Osmo-tetra » History » Version 1
laforge, 02/19/2016 10:52 PM
| 1 | 1 | laforge | [[PageOutline]] |
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| 2 | = Osmocom TETRA MAC/PHY layer experimentation code = |
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| 3 | |||
| 4 | This code aims to implement the sending and receiving part of the |
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| 5 | TETRA MAC/PHY layer. |
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| 6 | |||
| 7 | If you read the ETSI EN 300 392-2 (TETRA V+D Air Interface), you will |
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| 8 | find this code implementing the parts between the MAC-blocks (called |
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| 9 | type-1 bits) and the bits that go to the DQPSK-modulator (type-5 bits). |
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| 10 | |||
| 11 | It is most useful to look at Figure 8.5, 8.6, 9.3 and 19.12 of the |
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| 12 | abovementioned specification in conjunction with this program. |
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| 13 | |||
| 14 | == Big picture == |
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| 15 | |||
| 16 | {{{ |
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| 17 | #!graphviz |
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| 18 | digraph G { |
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| 19 | graph [ rankdir = LR ]; |
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| 20 | |||
| 21 | bits_file2 -> tetra_rx [ label = "read" ]; |
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| 22 | tetra_rx -> console [ label = "stdout" ]; |
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| 23 | tetra_rx -> wireshark [ label = "GSMTAP" ]; |
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| 24 | |||
| 25 | float_file2 -> float_to_bits [ label = "read" ]; |
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| 26 | float_to_bits -> bits_file1 [ label = "write" ]; |
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| 27 | |||
| 28 | USRP -> tetra_demod [ label = "USB" ]; |
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| 29 | tetra_demod -> float_file1 [ label = "write" ]; |
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| 30 | |||
| 31 | bits_file1 [ shape=box label="file.bits" ]; |
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| 32 | bits_file2 [ shape=box label="file.bits" ]; |
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| 33 | float_file1 [ shape=box label="file.float" ]; |
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| 34 | float_file2 [ shape=box label="file.float" ]; |
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| 35 | tetra_rx [ label="tetra-rx" ]; |
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| 36 | tetra_demod [ label="tetra-demod.py" ]; |
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| 37 | } |
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| 38 | }}} |
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| 39 | |||
| 40 | == Source Code == |
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| 41 | The source code is available via read-only git access at |
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| 42 | {{{ |
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| 43 | git clone git://git.osmocom.org/osmo-tetra.git |
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| 44 | }}} |
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| 45 | |||
| 46 | You can also browse the source code at http://cgit.osmocom.org/ |
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| 47 | |||
| 48 | You will need [http://bb.osmocom.org/trac/wiki/libosmocore libosmocore] to link. |
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| 49 | |||
| 50 | == Mailing List == |
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| 51 | There is a public mailing list regarding development of this project, you can |
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| 52 | visit the subscription page at https://lists.osmocom.org/mailman/listinfo/tetra |
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| 53 | |||
| 54 | This list is '''for discussion between software developers''' who intend to improve the |
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| 55 | Osmocom TETRA software. It is not a forum for individuals asking how they can tap |
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| 56 | into police radio (which is encrypted anyway). |
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| 57 | |||
| 58 | == FAQ == |
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| 59 | We now have a [wiki:FAQ] (Frequently asked Questions) page! |
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| 60 | |||
| 61 | == Demodulator == |
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| 62 | |||
| 63 | {{{src/demod/python/cpsk.py}}} |
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| 64 | * contains a gnuradio based pi4/DQPSK demodulator, courtesy of KA1RBI |
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| 65 | {{{src/demod/python/tetra-demod.py}}} |
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| 66 | * call demodulator on a 'cfile' containing complex baseband samples |
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| 67 | {{{src/demod/python/usrp1-tetra_demod.py}}} |
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| 68 | * use demodulator in realtime with a USRP1 SDR |
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| 69 | {{{src/demod/python/usrp2-tetra_demod.py}}} |
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| 70 | * use demodulator in realtime with a USRP2 SDR |
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| 71 | {{{src/demod/python/fcdp-tetra_demod.py}}} |
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| 72 | * use demodulator in realtime with a [wiki:Funcube_Dongle]. This may also be used with other Softrock-type receivers by downconverting the intermediate frequency of a radio scanner to the complex baseband. |
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| 73 | |||
| 74 | The output of the demodulator is a file containing one float value for each symbol, |
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| 75 | containing the phase shift (in units of pi/4) relative to the previous symbol. |
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| 76 | |||
| 77 | You can use the "float_to_bits" program to convert the float values to unpacked |
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| 78 | bits, i.e. 1-bit-per-byte |
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| 79 | |||
| 80 | |||
| 81 | == PHY/MAC layer == |
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| 82 | |||
| 83 | === library code === |
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| 84 | |||
| 85 | Specifically, it implements: |
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| 86 | |||
| 87 | {{{lower_mac/crc_simple.[ch]}}} |
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| 88 | * CRC16-CCITT (currently defunct/broken as we need it for |
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| 89 | non-octet-aligned bitfields) |
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| 90 | {{{lower_mac/tetra_conv_enc.[ch]}}} |
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| 91 | * 16-state Rate-Compatible Punctured Convolutional (RCPC) coder |
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| 92 | {{{lower_mac/tetra_interleave.[ch]}}} |
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| 93 | * Block interleaving (over a single block only) |
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| 94 | {{{lower_mac/tetra_rm3014.[ch]}}} |
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| 95 | * (30, 14) Reed-Muller code for the ACCH (broadcast block of |
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| 96 | each downlink burst) |
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| 97 | {{{lower_mac/tetra_scramb.[ch]}}} |
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| 98 | * Scrambling |
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| 99 | {{{lower_mac/viterbi*.[ch]}}} |
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| 100 | * Convolutional decoder for signalling and voice channels |
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| 101 | {{{phy/tetra_burst.[ch]}}} |
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| 102 | * Routines to encode continuous normal and sync bursts |
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| 103 | {{{phy/tetra_burst_sync.[ch]}}} |
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| 104 | |||
| 105 | |||
| 106 | === Receiver Program === |
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| 107 | |||
| 108 | The main receiver program {{{tetra-rx}}} expects an input file containing a |
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| 109 | stream of unpacked bits, i.e. 1-bit-per-byte. |
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| 110 | |||
| 111 | |||
| 112 | === Transmitter Program === |
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| 113 | |||
| 114 | The main program {{{conv_enc_test.c}}} generates a single continuous downlink sync |
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| 115 | burst (SB), contining: |
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| 116 | * a SYNC-PDU as block 1 |
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| 117 | * a ACCESS-ASSIGN PDU as broadcast block |
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| 118 | * a SYSINFO-PDU as block 2 |
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| 119 | |||
| 120 | Scrambling is set to 0 (no scrambling) for all elements of the burst. |
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| 121 | |||
| 122 | It does not actually modulate and/or transmit yet. |
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| 123 | |||
| 124 | |||
| 125 | == Quick example == |
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| 126 | |||
| 127 | assuming you have generated a file samples.cfile at a sample rate of 195.312kHz (100MHz/512 == USRP2 at decimation 512) |
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| 128 | |||
| 129 | {{{ |
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| 130 | ./src/demod/python/tetra-demod.py -i /tmp/samples.cfile -o /tmp/out.float -s 195312 -c 0 |
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| 131 | ./src/float_to_bits /tmp/out.float /tmp/out.bits |
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| 132 | ./src/tetra-rx /tmp/out.bits |
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| 133 | }}} |
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| 134 | |||
| 135 | For a complete list of local wiki pages, see TitleIndex. |
