Tri-M SystemsメーカーFV-25の使用説明書/サービス説明書
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1 Tri-M Systems, Inc. Unit 100, 1407 Kebet way Port Coquitlam, BC V3C 6L3 Canada ww w.tri-m.com Phone: 604.945.9565 Fax: 604.945.9566 info @ tri-m. com FV – 25 USER’S GUIDE This docum ent features.
2 Contents Pr eface………………………………………………………… Chapter 1 Introduction……………………………………….. 1.1 Supports……………………………………………………….. Chapter 2 S tart……………………………………………….
3 4.5 Navigation Data……………………………………………………. 4.5.1 Position Format……………………………………………… 4.5.2 Datums………………………………………………………. 4.5.3 Update Rate………………………………………………….
4 List of Figur es Figure 2.1 FV -25 Pin definitions (T op V iew)………………………………….. Figure 2.2 A reference layout for FV -25……………………………………….. Figure 2.3 Setting of comm. port num ber and the value of baud rate………….
5 List of T a bles T able 1.1 Specification of FV -25…………………………………………….. T able 2.1 Description of pin definition for FV -25…………………………… T able 4.1 Conditions for S tart-Up modes…………………………………….
6 Pr eface The objective of The FV -25 User ’ s Guide is to help user s to understand the properties of FV -25 thoroughly and, therefore, obtai n the maximum performance from the module easily .
7 Chapter 7 A vailable NMEA and UBX 1 Messages This chapter lists the available NMEA and u-blox proprietary (UBX) messages for the module. Chapter 8 T roubleshooting This chapter provides good helps when the module isn’ t running properly .
8 Chapter 1 Introduction In this chapter , the m ain goal of FV -25 will be described and then the features of the FV -25 module will be specified in order th at a user can make correct decis ion about module selection before proceeding furthe r development.
9 sensitivity for weak signals without sacrificing accuracy , AGPS function, DGPS function which is supporte d by R TCM, W AAS, and EGNO S, and flexibility for system integrations. Because of 8192 frequency search bins at the same time, it accelerates the start-up times of the module.
10 Specification Performance Characteristics Receiver T ype L1 frequency , C/A code, 16 Channels P o s i t i o n A c c u r a c y w / o a i d 3 . 3 m C E P D G P S (W AAS, EGNOS,RTCM) 2 .
11 D i m e n s i o n 3 7 . 1 m m x 2 5 . 6 m m Thickness 3.9 mm W e i g h t 9 . 5 g (include an SMA jack and 5 cm RG-316) Antenna T ype External Active or Passive Antenna Input V oltage (V ANT ) 1 .
12 Chapter 2 S tart 2.1 Pin Definitions and Reference Layout Figure 2.1 shows the pin definitions of FV -25. T able 2.1 describes the corresponding definitions for pins. Note tha t only either use V IN-1 (DC 5 ~ 12V) or V IN-2 (DC 3.3V) for voltage input.
13 Pin Definitions Pin No. Tit l e I/O Note a V IN-1 I V oltage input 5~12V DC (MUST leave open if V IN-2 is used) b V ANT I Antenna bias voltage input DC 1.8~ 8.0V (connect to ground if not used) c V IN-2 I V oltage input 3.3V DC (MUST leave open if V IN-1 is used) d V BAK I Backup voltage input 1.
14 2.2 Sanav_Demo Sanav_Demo is required to run on a PC with at least 4 MB RAM and W indows 98 that has at least one available serial comm. port (from 1 to 24). 2.2.1 Port Number & Baud Rate When users implement Sanav_Demo , the first window appeared on the screen is the setting of comm.
15 Figure 2.4 Setting of com m. port number . For setting the value of baud rate, pull th e scroll-down window for the “Baud rate” item and the desired window shows that the available range of ba ud rate is from 2400 bps to 1 15200 bps, as shown in Figure 2.
16 subsequent window will be th e one shown in Figure 2.6, i.e ., the navigation data from the module are displayed in the corresponding sub-windows. If the setting values are not correct or the connecti on hasn’ t established yet, Sanav_Demo will prompt a warning sentence “Comm port couldn’ t be open, please check the device”.
17 Figure 2.7 Co n stellation Map of GPS satellites. 2.2.4 Message V iew for NMEA Messages Figure 2.8 is the window for showing the desired (user -selected) output NMEA messages. There are two ways to show the “Message V iew” window . Click the item “W indows/T erminal V iew” or the shortcut button ?.
18 accumulatively with in the sub-window until the sub-window is filled up, i.e., the “Message V iew” window contains NMEA mess ages from several epochs, as shown in Figure 2.9, and the oldest data will be “squeezed” out in the top of the sub-window while the new data will be displayed in the bottom of the sub-window .
19 Figure 2.10 A vailable NMEA messages. NOTE: The output NMEA messages will be discar ded or not transmitted if the values of the baud rate is not sufficient to transmit the desir ed messages. Also, the discar ded part won’ t be output in the next epoch.
20 Figure 2.11 GPS satellite information. 2.2.7 Receiver Information Figure 2.12 describes the receiver information. They are: UTC Date : day/month/year; UTC Time : hour:minute:second; Lat : latitude xxyy .yyyy xx: degree, yy .yyyy: minute, -: southern hemisphere; Lon : longitude xxxyy .
21 Figure 2.12 Receiver Information. NOTE: Data displayed in the sub-windows (F igur es 2.7, 2.9, 2.1 1, and 2.12) depend on the user-selected output NMEA messages, i.e., if, for example, the module doesn’ t output GSV message, the associated information, such as eleva tion, azimuth, SNR, etc.
