GNU Radio decoders for Amateur satellites.
gr-satellites is a GNU Radio out-of-tree module encompassing a collection of telemetry decoders that supports many different Amateur satellites. This open-source project started in 2015 with the goal of providing telemetry decoders for all the satellites that transmit on the Amateur radio bands. It suports most popular protocols, such as AX.25, the GOMspace NanoCom U482C and AX100 modems, an important part of the CCSDS stack, the AO-40 protocol used in the FUNcube satellites, and several ad-hoc protocols used in other satellites.
The decoders don't need a graphical interface to run, so they can be used in an embedded or remote computer. They are designed to run in real time and print the telemetry packets to the terminal as they are received. Optionally, the telemetry packets can be uploaded in real time to the SatNOGS database or any other telemetry server that implements the SiDS (Simple Downlink Sharing Convention) protocol.
It is also possible to use the decoder with a recording (audio WAV or IQ file), in case that the telemetry wasn't processed in real time. To do this, one has to know the time and date at which the recording was started and the recording has to be played back at normal speed. This allows the decoder to compute the correct timestamps for the packets when uploading them to the telemetry server. It also simplifies Doppler correction of the recording with Gpredict if the recording was not Doppler corrected.
First you need to install the dependencies (see below).
After this, gr-satellites must be installed as any other GNU Radio out-of-tree module. The producedure usually boils down to doing the following:
mkdir build
cd build
cmake ..
make
sudo make install
sudo ldconfig
Finally, you need to compile the hierarchical flowgraphs include in gr-satellites (see below).
gr-satellites requires GNU Radio version 3.7.12.0 or new. An older version may be used, but note the following:
- The "Correlate Access Code - Tag" block has changed slightly in the 3.7.12.0
version (it now allows floats as well as bytes). The new block is
incompatible with the older one, so the flowgraphs using "Correlate Access
Code - Tag" will complain of missing blocks when using an older version of
GNU Radio. It is possible to replace the "Correlate Access Code - Tag" block
by hand with the older version and the flowgraphs should then
work. Especially, you have to look at the hierarchical blocks
sync_to_pdu.grc
andsync_to_pdu_packed.grc
in gr-satellites. - There is a bug in the "Additive scrambler" block. The bug fix was introduced in version 3.7.12.0 of GNU Radio. If using an older release of GNU Radio, do not expect this block to work completely. However, the "Additive scrambler" is only used to decode CCSDS scrambling. Decoders using G3RUH scrambling or no scrambler should work fine.
Required dependencies:
- Phil Karn's KA9Q
libfec
. A fork that builds in modern linux systems can be found here. - construct, at least version 2.9.
- requests.
- swig
The following GNUradio out-of-tree modules are only required for the decoder of one particular satellite. You may install only the ones you're interested in.
- gr-aausat AAUSAT-4 decoder and telemetry parser
- beesat-sdr BEESAT and TECHNOSAT decoder and TNC. It is also used for D-STAR One.
- gr-lilacsat This only needs to be installed if you want to submit telemetry to HIT. A complete decoder which does not use gr-lilacsat is already included in gr-satellites.
- PW-Sat2 FramePayloadDecoder This only needs to be installed if you want to parse frames from PW-Sat2. See the instructions here.
- gr-equisat_decoder EQUiSat decoder blocks, telemetry parser, and submitter.
If you want to use any of the realtime image decoders, you also need to install feh.
Some of the decoders use hierarchichal flowgraphs. These are placed in the
folder apps/hierarchical
. The hierarchical flowgraphs must be compiled and
installed before using any of the flowgraphs which include them.
To compile and install the hierarchical flowgraphs, the script
compile_hierarchical.sh
in the root folder can be used.
The signal is fed to the decoders using a UDP stream. The format used is the same that gqrx uses. Therefore, you can use gqrx to feed the signal to the decoders. You will have to set the proper frequency, mode and bandpass in gqrx for the satellite you want to receive. This is probably the easiest way to start using the decoders from gr-satellites. Gqrx supports Doppler correction with Gpredict.
