcs 2 pcs
G-‐T20 8 pcs 2 pcs 2 pcs 2 pcs 1 pcs 2 pcs 2 pcs
Device inputs are intended for connection of specific sensortypes. Compliance of inputs and types of sensors is given in table 11. Table 11.Compliance of inputs and sensors types Type of fuel level sensor Analog 0-‐36V Analog 0-‐5V
GT-‐10 Input 1,2 Input 1
G-‐T20 Input 1…8 Вход 1,2
Frequency Impulse, accumulationofimpulses, meander Impulse ++ (increment) Impulse -‐ -‐ (decrement) DigitalRS-‐232 DigitalRS-‐485
Input 1 Input 1 Input 4 Input 5 Input 3 (RX) 485А + 485В
Input 1,2 Input 1,2 Input 1 Input2 RS232 – 1 и 2 485А + 485В
WARNING! To NAVISET GT-‐10 CAN NOT BE simultaneously connected sensors via RS232 and RS485. The sensors are connected to one of specified interfaces. To NAVISET GT-‐20 can be simultaneously connected sensors via RS232 and RS485, but in advance put SW-‐1 (see Table 4) to the desired position.
7.2.1CONNECTION DIGITAL FUEL LEVEL SENSOR TO NAVISETGT-‐20 For operation with digital fuel sensors it is used RS-‐232 or RS485 digital interface. For 485 interfaces it is possible to connect two fuel sensors at the same time on one line and calibration in device configuration. To digital interface №1 can be connected one sensorRS-‐232 or two RS-‐485 sensors as shown in Figure 9.Interface is choosen of SW-‐1 (see Table 4).
Figure9.Connection of digital fuel level sensor RS-‐232 / RS-‐485 toNAVISETGT-‐20
To digital interface №2can be connected one sensorRS-‐232 as shown in Figure 10. RS-‐232 interfaceischoosenofSW-‐1.
Figure10.Connection of digital fuel level sensor RS-‐232 toNAVISETGT-‐20
Before connection, please read the manufacturer's instructions, which is provided by the manufacturer of sensor; keep the polarity of power and correctness of data bus connection.
Procedure of sensor installation and calibrating is described in the instruction of the sensor manufacturer, the instruction of sensor calibrating via a device configurator is described in part 000.
7.2.2 CONNECTION OF ANALOG, FREQUENCY AND IMPULSE FUEL LEVEL SENSORS TONAVISETGT-‐20 To NAVISET GT-‐20 can be connected up to 8 Analog sensors with a range of output voltage 0-‐ 36Vandup to 2 frequency or analog sensors with a range of output voltage 0-‐5V. Capability of inputs and types of sensors is given in table 11. Analog and frequency sensors can besimultaneously connected to different inputs. Example connection of analog, frequency and impulse fuel level sensor to input 1 is described in figure 11.
Figure 11.Connection of analog, frequency and impulse fuel level sensor toNAVISETGT-‐20 To device can be connected impulse flow-‐type sensor. The sensor is set in branch pipe of engine fuel feed, the other one is seton the return pipe. Input types 1 and 2 must be set to Impulse + + (increment) and Impulse -‐ -‐ (decrement) respectively. Connection diagram of impulsed flow-‐type sensors is shown in Figure 12.
Figure 12.Connection of impulse flow-‐type sensor toNAVISETGT-‐20
7.2.3 CONNECTION OF DIGITAL FUEL LEVEL SENSOR TONAVISETGT-‐10 For operation with digital fuel level sensors use digital RS-‐232 orRS-‐485 interface. For variant with 485 interface can be simultaneously connected 2 fuel sensors on one line and calibration in device configuration. To digital interface can be connected one RS-‐232 sensor as shown in Figure 12. Sensor input is not connected to the device and kept in the air. Therefore a calibration via the device will not work. Before connection of the sensor to the device, make its calibrating in advance.
Figure12. Connection digital RS-‐232 fuel sensor to NAVISET GT-‐10
To RS-‐485 interface can be connected one or twosensors with RS-‐485 interface as shown on the Figure 13. During the connection of two sensors, setin advance the address 01 and 02 respectively in advance.
Figure13.Connection of digital RS-‐485 fuel sensor to NAVISET GT-‐10
Before connection, please read the manufacturer's instructions, which is provided by the manufacturer of sensor; keep the polarity of power and correctness of data bus connection.
