663 lines
25 KiB
C
663 lines
25 KiB
C
// Part of dump1090, a Mode S message decoder for RTLSDR devices.
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//
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// demod_2400.c: 2.4MHz Mode S demodulator.
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//
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// Copyright (c) 2014,2015 Oliver Jowett <oliver@mutability.co.uk>
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//
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// This file is free software: you may copy, redistribute and/or modify it
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// under the terms of the GNU General Public License as published by the
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// Free Software Foundation, either version 2 of the License, or (at your
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// option) any later version.
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//
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// This file is distributed in the hope that it will be useful, but
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// WITHOUT ANY WARRANTY; without even the implied warranty of
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// MERCHANTABILITY or FITNESS FOR A PARTICULAR PURPOSE. See the GNU
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// General Public License for more details.
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//
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// You should have received a copy of the GNU General Public License
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// along with this program. If not, see <http://www.gnu.org/licenses/>.
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#include "dump1090.h"
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// 2.4MHz sampling rate version
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//
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// When sampling at 2.4MHz we have exactly 6 samples per 5 symbols.
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// Each symbol is 500ns wide, each sample is 416.7ns wide
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//
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// We maintain a phase offset that is expressed in units of 1/5 of a sample i.e. 1/6 of a symbol, 83.333ns
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// Each symbol we process advances the phase offset by 6 i.e. 6/5 of a sample, 500ns
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//
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// The correlation functions below correlate a 1-0 pair of symbols (i.e. manchester encoded 1 bit)
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// starting at the given sample, and assuming that the symbol starts at a fixed 0-5 phase offset within
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// m[0]. They return a correlation value, generally interpreted as >0 = 1 bit, <0 = 0 bit
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// TODO check if there are better (or more balanced) correlation functions to use here
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// nb: the correlation functions sum to zero, so we do not need to adjust for the DC offset in the input signal
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// (adding any constant value to all of m[0..3] does not change the result)
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static inline int slice_phase0(uint16_t *m) {
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return 5 * m[0] - 3 * m[1] - 2 * m[2];
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}
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static inline int slice_phase1(uint16_t *m) {
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return 4 * m[0] - m[1] - 3 * m[2];
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}
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static inline int slice_phase2(uint16_t *m) {
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return 3 * m[0] + m[1] - 4 * m[2];
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}
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static inline int slice_phase3(uint16_t *m) {
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return 2 * m[0] + 3 * m[1] - 5 * m[2];
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}
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static inline int slice_phase4(uint16_t *m) {
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return m[0] + 5 * m[1] - 5 * m[2] - m[3];
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}
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//
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// Given 'mlen' magnitude samples in 'm', sampled at 2.4MHz,
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// try to demodulate some Mode S messages.
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//
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void demodulate2400(struct mag_buf *mag)
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{
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static struct modesMessage zeroMessage;
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struct modesMessage mm;
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unsigned char msg1[MODES_LONG_MSG_BYTES], msg2[MODES_LONG_MSG_BYTES], *msg;
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uint32_t j;
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unsigned char *bestmsg;
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int bestscore, bestphase;
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uint16_t *m = mag->data;
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uint32_t mlen = mag->length;
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uint64_t sum_scaled_signal_power = 0;
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msg = msg1;
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for (j = 0; j < mlen; j++) {
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uint16_t *preamble = &m[j];
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int high;
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uint32_t base_signal, base_noise;
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int try_phase;
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int msglen;
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// Look for a message starting at around sample 0 with phase offset 3..7
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// Ideal sample values for preambles with different phase
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// Xn is the first data symbol with phase offset N
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//
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// sample#: 0 1 2 3 4 5 6 7 8 9 0 1 2 3 4 5 6 7 8 9 0
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// phase 3: 2/4\0/5\1 0 0 0 0/5\1/3 3\0 0 0 0 0 0 X4