22 Figure 2.13 Tracki ng V iew . 2.2.9 User Setting Clicking “W indows/User Setting” or the shortcut button ?, the “User Setting” window is activated, as shown in Figure 2.14. Click “ ” to move among the tags. 2.2.9.1 Position This function sets the initial latitude and long itude, as shown in Figure 2.
23 The output position will be updated as the position is fixed. 2.2.9.2 T ime and day This function sets the initial UTC date and time, as show n in Figure 2.15. The format for UTC date is “YYYY (year), MM (mont h), DD (day)” and the format for UTC time is “hh (hour), mm (m inute), ss (second)” .
24 Figure 2.16 Local tim e zone. 2.2.9.4 Restart This function sets the initial s tart-up mode, such as cold-start, warm -start, and hot-start, for the module, as shown in Figure 2.
25 2.2.9.5 DGPS This function activates the di f ferential GPS functions of the module, such as R TCM and W AAS/EGNOS, or only GPS function w ithout aids, as shown in Figure 2.18. Figure 2.18 DGPS. 2.2.9.6 Interval Referred to Section 2.2.5. 2.2.9.7 Geodetic ID This function sets coordinate datum that users prefer , as shown in Figure 2.
26 Chapter 3 Alternative S tart This chapter introduces an alternative ut ility , HyperT erminal (from W indows), to display the NMEA information. And, Using the utility , users can send a request to poll the desired NMEA information or implement other configurations from the module without the aid of Sanav_Demo .
27 the mode of connection. Figure 3.2 Connection setti ngs. After setting all th e necessary data, click the connection button, which is the fifth shortcut button from r ight . If the setting is correct, the HyperT erminal window will show desired output (NMEA messages), as shown in Figure 3.
28 will ask users to input the file name and folder . 3.3 Setting Configuration or Polling Information fr om Module For setting or polling the desired inform ation, click “T ransfer/Send T ext File…” button to send a “.txt” file, which contains command sentences, to activ ate the module.
29 Chapter 4 Navigation 4.1 Operating Modes 4.1.1 Continuous T racking Mode (CTM) CTM is the default setting of the module. While the CTM is on, the module tracks GPS signals and estimates position continuously , i.e., satellite acquisition, reacquisition, and tracking are th e states in the CTM.
30 Conditions Modes T ime Position Almanac Ephemeris Cold S tart None None None None Wa r m S t a r t Ye s Ye s Ye s N o n e H o t S t a r t Ye s Ye s Ye s Ye s T able 4.1 Conditions for S tart-Up modes. For the cold-start mode, the module assigns all the available SVs to 16 channels in a defaulted order .
31 will improve on TTFF depends on the accu racy of position and tim e from a near base station (service center) as well as hardware synchronization. The AGPS function of the module is activat ed by sending u-blox binary protocol UBX-AID-REQ. If there is no data availabl e from a near base station, the module is back to its normal start-up modes.
32 dB is used, the “High Sensitivity” mode is not r ecommended. 4.5 Navigation Data 4.5.1 Position Format The navigation data can be output in the format of local geodetic frame (latitude, longitude, and altitude), ECEF (Earth-Cen tered Earth-Fixed) frame, or Universal T ransverse Mercator (UTM) frame.
33 initial/assumed value of the altitude is 500 m. If the 2D position fix occurs after the 3D position fix (number of observable satellites drops from at least 4 to 3), the value of the altitude will keep the last k nown va lue of the altitude from the previous 3D position fix.
34 R TCM protocol, please refer to the web site http://www .rtcm.or g/ . The DGPS parameters can be changed in the UBX-CFG-NA V m essage, like DGPS T imetag Rounding. Do not change them under no specific reasons becau se the default values are based on real tests with DGPS function.
35 Chapter 5 Evaluation Kit The evaluation kit is an optional accessory while purchasing the m odule. It will provide an easy way to estimate the perfor mance of our module. The users can also follow the reference circuit design in Chapter 2 to test the performance of the module.
36 re-start up the GPS module in the either Continuous T racking Mode or FixNow mode. Figure 5.2 Front panel of the evaluati on kit. Figure 5.3 shows the back panel of the evaluati on kit. It includes (f rom left to right) the Antenna Input, Comm. Port 1, 1PPS Out put, and Power Input.
37 Both Comm. ports are the bi-directional ports, i.e., the ports also accep ts user software commands. For receiving R TCM message, either port can be used to accept the data through software command.
38 Chapter 6 Antennas T o get the maximum performance from the module, in addition to the own properties of the module, one of the important factors is how to select fitted antennas for the module bec.
39 For using passive antennas, the pin V ANT (DC bias voltage) on the module is connected to ground, and the antenna is direct ly connected to the GPS signal input pin ANT . Sometimes, a passive matching connecti on is required to match the elec trical circuit to 50 Ohms impedance.
40 6.3 Active Antenna Supervisor - Short Circuit Pr otection This is a built-in function that is mon itored by the BaseBand processor . If an abnormal current occurs and is detected, the voltage supply at pin V ANT (from the external or internal pow er supply) will be turned of f by the BaseBand processor .
41 Chapter 7 A vailable NMEA and UBX Messages 7.1 NMEA Protocol The NMEA protocol expresses the data in th e format of ASCII. This is a standard format for GPS applications.
42 the “PDOP Accuracy Mask”..
43 GGA – GPS Fix Data Position fix related data, such as position, time, number of satellites in use, etc.. $GPGGA,gga1,gga2,gga3,gga4,gga5,gga6,gga7,gga8,gga9,gga10,gga1 1,gga12,gga 13,gga14*hh<CR><LF> Parameters Descriptions Notes gga1 UTC time as position is fixed hhmmss.
