Click 100–400 Series User Guide

Transcript

Click 100–400 Series USER GUIDE Click 100–400 Series USER GUIDE www.wavetronix.com  •  78 East 1700 South Provo, Utah 84606  •  801.734.7200 © 2015 Wavetronix LLC. All Rights Reserved. Wavetronix, SmartSensor, Click, Command, and all associated product names and logos are trademarks of Wavetronix LLC. All other products or brand names as they appear are trademarks or registered trademarks of their respective holders. Protected by US Patent Nos. 6,556,916; 6,693,557; 7,426,450; 7,427,930; 7,573,400; 7,889,097; 7,889,098; 7,924,170; 7,991,542; 8,248,272; 8,665,113; Canadian Patent Nos. 2461411; 2434756; 2512689; and European Patent Nos. 1435036; 1438702; 1611458. Other US and international patents pending. The Company shall not be liable for any errors contained herein or for any damages arising out of or related to this document or the information contained therein, even if the Company has been advised of the possibility of such damages. This document is intended for informational and instructional purposes only. The Company reserves the right to make changes in the specifications and other information contained in this document without prior notification. FCC Part 15 Compliance: The Wavetronix SmartSensor sensors comply with Part 15 of the Federal Communications Commission (FCC) rules which state that operation is subject to the following two conditions: (1) this device may not cause harmful interference, and (2) this device must accept any interference received, including interference that may cause undesirable operation. FCC compliance statements for applicable optional modules are to be found in the module specifications. Unauthorized changes or modifications not expressly approved by the party responsible for compliance with the FCC rules could void the user’s authority to operate this equipment. Disclaimer: The advertised detection accuracy of the Wavetronix SmartSensor sensors is based on both external and internal testing, as outlined in each product’s specification document. Although our sensors are very accurate by industry standards, like all other sensor manufacturers we cannot guarantee perfection or assure that no errors will ever occur in any particular applications of our technology. Therefore, beyond the express Limited Warranty that accompanies each sensor sold by the company, we offer no additional representations, warranties, guarantees or remedies to our customers. It is recommended that purchasers and integrators evaluate the accuracy of each sensor to determine the acceptable margin of error for each application within their particular system(s). WX-500-0055 04/2012 Contents Introduction 7 Using this Manual 7 Part I Introduction to the Click Series Chapter 1 The Power Plant 11 Connecting to a Circuit Breaker 12; Connecting AC Surge Protection 12; Connecting Power 13; Wiring AC Power into the Click 201/202/204 14 Chapter 2 T-bus Basics 17 Adding a T-bus to the DIN Rail 18; Mounting Click Devices 18; Wiring T-buses 18 Chapter 3 Wiring the Devices 21 Working with Screw Terminal Blocks 21; RS-485 Communication 22; RS-232 Communication 24 Chapter 4 Installing Click Supervisor 27 Installing Click Supervisor 28; Microsoft .NET Framework 31 Chapter 5 Using Click Supervisor Connecting to Your Computer 33; Accessing the Communication Screen 34; Serial Communication 35; IP Communication 37; Working with Modules 38 33 Part II Individual Click 100–400 Series Modules Chapter 6 Click 100 — 16 Output Contact Closure 43 Physical Features 44; Troubleshooting 48 Chapter 7 Click 104 — 4-channel DIN Rail Contact Closure 49 Physical Features 50; Installation 52; Configuration 53; Rotary Switch 54; Front Panel Menu 55; Click Supervisor 61 Chapter 8 Click 110 — 4-channel Contact Closure Eurocard 67 Physical Features 68; Installation and Wiring 70; Fail-safe Mode 73; Configuration 73; DIP Switches 74; Front Panel Menu 80; Click Supervisor 89 Chapter 9 Click 112/114 — Detector Rack Cards 95 Physical Features 96; Installation and Wiring 97; Configuration 99; DIP Switches 100; Front Panel Menu 103 Chapter 10 Click 120/121 — Relay 117 Physical Features 118; Installation 118 Chapter 11 Click 200 — Lightning Surge Protector 121 Physical Features 122; Installation 123 Chapter 12 Click 201/202/204 — AC to DC Power Supply 127 Physical Features 128; Installation 128 Chapter 13 Click 203 — UPS/Battery 131 Physical Features 132; Installation 133; On-device Configuration 134 Chapter 14 Click 210 — AC Circuit Breaker 137 Physical Features 138; Installation 138 Chapter 15 Click 211 — AC Outlet Physical Features 140; Installation 140 139 Chapter 16 Click 221 — DC Surge Protector 143 Physical Features 144; Installation 144 Chapter 17 Click 222 — System Surge Protector 145 Physical Features 146; Installation 147 Chapter 18 Click 223 — Dual-485 Surge Protector 151 Physical Features 152; Installation 153 Chapter 19 Click 230 — AC Surge Protector 155 Physical Features 156; Installation 156 Chapter 20 Click 250 — Wireless Surge Protector 159 Physical Features 160; Installation 160 Chapter 21 Click 301 — Serial to Ethernet Converter 163 Physical Features 164; On-device Configuration 165 Chapter 22 Click 304 — RS-232 to RS-485 Converter 183 Physical Features 184; On-device Configuration 185; Computer Configuration 186 Chapter 23 Click 330 — Unmanaged Switch 195 Physical Features 196; Installation 197; Switching Characteristics 198 Chapter 24 Click 400 — 900 MHz Radio 199 Physical Features 200; On-device Configuration 201; Computer Configuration 203 Chapter 25 Click 421 — Serial to Bluetooth® Radio Physical Features 216; On-device Configuration 217; Computer Configuration 219 215 Introduction In the introduction ˽˽ Using this Manual Wavetronix Click products are a simple and cost-effective way to connect various traffic components into a single, unified system. With a broad range of easy-to-use products, the Click line integrates quickly and operates in even the harshest conditions. Click devices provide the power and communication solutions needed for effective traffic control and management. The Click series is divided into five smaller, numerically based series. Each device in a particular series shares common elements, functions, etc.: ˽˽ ˽˽ ˽˽ ˽˽ ˽˽ Click 100 series – Contact closure devices Click 200 series – Power and surge protection devices Click 300 series – Wired communication devices Click 400 series – Wireless communication devices Click 500 series – Customizable devices built on our Click 500 platform This user guide covers the Click 100–400 series. For the Click 500 series, please see the Click 500 Series User Guide. Using this Manual This manual is divided into two parts: ˽˽ Part I: Introduction to the Click Series – This part contains information common to the Click line, beginning with basic module installation guidelines. It then covers the 8 INTRODUCTION  •  CLICK 100–400 SERIES USER GUIDE Click Supervisor software, which is used with certain Click devices for configuration. For a list of Click 100–400 series devices that use Click Supervisor, see the beginning of Chapter 4. A few Click devices differ from what is written in the common information chapters in the way they are installed or the software used to configure them. In the event that a Click device departs from what is written in Part I, that difference will be noted in that device’s chapter in Part II. ˽˽ Part II: Individual Click 100–400 Series Modules – This part contains a chapter for every device (or set of devices, in some cases) in the Click 100–400 series. Each chapter has an introduction to the device along with a description of the device’s physical features and, when pertinent, sections on installation, configuration, troubleshooting and more. Part I Introduction to the Click Series Chapter 1 – The Power Plant Chapter 2 – T-bus Basics Chapter 3 – Wiring the Devices Chapter 4 – Installing Click Supervisor Chapter 5 – Using Click Supervisor 1 The Power Plant In this chapter ˽˽ Connecting to a Circuit Breaker ˽˽ Connecting AC Surge Protection ˽˽ Connecting Power 1 Power and surge protection are provided to your devices via the Click modules that make up what is known as the power plant (see Figure 1.1). Assembling the power plant is the first step in installing your Click devices. Earth Ground Black (Line) Green (Ground) White (Nuetral) Black (Ground) Red (+24 VDC) Figure 1.1 – The Click Power Plant 12 CHAPTER 1  •  THE POWER PLANT Note The power plant will only be used if your cabinet is supplied with AC power. If DC is coming into your cabinet, you will need the Click 221 DC surge protector, discussed in Part II. Connecting to a Circuit Breaker The first Click module you will connect is the Click 210, a circuit breaker designed to interrupt an electric current under overload conditions. The breaker is trip-free and can be easily reset after a current interruption by pushing the reset button (see the Click 210 chapter for more information on this device). To add a Click 210 circuit breaker and switch: 1 2 3 4 Using a rocking motion, mount the Click 210 onto the DIN rail. Make sure the reset button on front of the module is pressed down before wiring. Connect the black (line) wire from the terminal block or from the AC cord into one side of the module. Connect power out of the other side. Note It doesn’t matter which side is power in, as long as the opposite end is power out. Connecting AC Surge Protection The next module in the power plant is the Click 230, which provides surge protection to other modules on the DIN rail (see the Click 230 chapter for more information on this device). Use these steps to include AC surge protection in your installation: 1 2 3 4 Using a rocking motion, mount the Click 230 onto the DIN rail next to the Click 210. Connect the wire from the Click 210 to the rightmost screw terminal (terminal 5) on the side of the Click 230 marked IN (see Figure 1.2). Connect the white (neutral) and green (ground) wires from the AC terminal block or from the AC cord into screw terminals 1 and 3, respectively, also on the side marked IN. Connect the outgoing neutral and power wires to screw terminals 2 and 6, respectively, on the side marked OUT. CHAPTER 1  •  THE POWER PLANT Figure 1.2 – Click 230 Screw Terminals (labels beneath terminals have been added) Screw terminals 3 and 4 are directly bonded via the metal mounting foot of the base element to the DIN rail. There is no need for any additional grounding between terminals 3 and 4 and the DIN rail. Note If you are using a Click 211 in your installation, the configuration of the power plant will differ slightly from what is listed in this chapter, starting at this point in the installation process. See the Click 211 chapter of this manual for more information. Connecting Power The final component of the power plant is the AC to DC converter. The Click line features several such converters. The Click 201/202/204 are AC to DC power supplies that provide DC power to every Click product mounted on the DIN rail. The Click 201 provides 1 A, the Click 202 provides 2 A and the Click 204 provides 4 A. The screw terminals on the top and bottom of the Click 201/202/204 can be unplugged from the module, allowing you to pre-wire power before the final installation. The screw terminal blocks are red-keyed, allowing the block to plug back into only one specific jack. Note If you prefer, instead of the Click 201/202/204, you can use the Click 203, which is a combination UPS and battery. This set of modules will convert AC to DC and provide uninterrupted power to your equipment. See the Click 203 chapter in Part II of this document for more information. 13 14 CHAPTER 1  •  THE POWER PLANT Wiring AC Power into the Click 201/202/204 Use the steps below to properly wire AC power to the top of the Click 201/202/204: 1 2 Using a rocking motion, mount the Click 202/202/204 to the DIN rail next to the Click 230. Connect the power and neutral wires from the Click 230 into the screw terminals marked L and N, respectively, on the side of the module marked 100–240V AC In. Figure 1.3 – Wiring AC Power into the Click 201/202/204 Caution Make sure power to AC mains is disconnected while wiring the AC input. Wiring DC Power out of the Click 201/202/204 The screw terminals on the bottom of the devices are slightly different. The Click 202 and 204 have a single terminal block, while the Click 201 has two; it doesn’t matter which of the two terminal blocks on the 201 you wire into. Connect one wire for DC power (red is standard) to a screw terminal marked +. Connect a second wire as a ground wire (black is standard) to either of the two terminals marked – (see Figure 1.4). Note Do not wire into the DCOK terminal; it provides only 20 mA and should only be used to monitor the power supply. CHAPTER 1  •  THE POWER PLANT Figure 1.4 – Wiring DC Power out of the Click 201/202/204 Caution An authorized electrical technician should perform installation and operation of this unit. Persons other than authorized and approved electrical technicians should NOT attempt to connect this unit to a power supply and/or traffic control cabinet, as there is a serious risk of electrical shock through unsafe handling of the power source. Extreme caution should be used when connecting this unit to an active power supply. 15 T-bus Basics 2 In this chapter ˽˽ Adding a T-bus to the DIN Rail ˽˽ Mounting Click Devices ˽˽ Wiring T-buses 2 Now that the power plant is complete, the next step in installing your Click modules is adding a T-bus to your DIN rail. A T-bus is made up of small modules called T-bus connectors that snap onto your DIN rail to provide power and communication connections to your Click devices. You can connect together as many T-bus connectors as you need to provide power and communication to all the Click devices on the rail with only a single wiring connection. Wavetronix has two varieties of T-bus connectors: green connectors, which conduct both power and communication, and gray connectors, which only conduct power. Gray T-bus connectors are used when you don’t want certain devices to communicate with each other. In such a case, a gray connector placed between the two devices would prevent communication while still providing power. Note Wavetronix removes the communication lines from the gray T-bus connectors it provides. Gray T-bus connectors obtained from suppliers other than Wavetronix, however, will still have communication capabilities. 18 CHAPTER 2  •  T-BUS BASICS Adding a T-bus to the DIN Rail Placing the T-bus on the DIN rail is quick and easy. To attach a T-bus connector to the rail, simply position the connector over the rail with the male connector pointing to the right. Hook one arm of the connector over one side of the DIN rail and press the other arm down over the other side until the connector snaps in place. All the T-bus connectors you connect together should be facing this direction. To connect T-bus connectors together, simply slide them toward each other until you hear them snap into place. To disconnect T-bus connectors, use a small, thin item, like a small screwdriver, to gently pry the two modules apart. Mounting Click Devices To connect a Click device to the DIN rail and T-bus, simply position the device over the Tbus connector and, using the same rocking motion used to connect the devices in the power plant, snap the device onto the DIN rail. Note Not all Click devices use the T-bus this way. Some devices, such as the 330, 331, 340, 341, 342, and those in the power plant, snap onto the DIN rail but not onto the T-bus. For more information on how to install these devices, see the appropriate chapters in Part II of this document. Wiring T-buses There are two ways to provide power to a T-bus: wiring through a Click 200 and wiring through a 5-screw terminal block. Wiring through a Click 200 The Click 200 is a surge protection device that can be connected to a sensor. The Click 200 is unique among Click devices because it can take power and communications in through its screw terminals and send it through any T-bus it is currently mounted on. To provide power to a T-bus through a Click 200, follow these steps (see Figure 2.1): 1 2 3 Connect a Click 200 to a DIN rail and T-bus. Connect the red (+24 VDC) wire from the Click 201/202/204 into the +DC screw terminal on the side of the Click 200 marked PROTECTED. Connect the black (ground) wire from the Click 201/202/204 into any of the terminals marked GND on the same screw terminal block as the red wire. CHAPTER 2  •  T-BUS BASICS Figure 2.1 – Wiring Power into the Click 200 Wiring through a 5-screw Terminal If you choose not to use a Click 200, or if you have one but prefer not to wire through it, you can also connect power through a 5-screw terminal block connected to the end of the T-bus. To provide power to a T-bus through a 5-screw terminal block, follow these steps: 1 2 Attach a male 5-screw terminal block to the left end of the T-bus by aligning it with the first connector and pushing the modules together. Connect the black (ground) and red (+24 VDC) wires from the Click 201/202/204 into the top two screw terminals in the 5-screw terminal block (see Figure 2.2 for the 5-screw terminal block pinout). Figure 2.2 – 5-screw Terminal Block Pinout Note To disconnect a 5-screw terminal block from a T-bus connector, use a small, thin item, such as a small screwdriver, to gently pry the two modules apart. 19 20 CHAPTER 2  •  T-BUS BASICS Wiring out of a T-bus Occasionally you will need to provide power and communication to devices in your cabinet that are not on a DIN rail or on a T-bus. In these cases, you can connect a female 5-screw terminal block to the right side of your T-bus and wire +DC, ground and communication from there into the device. Wiring the Devices 3 In this chapter ˽˽ Working with Screw Terminal Blocks ˽˽ RS-485 Communication ˽˽ RS-232 Communication 3 You are now ready to begin adding Click modules to your cabinet. For information on the unique features of each of the devices in the Click line, see the corresponding chapter in Part II of this document (or of the Click 500 Series User Guide). Despite having different features, there are certain elements that are similar across devices. Some of these, such as DIN rail mounting and the use of a T-bus for power and communication, have already been discussed. This chapter will discuss another such element: wiring communication through the screw terminals. Working with Screw Terminal Blocks Many Click devices feature screw terminal blocks for wiring connections. These screw terminal blocks simplify wiring because they can be removed from the Click device, then wired and reinserted. To remove a screw terminal block, insert a small, thin item, such as a small screwdriver, into the gap between the screw terminal block and the Click device (just above the screw heads) and gently pry the two apart. After wiring, simply reinsert the screw terminal block and push until it snaps into place. The screw terminal blocks are red-keyed, meaning they will only plug into their specific jacks. 22 CHAPTER 3  •  WIRING THE DEVICES Figure 3.1 – Removing and Wiring Screw Terminal Blocks RS-485 Communication Another feature that is common to many Click devices is RS-485 communication capabilities. RS-485 is important for Click devices because it is carried on the T-bus to all the Click devices on a given DIN rail. Connecting RS-485 communications to the Click devices on a DIN rail can be accomplished in two different ways: through a 5-screw terminal on the end of a T-bus, or through a Click module, which will then communicate with the T-bus. Note The steps in this section are specifically for use with a Wavetronix SmartSensor cable. If you are using a different cable or wiring system, the colors of the wires used will be different. To connect through a 5-screw terminal, follow these steps. 1 2 3 Connect the +485 (white) wire from the terminal block or cable to the middle screw terminal on the 5-screw terminal block connector you’re using for the T-bus in question (see Figure 2.2 in the previous chapter for the pinout of the 5-screw terminal block). Connect the -485 (blue) wire from the terminal block or cable to the middle screw terminal on the 5-screw terminal block. Plug the 5-screw terminal block into the T-bus. To connect through any Click device with RS-485 ports, follow these steps: 1 2 3 4 Ensure that the Click device is mounted on a T-bus connector. Connect the +485 (white) wire from the terminal block or cable to the terminal marked “+485” in the screw terminal blocks (see Figure 3.2). Connect the -485 (blue) wire from the terminal block or cable to the terminal marked “-485” in the screw terminal blocks. Connect the RS-485 drain wire from the terminal block or cable to a GND terminal in the screw terminal blocks. CHAPTER 3  •  WIRING THE DEVICES Note If you are using a Click 200 in your installation, it is recommended you wire RS-485 through it if you would like to connect to a Click device. Figure 3.2 – Wiring RS-485 Communication into the Click 200 Wiring RS-485 from a Click Device Several Click devices—such as the 104, 110, 112/114, 172/174, 200, 301 and 304—also have RJ-11 jacks for RS-485 communication with a computer or with contact closure cards. To use, simply use an RJ-11 jumper cable to connect the two devices. Figure 3.3 – A Click Device Showing RJ-11 and DB-9 Jacks 23 24 CHAPTER 3  •  WIRING THE DEVICES RS-232 Communication Most Click devices also feature RS-232 communication capabilities. These modules will convert the RS-485 communication moving to and from the T-bus to RS-232. See below for how to connect RS-232 to a laptop. Several modules also have RS-232 screw terminals. Note The steps in this section are specifically for use with a Wavetronix SmartSensor cable. If you are using a different cable or wiring system, the colors of the wires used will be different. To use, follow the steps below: 1 2 3 4 5 Connect the RTS (orange) wire from the cable or terminal block to the RTS screw terminal on the protected side of the Click device (see Figure 3.4). Connect the CTS (brown) wire to the CTS terminal on the protected side of the Click device. Connect the TD (yellow) wire to the TD terminal on the protected side of the Click device. Connect the RD (purple) wire to the RD terminal on the protected side of the Click device. Connect the RS-232 drain wire to a GND terminal on the protected side of the screw terminal blocks. CHAPTER 3  •  WIRING THE DEVICES Figure 3.4 – Wiring RS-232 Communication into the Click 200 Wiring RS-232 from a Click Device Many Click modules feature an DB-9 jack for RS-232 communication with a laptop or other such device. To use, simply use a straight-through cable to connect the two devices. 25 Installing Click Supervisor 4 In this chapter ˽˽ Installing Click Supervisor ˽˽ Microsoft .NET Framework 4 Once your Click devices are installed and wired, the next step is to install Click Supervisor, a computer program that will help you work with your Click modules. Most Click devices can be configured and monitored to some extent using the buttons and LEDs on the module, but certain devices can be fine-tuned using Click Supervisor. These computerprogrammable devices include the following: ˽˽ ˽˽ ˽˽ ˽˽ ˽˽ ˽˽ ˽˽ ˽˽ Click 104 – 4-channel DIN rail contact closure module Click 110 – 4-channel contact closure Eurocard Click 112/114 – Detector rack cards Click 301 – Serial to Ethernet converter Click 304 – Intelligent RS-485 to RS-232 converter Click 306 – 1-port terminal server Click 400 – Autobaud 900 MHz spread spectrum radio Click 421 – Bluetooth® to serial converter There are also a number of Click 500 series devices that can be configured using Click Supervisor; these are discussed in the Click 500 Series User Guide. 28 CHAPTER 4  •  INSTALLING CLICK SUPERVISOR Note If you are running Windows® Vista, you must run Click Supervisor in XP Service Pack 2 compatibility mode. To switch to this mode, right-click on the Click Supervisor icon and select Properties from the drop-down menu. Go to the Compatibility tab. Under Compatibility mode, click the Run this program in compatibility mode for: checkbox. This will enable the drop-down menu, allowing you to select Windows XP (Service Pack 2). Hit OK. Installing Click Supervisor If you have a Wavetronix Install Kit, the handheld computer included in the kit comes with Click Supervisor already installed, along with sensor software. If you don’t have an install kit, or if you want to install on a desktop computer, follow the steps below. Click Supervisor can be run on a Windows® PC and on a handheld computer. Everything needed to install Click Supervisor is contained in the Click Supervisor Setup.exe file. The setup program can install Click Supervisor on a PC, handheld computer or both. Note You must have administrator rights to run the setup program. The software can be downloaded from the Wavetronix website at www.wavetronix.com. After downloading the setup file, double-click on it to run the Click Supervisor setup wizard (see Figure 4.1). Figure 4.1 – Click Supervisor Setup Wizard CHAPTER 4  •  INSTALLING CLICK SUPERVISOR To install Click Supervisor on a handheld computer, you need to have ActiveSync (on Windows XP or earlier) or Windows Mobile Device Center (on Windows Vista). If you do not have these programs, they are available for download on the Microsoft website. If you do not have ActiveSync or Windows Mobile Device Center installed on your computer, skip to the next section, titled Installing Click Supervisor on a PC. If you do have ActiveSync or Windows Mobile Device Center installed on your computer, the setup program will detect this and the next screen that comes up will prompt you to select where you want to install Click Supervisor: a PC, a Pocket PC, or both (see Figure 4.2). Figure 4.2 – Selecting an Installation If you select Computer, the program will go through the steps outlined in the next section, Installing Click Supervisor on a PC. If you select Pocket PC, the program will go through the steps in the section titled Installing Click Supervisor on a handheld computer. If you select both, the program will go through both installation processes, beginning with installing on the PC. Note Although the software can be installed on most handhelds, because of constantly changing handheld technologies, Wavetronix can only offer technical support on the handheld in the kit, which is a Socket Mobile 650. Installing Click Supervisor on a PC Follow these steps to install Click Supervisor on a PC: 1 2 On the screen shown in Figure 4.2, click the checkbox labeled Computer and then select Next > >. Select an installation location. The default location provided is normally “C:\Program Files\Wavetronix.” Click Browse to choose another location (see Figure 4.3). 29 30 CHAPTER 4  •  INSTALLING CLICK SUPERVISOR Figure 4.3 – Location to Be Installed 3 4 Click the Install Now button. After Click Supervisor is installed, you can create shortcuts to the software on the desktop and in the start menu using the corresponding checkboxes on the final screen (see Figure 4.4). If no shortcuts are desired, uncheck the corresponding boxes. If you are installing on a Pocket PC at the same time, this screen will not appear until both installations are complete. Figure 4.4 – Shortcut Options 5 6 Click the View release notes when finished checkbox to view the Click Supervisor release notes. The release notes contain additional information about the current version of the Click Supervisor software. A PDF reader program such as Adobe Acrobat Reader is required to view the release notes. Click Finish to complete the setup process. Installing Click Supervisor on a Handheld Computer Although the software can be installed on many handheld computers, because of constantly changing handheld technologies, Wavetronix can only offer technical support on the handheld in the kit, which is a Socket Mobile 650. CHAPTER 4  •  INSTALLING CLICK SUPERVISOR Use these steps to install Click Supervisor on a handheld computer: 1 2 3 Ensure that you have ActiveSync or Windows Mobile Device Center installed and that the handheld is connected to the PC and synced. On the screen shown in Figure 4.2, click the checkbox labeled Pocket PC and then select Next > >. On the next screen, click Continue > > to start the installation process (see Figure 4.5). The setup program runs the Add/Remove Programs application for Windows handheld devices. If a handheld device is connected to the computer, Add/Remove Programs will immediately begin installing Click Supervisor on the handheld device. If a device is not connected to the computer, Click Supervisor will be downloaded the next time a handheld device is connected to the computer. Figure 4.5 – Adding Click Supervisor to a Pocket PC 4 Click OK once the download is complete. Microsoft .NET Framework The Click Supervisor setup program will automatically detect whether Microsoft .NET Compact Framework v1.1 is installed on your PC. If it is not installed, you will be prompted to install it (see Figure 4.6). 31 32 CHAPTER 4  •  INSTALLING CLICK SUPERVISOR Figure 4.6 – Microsoft .NET Framework Prompt Use the following steps to install Microsoft .NET Framework: 1 2 Click the Install Framework button. Click the I Agree radio button when the License Agreement appears (see Figure 4.7). Figure 4.7 – Microsoft .NET License Agreement 3 4 Click Install. A window will appear stating that the .NET Framework has been installed successfully. Click OK and you will be returned to the Click Supervisor setup program. Using Click Supervisor 5 In this chapter ˽˽ ˽˽ ˽˽ ˽˽ ˽˽ Connecting to Your Computer Accessing the Communication Screen Serial Communication IP Communication Working with Modules 5 Once you have Click Supervisor installed on your computer, you can begin using it to configure and monitor your Click devices. Connecting to Your Computer The first step is to connect your computer to the Click modules on your DIN rail so that Click Supervisor can see them. Click Supervisor can detect all computer-programmable devices that are connected together by either a wired or wireless connection. You can do this one of two ways. If you are using an Ethernet connection, you must be on the same network with the Click device. Plug the Ethernet cable from your computer or switch to the RJ-45 jack on the front of the Click 301. You must use a crossover cable to connect your computer to the Click 301 via Ethernet. If you are using a serial RS-232 connection, the computer needs to be connected by a straight-through serial cable to the DB-9 connector on the front of any one of the computer-programmable devices on the T-bus. See the beginning of Chapter 4 for a list of Click 100–400 series devices that can be configured using Click Supervisor. 34 CHAPTER 5  •  USING CLICK SUPERVISOR Connecting the computer to another device that has a RS-232 port but is not computerprogrammable, such as the Click 200, will not allow Click Supervisor to communicate with the other computer-programmable devices on the T-bus. Accessing the Communication Screen To connect to your devices with Click Supervisor, open the program by double-clicking on it. It will bring you to the Click Supervisor main screen (see Figure 5.1). Figure 5.1 – Click Supervisor Main Screen Click on Communication to access the Communication screen (see Figure 5.2). There are two ways to connect to your Click devices: through a serial connection or an IP connection. Figure 5.2 – Communication Screen CHAPTER 5  •  USING CLICK SUPERVISOR Serial Communication The first section on the Communication screen is Serial Communication. Here you can connect to a Click device through an RS-232 cable. Changing Settings Click Settings to bring up the Serial Settings screen (see Figure 5.3). Figure 5.3 – Serial Settings Screen ˽˽ COM Port – Allows you to change the serial connection port. ˽˽ Baud Rate – Allows you to change the baud rate or set it to auto-detect. ˽˽ Flow Control – Is usually only used if you are connecting your computer to an RS-232 device that requires hardware handshaking. ˽˽ Parity – Allows you to set parity error checking. ˽˽ Stop Bits – Allows you to set the number of stop bits. ˽˽ Data Bits –Allows you to set the number of data bits being sent. Note The flow control, parity, stop bits and data bits settings should not be changed unless you have been instructed to do so by Wavetronix Technical Services. Click the Save as default settings checkbox to tell the software to remember your setup. Click OK to return to the Communication screen or Cancel to exit without saving your settings. On the Communication screen, you can see the settings reflected in the Port: and Baud: entries. Port: shows the port you’ve set the program to communicate through, and Baud: shows the baud rate, as set under Settings or as automatically detected. 