Navman GPS Receiver LA000578A User Manual

Jupiter 30  
20-channel GPS receiver  
module  
Development kit Guide  
(AA003029 series)  
Related products  
Jupiter 30 (standard) AA003025-G  
Related documents  
• Jupiter 30 Data sheet LA000576  
• Jupiter 30 Product brief LA000575  
• SiRF Binary Protocol reference manual  
MN000314  
• NMEA reference manual MN000315  
• SiRFDemo and SiRFflash user guide  
MN000316  
LA000578A © 2006 Navman New Zealand. All rights reserved. Proprietary information and specifications subject to change without notice.  
 
Figures  
Figure 2-1 Equipment supplied in the Jupiter 30 GPS Development Kit............................ 4  
Figure 3-1 Front and back panels of the Jupiter 30 development unit .............................. 5  
Figure 3-2 Configuration DIP switch .................................................................................. 7  
Figure 3-5 Internal layout of the development unit............................................................. 8  
Figure 3-3 Function LEDs on front panel ........................................................................... 9  
Figure 3-6 Jupiter 30 adapter board .................................................................................10  
Figure 3-4 Pin layout of the clock out connector...............................................................11  
Figure 4-1 Development unit test equipment.....................................................................15  
Tables  
Table 3-1 DIP switch settings............................................................................................. 7  
Table 3-2 Pin functions of the clock out connector ............................................................ 9  
Table 3-3 Mating connector part description.....................................................................11  
Table 3-4 Pin functionality.................................................................................................11  
Table 3-5 Signals available on the test points...................................................................12  
Table 3-6 Connections J1 (2 mm pitch header) and J2 (2.54 mm pitch header) ..............13  
 
1.0 Introduction  
This document provides detailed guidelines for the operation and configuration of the Jupiter  
30 GPS Module Development Kit. The AA003029 series of development kits assist in the  
integration of the Jupiter 30 in a customer’s application, offering a simple and easy to use  
platform for evaluation purposes.  
It is recommended that the user pays particular attention to the configuration settings outlined  
in section 3.0 prior to applying power and operating the development unit. For example, it is  
important to understand and recognise the main functional switches and connector locations  
accessible on the development unit’s front and rear panels. Following this information, simple  
step-by-step guidelines are presented to ensure successful setup of the development unit.  
In addition to hardware, the GPS Development Kit is supplied with SiRFDemo and SiRFflash  
analysis software to allow communication with the Jupiter 30 GPS receiver through a serial port.  
The Windows based software presents the receiver’s raw data in a geographical form, allowing  
both detailed analysis and evaluation for both NMEA and SiRF Binary formats.  
2.0 Equipment  
This section provides a brief overview of the equipment included in the Jupiter 30 GPS  
Development Kit.  
2.1 Equipment supplied  
This kit should contain the items illustrated in Figure 2-1.  
1. Jupiter 30 GPS development unit  
The Jupiter 30 GPS receiver development unit includes all of the following hardware to allow  
thorough evaluation:  
• Dual RS232 level serial data I/O ports  
• Selectable bias voltages for active GPS antennas  
• Backup power source for SRAM and RTC  
• Provision to insert a current measuring device to monitor both primary and backup power  
usage under various conditions  
• Regulated DC power supply to the Jupiter 30 module  
• Status indication through four LEDs on front panel  
• Configurable functionality using a DIP switch accessed through the front panel  
(2)  
(6)  
(1)  
DC Power  
9-16Volts  
Serial Port 1  
Serial Port 2  
-
+
Antenna  
DR  
Clock  
Out  
(4)  
(5)  
(3)  
software and documentation  
Figure 2-1 Equipment supplied in the Jupiter 30 GPS Development Kit  
Note: before supplying power to the development unit, please review the configuration settings and  
operation described in this document for optimum performance of the Jupiter 30 GPS receiver.  
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4
 