44 GLL – Geographic Position – Latitude/Longitude Navigation data and status. $GPGLL,gll1,gll2,gll3,gll4,gll5,gll6,gll7*hh<CR><LF> Parameters Descriptions Notes gll1 Latitude ddmm.mmmmm: dd – degree; mm.mmmmm – mi nut e ( 0 o ~ 90 o ) gll2 Latitude sector N – North; S – South gll3 Longitude dddmm.
45 GRS – GNSS Range Residual This message is used to monitor and support RAIM. $GPGRS,grs1,grs2,(grs3*12)*hh<CR><LF> Parameters Descriptions Notes grs1 UTC time from the GGA hhmmss.ss: hh – hour; mm – minute; ss.ss – second grs2 Mode to indicate the way to calc ulate the range residuals.
46 GSA – GNSS DOP and Active Satellites Receiver operating mode, the valu es of DOPs , and PRN numbers for satellites used in the GGA position solution.
47 GST – GNSS Pseudorange Error S tatistics This message is used to monitor and support RAIM. $GPGST ,gst1,gst2,gst3,gst4,gst 5,gst6,gst7,gst8*hh<CR><LF> Parameters Descriptions Notes gst1 UTC time from the GGA hhmmss.ss: hh – hour; mm – minute; ss.
48 GSV – GNSS Satellites in V i ew This message indicates the observable satel lites’ information, such as PRN num bers, elevation, azimuth, SNR, and number of satellites in view .
49 RMC – Recommended Minimum Specific GNSS Data This message transmits the neces sary navigation data, such as time, position, speed, course, and so on. $GPRMC,rmc1,rmc2,rmc3,rmc4,rmc5,r mc6,rmc7,rmc8,rmc9,rmc10,rmc1 1,rmc 12*hh<CR><LF> Parameters Descriptions Notes rmc1 UTC tim e as position is fixed hhmmss.
50 TXT – T ext T ransmission The message is used to transm it short text messages. T r ansmitting a longer m essage needs multi-TXT messages. $GPTXT ,txt1,txt2,txt3,txt4*hh<CR><LF> Param.
51 VTG – Course Over Gr ound and Gr ound Speed This message transmits the speed and course relative to ground. $GPVTG ,vtg1,vtg2,vtg3,vtg4,vtg5,vtg6,vtg7,vtg8,vtg9*hh<CR><LF> Parameters Descriptions Notes vtg1 Course over ground (degrees) Referenced to true north (000.
52 ZDA – Time & Date This message transmits UTC tim e and date, and local time zone. $GPZDA,zd a1,z da2,zda3,zda4,zda5,z da6*hh<CR><LF> Parameters Descriptions Notes zda1 UTC time hhmmss.
53 7.1.2 Pr oprietary NMEA Messages The non-standard NMEA messages is proposed by u-blox. The proprietary (non-standard) NMEA messages are grouped into two categories: Proprietary NMEA (PUBX) PUBX,00 .
54 PUBX, 00 – Latitude/Longitude Position Data Output message. This message transmits na vigation data defined in the local geodetic frame. $PUBX,00,p00x1,p00x2,p00x3,p00x4,p00x5,p00x6,p00x7,p00x8,p.
55 the position calculation p00x18 Number of GLONASS satellites used in the position calculation Always 0 p00x19 Dead reckoning used 0 – No; 1 – Y es hh Checksum hex number (2 – character) <C.
56 PUBX, 01 – UTM Position Data Output message. This message transm its na vigation data defined in the Universal T ransverse Mercator (UTM) frame. $PUBX,01,p01x1,p01x2,p01x3,p01x4,p01x5,p01x6,p01x7.
57 used in the position calculation p01x19 Dead reckoning used 0 – No; 1 – Y es hh Checksum hex number (2 – character) <CR><LF> End of message.
58 PUBX,03 – Satellite S tatus Output message. $PUBX,03,p03x1,((p03x2,p03x3,p03x4,p03x5,p03x6,p03x7)*n)*hh<CR><LF> Parameters Descriptions Notes p03x1 Number of GPS satellites tracked p0.
59 PUBX,04 – T ime of Day and Clock Information Output message. This message transmits UTC time, week num ber , and clock of fset. $PUBX,04,p04x1,p04x2,p04x3,p04x4,p04x5,p04x6,p04x7,p04x8*hh<CR><LF> Parameters Descriptions Notes p04x1 UTC time hhmmss.
60 GPQ – Poll Message Input message. Poll a standard NMEA message. $xxGPQ,gpq1*hh<CR><LF> Parameters Descriptions Notes $xxGPQ NMEA message header xx: talker device identifier gpq1 NMEA .
61 PUBX – Poll a PUBX Message Input message. Poll the proprietary PUBX messages. $PUBX,p1*hh<CR><LF> Parameters Descriptions Notes p1 Proprietary message ids xx: 00, 01, 03, and 04 hh Ch.
62 PUBX,40 – Set NMEA Message Output Rate Input message. $PUBX,40,p40x1,p40x2,p40x3,p40x4,p40x5*hh<CR><LF> Parameters Descriptions Notes p40x1 NMEA message ids String format: GGA, GLL, G.
63 PUBX,41 – Set Protocols and Baudrate Input message. $PUBX,41,p41x1,p41x2,p41x3,p41x4,p41x5*hh<CR><LF> Parameters Descriptions Notes p41x1 USAR T id 0, 1, 0r 2 p41x1 Input protocol mas.