Note: The exact frequency setting for optimal decoding may need to tuned to properly center the signal within the passband. This is especially true for SSB signals. One way to do this is by using this the Radio Control panel within Gpredict. This allows the user to make small adjustments while monitoring signals in the gqrx passband.
It is also possible to use the frontend streamers from gr-frontends. These allow to stream data by UDP from different SDR hardware without using a GUI SDR program. It remains to perform Doppler correction with Gpredict. There are also frontend streamers to use a conventional receiver connected via soundcard and recordings (audio WAV and IQ).
Each satellite has its own decoder in the apps/
folder. You can open the
.grc
file with gnuradio-companion
and edit the parameters (they are on the
upper part of the flowgraph). You can also generate and run the corresponding
.py
script and specify the parameters on the command line. Use the -h flag to
get help on how to specify the parameters. The decoder will printing each
telemetry packet in the terminal as soon as it receives it.
sat_1kuns_pf
1KUNS-PF, which transmits 1k2 or 9k6 GMSK telemetry in the 70cm band. It uses the GomSpace NanoCom AX100 transceiver in ASM+Golay mode. This uses a CCSDS scrambler and a (255,223) Reed-Solomon code. You must use FM mode to receive this satellite (437.300 MHz). 1KUNS-PF transmits JPEG images from an onboard camera. This decoder includes an image decoder which shows the images in real time using feh.sat_3cat_1
3CAT-1, which transmits 9k6 GFSK telemetry in the 70cm band. It uses a Texas Intruments CC1101 transceiver with a PN9 scrambler, and a (255,223) Reed-Solomon code from the rscode library. You must use FM mode to receive this satellite (437.250MHz).sat_3cat2
3CAT-2 (inactive), which transmits 9k6 AX.25 BPSK telemetry in the 2m band. You must use wide SSB mode to receive this satellite.aistechsat2
AISTECHSAT-2, which transmits 4k8 or 9k6 GMSK telemetry in the 70cm band. It uses the GomSpace NanoCom AX100 transceiver in ASM+Golay mode. This uses a CCSDS scrambler and a (255,223) Reed-Solomon code. You must use FM mode to receive this satellite (436.730MHz).aistechsat3
AISTECHSAT-3, which transmits 4k8 or 9k6 GMSK telemetry in the 70cm band. It uses the GomSpace NanoCom AX100 transceiver in ASM+Golay mode. This uses a CCSDS scrambler and a (255,223) Reed-Solomon code. The telemetry format is documented but a telemetry decoder has not been implemented yet. You must use FM mode to receive this satellite (436.730MHz).amgu_1
AmGU-1, which transmits 4k8 FSK telemetry in the 70cm band. It uses the Mobitex protocol, which includes FEC with a (12,8,3) linear code and CRC-16CCITT for error detection. The decoder requires the beesat-sdr OOT module. You must use FM mode to receive this satellite (436.250MHz).astrocast
,astrocast_old
,astrocast_9k6
Astrocast 0.1, which transmits 1k2 FSK telemetry in the 70cm band. It uses the FX.25 protocol with a (255,223) CCSDS Reed-Solomon code. Theastrocast_old
decoder is for the protocol variant used until 2019-02-13, which wast not completely compatible with AX.25. Theastrocast_9k6
decoder is for the 9k6 FSK protocol used for data download. This uses five interleaved (255,223) CCSDS Reed-Solomon codewords following the CCSDS standard. You must use FM mode to receive this satellite (437.150MHz).aausat_4
AAUSAT-4, which transmits 2k4 or 9k6 GFSK telemetry in the 70cm band. It uses the CSP protocol and FEC with an r=1/2, k=7 convolutional code and a (255,223) Reed-Solomon code. You must use FM mode to receive this satellite (437.425MHz).ao40_uncoded