35 36 CHAPTER 5  •  USING CLICK SUPERVISOR Connecting to a Device Click Supervisor can talk to one device at a time. There are two ways to select which module to talk to. Follow these steps if you know the Click ID number of the device: 1 2 Enter the five-digit ID number in the Click ID text field, either by typing or by using the arrows to the right of the box. Click Connect. After downloading the communication file, the program will return you to the Click Supervisor main screen. Note You can find the Click ID number of your device by looking at the number beneath the barcode. The ID number is the last five digits of this number. Each device on a rail must have a unique number. The number it’s been assigned should be unique, but if it is not, you can change it after connecting to the device. See that device’s chapter in Part II of this guide for more information. Alternatively, you can connect without the ID number: 1 2 Leave a 0 in the Click ID text field. Click Supervisor will look for all connected devices on the network. Click Connect. The Device Selection screen will appear (see Figure 5.4). The computer-programmable devices on the network will appear as they are detected. The device list is divided into three columns: ID shows the ID number of the device, Click shows the product number of the device, and Description shows the user-defined description of the device. Figure 5.4 – Device Selection CHAPTER 5  •  USING CLICK SUPERVISOR 3 Click on the device you’d like to connect to and hit Select. After downloading the communication file, the program will return you to the Click Supervisor main screen. Note After connecting, you may see a dialog box asking if you’d like to upgrade. Each version of Click Supervisor has the newest firmware for all the Click devices, and when it connects to a device it will check to see if the firmware in the program is newer than that in the device. If it is, you will see the dialog box. If you’d like to upgrade your device with the newest firmware, click Yes. IP Communication The second section on the Communication screen is IP Communication. To connect to the devices on your network, first enter the IP address assigned to the Click 301 (or other Ethernet communication device connected to your modules), then enter the port number. The default port number for the Click 301, as well as many other such devices, is 10001. The default IP address is 172.16.0.13. Once a connection is made, Click Supervisor will remember the information so you don’t have to type it the next time. Connecting to a Device As with a serial connection, you must choose which device Click Supervisor will connect to. There are two ways to select which device to talk to. Follow these steps if you know the Click ID number of the device: 1 2 Enter the five-digit ID number in the Click ID text field, either by typing or by using the arrows to the right of the box. Click Connect. After downloading the communication file, the program will return you to the Click Supervisor main screen. Note You can find the Click ID number of your device by looking at the number beneath the barcode. The ID number is the last five digits of this number. Each device on a rail must have a unique number. The number it’s been assigned should be unique, but if it is not, you can change it after connecting to the device. See that device’s chapter in Part II of this guide for more information. 37 38 CHAPTER 5  •  USING CLICK SUPERVISOR Alternatively, you can connect without the ID number: 1 2 3 Leave a 0 in the Click ID text field. Click Supervisor will look for all connected devices on the network. Click Connect. The Device Selection screen will appear, and after a few moments, the list will be populated with the computer-programmable devices on the network. The list is divided into three columns: ID shows the ID number of the device, Click shows the product number of the device, and Description shows the name of the device. Click on the device you’d like to connect to and hit Select. After downloading the communication file, the program will return you to the Click Supervisor main screen. Note After connecting, you may see a dialog box asking if you’d like to upgrade. Each version of Click Supervisor has the newest firmware for all the Click devices, and when it connects to a device it will check to see if the firmware in the program is newer than that in the device. If it is, you will see the dialog box. If you’d like to upgrade your device with the newest firmware, click Yes. Working with Modules You will now be able to select Setup Click and choose a driver to start working with the device (see Figure 5.5). The drivers under Setup Click will be different for every device you connect to. For information on how to configure each device through Click Supervisor, see that device’s chapter in Part II or in the Click 500 Series User Guide for more information. Figure 5.5 – Selecting a Driver From the Select Driver screen, you can also access backups you’ve made of settings (how to save these settings is discussed in each chapter in Part II that deals with Click Supervisor). CHAPTER 5  •  USING CLICK SUPERVISOR To open a backup, select the Backups radio button in the lower righthand corner of the screen. All the backups currently saved in the correct folder will appear (see Figure 5.6). Select the backup you wish to open and click OK. Figure 5.6 – Selecting a Backup Note The default folder to save backups in is C:\Program Files\Wavetronix\ClickHome\ Drivers\ [model number] \User. If you try to save the files elsewhere, the program will still save them in the User folder. After you’ve finished configuring a device, you can connect to another one by returning to the Communication screen, closing the connection, and connecting to a different device. 39 Part II Individual Click 100–400 Series Modules Chapter 6 – Click 100 Chapter 7 – Click 104 Chapter 8 – Click 110 Chapter 9 – Click 112/114 Chapter 10 – Click 120/121 Chapter 11 – Click 200 Chapter 12 – Click 201/202/204 Chapter 13 – Click 203 Chapter 14 – Click 210 Chapter 15 – Click 211 Chapter 16 – Click 221 Chapter 17 – Click 222 Chapter 18 – Click 223 Chapter 19 – Click 230 Chapter 20 – Click 250 Chapter 21 – Click 301 Chapter 22 – Click 304 Chapter 23 – Click 330 Chapter 24 – Click 400 Chapter 25 – Click 421 Click 100 — 16 Output Contact Closure 6 In this chapter ˽˽ Physical Features ˽˽ On-device Configuration ˽˽ Troubleshooting 6 The Click 100 is a hot-swappable contact closure module for use with the Wavetronix SmartSensor. It mounts onto a DIN rail and is connected to the SmartSensor through the Click 200 surge protection module. Figure 6.1 – The Click 100 44 CHAPTER 6  •  CLICK 100 Physical Features The Click 100 has eight primary and eight secondary contact outputs, which all share a logic ground (see Figure 6.2). Figure 6.2 – Diagram of Click 100 Communication Port The back of the Click 100 features a 5-position connector that plugs into a T-bus connector and provides power and RS-485 communication to the device. It also passes RS-485 communication from the Click 100 to all other devices on the T-bus when pressing the Mode button during configuration (see the On-device Configuration section of this chapter for more information). Screw Terminals The contact closure outputs are wired to a controller, data logger or BIU (Bus Interface Unit) using the pluggable screw terminals on the top and bottom of the Click 100. The top screw terminals are labeled 1–8 and represent the primary outputs. Primary 1 (P1) represents the lane closest to a side-fire SmartSensor and the remaining outputs represent the lanes as they sequentially get further from the sensor. For dual-loop emulation, the contact closure outputs must be wired with the primary always leading the secondary (see Figure 6.3). CHAPTER 6  •  CLICK 100 Traffic Direction Primary Detector Secondary Detector Figure 6.3 – Primary and Secondary Outputs Figure 6.4 below shows a diagram of the output signal time waveforms of the two detectors. Dual-Loop Emulation System (Output Time Waveform) Primary Channel On Off Detection Duration Secondary Channel Elapsed Time (Indicates Speed) On Off Time Figure 6.4 – Emulation System Output Waveforms The bottom screw terminals are also labeled 1–8 and represent the secondary outputs, with secondary one (S1) representing the lane closest to the SmartSensor. The remaining four screw terminal connections are labeled GND and are a common logic ground for all 16 contact closure outputs. You must provide a connection from the GND terminals to a logic ground to make the primary and secondary outputs operational. The screw terminal connectors can also be unplugged from the Click 100 allowing you to pre-wire the Click 100 before final installation. Configuration Features The four LEDs located right below the push-button are used to indicate operation modes, which will be discussed later in the On-device Configuration section of this chapter. Below is a list of the four LEDs: ˽˽ PR (Presence) – Red ˽˽ PU (Pulse) – Orange 45 46 CHAPTER 6  •  CLICK 100 ˽˽ AC (Actuation) – Green ˽˽ 1L (One Loop Speed) – Yellow The front also has a push-button labeled Mode Switch, which is used to cycle the Click 100 through operation modes. This will be discussed in the On-device Configuration section. LEDs The Click 100 module has sixteen contact closure outputs. Each output represents a primary or secondary channel and has a corresponding LED on the front of the Click 100 module. The eight red LEDs on the top of the faceplate correspond to the primary outputs and the eight yellow LEDs on the bottom of the faceplate correspond to the secondary outputs. On-device Configuration The Click 100 can be configured using the push-button in the middle of the faceplate. To automatically configure the Click 100, press and hold the push-button until the green LED flashes four times. The green LED and contact closure LEDs will flash during the autoconfiguration process, which normally takes 5–30 seconds. The auto-configuration process matches the Click 100 with the sensor’s baud rate, loop size and loop spacing. The first four primary LEDs indicate the current baud rate at which the Click 100 is trying to configure. The following table shows what the different flashing LEDs represent: Primary LED Baud Rate 1 9400 bps 2 19200 bps 3 38400 bps 4 57600 bps Table 6.1 – List of Baud Rates Note The maximum baud rate that can be used is 57600. If the sensor’s RS-485 bus is set higher than 57600, no data will be seen on the Click 100. The yellow LED will flash four times indicating the end of the auto-configuration process. Once the Click 100 is configured, the device will be set to Presence (PR) mode. Press the push-button until the desired operation mode is selected. CHAPTER 6  •  CLICK 100 Operation Modes Press and hold the push-button to cycle through the different operation modes; release the button when the desired mode is reached. A quick press and release of the push-button will exit out of any mode and return the unit back to normal operation. Table 6.2 describes the different operating modes. To use dual-loop emulation, you must wire both the primary and secondary outputs; to use single-loop emulation, you must only wire the primary output. Mode LED Definition PR (Presence) Red Outputs contact closures for single-loop or dual-loop emulation. Dual-loop emulation will signal the radar’s speed and duration measurements. Speed is signaled as the elapsed time between the primary and secondary outputs. Duration in the radar beam is signaled as the duration of the outputs. Single-loop emulation will simply signal the radar’s duration measurement (no speed information). PU (Pulse) Orange Outputs contact closures for single-loop or dual-loop emulation. Dual-loop emulation will signal the radar’s speed measurement using the time elapsed between the onset of the primary and secondary outputs, but not the radar’s duration measurement. Instead the outputs will be held active for precisely 125 milliseconds for every vehicle detected. This fixed period of time is necessary when integrating with some systems and is often used in counting applications. Single-loop emulation will simply signal that the radar detected a vehicle (no duration or speed information). AC (Actuation) Green Outputs contact closures for single-loop emulation. This mode of single-loop emulation is used both with true presence and continuous passage detectors. True presence detectors signal the existence of a stopped or moving vehicle within the detector beam. Continuous passage detectors signal the existence of a moving vehicle meeting specific criteria (speed, range, ETA) within the detector beam. When a vehicle within the detector beam meets the requirements of the true presence or continuous passage detector, the associated rack card output will be closed. This is the only mode used by SmartSensor Advance. With sidefire radar sensors this mode is used for occupancy data collection. 47 48 CHAPTER 6  •  CLICK 100 1L (One Loop Speed) Yellow Outputs contact closures for single-loop emulation. The duration of each contact closure output is based upon the speed of the detected vehicle (instead of the duration of the vehicle in the beam). The duration of each contact output is based on the formula: duration in seconds = nominal vehicle length in feet / actual speed in feet per second. The nominal vehicle length is read from the sensor when this mode is selected. To set the nominal vehicle length, use the SmartSensor Manager software. The nominal length in feet is entered in the default loop spacing field. Autobaud Autobauds to the connected SmartSensor; also polls it for loop spacing. These values are saved to flash memory. While autobauding, the green and yellow LEDs will flash intermittently, as well as the 16 digital output LEDs. If the autobauding is unsuccessful, the LEDs will remain in that state indefinitely. If the autobauding is successful, the yellow LED will flash, then the device will return to its normal state and default to the Presence mode. Green (flashing) Table 6.2 – Click 100 Mode Definitions Troubleshooting The Click 100 configuration will fail if the communication link is lost or if another device is active on the communication link (usually the sensor’s native RS-485 port). For example, the configuration will fail if SmartSensor Manager remains actively connected and communicating over the same link as the Click 100. To avoid this issue, connect SmartSensor Manager to the sensor’s native RS-232 port or simply shutdown SmartSensor Manager during Click 100 configuration. If you choose to use the sensor’s native RS-232 port by connecting to the DB-9 connector on the associated Click 200, this link will become unreliable if the cable run is longer than 200 feet. Contact Wavetronix Technical Services for assistance if you would like both of the sensor’s ports to be reliable over distances greater than 200 feet. One thing to be aware of is that the relays take five milliseconds to open or close; they physically cannot react any faster than the messages they receive. Click 104 — 4-channel DIN Rail Contact Closure 7 In this chapter ˽˽ ˽˽ ˽˽ ˽˽ ˽˽ ˽˽ Physical Features Installation Configuration Rotary Switch Front Panel Menu Click Supervisor 7 The Click 104 is a 4-channel contact closure module for use with sensors that use Z4 protocol: HD, Advance and Matrix. It mounts on a DIN rail for power and communication. Figure 7.1 – The Click 104 50 CHAPTER 7  •  CLICK 104 Physical Features The Click 104 has the following physical features. T-Bus Connector RS-232 Connector TOP FRONT RS-232 LEDs Bus 1 Data +DC -DC +485 LED Indicators RS-485 Bus 2 Control Click 104 -485 Bus 1 Data GND Contact Closures 3-4 RS-485 Connector Mode Switch Rotary Switch 1-2 Mode Switch Rotary Switch Outputs 1-2 Connector Outputs 3-4 Connector Figure 7.2 – Diagram of Click 104 Communication Ports The Click 104 has two independent serial communications buses. Bus 1, also referred to as the data bus, should be used to report vehicle data; its associated communication ports consist of two RJ-11 jacks, for RS-485, on the faceplate and one screw terminal, for RS-232, on the top of the device. Bus 2, also referred to as the control bus, should be used for configuration. Its associated communication port is the a 5-position connector, located on the back of the Click 104, that plugs into a T-bus connector and provides power and RS-485 communication to the device. It also passes RS-485 communication from the Click 104 to all other devices on the T-bus. Contact Closure Outputs The contact closure outputs should be wired to a controller, data logger or BIU (Bus Interface Unit) using the pluggable screw terminals on the bottom of the Click 104. There are two screw terminal blocks; the one closer to the faceplate has outputs 1 and 2, and the farther one has outputs 3 and 4. Each output consists of two terminals, one + and one –. The screw terminal connectors can also be unplugged from the Click 104 allowing you to pre-wire the Click 104 before final installation. CHAPTER 7  •  CLICK 104 Rotary Switch On the faceplate of the device is a rotary switch, numbered 0–9. This switch, which can be twisted by inserting a small screwdriver into the arrow slot, is used to configure channels. Mode Switch The faceplate of the Click 104 features a push-button labeled Mode Switch, which is used to cycle through and select menu and configuration options. LEDs The faceplate of the Click 104 has three banks of LEDs. The top bank is used for detection indication, the second bank menu indication, and the third for menu indication as well as operation states. Channel 1 2 3 4 Menu PWR OK TD RD Figure 7.3 – Click 104 LEDs The Channel LEDs are detection indicators; they consist of four red LEDs numbered 1–4, each representing a channel (see Figure 7.3). An illuminated LED indicates that the associated contact is being closed (this can mean either a vehicle detection or fail-safe mode, which will be discussed later in this chapter). These indicators are dedicated to detection and have no other display purposes. The menu indicator LEDs include two rows of LEDs (see Figure 7.3). The lower row contains Level 1 indicators, while the upper row contains Level 2 indicators. Each level consists of four LEDs numbered 1–4 (left to right). Level 1 LEDs (the multicolored row) display which menu item is active. These Level 1 LEDs are dual-purpose, each indicating both menu selection as well as a normal operation state when not in Menu mode. The normal operation state functions include: ˽˽ Red (PWR) – Indicates the presence of power to the device. ˽˽ Blue (OK) – Indicates proper system operation; it extinguishes during fail-safe mode. ˽˽ Green (TD) – Indicates serial communication transmit data (from the Click 104) on either bus 1 (data) or bus 2 (control). ˽˽ Yellow (RD) – Indicates serial communication receive data (to the Click 104) on either bus 1 (data) or bus 2 (control). 51 52 CHAPTER 7  •  CLICK 104 Level 2 LEDs display configuration options for the menu items selected via the level 1 LEDs. All level 2 LEDs are red. These LEDs are dedicated to menu operation, and are extinguished when the menu is not active. Installation 1 2 Mount the Click 104 on a DIN rail over a T-bus connector. This connects the device’s control bus (bus 2) to the installation’s shared communication bus; you can connect your computer to another device on this shared bus, such as the Click 305 USB converter, to access the Click 104 to configure it using Click Supervisor. Mounting the Click 104 on the T-bus also connects it to the power source. Send detection data to the data bus (bus 1) in one of two ways. If you’re using a SmartSensor Advance or Matrix, and therefore a Click 222 or 223, connect it to the Click 104 by connecting jumper cables from the RJ-11 jacks on the faceplate of the Click 222 or 223 to the RJ-11 jacks on the faceplate of the Click 104. If you’re using a SmartSensor HD, first set the sensor to push data on the RS-232 port. Then connect wires between the TD and RD screw terminals on the protected side of the Click 200 to the TD and RD screw terminals on the Click 104. 3 If needed, daisy-chain multiple Click 104 devices together by utilizing both RJ-11 jacks on each device’s faceplate. Contact Closure Outputs Part of installing the device is wiring its contact closure outputs to the traffic controller (or data logger or other device). It’s recommended, however, that you not do this until the device is done being configured, to avoid sending any incorrect contact closures to the controller There are four contact closure outputs, for the four channels the Click 104 can handle. Each output has two screw terminals, one + and one –. The + terminals are for data, while the – are ground, or common. Each – terminal is isolated from all the other grounds; if your installation requires a common ground for each contact closure output, you’ll need to tie together the wires from those four terminals yourself. Fail-safe Mode The Click 104 receives datagrams from the connected SmartSensor. These datagrams must be mapped to device outputs, as will be discussed later in this chapter. If the Click 104 does not receive a datagram describing the device’s channels for ten seconds, the device will enter fail-safe mode. In fail-safe mode, all outputs will assert a detection condition, and will continue to do so until the device receives a datagram that updates the state of its configured channels. See the Click Supervisor section of this chapter for more information on how to change the amount of time that must elapse without the device receiving a pertinent datagram before the device enters fail-safe mode. CHAPTER 7  •  CLICK 104 Configuration The Click 104 can be configured in three ways: the rotary switch (which can only change one parameter), the front panel menu, and Click Supervisor. These three configuration methods can configure different sets of parameters; some of these parameters can be set using multiple configuration methods, and some of them can only be set using one particular method. Table 7.1 lists how each parameter may be accessed and configured. Rotary Switch Front Panel Menu Click Supervisor Baud Rate No Yes Yes Channel Input Map Yes Yes Yes Autobaud No Yes No Reset to Default No Yes Yes Description No No Yes Location No No Yes Device ID No No Yes Fail-safe Settings No No Yes To use this configuration option: Hardware mode Software mode Software mode Table 7.1 – Click 104 Configuration Options Configuration Modes The final row on the table refers to configuration modes. Hardware mode means a particular parameter is set by the rotary switch; Software mode means that parameter is set by either the front panel menu or Click Supervisor. However, this is only applicable for channel input mapping, since that is the only parameter that can be set by the rotary switch. The position of the rotary switch determines whether the device is in Hardware or Software mode: ˽˽ If the switch is set to 0, the device is in Software mode. This means that all parameters are set by the front panel menu or Click Supervisor. ˽˽ If the switch is set to any other number, the device is in Hardware mode, meaning that the channel input mapping is set by the rotary switch. If this is set, you will not be able to change the channel input mapping any other way; in Click Supervisor the option will be grayed out, and the front panel menu will only allow to view, not change, this setting. However, even when the rotary switch is set in Hardware mode, you will still be able to configure all other parameters (besides channel input mapping) using the front panel menu and Click Supervisor. 53 54 CHAPTER 7  •  CLICK 104 Note If any non-switch setting—that is, those that aren’t set by the rotary switch—has been set using both the front panel menu and Click Supervisor, whichever configuration was set most recently will take precedence. Rotary Switch The rotary switch is located on the lower part of the faceplate and can be used to change the channel input mapping. Remember that if you use this switch to set the channel input mapping, you won’t be able to use the software or the front panel menu to change this particular parameter (although you will still be able to use them to change other parameters). Channel input mapping is the process of telling the device which incoming data channels should be mapped to which outgoing channels. As mentioned earlier, the Click 104 receives serial datagrams from a sensor to which it is connected. These datagrams can contain many channels of detection data. Because the devices have fewer output channels than there are possible input datagram channels received from the sensor, you must use the channel input map to map the desired inputs to outputs. The Click 104 has four output channels; if you need more than this, you’ll need to use multiple devices daisy-chained together. As shown in the table below, the outputs are mapped sequentially—that is, they can only be mapped in numerically ordered groups of four (1–4, 5–8, etc.). If you set the switch to 3, for 9–12, then input 9 would be mapped to output 1, input 10 would be mapped to output 2, input 11 would be mapped to output 3, and input 12 would be mapped to output 4. Switch Channels 0 Software mode 1 1–4 2 5–8 3 9–12 4 13–16 5 17–20 6 21–24 7 25–28 8 29–32 9 33–36 Table 7.2 – Click 104 Rotary Switch Channel Input Map Settings CHAPTER 7  •  CLICK 104 To set the switch, insert a small screwdriver into the slot and twist until the arrow is pointed at the desired number. Front Panel Menu The front panel of the device features a push-button and three banks of LEDs for on-device configuration and monitoring. The first bank of LEDs, labeled Channel, displays the state of the contact closure outputs and is described in the Physical Features section. The two lower banks of LEDs, labeled Menu, and the push-button, labeled Mode Switch, are used for navigating through Menu mode. This section will cover how to use the menu to configure the Click 104. The lower bank of LEDs will be referred to as Level 1 and is used in selecting menu options. The upper bank will be referred to as Level 2 and is used in configuring the menu options. Level 2 LEDs only light up when a menu selection is made using the Level 1 LEDs. 1 2 3 4 Menu Level 2 Level 1 PWR OK TD RD Mode Switch Figure 7.4 – Menu Indicator LEDs and Mode Switch Note The LEDs in the lower bank also function as activity/status indicators. These functions, outlined in the Physical Features section of this chapter, are only executed when the device is not in Menu mode. In this case, the upper bank of LEDs (Level 2) remains off. Navigating through the Menu The mode switch push-button is used to enter Menu mode. To use the menu: 1 2 Press and hold the mode switch to enter Menu mode. The Level 1 LEDs will start to light up to indicate that the device is cycling through all menu options (specifics on these menu options, and which LEDs and LED combinations represent them, will be covered later in this section). Release the mode switch when you reach the desired menu option. (Pressing and hold- 55 56 CHAPTER 7  •  CLICK 104 3 4 5 6 ing again will resume cycling through menu options.) Quickly press and release the mode switch to select the current menu option. Once it’s selected, the Level 2 LEDs will start to let you configure the options for the selected menu option. Press and hold the mode switch to cycle through the submenu. The Level 2 LEDs will light to indicate that the device is cycling though all configuration options (specifics on these configuration options, and which LEDs and LED combinations represent them, will be covered later in this section). Release the mode switch once the desired configuration option is reached. Quickly press and release the mode switch to select the current configuration option. The device will exit Menu mode, and either the selected function will run or the selected configuration will be set and saved to the device. For example, the following table illustrates an example of how the mode switch and menu indicator LEDs are used in configuring the Click 104—in this case, how to autobaud bus 2. Mode Switch Action Display State None Normal operation Press and hold Channel map menu option displayed Continue holding Autobaud menu option displayed Release Autobaud menu option displayed Press and release Autobaud menu selected and first configuration parameter displayed (bus 1 autobaud) Press and hold Second configuration parameter displayed (bus 2 autobaud) Release Second configuration parameter displayed Press and release Configuration parameter selected; autobaud commences (will show intermediate LED states); autobaud finishes and normal operation resumes Table 7.3 – Menu Operation Example CHAPTER 7  •  CLICK 104 Inactivity of one minute on the mode switch will exit menu mode. Front Panel Menu Options The following figure documents the menu and configuration options available from the front panel menu. This label is also printed on the side of the device. Menu Operation • PUSH and HOLD Mode Switch to = LED On RBGY Autobaud RBGY Input Mapping 1-4 5-8 9-12 13-16 17-20 Bus 1 Bus 2 0 = SW RBGY RBGY Bus 1 Baud Rate Bus 2 Baud Rate 2 = 5-8 Menu LEDs 1 2 34 Cancel Menu LEDs 1 2 34 Cancel 4 = 13-16 1 = 1-4 3 = 9-12 5 = 17-20 9600 9600 6 = 21-24 25-28 19200 19200 7 = 25-28 29-32 38400 38400 8 = 29-32 33-36 57600 57600 9 = 33-36 21-24 90 1 Menu LEDs 1 2 34 Cancel Menu LEDs 1 2 34 Cancel cycle through menus and options. • PUSH and RBGY RELEASE Mode Switch to make Reset to Default selections. • 1 minute of Menu LEDs inactivity exits 1 2 34 menu. Cancel Rotary 7 8 Reset Switch 456 = LED Flashing 23 = LED Off Figure 7.5 – Front Panel Menu Label The menu options are displayed on the Level 1 LEDs (multicolored) and the configuration parameters are displayed on the Level 2 LEDs (all red). Channel Input Map The first configuration parameter that comes up when you’re cycling through the front panel menu is the channel input map. To select this parameter, release the push-button when the blue LED flashes. Note This parameter can also be changed using the rotary switch or Click Supervisor. As mentioned earlier, the Click 104 devices receive serial datagrams from a SmartSensor. These datagrams can contain many channels of detection data. 57 58 CHAPTER 7  •  CLICK 104 Because the devices have fewer output channels than there are possible input datagram channels received from the sensor, you must use the channel input map to map the desired inputs to outputs. The Click 104 has four outputs and therefore must be mapped to four inputs; if you need more than four channels, you’ll need to use multiple devices daisy-chained together. As shown in the table below, the outputs are mapped sequentially—that is, they can only be mapped in numerically ordered groups of four (1–4, 5–8, etc.). If you set the switch to 3, for 9–12, then input 9 would be mapped to output 1, input 10 would be mapped to output 2, input 11 would be mapped to output 3, and input 12 would be mapped to output 4. Level 1 LEDs     Input Mapping Cancel and exit menu Channels 1–4 Channels 5–8 Channels 9–12 Level 2 LEDs Channels 13–16 Channels 17–20 Channels 21–24 Channels 25–28 Channels 29–32 Channels 33–36 LED off LED on Table 7.4 – Click 104 Front Panel Menu Channel Input Map Settings See the earlier Navigating through the Menu and the Menu Operation Example sections for how to configure this parameter. Because this parameter can also be set by the rotary switch, you may need to ensure that the switch is set to 0; if it’s not, the front panel menu will be able to display but not change the channel input mapping. Autobaud The second option that comes up when you’re cycling through the front panel menu is the autobaud function. To select this option, release the push-button when the green LED comes on solid. CHAPTER 7  •  CLICK 104 Note The autobaud function can only be accessed here, on the front panel menu. This function initiates an autobaud on the communication buses (you will select which bus to autobaud on the Level 2 LEDs). An autobaud will stop data reporting on the selected port and attempt to communicate with the SmartSensor at all supported baud rates. Level 1 LEDs Autobaud Cancel and exit menu Level 2 LEDs Autobaud on bus 1 Autobaud on bus 2 LED off LED on Table 7.5 – Front Panel Menu Autobaud Settings See the earlier Navigating through the Menu and the Menu Operation Example sections for how to configure this parameter. As each baud rate is attempted, the Level 2 LEDs will sequence with a single LED illuminated from LED 1–4. If the Click 104 is successful in communicating with a SmartSensor, it will display the baud rate found, using the same Level 2 LED pattern used in selecting the baud rate (covered in the Baud Rate section of this chapter and Table 7.6). After a short time of displaying the autobaud results, the menu will return to normal operation with the baud rate setting updated (and stored) to the baud rate detected during the autobaud process. If the autobaud fails, all four Level 2 LEDs will light up for a few seconds, and then the menu will return to normal operation with the baud rate setting remaining unchanged. Baud Rate (Bus 1 and 2) The next two configuration parameters that come up in the front panel menu allow you to manually set the baud rate of the two communication buses. Bus 1 comes up first, with the yellow LED coming on solid, then bus 2, with the yellow LED flashing. Note This parameter can also be changed using Click Supervisor. 59 60 CHAPTER 7  •  CLICK 104 Baud rate for bus 1 Level 1 LEDs     Baud rate for bus 2 Cancel and exit menu 9600 bps (default) Level 2 LEDs 19200 bps 38400 bps 57600 bps LED off LED on Table 7.6 – Front Panel Menu Baud Rate Settings See the earlier Navigating through the Menu and the Menu Operation Example sections for how to configure this parameter. Reset to Default Settings The final option that comes up in the menu is Reset to Default Settings. To select this function, release the mode switch when the red LED starts flashing. Note Resetting to default settings can also be done using Click Supervisor. This function will restore all configuration settings to factory defaults, even those parameters not configured using the front panel menu: baud rate, channel input map, description field, location field, and device ID. Level 1 LEDs Level 2 LEDs   Reset to Default Settings Cancel and exit menu Reset to default settings LED off LED on Table 7.7 – Front Panel Menu Reset to Default Settings See the earlier Navigating through the Menu and the Menu Operation Example sections for how to view this parameter. After the Click 104 has reset to factory defaults, it will check the rotary switch; if it is set to any option besides 0, that channel input mapping will be applied. If resetting to factory defaults doesn’t reset the channel input mapping, check the rotary switch to see if it’s affecting this setting. CHAPTER 7  •  CLICK 104 Click Supervisor Click Supervisor is the only way to configure non-data path type parameters such as the description, location, and device ID. See Chapters 4 and 5 of this document for instructions on how to download and install Click Supervisor and how to connect to your device using the software. Note Some of the parameters mentioned below can only be configured in Click Supervisor. Others can be configured by the front panel menu and/or the rotary switch. If the rotary switch has been used to configure the channel input mapping, that parameter is considered to be in Hardware mode; it will be grayed out in Click Supervisor, meaning you can view but not change the setting. If you would like to set it using Click Supervisor, you will have to turn the rotary switch to 0. The Click 104 can be configured using the Expert driver (see Figure 7.6). Figure 7.6 – Selecting a Driver After you have made configuration changes on the driver and saved it to the Click device, the word “current” will appear after it to indicate the driver is currently loaded onto the device. The Backups option can be used to read configurations that have previously been saved to file. See Chapter 5 for more information. Expert Driver The Expert driver contains two tabs, System and Diagnostics; the System tab is then subdivided further. 