Procedure of sensor installation and calibrating is described in the instruction of the sensor manufacturer, the instruction of sensor calibrating via a device configurator is described in part 000.
7.2.4 CONNECTION ANALOG, FREQUENCY AND IMPULSE FUEL SENSOR TO NAVISETGT-‐10 To NAVISETGT-‐10 can be connected up to 2 Analog sensors with a range of output voltage 0-‐ 36Vandone frequency andone analog sensors with a range of output voltage 0-‐5V. Capability of inputs and types of sensors is given in table 14. Analog and frequency sensors can besimultaneously connected to different inputs. Example of connection of analog, frequency and impulse fuel level sensor to input 1 is described in figure 14.
Figure 14.Connection of analog, frequency and impulse fuel level sensor toNAVISETGT-‐10 To device can be connected impulse flow-‐type sensor. One sensor is set in branch pipe of engine fuel feed, the other one is seton the return pipe. Input types 4 and 5 must be set to Impulse + + (increment) and Impulse -‐ -‐ (decrement) respectively. Connection diagram of impulsed flow-‐type sensors is shown in Figure 15. .
Figure 15.Connection of impulse flow-‐type sensor to NAVISET GT-‐10
8. CONNECTRION OF TEMPERATURE SENSOR AND DRIVER INDENTIFICATION BUTTOM To NAVISETGT-‐10 and NAVISETGT-‐20 device can be connected up to 8 digital temperature sensors. The sensors are connected to one line interface 1-‐Wire. This interface is also designed for connection of touch memory to indentify the drivers. Example of temperature sensor and touch memory connection to NAVISETGT-‐20 device is shown on Figure 16.
Figure 16. Temperature sensor and touch memory connection to NAVISETGT-‐20
Example of temperature sensor and touch memory connection to NAVISETGT-‐10 device is shown on Figure 17.
Figure 17. Temperature sensor and touch memory connection to NAVISETGT-‐10
WARNING! Instead of the TM contactor it is possible to connect the reader of noncontact RFID of cards with the output T-‐Button interface, for example, applicator reader PRIXIMITY of PR-‐01cards or set-‐in reader PRIXIMITY of CP-‐Z2B cards. These readers are available in any security and fire alarm system store.
9. CONNECTION TO CAN-‐BUS INTERFACE (WIRE) There are several options of connection to a CAN-‐bus of vehicle. Option 1. With the current-‐limiting resistors (Figure 18). This option is preferable to use when connected directly to the onboard bus CAN. Выводы CAN_L CAN_H подключать через сопротивления 1 кОм к соответствующим сигналам CAN_L CAN_H, без законцовочного резистора 120 Ом. Option 2. Direct connection (Fig. 18). This option is used in case of connection to the diagnostic connector. The need of connection of the additional resistor (shown as dashed lines) is defined as follows: in case of the switched-‐off electronics of the vehicle, measure resistance of outputs of the diagnostic connector CAN_L CAN_H .Если сопротивление около 60 Ом, то резистор не нужен, если 120 Ом, то подключаем дополнительный резистор.
Figure 18. Connection of NAVISETGT-‐20 to CAN-‐BUS Wire of vehicle В приборе NAVISETGT-‐10 has not a CAN-‐BUS interface, but it can receive, store and transfer
data to the server from the CAN bus using the external converter CAN-‐RS232 ANTELIS or CAN-‐LOG. Connection is the same as connection of RS-‐232 fuel sensor, which is shown on a figure 12. Device don't transfer any information to the data bus CAN, operation is carried out only in a passive mode (only reading) therefore in case of connection don't break operation of standard systems of the vehicle.
10. CONNECTION OF AUTOINFORMER DEVICE NAVISETGT-‐20 supports the autoinformer function? using the output of «EXTSPEAK». This output is "linear", the amplitude of the output signal is no more than 100mV, so for signal amplification is necessary to use a low-‐frequency amplifier(LFA). You can use any amplifier of 4W. Connection diagram of autoinformer is shown on figure 19.