AO-40 (inactive), which transmitted 400bps BPSK telemetry in several bands. This decoder is for the uncoded telemetry, which did not use any forward error correction. The specifications of the telemetry can be found in this document. AO-40 is no longer functional, but it is of high historic interest. You must use SSB mode to receive this satellite.ao73
AO-73 (FUNcube), which transmits 1k2 BPSK telemetry in the 2m band. It uses the AO-40 FEC protocol, which includes block interleaving, an r=1/2, k=7 convolutional code, CCSDS scrambling and two interleaved (160,128) Reed-Solomon codes. You must use SSB mode to receive this satellite (145.935MHz).aisat
AISAT, which transmits 4k8 AF GMSK telemetry in the 70cm band. It uses a NanoCom U482C transceiver with the CSP protocol and FEC with a (255,223) Reed-Solomon code. It also uses a CCSDS scrambler. There is no telemetry parser yet, as the beacon format is unknown. This satellite has an AIS receiver on board. You must use FM mode to receive this satellite.at03
QB50 AT03 (PEGASUS), which transmits 9k6 GFSK telemetry in the 70cm band. It uses the TT-64 protocol, which includes a CRC16-ARC and FEC with a (64,48) Reed-Solomon code. Reed-Solomon decoding is done with the rscode library. You must use FM mode to receive this satellite (436.670MHz).athenoxat-1
ATHENOXAT-1, which transmits 4k8 AF GMSK telemetry in the 70cm band. It uses a NanoCom U482C transceiver, with the CSP protocol and FEC with a (255,223) Reed-Solomon code. It also uses a CCSDS scrambler. There is no telemetry parser yet, as the beacon format is unknown. This satellite is on a low inclination orbit, so it can only be received near the equator. You must use FM mode to receive this satellite (437.485MHz).au02
QB50 AU02 (UNSW-EC0), which transmits 4k8 AF GMSK telemetry in the 70cm band. It uses a NanoCom U482C transceiver, with the CSP protocol and FEC with an r=1/2, k=7 convolutional code and a (255,223) Reed-Solomon code. It also uses a CCSDS scrambler. You must use FM mode to receive this satellite (436.525MHz).au03
QB50 AU03 (i-INSPIRE II), which transmits 4k8 AF GMSK telemetry in the 70cm band. It uses a NanoCom U482C transceiver, with the CSP protocol and FEC with an r=1/2, k=7 convolutional code and a (255,223) Reed-Solomon code. It also uses a CCSDS scrambler. You must use FM mode to receive this satellite (436.330MHz).beesat
BEESAT-1,-2,-4 and -9 and TECHNOSAT, which transmit 4k8 FSK telemetry in the 70cm band. They use the Mobitex-NX protocol, which includes FEC with a (12,8,3) linear code and CRC-16CCITT for error detection. The decoder requires the beesat-sdr OOT module. You must use FM mode to receive these satellites (435.950MHz).by701
BY70-1 (inactive), which transmits 9k6 BPSK telemetry in the 70cm band. It uses FEC with an r=1/2, k=7 convolutional code and a (255,223) Reed-Solomon code (the same as the LilacSat-2 9k6 BPSK telemetry). You must use wide SSB mode to receive this satellite. It has an optical camera on board and it transmits JPEG images together with the telemetry.by701
includes a complete telemetry decoder and image receive software. This satellite launched on 28 December 2016 into a 520x220km orbit. The perigee is too low because of a problem in the launch. BY70-1 reentered on 18 February 2017. You must use wide SSB mode to receive this satellite.ca03
QB50 CA03 (Ex-Alta 1), which transmits 4k8 GFSK telemetry in the 70cm band. Occasionaly it has been seen to transmit in 9k6. It uses the CSP protocol and FEC with a (255,223) Reed-Solomon code. It also uses a G3RUH scrambler. The transceiver is the GomSpace NanoCom AX100, the same transceiver used in GOMX-3. You must use FM mode to receive this satellite (436.705MHz).cz02