61 62 CHAPTER 7  •  CLICK 104 The System > General tab lets you change general information about your device. The tab has the following parameters (see Figure 7.7 and Table 7.8): Figure 7.7 – Expert Driver General Tab Note These parameters can only be configured using Click Supervisor. Setting Description Module Allows you to enter a name and description of the device. Driver Names the driver you are currently working with. Description Shows a description of the device being configured. This is only for your information and does not affect the operation of the device. Location Displays the location of the device being configured. This is only for your information and does not affect the operation of the device. Serial Number Displays the serial number of your device. This information cannot be changed. Firmware Version Shows the version of firmware your device currently has installed. If Click Supervisor detects a discrepancy between this version and the most current version it currently has access to, you will be prompted to upgrade when you connect to the device. This information cannot be changed. Subnet ID Shows the subnet ID number. This option is currently not available. CHAPTER 7  •  CLICK 104 Device ID Gives the ID number of the device being configured, which is used to identify the device when you are connecting to it. By default, this number is the last five digits of the serial number, which can be found under the About tab or on the barcode sticker on the bottom of the device. It is recommended that you do not change this number unless another device on your network has the same ID number. Table 7.8 – Expert Driver General Tab The System > Settings tab lets you configure and view many of the parameters that are also available elsewhere on the device (see Table 7.1 earlier in this chapter for more information). The tab has the following parameters (see Figure 7.8 and Table 7.9): Figure 7.8 – Expert Driver Settings Tab Note These parameters can also be configured using the front panel menu. Also, channel input mapping can be set using the rotary switch; if the rotary switch is set to anything but 0, the input mapping drop-down will appear grayed out on this screen. Setting Description Control (T-Bus) Baud Lets you change the baud rate, in bps, of the control bus (bus 2). Data (RJ11 _232) Baud Lets you change the baud rate, in bps, of the data bus (bus 1). Input Mapping Lets you assign input datagram channels received from the sensor to the two or four output channels on the device. The outputs are mapped sequentially—that is, they can only be mapped in numerically ordered groups of four. See Input Mapping in either the Rotary Switch or Front Panel Menu sections in this chapter for more information. 63 64 CHAPTER 7  •  CLICK 104 Failsafe Enabled Turns on and off fail-safe mode. For more information on what this mode is, see the Fail-safe Mode section earlier in this chapter. Failsafe Timeout (Sec) Lets you select what length of time, in seconds, the device can go without receiving datagrams describing the device’s channels before it goes into fail-safe mode. The default is 10 seconds. Table 7.9 – Expert Driver Settings Tab Under the Diagnostics tab, you can run diagnostics on your device (see Figure 7.9). Figure 7.9 – Expert Driver Diagnostics Tab Click the General button to run diagnostics on the items listed below the button. If a problem is detected, the program will display a red square next to the item in question. If no problems are detected, a green circle will appear. Click Failsafe Status to check whether any of the channels are in fail-safe mode. If a fail-safe condition is detected, a red square will be displayed below the button. If no problems are detected, a green circle will appear. Once you have finished, use the menu bar at the top of the screen to save your settings, return to the Select Driver screen, and more. ˽˽ The Save menu allows you to save your settings. Select Save to File to save your settings to a file. Selecting this will open a directory box, allowing you to name your settings file. This file will always be saved in the Wavetronix folder created when you installed Click Supervisor, under Wavetronix > ClickHome > Drivers > 104 > User. You can also select Save to Device to save your settings to your Click 104. CHAPTER 7  •  CLICK 104 Note If you do not save your settings to your Click 104, they will be lost the next time you power the device down. ˽˽ The Tools menu contains five options for working with your device. Reset > System power cycles your device, while Reset > Factory Default restores your device to the settings with which it was shipped. Restore will restore the driver to the settings currently saved on the Click 104, erasing any unsaved changes. Upgrade can be used to manually upgrade to the most current firmware for your device. Hex View changes the view of certain settings in the driver to hexadecimal. ˽˽ Clicking the Quit menu exits the driver and returns you to the Click Supervisor main page. Once you have finished, click Save on the menu bar to save your settings. 65 Click 110 — 4-channel Contact Closure Eurocard 8 In this chapter ˽˽ ˽˽ ˽˽ ˽˽ Physical Features Installation and Wiring Operation Configuration 8 The Click 110 is used to report vehicle data to a MIDAS outstation when used with Wavetronix SmartSensors. This card plugs directly into an outstation and reports four channels of detection. Because the Click 110 has two independent serial buses, it can be configured without interfering with data reporting. Figure 8.1 – The Click 110 68 CHAPTER 8  •  CLICK 110 Physical Features The following sections describe the physical features of the Click 110 card. Figure 8.2 – Diagram of the Click 110 Communication Ports The Click 110 contains two independent serial communications ports. Each port is made up of two RJ-11 connectors, which make it simple to daisy-chain multiple Click 110 cards together and create a RS-485 bus. The two RJ-11 RS-485 data buses can be connected to a SmartSensor through a Click 200 surge protection module, or through a serial data converter. Typically, one bus is used to report vehicle data, and the other is used for configuration. As both buses are identical it does not matter which is used for data or configuration. Alternatively, a single bus could be used for both data and configuration, but data reporting would be temporarily halted during configuration. During this time, the Click 110 will enter failsafe mode if vehicle data is not reported for ten seconds. LEDs The faceplate of the Click 110 has four banks of LEDs. The top bank is used for detection indication, the second bank for fault indication, the third for menu indication, and the fourth for menu indication as well as operation states. CHAPTER 8  •  CLICK 110 Detection 1 2 3 4 Fault Menu 1 PWR 2 MF 3 TD 4 RD Figure 8.3 – Click 110 LEDs The detection indicator LEDs consist of four red LEDs numbered 1–4, each representing a channel (see Figure 8.3). An illuminated LED indicates the presence of a vehicle. These indicators are dedicated to detection and have no other display purposes. The fault indicator LEDs consist of four dual-color (green / yellow) LEDs numbered 1–4, each representing the channel with the corresponding number (see Figure 8.3). ˽˽ Illuminated green LED – Indicates a no-fault condition. ˽˽ Illuminated yellow LED – Indicates a fault condition which has existed for less than one minute. ˽˽ Extinguished LED – Indicates a fault condition which has existed for more than one minute. The menu indicator LEDs include two rows of LEDs (see Figure 8.3). The lower row contains Level 1 indicators, while the upper row contains Level 2 indicators. Each level consists of four LEDs numbered 1–4 (left to right). Level 1 LEDs display which menu is active. These Level 1 LEDs are dual-purpose, each indicating both menu selection as well as a normal operation state when not in Menu mode. The normal operation state functions include: ˽˽ Red (PWR) – Indicates the presence of power to the device. ˽˽ Blue (MF) – Illuminates when the master fault output is in the no-fault condition. The LED is extinguished in the fault condition. ˽˽ Green (TD) – Indicates serial communication transmit data (from the Click 110) on either RS-485 bus 1 or RS-485 bus 2. ˽˽ Yellow (RD) – Indicates serial communication receive data (to the Click 110) on either RS-485 bus 1 or RS-485 bus 2. Level 2 LEDs display configuration options. All level 2 LEDs are red. These LEDs are dedicated to menu operation, and are extinguished when the menu is not active. 69 70 CHAPTER 8  •  CLICK 110 Push-buttons The faceplate of the Click 110 features two push-buttons. The upper push-button, labeled Mode Switch, is used to cycle through and select menu and configuration options. The lower push-button, labeled Reset, will reboot the Click 110. The Click 110 can be rebooted in any of three ways: via the reset switch, from the outstation via the 64 way DIN 41612, or by power cycling the device. A reboot is the only way to clear a latched fault condition. To reboot using the reset switch, simply press and release the push-button. DIP Switches Just behind the faceplate of the Click 110, on the circuit board, is a set of DIP switches. These switches are used to configure the Click 110 in Hardware mode. All settings, with the exception of Outstation mode and disabling fault latching, are also configurable via Software mode (front panel menu, or Click Supervisor). See the DIP Switches section of this chapter for more information. Installation and Wiring Use the following steps to install and wire Click 110 devices: 1 2 3 4 If you’re using hardware configuration, set all DIP switches before installing Click 110 devices (this will be covered in the DIP Switches section of this chapter). Insert the cards into the rack. Daisy-chain together all the cards you intend to use in your installation, using short RJ-11 jumper cables. Connect the first Click 110 card to the SmartSensor via a surge protector, such as the Click 200, 222, or 223, and a 60" RJ-11 patch cord. For your information, this guide includes the pinout for the 64-pin backplane connector on the the back of the Click 110. However, the pins behave differently depending on which Outstation mode the device is set to, Peek or Siemens (for more on Outstation mode, see the DIP Switches section of this chapter); the differences all relate to the fault outputs and whether they are normally opened or normally closed. For this reason, there are two pinout tables on the following pages. The first is the pinout when the Click 110 is set to Peek; the second is when it’s set to Siemens. Note The pins that change between the two tables will be highlighted in light gray for ease of comparison. CHAPTER 8  •  CLICK 110 Description Pin A1 Pin Description Channel 1 fault, normally closed B1 A1 Channel 1, normally closed Channel 1 common B2 A2 No connection Channel 1 fault common B3 A3 Channel 1, normally open Master fault, normally closed B4 A4 No connection No connection B5 A5 No connection No connection B6 A6 No connection No connection B7 A7 Master fault, normally open Channel 2, normally closed B8 A8 Channel 2 fault, normally closed No connection B9 A9 Channel 2 common Channel 2, normally open B10 A10 Channel 2 fault common No connection B11 A11 Master fault common No connection B12 A12 No connection No connection B13 A13 No connection Chassis ground B14 A14 No connection Channel 3 fault, normally closed B15 A15 Channel 3, normally closed Channel 3 common B16 A16 No connection Channel 3 fault common B17 A17 Channel 3, normally open No connection B18 A18 No connection No connection B19 A19 No connection No connection B20 A20 No connection No connection B21 A21 No connection Channel 4, normally closed B22 A22 Channel 4 fault, normally closed No connection B23 A23 Channel 4 common Channel 4, normally open B24 A24 Channel 4 fault common No connection B25 A25 No connection No connection B26 A26 No connection No connection B27 A27 No connection No connection B28 A28 No connection No connection B29 A29 Reset +DC (12–24 VDC) B30 A30 No connection No connection B31 A31 No connection -DC (common) B32 A32 No connection Figure 8.4 – Click 110 Pinout with Peek Outstation 71 72 CHAPTER 8  •  CLICK 110 Description Pin A1 Pin Description Channel 1 fault, normally open B1 A1 Channel 1, normally closed Channel 1 common B2 A2 No connection Channel 1 fault common B3 A3 Channel 1, normally open Master fault, normally open B4 A4 No connection No connection B5 A5 No connection No connection B6 A6 No connection No connection B7 A7 Master fault, normally closed Channel 2, normally closed B8 A8 Channel 2 fault, normally open No connection B9 A9 Channel 2 common Channel 2, normally open B10 A10 Channel 2 fault common No connection B11 A11 Master fault common No connection B12 A12 No connection No connection B13 A13 No connection Chassis ground B14 A14 No connection Channel 3 fault, normally open B15 A15 Channel 3, normally closed Channel 3 common B16 A16 No connection Channel 3 fault common B17 A17 Channel 3, normally open No connection B18 A18 No connection No connection B19 A19 No connection No connection B20 A20 No connection No connection B21 A21 No connection Channel 4, normally closed B22 A22 Channel 4 fault, normally open No connection B23 A23 Channel 4 common Channel 4, normally open B24 A24 Channel 4 fault common No connection B25 A25 No connection No connection B26 A26 No connection No connection B27 A27 No connection No connection B28 A28 No connection No connection B29 A29 Reset +DC (12–24 VDC) B30 A30 No connection No connection B31 A31 No connection -DC (common) B32 A32 No connection Figure 8.5 – Click 110 Pinout with Siemens Outstation CHAPTER 8  •  CLICK 110 Preparing the SmartSensor In addition to wiring the SmartSensor to the Click 110, you must also make sure that the SmartSensor is configured correctly. Because the Click 110 device receives serial datagrams from the sensor, the sensor must be configured to report data properly for each application. This includes configuring the sensor for the following: ˽˽ ˽˽ ˽˽ ˽˽ Dual-loop speed trap or one-loop configuration Predefined pulse duration, or pulse duration emulating a given loop size Z4 protocol Physical loop spacing to emulate Fail-safe Mode The Click 110 receives datagrams from the connected SmartSensor. These datagrams must be mapped to device outputs (covered in the next section). If the Click 110 does not receive a datagram containing a channel that is mapped to its outputs for ten seconds, the device will enter fail-safe mode. In fail-safe mode, all enabled outputs will assert a detection and fault condition. The master fault output will also assert. How the device gets out of fail-safe mode is determined by the fault latch configuration option, which will be covered at the end of the DIP Switches section of this chapter. Configuration The Click 110 can be configured in three ways: DIP switches, the front panel menu, and Click Supervisor. These three different configuration methods can configure different sets of options; some of these parameters can be set using multiple configuration methods, and some of them can only be set using one particular method. Table 8.1 lists how each parameter may be accessed and configured. DIP Switch Front Panel Menu Click Supervisor Baud Rate Yes Yes Yes Channel Enable Yes Yes Yes Channel Input Map Yes Yes Yes Fault Latch Disable Yes Read-only Read-only Outstation Mode Yes Read-only Read-only Autobaud No Yes No Reset to Default No Yes Yes Description No No Yes 73 74 CHAPTER 8  •  CLICK 110 Location No No Yes Device ID No No Yes Fault Status No Fault Indicators Read-only To use this configuration feature: Hardware Configu- Software Configuration Mode ration Mode Software Configuration Mode Table 8.1 – Click 110 Configuration Options The final row on the table refers to configuration modes. The DIP switches can be used to choose between Hardware and Software modes. If the switches are set to Hardware mode, the DIP switches will be used to change configuration options. If the switches are set to Software mode, the front panel menu and Click Supervisor will be used to change configuration options. This will be discussed in greater detail in the DIP Switches section of this chapter. Note Any setting which has been configured via the DIP switches will be read-only in Click Supervisor and the front panel menu. DIP Switches The DIP switches are located on the circuit board behind the faceplate. The side of the faceplate contains information on configuring using the DIP switches, as shown in Figure 8.6. Figure 8.6 – Click 110 DIP Switches CHAPTER 8  •  CLICK 110 The Click 110 features three DIP switches labeled S1, S2 and S3 on the label and in the picture above. (The fourth switch, labeled S4, is currently not used.) Each DIP switch is used to configure one or two different settings, for a total of six different configurable parameters: ˽˽ ˽˽ ˽˽ ˽˽ ˽˽ ˽˽ Bus 1 baud rate Bus 2 baud rate Channel enable Channel input map Outstation mode Fault latch Each parameter (except fault latch and outstation mode) has a way to pick between Hardware/Software modes. If Software mode is selected, the parameter must be configured using the front panel menu or Click Supervisor. If Hardware mode is selected, the parameter can be configured using the switches. In this case, the setting can be viewed but not changed via Click Supervisor and the front panel menu. Baud Rate The baud rates for the two RS-485 buses, bus 1 and bus 2 (see the faceplate of the device for which RJ-11 jacks are for each bus), may be independently configured using the switches on the first DIP switch, labeled S1. Note This parameter can also be changed using the front panel menu or Click Supervisor. The switch patterns for the two parameters are identical, but bus 1 is configured using switches 1–4 (S1:1–4) while bus 2 is configured using switches 5–8 (S1:5–8). 75 76 CHAPTER 8  •  CLICK 110 S1: Bus 1 Baud Rate S2: Bus 2 Baud Rate 1 2 3 4 Value 5 6 7 8 Value Off – – – Software mode Off – – – Software mode On Off Off Off 9600 bps On Off Off Off 9600 bps On Off Off On 19200 bps On Off Off On 19200 bps On Off On Off 38400 bps On Off On Off 38400 bps On Off On On 57600 bps On Off On On 57600 bps On On Off Off 9600 bps On On Off Off 9600 bps On On Off On 9600 bps On On Off On 9600 bps On On On Off 9600 bps On On On Off 9600 bps On On On On 9600 bps On On On On 9600 bps Table 8.2 – DIP Switch Baud Rate Settings for Bus 1 (left) and Bus 2 (right) As these tables show, if the switches are in any configuration besides the ones laid out in the first few rows of these tables, that bus will default to 9600 bps. If switch 1/5 is on (up), Hardware mode is selected, meaning the baud rate can be configured using the DIP switches (as shown in Table 8.2 above), and Click Supervisor and the front panel menu will be able to display the current setting, but not change it. (Dashes in the table above indicate that the other three switches don’t affect Software mode selection.) If switch 1/5 is off (down), Software mode is selected and Click Supervisor and the front panel menu will be able to both display and change the current setting. Channel Enable The next parameter that can be configured is which of the output channels are enabled. Enabling output channels is located on the second DIP switch, labeled S2, and is controlled with switches 4–8 (S2:4–8). Note This can also be changed using the front panel menu or Click Supervisor. A disabled output will never enter the detection state, and will never indicate a fault condition. Any combination of outputs can be enabled. Due to limited space on the faceplate side label, not all combinations of enabled and disabled channels are listed. A complete table is shown below. CHAPTER 8  •  CLICK 110 S2: Channel Enable 4 5 6 7 8 Channel Off – – – – Software mode On Off Off Off Off All off On Off Off Off On Channel 4 on On Off Off On Off Channel 3 on On Off Off On On Channels 3 and 4 on On Off On Off Off Channel 2 on On Off On Off On Channels 2 and 4 on On Off On On Off Channels 4 and 3 on On Off On On On Channels 2, 3, and 4 on On On Off Off Off Channel 1 on On On Off Off On Channels 1 and 4 on On On Off On Off Channels 1 and 3 on On On Off On On Channels 1, 3, and 4 on On On On Off Off Channels 1 and 2 on On On On Off On Channels 1, 2, and 4 on On On On On Off Channels 1, 2, and 3 on On On On On On Channels 1, 2, 3, and 4 on Table 8.3 – DIP Switch Channel Enable Settings If switch 4 (S2:4) is on (up), Hardware mode is selected, meaning the channels can be enabled using the DIP switches (as shown in Table 8.3 above), and Click Supervisor and the front panel menu will be able to display the current setting, but not change it. (Dashes in the table above indicate that the other three switches don’t affect Software mode selection.) If switch 4 is off (down), Software mode is selected and Click Supervisor and the front panel menu will be able to both display and change the current setting. Channel Input Map The next set of switches is used in mapping channel inputs. Mapping input datagram channels to output channels is configured on the third DIP switch, labeled S3, using switches 1–4 (S3:1–4). Note This parameter can also be changed using the front panel menu or Click Supervisor. 77 78 CHAPTER 8  •  CLICK 110 As mentioned earlier, the Click 110 device receives serial datagrams from a SmartSensor. These datagrams can contain many channels of detection data. Because the Click 110 has four output channels, only four input datagram channels, received from the sensor, can be output by each device. (If you need more than four channels, consider using multiple devices.) As shown in the table below, the outputs are mapped sequentially—that is, they can only be mapped in numerically ordered groups of four (1–4, 5–8, etc.). If you chose, for example, 17–20, then input 17 would be mapped to output 1, input 18 would be mapped to output 2, input 19 would be mapped to output 3, and input 20 would be mapped to output 4. If fewer than four outputs are required, any contact closure output can be disabled. A disabled output will never enter the detection state, and will never indicate a fault condition. Depending on whether each channel is enabled or disabled, the input mapped to it will also be enabled or disabled. S3: Channel Input Map 1 2 3 4 Channel Off – – – Software mode On Off Off Off 1–4 On Off Off On 5–8 On Off On Off 9–12 On Off On On 13–16 On On Off Off 17–20 On On Off On 21–24 On On On Off 25–28 On On On On 29–32 Table 8.4 – DIP Switch Channel Input Map Settings If switch 1 (S3:1) is on (up), Hardware mode is selected, meaning the inputs can be mapped using the DIP switches (as shown in Table 8.4 above), and Click Supervisor and the front panel menu will be able to display the current setting, but not change it. (Dashes in the table above indicate that the other three switches don’t affect Software mode selection.) If switch 1 is off (down), Software mode is selected and Click Supervisor and the front panel menu will be able to both display and change the current setting. Outstation Mode Also on this switch is the outstation mode. This is configured on the third DIP switch, labeled S3, using switch 6 (S3:6). CHAPTER 8  •  CLICK 110 Note This parameter can only be changed using the DIP switches. The Click 110 can be used with two brands of outstations, Peek and Siemens. Because of differences in the way these two operate, you need to use switch 6 on the S3 DIP switch to tell the Click 110 with which outstation it is going to be used. If S3:6 is off (down), the Click 110 is set to work with a Peek brand outstation. If S3:6 is on (up), the Click 110 is set to work with a Siemens brand outstation. S3: Outstation Mode 6 State Off Peek On Siemens Table 8.5 – DIP Switch Outstation Mode Settings Note In Peek mode the Isolated fault output channels are N/C; in Siemens mode they are N/O. The Master Fault output relay is also opposite when switching between the two modes. Refer to the pinout table earlier in this chapter for more information. Because Outstation mode can only be changed using the DIP switches (though it can be viewed elsewhere), there is no option for selecting Hardware or Software configuration modes. Fault Latch The last option that can be configured on the DIP switches is fault latching. This is configured on the third DIP switch, labeled S3, using switch 8 (S3:8). Note This parameter can only be changed using the DIP switches. Fault latching involves how the Click 110 reacts when the flow of data from the connected SmartSensor is interrupted. As mentioned in the Fail-safe Mode section above, if the Click 110 does not receive a datagram containing a channel that is mapped to its outputs for ten 79 80 CHAPTER 8  •  CLICK 110 seconds, the device will enter fail-safe mode. In fail-safe mode, all enabled outputs will assert a detection and fault condition. The master fault output will also assert. As long as the flow of data is reestablished within one minute, the device will exit the mode and continue normal operation. How the device reacts when data flow is not reestablished is determined by whether fault latch is enabled or disabled. If S3:8 is on (up), fault latching is disabled. This means that if the Click 110 starts to receive data again at any point after the one-minute mark, the device will exit fail-safe mode and continue normal operation. If S3:8 is off (down), fault latching is enabled. In this case, if the fault condition has existed for more than one minute, normal mode can only be restored by rebooting (front panel reset switch, power cycle, or remote reset via outstation), even if the device has started to receive data again. S3: Fault Latch 8 State Off Enable On Disable Table 8.6 – DIP Switch Fault Latch Settings Because fault latching can only be changed using the DIP switches, there is no need (and no option) for selecting Hardware or Software configuration modes. Front Panel Menu The front panel of the device features two push-buttons and four banks of LEDs for ondevice configuration and monitoring. The first two banks of LEDs, labeled Detection and Fault, and the lower push-button, labeled Reset, are for basic monitoring and configuration and are explained in the Physical Features section. The two lower banks of LEDs, labeled Menu, and the first push-button, labeled Mode Switch, are used for navigating through Menu mode. This section will cover how to use these features and the menu to configure the Click 110. The lower bank of LEDs will be referred to as Level 1 and is used is selecting menu options. The upper bank will be referred to as Level 2 and is used in configuring the menu options. CHAPTER 8  •  CLICK 110 Menu Level 2 1 2 3 4 Level 1 PWR MF TD RD Mode Switch Figure 8.7 – Menu Indicator LEDs and Mode Switch Note The LEDs in the lower bank also function as activity/status indicators. These functions, outlined in the Physical Features section of this chapter, are only executed when the device is not in Menu mode. In this case, the upper bank of LEDs (Level 2) remains off. Navigating through the Menu The mode switch push-button is used to enter Menu mode. To use the menu: 1 2 3 4 5 6 Press and hold the mode switch to enter Menu mode. The Level 1 LEDs will start to light up to indicate that the device is cycling through all menu options (specifics on these menu options, and which LEDs and LED combinations represent them, will be covered later in this section). Release the mode switch when you reach the desired menu option. (Pressing and holding again will resume cycling through menu options.) Quickly press and release the mode switch to select the current menu option. Once it’s selected, the Level 2 LEDs will start to let you configure the options for the selected menu option. Press and hold the mode switch to cycle through the submenu. The Level 2 LEDs will light up to indicate that the device is cycling though all configuration options (specifics on these configuration options, and which LEDs and LED combinations represent them, will be covered later in this section). Release the mode switch once the desired configuration option is reached. Quickly press and release the mode switch to select the current configuration option. The device will exit Menu mode, and either the selected function will run or the selected configuration will be set and saved to the device. Inactivity of one minute on the mode switch will exit menu mode and resume normal operation. The following table illustrates an example of how the mode switch and menu indicator LEDs are used in configuring the Click 110—in this case, how to autobaud bus 2. 81 82 CHAPTER 8  •  CLICK 110 Mode Switch Action Display State None Normal operation Press and hold Channel map menu option displayed Continue holding Autobaud menu option displayed Release Autobaud menu option displayed Press and release Autobaud menu selected and first configuration parameter displayed (bus 1 autobaud) Press and hold Second configuration parameter displayed (bus 2 autobaud) Release Second configuration parameter displayed (bus 2 autobaud) Press and release Configuration parameter selected and normal operation resumes Table 8.7 – Menu Operation Example Front Panel Menu Options The following figure documents the menu and configuration options available from the front panel menu. This label is also printed on the side of the Click 110 (on the opposite side from the DIP switches). CHAPTER 8  •  CLICK 110 Level 1 LEDs Using the Mode Switch to View or Modify Configuration Level 2 LEDs Level 1 LEDs 1 Menu On 2 3 4 Blinking Off • Press and hold Mode Switch to cycle through options • Press and release Mode Switch to select option Baud Rate = 9600 (default) Baud Rate = 19200 Level 2 LEDs Baud Rate Setting for Bus 1 Channel Enable Fault Latch Baud Rate = 19200 Level 2 LEDs Channel Input Map Cancel and Exit Menu Channel: 1 2 3 4 Level 1 LEDs Channel Enable All Channels Disabled (default) Channels 5 - 8 Enable Channel 1 Channels 13 - 16 Level 2 LEDs Channels 29 - 32 Cancel and Exit Menu Autobaud Settings Perform Autobaud on Bus 1 Perform Autobaud on Bus 2 Cancel and Exit Menu NOTE: If a settings DIP switch is not set to SW Config, then the current setting is displayed but cannot be modified using the Mode Switch. Enable Channel 3 Cancel and Exit Menu Channels 21 - 24 Channels 25 - 28 Enable Channel 2 Enable Channel 4 Channels 17 - 20 Level 2 LEDs Baud Rate = 57600 Channels 1 - 4 Channels 9 - 12 Level 1 LEDs Baud Rate = 38400 Baud Rate = 115200 Reset to Default Settings Level 1 LEDs Baud Rate Setting for Bus 2 Baud Rate = 9600 (default) Outstation Support Settings Cancel and Exit Menu Baud Rate = 57600 Cancel and Exit Menu Level 1 LEDs Baud Rate Setting for Bus 2 Level 1 LEDs Baud Rate = 38400 Baud Rate = 115200 Channel Input Map Autobaud Settings Baud Rate Setting for Bus 1 Level 1 LEDs Level 2 LEDs Level 1 LEDs Level 2 LEDs Level 1 LEDs Level 2 LEDs Fault Latch Fault Latch Enabled (default) Fault Latch Disabled Outstation Support Settings Peek Outstation Support (default) Siemens Outstation Support Reset to Default Settings Reset to Default Settings Cancel and Exit Menu Figure 8.8 – Front Panel Menu Label As shown above, the menu options are displayed on the Level 1 LEDs and the configuration parameters are displayed on the Level 2 LEDs. If a configuration parameter has been set using the DIP switches (meaning that parameter is currently set to Hardware mode), you cannot change it using the front panel menu. After selecting that particular menu option from the Level 1 LEDs, the Level 2 LEDs will display the configuration option set in the DIP switches and will not allow you to switch from that option. The only way to exit at this point is to press the push-button once. Channel Input Map The first configuration parameter that comes up when you’re cycling through the front panel menu is the channel input map. To select this parameter, release the push-button when the yellow LED comes on solid. 