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// phase 4: 1/5\0/4\2 0 0 0 0/4\2 2/4\0 0 0 0 0 0 0 X0
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// phase 5: 0/5\1/3 3\0 0 0 0/3 3\1/5\0 0 0 0 0 0 0 X1
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// phase 6: 0/4\2 2/4\0 0 0 0 2/4\0/5\1 0 0 0 0 0 0 X2
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// phase 7: 0/3 3\1/5\0 0 0 0 1/5\0/4\2 0 0 0 0 0 0 X3
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//
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// quick check: we must have a rising edge 0->1 and a falling edge 12->13
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if (! (preamble[0] < preamble[1] && preamble[12] > preamble[13]) )
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continue;
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if (preamble[1] > preamble[2] && // 1
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preamble[2] < preamble[3] && preamble[3] > preamble[4] && // 3
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preamble[8] < preamble[9] && preamble[9] > preamble[10] && // 9
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preamble[10] < preamble[11]) { // 11-12
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// peaks at 1,3,9,11-12: phase 3
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high = (preamble[1] + preamble[3] + preamble[9] + preamble[11] + preamble[12]) / 4;
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base_signal = preamble[1] + preamble[3] + preamble[9];
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base_noise = preamble[5] + preamble[6] + preamble[7];
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} else if (preamble[1] > preamble[2] && // 1
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preamble[2] < preamble[3] && preamble[3] > preamble[4] && // 3
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preamble[8] < preamble[9] && preamble[9] > preamble[10] && // 9
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preamble[11] < preamble[12]) { // 12
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// peaks at 1,3,9,12: phase 4
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high = (preamble[1] + preamble[3] + preamble[9] + preamble[12]) / 4;
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base_signal = preamble[1] + preamble[3] + preamble[9] + preamble[12];
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base_noise = preamble[5] + preamble[6] + preamble[7] + preamble[8];
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} else if (preamble[1] > preamble[2] && // 1
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preamble[2] < preamble[3] && preamble[4] > preamble[5] && // 3-4
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preamble[8] < preamble[9] && preamble[10] > preamble[11] && // 9-10
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preamble[11] < preamble[12]) { // 12
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// peaks at 1,3-4,9-10,12: phase 5
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high = (preamble[1] + preamble[3] + preamble[4] + preamble[9] + preamble[10] + preamble[12]) / 4;
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base_signal = preamble[1] + preamble[12];
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base_noise = preamble[6] + preamble[7];
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} else if (preamble[1] > preamble[2] && // 1
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preamble[3] < preamble[4] && preamble[4] > preamble[5] && // 4
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preamble[9] < preamble[10] && preamble[10] > preamble[11] && // 10
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preamble[11] < preamble[12]) { // 12
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// peaks at 1,4,10,12: phase 6
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high = (preamble[1] + preamble[4] + preamble[10] + preamble[12]) / 4;
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base_signal = preamble[1] + preamble[4] + preamble[10] + preamble[12];
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base_noise = preamble[5] + preamble[6] + preamble[7] + preamble[8];
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} else if (preamble[2] > preamble[3] && // 1-2
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preamble[3] < preamble[4] && preamble[4] > preamble[5] && // 4
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preamble[9] < preamble[10] && preamble[10] > preamble[11] && // 10
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preamble[11] < preamble[12]) { // 12
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// peaks at 1-2,4,10,12: phase 7
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high = (preamble[1] + preamble[2] + preamble[4] + preamble[10] + preamble[12]) / 4;
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base_signal = preamble[4] + preamble[10] + preamble[12];
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base_noise = preamble[6] + preamble[7] + preamble[8];
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} else {
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// no suitable peaks
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continue;
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}
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// Check for enough signal
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if (base_signal * 2 < 3 * base_noise) // about 3.5dB SNR
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continue;
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// Check that the "quiet" bits 6,7,15,16,17 are actually quiet
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if (preamble[5] >= high ||
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preamble[6] >= high ||
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preamble[7] >= high ||
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preamble[8] >= high ||
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preamble[14] >= high ||
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preamble[15] >= high ||
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preamble[16] >= high ||
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preamble[17] >= high ||
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preamble[18] >= high) {
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continue;
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}
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// try all phases
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Modes.stats_current.demod_preambles++;
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bestmsg = NULL; bestscore = -2; bestphase = -1;
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for (try_phase = 4; try_phase <= 8; ++try_phase) {
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uint16_t *pPtr;
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int phase, i, score, bytelen;