QB50 CZ02 (VZLUSAT-1), which transmits 4k8 AF GMSK telemetry in the 70cm band. It uses a NanoCom U482C transceiver, with the CSP protocol and a (255,223) Reed-Solomon code. It also uses a CCSDS scrambler. You must use FM mode to receive this satellite (437.240MHz).delphini1
Delphini-1, which transmits 4k8 GMSK telemetry in the 70cm band. It uses the GomSpace NanoCom AX100 transceiver in ASM+Golay mode. This uses a CCSDS scrambler and a (255,223) Reed-Solomon code. You must use FM mode to receive this satellite (437.500MHz).dsat
D-SAT (inactive), which transmits 4k8 AF GMSK telemetry in the 70cm band. It uses a NanoCom U482C transceiver with the CSP protocol and FEC with a (255,223) Reed-Solomon code. It also uses a CCSDS scrambler. This receiver supports sending frames to the D-SAT groundstation software, which decodes telemetry. See this post for detailed instructions. D-SAT transmits JPEG images from an onboard camera. This decoder includes an image decoder which shows the images in real time using feh.dstar_one
D-STAR One, which transmits 4k8 FSK telemetry in the 70cm band. It uses the Mobitex protocol, which includes FEC with a (12,8,3) linear code and CRC-16CCITT for error detection. The decoder requires the beesat-sdr OOT module. You must use FM mode to receive this satellite (435.700MHz).entrysat
EntrySat, which transmits 9k6 AX.25 BPSK telemetry in the 70cm band. It uses a G3RUH scrambler. You must use wide SSB mode to receive this satellite (436.950MHz).equisat
EQUiSat, which transmits 9k6 baud 4FSK telemetry in the 70cm band. It uses a double-interleaving encoding and a (255,223) Reed-Solomon code. The decoder requires the gr-equisat_decoder OOT module. You must use FM mode to receive this satellite (435.525MHz). For more info see brownspace.org/receiving-equisat, and see below for how to submit to the telemetry database.eseo
ESEO, which transmits 9k6 GFSK telemetry in the 70cm band. It uses a custom protocol vaguely similar to AX.25 with some form of G3RUH scrambling and a (255,239) Reed-Solomon code. You must use FM mode to receive this satellite (437.000MHz).facsat_1
, FACSAT-1, which transmits 9k6 GMSK telemetry in the 70cm band. It uses the GomSpace NanoCom AX100 transceiver in ASM+Golay mode. This uses a CCSDS scrambler and a (255,223) Reed-Solomon code. The telemetry format is unknown. You must use FM mode to receive this satellite (437.350MHz).fmn1
FMN-1, which transmits 9k6 AX.25 BPSK telemetry in the 70cm band. It uses a G3RUH scrambler. You must use wide SSB mode to receive this satellite (435.350MHz).galassia
GALASSIA, which transmits 4k8 AF GMSK telemetry in the 70cm band. It uses a NanoCom U482C transceiver with the the CSP protocol and FEC with a (255,223) Reed-Solomon code. It also uses a CCSDS scrambler. There is no telemetry parser yet, as the beacon format is unknown. This satellite is on a low inclination orbit, so it can only be received near the equator. You must use FM mode to receive this satellite.gomx_1
GOMX-1, which transmits 4k8 AF GMSK telemetry in the 70cm band. It uses a NanoCom U482C transceiver with the CSP protocol and FEC with a (255,223) Reed-Solomon code. It also uses a CCSDS scrambler. The beacons include information from ADS-B beacons transmitted by terrestrial aircraft. You must use FM mode to receive this satellite (437.255MHz).gomx_3
GOMX-3 (inactive), which transmits 19k2 GFSK telemetry in the 70cm band. It uses the CSP protocol and FEC with a (255,223) Reed-Solomon code. It also uses a G3RUH scrambler. The beacons include information from ADS-B beacons transmitted by terrestrial aircraft. GOMX-3 reentered on 18 October 2016. You must use FM mode to receive this satellite.gr01