83 84 CHAPTER 8  •  CLICK 110 Note This parameter can also be changed using the DIP switches or Click Supervisor. As mentioned earlier, the Click 110 device receives serial datagrams from a SmartSensor. These datagrams can contain many channels of detection data. Because the Click 110 has four output channels, only four input datagram channels, received from the sensor, can be output by each device. (If you need more than four channels, consider using multiple devices.) As shown in the table below, the outputs are mapped sequentially—that is, they can only be mapped in numerically ordered groups of four (1–4, 5–8, etc.). If you chose, for example, 17–20, then input 17 would be mapped to output 1, input 18 would be mapped to output 2, input 19 would be mapped to output 3, and input 20 would be mapped to output 4. If fewer than four outputs are required, any contact closure output can be disabled (covered later in this section). A disabled output will never enter the detection state, and will never indicate a fault condition. Depending on whether each channel is enabled or disabled, the input mapped to it will also be enabled or disabled. Level 1 LEDs Input Mapping Channels 1–4 Channels 5–8 Channels 9–12 Channels 13–16 Level 2 LEDs Channels 17–20 Channels 21–24 Channels 25–28 Channels 29–32 LED off Cancel and exit menu LED on Table 8.8 – Front Panel Menu Channel Input Map Settings See the earlier Navigating through the Menu and the Menu Operation Example sections for how to configure this parameter. Because this parameter can also be set by the DIP switches, you may need to ensure that the DIP switches are set to Software configuration mode; if they are set to Hardware, the front panel menu will be able to display but not change these settings. CHAPTER 8  •  CLICK 110 Autobaud The second option that comes up when you’re cycling through the front panel menu is the autobaud function. This option is indicated by the green LED coming on solid. Note The autobaud function can only be accessed here, on the front panel menu. This function initiates an autobaud on the RS-485 buses (you will select which bus to autobaud on the Level 2 LEDs). An autobaud will stop data reporting on the selected port and attempt to communicate with the SmartSensor at all supported baud rates. Level 1 LEDs Autobaud Autobaud on bus 1 Level 2 LEDs Autobaud on bus 2 LED off Cancel and exit menu LED on Table 8.9 – Front Panel Menu Autobaud Settings See the earlier Navigating through the Menu and the Menu Operation Example sections for how to configure this parameter. As each baud rate is attempted, the Level 2 LEDs will sequence with a single LED illuminated from LED 1–4. If the Click 110 is successful in communicating with a SmartSensor, it will display the baud rate found, using the same Level 2 LED system used in selecting the baud rate (covered in the Baud Rate section of this chapter and Table 8.10). After a short time of displaying the autobaud results, the menu will return to normal operation. If the autobaud fails, all four Level 2 LEDs will flash once, and then the menu will return to normal operation. Note If the baud rate of either of the RS-485 buses was configured using the DIP switches (so that parameter is set to Hardware mode), the Level 2 LED configuration options for that bus will not be displayed (the LED option will never come on). If both RS-485 buses are configured using the DIP switches, the Level 1 LED menu option for autobaud will not be displayed (the green LED option will never come on). 85 86 CHAPTER 8  •  CLICK 110 Baud Rate (Bus 1 and 2) The next two configuration parameters that come up in the front panel menu allow you to manually set the baud rate of the two RS-485 buses. Bus 1 comes up first, with the green and yellow LEDs coming on together; bus 2 comes up second, with the blue LED glowing solid. Note This parameter can also be changed using the DIP switches or Click Supervisor. Level 1 LEDs Baud rate for bus 1 Baud rate for bus 2 9600 bps (default) 19200 bps Level 2 LEDs 38400 bps 57600 bps LED off Cancel and exit menu LED on Table 8.10 – Front Panel Menu Baud Rate Settings See the earlier Navigating through the Menu and the Menu Operation Example sections for how to configure this parameter. Because this parameter can also be set by the DIP switches, you may need to ensure that the DIP switches are set to Software configuration mode; if they are set to Hardware, the front panel menu will be able to display but not change these settings. Channel Enable The next configurable parameter is enabling output channels. To select this parameter, release the push-button when the blue and yellow LEDs come on. Note This parameter can also be changed using the DIP switches or Click Supervisor. A disabled output will never enter the detection state, and will never indicate a fault condition. Any combination of outputs can be enabled. Due to limited space on the side label, not CHAPTER 8  •  CLICK 110 all combinations of enabled and disabled channels are listed. A complete table is shown below. Level 1 LEDs Channel Enable All off (default) Channel 4 on Channel 3 on Channels 3 and 4 on Channel 2 on Channels 2 and 4 on Channels 2 and 3 on Channels 2, 3, and 4 on Level 2 LEDs Channel 1 on Channels 1 and 4 on Channels 1 and 3 on Channels 1, 3, and 4 on Channels 1 and 2 on Channels 1, 2, and 4 on Channels 1, 2, and 3 on Channels 1, 2, 3, and 4 on LED off Cancel and exit menu LED on Table 8.11 – Front Panel Menu Channel Enable Settings Note If you are configuring the device with the front panel menu, it’s vital that you set up your enabled channels; if you don’t, as you can see in the table, it will default to all channels being disabled and the device will not work. See the earlier Navigating through the Menu and the Menu Operation Example sections for how to configure this parameter. Because this parameter can also be set by the DIP switches, you may need to ensure that the 87 88 CHAPTER 8  •  CLICK 110 DIP switches are set to Software configuration mode; if they are set to Hardware, the front panel menu will be able to display but not change these settings. Fault Latch Although the fault latch can only be configured via the DIP switches, you can use the front panel menu to view the current fault latching configuration, as shown below (see the Fault Latch section of the DIP Switches section above for more information on this parameter). Note This parameter can only be viewed on the front panel menu; it can only configured using the DIP switches. Level 1 LEDs Level 2 LEDs Fault Latch Fault latch enabled Fault latch disabled LED off LED on Table 8.12 – Front Panel Menu Fault Latch Settings See the earlier Navigating through the Menu and the Menu Operation Example sections for how to view this parameter. After you have viewed the fault latch configuration, press and release the mode switch to exit. Outstation Mode The next option you come across in the front panel menu is outstation mode. Like fault latch, this is read-only in the front panel menu; you can use it to view which kind outstation the device is set to use, Peek or Siemens. To modify this setting, use the DIP switches (see the DIP Switches section for more information). Level 1 LEDs Level 2 LEDs Outstation Mode Peek Outstation Support Siemens Outstation Support LED off LED on Table 8.13 – Front Panel Menu Fault Latch Settings See the earlier Navigating through the Menu and the Menu Operation Example sections for how to view this parameter. CHAPTER 8  •  CLICK 110 After you have viewed the outstation mode configuration, press and release the mode switch to exit. Reset to Default Settings The final option that comes up in the menu is Reset to Default Settings. To select this function, release the mode switch when the red LED starts flashing. Note This parameter can only be configured using the DIP switches. This function will restore all configuration settings to factory defaults, even those parameters not configured using the front panel menu: baud rate, channel map, channel enable, description field, location field, and device ID. (The exceptions are fault latch and outstation mode, which are not reset by this option.) Level 1 LEDs Level 2 LEDs Reset to Default Settings Reset to default settings Cancel and exit menu LED off LED on Table 8.14 – Front Panel Menu Reset to Default Settings See the earlier Navigating through the Menu and the Menu Operation Example sections for how to view this parameter. After the Click 110 has reset to factory defaults, it will check the DIP switches; if any of them are set to Hardware mode, it will apply those settings to the parameter in question. If resetting to factory defaults doesn’t change certain settings the way you expected it to, check the DIP switches to see if they are causing settings to be changed to something other than the default. Click Supervisor Click Supervisor is the only way to configure non-data path type parameters such as the description, location, and device ID. See Chapters 4 and 5 of this document for instructions on how to download and install Click Supervisor and how to connect to your device using the software. 89 90 CHAPTER 8  •  CLICK 110 Note Some of the parameters mentioned below can only be configured in Click Supervisor. Others can be configured by the front panel menu and/or the DIP switches. In the case of the DIP switches, if that parameter is set to Hardware mode, it will be grayed out in Click Supervisor, meaning you can view but not change the setting. If you would like to set it using Click Supervisor, you will have to flip those switches on the device. The Click 110 can be configured using the Expert driver (see Figure 8.9). Figure 8.9 – Selecting a Driver After you have made configuration changes on the driver and saved it to the Click device, the word “current” will appear after it to indicate the driver is currently loaded onto the device. The Backups option can be used to read configurations that have previously been saved to file. See Chapter 5 for more information. Expert Driver The Expert driver contains two tabs, System and Diagnostics; the System tab is then subdivided further. The System > General tab lets you change general information about your device. The tab has the following parameters (see Figure 8.10 and Table 8.15): CHAPTER 8  •  CLICK 110 Figure 8.10 – Expert Driver General Tab Note This parameter can only be configured using Click Supervisor. Setting Description Module Allows you to enter a name and description of the device. Driver Names the driver you are currently working with. Description Shows a description of the device being configured. This is only for your information and does not affect the operation of the device. Location Displays the location of the device being configured. This is only for your information and does not affect the operation of the device. Serial Number Displays the serial number of your device. This information cannot be changed. Firmware Version Shows the version of firmware your device currently has installed. If Click Supervisor detects a discrepancy between this version and the most current version it currently has access to, you will be prompted to upgrade when you connect to the device. This information cannot be changed. Subnet ID Shows the subnet ID number. This option is currently not available. Device ID Gives the ID number of the device being configured, which is used to identify the device when you are connecting to it. By default, this number is the last five digits of the serial number, which can be found under the About tab or on the barcode sticker on the bottom of the device. It is recommended that you do not change this number unless another device on your network has the same ID number. Table 8.15 – Expert Driver General Tab 91 92 CHAPTER 8  •  CLICK 110 The System > Settings tab lets you configure and view many of the parameters that are also available elsewhere on the device (see Table 8.1 earlier in this chapter for more information). The tab has the following parameters (see Figure 8.11 and Table 8.16): Figure 8.11 – Expert Driver Settings Tab Note These parameters can also be configured using the DIP switches or the front panel menu; if in the DIP switches they are set to Hardware mode, the parameters will appear grayed out on this screen. Setting Description Baud Rate for Bus 1 Lets you change the baud rate, in bps, of bus 1. Baud Rate for Bus 2 Lets you change the baud rate, in bps, of bus 2. Input Mapping Lets you assign input datagram channels received from the sensor to the device’s four output channels. The outputs are mapped sequentially—that is, they can only be mapped in numerically ordered groups of four (1–4, 5–8, etc.). See Input Mapping in either the DIP Switches or Front Panel Menu sections in this chapter for more information. Channel Enable Lets you choose which of the output channels are enabled. Any combination of outputs can be enabled. A disabled output will never enter the detection state, and will never indicate a fault condition. Fault Latch Lets you view if Fault Latch is enabled. See Fault Latch in the DIP Switches section of this chapter for more information. Fault latching can only be configured using the DIP switches, so this parameter will always be grayed out, allowing you to view but not change the configuration of this parameter. CHAPTER 8  •  CLICK 110 Outstation Mode Lets you view which brand of outstation, Peek or Siemens, the device is currently set to work with. See Outstation Mode in the DIP Switches section of this chapter for more information. Outstation mode can only be configured using the DIP switches, so this parameter will always be grayed out, allowing you to view but not change this parameter. Table 8.16 – Expert Driver Settings Tab Under the Diagnostics tab, you can run diagnostics on your device (see Figure 8.12). Figure 8.12 – Expert Driver Diagnostics Tab Click the General button to run diagnostics on the items listed below the button. If a problem is detected, the program will display a red square next to the item in question. If no problems are detected, a green circle will appear. Click Fault Status to check whether any of the channels are indicating a fault condition. If a fault status is detected, a red square will be displayed next to the channel with the fault, as well as next to Master. If no problems are detected, a green circle will appear. Once you have finished, use the menu bar at the top of the screen to save your settings, return to the Select Driver screen, and more. ˽˽ The Save menu allows you to save your settings. Select Save to File to save your settings to a file. Selecting this will open a directory box, allowing you to name your settings file. This file will always be saved in the Wavetronix folder created when you installed Click Supervisor, under Wavetronix > ClickHome > Drivers > 110 > User. You can also select Save to Device to save your settings to your Click 110. 93 94 CHAPTER 8  •  CLICK 110 Note If you do not save your settings to your Click 110, they will be lost the next time you power the device down. ˽˽ The Tools menu contains five options for working with your device. Reset > System power cycles your device, while Reset > Factory Default restores your device to the settings with which it was shipped. Restore will restore the driver to the settings currently saved on the Click 110, erasing any unsaved changes. Upgrade can be used to manually upgrade to the most current firmware for your device. Hex View changes the view of certain settings in the driver to hexadecimal. ˽˽ Clicking the Quit menu exits the driver and returns you to the Click Supervisor main page. Once you have finished, click Save on the menu bar to save your settings. Click 112/114 — Detector Rack Cards 9 In this chapter ˽˽ ˽˽ ˽˽ ˽˽ ˽˽ ˽˽ Physical Features Installation and Wiring Configuration DIP Switches Front Panel Menu Click Supervisor 9 The Click 112 and 114 are 2-channel and 4-channel contact closure cards that can be used with the SmartSensor Matrix, Advance or HD. These cards plug into any standard detector rack card slot and can be connected to the sensor via a surge protector like the Click 222. Figure 9.1 – The Click 112/114 96 CHAPTER 9  •  CLICK 112/114 Physical Features The following sections describe the physical features of the Click 112/114. Figure 9.2 – Diagram of the Click 114 Communication Ports The Click 112/114 contain two independent serial communications ports. Each port is made up of two RJ-11 connectors, which make it simple to daisy-chain multiple cards together and create an RS-485 bus. The two RJ-11 RS-485 data buses can be connected to a SmartSensor through a surge protection module (the cards are designed for use with the Click 222, though the Click 200 can be used as well), or through a serial data converter. Bus 1 should be used to report vehicle data, and bus 2 should be used for configuration. Having one bus dedicated to each function leads to optimum Click 112/114 performance. On certain newer devices, the buses are labeled as Data and Control to let you know which one to use. DIP Switches On the lower part of the circuit board, behind the faceplate of the device, is a set of DIP switches. These switches are used to configure the Click 112/114 in Hardware mode. The parameters that can be configured using the DIP switches can also be configured via Software mode (front panel menu or Click Supervisor). See the DIP Switches section of this chapter for more information. Mode Switch The faceplate of the Click 112/114 features a push-button labeled Mode Switch, which is used to cycle through and select menu and configuration options. CHAPTER 9  •  CLICK 112/114 LEDs The faceplate of the Click 112/114 has three banks of LEDs. The top bank is used for detection indication, the second bank menu indication, and the third for menu indication as well as operation states. 1 Channel 2 3 4 Menu 1 PWR 2 PU 3 TD 4 RD Figure 9.3 – Click 114 LEDs The Channel LEDs are detection indicators; they consist of two (Click 112) or four (Click 114) red LEDs numbered 1–2 or 1–4, each representing a channel (see Figure 9.3). An illuminated LED indicates that the associated contact is being closed (this can mean either a vehicle detection or fail-safe mode, which will be discussed later in this chapter). These indicators are dedicated to detection and have no other display purposes. The menu indicator LEDs include two rows of LEDs (see Figure 9.3). The lower row contains Level 1 indicators, while the upper row contains Level 2 indicators. Each level consists of four LEDs numbered 1–4 (left to right). Level 1 LEDs (the multicolored row) display which menu item is active. These Level 1 LEDs are dual-purpose, each indicating both menu selection as well as a normal operation state when not in Menu mode. The normal operation state functions include: ˽˽ Red (PWR) – Indicates the presence of power to the device. ˽˽ Blue (PU) – This LED is not associated with any general status function and should remain off while the card is in normal operating mode. ˽˽ Green (TD) – Indicates serial communication transmit data (from the Click 112/114) on either RS-485 bus 1 or RS-485 bus 2. ˽˽ Yellow (RD) – Indicates serial communication receive data (to the Click 112/114) on either RS-485 bus 1 or RS-485 bus 2. Level 2 LEDs display configuration options for the menu items selected via the level 1 LEDs. All level 2 LEDs are red. These LEDs are dedicated to menu operation, and are extinguished when the menu is not active. Installation and Wiring Use the following steps to install and wire Click 112/114 devices: 1 If you’re using hardware configuration, set all DIP switches before installing Click 97 98 CHAPTER 9  •  CLICK 112/114 2 3 4 112/114 devices (covered in the DIP Switches section of this chapter). Insert the cards into the slots on the detector rack. The cards are hot-swappable, meaning they can be inserted and removed while there is still power to the rack. Daisy-chain together all the cards you intend to use in your installation, using short RJ-11 jumper cables. Connect the first Click 112/114 card to the SmartSensor via a Click 200 or Click 222 surge protector and a 60” RJ-11 patch cord. For your information, here is the pinout for the 44-pin edge connector on the back of the Click 112/114. Pin Back View Description Pin Front View Description 1 No connection A -DC (common) 2 No connection B +DC (12–24 VDC) 3 No connection C No connection 4 No connection D No connection 5 No connection E No connection 6 No connection F Channel 1 output (+) 7 Channel 1 status output H Channel 1 output (–) 8 No connection J No connection 9 No connection K No connection 10 No connection L Chassis ground 11 No connection M No connection 12 No connection N No connection 13 No connection P No connection 14 No connection R No connection 15 No connection S Channel 3 output (+)* 16 Channel 3 status output* T Channel 3 output (–)* 17 No connection U No connection 18 No connection V No connection 19 No connection W Channel 2 output (+) 20 Channel 2 status output X Channel 2 output (–) 21 No connection Y Channel 4 output (+)* 22 Channel 4 status output* Z Channel 4 output (–)* * Channels 3 and 4 exist only in the Click 114. In the Click 112, any pin marked here as being associated with channel 3 or 4 will not be connected to anything. Table 9.1 – Click 112/114 Pinout CHAPTER 9  •  CLICK 112/114 Note For specific information on how to use the Click 112/114 with the SmartSensor Matrix, see the SmartSensor Matrix User Guide. Configuration The Click 112/114 can be configured in three ways: DIP switches, the front panel menu, and Click Supervisor. These three configuration methods can configure different sets of parameters; some of these parameters can be set using multiple configuration methods, and some of them can only be set using one particular method. Table 8.17 lists how each parameter may be accessed and configured. DIP Switch Front Panel Menu Click Supervisor Baud Rate Yes Yes Yes Channel Input Map Yes Yes Yes Autobaud No Yes No Reset to Default No Yes Yes Description No No Yes Location No No Yes Device ID No No Yes To use this configuration feature: Hardware mode Software mode Software mode Table 9.2 – Click 112/114 Configuration Options The final row on the table refers to configuration modes. The DIP switches can be used to choose between Hardware and Software modes. If any of the switches are set to the ON position, that particular parameter is set to Hardware mode and only the DIP switches can be used to change its configuration options. If all switches are set to the OFF position for a particular parameter, it is in Software mode and the front panel menu and Click Supervisor may be used to change configuration options. This will be discussed in greater detail in the DIP Switches section of this chapter. Note Any setting which has been configured via the DIP switches will be read-only in Click Supervisor and the front panel menu. 99 100 CHAPTER 9  •  CLICK 112/114 One benefit of using DIP switches to configure is that if you ever have a field service call and need to replace a Click 112/114, all you need to do is match the pattern of the DIP switches on the card you are replacing. This paradigm will even work in situations where the old rack card will not power up. On the other hand, a benefit of using the software configuration is that you can remotely manage the configuration of the cards, if you are connected to them. In this paradigm, it becomes the user’s responsibility to keep a record of how each card was configured, which is easy to do using Click Supervisor. Note The Click 112/114 receives datagrams from the connected SmartSensor. These datagrams must be mapped to device outputs (covered in the next section). If the Click 112/114 does not receive a datagram describing the device’s channels for ten seconds, the device will enter fail-safe mode. In fail-safe mode, all outputs will assert a detection condition, and will continue to do so until the device receives a datagram that updates the state of its configured channels. DIP Switches The DIP switches are located on the lower part of the circuit board, behind the faceplate. Printed on the board above the switches is information about configuring the card using the DIP switches, as shown in Figure 9.4. Figure 9.4 – Click 112/114 DIP Switches The Click 112/114 feature two DIP switches labeled S4 and S5 on the silk screen. The switches are used to configure a total of three different parameters: ˽˽ Bus 1 baud rate CHAPTER 9  •  CLICK 112/114 ˽˽ Bus 2 baud rate ˽˽ Channel input map For each parameter, if any individual switch is in the ON position, that parameter is in Hardware mode. If Hardware mode is selected, the parameter can be configured using the switches. In this case, the setting can be viewed but not changed via Click Supervisor and the front panel menu. If all switches for a particular parameter are in the OFF position, that parameter is in Software mode. If Software mode is selected, the parameter must be configured using the front panel menu or Click Supervisor. Channel Input Map The first parameter that can be configured is channel input. Mapping input datagram channels to output channels is configured on the first DIP switch, labeled S4, using switches 1–4 (S4:1–4). Note If set to software mode, this parameter can also be changed using the front panel menu or Click Supervisor. As mentioned earlier, the Click 112//114 receives serial datagrams from a SmartSensor to which is it connected. These datagrams can contain many channels of detection data. Because the devices have fewer output channels than there are possible input datagram channels received from the sensor, you must use the channel input map to map the desired inputs to outputs. The Click 112 has two outputs and therefore must be mapped to two inputs; the Click 114 has four. (If you need more than two or four channels, you’ll need to use multiple devices daisy-chained together.) As shown in the table below, the outputs are mapped sequentially—that is, they can only be mapped in numerically ordered groups of two or four depending on which device you are using (1–2, 3–4, or 1–4, 5–8, etc.). If you chose, for example, 17–20 (on a Click 114), then input 17 would be mapped to output 1, input 18 would be mapped to output 2, input 19 would be mapped to output 3, and input 20 would be mapped to output 4. You will notice that the DIP switch labels on the Click 112 and 114 each have the input mapping information for both devices combined. Make sure you are looking at the correct information for your device. Additionally, the two sets of information are separated out and displayed below. (To turn a switch on, flip it up. To turn a switch off, flip it down.) 101 102 CHAPTER 9  •  CLICK 112/114 S4: Input Mapping 1 2 3 4 Channel Off Off Off Off Software mode Off Off Off On 1–2 Off Off On Off 3–4 Off Off On On 5–6 Off On Off Off 7–8 Off On Off On 9–10 Off On On Off 11–12 Off On On On 13–14 On Off Off Off 15–16 On Off Off On 17–18 On Off On Off 19–20 On Off On On 21–22 On On Off Off 23–24 On On Off On 25–26 On On On Off 27–28 Table 9.3 – Click 112 DIP Switch Channel Input Map Settings S4: Input Mapping 1 2 3 4 Channel Off Off Off Off Software mode Off Off Off On 1–4 Off Off On Off 5–8 Off Off On On 9–12 Off On Off Off 13–16 Off On Off On 17–20 Off On On Off 21–24 Off On On On 25–28 Table 9.4 – Click 114 DIP Switch Channel Input Map Settings If any switch is on (up), Hardware mode is selected, meaning the inputs can only be mapped using the DIP switches (as shown in the tables above), and Click Supervisor and the front panel menu will be able to display the current setting, but not change it. If all switches are off (down), Software mode is selected and Click Supervisor and the front panel menu will be able to both display and change the current setting. CHAPTER 9  •  CLICK 112/114 Baud Rate The baud rates for the two RS-485 buses, bus 1 and bus 2 (see the faceplate of the device for which RJ-11 jacks are for each bus), may be independently configured using the switches on the second DIP switch, labeled S5. Note This parameter can also be changed using the front panel menu or Click Supervisor. The switch patterns for the two parameters are identical, but bus 1 is configured using switches 1–3 (S5:1–3) while bus 2 is configured using switches 4–6 (S5:4–6). Also, unlike the channel input map, there is no difference between these switches on the Click 112 and the Click 114. S5: Bus 1 Baud Rate S5: Bus 2 Baud Rate 1 2 3 Value 4 5 6 Value Off Off Off Software mode Off Off Off Software mode Off Off On 9600 bps Off Off On 9600 bps Off On Off 19200 bps Off On Off 19200 bps Off On On 38400 bps Off On On 38400 bps On Off Off 57600 bps On Off Off 57600 bps Table 9.5 – DIP Switch Baud Rate Settings for Bus 1 (at left) and Bus 2 (at right) If any switch is on (up), Hardware mode is selected, meaning the baud rate can only be changed using the DIP switches (as shown in the tables above), and Click Supervisor and the front panel menu will be able to display the current setting, but not change it. If all switches are off (down), Software mode is selected and Click Supervisor and the front panel menu will be able to both display and change the current setting. Front Panel Menu The front panel of the device features a push-button and three banks of LEDs for on-device configuration and monitoring. The first bank of LEDs, labeled Channel, displays the state of the contact closure outputs and is described in the Physical Features section. The two lower banks of LEDs, labeled Menu, and the push-button, labeled Mode Switch, are used for navigating through Menu mode. This section will cover how to use the menu to configure the Click 112/114. The lower bank of LEDs will be referred to as Level 1 and is used in selecting menu options. The upper bank will be referred to as Level 2 and is used in 103 104 CHAPTER 9  •  CLICK 112/114 configuring the menu options. Level 2 LEDs only light up when a menu selection is made using the Level 1 LEDs. Menu Level 2 1 2 3 4 Level 1 PWR PU TD RD Mode Switch Figure 9.5 – Menu Indicator LEDs and Mode Switch Note The LEDs in the lower bank also function as activity/status indicators. These functions, outlined in the Physical Features section of this chapter, are only executed when the device is not in Menu mode. In this case, the upper bank of LEDs (Level 2) remains off. Navigating through the Menu The mode switch push-button is used to enter Menu mode. To use the menu: 1 2 3 4 5 6 Press and hold the mode switch to enter Menu mode. The Level 1 LEDs will start to light up to indicate that the device is cycling through all menu options (specifics on these menu options, and which LEDs and LED combinations represent them, will be covered later in this section). Release the mode switch when you reach the desired menu option. (Pressing and holding again will resume cycling through menu options.) Quickly press and release the mode switch to select the current menu option. Once it’s selected, the Level 2 LEDs will start to let you configure the options for the selected menu option. Press and hold the mode switch to cycle through the submenu. The Level 2 LEDs will light to indicate that the device is cycling though all configuration options (specifics on these configuration options, and which LEDs and LED combinations represent them, will be covered later in this section). Release the mode switch once the desired configuration option is reached. Quickly press and release the mode switch to select the current configuration option. The device will exit Menu mode, and either the selected function will run or the selected configuration will be set and saved to the device. Inactivity of one minute on the mode switch will exit menu mode. CHAPTER 9  •  CLICK 112/114 The following table illustrates an example of how the mode switch and menu indicator LEDs are used in configuring the Click 112/114—in this case, how to autobaud bus 2. Mode Switch Action Display State None Normal operation Press and hold Channel map menu option displayed Continue holding Autobaud menu option displayed Release Autobaud menu option displayed Press and release Autobaud menu selected and first configuration parameter displayed (bus 1 autobaud) Press and hold Second configuration parameter displayed (bus 2 autobaud) Release Second configuration parameter displayed (bus 2 autobaud) Press and release Configuration parameter selected; autobaud commences (will show intermediate LED states); autobaud finishes and normal operation resumes Table 9.6 – Menu Operation Example Front Panel Menu Options The following figure documents the menu and configuration options available from the front panel menu. This label is also printed on the side of the circuit board (on the opposite side from the DIP switches). 