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// Decode all the next 112 bits, regardless of the actual message
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// size. We'll check the actual message type later
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pPtr = &m[j+19] + (try_phase/5);
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phase = try_phase % 5;
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bytelen = MODES_LONG_MSG_BYTES;
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for (i = 0; i < bytelen; ++i) {
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uint8_t theByte = 0;
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switch (phase) {
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case 0:
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theByte =
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(slice_phase0(pPtr) > 0 ? 0x80 : 0) |
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(slice_phase2(pPtr+2) > 0 ? 0x40 : 0) |
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(slice_phase4(pPtr+4) > 0 ? 0x20 : 0) |
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(slice_phase1(pPtr+7) > 0 ? 0x10 : 0) |
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(slice_phase3(pPtr+9) > 0 ? 0x08 : 0) |
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(slice_phase0(pPtr+12) > 0 ? 0x04 : 0) |
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(slice_phase2(pPtr+14) > 0 ? 0x02 : 0) |
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(slice_phase4(pPtr+16) > 0 ? 0x01 : 0);
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phase = 1;
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pPtr += 19;
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break;
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case 1:
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theByte =
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(slice_phase1(pPtr) > 0 ? 0x80 : 0) |
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(slice_phase3(pPtr+2) > 0 ? 0x40 : 0) |
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(slice_phase0(pPtr+5) > 0 ? 0x20 : 0) |
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(slice_phase2(pPtr+7) > 0 ? 0x10 : 0) |
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(slice_phase4(pPtr+9) > 0 ? 0x08 : 0) |
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(slice_phase1(pPtr+12) > 0 ? 0x04 : 0) |
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(slice_phase3(pPtr+14) > 0 ? 0x02 : 0) |
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(slice_phase0(pPtr+17) > 0 ? 0x01 : 0);
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phase = 2;
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pPtr += 19;
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break;
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case 2:
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theByte =
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(slice_phase2(pPtr) > 0 ? 0x80 : 0) |
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(slice_phase4(pPtr+2) > 0 ? 0x40 : 0) |
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(slice_phase1(pPtr+5) > 0 ? 0x20 : 0) |
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(slice_phase3(pPtr+7) > 0 ? 0x10 : 0) |
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(slice_phase0(pPtr+10) > 0 ? 0x08 : 0) |
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(slice_phase2(pPtr+12) > 0 ? 0x04 : 0) |
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(slice_phase4(pPtr+14) > 0 ? 0x02 : 0) |
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(slice_phase1(pPtr+17) > 0 ? 0x01 : 0);
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phase = 3;
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pPtr += 19;
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break;
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case 3:
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theByte =
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(slice_phase3(pPtr) > 0 ? 0x80 : 0) |
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(slice_phase0(pPtr+3) > 0 ? 0x40 : 0) |
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(slice_phase2(pPtr+5) > 0 ? 0x20 : 0) |
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(slice_phase4(pPtr+7) > 0 ? 0x10 : 0) |
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(slice_phase1(pPtr+10) > 0 ? 0x08 : 0) |
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(slice_phase3(pPtr+12) > 0 ? 0x04 : 0) |
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(slice_phase0(pPtr+15) > 0 ? 0x02 : 0) |
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(slice_phase2(pPtr+17) > 0 ? 0x01 : 0);
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phase = 4;
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pPtr += 19;
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break;
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case 4:
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theByte =
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(slice_phase4(pPtr) > 0 ? 0x80 : 0) |
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(slice_phase1(pPtr+3) > 0 ? 0x40 : 0) |
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(slice_phase3(pPtr+5) > 0 ? 0x20 : 0) |
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(slice_phase0(pPtr+8) > 0 ? 0x10 : 0) |
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(slice_phase2(pPtr+10) > 0 ? 0x08 : 0) |
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(slice_phase4(pPtr+12) > 0 ? 0x04 : 0) |
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(slice_phase1(pPtr+15) > 0 ? 0x02 : 0) |
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(slice_phase3(pPtr+17) > 0 ? 0x01 : 0);
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phase = 0;
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pPtr += 20;
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break;
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}
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msg[i] = theByte;
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if (i == 0) {
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switch (msg[0] >> 3) {
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case 0: case 4: case 5: case 11:
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bytelen = MODES_SHORT_MSG_BYTES; break;
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case 16: case 17: case 18: case 20: case 21: case 24:
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break;
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default:
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bytelen = 1; // unknown DF, give up immediately
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break;
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}
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}
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}
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// Score the mode S message and see if it's any good.