QB50 GR01 (DUTHSat) (inactive), which transmits 1k2 or 9k6 AX.25 BPSK telemetry in the 70cm band. It uses a G3RUH scrambler. For 1k2 telemetry you must use SSB mode, while for 9k6 telemetry you must use wide SSB mode.il01
QB50 IL01 (DUCHIFAT-2), which transmits 9k6 AX.25 BPSK telemetry in the 70cm band. It uses a G3RUH scrambler. You must use wide SSB mode to receive this satellite (437.740MHz).indus
Mystery satellite transmitting on 435.080MHz using 1k2 FSK AX.25 and the callsign INDUSR-10 (see here).innosat_2
, INNOSAT-2, which transmits 4k8 GMSK telemetry in the 70cm band. It uses the GomSpace NanoCom AX100 transceiver in ASM+Golay mode. This uses a CCSDS scrambler and a (255,223) Reed-Solomon code. You must use FM mode to receive this satellite (437.450MHz).itasat1
ITASAT 1, which transmits 1k2 AX.25 BPSK telemetry in the 2m band. You must use SSB mode to receive this satellite (145.860MHz).jy1sat
JY1-Sat (FUNcube-6), which transmits 1k2 BPSK telemetry in the 2m band. It uses the AO-40 FEC protocol, which includes block interleaving, an r=1/2, k=7 convolutional code, CCSDS scrambling and two interleaved (160,128) Reed-Solomon codes. Decoding SSDV images is supported. See this post. You must use SSB mode to receive this satellite (145.840MHz).k2sat_image
K2SAT, which transmits images using QPSK in the 13cm band. See this post.kr01
QB50 KR01 (LINK) (inactive), which transmits 9k6 AX.25 BPSK telemetry in the 70cm band. It uses a G3RUH scrambler. Currently it transmits 1k2 telemetry (safe mode perhaps), so you must use SSB mode to receive this satellite.ks_1q
KS-1Q (inactive), which transmits 20k FSK telemetry in the 70cm band. It uses KISS framed CSP packets and FEC with an r=1/2, k=7 convolutional code and a (255,223) Reed-Solomon code (the protocol is very similar to LilacSat-2). It also uses a CCSDS scrambler. You must use FM mode to receive this satellite.lilacsat2
LilacSat-2, which transmits 9k6 BPSK, 4k8 GFSK and FM subaudio telemetry in the 70cm band. It uses FEC with an r=1/2, k=7 convolutional code and a (255,223) Reed-Solomon code. The decoders for this satellite are organized a bit different from the decoders for other satellites, because LilacSat-2 transmits in several different frequencies using several different modes. You can uselilacsat2
as a usual single-frequency single-mode decoder. You can use gqrx or one of the frontends from gr-frontends to feed an UDP audio stream tolilacsat2
. However, you can decode only one frequency and mode using this method. You should tune to 437.200MHz in wide SSB mode to receive 9k6 BPSK telemetry, to 437.200MHz in FM mode to receive FM subaudio telemetry and to 437.225MHz in FM mode to receive 4k8 GFSK telemetry.lilacsat2
will recognise the telemetry format automatically. To receive all the frequencies and modes at the same time, you need to use an SDR receiver. The receiverslilacsat_fcdpp
andlilacsat_rtlsdr
can be used with a FUNcube Dongle Pro+ and an RTL-SDR respectively. These are complete receivers and decoders. They submit telemetry to the SatNOGS database and can use Doppler correction with Gpredict, in the same way as the frontends from gr-frontends. Forlilacsat_fcdpp
andlilacsat_rtlsdr
, when using Doppler correction with Gpredict, you have to set 437.200MHz as the downlink frequency in Gpredict.lucky_7
Lucky-7, which transmits 4k8 GFSK telemetry in the 70cm band. It uses a SiLabs Si4463 transceiver with a PN9 scrambler and a CRC-16. You must use FM mode to receive this satellite (437.525MHz).lume1
LUME-1, which transmits 4k8 GMSK telemetry in the 70cm band. It uses the GomSpace NanoCom AX100 transceiver in ASM+Golay mode. This uses a CCSDS scrambler and a (255,223) Reed-Solomon code. You must use FM mode to receive this satellite (437.060MHz).mysat1