105 106 CHAPTER 9  •  CLICK 112/114 Figure 9.6 – Front Panel Menu Label As shown above, the menu options are displayed on the Level 1 LEDs (multicolored) and the configuration parameters are displayed on the Level 2 LEDs (all red). If a configuration parameter has been set using the DIP switches (meaning that parameter is currently set to Hardware mode), you cannot change it using the front panel menu. After selecting that particular menu option from the Level 1 LEDs, the Level 2 LEDs will display the configuration option set in the DIP switches but will not allow you to modify the setting. When you have finished reviewing the setting, press the mode switch once to leave Menu mode and return to normal operation. Channel Input Map The first configuration parameter that comes up when you’re cycling through the front panel menu is the channel input map. To select this parameter, release the push-button when the blue LED flashes. Note This parameter can also be changed using the DIP switches or Click Supervisor. CHAPTER 9  •  CLICK 112/114 As mentioned earlier, the Click 112/114 devices receive serial datagrams from a SmartSensor. These datagrams can contain many channels of detection data. Because the devices have fewer output channels than there are possible input datagram channels received from the sensor, you must use the channel input map to map the desired inputs to outputs. The Click 112 has two outputs and therefore must be mapped to two inputs; the Click 114 has four. (If you need more than two or four channels, you’ll need to use multiple devices daisychained together.) As shown in the table below, the outputs are mapped sequentially—that is, they can only be mapped in numerically ordered groups of two or four depending on which device you are using (1–2, 3–4, or 1–4, 5–8, etc.). If you chose, for example, 17–20 (on a Click 114), then input 17 would be mapped to output 1, input 18 would be mapped to output 2, input 19 would be mapped to output 3, and input 20 would be mapped to output 4. You’ll notice the menu operation labels on the Click 112 and 114 both have input mapping information for both devices combined. Make sure you are looking at the correct information for your device. The two sets of information are separated out and displayed below. Level 1 LEDs Input Mapping Cancel and exit menu Channels 1–2 Channels 3–4 Channels 5–6 Channels 7–8 Channels 9–10 Channels 11–12 Level 2 LEDs Channels 13–14 Channels 15–16 Channels 17–18 Channels 19–20 Channels 21–22 Channels 23–24 Channels 25–26 LED off Channels 27–28 LED on Table 9.7 – Click 112 Front Panel Menu Channel Input Map Settings 107 108 CHAPTER 9  •  CLICK 112/114 Level 1 LEDs Input Mapping Cancel and exit menu Channels 1–4 Channels 5–8 Level 2 LEDs Channels 9–12 Channels 13–16 Channels 17–20 Channels 21–24 LED off Channels 25–28 LED on Table 9.8 – Click 114 Front Panel Menu Channel Input Map Settings See the earlier Navigating through the Menu and the Menu Operation Example sections for how to configure this parameter. Because this parameter can also be set by the DIP switches, you may need to ensure that the DIP switches are set to Software configuration mode; if they are set to Hardware, the front panel menu will be able to display but not change these settings. Autobaud The second option that comes up when you’re cycling through the front panel menu is the autobaud function. To select this option, release the push-button when the green LED comes on solid. Note The autobaud function can only be accessed here, on the front panel menu. This function initiates an autobaud on the RS-485 buses (you will select which bus to autobaud on the Level 2 LEDs). An autobaud will stop data reporting on the selected port and attempt to communicate with the SmartSensor at all supported baud rates. CHAPTER 9  •  CLICK 112/114 Level 1 LEDs Autobaud Cancel and exit menu Level 2 LEDs Autobaud on bus 1 LED off Autobaud on bus 2 LED on Table 9.9 – Front Panel Menu Autobaud Settings See the earlier Navigating through the Menu and the Menu Operation Example sections for how to configure this parameter. As each baud rate is attempted, the Level 2 LEDs will sequence with a single LED illuminated from LED 1–4. If the Click 112/114 is successful in communicating with a SmartSensor, it will display the baud rate found, using the same Level 2 LED pattern used in selecting the baud rate (covered in the Baud Rate section of this chapter and Table 8.17). After a short time of displaying the autobaud results, the menu will return to normal operation with the baud rate setting updated (and stored) to the baud rate detected during the autobaud process. If the autobaud fails, all four Level 2 LEDs will light up for a few seconds, and then the menu will return to normal operation with the baud rate setting remaining unchanged. Note If the baud rate of either of the RS-485 buses was configured using the DIP switches (so that parameter is set to Hardware mode), the Level 2 LED configuration options for that bus will not be displayed (the LED option will never come on). If both RS-485 buses are configured using the DIP switches, the Level 1 LED menu option for autobaud will not be displayed (the green LED option will never come on). Baud Rate (Bus 1 and 2) The next two configuration parameters that come up in the front panel menu allow you to manually set the baud rate of the two RS-485 buses. Bus 1 comes up first, with the yellow LED coming on solid, then bus 2, with the yellow LED flashing. Note This parameter can also be changed using the DIP switches or Click Supervisor. 109 110 CHAPTER 9  •  CLICK 112/114 Level 1 LEDs Baud rate for bus 1 Baud rate for bus 2 Cancel and exit menu 9600 bps (default) Level 2 LEDs 19200 bps 38400 bps LED off 57600 bps LED on Table 9.10 – Front Panel Menu Baud Rate Settings See the earlier Navigating through the Menu and the Menu Operation Example sections for how to configure this parameter. Because this parameter can also be set by the DIP switches, you may need to ensure that the DIP switches are set to Software configuration mode; if they are set to Hardware, the front panel menu will be able to display but not change these settings. Reset to Default Settings The final option that comes up in the menu is Reset to Default Settings. To select this function, release the mode switch when the red LED starts flashing. Note Resetting to default settings can also be done using Click Supervisor. This function will restore all configuration settings to factory defaults, even those parameters not configured using the front panel menu: baud rate, channel input map, description field, location field, and device ID. Level 1 LEDs Level 2 LEDs Reset to Default Settings Cancel and exit menu LED off Reset to default Settings LED on Table 9.11 – Front Panel Menu Reset to Default Settings See the earlier Navigating through the Menu and the Menu Operation Example sections for how to view this parameter. CHAPTER 9  •  CLICK 112/114 After the Click 112/114 has reset to factory defaults, it will check the DIP switches; if any of them are set to Hardware mode, it will apply those settings to the parameter in question. If resetting to factory defaults doesn’t change certain settings the way you expected it to, check the DIP switches to see if they are causing settings to be changed to something other than the default. Click Supervisor Click Supervisor is the only way to configure non-data path type parameters such as the description, location, and device ID. See Chapters 4 and 5 of this document for instructions on how to download and install Click Supervisor and how to connect to your device using the software. Note Some of the parameters mentioned below can only be configured in Click Supervisor. Others can be configured by the front panel menu and/or the DIP switches. In the case of the DIP switches, if that parameter is set to Hardware mode, it will be grayed out in Click Supervisor, meaning you can view but not change the setting. If you would like to set it using Click Supervisor, you will have to turn off all those switches on the device. The Click 112/114 can be configured using the Expert driver (see Figure 9.7). Figure 9.7 – Selecting a Driver After you have made configuration changes on the driver and saved it to the Click device, the word “current” will appear after it to indicate the driver is currently loaded onto the device. 111 112 CHAPTER 9  •  CLICK 112/114 The Backups option can be used to read configurations that have previously been saved to file. See Chapter 5 for more information. Expert Driver The Expert driver contains two tabs, System and Diagnostics, which are then subdivided further. The System > General tab lets you change general information about your device. The tab has the following parameters (see Figure 9.8 and Table 9.12): Figure 9.8 – Expert Driver General Tab Note These parameters can only be configured using Click Supervisor. Setting Description Module Allows you to enter a name and description of the device. Driver Names the driver you are currently working with. Description Shows a description of the device being configured. This is only for your information and does not affect the operation of the device. Location Displays the location of the device being configured. This is only for your information and does not affect the operation of the device. Serial Number Displays the serial number of your device. This information cannot be changed. CHAPTER 9  •  CLICK 112/114 Firmware Version Shows the version of firmware your device currently has installed. If Click Supervisor detects a discrepancy between this version and the most current version it currently has access to, you will be prompted to upgrade when you connect to the device. This information cannot be changed. Subnet ID Shows the subnet ID number. This option is currently not available. Device ID Gives the ID number of the device being configured, which is used to identify the device when you are connecting to it. By default, this number is the last five digits of the serial number, which can be found under the About tab or on the barcode sticker on the bottom of the device. It is recommended that you do not change this number unless another device on your network has the same ID number. Table 9.12 – Expert Driver General Tab The System > Settings tab lets you configure and view many of the parameters that are also available elsewhere on the device (see Table 9.2 earlier in this chapter for more information). The tab has the following parameters (see Figure 9.9 and Table 9.13): Figure 9.9 – Expert Driver General Tab Note These parameters can also be configured using the DIP switches or the front panel menu; if in the DIP switches they are set to Hardware mode, the parameters will appear grayed out on this screen. Setting Description Baud Rate for Bus 1 Lets you change the baud rate, in bps, of bus 1. Baud Rate for Bus 2 Lets you change the baud rate, in bps, of bus 2. 113 114 CHAPTER 9  •  CLICK 112/114 Input Mapping Lets you assign input datagram channels received from the sensor to the two or four output channels on the device. The outputs are mapped sequentially—that is, they can only be mapped in numerically ordered groups of two (Click 112) or four (Click 114). See Input Mapping in either the DIP Switches or Front Panel Menu sections in this chapter for more information. Table 9.13 – Expert Driver Settings Tab Under the Diagnostics tab, you can run diagnostics on your device (see Figure 9.10). Figure 9.10 – Expert Driver Diagnostics Tab Click the General button to run diagnostics on the items listed below the button. If a problem is detected, the program will display a red square next to the item in question. If no problems are detected, a green circle will appear. Click Failsafe Status to check whether any of the channels are in fail-safe mode. If a fail-safe condition is detected, a red square will be displayed below the button. If no problems are detected, a green circle will appear. Once you have finished, use the menu bar at the top of the screen to save your settings, return to the Select Driver screen, and more. ˽˽ The Save menu allows you to save your settings. Select Save to File to save your settings to a file. Selecting this will open a directory box, allowing you to name your settings file. This file will always be saved in the Wavetronix folder created when you installed Click Supervisor, under Wavetronix > ClickHome > Drivers > 112 > User (or Wavetronix > ClickHome > Drivers > 114 > User). You can also select Save to Device to save your settings to your Click 112/114. CHAPTER 9  •  CLICK 112/114 Note If you do not save your settings to your Click 112/114, they will be lost the next time you power the device down. ˽˽ The Tools menu contains five options for working with your device. Reset > System power cycles your device, while Reset > Factory Default restores your device to the settings with which it was shipped. Restore will restore the driver to the settings currently saved on the Click 112/114, erasing any unsaved changes. Upgrade can be used to manually upgrade to the most current firmware for your device. Hex View changes the view of certain settings in the driver to hexadecimal. ˽˽ Clicking the Quit menu exits the driver and returns you to the Click Supervisor main page. Once you have finished, click Save on the menu bar to save your settings. 115 10 Click 120/121 — Relay In this chapter ˽˽ Physical Features ˽˽ Installation 10 The Click 120/121 provide an interface between Click contact closure devices and signaling systems.­ Figure 10.1 – The Click 120 118 CHAPTER 10  •  CLICK 120/121 Physical Features Figure 10.2 – Diagram of the Click 120 The Click 120/121 feature five terminals. On the Click 120, these are screw terminals; the Click 121 features spring cage terminals. On the top, or coil, side of the module are two terminals marked A1+ and A2–. These terminals are for wiring in from a contact closure module such as the Click 100. On the bottom, or contact, side of the module are three terminals marked 11, 14 and 12. These terminals are for wiring in power and for wiring to the signaling system. On the upper front of the device is an LED marked 24 V. This LED will light up when the coil side is receiving 24 VDC in (meaning there is a current from the contact closure module, and the contact side of the Click 120/121 has switched from 12 to 14). On the lower front of the device is the engagement lever, which allows you to remove the relay module and replace it, if necessary. To remove the relay module, slide the switch down (away from the relay section) until the relay module pops out. To put in a new module, position it in the center, lining up the holes in the base with the prongs in the relay section, then press down until the engagement lever pops back into place. Installation The Click 120/121 are mounted on a DIN rail using the same motion used for all Click CHAPTER 10  •  CLICK 120/121 devices. To remove a Click 120/121 from the DIN rail, insert a small screwdriver into the notch at the upper back corner of the device and pull the screwdriver down to lever the snap-on foot off the rail. Follow the steps below to wire the relay device (see Figure 10.3): Figure 10.3 – Wiring from a Contact Output to the Relay 1 2 3 4 5 Wire 24 VDC into the A1+ terminal on the coil side of the relay. Wire from the A2– terminal on the coil side of the relay to the appropriate contact closure terminal on the contact closure device. Wire from the ground or common terminal on the contact closure device to a convenient ground or common terminal elsewhere (for instance, on a power supply). Wire power (12–250 V, either AC or DC) to the terminal marked 11 on the contact side of the device. As this is the power that will run the load or loads, it needs to be the type of current and the voltage that the loads use. Wire your loads into the terminals marked 12 and 14: If you are using one load and want it to turn on whenever there’s a current across the contact closure device, wire it to 14. If you are using one load and want it turn on whenever there is not a current across the contact closure device, wire it to 12. If you are using two loads and want the relay to switch back and forth between which one is being powered, wire them into 12 and 14. Wire the load you want turned on when there’s a current across the contact closure device to terminal 14. Example: Click 120/121 to Traffic Signal Here is an example of how relays might be used to control a single traffic light. Follow the steps below to set the example up: 1 2 Mount three relays onto a DIN rail, one for the red light, one for the yellow and one for the green. Wire from the A1+ terminal on the coil side of each relay to 24 VDC. 119 120 CHAPTER 10  •  CLICK 120/121 3 4 5 Wire from the A2– terminal on the coil side of each relay to the correct output terminals on the contact closure device or traffic controller. Wire from the 14 terminal on the contact side of each relay to its corresponding light in the traffic signal (for example, make sure the relay that is wired to the contact closure output for the red light is then wired into the red light itself). Wire the appropriate voltage and current for the traffic signal to the 11 terminal on each relay. Click 200 — Lightning Surge Protector 11 In this chapter ˽˽ Physical Features ˽˽ Installation 11 The Click 200 module is designed to protect SmartSensors from surges on all power and communication connections, suppressing power surges for DC power, half-duplex RS-485 communication and full-duplex RS-232 communication with CTS and RTS. The Click 200 can also be used to protect any device from surges from the SmartSensor or any other device with 9–28 VDC power or RS-485 or RS-232 communication. Figure 11.1 – The Click 200 122 CHAPTER 11  •  CLICK 200 Physical Features The physical features of the Click 200 include communication and power connections. Figure 11.2 – The Click 200 Communication Ports There are six screw terminal blocks on the 200, each containing four screw terminals. The three blocks on the top of the module are protected (check for the PROTECTED label to be sure you have the correct side) and the three on the bottom of the module are unprotected. These screw terminal blocks are for wiring power, ground, and communication (RS-232 and RS-485) between the Click 200 and the sensor (or the sensor block, which is in turn connected to the sensor). They will be discussed in greater detail in the Installation section of this chapter. There are also two other ways to wire RS-485. The back of the Click 200 features a 5-position connector that plugs into a T-bus connector and provides power and RS-485 communication to the device. It also passes that RS-485 communication to all other devices on the T-bus. In addition, the faceplate of the Click 200 features an RJ-11 jack for RS-485 communication. This jack can be used to connect a jumper cable from the Click 200 to contact closure cards or to another device that uses RS-485 communication. The front of the device also features a DB-9 connector for RS-232 communication. CHAPTER 11  •  CLICK 200 Note The Click 200 does not convert RS-232 to RS-485 or vice versa. Connecting to the DB-9 connector will allow you to communicate with the sensor using RS-232 protocol, but not using RS-485 protocol. You will also not be able to use the DB-9 connector to communicate with other devices over the T-bus. If you need to convert RS-232 to RS-485, use another Click module such as the Click 304. A pinout diagram is provided on each individual unit as a reference in the field. Note Certain newer Click 200 devices also have an LED on the faceplate. This LED, if present, lights up to indicate power is present and surge protection is okay. If the light is off, either there is no power to the device or surge protection is currently not ready. Power Connections The Click 200 receives power from the T-bus via the T-bus connection on the back of the module. Additionally, if the power supply is not wired directly into the T-bus, power can be connected to the +DC and -DC screw terminals on the UNPROTECTED side of the module. In this case, the Click 200 will then pass power through the T-bus to all other devices connected to it. Installation To install the Click 200 in a pole-mount cabinet, simply mount it on the DIN rail and wire the service end of the sensor cable into the PROTECTED side (see the section on wiring for how to do this). In many installations, the pole-mount cabinet is also connected to a main traffic cabinet via an underground homerun cable. To protect the traffic cabinet, a second surge device is required. Note If any part of the cable goes underground, it’s necessary to have a Click 200 on each end of the cable to protect the traffic cabinet and pole-mount box from electrical surges. 123 124 CHAPTER 11  •  CLICK 200 Follow the steps below to include surge protection using Click 200 devices (see Figure 11.3): 1 2 3 4 Install a Click 200 device in a pole-mount box on the same pole as the sensor being protected. Install another Click 200 in the main traffic cabinet. Connect the cable from the sensor to the PROTECTED side of the Click 200 in the pole-mount cabinet. The SmartSensor cable should be kept as short as possible. Connect a cable from the UNPROTECTED side of the Click 200 on the pole to the UNPROTECTED side of the Click 200 in the main traffic cabinet (see the section on wiring for how to do this). Main Traffic Cabinet Smart Sensor Both ends of the homerun cable connect to the UNPROTECTED side of the surge modules. Pole Mount Traffic Cabinet 120 VAC Figure 11.3 – Standard SmartSensor Installation Using Homerun Cable Wiring the Cable Figure 11.4 below shows how to wire the two sides of the Click 200. The UNPROTECTED side of the Click 200 is not surge protected and is designed to be connected to the source(s) from which power surges may come. Note It is important to note that there are two different cables that could be used with the Click 200. All new SmartSensor HD and V sensors are sold with the 8-conductor cable, so that’s what this lesson will discuss. Older installations, however, may still have the 9-conductor cable, often just called the SmartSensor cable. Differences in the wiring of the 9-conductor cable are noted below. CHAPTER 11  •  CLICK 200 If you have a 9-conductor cable, there is a ground (gray) wire and a total of three drains; these can all be wired into any of the GND terminals. Also, the +485 wire will not have a blue stripe. RTS (Orange) CTS (Brown) RD (Purple) TD (Yellow) -485 (Blue) +485 (White) +DC (Red) -DC (Black) Drain Figure 11.4 – Click 200 Terminal Connections Wiring to Earth Ground All Click 200 devices should be mounted on a DIN rail that is connected to earth ground, either through an earth-grounded chassis or a 16 AWG or larger grounding wire attached to a 7-foot grounding rod. Follow the steps below to correctly wire to earth ground: 1 2 Connect the grounding wire from either the DIN rail or a GND screw terminal on the UNPROTECTED side of the Click 200 to the lug bolt on the inside of the pole-mount box. Connect another grounding wire from the exterior lug bolt to earth ground. Verify Connections to Earth Ground If there is not a good connection to ground, the Click 200 cards will not protect any equipment. After all connections have been wired, verify that a good connection is made between the Click 200 cards and earth ground by following the steps below: 1 2 Use a multimeter that is able to measure resistance in increments of less than one ohm. Connect one probe to the drain on the unprotected side of the Click 200 (see Figure 11.5); connect the other probe on the multimeter to earth ground. 125 126 CHAPTER 11  •  CLICK 200 Figure 11.5 – Verifying Earth Ground 3 The resistance should measure less than one ohm. If not, the most likely problem is the DIN rail is not making connection to earth ground through the chassis of the cabinet. The Click 200 cards have a connector on the bottom that snaps on the DIN rail that provides the connection to earth ground. If the DIN rail is not making a good connection to earth ground, connect a 16 AWG (or larger) wire to the DIN rail with a bolt and run that wire directly to an earth ground terminal. Verify Communication Follow the steps below to verify the communication connections: 1 2 3 4 Check the RS-232 connection by plugging a straight-through RS-232 cable between a laptop and the DB-9 connector on the Click 200. Launch SmartSensor Manager and connect via a serial connection. If there are problems connecting, verify that the cabling is set up correctly. Check the RS-485 connection to the SmartSensor using a Click 304 RS-232 to RS-485 converter. Attach the Click 304 to the T-bus (see Chapter 2 for more on T-buses) and then plug a straight-through RS-232 cable between a laptop and the DB-9 connector on the faceplate of the Click 304. Launch SmartSensor Manager and connect via a serial connection. If there are problems connecting, verify that the cabling is set up correctly. Once communication and ground connections have been verified, the installation of the Click 200 is complete. Click 201/202/204 — AC to DC Power Supply 12 In this chapter ˽˽ Physical Features ˽˽ Installation 12 Click 201/202/204 modules are 120–240 VAC to 24 VDC power supplies. One of these modules should be used as part of the power plant, providing reliable DC power to the rest of the cabinet, unless a Click 203 is used (see Chapter 1). A Click 201 provides 1 A of power and is capable of powering a single Wavetronix SmartSensor; a Click 202 provides 2 A and can power two sensors; and a Click 204 provides 4 A and can power four sensors. Figure 12.1 – The Click 201, 202 and 204 128 CHAPTER 12  •  CLICK 201/202/204 Physical Features Click 201/202/204 modules have the following physical features. Figure 12.2 – Diagram of the Click 202 Click 201/202/204 modules are wired through the pluggable screw terminal blocks on the top and bottom of each module. The top block has either two or four screw terminal connections for wiring AC in. DC out is wired through the bottom of the module. The Click 202 and 204 feature one screw terminal block on the bottom of the module, while the Click 201 has two. The screw terminal blocks are red-keyed, allowing them to plug only into their proper slots. Click 201/202/204 modules also have a green activity indicator light marked DC OK on the faceplate. This light glows steadily when the module is working properly, but will go out if the power supply is interrupted or if the DC connection is shorted. Finally, the devices also have a potentiometer, marked “22.5–28.5 V DC,” located on the faceplate beneath the LED. This can be used to set the DC output voltage. Insert a small screwdriver into the hole and twist clockwise to raise the voltage and counterclockwise to lower it. Voltages from 22.5–28.5 VDC are allowed. Change this setting only if instructed to do so by Wavetronix Technical Services. Installation The Click 201/202/204 devices are wired through the pluggable screw terminal blocks located on the tops and bottoms of the modules. Refer to the tables and figures below to correctly wire the Click 201/202/204. CHAPTER 12  •  CLICK 201/202/204 Note Ensure power to AC mains is disconnected while wiring the AC input. Wiring AC Power Into the Click 201/202/204 Click 201/202/204 AC In Line (black) L Neutral (white) N Table 12.1 – Wiring AC+ Power In Figure 12.3 – Wiring AC Power into the Click 201/202/204 Note The NC screw terminals found in the Click 201 and 202 are not connected internally. Connecting a wire to a no connect (NC) terminal simply gives it a convenient termination point. Wiring DC Power out of the Click 201/202/204 Click 201/202/204 DC Out +DC (red) L -DC (black) N Table 12.2 – Wiring AC Power Out 129 130 CHAPTER 12  •  CLICK 201/202/204 Figure 12.4 – Wiring DC Power out of the Click 201/202/204 Note Do not wire out of the DC OK terminal; it supplies only 20 mA and should only be used to monitor the status of the power supply. 13 Click 203 — UPS/Battery In this chapter ˽˽ Physical Features ˽˽ Installation ˽˽ On-device Configuration 13 The Click 203 is a combination uninterrupted power supply and battery, keeping power supplied to your equipment even when the external power source goes out. The UPS converts AC power to DC, with a 2 A output, and the battery will keep a SmartSensor running for up to 30 minutes in the case of a power loss. Figure 13.1 – The Click 203 132 CHAPTER 13  •  CLICK 203 Note Because the Click 203 is a power supply, if you are using one, you do not need a Click 201/202/204. Physical Features The Click 203 has the following physical features. Figure 13.2 – Diagram of the Click 203 UPS Module The UPS module features three pluggable screw terminal blocks. The screw terminal block on the bottom of the module has two screw terminals for wiring AC power in. The top of the module has two screw terminal blocks situated next to each other: the block on the right has two screw terminals for wiring to the battery, and the block on the left has seven screw terminals, for DC out, among other things. Wiring the device will be discussed later in the chapter. The screw terminals are removable for easy preinstallation wiring. The UPS module has three LEDs on the faceplate. See the On-device Configuration section for information on these LEDs. The faceplate also features two adjustable features, the potentiometer and the buffer time selector switch. See the On-device Configuration section for more information. Battery Module The battery module has a screw terminal block on top for wiring to the UPS module. There’s also a fuse on the faceplate of the module to protect the battery in case of a short. CHAPTER 13  •  CLICK 203 Note The battery fuse must be removed when installing or replacing the module. Installation Use the following tables to wire the UPS and battery. Wiring into the UPS Module Terminal Connection L (+) AC line (black) in N (–) AC neutral (white) in Table 13.1 – Wiring into the UPS Module Note Ensure power to AC mains is disconnected while wiring the AC input. Wiring out of the UPS Module Terminal Connection + +DC out (red) – -DC out (black) Alarm Active switching output (see Signaling Outputs section) Bat.-Mode Active switching output (see Signaling Outputs section) Bat.-Charge Active switching output (see Signaling Outputs section) R1 Remote terminal (see Remote Shutdown section) R2 Remote terminal (see Remote Shutdown section) Table 13.2 – Wiring out of the UPS Module, 7-terminal Block Terminal Connection Battery + +DC to battery (red) Battery – -DC to battery (black) Table 13.3 – Wiring Out of the UPS Module, 2-terminal Block 133 134 CHAPTER 13  •  CLICK 203 Remote Shutdown The R1 and R2 screw terminals are used for the remote shutdown function. When remote shutdown is active, the UPS does not switch over to the buffer mode in the event of a supply voltage failure; the device switches off. The rechargeable battery module is charged when the supply voltage is reconnected, but the device remains switched off until R1 and R2 are shorted. To activate remote shutdown, do not short-circuit the terminals. For normal Click 203 operation—the UPS switches over to buffer mode in the event of a supply voltage failure—remote shutdown should be deactivated.To deactivate remote shutdown, short-circuit the terminals (i.e. with a plug-in bridge). On-device Configuration The Click 203 has several features for monitoring and configuring the operation of the module. The buffer time selector switch, marked with numbers around the circumference, can be used to set how long the device will remain in buffer mode before automatically turning off. Insert a small screwdriver into the hole and twist until the arrow in the screw head is pointing to the time you want. The switch has times from half a minute to thirty minutes, or you can set it to remain on continuously by turning the dial to the ∞ sign. If the switch is set to the continuous option, the Click 203 will run until the battery is discharged and then turn off. The potentiometer, marked “22.5-28.5 V DC,” can be used to set the DC output voltage. Insert a small screwdriver into the hole and twist clockwise to raise the voltage and counterclockwise to lower it. Change this setting only if instructed to do so by Wavetronix Technical Services. Signaling Outputs The Click 203 features three signal outputs: alarm, battery mode and battery charge. These outputs work in conjunction with the three LEDs to monitor module operation. See the table below for an explanation of how these outputs and LEDs work. State Power in OK (green) Battery mode/Battery charge (yellow) Alarm (red) Supply voltage OK, rechargeable battery is being charged LED on LED is flashing; battery mode output: 0 V, battery charge output: 24 V LED off; output: 0 V Supply voltage OK, rechargeable battery charged (normal mode) LED on LED off; battery mode / battery charge output: 0 V LED off; output: 0 V CHAPTER 13  •  CLICK 203 Buffer mode LED off LED on; battery mode outLED off; output: 0 V put: 24 V, battery charge: 0 V Rechargeable battery discharged, UBAT < 20.4 V DC LED off LED on; battery mode / battery charge output: 0 V LED on; output: 24 V Rechargeable battery test negative LED on LED off; battery mode / battery charge output: 0 V LED on; output: 24 V Buffer time over and remote shutdown activated LED off LED off; battery mode / battery charge output: 0 V LED off; output: 0 V Table 13.4 – Signaling Outputs 135 14 Click 210 — AC Circuit Breaker In this chapter ˽˽ Physical Features ˽˽ Installation 14 The Click 210 is a compact circuit breaker DIN rail device designed to interrupt an electric current under overload conditions. The breaker is trip-free and can be easily reset after a current interruption by pushing the reset button. Use the Click 210 as part of your installation to protect your other devices from overloads. Figure 14.1 – The Click 210 138 CHAPTER 14  •  CLICK 210 Note The Click 210 is a 0.5 A circuit breaker. There are also 2 A and 8 A models available; contact your Wavetronix dealer for more information or to order. Physical Features Figure 14.2 – Diagram of the Click 210 The Click 210 features two screw terminals, one on each side, for wiring power. It also features a reset button on top that can be used to reset the breaker after a current interruption. Installation Connect the line (black) wire from the AC terminal block or AC plug into one of the two screw terminal connectors, and another line wire out of the other connector for power out. It doesn’t matter which side you use for power in as long as the other end is power out. Note Be sure the reset button on top of the module is pressed down before wiring. 