64 7.2 UBX Binary Protocol T o obtain the maximum performance from GPS chips, which mainly consists of FV -25, u-blox proposed a proprietary binary pr otocol. The binary protocol can set and poll all the available actions and messa ges from the module.
65 For the calculation of the checksum, u- blox utilizes the low-overhead checksum algorithm, which is the TCP standard (R FC 1 145). The calculation of the checksum covers the range from the CLASS ID byte (inc luded) to DA T A bytes (included).
66 R8 IEEE754 Double Precision 8 -1*2 1023 ~ 2 1023 ~V alue*2 -53 CH ASCII / ISO 8859.1 Encoding 1 T able 7.1 The types of dat a. 7.2.2 Classification of UBX Messages The u-blox proprietary message s are classified into 9 gr oups. Based on a specific topic, each group contains the associated information.
67 7.2.4 UBX Messages UBX Class ACK This class is used for responding a CFG message. ACK – ACK (0x05 0x01) Message acknowledged. Header ID Data Length Data Checksum 0xB5 0x62 0x05 0x01 2 See bel ow .
68 ACK – NAK (0x05 0x00) Message not-acknowledged. Header ID Data Length Data Checksum 0xB5 0x62 0x05 0x00 2 See bel ow CK_A CK_B Data Offset bytes Format Descriptions Notes 0 U1 Class ID for the de.
69 UBX Class AID This class is used to support AGPS function or send aiding data, su ch as time, position, almanac, and ephemeris, to the GPS receiver . AID – REQ (0x0B 0x00) It’ s a virtual request to poll all GPS ai ding data (AID-DA T A). The character of AID-REQ is determined by CFG-MSG .
70 AID – DA T A (0x0B 0x10) It’ s a request to poll all the GPS initial aiding data. This message will activate th e sending of AID-INI, AID-HUI , AID-EPH, and AID-ALM as it is received by the module.
71 AID – INI (0x0B 0x01) It’ s a poll request when “data length” is equal to 0. Poll GPS initial aiding data. Header ID Data Length Data Checksum 0xB5 0x62 0x0B 0x01 0 None C K_A CK_B AID – INI (0x0B 0x01) This is an I/O message. It contains the in formation of position and tim e.
72 AID – HUI (0x0B 0x02) It’ s a poll request when “data length” is equal to 0. Poll GPS health, UTC, and Ionosphere data. Header ID Data Length Data Checksum 0xB5 0x62 0x0B 0x02 0 None C K_A CK_B AID – HUI (0x0B 0x02) It’ s an I/O message.
73 48 R4 Alpha3 Klobuchar parameters 52 R4 Beta0 Klobuchar parameters 56 R4 Beta1 Klobuchar parameters 60 R4 Beta2 Klobuchar parameters 64 R4 Beta3 Klobuchar parameters 68 U4 Flag3 0x1 – valid healt.
74 AID – ALM (0x0B 0x30) It’ s a poll request when “data length” is equal to 0. Poll all available aiding alm anac data. Header ID Data Length Data Checksum 0xB5 0x62 0x0B 0x30 0 None C K_A CK_B AID – ALM (0x0B 0x30) It’ s also a poll request.
75 28 U4 Almanac – WORD5 32 U4 Almanac – WORD6 36 U4 Almanac – WORD7 NOTE: 1. WORD0 ~ WORD7 contain the dat a following the Hand-Over W or d (HOW) in the navigation message. The data ar e fr om the sub-frame 4 of Pages 1 ~ 24 and the sub-frame 5 of Pages 2 ~ 10.
76 AID – EPH (0x0B 0x31) It’ s a poll request when “data length” is eq ual to 0. Poll all available aiding ephemeris data. Header ID Data Length Data Checksum 0xB5 0x62 0x0B 0x31 0 None C K_A CK_B AID – EPH (0x0B 0x31) It’ s also a poll request.
77 32+n*96 U4 Sub-frame 1 – WORD6 36+n*96 U4 Sub-frame 1 – WORD7 40+n*96 U4 Sub-frame 2 – WORD0 44+n*96 U4 Sub-frame 2 – WORD1 48+n*96 U4 Sub-frame 2 – WORD2 52+n*96 U4 Sub-frame 2 – WORD3.
78 UBX Class CFG This class is used to configure the GPS module and output the current configuration of the GPS module. The modul e will respond the ACK-ACK me ssage if the request is proceeded correctly and ACK-NAK message if the request is failed. CFG – PR T (0x06 0x00) It’ s a poll request.
79 10 – 2 stop bit ; 1 1 – reserved Bit[16] 0 – LSB first bit order 1 – MSB first bi t order Bit[19] 0 – 16x oversampling 1 – 8x oversampling 8+N*20 U4 Baud rate (bps) 12+N*20 U2 Input protocol for a sin gle port. Multi- p rotocols ca n be selected for a single port.
80 CFG – MSG (0x06 0x01) It’ s a poll request. Poll a message configuration. Header ID Data Length Data Checksum 0xB5 0x62 0x06 0x01 2 See below C K_A CK_B Data Offset bytes Format Descriptions Notes 0 U1 Class ID 1 U1 Message ID CFG – MSG (0x06 0x01) It’ s an I/O message.
81 Data Offset bytes Format Descriptions Notes 0 U1 Class ID 1 U1 Message ID 2 U1 Message rate on t he current target.
82 CFG – NMEA (0x06 0x17) It’ s a poll request. Poll the NMEA protocol configuration. Header ID Data Length Data Checksum 0xB5 0x62 0x06 0x17 0 None CK_A CK_B CFG – NMEA (0x06 0x17) It’ s an input message.