MYSAT 1, which transmits 1k2 or 9k6 AX.25 BPSK telemetry in the 70cm band. It uses a G3RUH scrambler. For 1k2 telemetry you must use SSB mode, while for 9k6 telemetry you must use wide SSB mode (435.77MHz).nayif1
Nayif-1 (FUNcube-5), which transmits 1k2 BPSK telemetry in the 2m band. It uses the AO-40 FEC protocol, which includes block interleaving, an r=1/2, k=7 convolutional code, CCSDS scrambling and two interleaved (160,128) Reed-Solomon codes. You must use SSB mode to receive this satellite (145.940MHz).nusat
ÑuSat-1 and -2, which transmit 40k FSK telemetry in the 70cm band (ÑuSat-1 on 436.445, ÑuSat-2 on 437.455). They use FEC with a (64, 60) Reed-Solomon code and a CRC-8. Since a sample rate of 48kHz is too low to work with 40k FSK, the flowgraph is prepared to use an IQ recording at 192kHz. Depending on the characteristics of your IQ recording you may need to edit the flowgraph. The Reed-Solomon decoder is taken from the rscode library. A sample IQ recording is included in satellite-recordings.picsat
PicSat, which transmits 1k2 or 9k6 AX.25 BPSK telemetry in the 70cm band. It uses a G3RUH scrambler. For 1k2 telemetry you must use SSB mode, while for 9k6 telemetry you must use wide SSB mode (435.525MHz).pwsat2
PW-Sat2, which transmits 1k2, 2k4, 4k8 or 9k6 AX.25 BPSK telemetry in the 70cm band. It uses a G3RUH scrambler. Currently the decoder only supports 1k2 or 9k6, since it is not clear if the other baudrates will be ever used. Telemetry parsing is supported using the external PW-Sat2 software. See here for the instructions. Uploading to the PW-Sat2 Telemetry Server is also supported. See here for the instructions. For 1k2 telemetry you must use SSB mode, while for 9k6 telemetry you must use wide SSB mode (435.275MHz).qo100
QO-100 (Es'hail 2 AMSAT Phase 4-A), which transmits a 400baud BPSK beacon in the 3cm band. The beacon is relayed from the control centre in Qatar via a 13cm/3cm linear transponder on the satellite. The format of the telemetry is the same as that of the AO-40 beacon. Uncoded and FEC frames are sent alternatively. You must use SSB mode to receive this satellite (10489.800MHz).reaktor_hello_world
Reaktor Hello World, which transmits 9k6 GFSK telemetry in the 70cm band. It uses a Texas Intruments CC1125 transceiver with a PN9 scrambler and a CRC-16. You must use FM mode to receive this satellite (437.775MHz).shaonian_xing
Shaonian Xing (MXSat-1), which transmits 9k6 AX.25 BPSK telemetry in the 70cm band. It uses a G3RUH scrambler. You must use wide SSB mode to receive this satellite (436.375MHz).snet
S-NET A,B,C,D, which transmit 1k2 AFSK telemetry in the 70cm band. They use a custom coding with BCH FEC and interleaving. You must use FM mode to receive these satellites (435.950MHz).sokrat
Sokrat, which transmits 4k8 FSK telemetry in the 70cm band. It uses the Mobitex protocol, which includes FEC with a (12,8,3) linear code and CRC-16CCITT for error detection. The decoder requires the beesat-sdr OOT module. You must use FM mode to receive this satellite (436.000MHz).spooqy_1
SpooQy-1, which transmits 9k6 GMSK telemetry in the 70cm band. It uses the GomSpace NanoCom AX100 transceiver in ASM+Golay mode. This uses a CCSDS scrambler and a (255,223) Reed-Solomon code. The telemetry format is unknown. You must use FM mode to receive these satellites (436.200MHz).suomi_100
Suomi 100, which transmits 9k6 GMSK telemetry in the 70cm band. It uses the GomSpace NanoCom AX100 transceiver in ASM+Golay mode. This uses a CCSDS scrambler and a (255,223) Reed-Solomon code. You must use FM mode to receive this satellite (437.775MHz).tanusha3_pm