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score = scoreModesMessage(msg, i*8);
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if (score > bestscore) {
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// new high score!
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bestmsg = msg;
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bestscore = score;
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bestphase = try_phase;
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// swap to using the other buffer so we don't clobber our demodulated data
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// (if we find a better result then we'll swap back, but that's OK because
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// we no longer need this copy if we found a better one)
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msg = (msg == msg1) ? msg2 : msg1;
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}
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}
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// Do we have a candidate?
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if (bestscore < 0) {
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if (bestscore == -1)
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Modes.stats_current.demod_rejected_unknown_icao++;
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else
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Modes.stats_current.demod_rejected_bad++;
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continue; // nope.
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}
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msglen = modesMessageLenByType(bestmsg[0] >> 3);
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// Set initial mm structure details
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mm = zeroMessage;
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mm.timestampMsg = mag->sampleTimestamp + (j*5) + bestphase;
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// compute message receive time as block-start-time + difference in the 12MHz clock
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mm.sysTimestampMsg = mag->sysTimestamp; // start of block time
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mm.sysTimestampMsg.tv_nsec += receiveclock_ns_elapsed(mag->sampleTimestamp, mm.timestampMsg);
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normalize_timespec(&mm.sysTimestampMsg);
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mm.score = bestscore;
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// Decode the received message
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{
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int result = decodeModesMessage(&mm, bestmsg);
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if (result < 0) {
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if (result == -1)
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Modes.stats_current.demod_rejected_unknown_icao++;
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else
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Modes.stats_current.demod_rejected_bad++;
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continue;
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} else {
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Modes.stats_current.demod_accepted[mm.correctedbits]++;
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}
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}
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// measure signal power
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{
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double signal_power;
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uint64_t scaled_signal_power = 0;
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int signal_len = msglen*12/5;
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int k;
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for (k = 0; k < signal_len; ++k) {
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uint32_t mag = m[j+19+k];
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scaled_signal_power += mag * mag;
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}
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signal_power = scaled_signal_power / 65535.0 / 65535.0;
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mm.signalLevel = signal_power / signal_len;
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Modes.stats_current.signal_power_sum += signal_power;
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Modes.stats_current.signal_power_count += signal_len;
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sum_scaled_signal_power += scaled_signal_power;
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if (mm.signalLevel > Modes.stats_current.peak_signal_power)
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Modes.stats_current.peak_signal_power = mm.signalLevel;
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if (mm.signalLevel > 0.50119)
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Modes.stats_current.strong_signal_count++; // signal power above -3dBFS
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}
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// Skip over the message:
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// (we actually skip to 8 bits before the end of the message,
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// because we can often decode two messages that *almost* collide,
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// where the preamble of the second message clobbered the last
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// few bits of the first message, but the message bits didn't
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// overlap)
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j += msglen*12/5;
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// Pass data to the next layer
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useModesMessage(&mm);
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}
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/* update noise power */
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{
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double sum_signal_power = sum_scaled_signal_power / 65535.0 / 65535.0;
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Modes.stats_current.noise_power_sum += (mag->total_power - sum_signal_power);