83 CFG – RA TE (0x06 0x08) It’ s a poll request. Poll the current navi gation/measurement rate setting. The m odule will respond the same message defined below (I/O m essage). Header ID Data Length Data Checksum 0xB5 0x62 0x06 0x08 0 None CK_A CK_B CFG – RA TE (0x06 0x08) It’ s an I/O message.
84 CFG – CFG (0x06 0x09) It’ s a command message. The me ssage will clear , save, an d load configurations. The command consists of the three m asks (clear , save, and load) in each individual bit.
85 UBX-CFG-ANT) 11 R e s er v e d 12 ~ 15 Reserved for user applications 16 ~ 31 Reserved.
86 CFG – TP (0x06 0x07) It’ s a poll request. Poll time pulse inform ation. The module will respond the same message defined below (I/O message). Header ID Data Length Data Checksum 0xB5 0x62 0x06 0x07 0 None CK_A CK_B CFG – TP (0x06 0x07) It’ s an I/O message.
87 CFG – NA V (0x06 0x03) It’ s a poll request. Poll e ngine settings for navigati on. The module will respond the same message defined below (I/O m essage). Header ID Data Length Data Checksum 0xB5 0x62 0x06 0x03 0 None CK_A CK_B CFG – NA V (0x06 0x03) It’ s an I/O message.
88 used in the navigation solut ion 6 U1 DGPS tim etag rounding 1 – enable 0 – disable 7 U1 T imeout f or diffe rential correction data (s) 8 U1 T imeout for pse udorange correction data (s) 9 U1 .
89 CFG – DA T (0x06 0x06) It’ s a poll request. Poll datum setting. The module will respond the same message defined below (I/O message). Header ID Data Length Data Checksum 0xB5 0x62 0x06 0x06 0 None CK_A CK_B CFG – DA T (0x06 0x06) It’ s an input message.
90 seconds) 40 R4 Scale change (ppm) 0.0 ~ 50.0 CFG – DA T (0x06 0x06) It’ s an output message. Poll the current datu m. If the datum number is –1, the module is using the user-defin ed datum and only the value for se mi-m ajor axis is valid and the rest of them are not valid.
91 CFG – INF (0x06 0x02) It’ s a poll request. It’ s used to identify the output protocol. Header ID Data Length Data Checksum 0xB5 0x62 0x06 0x02 1 See below CK_A CK_B Data Offset bytes Format .
92 13 – User1-defined protocol 14 – User2-defined protocol 15 – User3-defined protocol 16 ~ 255 – reserved 1+N*8 U1 Reserved 2+N*8 U2 Reserved 4+N*8 U1 Informat ion message ena bled (INF class) at I/O target 0 (USAR T 0) Bit mask.
93 CFG – RST (0x06 0x04) It’ s an input message. It’ s used to reset receiver or clear backup data structure. Header ID Data Length Data Checksum 0xB5 0x62 0x06 0x04 4 See below CK_A CK_B Data O.
94 CFG – RXM (0x06 0x1 1) It’ s a poll request. It’ s used to poll RXM configura tion. The m odule responds the same message defined below . Header ID Data Length Data Checksum 0xB5 0x62 0x06 0x1 1 0 None CK_A CK_B CFG – RXM (0x06 0x1 1) It’ s an I/O message.
95 CFG – ANT (0x06 0x13) It’ s a poll request. It’ s used to poll ante nna control settings. The module responds the same message defined below . Header ID Data Length Data Checksum 0xB5 0x62 0x06 0x13 0 None CK_A CK_B CFG – ANT (0x06 0x13) It’ s an I/O message.
96 CFG – FXN (0x06 0x0E) It’ s a poll request. It’ s used to poll power saving (FixNow) mode configuration. The module responds the same m essage defined below . Header ID Data Length Data Checksum 0xB5 0x62 0x06 0x0E 0 None CK_A CK_B CFG – FXN (0x06 0x0E) It’ s a command message.
97 CFG – SBAS (0x06 0x16) It’ s a command message. It’ s used to configure SBAS systems, su ch as W AAS, EGNOS, and MSAS. More information about SB AS services is referred to document R TCA/DO-229C (www .
98 CFG – TM (0x06 0x10) It’ s a poll request. It’ s used to poll time m ark configuration. Header ID Data Length Data Checksum 0xB5 0x62 0x06 0x10 0 None CK_A CK_B CFG – TM (0x06 0x10) It’ s an I/O message. It’ s used to set/get time mark configuration.
99 CFG – EKF (0x06 0x12) It’ s a poll request. It’ s used to poll E KF configuration. The module responds the same message defined below . Header ID Data Length Data Checksum 0xB5 0x62 0x06 0x12 0 None CK_A CK_B CFG – EKF (0x06 0x12) It’ s an I/O message.
100 2 U1 Reserved 3 U1 Inverse_flags Bit 0 – invert m eaning of direction pi n; 0: High=Forw ards; 1: High=Backwards Bit 1 – invert meaning of gyro rotation se nse; 0: clockwis e p ositive; 1: cou.
101 UBX Class INF Basically , the INF class is an output class. It outputs strings with a printf-style call. INF – ERROR (0x04 0x00) It outputs an ASCII string to indicate error message.
102 INF – W ARNING (0x04 0x01) It outputs an ASCII string to indicate warning message. Header ID Data Length Data Checksum 0xB5 0x62 0x04 0x01 N*1 See below CK_A CK_B Data Offset bytes Format Descriptions Notes The following data will be repeated N times (variable length).