TANUSHA-3, which transmits FM audio, 1k2 AX.25 AFSK telemetry and 1k2 audio frequency phase modulation AX.25 telemetry in the 70cm band. This decoder is for the phase modulation packets. For the AFSK packets you can use any regular packet decoder such as direwolf. You must use FM mode to receive this satellite (437.050MHz).tw_1a
,tw_1b
,tw_1c
TW-1A, TW-1B, TW-1C, which transmit 4k8 GFSK telemetry in the 70cm band. They use the CSP protocol and FEC with a (255,223) Reed-Solomon code. They also use a G3RUH scrambler. The transceiver is the GomSpace NanoCom AX100, the same transceiver used in GOMX-3. There is no beacon parser yet, as the beacon format is unknown. The only difference between the 3 receivers is that the NORAD ID is set for the correct satellite when doing telemetry submission. You must use FM mode to receive these satellites. TW-1A, TW-1C (435.645 MHz), TW-1B (437.645 MHz).ty_2
,ty_4
,ty_6
TY-2, TY 4-01, and TY-6, which transmit 9k6 GMSK telemetry in the 70cm band. They use the GomSpace NanoCom AX100 transceiver in ASM+Golay mode. This uses a CCSDS scrambler and a (255,223) Reed-Solomon code. The telemetry format is unknown. The only difference between the 2 receivers is that the NORAD ID is set for the correct satellite when doing telemetry submission. You must use FM mode to receive these satellites. TY-2 (435.350MHz), TY 4-01 (435.925MHz), TY-6 (436.100MHz).ua01
QB50 UA01 (PolyITAN-2-SAU), which transmits 9k6 AX.25 BPSK telemetry in the 70cm band. It uses a G3RUH scrambler and two stages of NRZI coding. You must use wide SSB mode to receive this satellite (436.600MHz).ukube1
UKube-1 (FUNcube-2), which transmits 1k2 BPSK telemetry in the 2m band. It uses the AO-40 FEC protocol, which includes block interleaving, an r=1/2, k=7 convolutional code, CCSDS scrambling and two interleaved (160,128) Reed-Solomon codes. You must use SSB mode to receive this satellite (145.915MHz).zhou_enlai
Zhou Enlai, which transmits 9k6 AX.25 BPSK telemetry in the 70cm band. It uses a G3RUH scrambler. You must use wide SSB mode to receive this satellite (437.644MHz).
I do not add specific decoders to gr-satellites for satellites using standard
AFSK or FSK AX.25 packet radio, since there are many satellites using these
modes and there are already very good decoders for packet radio such as
direwolf. However, in case someone finds
it useful, I have added generic_4k8_fsk_ax25
, generic_9k6_fsk_ax25
and
generic_19k2_fsk_ax25
generic decoders for 4k8, 9k6 and 19k2 FSK AX.25 packet
radio. Additionally, there is generic_1k2_afsk_ax25
for 1k2 AFSK AX.25 packet
radio. Note that the performance of the AFSK decoder may not be optimal due to
improvable aspects in the signal processing (designing a good AGC is a
challenge, for instance).
To sumbit telemetry to the SatNOGS database (or
another SiDS telemetry server), you have to specify your callsign and
coordinates. The callsign is specified using the --callsign
parameter and the
latitude and longitude are specified using the --latitude
and --longitude
parameters if you are using the .py
script. If you are using the .grc
file
with gnuradio-companion
, you can set these parameters by editing the boxes on
the upper part of the flowgraph.
The format for the latitude and longitude is of the form 00.00000
or
-00.00000
. The -
means South (for latitude) or West (for longitude).
If you want to submit telemetry from a recording, you have to specify the UTC
date and time when the recording was started. This allows the decoder to compute
the proper timestamp for the packets. The format is YYYY-MM-DD HH:MM:SS
and it
is specified using --recstart
if using the .py
script or with the parameter
box on the upper part of the flowgrah if using the .grc
file with
gnuradio-companion
.