15 Click 211 — AC Outlet In this chapter ˽˽ Physical Features ˽˽ Installation 15 The Click 211 is an AC outlet that provides a standard three-hole socket for devices powered through an AC power plug. The outlet snaps onto a DIN rail and is wired through twin terminal blocks attached to the power plant. If you are using a Click 211, the power plant configuration will differ from the standard configuration outlined in Chapter 1 of this manual. Figure 15.1 – The Click 211 140 CHAPTER 15  •  CLICK 211 Note Wiring the Click 211 from the power plant requires the use of two twin terminal blocks. Physical Features Figure 15.2 – Diagram of the Click 211 The Click 211 has three screw terminal connections, located on the top of the module, for wiring in power. There is also an LED located on the front of the module; this LED lights up when the Click 211 is working properly. Installation Installing the Click 211 involves a slight change in how your installation’s power plant is put together. Follow these steps to wire the power plant and Click 211. Note The pictures below show the Click 211 being installed on a backplate as part of a cabinet installation. It is not necessary to use a backplate, however, and if you are not, the wiring will still be the same. CHAPTER 15  •  CLICK 211 Wiring the Power Plant 1 2 3 4 5 Install the Click 210 and Click 230 as outlined in Chapter 1. Attach two ST 2.5 twin terminal blocks to the DIN rail next to the Click 230. Attach the Click 201/202/204 (or 203, if you prefer to use that as a power supply) to the DIN rail next to the twin terminal blocks. Attach 14 AWG wires that are stripped 3/8” on both ends to the N and L screw terminal connections on the OUT side of the Click 230 (the standard is to use white and black wires, respectively). Terminate the white, or neutral, wire into one of the ports on the first twin terminal block. Terminate the black, or line, wire into one of the ports on the second twin terminal block (see Figure 15.3). For ease in wiring, use the same port on each block. Figure 15.3 – Wiring into Twin Terminal Blocks 6 7 Attach 14 AWG wires that are stripped 3/8” on both ends to the second set of ports on each of the twin terminal blocks, following the coloring of the wires coming in. Terminate the white, or neutral, wire in the N screw terminal connection on the AC In side of the Click 201/202/204. Terminate the black, or line, wire in the L screw terminal connection (see Figure 15.4). Figure 15.4 – Wiring into the Power Supply 141 142 CHAPTER 15  •  CLICK 211 8 Wire power out of the Click 201/202/204 as described in Chapter 1. Wiring the Click 211 1 2 3 4 5 6 Attach a 14 AWG wire that is stripped 3/8” on both ends (green is standard) to the screw terminal marked G on the OUT side of the Click 230. Attach 14 AWG wires that are stripped 3/8” on both ends to the last set of ports on the two twin terminal blocks, following the coloring of the wires attached to each block. Snap the Click 211 onto a DIN rail within reaching distance of the device to be plugged in. The device cannot be mounted over a T-bus. Terminate the line (black) wire into the screw terminal on the Click 211 marked L1. Terminate the ground (green) wire into the screw terminal on the Click 211 marked PE (protective earth). Terminate the neutral (white) wire into the screw terminal on the Click 211 marked N (see Figure 15.5). Figure 15.5 – Properly Wired Click 211 16 Click 221 — DC Surge Protector In this chapter ˽˽ Physical Features ˽˽ Installation 16 The Click 221 provides surge protection on DC input lines. Use this device in a cabinet with DC input to protect your equipment from surges on the power lines. Figure 16.1 – The Click 221 This device is used if your device has a DC power input and therefore does not need the Click power plant modules. If you’re using the power plant modules, your cabinet has an AC power input and you need a Click 230 instead. 144 CHAPTER 16  •  CLICK 221 Physical Features Figure 16.2 – Diagram of the Click 221 The bottom of the Click 221 has a screw terminal block with four screw terminals—+DC, -DC and two PE terminals—for DC power. The back of the Click 221 features a 5-position connector that plugs into a T-bus connector and provides power to the device. It also passes that power to all other devices on the T-bus. A pinout diagram is provided on each individual unit as a reference in the field. The faceplate has an LED used for monitoring the device: if the LED is on, the device has power and the surge protection is functional. Installation To install and wire the Click 221: 1 2 3 4 Mount the Click 221 on the T-bus it is going to protect. Wire power from the DC power source into the +DC and -DC terminals on the bottom of the device. Wire from one of the PE terminals to a good earth ground. If the device is in a cabinet, there will likely be a central grounding point—such as a grounding lug—for just such a purpose. Watch the LED. If it comes on, the device has power and the surge protection is ready. Click 222 — System Surge Protector 17 In this chapter ˽˽ Physical Features ˽˽ Installation 17 The Click 222 system surge protection device is designed to prevent electrical surges conducted along underground cables from damaging the cabinet equipment. The power and RS-485 serial connections on the device are protected from these incoming surges. It can be used with a number of devices, including the SmartSensor Matrix. Figure 17.1 – The Click 222 CHAPTER 17  •  CLICK 222 Physical Features The physical features of the Click 222 include communication and power connections. T-Bus Connector Click! 222 DC Surge TD OK RS-485 B Connector Data RS-485 A Connector Data Control RD RS-485 B RS-485 Bridge Connector PWR RS-485 Bridge LED Indicators RS-485 A 146 System Surge Protection www.wavetronix.com RS-485 Connector RS-485 Connector Power Connector Figure 17.2 – Diagram of the Click 222 Connections The faceplate of the Click 222 has three RJ-11 jacks, which provide the following three independent serial connections: ˽˽ Topmost jack – control bridge ˽˽ Middle jack – dedicated communications for sensor 2 detection calls ˽˽ Lowest jack – dedicated communications for sensor 1 detection calls The back of the Click 222 features a 5-position connector that plugs into a T-bus connector and provides power and RS-485 communication to the device. It also passes RS-485 communication from the module to all other devices on the T-bus. The bottom of the Click 222 has three pluggable screw terminal blocks with four terminals each, for a total of twelve connections. These terminals are used for wiring in the cable from the sensor. The terminals have four different RS-485 connections, each consisting of a +485 and a -485 terminal; two of these connections are for detection calls and two for the control bridge, allowing two sensors to be wired in to each Click 222. This will be explained in greater detail in the Installation section of this chapter. CHAPTER 17  •  CLICK 222 Configuration Features The front of the Click 222 has four LEDs that indicate device activity and status: ˽˽ PWR (red) lights up to indicate that the device has power. ˽˽ DC Surge OK (blue) lights up to indicate DC surge protection is working. ˽˽ TD (green) lights up to indicate when data is transmitted over the T-bus or over the control bridge. This LED does not indicate data transmitted on the A or B ports. ˽˽ RD (yellow) lights up to indicate when data is received over the T-bus or over the control bridge. This LED does not indicate data received on the A or B ports. Installation The Click 222 is commonly used with the SmartSensor Matrix and SmartSensor 6-conductor cable; the steps that follow in this section are specific to this application. If you do not plan on using the 6-conductor cable, you can skip the steps below and simply wire your power and communications by following the labels on the screw terminals; in this case, be aware that you should use the terminals marked 485A and 485B for detection calls. +485A (Orange/White) –485A (Orange) Sensor 1 +485C (Blue/White) –485C (Blue) +DC (Red) –DC (Black) Drain –485B (Orange) +485B (Orange/White) +485D (Blue) –485D (Blue/White) +DC (Red) –DC (Black) Drain Earth ground Figure 17.3 – Wiring the Click 222 Sensor 2 147 148 CHAPTER 17  •  CLICK 222 The steps below refer to how to install and wire a Click 222. If you are using a SmartSensor Matrix preassembled cabinet, the device will already be installed and wired; all you will have to do is wire the plug on the terminal block. A single Click 222 can be connected to two sensors. If you have a four-sensor approach, you will install a second Click 222 next to the first by repeating the steps below. 1 Using a rocking motion, mount the Click 222 onto the DIN rail, making sure it’s on the T-bus with the devices it’s supposed to protect. Note Depending on your installation, your Click 222 may be wired in different ways. If you’re using terminal blocks on the lowest DIN rail, you will wire your sensor cable into those, and then wire from the terminal blocks to the Click 222. If you are not using terminal blocks, you will wire your sensor cable directly into the Click 222. 2 3 4 5 6 7 Wire the cable from sensor 1 to the frontmost pluggable screw terminal block: connect the orange and white–striped wire to the screw terminal marked +485A. Connect the orange wire to the screw terminal marked -485A. (For ease, you can remove the terminal block from the device, wire it, then reinsert it.) Wire the cable from sensor 1 to the middle pluggable screw terminal block: connect the blue and white–striped wire to the screw terminal marked +485C. Connect the blue wire to the screw terminal marked -485C. If you are using a second sensor, repeat steps 2 and 3 using that sensor’s cable. The orange and orange-striped wires go into -485B and +485B; the blue and blue-striped wires go into -485D and +485D. Wire the backmost pluggable screw terminal block: connect the red wire into the screw terminal marked +DC and the black wire into -DC. Wire the drain into either of the terminals marked PE. If you are using two sensors, these three terminals will both have two wires (one from each cable) terminated in them. Connect a 14 AWG wire between the other terminals marked PE to a grounded location, such as a grounding lug or an earth ground terminal block (if you are using terminal blocks). If you are using two Click 222 devices, you can either ground them seperately or ground one of them and then connect the second one to it (by connecting a 14 AWG wire from one of its PE terminals to the free PE terminal on the first device). The Click 222 is designed to be used with the Click 112/114 detector rack cards. To connect to the cards: 1 2 Connect a patch cord from the Click 222 RS-485 A port to a bus 1 port on the appropriate rack card. Connect a patch cord from the Click 222 RS-485 B port to a bus 1 port on another rack card. CHAPTER 17  •  CLICK 222 3 4 If you are using Click 112 cards, use a short patch cord to share bus 1 between cards dedicated to the same sensor, as shown with the two rightmost cards in Figure 17.4. If you have more than two sensors in your system, repeat steps 1–3 for all remaining rack cards. Figure 17.4 – Wiring the Click 112/114 Rack Cards 5 6 Connect a patch cord from one of the Click 222 bridge ports to bus 2 of the rack cards. Use short patch cords to daisy-chain bus 2 together on all the cards. This bus will be used for configuration. See the Click 112/114 chapter in this manual for more information on configuring and using the detector rack cards. 149 Click 223 — Dual-485 Surge Protector 18 In this chapter ˽˽ Physical Features ˽˽ Installation 18 The Click 223 dual-485 surge protector device is designed to prevent electrical surges from damaging connected equipment. It protects one DC power and two RS-485 serial connections from these incoming surges, which are usually caused by lightning strikes and carried along underground cables. The Click 223 can be used with a number of devices, including the SmartSensor Advance. Figure 18.1 – The Click 223 152 CHAPTER 18  •  CLICK 223 Physical Features Figure 18.2 – Diagram of the Click 223 The faceplate of the Click 223 has two RJ-11 jacks, which provide two independent serial connections: ˽˽ RS-485A (upper jack) – passes RS-485 between the jack, the 485A screw terminals on the top and bottom of the device, and the T-bus 5-position connector. ˽˽ RS-485B (lower jack) – passes RS-485 between the jack and the 485B screw terminals on the top and bottom of the device. As mentioned above, the back of the Click 223 features a 5-position connector that plugs into a T-bus connector and passes power and communication from the Click 223 to the rest of the T-bus and vice versa. This connector is only connected to the RS-485A bus; any data on the RS-485B bus will not be transmitted on the T-bus. The top and bottom of the Click 223 each have three pluggable screw terminal blocks with four terminals each, for a total of twelve connections. These terminals are used for wiring in the cable from the SmartSensor Advance or other external device. Each set of twelve terminals is made up of the following: ˽˽ +DC and -DC for power ˽˽ Four ground terminals for drains ˽˽ Two PE (protective earth) terminals for earth ground CHAPTER 18  •  CLICK 223 ˽˽ Two RS-485 connections, each consisting of one -485 and one +485 terminal The front of the Click 223 has an LED that lights up to indicate the device has power and the surge protection is working properly. If the LED is not lit, either the device has no power or the surge protection is not working. Installation The Click 223 is designed for use with the SmartSensor 6-conductor cable and a Wavetronix sensor that uses this cable, such as the SmartSensor Advance. The steps that follow in this section are specific to this application. If you do not plan on using the 6-conductor cable, you can skip the steps below and simply wire your power and communications by following the labels on the screw terminals. Which side of the Click 223 you wire into depends on your installation. If you’ve got an underground cable run, you’ll put a Click 223 on each end and connect the ends of the cable to the UNPROTECTED side of each device. If you’re connecting to a sensor as well, the sensor cable should be connected into the side of the device marked PROTECTED. -DC (Black) +DC (Red) -485A (Orange) +485A (Orange/white) Drain +485B (Blue/white) -485B (Blue) -485B (Blue) +485B (Blue/white) +485A (Orange/white) -485A (Orange) +DC (Red) -DC (Black) Drain Earth ground Figure 18.3 – Wiring the Click 223 Once you know which side of the device you need to wire into, follow the steps below to do so: 1 2 Using a rocking motion, mount the Click 223 onto the DIN rail, making sure it’s on the T-bus with the devices it’s supposed to protect. Wire the cable to the frontmost pluggable screw terminal block: connect the blue wire to the screw terminal marked -485B. Connect the blue and white–striped wire to the screw terminal marked +485B. (For ease, you can remove the terminal block from the 153 154 CHAPTER 18  •  CLICK 223 3 4 5 6 device, wire it, then reinsert it.) Wire the middle pluggable screw terminal block: connect the orange wire to the screw terminal marked -485A. Connect the orange and white–striped wire to the screw terminal marked +485A. Wire the backmost pluggable screw terminal block: connect the red wire into the screw terminal marked +DC and the black wire into -DC. Wire the drain into any screw terminal marked GND. Connect a 14 AWG wire between either of the terminals marked PE to a grounded location, such as a grounding lug or an earth ground terminal block (if you are using terminal blocks). If you need to wire the PROTECTED side of the device as well, do so now. However, since the UNPROTECTED side has already been wired with earth ground, it is not necessary to follow step 6 on the PROTECTED side. 19 Click 230 — AC Surge Protector In this chapter ˽˽ Physical Features ˽˽ Installation 19 The Click 230 provides up to 10 kA (8/20 μS) of surge protection per AC input line. Figure 19.1 – The Click 230 156 CHAPTER 19  •  CLICK 230 Note The Click 230 is designed for use with 120 VAC. A 220 VAC version is available for installations using that voltage. See your Wavetronix dealer for details. Protection is achieved through the use of tightly coordinated hybrid circuits consisting of fast-responding surge-arresting diodes (SAD), high-powered current-handling gas discharge tubes (GDT) and series decoupling elements. Physical Features The Click 230 has eight active screw terminal connections. The module is wired in through terminals 1, 3 and 5, and out through terminals 2, 4 and 6. Terminals 11 and 12, also on the OUT side, are for testing. Figure 19.2 – Diagram of the Click 230 Installation 1 Connect the black (line) wire from the Click 210 circuit breaker to the rightmost screw terminal (terminal 5) on the IN side of the Click 230. CHAPTER 19  •  CLICK 230 2 3 Connect the white (neutral) and green (ground) wires from the terminal block or from the AC cord into screw terminals 1 and 3, respectively, also on the side marked IN. Connect the outgoing neutral and power wires to screw terminals 2 and 6, respectively, on the side marked OUT. Terminals 3 and 4 are directly bonded via the metal mounting foot of the base element to the DIN rail, so there is no need for any additional grounding. 157 Click 250 — Wireless Surge Protector 20 In this chapter ˽˽ Physical Features ˽˽ Installation 20 The Click 250 is a 100 MHz–3 GHz bulkhead N-Female to N-Female 90 V coaxial wireless surge protector. Mounted in the wall of a cabinet, the Click 250 protects wireless communication devices in the cabinet, such as the Click 400, from surges that could come in from external antennas to which those wireless devices are wired. Figure 20.1 – The Click 250 160 CHAPTER 20  •  CLICK 250 Physical Features Figure 20.2 – Diagram of the Click 250 The Click 250 is a bulkhead N-Female to N-Female connector; both connector ports are equally protected. The ground lug and terminal are located directly on the housing of the Click 250. Installation The Click 250 should be mounted in the wall (usually the bottom) of a cabinet, in a 5/8” hole. Wavetronix fiberglass cabinets come with such holes predrilled; aluminum cabinets do not and a hole will need to be drilled. It is recommended that the hole be in the bottom of the cabinet, on the far right. x GND Click! 250 Figure 20.3 – Click 250 in Wall of Cabinet Follow the steps below to install a Click 250. 1 Connect a 12 AWG stranded copper grounding wire to the surge GND bolt, as shown below. There are two bolts on the Click 250; use the bolt with the rounded top. CHAPTER 20  •  CLICK 250 Figure 20.4 – Connecting the Grounding Wire 2 3 4 Get a coaxial cable that’s female on one end and male on the other. Connect the female connector to the antenna connector on the wireless communication module, and connect the male connector to the nonbulkhead (smaller) end of the Click 250. Remove the nut and lock washer from the bulkhead (larger) end of the Click 250, then insert that end into the hole in the side of the cabinet. Push the provided rubber washer over the bulkhead end, which should now be on the outside of the cabinet. Reattach the nut and lock washer and tighten. Figure 20.5 – Mounting the Click 250 in the Cabinet 5 6 Get a coaxial cable that is female on both ends. Connect one end to the bulkhead end of the Click 250. Connect the other end to the antenna. Connect the grounding wire from step 1 to the ground lug in the cabinet or another earth ground location. Figure 20.6 – Connecting to Earth Ground 161 Click 301 — Serial to Ethernet Converter 21 In this chapter ˽˽ Physical Features ˽˽ On-device Configuration ˽˽ Computer Configuration 21 The Click 301 serial to Ethernet converter changes half-duplex two-wire RS-232 and RS485 communication to Ethernet and vice versa. Use this device in a cabinet to transfer data from a sensor to your computer or traffic operations center via a wired network connection. Figure 21.1 – The Click 301 164 CHAPTER 21  •  CLICK 301 Physical Features The Click 301 has several communication ports, as well as features for configuration (see Figure 21.2). Figure 21.2 – Diagram of the Click 301 Communication Ports The back of the Click 301 features a 5-position connector that plugs into a T-bus connector and provides power and RS-485 communication to the device. It also passes RS-485 communication from the module to all other devices on the T-bus. The top of the device has a pluggable screw terminal block that features -485, one +485 and two ground screw terminals for wiring RS-485 communication. This screw terminal block can be removed for easy preinstallation wiring. It will not be necessary to wire RS-485 through the screw terminal block if the device is connected to a T-bus with uninterrupted RS-485 communication. The front of the Click 301 features a DB-9 connector for RS-232 communication. A straightthrough cable can be used to connect from this port to a computer so that the device can be configured using Click Supervisor. The front of the device also has an RJ-45 jack for Ethernet communication. Any data on one port will be transmitted simultaneously on all other ports. CHAPTER 21  •  CLICK 301 Configuration Features The faceplate of the Click 301 has three activity indicator LEDs: ˽˽ PWR (red) lights up when the device has power. ˽˽ TD (yellow) lights up when the device is transmitting data. ˽˽ RD (green) lights up when the device is receiving data. The LEDs are also used to indicate operation modes, which will be discussed in the Ondevice Configuration section of this chapter. The faceplate also has a push-button labeled Mode Switch, which is used to cycle the Click 301 through operation modes. This will be discussed in the On-device Configuration section of this chapter. On-device Configuration The Click 301 can be configured using the push-button on the lower part of the faceplate. Press and hold the push-button to cycle through the different operation modes; release the button when the desired mode is reached. A quick press and release of the push-button will exit out of any mode and return the unit back to normal operation. Table 21.1 and the following sections describe the different operating modes. Mode LED Definition Autobaud Green (solid) To autobaud the Click 301, press the push-button, then release when the green LED turns on. Reset Red (flashing) To reset the Click 301 to factory defaults, press the pushbutton, then release when the red LED is blinking. Table 21.1 – Click 301 Operation Mode Definitions Autobaud (green solid) The Autobaud mode is used to match baud rates with an external device. By default, the device will attempt to match baud rates with a SmartSensor on the bus; however, the device can be configured to autobaud with any device that supports a serial interface. While the device is autobauding, the green LED will be on while the red LED blinks. The autobaud was successful if the red LED stays on and the green LED turns off. If the autobaud is not successful after a few minutes of trying, the red and green LEDs will stay on indefinitely. In the case of a failed autobaud, push the push-button once to return the device to its normal state. 165 166 CHAPTER 21  •  CLICK 301 Note On certain devices, the yellow LED may replace the green LED in the autobaud process—that is, the yellow LED will come on to select the autobaud process, the yellow LED is on during the autobaud process, etc. Factory Reset (red flashing) The Factory Reset operation will erase all user-configured fields, meaning that after the reset, the Click 301 may have to be reconfigured to work properly in its current application. If a device is not responding and not communicating, resetting the device may fix the problem. Once the device is responding, restore the configuration needed for its current application. To reset the Click 301 to factory defaults, release the push-button when the red LED begins flashing. The red LED should blink slowly, then the green and yellow LEDs will flicker. When the red LED glows solid, the module has the original factory configuration. Computer Configuration The Click 301 can be configured more exactly using the Click Supervisor software. See Chapters 4 and 5 of this document for instructions on how to download and install Click Supervisor and how to connect to your device using the software. The Click 301 can be configured using one of three drivers (see Figure 21.3). Figure 21.3 – Selecting a Driver Which driver you use will depend on what you need to use the device for. The first two drivers are known as application drivers and are used to set the Click device to work in specific CHAPTER 21  •  CLICK 301 applications. Use the list below to find the appropriate driver for your application. ˽˽ If you intend to connect from your TOC to the Click 301 to a sensor, use the SmartSensor driver. ˽˽ If you intend to connect from your TOC to a Click 301 to another Click 301 to the sensor, use the Point to Point driver. To see advanced settings, use the Expert driver. This driver, which exposes every available field for the Click 301, should only be used under the direction of Wavetronix Technical Services. After you have made configuration changes on a driver and saved it to the Click device, the word “current” will appear after that driver to indicate the driver that is currently loaded onto the device. Note Some settings appear on multiple drivers. Changing one of those settings on any driver and saving them to the Click device will change that setting on all other drivers it appears on. The Backups option can be used to read configurations that have previously been saved to file. See Chapter 5 for more information. Application Drivers The two application drivers have very similar settings and fields; the only important differences are found in the Setup tab. Under the Setup tab, you can change the settings affecting the setup of the device and sensor (see Figure 21.4 and Table 21.2). Figure 21.4 – Setup Tab 167 168 CHAPTER 21  •  CLICK 301 The following settings are common to both application drivers. Setting Description Description Shows a description of the device being configured. This is only for your information and does not affect the operation of the device. Location Displays the location of the device being configured. This is only for your information and does not affect the operation of the device. Device ID Gives the ID number of the device being configured, which is used to identify the device when you are connecting to it. By default, this number is the last five digits of the serial number, which can be found under the About tab or on the barcode sticker on the bottom of the device. It is recommended that you do not change this number unless another device on the network has the same ID number. Baud Rate Allows you to change the baud rate at which the device connects to the sensor. IP Address Lets you view and change the IP address currently assigned to the device. Each Click 301 defaults to an IP address of 172.16.0.13. IP Port Lets you view and change the IP port currently assigned to the device. Each Click 301 defaults to 10001. Table 21.2 – Setup Tab Common Settings In addition to the common settings, the Point to Point driver has the following settings: Setting Description Remote IP Allows you to enter the IP address of the Click 301 that you want the device you’re configuring to connect to. Each Click 301 defaults to a remote IP address of 172.16.0.14. Remote Port Allows you to enter the IP port of the Click 301 that you want the device you’re configuring to connect to. Each Click 301 defaults to a remote port of 10001. Table 21.3 – Specific Point to Point Settings Under the About tab, you can view information about your Click 301 (see Figure 21.5 and Table 21.4). CHAPTER 21  •  CLICK 301 Figure 21.5 – About Tab The following settings are common to both application drivers: Settings Description Driver Names the driver you are currently working with. Serial Number Displays the serial number of your device. Firmware Version Shows the version of firmware your device currently has installed. If Click Supervisor detects a discrepancy between this version and the most current version it currently has access to, you will be prompted to upgrade when you connect to the device. Table 21.4 – About Tab Common Settings Under the Diagnostics tab, you can run diagnostics on your device (see Figure 21.6). Click the General or Ethernet buttons to run diagnostics on the items listed below each button. If a problem is detected, the program will display a red square next to the item in question. If no problems are detected, a green circle will appear. 169 170 CHAPTER 21  •  CLICK 301 Figure 21.6 – Diagnostics Tab Once you have finished, use the menu bar at the top of the screen to save your settings, return to the Select Driver screen, and more. ˽˽ The Save menu allows you to save your settings. Select Save to File to save your settings to a file. Selecting this will open a directory box, allowing you to name your settings file. This file will always be saved in the Wavetronix folder created when you installed Click Supervisor, under Wavetronix > ClickHome > Drivers > 301 > User. You can also select Save to Device to save your settings to your Click 301. Note If you do not save your settings to your Click 301, they will be lost the next time you power the device down. ˽˽ The Tools menu contains five options for working with your device. Reset > System power cycles your device, while Reset > Factory Default restores your device to the settings with which it was shipped. Restore will restore the driver to the settings currently saved on the Click 301, erasing any unsaved changes. Upgrade can be used to manually upgrade to the most current firmware for your device. Hex View changes the view of certain settings in the driver to hexadecimal. ˽˽ Clicking the Quit menu exits the driver and returns you to the Click Supervisor main page. Expert The Expert driver allows you to see all possible settings and fields, both those available in other drivers and those available only through this driver. The driver is divided into three tabs—System, Ethernet and Diagnostics—which are then subdivided further. CHAPTER 21  •  CLICK 301 The System > General tab combines elements of the Setup and About tabs from the other drivers (see Figure 21.7 and Table 21.5). Figure 21.7 – Expert Driver General Tab Setting Description Module Shows the last driver (besides Expert) that was loaded onto the device. Driver Names the driver you are currently working with. Description Shows a description of the device being configured. This is only for your information and does not affect the operation of the device. Location Displays the location of the device being configured. This is only for your information and does not affect the operation of the device. Serial Number Displays the serial number of your device. Firmware Version Shows the version of firmware your device currently has installed. If Click Supervisor detects a discrepancy between this version and the most current version it currently has access to, you will be prompted to upgrade when you connect to the device. Subnet ID Shows the subnet ID number. This option is currently not available. Device ID Gives the ID number of the device being configured, which is used to identify the device when you are connecting to it. By default, this number is the last five digits of the serial number, which can be found under the About tab or on the barcode sticker on the bottom of the device. It is recommended that you do not change this number unless another device on the network has the same ID number. Table 21.5 – Expert Driver General Tab The System > Comm tab allows you to configure how the Click device communicates (see Figure 21.8 and Table 21.6). 171 172 CHAPTER 21  •  CLICK 301 Figure 21.8 – Expert Driver Comm Tab Setting Description Baud Rate Allows you to change the baud rate at which the device connects to the sensor. Flow Control Is used for configuring hardware handshaking. This option is currently not available. Parity Allows you to set parity error checking. Stop Bits Allows you to set the number of stop bits. Data Bits Shows you the number of data bits being sent. This option cannot be changed. Active Port Indicates on which port you are communicating with the sensor. This option cannot be changed. Latency Indicates the latency between the sensor and the Click device. This option cannot be changed. Table 21.6 – Expert Driver Comm Tab The System > Autobaud tab allows you to configure how the device autobauds (see Figure 21.9 and Table 21.7). CHAPTER 21  •  CLICK 301 Figure 21.9 – Expert Driver Autobaud Tab Setting Description Command Allows you to set the command sent from the device during the autobaud process. Don’t change these values unless instructed to by Wavetronix Technical Services. Response Shows the response the device is expecting from the above command. Don’t change these values unless instructed to by Wavetronix Technical Services. SmartSensor ID Shows the ID number of the sensor with which the Click device is currently communicating. This only shows the number after you have autobauded the Click device; when the Click device is not communicating with a sensor, this option will display a 1. Server/Client Allows you to set whether the device is a server or client. (This option is not related to device autobauding.) Table 21.7 – Expert Driver Autobaud Tab The Ethernet > General > Network tab allows you to configure network settings (see Figure 21.10 and Table 21.8). 173 174 CHAPTER 21  •  CLICK 301 Figure 21.10 – Expert Driver Network Tab Setting Description Local IP Lets you view and change the IP address currently assigned to the device. Local TCP Port Lets you view and change the IP port currently assigned to the device. Each Click 301 defaults to 10001. Subnet Mask Defines the number of bits taken from the IP address that are assigned for the host part. Gateway IP Lets you view and change the gateway IP address. The gateway address should be the IP address of the router connected to the same LAN segment as the unit. The gateway address must be within the local network. Remote IP Allows you to enter the IP address of the Click 301 that the Click 301 you’re configuring should connect to. Each Click 301 defaults to a remote IP address of 172.16.0.14. Remote TCP Port Allows you to enter the port of the Click 301 that the Click 301 you’re configuring should connect to. Each Click 301 defaults to a remote port of 10001. Auto Increment Increments the local port number for new outgoing connections automatically. The range of auto-incremented port numbers is 50,000 to 59,999 and loops back to the beginning when the maximum range is reached. Only use this automatic port increment feature to initiate a connection using TCP. Table 21.8 – Expert Driver Network Tab The Ethernet > General > Server tab allows you to configure server settings (see Figure 21.11 and Table 21.9). CHAPTER 21  •  CLICK 301 Figure 21.11 – Expert Driver Server Tab Setting Description Telnet Password Allows you to enter the password required for Telnet access. ARP Cache Timeout Defines the number of seconds (1–600) before the device refreshes the ARP cache. TCP Keepalive Defines how many seconds the unit waits during an inactive connection before checking its status. If the unit does not receive a response, it drops that connection. The value can be between 0 and 60 seconds. 