Figure 19. Connection NAVISETGT-‐20 device to CAN-‐BUS wire of vehicle
As a part of NAVISET GT-‐20 and NAVISETGT-‐10 can use voice annunciators (device with in advance written messages). Voice annunciators have two categories: 1 . Analog, which supports two audiofragments. Activation of voice annunciator is produced by applying a voltage of 12V to input. 2 . Digital, which supports up to 100 different audiofragments. Activation of voice annunciator is produced of the command of the RS-‐232 or RS-‐485 interface. This option is advisable to use as a part of NAVISETGT-‐10 device, as it have not a built autoinformer.
11. CONNECTION OF SL-‐CAM-‐1 ANDSL-‐CAM-‐2 CAMCORDER NAVISET GT-‐10 and NAVISET GT-‐20 support transmission of snapshots of the connected camcorders. Connection is made via digital RS232 and RS485 interfaces (for camcorders with the 485 interface). Types of supported camcorders are given by each device in table 11. Table 11. Supported camcorders Type of camcorders SL-‐CAM-‐1 SL-‐CAM-‐2
NavisetGT-‐10 + +
NavisetGT-‐20 -‐ +
SL-‐CAM-‐1 camcorder is not available to connect to NAVISET GT-‐20, because the power of this camcorder has tension of 4,2V. GT-‐20 device has no output of an external power 4,2V. NAVISET GT-‐10 has this output and is available to connect this camcorder to it. Connection is carried out in compliance with table 12 and 13. Table 12.Connection of camcorder to NAVISETGT-‐10
Type of camcorder
Naviset GT-10contactor IN3/RX
SL-CAM-1
4.2B
Camcorder Green contactor yellow red
GND
black
IN3/RX
green yellow red black
SL-CAM-2
12/24B GND
Table 13.Connection of camcorder toNAVISETGT-‐20
Type of camcorder
Naviset GT-20contactor
Camcorder contactor
SL-CAM-2
RX
green
TX 12/24B GND
yellow red black
Please NOTE! The camcorder is connected to NAVISET GT-‐10 via the digital RS232 interface. Use is possible only in case of absence of the digital sensor of fuel. Before connection be convinced that the used type of the camcorder is compatible with the Naviset GT20. The camcorder of SL-‐CAM-‐1 has no overvoltage protection and it is necessary to connect a camcorder power strictly to the jumper of 4,2V. If after connection of the camcorder, the snapshot isn't transferred in case of snapshot's request of a configuration,it is necessary to change places of green and yellow wires.
12. Connection of panic button NAVISET GT-‐10 and NAVISET GT-‐20 support connection of the panic button. The panic button can be connected to any input. The example of connection of the panic button to input #1 of NAVISET GT-‐10 and NAVISET GT-‐20 terminals is given in figures 20 and 21 respectively.
Figure 20. Connecting of panic button to a NAVISET GT-‐10 devise
Figure 21. Connecting of panic button to a NAVISET GT-‐20 devise The panic button has not a polarity, therefore in case of connection, it does not matter which one of wire will be connected to power voltage and which one of wire -‐ to input # 1. The model and modification of the button has not a value. The model is selected proceeding from a place and conditions of installation for each specific vehicle. Main requirements: 1 . Absence of the clicking fixer 2 . Normally opened couple of contacts
13. Operation and setting change via SMS To operate and change settings via SMS is used specialized command set. These commands are sent from any authorized phone(entered in the device memory). The list of available commands and their value are provided in table 14. Table 14.List of the control and configuring command Command COM0 PASS Device state request
COM1 OLD_PASS, NEW_PASS Password change
COM2 PASS,ID Change ID number of device
Possessing the value PASS is a current password set in the device. Manufacturer’s value is 1234. EXAMPLE: COM0 1234 Message of current state will received after command completion
OLD_PASS is a current password set in the device. Manufacturer’s value is1234. NEW-PASS is a new password, that will change the previous password. EXAMPLE: COM1 1234,4321 Confirmation ‘NEW_PASS: 4321‘ will come after command completion PASS - текущий пароль, установленный в приборе. Manufacturer’s value is 1234. ID is a number of device, takes on a value of 1 to 65535. EXAMPLE: COM2 1234,8888 Confirmation ‘ NEW_ID: 8888‘ will come after command completion
COM3 PASS,IP,PORT Server setiing