103 INF – NOTICE (0x04 0x02) It outputs an ASCII string to transmit informational contents. Header ID Data Length Data Checksum 0xB5 0x62 0x04 0x02 N*1 See below CK_A CK_B Data Offset bytes Format Descriptions Notes The following data will be repeated N times (variable length).
104 INF – TEST (0x04 0x03) It outputs an ASCII string to indicate test message. Header ID Data Length Data Checksum 0xB5 0x62 0x04 0x03 N*1 See below CK_A CK_B Data Offset bytes Format Descriptions Notes The following data will be repeated N times (variable length).
105 INF – DEBUG (0x04 0x04) It outputs an ASCII string to indicate debug message. Header ID Data Length Data Checksum 0xB5 0x62 0x04 0x04 N*1 See below CK_A CK_B Data Offset bytes Format Descriptions Notes The following data will be repeated N times (variable length).
106 INF – USER (0x04 0x07) It outputs an ASCII string to indicate user output message. Header ID Data Length Data Checksum 0xB5 0x62 0x04 0x07 N*1 See below CK_A CK_B Data Offset bytes Format Descriptions Notes The following data will be repeated N times (variable length).
107 UBX Class MON This message is used to transmit GPS receiv er status, such as CPU statu s, I/O status, etc.. MON – SCHD (0x0A 0x01) It periodically polls the status of system scheduler .
108 MON – IO (0x0A 0x02) It periodically polls the I/O status. Header ID Data Length Data Checksum 0xB5 0x62 0x0A 0x02 80 See below CK_A CK_B Data Offset bytes Format Descriptions Notes The following data will be repeated fo ur times (N = 4).
109 MON – MAGPP (0x0A 0x06) It periodically polls message parse and process status. Header ID Data Length Data Checksum 0xB5 0x62 0x0A 0x06 144 See below CK_A CK_B Data Offset bytes Format Descripti.
11 0 MON – RXBUF (0x0A 0x07) It periodically polls the status of receiver buf fer . Header ID Data Length Data Checksum 0xB5 0x62 0x0A 0x07 16 See below CK_A CK_B Data Offset bytes Format Descriptio.
111 MON – TXBUF (0x0A 0x08) It periodically polls the status of transmitter buf fer . Header ID Data Length Data Checksum 0xB5 0x62 0x0A 0x08 20 See below CK_A CK_B Data Offset bytes Format Descript.
11 2 MON – VER (0x0A 0x04) It is used to poll the hardware/software version. Header ID Data Length Data Checksum 0xB5 0x62 0x0A 0x04 40+N*30 See bel ow CK_A CK_B Data Offset bytes Format Descriptions Notes 0 CH[30] Software version 30 CH[10] Hardware version The following data will be repeated N times.
11 3 UBX Class NA V The messages in this class transm it navi gation data, status flags, and accuracy information. NA V – POSECEF (0x01 0x01) It periodically polls the receiver ’ s position in the ECEF frame.
11 4 NA V – POSLLH (0x01 0x02) It periodically polls the receiver ’ s position in the local geodetic frame. Header ID Data Length Data Checksum 0xB5 0x62 0x01 0x02 28 See below CK_A CK_B Data Offs.
11 5 NA V – POSUTM (0x01 0x08) It periodically polls the receiver ’ s position in the UTM frame. Header ID Data Length Data Checksum 0xB5 0x62 0x01 0x08 18 See below CK_A CK_B Data Offset bytes Fo.
11 6 NA V – DOP (0x01 0x04) It periodically polls the values of DOPs. Header ID Data Length Data Checksum 0xB5 0x62 0x01 0x04 18 See below CK_A CK_B Data Offset bytes Format Descriptions Notes 0 U4 .
11 7 NA V – ST A TUS (0x01 0x03) It periodically polls navigation status. Header ID Data Length Data Checksum 0xB5 0x62 0x01 0x03 16 See below CK_A CK_B Data Offset bytes Format Descriptions Notes 0.
11 8 NA V – SOL (0x01 0x06) It periodically polls the information about navigation solution. Header ID Data Length Data Checksum 0xB5 0x62 0x01 0x06 52 See below CK_A CK_B Data Offset bytes Format D.
11 9 NA V – VELECEF (0x01 0x1 1) It periodically polls velocity solution in the ECEF frame. Header ID Data Length Data Checksum 0xB5 0x62 0x01 0x1 1 20 See below CK_A CK_B Data Offset bytes Format D.
120 NA V – VELNED (0x01 0x12) It periodically polls velocity solution in the NED frame. Header ID Data Length Data Checksum 0xB5 0x62 0x01 0x12 36 See below CK_A CK_B Data Offset bytes Format Descri.
121 NA V – TIMEGPS (0x01 0x20) It periodically polls the information about GPS time. Header ID Data Length Data Checksum 0xB5 0x62 0x01 0x20 16 See below CK_A CK_B Data Offset bytes Format Descripti.
122 NA V – TIMEUTC (0x01 0x21) It periodically polls the information about UTC time. Header ID Data Length Data Checksum 0xB5 0x62 0x01 0x21 20 See below CK_A CK_B Data Offset bytes Format Descripti.
123 NA V – CLOCK (0x01 0x22) It periodically polls receiver clock information. Header ID Data Length Data Checksum 0xB5 0x62 0x01 0x22 20 See below CK_A CK_B Data Offset bytes Format Descriptions No.
124 NA V – SVINFO (0x01 0x30) It periodically polls the information about UTC time. Header ID Data Length Data Checksum 0xB5 0x62 0x01 0x30 8+N*12 See below CK_A CK_B Data Offset bytes Format Descri.