0 disables keepalive. The default setting is 45. Monitor Mode Disable Allows you to disable entry into the monitor mode using the ‘yyy’ or ‘xx1’ key sequence at startup. This field prevents the unit from entering monitor mode by interpreting the stream of characters that are received during the device server’s initialization at startup. CPU Performance (High) Sets the device to high performance. High performance is 88 MHz, while regular is 48 MHz. The high performance setting requires more energy. DHCP Name Lets you enter the name of the host on the network providing the IP address. HTTP Port Allows the configuration of the web server port number. The valid range is 1–65535. The default port is 80. Table 21.9 – Expert Driver Server Tab The Ethernet > Channel > Connect tab defines how the unit makes a connection (see Figure 21.12 and Table 21.10). 175 176 CHAPTER 21  •  CLICK 301 Figure 21.12 – Expert Driver Connect Tab Setting Description Incoming Connection Allows you to configure how the device reacts to incoming connections over the network. Never rejects all external connection attempts. Accept DTR accepts external connection requests only when the Modem Control In input is asserted; this setting cannot be used with Modem mode. Accept All is the default setting and accepts any incoming connection when a connection is not already established. Response Lets you set character response. When this is set to Character, a single character is transmitted to the serial port when there is a change in connection state: C = connected D = disconnected N = host unreachable The IP address of the host connecting to the CoBos device will be provided when you use verbose mode. This option is overridden when the Active Start Modem Mode or Active Start Host List is in effect. The default setting is Nothing. CHAPTER 21  •  CLICK 301 Startup Allows you to configure active startup settings. No Activity, the default, does not attempt to initiate a connection under any circumstance. Any Char attempts to connect when any character is received from the serial port. Active DTR accepts external connection requests only when the Modem Control In input is asserted. Specific Char attempts to connect when it receives a specific start character from the serial port. The default start character is a carriage return. To change the character, see the Disconnect tab. Manual Connect attempts to connect when directed by a command string received from the serial port. Autostart automatically connects to the remote IP address and remote port specified when the firmware starts. Modem Mode causes the unit to present a modem interface to the attached serial device. It accepts AT-style modem commands and handles the modem signals correctly. Input Buffer Allows you to choose circumstances under which the input buffer will be flushed. On Active clears the input buffer when a connection is initiated from the device to the network. On Passive clears the input buffer when a connection is initiated from the network to the device. At Disconn. clears the input buffer when the network connection with the device is disconnected. Output Buffer Allows you to choose circumstances under which the output buffer will be flushed. On Active clears the output buffer when a connection is initiated from the device to the network. On Passive clears the output buffer when a connection is initiated from the network to the device. At Disconn. clears the output buffer when the network connection with the device is disconnected. Table 21.10 – Expert Driver Connect Tab The Ethernet > Channel > Disconnect tab determines the conditions under which the unit will cause a network connection to terminate (see Figure 21.13 and Table 21.11). 177 178 CHAPTER 21  •  CLICK 301 Figure 21.13 – Expert Driver Disconnect Tab Setting Description Disconnect Mode Allows you to set conditions under which the device should drop a connection. Ignore DTR, the default, indicates that the Modem Control In doesn’t affect the connection. DTR Drop sets the network connection to or from the serial port to disconnect (drop) when Modem Control In transitions from an asserted state to not asserted state. Start Character Provides a place to enter the start character that is used to signal the active startup function (found under the Connect tab) to attempt to connect. Telnet Mode Enables Telnet mode. Port Password Enables the use of a password on the serial port. CTRL-D Disconnect Drops the connection when Ctrl-D or Hex 04 is detected. Both Telnet Com Port Cntrl and Check EOT (Ctrl+D) must be enabled for Disconnect with EOT to function properly. Ctrl+D is only detected going from the serial port to the network. Hard Disconnect Closes the TCP connection even if the remote site does not acknowledge the disconnect request. Inactivity Timeout Sets the amount of time there can be no activity on the serial line before the device drops the connection. Telnet Name/Port Password Lets you enter either the Telnet name you’re using or the password for the serial port, depending on which of those two boxes—Telnet Mode or Port Password—is checked. Table 21.11 – Expert Driver Disconnect Tab The Ethernet > Channel > Packing tab allows you to configure packing settings, as well as to set other options (see Figure 21.14 and Table 21.12). CHAPTER 21  •  CLICK 301 Figure 21.14 – Expert Driver Packing Tab Setting Description Packing Algorithm Enables packing, which defines how long the unit should wait before sending accumulated characters. Idle Time (ms) Allows you to set the maximum time for inactivity. Trailing Chars Lets you select the number of bytes to send after the end-of-sequence characters. The default is None. Send Immediate Causes the module to send immediately after recognizing the transmit condition (sendchar or timeout). If it is not set, any characters already in the serial buffer are included in the transmission after a “transmit” condition is found. Send Char 2-Byte Causes the device to interpret the sendchars as a 2-byte sequence; if this option is not enabled, the module interprets them independently. Send Characters Lets you enter up to two characters in hexadecimal. If the module receives a character on the serial line that matches one of these characters, it sends the character immediately, along with any awaiting characters, to the TCP connection. This action minimizes the response time for specific protocol characters on the serial line (for example, ETX, EOT). UDP Datagram Enables the use of UPD datagrams. This option cannot be changed here; it is enabled when you open one of the two point to multipoint drivers and save that driver to the device. Table 21.12 – Expert Driver Packing Tab The Ethernet > Hostlist tab allows you to set up and use a host list. When the host list is enabled, the Click 301 scrolls through the host list until it makes a successful connection to one of the addresses. After a successful connection, the unit stops trying to connect to any others. If this connection fails, the unit continues to scroll through the table until the next successful connection. 179 180 CHAPTER 21  •  CLICK 301 The host list supports a minimum of 1 and a maximum of 12 entries. Each entry contains an IP address and a port number. The host list is flowed onto three third-level tabs. If you need to enter more than the three host IP addresses on the first screen, go to the IP 4-9 and IP 10-12 third-level tabs. The three third-level tabs below Ethernet > Hostlist allow you to configure the hostlist (see Figure 21.15 and Table 21.13). Figure 21.15 – Expert Driver Hostlist Tabs Setting Description Hostlist Enable Enables the use of the host list. Retry Counter Lets you set the number of times the module should attempt to retry connecting to the host list. Retry Timeout Allows you to enter the duration (in seconds) the module should try to make a connection to the host list before abandoning the attempt. Host IP Address Lets you enter the host’s IP address. TCP Port Allows you to set the target port number. Table 21.13 – Expert Driver Hostlist Tabs Under the Diagnostics tab, you can run diagnostics on your device (see Figure 21.16). Click the General or Ethernet buttons to run diagnostics on the items listed below each button. CHAPTER 21  •  CLICK 301 If a problem is detected, the program will display a red square next to the item in question. If no problems are detected, a green circle will appear. Figure 21.16 – Expert Driver Diagnostics Tab Once you have finished, use the menu bar at the top of the screen to save your settings, return to the Select Driver screen, and more. ˽˽ The Save menu allows you to save your settings. Select Save to File to save your settings to a file. Selecting this will open a directory box, allowing you to name your settings file. This file will always be saved in the Wavetronix folder created when you installed Click Supervisor, under Wavetronix > ClickHome > Drivers > 301 > User. You can also select Save to Device to save your settings to your Click 301. Note If you do not save your settings to your Click 301, they will be lost the next time you power the device down. ˽˽ The Tools menu contains five options for working with your device. Reset > System power cycles your device, while Reset > Factory Default restores your device to the settings with which it was shipped. Restore will restore the driver to the settings currently saved on the Click 301, erasing any unsaved changes. Upgrade can be used to manually upgrade to the most current firmware for your device. Hex View changes the view of certain settings in the driver to hexadecimal. ˽˽ Clicking the Quit menu exits the driver and returns you to the Click Supervisor main page. 181 Click 304 — RS-232 to RS-485 Converter 22 In this chapter ˽˽ Physical Features ˽˽ On-device Configuration ˽˽ Computer Configuration 22 The Click 304 converts half-duplex RS-232 communication to RS-485 communication and vice versa. The Click 304 improves serial communications and also extends the capabilities of a serial network. Figure 22.1 – The Click 304 184 CHAPTER 22  •  CLICK 304 Physical Features The Click 304 has several communication ports, as well as features for configuration. Figure 22.2 – Diagram of the Click 304 Communication Ports The back of the Click 304 features a 5-position connector that plugs into a T-bus connector and provides power and RS-485 communication to the device. It also passes RS-485 communication from the Click 304 to all other devices on the T-bus. The top of the device has a pluggable screw terminal block that features four terminals—one -485, one +485 and two grounds—for wiring RS-485 communication. This screw terminal block can be removed for easy preinstallation wiring. It will not be necessary, however, to wire RS-485 through the screw terminal block if the device is connected to a T-bus with uninterrupted RS-485 communication. The front of the Click 304 features a DB-9 connector and an RJ-11 connector for RS-232 and RS-485 communication. A straight-through cable can be used to connect from the RS-232 DB-9 connector to a computer so that the device can be configured using Click Supervisor. An RJ-11 cable can be connected from the front of the Click 304 to the front of the Click 172/174 contact closure cards. Any data on one port will be transmitted simultaneously on all other ports. CHAPTER 22  •  CLICK 304 Configuration Features The faceplate of the Click 304 has the following three LEDs: ˽˽ PWR (red) lights up when the device has power. ˽˽ TD (yellow) lights up when the device is transmitting data. ˽˽ RD (green) lights up when the device is receiving data. The LEDs are also used to indicate operation modes, which will be discussed in the Ondevice Configuration section of this chapter. The front also has a push-button labeled Mode Switch, which is used to cycle the Click 304 through operation modes. This will be discussed in the On-device Configuration section of this chapter. On-device Configuration The Click 304 can be configured using the push-button on the lower part of the faceplate. Press and hold the push-button to cycle through the different operation modes; release the button when the desired mode is reached. A quick press and release of the push-button will exit out of any mode and return the unit back to normal operation. Table 22.1 and the following sections describe the different operating modes. Mode LED Definition Autobaud Green (solid) To autobaud the Click 304, press the push-button, then release when the green LED turns on. Reset Red (flashing) To reset the Click 304 to factory defaults, press the pushbutton, then release when the red LED is blinking. Table 22.1 – Click 304 Operation Mode Definitions Autobaud (green solid) The Autobaud mode is used to match baud rates with an external device. By default, the device will attempt to match baud rates with a SmartSensor on the bus; however, the device can be configured to autobaud with any device that supports a serial interface. While the device is autobauding, the green LED will be on while the red LED blinks. The autobaud was successful if the red LED stays on and the green LED turns off. If the autobaud is not successful after a few minutes of trying, the red and green LEDs will stay on indefinitely. In the case of a failed autobaud, push the push-button once to return the device to its normal state. 185 186 CHAPTER 22  •  CLICK 304 Note On certain devices, the yellow LED may replace the green LED in the autobaud process—that is, the yellow LED will come on to select the autobaud process, the yellow LED is on during the autobaud process, etc. Factory Reset (red flashing) The Factory Reset operation will erase all user-configured fields and the Click 304 may have to be reconfigured to work properly in its current application. If a device is not responding and not communicating, resetting the device may fix the problem. Once the device is responding, restore the configuration needed for its current application. Computer Configuration The Click 304 can be configured more exactly using the Click Supervisor software. See Chapters 4 and 5 of this document for instructions on how to download and install Click Supervisor and how to connect to your device using the software. The Click 304 is configured using one of the following drivers (see Figure 22.3): Figure 22.3 – Selecting a Driver Which driver you use will depend on what you need to use the device for. If you intend to connect from your TOC to the Click 304 to a sensor, use the SmartSensor driver. To see advanced settings, use the Expert driver. This driver, which exposes every available CHAPTER 22  •  CLICK 304 field for the Click 304, should only be used under the direction of Wavetronix Technical Services. After you have made configuration changes on a driver and saved it to the Click device, the word “current” will appear after that driver to indicate the driver that is currently loaded onto the device. Note Some settings appear on multiple drivers. Changing one of those settings on any driver and saving them to the Click device will change that setting on all other drivers it appears on. The Backups option can be used to read configurations that have previously been saved to file. See Chapter 5 for more information. SmartSensor Driver The SmartSensor driver contains three tabs: Setup, About and Diagnostics. The Setup tab has the following settings (see Figure 22.4 and Table 22.2): Figure 22.4 – SmartSensor Driver Setup Tab Setting Description Description Shows a description of the device being configured. This is only for your information and does not affect the operation of the device. Location Displays the location of the device being configured. This is only for your information and does not affect the operation of the device. 187 188 CHAPTER 22  •  CLICK 304 Device ID Gives the ID number of the device being configured, which is used to identify the device when you are connecting to it. By default, this number is the last five digits of the serial number, which can be found under the About tab or on the barcode sticker on the bottom of the device. It is recommended that you do not change this number unless another device in the network has the same ID number. Baud Rate Allows you to change the baud rate at which the device connects to the sensor. Table 22.2 – SmartSensor Driver Setup Tab The About tab contains the following information about your Click 304 (see Figure 22.5 and Table 22.3): Figure 22.5 – SmartSensor Driver About Tab Settings Description Driver Names the driver you are currently working with. Serial Number Displays the serial number of your device. Firmware Version Shows the version of firmware your device currently has installed. If Click Supervisor detects a discrepancy between this version and the most current version it currently has access to, you will be prompted to upgrade when you connect to the device. Table 22.3 – SmartSensor Driver About Tab Under the Diagnostics tab, you can run diagnostics on your device (see Figure 22.6). Click the General button to run diagnostics on the items listed below the button. If a problem is detected, the program will display a red square next to the item in question. If no problems are detected, a green circle will appear. CHAPTER 22  •  CLICK 304 Figure 22.6 – SmartSensor Driver Diagnostics Tab Once you have finished, use the menu bar at the top of the screen to save your settings, return to the Select Driver screen, and more. ˽˽ The Save menu allows you to save your settings. Select Save to File to save your settings to a file. Selecting this will open a directory box, allowing you to name your settings file. This file will always be saved in the Wavetronix folder created when you installed Click Supervisor, under Wavetronix > ClickHome > Drivers > 304 > User. You can also select Save to Device to save your settings to your Click 304. Note If you do not save your settings to your Click 304, they will be lost the next time you power the device down. ˽˽ The Tools menu contains five options for working with your device. Reset > System power cycles your device, while Reset > Factory Default restores your device to the settings with which it was shipped. Restore will restore the driver to the settings currently saved on the Click 304, erasing any unsaved changes. Upgrade can be used to manually upgrade to the most current firmware for your device. Hex View changes the view of certain settings in the driver to hexadecimal. ˽˽ Clicking the Quit menu exits the driver and returns you to the Click Supervisor main page. Once you have finished, click Save on the menu bar to save your settings. Expert Driver The Expert driver allows you to see all possible settings and fields, both those available in 189 190 CHAPTER 22  •  CLICK 304 the SmartSensor driver and those available only through this driver. The driver is divided into two tabs—System and Diagnostics—which are then subdivided further. The System > General tab combines elements of the Setup and About tabs from the other drivers (see Figure 22.7 and Table 22.4). Figure 22.7 – Expert Driver General Tab Setting Description Module Allows you to enter a name for the device. Driver Names the driver you are currently working with. Description Shows a description of the device being configured. This is only for your information and does not affect the operation of the device. Location Displays the location of the device being configured. This is only for your information and does not affect the operation of the device. Serial Number Displays the serial number of your device. Firmware Version Shows the version of firmware your device currently has installed. If Click Supervisor detects a discrepancy between this version and the most current version it currently has access to, you will be prompted to upgrade when you connect to the device. Subnet ID Shows the subnet ID number. This option is currently not available. Device ID Gives the ID number of the device being configured, which is used to identify the device when you are connecting to it. By default, this number is the last five digits of the serial number, which can be found under the About tab or on the barcode sticker on the bottom of the device. It is recommended that you do not change this number unless another device on your network has the same ID number. Table 22.4 – Expert Driver General Tab The System > Comm tab allows you to configure Click device communication (see Figure 22.8 and Table 22.5). CHAPTER 22  •  CLICK 304 Figure 22.8 – Expert Driver Comm Tab Setting Description Baud Rate Allows you to change the baud rate at which the device connects to the sensor. Flow Control Is used for configuring hardware handshaking. This option is currently not available. Parity Allows you to set parity error checking. Stop Bits Allows you to set the number of stop bits. Data Bits Shows you the number of data bits being sent. This option currently cannot be changed. Active Port Indicates on which port you are communicating with the sensor. This option cannot be changed. Latency Indicates the latency between the sensor and the Click device. This option cannot be changed. Table 22.5 – Expert Driver Comm Tab The Autobaud subtab allows you to configure how the device autobauds (see Figure 22.9 and Table 22.6). 191 192 CHAPTER 22  •  CLICK 304 Figure 22.9 – Expert Driver Autobaud Tab Setting Description Command Allows you to set the command sent from the device during the autobaud process. Don’t change these values unless instructed to by Wavetronix Technical Services. Response Shows the response the device is expecting from the above command. Don’t change these values unless instructed to by Wavetronix Technical Services. SmartSensor ID Shows the ID number of the sensor with which the Click device is currently communicating. This only shows the number after you have autobauded the Click device; when the Click device is not communicating with a sensor, this option will display a 0. Server/Client Allows you to set whether the device is a server or client in a point to multipoint setup. (This option is not related to device autobauding.) Table 22.6 – Expert Driver Autobaud Tab Under the Diagnostics tab, you can run diagnostics on your device (see Figure 22.10). Click the General button to run diagnostics on the items listed below the button. If a problem is detected, the program will display a red square next to the item in question. If no problems are detected, a green circle will appear. CHAPTER 22  •  CLICK 304 Figure 22.10 – Expert Driver Diagnostics Tab Once you have finished, use the menu bar at the top of the screen to save your settings, return to the Select Driver screen, and more. ˽˽ The Save menu allows you to save your settings. Select Save to File to save your settings to a file. Selecting this will open a directory box, allowing you to name your settings file. This file will always be saved in the Wavetronix folder created when you installed Click Supervisor, under Wavetronix > ClickHome > Drivers > 304 > User. You can also select Save to Device to save your settings to your Click 304. Note If you do not save your settings to your Click 304, they will be lost the next time you power the device down. ˽˽ The Tools menu contains five options for working with your device. Reset > System power cycles your device, while Reset > Factory Default restores your device to the settings with which it was shipped. Restore will restore the driver to the settings currently saved on the Click 304, erasing any unsaved changes. Upgrade can be used to manually upgrade to the most current firmware for your device. Hex View changes the view of certain settings in the driver to hexadecimal. ˽˽ Clicking the Quit menu exits the driver and returns you to the Click Supervisor main page. Once you have finished, click Save on the menu bar to save your settings. 193 Click 330 — Unmanaged Switch 23 In this chapter ˽˽ Physical Features ˽˽ Installation ˽˽ Switching Characteristics 23 The Click 330 is used for quick and cost-effective Ethernet network expansion at the field level. The switch offers transmission speeds of 10/100/1000 Mbps. The RJ-45 ports offer auto-crossing and auto-negotiation functionality. Figure 23.1 – The Click 330 and 331 196 CHAPTER 23  •  CLICK 330 Physical Features Click 330 module has several Ethernet ports, allowing you to create a quick Ethernet network by simply connecting Ethernet cables. DIN Rail Clip TOP Redundant Power Supply FRONT LED Indicators Click! 330 US1 US2 US www.wavetronix.com K/ LN CT A K/ LN CT A X1 0 10 X2 0 10 K/ LN CT A K/ LN CT A X3 0 10 RJ45 Ports (8) with LED Indicators FL SWITCH SFN 8GT Ord.No.2891673 1000 Mbps Switch, 8 Port X4 0 10 K/ LN CT A K/ LN CT A X5 0 10 X6 0 10 K/ LN CT A K/ LN CT A X7 0 10 X8 0 10 Figure 23.2 – Diagram of the Click 330 Screw Terminals The top of the Click 330 contains a screw terminal block, with a total of six screw terminal connections. The screw terminal block allows you to wire a power supply (US1 and GND), a redundant power supply (US2 and GND) and alarm notices (R1 and R2). Ethernet Ports The Click 330 is an unmanaged switch with eight RJ-45 ports. LEDs The Click 330 has three different kinds of LEDs. ˽˽ At the top of the device are two green LEDs labeled US1 and US2, used for monitoring the power supply (see Table 23.1). US1 monitors the main power supply and US2 monitors the second (redundant) power supply. CHAPTER 23  •  CLICK 330 Status Meaning On Supply voltage is in an acceptable range Off Supply voltage is too low Table 23.1 – Power Monitor LEDs ˽˽ Each Ethernet port has two LEDs that show the data transmission speed of that port, as shown in Table 23.2. These LEDs are labeled 100/ACT and 1000/ACT. If the LED is on, there is an electrical link. If the LED blinks, there is currently network traffic at that speed. LED 10 Mbps 100 Mbps 1000 Mbps 100/ACT On or blinking On or blinking Off 1000/ACT On or blinking Off On or blinking Table 23.2 – Ethernet Port Monitor LEDs Installation Unlike many other Click devices, the Click 330 does not mount over the T-bus, meaning that power and communications will have to be wired in. Wiring Power and Communication The first four screw terminals, marked US1, GND, US2 and GND, are for wiring in power. The other two, which are labeled R1 and R2, are for security and functionality alarm purposes (see Figure 23.3). Figure 23.3 – Wiring the Click 330 Follow the steps below to install and wire a Click 330: 1 2 Attach the device to a location on the DIN rail that is not over a T-bus. Attach a wire for +DC (red is standard) to the screw terminal marked US1. 197 198 CHAPTER 23  •  CLICK 330 3 4 5 6 7 Attach a wire for -DC (black is standard) to the screw terminal marked GND. Attach the other end of these two wires to a DC power source. Optional: repeat steps 2–4 with the second set of screw terminals to wire in a redundant power supply. Optional: wire into the screw terminals marked R1 and R2 for an alarm. Make sure the DIN rail is properly grounded (see Figure 23.4). The switch can be grounded via an eyelet ring on the top of the device. Figure 23.4 – Grounding the Click 330 8 Plug the Ethernet cables into any Ethernet port on the Click 330. Switching Characteristics Store and Forward All data telegrams that are received by the switch are saved and their validity checked. Invalid or faulty data packets (> 1522 bytes or CRC errors) and fragments (< 64 bytes) are rejected. Valid data telegrams are forwarded by the switch. The switch always forwards the data using the data transmission speed that is used in the destination network segment. Multi-address Function The switch independently learns the addresses for termination devices, which are connected via a port, by evaluating the source addresses in the data telegrams. Only packets with unknown addresses, with a source address of this port or with a multicast/broadcast address in the destination address field are forwarded via the corresponding port. The switch can store addresses in its address table with an aging time of five minutes. This is important when more than one termination device is connected to one or more ports. In this way, several independent subnetworks can be connected to one switch. Quality of Service (QoS): IEEE 802.1P/Q The SFN switches are capable of reading Ethernet packets that have already been assignent a priority level by a managed switch or other. In cases of heavy traffic, packets with a priority 4–7 are considered high priority and processed before packets with 0–3 priority level. After prioritization the packets are forwarded without modification. 