2. GPS antenna with pre-amp, magnetic base and SMA connector  
A magnetic-mount active antenna is supplied with the receiver development kit, along with an  
RF cable (RG-316) already terminated with the proper connector for the development unit. The  
nominal measured attenuation of the cable with connectors is approximately 5 dB. The supplied  
active antenna should be biased at +3 VDC, but a different active antenna with a bias of either  
+3, +5 or +12 VDC may be used. Refer to section 3.2 to ensure that the configuration switches  
on the front panel of the development unit are chosen to select the appropriate bias voltage.  
Caution: ensure antenna power switches are properly set before connecting the antenna. An  
antenna designed for +3 VDC operation will be damaged if connected to a +12 VDC  
source.  
3. Serial interface cable  
A serial cable is provided to interface between the development unit and the customer’s PC, or  
between the development unit and a DGPS receiver. This cable is terminated at both ends with  
female connectors to match the male connectors on the development unit and the PC. If the PC  
used only supports a USB port, an RS232/USB converter could be utilised.  
4. Power adapter for 240/120 VAC operation  
DC power for the development unit is provided by either an AC/DC converter or automobile  
adapter. The AC/DC converter operates from a nominal 120/240 VAC input and provides a  
12 VDC at 500 mA out.  
5. Power adapter for 12 VDC vehicle operation  
For mobile operation, an automotive adapter intended for use in 12 VDC vehicles is provided.  
'03 $EVELOPMENT 5NIT  
1
2
3
4
5
6
7
8
CTS  
206-8  
T114  
4)-% 0/7%2 $'03  
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function  
reset  
power  
configuration  
‘U’ slot for  
antenna  
SMA  
antenna  
DC Power  
9-16Volts  
Serial Port 1  
Serial Port 2  
-
+
Antenna  
DR  
Clock  
Out  
1PPS  
dead  
reckoning  
comm 1  
NMEA &  
comm 2  
(RTCM)  
DC input  
Figure 3-1 Front and back panels of the Jupiter 30 development unit  
(showing functional switches and connector locations)  
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5
 