125 NA V – DGPS (0x01 0x31) It periodically polls DGPS correction data that are used in the navigation solution. Header ID Data Length Data Checksum 0xB5 0x62 0x01 0x31 16+N*12 See below CK_A CK_B D.
126 NA V – SBAS (0x01 0x32) It periodically polls the status of SBAS. Header ID Data Length Data Checksum 0xB5 0x62 0x01 0x32 12+N*12 See below CK_A CK_B Data Offset bytes Format Descriptions Notes 0 U4 GPS time of week (m s) 4 U1 PRN number for SBAS, e.
127 17+N*12 U1 Reserved 18+N*12 I2 Pseudo range correction (cm) 20+N*12 I2 Reserved 22+N*12 I2 Ionosphere correction (cm).
128 UBX Class RXM This class transmits the status of receiver m anager and received raw data, e.g. pseudorange and carrier phase measurements, ephem eris, and almanac data. RXM – RA W (0x02 0x10) It periodically outputs raw m easurement data . It defines all the necessary data for a RINEX file.
129 RXM – SFRB (0x02 0x1 1) It periodically outputs the data in the subframe of navigation message. Header ID Data Length Data Checksum 0xB5 0x62 0x02 0x1 1 42 See below CK_A CK_B Data Offset bytes .
130 RXM – SVSI (0x02 0x20) It periodically polls the information of SV status. Header ID Data Length Data Checksum 0xB5 0x62 0x02 0x20 8+N*6 See below CK_A CK_B Data Offset bytes Format Descriptions.
131 RXM – ALM (0x02 0x30) It’ s an input request for polling almanac data . The receiver responds with all available (32) RXM-ALM messages defined below . Header ID Data Length Data Checksum 0xB5 0x62 0x02 0x30 0 None C K_A CK_B RXM – ALM (0x02 0x30) It’ s an input request for polling almanac data of one specific SV .
132 not valid. 2. WORD0 ~ WORD7 contain th e data following the Hand-Over W ord (HOW) in the navigation message. The data ar e fr om th e sub-frame 4 of Pages 1 ~ 24 and the sub-frame 5 of Pages 2 ~ 10. Mor e info rmation about almanac data structur e is r eferr ed to ICD-GPS-200.
133 RXM – EPH (0x02 0x31) It’ s an input request for polling epheme ris data. The receiver responds with all available RXM-EPH messages defined below . Header ID Data Length Data Checksum 0xB5 0x62 0x02 0x31 0 None C K_A CK_B RXM – EPH (0x02 0x31) It’ s an input request for polling ephemeri s data of one specific SV .
134 36+n*96 U4 Sub-frame 1 – WORD7 40+n*96 U4 Sub-frame 2 – WORD0 44+n*96 U4 Sub-frame 2 – WORD1 48+n*96 U4 Sub-frame 2 – WORD2 52+n*96 U4 Sub-frame 2 – WORD3 56+n*96 U4 Sub-frame 2 – WORD.
135 RXM – POSREQ (0x02 0x40) It’ s an input message for requesting a positi on fix in the FixNow mode (power saving mode). Header ID Data Length Data Checksum 0xB5 0x62 0x02 0x40 0 None C K_A CK_B.
136 UBX Class TIM This class transmits the inform ation of time pulse and time mark. TIM – TM (0x0D 0x02) It periodically polls the time mark data. Header ID Data Length Data Checksum 0xB5 0x62 0x0D.
137 TIM – TP (0x0D 0x01) It periodically polls the time pulse data. Header ID Data Length Data Checksum 0xB5 0x62 0x0D 0x01 16 See below CK_A CK_B Data Offset bytes Format Descriptions Notes 0 U4 GP.
138 UBX Class UPD This class is used to update the firmware. UPD – DOWNL (0x09 0x01) It is an I/O message. It is used to download data to mem ory . Header ID Data Length Data Checksum 0xB5 0x62 0x09.
139 UPD – UPLOAD (0x09 0x02) It is an I/O message. It is used to upload data from m emory . Header ID Data Length Data Checksum 0xB5 0x62 0x09 0x02 12+N*1 See below CK_A CK_B Data Offset bytes Forma.
140 Chapter 8 T roubleshooting The following table lists questions/problem s that you m ight encounter for operating the module and possible suggested resolutions for the questions/problems. If you have further questions/problems that cannot be reso lved in this table, please feel free to contact us.
141 6. The estimated positions have steadily expressed about a few meters or up to a few hundred meters of f the reference position. Make sure the estimated positio n and reference position are expressed in the same coordinate frame. The default datum of the module is WGS 84.
142 Appendix A Geodetic ID: Coordinate Datum Index Name Acron y m DX (m) DY(m) DZ (m) Ellipsoid Index (See below) Rotation and Scale (See below) 0 W orld Geodetic System - 84 WGS 84 0.0 0.0 0.0 0 0 1 W orld Geodetic System - 72 WGS 72 0.0 0.0 4.5 23 1 2 Earth-90 - GLONASS Coordinate system ETH 90 0.
143 18 ARC 1950 - Zambi a ARF-F -147.0 -74.0 -283.0 7 0 19 ARC 1950 - Zim babwe ARF-G -142.0 -96.0 -293.0 7 0 20 ARC 1960 - Mean (Kenya, T anzania) ARS -160.0 -6.0 -302.0 7 0 21 A yabelle Lighthouse - Djibouti PHA -79.0 -129.0 145.0 7 0 22 Bissau - Guinea-Bissau BID -173.