24 Click 400 — 900 MHz Radio In this chapter ˽˽ Physical Features ˽˽ On-device Configuration ˽˽ Computer Configuration 24 The Click 400 is a 900 MHz spread spectrum radio with two RS-485 ports and one RS-232 port which are active at all times. The unit also auto-detects the serial settings of a SmartSensor network for quick and easy installation. Supporting baud rates of 9600 bps to 115.2 Kbps, all Click 400 units can have different serial baud rates and still communicate perfectly. Figure 24.1 – The Click 400 200 CHAPTER 24  •  CLICK 400 Physical Features The Click 400 has several communication ports, as well as features for configuration. Figure 24.2 – Diagram of the Click 400 Communication Ports The back of the Click 400 features a 5-position connector that plugs into a T-bus connector and provides power and RS-485 communication to the device. It also passes RS-485 communication from the Click 400 to all other devices on the T-bus. The top of the device has a pluggable screw terminal block that features four terminals—one -485, one +485 and two grounds—for wiring RS-485 communication. This screw terminal block can be removed for easy preinstallation wiring. It will not be necessary, however, to wire RS-485 through the screw terminal block if the device is connected to a T-bus with uninterrupted RS-485 communication. The front of the device has a DB-9 connector for RS-232 communication. Connect a straightthrough cable from this port to a computer to configure the device using Click Supervisor. Any data on one port will be transmitted simultaneously on all other ports. Antenna The Click 400 has a reversed polarity SMA antenna connector. An external antenna can be mounted on the exterior of the traffic cabinet or up on a pole for maximum range. A whip antenna can also be used inside the cabinet. If the antenna is installed inside a metal cabinet, the range will be diminished. CHAPTER 24  •  CLICK 400 Configuration Features The faceplate of the Click 400 has the following four LEDs: ˽˽ PWR (red) lights up when the device has power. ˽˽ Wireless Link (blue) lights up when the device is set to be a client and can see a server. If the device is set up to be a server, this LED will blink. ˽˽ TD (green) lights up when the device is transmitting data. ˽˽ RD (yellow) lights up when the device is receiving data. The LEDs are also used to indicate operation modes, which will be discussed later in the On-device Configuration section of this chapter. The front also has a push-button labeled Mode Switch, which is used to cycle the Click 400 through operation modes. This will be discussed in the On-device Configuration section of this chapter. On-device Configuration The Click 400 can be configured using the push-button on the lower part of the faceplate. Press and hold the push-button to cycle through the different operation modes; release the button when the desired mode is reached. A quick press and release of the push-button will exit out of any mode and return the unit back to normal operation. Table 24.1 and the following sections describe the different operating modes. Mode LED Definition Autobaud Green (solid) To autobaud the Click 400, press the push-button, then release when the green LED turns on. The Click 400 is autobauding when the green LED is on and the red LED is blinking. When it is finished autobauding, the red LED will turn on. If you autobaud a Click 400, the device will always be set up as a client. Link Test (Client) Blue (solid) To set the Click 400 in Link Test mode as a client, press the push-button, then release when the blue LED turns on. If the yellow LED is blinking, then the module is receiving data out of sequence (missing some data). If the green LED is blinking, then the module is receiving all data in order. Link Test (Server) Blue (flashing) To set the Click 400 in Link Test mode as a server, press the push-button, then release when the blue LED is blinking. The Click 400 is transmitting data if the red and blue LED stay on and the green LED blinks. Reset To reset the Click 400 to factory defaults, press the push-button, then release when the red LED is blinking. Red (flashing) Table 24.1 – Click 400 Operation Mode Definitions 201 202 CHAPTER 24  •  CLICK 400 Autobaud (solid green) The Autobaud mode is used to match baud rates with an external device. By default, the device will attempt to match baud rates with a SmartSensor on the bus; however, the device can be configured to autobaud with any device that supports a serial interface. During the autobaud process, the green LED will stay on and the red LED will flash after every autobaud cycle (the cycle time increases as latency is added after each cycle). If the autobaud was successful, the radio will be set up as a client and the green LED will turn off and the yellow LED will start to flash as data arrives over the bus; if the autobaud was not successful, the green LED will turn off and the yellow LED will be solid. Link Test in Server (flashing blue) and Client (solid blue) Modes The Link Test modes are used to test the wireless link between two Click 400 modules. Follow the steps below to perform a link test: 1 2 3 4 5 6 Set one of the devices in Link Test mode as a server by pressing the push-button, then releasing when the blue LED begins flashing. A server in Link Test mode will have a solid blue and red LED and the green LED will begin flashing as it sends data for the test. Set the other device in Link Test mode as a client by pressing the push-buttonm then releasing when the blue LED turns on solid. The client device will have a solid red LED. Watch the client to be sure it has found a server: if the device finds a server on the same channel, the blue LED will be solid. If the blue LED does not turn on, then the client cannot find a server. Once you’re sure the client has found a server, watch the LEDs on the client to see the results of the link test. A blinking green LED means that the client is receiving valid link test data from the server; a flashing yellow LED means that the device is receiving invalid link test data; and a solid yellow LED means no data is being received. If the Click 400 is receiving invalid link test data, verify that the server is in link test mode. If this does not fix the problem, then check the line of sight and the antenna for possible problems. Once the test is complete, the devices must be taken out of link test mode in order to operate. Press and release the mode button on each device to get back to operational mode. Factory Reset (flashing red) The Factory Reset operation will erase all user-configured fields and the Click 400 may have to be reconfigured to work properly in its current application. If a device is not responding and not communicating, resetting the device may fix the problem. Once the device is responding, restore the configuration needed for its current application (i.e. loading a SmartSensor client driver or changing to the correct channel). To reset the Click 400 to factory defaults, release the push-button when the red LED begins CHAPTER 24  •  CLICK 400 flashing. The red LED should be solid and the green and yellow LEDs will flash. Wait for a few seconds and the device will now have the original factory configuration. Computer Configuration The Click 400 can be configured more exactly using the Click Supervisor software. See Chapters 4 and 5 of this document for instructions on how to download and install Click Supervisor and how to connect to your device using the software. The Click 400 can be configured using one of five drivers (see Figure 24.3). Figure 24.3 – Selecting a Driver Which driver you use will depend on what you need to use the device for. The first four drivers are known as application drivers and are used to set the Click device to work in specific applications. Use the list below to find the appropriate driver for your application: ˽˽ Client – If you intend to connect multiple clients to a single server, use the Client driver. ˽˽ Server – If you intend to connect a single radio to another single radio, use the Server driver. ˽˽ SmartSensor Client – If you intend to connect a wireless sensor station to a wireless base station, use the SmartSensor Client driver. ˽˽ SmartSensor Server – If you intend to connect a wireless base station to a wireless sensor station, use the SmartSensor Server driver. To see advanced settings, use the Expert driver. This driver, which exposes every available field for the Click 400, should only be used under the direction of Wavetronix Technical Services. After you have made configuration changes on a driver and saved it to the Click device, the word “current” will appear after that driver to indicate the driver that is currently loaded 203 204 CHAPTER 24  •  CLICK 400 onto the device. Note Some settings appear on multiple drivers. Changing one of those settings on any driver and saving them to the Click device will change that setting on all other drivers it appears on. The Backups option can be used to read configurations that have previously been saved to file. See Chapter 5 for more information. Application Drivers The four application drivers have essentially identical fields and settings, so the section that follows will use images of just one of those drivers as an example. Under the Setup tab, you can change the settings affecting the setup of the device and sensor (see Figure 24.4 and Table 24.2). Figure 24.4 – Setup Tab The following settings are common to all four application drivers. Setting Description Description Shows a description of the device being configured. This is only for your information and does not affect the operation of the device. Location Displays the location of the device being configured. This is only for your information and does not affect the operation of the device. CHAPTER 24  •  CLICK 400 Device ID Gives the ID number of the device being configured, which is used to identify the device when you are connecting to it. By default, this number is the last five digits of the serial number, which can be found under the About tab or on the barcode sticker on the bottom of the device. It is recommended that you do not change this number unless another device on your network has the same ID number. RF Channel Specifies the frequency channel of the device (the channels range from 0 to 47). Each client and server must be on the same channel. It is recommended that each system be on a different channel, since the ranges on these devices extend for miles and sharing the same channel with another location could result in interference. Tx Power (1W Max) Allows you to modify the power level in increments of 10%. The Click 400 transmit power can be reduced to decrease interference caused by multiple radios. Baud Rate Allows you to change the baud rate at which the device connects to the sensor. Table 24.2 – Setup Tab Under the About tab, you can view information about your Click 400 (see Figure 24.5 and Table 24.3). Figure 24.5 – About Tab The following settings are common to all four application drivers: Settings Description Driver Names the driver you are currently working with. Serial Number Displays the serial number of your device. 205 206 CHAPTER 24  •  CLICK 400 Firmware Version Shows the version of firmware your device currently has installed. If Click Supervisor detects a discrepancy between this version and the most current version it currently has access to, you will be prompted to upgrade when you connect to the device. MAC ID The MAC ID is the unique identifier of the MAC layer of the Click 400. Table 24.3 – About Tab Under the Diagnostics tab, you can run diagnostics on your device (see Figure 24.6). Click the General or 900 MHz buttons to run diagnostics on the items listed below each button. If a problem is detected, the program will display a red square next to the item in question. If no problems are detected, a green circle will appear. Figure 24.6 – Diagnostics Tab The RSSI display will show the relative RSSI strength of the radio, which is useful for detecting a low signal. If a low RSSI strength is shown, the user can boost the transmit power of the radio (if it isn’t already at 100%), check line of sight to determine if any obstacles are blocking the signal or check the gain on the antenna and replace the antenna if needed. Once you have finished, use the menu bar at the top of the screen to save your settings, return to the Select Driver screen, and more. ˽˽ The Save menu allows you to save your settings. Select Save to File to save your settings to a file. Selecting this will open a directory box, allowing you to name your settings file. This file will always be saved in the Wavetronix folder created when you installed Click Supervisor, under Wavetronix > ClickHome > Drivers > 400 > User. You can also select Save to Device to save your settings to your Click 400. CHAPTER 24  •  CLICK 400 Note If you do not save your settings to your Click 400, they will be lost the next time you power the device down. ˽˽ The Tools menu contains five options for working with your device. Reset > System power cycles your device, while Reset > Factory Default restores your device to the settings with which it was shipped. Restore will restore the driver to the settings currently saved on the Click 400, erasing any unsaved changes. Upgrade can be used to manually upgrade to the most current firmware for your device. Hex View changes the view of certain settings in the driver to hexadecimal. ˽˽ Clicking the Quit menu exits the driver and returns you to the Click Supervisor main page. Expert Driver The Expert driver allows you to see all possible settings and fields, both those available in other drivers and those available only through this driver. The driver is divided into three tabs—System, 900 MHz and Diagnostics—which are then subdivided further. The System > General tab combines elements of the Setup and About tabs from the other drivers (see Figure 24.7 and Table 24.4). Figure 24.7 – Expert Driver General Tab Setting Description Module Allows you to enter a name for the device. Driver Names the driver you are currently working with. 207 208 CHAPTER 24  •  CLICK 400 Description Shows a description of the device being configured. This is only for your information and does not affect the operation of the device. Location Displays the location of the device being configured. This is only for your information and does not affect the operation of the device. Serial Number Displays the serial number of your device. Firmware Version Shows the version of firmware your device currently has installed. If Click Supervisor detects a discrepancy between this version and the most current version it currently has access to, you will be prompted to upgrade when you connect to the device. Subnet ID Shows the subnet ID number. This option is currently not available. Device ID Gives the ID number of the device being configured, which is used to identify the device when you are connecting to it. By default, this number is the last five digits of the serial number, which can be found under the About tab or on the barcode sticker on the bottom of the device. It is recommended that you do not change this number unless another device on your network has the same ID number. Table 24.4 – Expert Driver General Tab The System > Comm tab allows you to configure how the Click device communicates (see Figure 24.8 and Table 24.5). Figure 24.8 – Expert Driver Comm Tab Setting Description Baud Rate Allows you to change the baud rate at which the device connects to the sensor. Flow Control Is used for configuring hardware handshaking. This option is currently not available. Parity Allows you to set parity error checking. Stop Bits Allows you to set the number of stop bits. CHAPTER 24  •  CLICK 400 Data Bits Shows you the number of data bits being sent. This option currently cannot be changed. Active Port Indicates on which port you are communicating with the sensor. This option cannot be changed. Latency Indicates the latency between the sensor and the Click device. This option cannot be changed. Table 24.5 – Expert Driver Comm Tab The System > Autobaud tab allows you to configure how the device autobauds (see Figure 24.9 and Table 24.6). Figure 24.9 – Expert Driver Autobaud Tab Setting Description Command Allows you to set the command sent from the device during the autobaud process. Don’t change these values unless instructed to by Wavetronix Technical Services. Response Shows the response the device is expecting from the above command. Don’t change these values unless instructed to by Wavetronix Technical Services. SmartSensor ID Shows the ID number of the sensor with which the Click device is currently communicating. This only shows the number after you have autobauded the Click device; when the Click device is not communicating with a sensor, this option will display a 0. Server/Client Allows you to set whether the device is a server or client in a point to multipoint setup. (This option is not related to device autobauding.) Table 24.6 – Expert Driver Autobaud Tab The 900 MHz > Config 1 tab allows you to change the RF channel and delivery settings (see Figure 24.10 and Table 24.7). 209 210 CHAPTER 24  •  CLICK 400 Figure 24.10 – Expert Driver Config 1 Tab Setting Description RF Channel Specifies the frequency channel of the device (the channels range from 0 to 47). Each client and server must be on the same channel. It is recommended that each system be on a different channel, since the ranges on these devices extend for miles and sharing the same channel with another location could result in interference. Tx Power (1W Max) Allows you to modify the power level in increments of 10%. The Click 400 transmit power can be reduced to decrease interference caused by multiple radios. Receive Mode Allows you to select which data packets will be received. If the device is set up as a client, select Address/Broadcast; if the device is set up as a server, select Address. RF Delivery Allows you to send to a specific address or broadcast to all radios. If the device is set up as a client, select Address; if the device is set up as a server, select Broadcast. Auto Destination Allows you to choose the destination for the data packets. If Destination ID is selected, the Dest. ID will need to be entered for the Click 400 you are communicating with; if Server ID is selected, the Click 400 will automatically communicate with the Server. Dest. ID Allows you to enter the MAC ID of the radio that the Click 400 you’re configuring should connect to. MAC ID The MAC ID is the unique identifier of the MAC layer of the Click 400. Table 24.7 – Expert Driver Config 1 Tab The 900 MHz > Config 2 tab contains channel synchronization settings (see Figure 24.11 and Table 24.8). CHAPTER 24  •  CLICK 400 Figure 24.11 – Expert Driver Config 2 Tab Setting Description CTS Asserted Reserved for hardware handshaking. This field is not editable. CTS Deasserted Reserved for hardware handshaking. This field is not editable. Sync to channel Allows you to synchronize channels with other servers. Sync Channel Allows you to choose the channel number to synch to. This number must be lower than the RF channel. DES Encryption Allows you to encrypt data going across radios. DES Key Must be the same on all radios you are using. Table 24.8 – Expert Driver Config 2 Tab The 900 MHz > Config 3 tab contains timeout settings (see Figure 24.12 and Table 24.9). Figure 24.12 – Expert Driver Config 3 Tab 211 212 CHAPTER 24  •  CLICK 400 Setting Description RF Packet Size Allows you to set the maximum size of an RF packet before it is sent. Interface Timeout Allows you to set the amount of time in milliseconds to wait until your buffer is full before sending. Transmit Retries Allows you to set the number of times the radio will transmit after not getting a response (Address mode). Broadcast Attempts Allows you to set a number of times the radio will broadcast after not getting a response (Broadcast mode). System ID Allows you to set a network password. Table 24.9 – Expert Driver Config 3 Tab Under the Diagnostics tab, you can run diagnostics on your device (see Figure 24.13). Click the General or 900 MHz buttons to run diagnostics on the items listed below each button. If a problem is detected, the program will display a red square next to the item in question. If no problems are detected, a green circle will appear. Figure 24.13 – Expert Driver Diagnostics Tab Once you have finished, use the menu bar at the top of the screen to save your settings, return to the Select Driver screen, and more. ˽˽ The Save menu allows you to save your settings. Select Save to File to save your settings to a file. Selecting this will open a directory box, allowing you to name your settings file. This file will always be saved in the Wavetronix folder created when you installed Click Supervisor, under Wavetronix > ClickHome > Drivers > 400 > User. You can also select Save to Device to save your settings to your Click 400. CHAPTER 24  •  CLICK 400 Note If you do not save your settings to your Click 400, they will be lost the next time you power the device down. ˽˽ The Tools menu contains five options for working with your device. Reset > System power cycles your device, while Reset > Factory Default restores your device to the settings with which it was shipped. Restore will restore the driver to the settings currently saved on the Click 400, erasing any unsaved changes. Upgrade can be used to manually upgrade to the most current firmware for your device. Hex View changes the view of certain settings in the driver to hexadecimal. ˽˽ Clicking the Quit menu exits the driver and returns you to the Click Supervisor main page. 213 Click 421 — Serial to Bluetooth® Radio 25 In this chapter ˽˽ Physical Features ˽˽ On-device Configuration ˽˽ Computer Configuration 25 The Click 421 serial to Bluetooth radio converts half-duplex two-wire RS-232 and 485 communication to Bluetooth and vice versa. Use this device in a cabinet to transfer data from a sensor to your computer via a wireless Bluetooth connection. Figure 25.1 – The Click 421 216 CHAPTER 25  •  CLICK 421 Physical Features The Click 421 has several communication ports, plus features for configuration. Figure 25.2 – Diagram of the Click 421 Communication Ports The back of the Click 421 features a 5-position connector that plugs into a T-bus connector and provides power and RS-485 communication to the device. It also passes that RS-485 communication to all other devices on the T-bus. The top of the device has two pluggable screw terminal blocks. The first block features -485, +485 and two ground screw terminals for wiring RS-485 communication. (It will not be necessary, however, to wire RS-485 through the screw terminal block if the device is connected to a T-bus with uninterrupted RS-485 communication.) The second block features RTS, CTS, TD and RD screw terminals for RS-232 communication. Both of these screw terminal blocks can be removed for easy preinstallation wiring. The front of the Click 421 features a DB-9 connector for RS-232 communication. A straightthrough cable can be used to connect from this port to a computer so that the device can be configured using Click Supervisor. Any data on one port will be transmitted simultaneously on all other ports. Antenna The Click 421 has a reversed polarity SMA antenna connector. An external antenna can be CHAPTER 25  •  CLICK 421 mounted on the exterior of the traffic cabinet or up on a pole for maximum range. A whip antenna can also be used inside the cabinet. If the antenna is installed inside a metal cabinet, the range will be diminished. Configuration Features The other three LEDs are activity indicators. ˽˽ PWR (red) lights up when the device has power. ˽˽ Bluetooth Link (blue) lights up when a link is successfully made over Bluetooth to an external device. ˽˽ TD (green) lights up when the device is transmitting data. ˽˽ RD (yellow) lights up when the device is receiving data. The LEDs are also used to indicate operation modes, which will be discussed later in the On-device Configuration section of this chapter. The front also has a push-button labeled Mode Switch, which is used to cycle the Click 421 through operation modes. This will be discussed later in the On-device Configuration section. On-device Configuration The Click 421 can be configured using the push-button on the lower part of the faceplate. Press and hold the push-button to cycle through the different operation modes; release the button when the desired mode is reached. A quick press and release of the push-button will exit out of any mode and return the unit back to normal operation. Table 25.1 and the following sections describe the different operating modes. Mode LED Definition Autobaud Green (solid) To autobaud the Click 421, press the push-button, then release when the green LED turns on. The Click 421 is autobauding when the green LED is on and the red LED is blinking. Link Test (Server) Blue (flashing) To set the Click 421 in Link Test mode as a server, press the push-button, then release when the blue LED is blinking. The Click 421 is transmitting data if the red LED comes on and the green LED blinks. Reset To reset the Click 421 to factory defaults, press the pushbutton, then release when the red LED is blinking. Red (flashing) Table 25.1 – Click 421 Operation Mode Definitions Autobaud (green solid) The Autobaud mode is used to match baud rates with an external device. By default, the module will attempt to match baud rates with a SmartSensor on the bus; however, the de- 217 218 CHAPTER 25  •  CLICK 421 vice can be configured to autobaud with any device that supports a serial interface. During the autobaud process, the green LED will stay on and the red LED will flash after every autobaud cycle (the cycle time increases as latency is added after each cycle). If the autobaud was successful, the red LED will turn off and the green and yellow LEDs will flash; if the autobaud is not successful after a few minutes of trying, the yellow LED will come on. Link Test in Server Mode (blue flashing) In Server mode, the Click 421 performs a link test, pushing a series of characters—the alphabet—to a connected Bluetooth device. Follow the steps below to perform a link test: Note Before you perform a link test, you must use your handheld computer, laptop or other external device to establish a connection with the Click 421. 1 2 3 4 Press the push-button on the faceplate of the device, then release when the blue LED blinks. While the link test is running, the red LED will glow solid and the green LED will blink. Watch the LEDs. The blue LED will come on to indicate that there is a connection to the external Bluetooth device you are connected to. If the connection is no longer valid, the blue LED will never come on and the device LEDs will remain in the state outlined in step 1. To check if the data being pushed to the laptop or handheld is good, open a terminal emulation program such as HyperTerminal and connect to the Bluetooth signal. Observe the data being received. It should be the alphabet repeated continuously; if nothing comes or any letters are missing, the data is not being received or is corrupted. To stop the link test and return the Click 421 to normal operation, press the pushbutton once. Factory Reset (red flashing) The Factory Reset operation will erase all user-configured fields, meaning that after the reset, the Click 421 may have to be reconfigured to work properly in its current application. If a device is not responding and not communicating, resetting the device may fix the problem. Once the device is responding, restore the configuration needed for its current application. To reset the Click 421 to factory defaults, release the push-button when the red LED begins flashing. The red LED should blink slowly, then the green and yellow LEDs will flicker. When the red LED glows solid, the module has the original factory configuration. CHAPTER 25  •  CLICK 421 Computer Configuration The Click 421 can be configured more exactly using the Click Supervisor software. See Chapters 4 and 5 of this document for instructions on how to download and install Click Supervisor and how to connect to your device using the software. The Click 421 can be configured using one of two drivers (see Figure 25.3). Figure 25.3 – Selecting a Driver If you intend to connect from your computer to the Click 421 to a sensor, use the SmartSensor driver. To see advanced settings, use the Expert driver. This driver, which exposes every available field for the Click 421, should only be used under the direction of Wavetronix Technical Services. After you have made configuration changes on a driver and saved it to the Click device, the word “current” will appear after that driver to indicate the driver that is currently loaded onto the device. Note Changing any of the settings on any driver and saving them to the Click device will change those settings on all drivers. The Backups option can be used to read configurations that have previously been saved to file. See Chapter 5 for more information. 219 220 CHAPTER 25  •  CLICK 421 SmartSensor Driver When you open the SmartSensor driver, you will see three tabs: Setup, About and Diagnostics. Under the Setup tab, you can change the settings affecting the setup of the Click device (see Figure 25.4 and Table 25.2). Figure 25.4 – SmartSensor Driver Setup Tab Setting Description Description Shows a description of the device being configured. This is only for your information and does not affect the operation of the device. Location Displays the location of the device being configured. This is only for your information and does not affect the operation of the device. Device ID Gives the ID number of the device being configured, which is used to identify the device when you are connecting to it. By default, this number is the last five digits of the serial number, which can be found under the About tab or on the barcode sticker on the bottom of the device. It is recommended that you do not change this number unless another device on the network has the same ID number. Baud Rate Allows you to change the baud rate at which the device connects to the sensor. Table 25.2 – SmartSensor Driver Setup Tab Under the About tab, you can view information about your Click 421 (see Figure 25.5 and Table 25.3). CHAPTER 25  •  CLICK 421 Figure 25.5 – SmartSensor Driver About Tab Setting Description Driver Names the driver you are currently working with. Serial Number Displays the serial number of your device. Firmware Version Shows the version of firmware your device currently has installed. If Click Supervisor detects a discrepancy between this version and the most current version it currently has access to, you will be prompted to upgrade when you connect to the device. Bluetooth Name Shows the name of the device, which is broadcast with the Bluetooth signal. This name can be changed in the Expert driver. Table 25.3 – SmartSensor Driver About Tab Under the Diagnostics tab, you can run diagnostics on your device (see Figure 25.6). Click the General or Bluetooth buttons to run diagnostics on the items listed below each button. If a problem is detected, the program will display a red square next to the item in question. If no problems are detected, a green circle will appear. 221 222 CHAPTER 25  •  CLICK 421 Figure 25.6 – SmartSensor Driver Diagnostics Tab Once you have finished, use the menu bar at the top of the screen to save your settings, return to the Select Driver screen, and more. ˽˽ The Save menu allows you to save your settings. Select Save to File to save your settings to a file. Selecting this will open a directory box, allowing you to name your settings file. This file will always be saved in the Wavetronix folder created when you installed Click Supervisor, under Wavetronix > ClickHome > Drivers > 421 > User. You can also select Save to Device to save your settings to your Click 421. Note If you do not save your settings to your Click 421, they will be lost the next time you power the device down. ˽˽ The Tools menu contains five options for working with your device. Reset > System power cycles your device, while Reset > Factory Default restores your device to the settings with which it was shipped. Restore will restore the driver to the settings currently saved on the Click 421, erasing any unsaved changes. Upgrade can be used to manually upgrade to the most current firmware for your device. Hex View changes the view of certain settings in the driver to hexadecimal. ˽˽ Clicking the Quit menu exits the driver and returns you to the Click Supervisor main page. Expert The Expert driver allows you to see all possible settings and fields, both those available in the SmartSensor driver and those available only through this driver. The driver is divided into three tabs, System, Bluetooth and Diagnostics. CHAPTER 25  •  CLICK 421 The System tab is divided into three subtabs: General, Comm, and Autobaud. The General subtab contains information about the device (see Figure 25.7 and Table 25.4). Figure 25.7 – Expert Driver General Tab Setting Description Module Shows the name of the Click device. Driver Names the driver you are currently working with. Description Shows a description of the device being configured. This is only for your information and does not affect the operation of the device. Location Displays the location of the device being configured. This is only for your information and does not affect the operation of the device. Serial Number Displays the serial number of your device. Firmware Version Shows the version of firmware your device currently has installed. If Click Supervisor detects a discrepancy between this version and the most current version it currently has access to, you will be prompted to upgrade when you connect to the device. Subnet ID Shows the subnet ID number. This option is currently not available. Device ID Gives the ID number of the device being configured, which is used to identify the device when you are connecting to it. By default, this number is the last five digits of the serial number, which can be found under the About tab or on the barcode sticker on the bottom of the device. It is recommended that you do not change this number unless another device on the network has the same ID number. Table 25.4 – Expert Driver General Tab The Comm subtab allows you to configure how the Click device communicates (see Figure 25.8 and Table 25.5). 223 224 CHAPTER 25  •  CLICK 421 Figure 25.8 – Expert Driver Comm Tab Setting Description Baud Rate Allows you to change the baud rate at which the device connects to the sensor. Flow Control Is used for configuring hardware handshaking. This option is currently not available. Parity Allows you to set parity error checking. Stop Bits Allows you to set the number of stop bits. Data Bits Shows you the number of data bits being sent. This option cannot be changed. Active Port Indicates on which port you are communicating with the sensor. This option cannot be changed. Latency Indicates the latency between the sensor and the Click device. This option cannot be changed. Table 25.5 – Expert Driver Comm Tab The Autobaud subtab allows you to configure how the device autobauds (see Figure 25.9 and Table 25.6). CHAPTER 25  •  CLICK 421 Figure 25.9 – Expert Driver Autobaud Tab Setting Description Command Allows you to set the command sent from the device during the autobaud process. Don’t change these values unless instructed to by Wavetronix Technical Services. Response Shows the response the device is expecting from the above command. Don’t change these values unless instructed to by Wavetronix Technical Services. SmartSensor ID Shows the ID number of the sensor with which the Click device is currently communicating. This only shows the number after you have autobauded the Click device; when the Click device is not communicating with a sensor, this option will display a 0. Server/Client Allows you to set whether the device is a server or client in a point to multipoint setup (this option is not related to device autobauding). This option is currently not available. Table 25.6 – Expert Driver Autobaud Tab The Bluetooth tab allows you to configure your device’s Bluetooth communications (see Figure 25.10 and Table 25.7). 225 226 CHAPTER 25  •  CLICK 421 Figure 25.10 – Expert Driver Bluetooth Tab Setting Description Bluetooth Name Allows you to change the name of your Bluetooth device, which is broadcast with the Bluetooth signal. Power Level Lets you change the power level of the Bluetooth signal; the options are 25%, 50%, 75% and 100%. Password Provides a field to enter the password to be used, if you have enabled the use of a password on the Bluetooth signal. Password Enable Enables the use of a password on the signal. Table 25.7 – Expert Driver Bluetooth Tab Note If you decide to password protect your Click 421, be sure to keep a good record of the password you choose. Wavetronix is not able to recover passwords or remove password protection from a device, so if the password is ever forgotten or lost, it will render the module unusable. Under the Diagnostics tab, you can run diagnostics on your device. Click the General or Bluetooth buttons to run diagnostics on the items listed below each button. If a problem is detected, the program will display a red square next to the item in question. If no problems are detected, a green circle will appear. CHAPTER 25  •  CLICK 421 Figure 25.11 – Expert Driver Diagnostics Tab Once you have finished, use the menu bar at the top of the screen to save your settings, return to the Select Driver screen, and more. ˽˽ The Save menu allows you to save your settings. Select Save to File to save your settings to a file. Selecting this will open a directory box, allowing you to name your settings file. This file will always be saved in the Wavetronix folder created when you installed Click Supervisor, under Wavetronix > ClickHome > Drivers > 421 > User. You can also select Save to Device to save your settings to your Click 421. Note If you do not save your settings to your Click 421, they will be lost the next time you power the device down. ˽˽ The Tools menu contains five options for working with your device. Reset > System power cycles your device, while Reset > Factory Default restores your device to the settings with which it was shipped. Restore will restore the driver to the settings currently saved on the Click 421, erasing any unsaved changes. Upgrade can be used to manually upgrade to the most current firmware for your device. Hex View changes the view of certain settings in the driver to hexadecimal. ˽˽ Clicking the Quit menu exits the driver and returns you to the Click Supervisor main page. 227 www.wavetronix.com