6. Software and documentation CD  
The CD contains the Jupiter 30 GPS receiver data sheet, PC Analysis software (SiRFDemo and  
SiRFflash), and other information on how to use GPS receivers.  
2.2 Equipment required  
The following equipment is also required to evaluate the Jupiter 30 receiver.  
• IBM compatible PC  
• Minimum one serial port (If your PC only has USB, a USB/RS232 converter can be  
employed)  
• Windows 95/98, WinNT4.0 or higher  
• 486 100MHz or higher  
• SVGA at least 800x600 resolution  
• 16 Megabytes of RAM  
• 6 Megabytes (min) of disk space  
3.0 Technical configuration  
This section provides a detailed description of all the technical aspects and configurable  
functionality of the Jupiter 30 GPS development unit.  
3.1 Overview  
Figure 3-1 illustrates the connectors, switches and LEDs available on the development unit.  
3.1.1 Power switch (On/Off)  
The switch on the front panel controls primary power to the Jupiter 30 receiver module inside.  
The power status LED (see section 3.3) indicates the state of the unit: if lit, the module has  
primary power supplied. If the configuration DIP switch 5 is on and Jumper JB5/6 linked, the  
module’s secondary supply SRAM and RTC will continue to be powered when the power switch  
is off. Only the removal of the DC power input at the rear of the unit will stop secondary power  
being applied (assuming Jumper JB5/6 and switch 5 are correctly set). Having this secondary  
power supply applied means that the Jupiter 30 will have a ‘hot start’ capability when primary  
power is re-applied within 4 hours, and a ‘warm start’ thereafter, by maintaining last position,  
current time and satellite ephemerides.  
3.1.2 Configuration DIP switch  
The configuration DIP switch on the front panel provides the ability to configure the Jupiter  
30 module, offering flexibility depending on the specific application. Refer to section 3.2 for a  
description of the functionality of each individual switch, including the typical settings when using  
the Jupiter 30 module.  
3.1.3 Function LEDs  
The four LEDs on the front panel provide an indication of the current status of basic features  
associated with the development unit. Refer to section 3.3 for a complete description of the  
function of each LED.  
3.1.4 Reset switch  
A reset push button is provided on the front panel to generate a receiver system hardware reset.  
3.1.5 Clock out connector  
The Clock out connector, located on the rear panel of the development unit, can be used to  
provide module generated timing signals. Refer to section 3.4 for more detailed information.  
3.1.6 Serial port 1  
This host serial port is used to send and receive serial data. This port is used as the default, with  
transmission in NMEA format at the rate of 9600 Baud. The connectors to be used with these  
serial ports are 9-pin D-subminiature connectors.  
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3.1.7 Serial port 2  
This is the auxiliary serial port, and primarily used for the reception of RTCM SC-104 DGPS  
(Differential GPS) correction messages.  
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 development unit.  
3.1.10 DC power input  
The supplied DC power adapter is to be plugged into the DC connector on the rear panel of  
development unit. The development unit will accept voltages from 9 to 16 VDC. The middle pin  
on J1 is negative polarity, while the outer shell is positive.  
3.2 Configuration DIP switch  
A typical setting of the Configuration DIP switch is shown in Figure 3-2.  
1 2 3 4 5 6 7 8  
ON  
OFF  
Figure 3-2 Configuration DIP switch  
Table 3-1 outlines the available functionality and corresponding switch position for the  
Configuration DIP switch.  
Switch  
Description  
GPIO3/GYROIN*  
Typical setting  
OFF (high)  
1
2
3
4
5
6
7
8
GPIO15/FR*  
OFF (high)  
Serial BOOT  
OFF (normal run)  
OFF (high)  
GPIO1/W_TICKS*  
RTC BACKUP POWER  
PREAMP power select  
PREAMP power select  
PREAMP power enable  
ON (enabled)  
OFF (3 V)  
OFF (12 V)  
ON (enabled)  
* These functions have been disabled by internal switch  
SW3 to allow correct operation of the antenna current sense  
circuits on the Jupiter 30 adapter board.  
Table 3-1 DIP switch settings  
A brief description of the functionality of each switch is specified below. Refer to the Jupiter 30  
Data sheet for more information about the functionality of specific pads. The receiver  
operating settings will not change after moving the position of a configuration switch while the  
development unit is operating. Pressing the reset switch, or turning the unit off and on will enable  
the settings to take effect in the receiver. The recommended method for reconfiguration is to  
switch the unit off, modify the switch positions, then re-apply the power.  
3.2.1 DIP switch 1 – GPIO3 /GYROIN input  
DIP switch 1 interfaces with the GPIO3 /GYROIN 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  
internal switch SW3.1.  
3.2.2 DIP switch 2 – GPIO15 /FR input  
DIP switch 2 interfaces with the GPIO15 /FR 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 internal  
switch SW3.2.  
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3.2.3 DIP switch 3 – BOOT from serial mode  
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  
internal switch SW3.4.  
3.2.5 DIP switch 5 – RTC backup power enable  
DIP switch 5 provides control of the RTC backup power to the module. When set to the on  
position, the RTC backup power is applied to the module, allowing the RTC and SRAM to  
continue being powered when the primary source is removed. The jumper JB5/6 must also be  
in place for the backup power to be supplied. This power supply will be supplied to the module  
even with the main power switch in the off position.  
3.2.6 DIP switch 6 – Antenna preamp power select (3.3 V or 5/12 V)  
Dip switch 6 provides control of the antenna preamp voltage applied to the module. The switch  
position determines the supply voltage (off = 3.3 V, on = 5/12 V). Switch 6 should be left in the  
3.3V (off) position. The positions of switches 7 and 8 also need to be considered when using  
the preamp function.  
Note: the supplied antenna is a 3.3 V type.  
3.2.7 DIP switch 7 – Antenna preamp power select (5 V or 12 V)  
DIP switch 7 also controls the antenna preamp voltage applied to the module. If switch 6 is  
on, then switch 7 will determine the supply voltage to the active antenna (off = 12 V, on = 5 V).  
Switch 7 is not operational when switch 6 is in the 3.3V (off) position.  
3.2.8 DIP switch 8 – Antenna preamp power enable  
DIP switch 8 provides the ability to enable/disable the antenna preamp voltage to the module  
depending on the antenna being used. Typically this switch is on, enabling 3 V to be applied to  
the active antenna supplied with the kit.  
serial port 2  
serial port 1  
DR connector  
DC power  
timing connector  
JB10/11/12  
JB13/14/15  
voltage selection  
switch (3.3V or 5V)  
test points E1 to E9  
JB16/17  
JB1/2  
JB3/4  
SW3  
all off except SW3.3  
ON/OFF switch  
configuration DIP  
function LEDS  
JB5/6  
reset switch  
switch  
Figure 3-5 Internal layout of the development unit  
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8
 
3.3 Function LEDs  
There are four LEDs on the front panel of the development unit, indicating the status of a  
selection of basic functions. The functions of the LEDs are described in the sections that follow.  
1PPS  
Power  
AUX  
GPIO  
Figure 3-3 Function LEDs on front panel  
Note that some early versions of the evaluation unit have different LED legends.  
3.3.1 1PPS  
This LED will flash on with each transition of the 1 PPS (Pulse Per Second) output of the GPS  
receiver. The 1PPS LED will begin flashing when the receiver is tracking a satellite.  
3.3.2 Power  
This LED indicates presence of primary DC power to the module.  
3.3.3 AUX  
This LED shows activity on the auxiliary serial RS232 port (DGPS).  
3.3.4 GPIO  
This LED indicates the state of GPIO15 , which can be set via DIP switch 2. This LED is lit when  
switch 2 is set to on. (Note that switch 2 has no effect when using standard Jupiter 30 software.)  
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  
not used  
1
2
3
4
inverted 1PPS signal  
normal 1PPS signal  
ground  
Table 3-2 Pin functions of the clock out connector  
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9
 