144 41 Djakarta (Batavia)- Sumatra (Indonesia) BA T -377.0 681.0 -50.0 5 0 42 Hong Kong 1963 - Hong Kong HKD -156.0 -271.0 -189.0 20 0 43 Hu-Tzu-Shan - T aiwan HTN -637.0 -549.0 -203.0 20 0 44 Indian - Bangladesh IND-B 282.0 726.0 254.0 9 0 45 Indian - India & Nepal IND-I 295.
145 62 T okyo - Okinawa TOY - C -158.0 507.0 676.0 5 0 63 T okyo - South Korea TOY -B -146.0 507.0 687.0 5 0 64 Australian Geodetic 1966 - Australia & T asm ania AUA -133.0 -48.0 148.0 3 0 65 Australian Geodetic 1984 - Australia & T asm ania AUG -134.
146 80 European 1979 - Mean Solution (AU, FN, NL, N, E, S, CH) EUS -86.0 -98.0 -1 19.0 20 0 81 Hjorsey 1955 - Iceland HJO -73.0 46.0 -86.0 20 0 82 Ireland 1965 IRL 506.0 -122.0 61 1.0 2 0 83 Ordnance Survey of GB 1936 - Mean (E, IoM, S, ShI, W) OGB-M 375.
147 Alaska (excluding Aleutian Islands) 96 N. Am erican 1927 - Aleutian Islands, East of 180W NAS-V -2.0 152.0 149.0 6 0 97 N. Am erican 1927 - Aleutian Islands, W est of 180W NAS-W 2.0 204.0 105.0 6 0 98 N. Am erican 1927 - Bahamas (excl uding San Salvador Island) NAS-Q -4.
148 Caribbean 108 N. Am erican 1927 - Central America NAS-N 0.0 125.0 194.0 6 0 109 N. Am erican 1927 - Cuba NAS-T -9.0 152.0 178.0 6 0 1 10 N. Am erican 1927 - Greenland (Hayes Peninsula) NAS-U 11 . 0 1 14.0 195.0 6 0 111 N. American 1927 - Mexico NAS-L -12.
149 Bolivia 124 Prov S. Am erican 1956 - Northern Chile (near 19S) PRP-B -270.0 183.0 -390.0 20 0 125 Prov S. Am erican 1956 - Southern Chile (near 43S) PRP-C -305.0 243.0 -442.0 20 0 126 Prov S. Am erican 1956 - Colombia PRP-D -282.0 169.0 -371.0 20 0 127 Prov S.
150 Galapagos Islands) 139 South American 1969 - Baltra, Galapagos Isla nds SAN-J -47.0 26.0 -42.0 22 0 140 South American 1969 - Guyana SAN-G -53.0 3.0 -47.0 22 0 141 South American 1969 - Paraguay SAN-H -61.0 2.0 -33.0 22 0 142 South American 1969 - Peru SAN-I -58.
151 154 L.C. 5 Astro 1961 - Cayman Brac Island LCF 42.0 124.0 147.0 6 0 155 Montserrat Island Astro 1958 - Montserrat Leeward Islands ASM 174.0 359.0 365.0 7 0 156 Naparima, BWI - T rinidad & T obago NAP -10.0 375.0 165.0 20 0 157 Observatorio Meteorologi co 1939 - Corvo and Flores Islands (Azores) FLO -425.
152 Diego Garcia 169 Kerguele n Island 1949 - Kerguele n Island KEG 145.0 -187.0 103.0 20 0 170 Mahe 1971 - Mahe Isla nd MIK 41.0 -220.0 -134.0 7 0 171 Reunion - Mascarene Islands RUE 94.0 -948.0 -1262.0 20 0 172 American Sam oa 1962 - American Samoa Islands AMA -115.
153 185 Johnston Island 1961 - Johnston Island JOH 189.0 -79.0 -202.0 20 0 186 Kusaie Astro 1951 - Caroline Islands, Fed. States of Micronesia KUS 647.0 1777.0 -1 124.0 20 0 187 Luzon - Philippines (excluding Mindanao Island) LUZ-A -133.0 -77.0 -51.0 6 0 188 Luzon - Mindanao Island (Philippines) LUZ-B -133.
154 Antarctica 202 European 1950 - Iraq, Israel, Jordan, Kuwait, Lebanon, Saudi Arabia & Syria EUR-S -103.0 -106.0 -141.0 20 0 203 Gunung Segara - Kalimant an (Indonesia) GSE" -403.0 684.0 41.0 5 0 204 Herat North - Afghanistan HEN -333.0 -222.
155 Ellipsoids Index Name Semi Major Axis (m) 1/Flattening 0 WGS 84 6378137.000 298.257223563 1 Airy 1830 6377563.396 299.3249646 2 Modified Airy 6377340.189 299.3249646 3 Australian National 6378160.000 298.25 4 Bessel 1841 (Nami bia) 6377483.865 299.
156 Rotation and Scale T able Index Name Rot. X (seconds) Rot. Y (seconds) Rot. Z (seconds) Scale (-) 0 +0.0000 +0.0000 +0.0000 0.000 1 0.0000 0.0000 -0.
157 Appendix B Acr onyms BBR Battery Backed-up RAM C L T C a r r i e r L o c k T i m e CN0 Carrier to Noise Ratio COG Course Over Ground CTM Continuous T racking Mode DGPS Dif ferential GPS DOP Diluti.
158 Refer ences 1. ANT ARIS R Chipset – System Integration- Manual for San Jose Navigation, Doc. No. GPS.G3-DK-03014. 2. ANT ARIS R Protocol Specifications, Doc. No. GPS.G3-X-03002. 3. NMEA 0183, Standard For Interfacing Marine Electronic Devices, V ersion 2.
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