PASS is a current password set in the device. Manufacturer’s value is 1234. IP is aIP address of remote collection server. PORT is a IP port of remote collection server. EXAMPLE: COM3 1234,255.255.255.255,15000 Confirmation ‘IP: 255.255.255.255:15000’ will come after command completion
COM4 PASS,IN,OUT,MEM Security option
COM5 PASS,IP,PORT Remote configuration
COM6 PASS,MAP Location information
COM7 PASS,OUTNUM,ON/OFF Output control
PASS is a current password set in the device. Manufacturer’s value is 1234. IN is a time of disaming, принимаетзначениеот 0 до 255 сек. OUT is a arming time, value is range of 0 to 255 sec. MEM is a time of reactivating of a interrogating, value is range of 0 to 255 min. EXAMPLE: COM4 1234,10,10,1 Confirmation ‘NEW_TIMES: 10,10,1’ will come after command completion PASS is a current password set in the device. Manufacturer’s value is 1234. IP is a IP address of remote configuration server. PORT is aIP port of remote configuration server. EXAMPLE: COM5 1234,255.255.255.255,12500 The device will switch on following address after command completion
PASS is a current password set in the device. Manufacturer’s value is 1234. MAP - Web-card. 0 - OpenStreet, 1 - Google. EXAMPLE: COM6 1234,0 After command completion the SMS will received with coordinates and details of selected card . PASS is a current password set in the device. Manufacturer’s value is 1234. OUTNUM is a number of an output. Available value (1,2,3 or 4) ON/OFF – Output state after completion. 1 – turn on, 0 turn off. EXAMPLE: COM7 1234,3,1 Confirmation ‘OUT3: ON’ will come after command completion
COM8 PASS,SW Auto switching of a SIM card
COM9 PASS,MOVE,PARKING Period of packet transmission
COM10 PASS Disarrming (security)
COM11 PASS Arming (security)
COM12 PASS,SIM Switch on another SIM card
COM13 PASS,SIM,APN,LOGIN,PASS2# ChangeAPN SIM cards
COM97 PASS To remove a track from the device memory
COM98 PASS Reboot the device
COM99 PASS, IP, PORT, DAY FW update via GPRS
PASS is a current password set in the device. Manufacturer’s value is 1234. SW is a state. 0 – to forbid auto switching of a SIM cards, 1 – to allow. EXAMPLE: COM8 1234,1 Confirmation ‘Autoswitch SIM ON’ will come after command completion PASS is a current password set in the device. Manufacturer’s value is 1234. MOVE is a period of packet transmission in motion (by default 30 sec). PARKING is a period of packet transmissionduring the parking (by default 120 sec). EXAMPLE: COM9 60,300 Confirmation ‘NEW_SEND_PACK: 60,300’ will come after command completion PASS is a current password set in the device. Manufacturer’s value is 1234. EXAMPLE: COM10 1234 Confirmation ‘DISARM XX:XX’ will come after command completion, where XX:XX is time of disarming PASS is a current password set in the device. Manufacturer’s value is 1234. EXAMPLE: COM11 1234 Confirmation ‘ARM XX:XX’ will come after command completion, where XX:XX is time of arming PASS is a current password set in the device. Manufacturer’s value is 1234. SIM is a number of SIM card, that is needed to be active. EXAMPLE: COM12 1234,2 – switch on another SIM card for operation. Confirmation ‘Switch to SIM 2’ will come after command completion PASS is a current password set in the device. Manufacturer’s value is 1234. SIM- number of Sim cards. APN - APN provider. LOGIN is anuser name. PASS2 is a user password. Line shall terminate # (hash). EXAMPLE: COM13 1234,1, mymternet, logm, pass# - to write the APN parameters for the first SIM card. Confirmation ‘APN update’ will come after command completion PASS is a current password set in the device. Manufacturer’s value is 1234. EXAMPLE: COM97 1234 Confirmation ‘TRACK DELETED’ will come after command completion PASS is a current password set in the Manufacturer’s value is 1234. EXAMPLE: COM98 1234.
device.
PASS is a current password set in the device. Manufacturer's value is 1234.IP- the IP address of a remote server of firmware updating PORT- IP port of update remote server DAY- a date of auto update, accepts values from 0 to 31. Value distinct from zero allows auto update, equal to zero is forbidden.. EXAMPLE: COM99 1234,255.255.255.255,5001,10 After the updating you receive Firmware load confirmation.
PLEASE NOTE! Manufacturer's value of the password 1234. Additional functions are set up only through the configuration program via direct connection or remotely via GPRS.