J1  
J2 (not normally fitted)  
GPS fix LED  
RTC backup battery  
(not normally fitted)  
power LED  
Jupiter 30 module  
antenna  
Figure 3-6 Jupiter 30 adapter board  
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10  
 
4
3
2
1
Figure 3-4 Pin layout of the clock out connector  
A mating connector for the clock out connector is supplied with the development kit. The part  
number is shown in Table 3-3.  
Manufacturer  
Part number  
Molex  
70400 series ‘G’  
Table 3-3 Mating connector part description  
3.5 Internal configuration  
It should not be necessary to open the development unit unless accessing the internal test pins.  
Most combinations of I/O can be made from the front panel configuration switch. In the event  
that it is necessary to open the unit, Figure 3-5 illustrates the internal layout of the development  
unit board.  
As shown in Figure 3-5, there is a selection of links that can be configured to provide  
functionality depending on the application. Table 3-4 lists the functions available.  
Pins  
Function when linked  
Current link for 5 V supply. Can be used to  
determine current on 5 V rail. Not used for  
the Jupiter 30 module.  
JB1/2  
Current link for the primary power 3.3 V  
supply. Can be used to determine supply  
current for 3.3 V rail.  
JB3/4  
JB5/6  
Current link for the secondary power RTC  
supply. Can be used to determine supply  
current for RTC rail.  
JB10/11 5 V supplied to Pin 1 of the DR connector  
3.3 V supplied to Pin 1 of the DR  
connector  
JB11/12  
JB13/14 not used  
JB14/15 not used  
JB16/17 Internal interface enable (normally fitted)  
Table 3-4 Pin functionality  
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11  
 
In addition to the configurable jumpers, there is a selection of test points on the board. The  
signals available on the test points are shown in Table 3-5.  
Test point  
Function  
TXA  
E1  
E2  
E3  
E4  
E6  
E7  
E8  
E9  
RXA  
TXB  
RXB  
1PPS  
not used  
ground  
ground  
Table 3-5 Signals available on the test points  
There are some settings that should not be changed when using the standard Jupiter 30 module  
in conjunction with the development unit. These are as follows:  
• SW2 must remain selected on 3.3 VDC  
• Link for JB3/4 must be fitted  
• Link for JB16/17 must be fitted  
• SW3 DIP switch must be all off except SW3.3  
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12  
 
3.6 Jupiter 30 module on adapter board  
Figure 3-6 (on the following page) shows the adapter board with the positions of the connectors  
and indicators.  
Table 3-6 lists the pin configurations for the J1 and J2 connectors.  
Jupiter function  
J2 (2.54 mm  
J1 (2 mm  
pitch header) pitch header)  
pin no.  
pin no.  
V_ANT  
1
1
VCC_RF  
V_BATT  
VDD  
2
3
3
4
5
6
7
8
9
4
M_RST  
GPIO3/GYRO IN  
GPIO15/FR  
BOOT  
5
6
7
8
GPIO1/W TICKS  
RFON  
9
10  
GND  
10  
11  
12  
TXA  
11  
12  
13  
RXA  
GPIO4  
GND  
13  
14  
15  
TXB  
14  
15  
16  
17  
18  
RXB  
Wake-up  
GND  
16  
GPIO13  
GND  
17  
18  
19  
GND  
1PPS  
19  
20  
GPS_FIX/GPIO10  
Table 3-6 Connections J1 (2 mm pitch header) and J2 (2.54 mm pitch header)  
4.0 Operating instructions  
This section provides important information for the evaluation of the Jupiter 30 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.  
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 follow the installation process.  
Set up the hardware:  
1. Connect the DC power adapter to the power input J1.  
2. Connect the antenna cable to the SMA coaxial antenna connector on the rear panel of the  
Development unit.  
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13  
 
