GPS Simulation: Difference between revisions
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then get some coffee - it's a slow single threaded process which is why we have to create a data file and then transmit it instead of realtime radio broadcast. When done make sure your gnuradio-companion graph is setup with the right source filename, data types, sink driver, antenna, etc. Anything miss-matches can cause it to frustratingly run but not work. | then get some coffee - it's a slow single threaded process which is why we have to create a data file and then transmit it instead of realtime radio broadcast. When done make sure your gnuradio-companion graph is setup with the right source filename, data types, sink driver, antenna, etc. Anything miss-matches can cause it to frustratingly run but not work. | ||
[[File:Grc_xmit_only.jpg]] | [[File:Grc_xmit_only.jpg]] | ||
Then click the run button or create top_block.py and run it on the command line and your gps simulated broadcast should be visible to devices a few inches away from the antenna. You can play with various gain settings in the sink block - looks like a setting of '0' sets the power amp driver to -52 db attenuatin and a setting of 10 you get -42 db: | |||
<nowiki>[INFO] SoapyLMS7::setGain(Tx, 0, PAD, -42 dB)</nowiki> | |||
{{Community}} | {{Community}} |
Revision as of 16:42, 1 March 2017
Introduction
This page details experiences using LimeSDR to simulate GPS.
These experiments were inspired by the excellent procedure written up here [1]. We want to use a similar process to target real devices, and have had luck with a qstarz 818XT bluetooth gps device a couple of inches from an antenna. Here I am visiting Trinity College Cambridge.
Setup
Software to git clone - https://github.com/osqzss/gps-sdr-sim
Follow the instructions on the github page for how to compile, it is a very easy procedure on Ubuntu with build-essential package installed.
$ gcc gpssim.c -lm -O3 -o gps-sdr-sim
Note there is a setting in gpssim.h for USER_MOTION_SIZE default 3000 max duration at 10MHz (300 seconds). You can increase that to 6000 or more to get longer default running times.
The default sample rate for gps-sdr-sim is 2.6e6, 16 bit I/Q data format. LimeSDR will need 10e6, and 8 bit interleaved I/Q data format, so the strategy is to create an rf data file non-realtime and then transmit that with a simple gnuradio python script created in gnuradio-companion. The gps-fake-out project [2] links to a grc file, or it's easy to create your own. That example project simultaneous transmits the rf data file and also collects rf data for later analysis with Matlab and SoftGNSS. I found it useful to replace the file sink with an fft display slightly offset, and 20e6 input rate.
The last puzzle piece needed are ephemeris data to feed gps-sdr-sim (required), RINEX v2 format ( read all about it here [3] - especially the file name format). There is a global network of Internation GNSS Service installations [4] providing up to date data, which may be accessed with anonymous ftp from the Goddard Space Flight Center
ftp -p cddis.gsfc.nasa.gov
Login anonymous 'ftp' and email for password. Use the merged GPS broadcast ephemeris file found in /pub/gps/data/daily/2017/brdc/. The filename convention is
'brdc' + <3 digit day of year> + '0.' + <2 digit year> + 'n.Z'
'n' for gps (don't get the 'g' files, that is glonass), and 'Z' for compressed. Day of year can be found with
$ date +%j
Get yesterdays - for example, today, Feb 28, 2017, I would get 'brdc0580.17n.Z', uncompress
$ uncompress brdc0580.17n.Z
Pick a place - All you need now is a location to go, Google maps is good for entering latitude,longitude and seeing where it goes, or pick a spot, right click and pick "Directions to here" and a little url hacking to get the coordinates, like 1.8605853,73.5213033 for a spot in the Maldives. To do: use the gpssim with a user motion file instead of a static location, there is even support for Google Earth and SatGen software.
Execution
Get ready to host some large files, ranging from 5 to 20GB in size, if going with a larger USER_MOTION_SIZE full duration and/or trying 16 bit. Create the rf data file, using 10e6 samples per second in interleaved 8bit I/Q sample format, using the day of year 059 merged broadcast ephemeris file:
$ ./gps-sdr-sim -e brdc0590.17n -l 1.8605853,73.5213033,5 -t 2017/02/28,22:00:00 -o gpssim_10M.s8 -s 10e6 -b 8 -v Using static location mode. 9.313e-09 0.000e+00 -5.960e-08 0.000e+00 9.011e+04 0.000e+00 -1.966e+05 0.000e+00 1.86264514923e-09 1.77635683940e-15 319488 1938 18 Start time = 2017/02/28,22:00:00 (1938:252000) Duration = 600.0 [sec] 02 78.1 5.0 25142702.4 4.5 04 305.9 10.6 24630434.2 4.0 10 244.0 20.9 23656748.6 3.2 12 174.6 31.9 22801339.9 2.6 13 59.8 27.2 23001942.1 2.8 15 80.1 60.3 20615340.0 1.7 18 273.8 42.7 21969027.9 2.1 20 3.4 36.7 22141445.5 2.3 21 322.3 14.4 24860118.2 3.7 24 152.1 21.2 23574508.7 3.2 25 227.1 49.6 21537006.8 1.9 26 310.2 0.2 25799081.3 5.1 29 2.7 52.0 21259731.6 1.8 32 211.7 0.4 25733242.7 5.0 Time into run = 1.6
then get some coffee - it's a slow single threaded process which is why we have to create a data file and then transmit it instead of realtime radio broadcast. When done make sure your gnuradio-companion graph is setup with the right source filename, data types, sink driver, antenna, etc. Anything miss-matches can cause it to frustratingly run but not work. Then click the run button or create top_block.py and run it on the command line and your gps simulated broadcast should be visible to devices a few inches away from the antenna. You can play with various gain settings in the sink block - looks like a setting of '0' sets the power amp driver to -52 db attenuatin and a setting of 10 you get -42 db:
[INFO] SoapyLMS7::setGain(Tx, 0, PAD, -42 dB)
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