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Jupiter 20
GPS receiver module
Development kit guide
Applies only to older models:
TU10-D007-400
TU10-D007-401
TU10-D007-402
Related products
• Jupiter 20 (standard)
TU20-D411-001
• Jupiter 20 S (high sensitivity)
TU20-D411-101
• Jupiter 20 D (dead reckoning)
TU20-D421-201
Related documents
• Jupiter 20 Product brief LA000509
• Jupiter 20 Data sheet LA000507
• Jupiter 20 DR Application note LA000433
• Jupiter 30 / 20 Integrator’s manual LA000577
• SiRF Binary Protocol reference manual
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Contents 1.0 Introduction .......................................................................................................4 2.0 Equipment..........................................................................................................4 2.1 Equipment supplied ...................................................................................................... 4 2.2 Equipment required .................................................................................................
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Figures Figure 2-1 Equipment supplied in the Jupiter 20 GPS Development kit ............................. 4 Figure 3-1 Front and back panels of the Jupiter 20 development unit ............................... 6 Figure 3-2 Configuration DIP switch .................................................................................. 7 Figure 3-3 Function LEDs on front panel ........................................................................... 8 Figure 3-4 Pin layout of the clock out connector ..
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1.0 Introduction The TU10-D007-400 series of Development kits assist in the integration of either the standard or DR version of the Jupiter 20 into a customer’s application, offering an easy to use platform for evaluation purposes. This document provides detailed guidelines for the operation and configuration of the Jupiter 20 GPS reciever module Development kit. Note: before supplying power to the Development Unit, carefully review the configuration settings outlined in section 3.0. Also, f
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5. Power adapter for 12 VDC vehicle operation For mobile operation, an automotive adapter intended for use in 12 VDC vehicles is provided. 6. Software and documentation CD The CD contains Jupiter 20 GPS receiver documentation and other information on how to use GPS receivers. SiRFDemo and SiRFflash analysis software are also provided to allow communication with the Jupiter 20 GPS receiver through a serial port. This Windows based software presents the receiver’s raw data in a geographical for
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3.0 Technical configuration This section provides a detailed description of all the technical aspects and configurable functionality of the Jupiter 20 GPS Development Unit. 3.1 Overview Figure 3-1 illustrates the connectors, switches and LEDs available on the Development Unit. 1 2 3 4 5 6 7 8 CTS 206-8 T114 power switch function LEDs reset switch configuration switch ‘U’ slot for antenna SMA antenna cable (custom) connector DC Power 9-16Volts Serial
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3.1.7 Serial port 2 This is the auxiliary serial port, primarily used for the reception of RTCM SC-104 DGPS (Differential GPS) correction messages. 3.1.8 DR connector The DR connector is used to interface with a gyroscope, wheel tick pulses and forward/reverse indicator when using a Jupiter 20 DR module. Refer to section 3.5 for more information. 3.1.9 Antenna connector The antenna provided with this Development kit should be connected to the SMA connector located on the rear panel of the Dev
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DIP switch 3 interfaces with the BOOT pad of the module and allows the user to upgrade the Flash memory. For normal operation the switch should be set to OFF. To boot from the serial port the switch should be set to ON. This switch is enabled by the internal switch SW3.3. 3.2.4 DIP switch 4 – GPIO1/W_TICKS input DIP switch 4 interfaces to the GPIO1/W_TICKS pad of the module. The switch is typically OFF, but has no effect with the standard module’s software. This switch can be enabled by the
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3.4 Clock out connector The Clock out connector provides an interface for all associated timing signals with the module. It provides the user access to the Time Mark (1PPS) signal. The pinout connections are described in Table 3-2, and illustrated in Figure 3-4. Pin number Function 1 not used 2 inverted 1PPS signal 3 normal 1PPS signal 4 ground Table 3-2 Pin functions of the clock out connector 4 3 2 1 Figure 3-4 Pin layout of the clock out connector A mating connector for the clock out connec
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Pins Function when linked Current link for 5 V supply. Can be used to JB1/2 determine current on 5 V rail. Not used for the Jupiter 20 module. Current link for the primary power 3.3 V JB3/4 supply. Can be used to determine supply current for 3.3 V rail. Current link for the secondary power RTC JB5/6 supply. Can be used to determine supply current for RTC rail. JB10/11 5 V supplied to Pin 1 of the DR connector JB11/12 3.3 V supplied to Pin 1 of the DR connector JB13/14 not used JB14/15 not
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3.6 Jupiter 20 module on adapter board Figure 3-6 shows the adapter board with the positions of the connectors and indicators. power LED GPS fix LED Jupiter 20 module RTC backup battery J1 antenna (not normally fitted) J2 (not normally fitted) Figure 3-6 Jupiter 20 adapter board Table 3-6 lists the pin configurations for the J1 and J2 connectors. Jupiter function J2 (2.54 mm pitch header) J1 (2 mm pitch header) pin no. pin no. V_ANT 1 1 VCC_RF 2 V_BATT 3 3 VDD 4 4 M_RST 5 5 GPIO3/GYRO IN 6 6
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4.0 Operating instructions This section provides important information for the evaluation of the Jupiter 20 GPS module. Step-by-step instructions for connecting and operating the GPS development kit are included for first time setup. 4.1 Initial connection and operation The following steps describe how to connect and operate the GPS Development Kit. 4.1.1 Install the supplied SiRFdemo on your PC: 1. Insert the supplied CD into the CDROM drive 2. Double click on the SiRFDemo software icon and
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power antenna development unit optional antenna or pre-amplifier RTCM DGPS data source optional connection for logging RTCM data monitor PC Figure 4-1 Development Unit test equipment The Development Unit should be set up as shown in Figure 4-1 with only the RTCM correction source connected to the receiver. If the RTCM cable is not connected to the receiver’s auxiliary port, DGPS operation will not be possible. When RTCM data is being received the AUX LED will be lit. Note: the Development
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To set the receiver output to SiRF binary 1. Open the SiRFDemo software. 2. When the Data Source setup is displayed, select the appropriate COM port and 9600 Baud from the drop down menu. 3. Select the Action menu and click on Open Data Source. If the Development Unit is powered, and the serial port is connected to the PC, NMEA data should appear in the Debug View window. To change to SiRF binary, select the Action menu and click on the Switch to SiRF Protocol. This should now present infor
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The gyro should be mounted so that its sensitive axis is as near vertical as practical. Deviations from the vertical will reduce sensitivity for heading changes in the horizontal direction. Experiments have shown that acceptable performance can be achieved with mounting deviations of several degrees, but a better performance is achieved when the gyro is mounted closer to vertical. Characteristics Symbol Condition Minimum Standard Maximum Unit Supply voltage Vcc +4.5 +5.0 +5.5 VDC Max. angula
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® Windows is a trademark of Microsoft Corporation. © 2004 Navman NZ Ltd. All Rights Reserved. Information in this document is provided in connection with Navman NZ Ltd. (‘Navman’) products. These materials are provided by Navman as a service to its customers and may be used for informational purposes only. Navman assumes no responsibility for errors or omissions in these materials. Navman may make changes to specifications and product descriptions at any time, without notice. Navman makes no