3. Connect the DB9 serial data cable between the PC serial communication port and the  
development unit’s Serial Port 1.  
4. Place the antenna in a site where a good view of the sky can be seen (refer to section 4.2 for  
more detail).  
5. Run the GPS analyser software on the PC. (Refer to section 4.4 for more details.)  
6. Connect the power supply to a suitable AC outlet.  
7. Turn the unit on using the power switch on the front panel to provide primary power to the  
Jupiter 30 receiver. Once power is applied, the Power LED should be lit.  
4.2 Positioning the GPS antenna  
The GPS antenna should be located with a clear view of the sky for optimal reception of the  
satellite signals. The 1PPS LED should begin flashing at 1 Hz once the receiver is powered  
and has started receiving at least one satellite. This provides an indication of whether or not the  
receiver is running.  
Note: GPS signals may be severely attenuated or totally obscured by roofs, solid walls, dense  
foliage, or even coated glass (found in many office structures and car windows). The  
development unit should be outside, or on the roof of a building to effectively evaluate  
receiver performance. With stationary developments, care should be taken to keep the  
antenna away from the side of a building as GPS signals can reflect off metal or coated  
glass. These reflections have a longer path than direct signals and can cause multi-path  
errors.  
4.3 Connecting an RTCM differential source  
For debugging purposes, it is suggested that users log both the GPS and RTCM data  
simultaneously. To allow the provision to do this, Navman can supply a software program called  
Labmon.  
The development unit, PC and the RTCM SC-104 differential correction source are connected  
as shown in Figure 4.1. If RTCM SC-104 data needs to be logged at the same time it is sent  
to the receiver, the OEM must supply a cable with three connectors to connect the RTCM  
correction source to the development unit’s auxiliary port and to an unused serial port on the  
PC. In this case, data is only logged when Labmon is invoked with file names as command line  
arguments (refer to the Labmon application note LA010103). Logging and subsequent review of  
the RTCM correction data often resolves performance or compatibility issues.  
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 unit may be connected to either the COM1, COM2, COM3, or COM4  
serial ports and the RTCM differential correction data source connected either directly to  
the receiver’s auxiliary I/O port, to one of the remaining serial ports of the PC, or to both  
using an OEM-supplied three-connector serial cable.  
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14  
 
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  
4.4 Operating the GPS Analyser software  
There are two software packages supplied with the GPS Development Kit: SiRFDemo and  
SiRFflash. The VisualGPS program can be obtained free of charge from the VisualGPS website  
4.4.1 VisualGPS  
VisualGPS graphically presents the serial data transmitted by the receiver. The receiver output  
must be enabled in the NMEA protocol for this software to be used.  
To enable the receiver output  
1. Open the VisualGPS software installed on the PC.  
2. Select the Settings>Communications tab.  
3. When the Communications Settings window is displayed, select the correct COM Port and set  
the Baud rate to 9600 Baud.  
When this has been carried out, and the development unit is powered, raw NMEA data should  
appear in the NMEA Monitor Window. For more detailed information on any of the analysis  
windows, use the Help function in the top toolbar.  
4.4.2 SiRFDemo  
SiRFDemo software can provide analysis of receiver output in either SiRF binary or NMEA  
protocols. When enabled in NMEA format, the only analysis provided is raw data being  
transmitted by the receiver. While the module is transmitting serial data in NMEA format, it is  
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15  
 
suggested that VisualGPS is used for analysis, rather than SiRFDemo.  
To provide graphical presentation of the data, the receiver can be set to output in SiRF binary  
format.  
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 information in each window, similar to that of VisualGPS. Whilst enabled in  
SiRF binary protocol, more of the analysis software’s functionality can be accessed. To switch  
back into NMEA mode, select the Action menu and click on Switch to NMEA Protocol. Select  
9600 for the baud rate and click on the Send button.  
Note: settings, including the current output protocol, are reset if all power is removed from the  
unit. For more information, refer to the Navman SiRFDemo and SiRFflash User Guide  
MN000316.  
5.0 Acronyms used in this document  
1PPS: One Pulse Per Second  
DGPS: Differential Global Positioning System  
GPIO: General Purpose Input Output  
GPS: Global Positioning System  
NMEA: National Marine Electronics Association  
RTC: Real Time Clock  
RTCM: Radio Technical Commission for Maritime services  
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16  
 
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© 2006 Navman New Zealand. All Rights Reserved.  
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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  
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information and shall have no responsibility whatsoever for conflicts or incompatibilities arising from future changes to  
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products, Navman assumes no liability whatsoever.  
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using or selling Navman products for use in such applications do so at their own risk and agree to fully indemnify  
Navman for any damages resulting from such improper use or sale. Product names or services listed in this publication  
are for identification purposes only, and may be trademarks of third parties. Third-party brands and names are the  
Reader Response: Navman strives to produce quality documentation and welcomes your feedback. Please send  
comments and suggestions to [email protected]. For technical questions, contact your local Navman sales  
office or field applications engineer.  
LA000578A © 2006 Navman New Zealand. All rights reserved. Proprietary information and specifications subject to change without notice.  
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