It is also very important that the decoder and the recording streamer are started simultaneously. This can be achieved by something like
gr-frontends/wav_48kHz.py -f recording.wav & \
gr-satellites/sat_3cat2.py --recstart="2016-01-01 00:00" --callsign=N0CALL --latitude=0.000 --longitude=0.000
There are many satellites that use standard packet radio AX.25 and can be
received with any software TNC such as
Direwolf. gr-satellites includes
kiss_submitter
to perform telemetry submission when using a software TNC.
kiss_submitter
connects to the software TNC as a KISS TCP client. The frames
received by the software TNC will be submitted by kiss_submitter
. To use
kiss_submitter
, you must specify your callsign and coordinates as when
submitting telemetry using any of the decoders. You also need to specify the
NORAD ID of the satellite you are receiving. This can be done by setting using
--norad
if using the .py
script or with the parameter if using the .grc
file. It is very important that you set the NORAD ID correctly. You can search
the NORAD ID in celestrak.
You must start the software TNC first and the run the .py
script or the .grc
file for kiss_submitter
.
The flowgraphs for the different FUNcube satellites/payloads also support
submitting telemetry to the FUNcube server. To use this, you need to obtain the
"Site Id" (your username) and "Auth code" from your account on the FUNcube
server. These parameters can then be indicated by using the --site-id
and
--auth-code
if using the .py
script or by editing the boxes in the lower
right part of the flowgraph if using the .grc
file.
It is also possible to use the flowgraphs in gr-satellites to submit telemetry
to the Harbin Institute of Technology servers using proxy_publish.py
in
gr-lilacsat/examples/proxy_publish
. To enable this, you must open the
flowgraphs in gnuradio-companion
and enable the "Socket PDU" block (usually on
the lower right corner of the flowgraph). This block is disabled by default
because when it is enabled the flowgraph won't run unless proxy_publish.py
is
running. Also see this information about
how to set the proper ports in proxy_publish.py
.
The EQUiSat flowgraph also supports submitting telemetry to the Brown Space Engineering data server. To use this, you need to obtain an API key from the server. This can be done simply with the following command:
curl -s -X POST http://api.brownspace.org/equisat/generate-key
The API key returned from this can then be specified using the --api-key
parameter
if using the .py
script or by editing the box in the upper middle part of the
flowgraph if using the .grc
file.
You can also specify similar submit metadata as the SatNOGS submitter (above),
such as your callsign and location. See python equisat.py --help
for all the options.
Some modes (9k6 BPSK, for instance) need to be received using SSB mode, but the bandwidth of the signal is larger than the usual 3kHz bandwidth of a conventional SSB receiver. Therefore, an SDR receiver or a heavily modified conventional SSB receiver is needed (a 9k6 BPKS signal is about 15kHz wide).
The decoders for satellites using these kind of wide SSB signals expect the
signal to be centred at an audio frequency of 12kHz. This means that you have to
dial in USB mode to a frequency 12kHz lower than the nominal frequency of the
satellite (+/- Doppler). If your SDR program allows this (gqrx does), the best
idea is to set an SSB audio filter from 0Hz to 24kHz and then tune the signal in
the middle of the passband. Alternatively, you can use the --bfo
parameter if
using the .py
file or edit the corresponding parameter in the .grc
file to
use a frequency different from 12kHz.
If you are using the wide SSB receivers from gr-frontends you don't need to do anything special, as these receivers already dial in USB mode to a frequency 12kHz than the nominal and use a 24kHz wide audio filter.
We are all used to the two SSB modes: USB (which is sideband-preserving) and LSB (which is sideband-inverting). When receiving FM (or FSK), there is the same concept. An FM receiver can be sideband-preserving or sideband-inverting. This makes no difference when receiving analog FM (both sound the same) or AX.25 (which uses a differential protocol).
However, some satellites which use FSK (AAUSAT-4 and GOMX-3, for instance) need
a sideband-preserving FM receiver. If your receiver is sideband-inverting, you
can use set --invert=-1
while running the .py
file or edit the corresponding
parameter in the .grc
file to invert the signal again in the decoder and
recover the original signal with the correct sidebands.
To run the decoder and save the output to a file, it is possible to do something like
python2 -u aausat_4.py | tee /tmp/aausat4.log
This will both print the beacons in real time and also save all the output to
the text file /tmp/aausat4.log
.