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Modes.stats_current.noise_power_count += mag->length;
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}
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}
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//////////
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////////// MODE A/C
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//////////
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// Mode A/C bits are 1.45us wide, consisting of 0.45us on and 1.0us off
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// We track this in terms of a (virtual) 60MHz clock, which is the lowest common multiple
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// of the bit frequency and the 2.4MHz sampling frequency
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//
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// 0.45us = 27 cycles }
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// 1.00us = 60 cycles } one bit period = 1.45us = 87 cycles
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//
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// one 2.4MHz sample = 25 cycles
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void demodulate2400AC(struct mag_buf *mag)
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{
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struct modesMessage mm;
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uint16_t *m = mag->data;
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uint32_t mlen = mag->length;
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unsigned f1_sample;
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memset(&mm, 0, sizeof(mm));
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for (f1_sample = 1; f1_sample < mlen; ++f1_sample) {
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// Mode A/C messages should match this bit sequence:
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// bit # value
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// -1 0 quiet zone
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// 0 1 framing pulse (F1)
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// 1 C1
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// 2 A1
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// 3 C2
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// 4 A2
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// 5 C4
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// 6 A4
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// 7 0 quiet zone (X1)
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// 8 B1
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// 9 D1
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// 10 B2
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// 11 D2
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// 12 B4
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// 13 D4
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// 14 1 framing pulse (F2)
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// 15 0 quiet zone (X2)
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// 16 0 quiet zone (X3)
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// 17 SPI
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// 18 0 quiet zone (X4)
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// 19 0 quiet zone (X5)
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// 20 0 quiet zone (X6)
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// 21 0 quiet zone (X7)
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// 22 0 quiet zone (X8)
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// 23 0 quiet zone (X9)
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// Look for a F1 and F2 pair,
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// with F1 starting at offset f1_sample.
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// the first framing pulse covers 3.5 samples:
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//
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// |----| |----|
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// | F1 |________| C1 |_
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//
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// | 0 | 1 | 2 | 3 | 4 |
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//
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// and there is some unknown phase offset of the
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// leading edge e.g.:
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//
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// |----| |----|
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// __| F1 |________| C1 |_
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//
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// | 0 | 1 | 2 | 3 | 4 |
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//
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// in theory the "on" period can straddle 3 samples
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// but it's not a big deal as at most 4% of the power
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// is in the third sample.
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if (!(m[f1_sample-1] < m[f1_sample+0]))
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continue; // not a rising edge
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|
if (m[f1_sample+2] > m[f1_sample+0] || m[f1_sample+2] > m[f1_sample+1])
|
|
continue; // quiet part of bit wasn't sufficiently quiet
|
|
|
|
unsigned f1_noise = (m[f1_sample-1] + m[f1_sample+2]) / 2;
|
|
unsigned f1_signal = (m[f1_sample+0] + m[f1_sample+1]) / 2;
|
|
|
|
if (f1_noise * 4 > f1_signal) {
|
|
// require 12dB SNR
|
|
continue;
|
|
}
|
|
|
|
// estimate initial clock phase based on the amount of power
|
|
// that ended up in the second sample
|
|
unsigned f1_clock = 25 * f1_sample;
|
|
if (m[f1_sample+1] > f1_noise) {
|
|
f1_clock += 25 * (m[f1_sample+1] - f1_noise) / (2*(f1_signal - f1_noise));
|
|
}
|
|
|
|
// same again for F2
|
|
// F2 is 20.3us / 14 bit periods after F1
|
|
|
|
unsigned f2_clock = f1_clock + (87 * 14);
|
|
unsigned f2_sample = f2_clock / 25;
|
|
|
|
if (!(m[f2_sample-1] < m[f2_sample+0]))
|
|
continue;
|
|
|
|
if (m[f2_sample+2] > m[f2_sample+0] || m[f2_sample+2] > m[f2_sample+1])
|
|
continue; // quiet part of bit wasn't sufficiently quiet
|
|
|
|
unsigned f2_noise = (m[f2_sample-1] + m[f2_sample+2]) / 2;
|
|
unsigned f2_signal = (m[f2_sample+0] + m[f2_sample+1]) / 2;
|
|
|
|
if (f2_noise * 4 > f2_signal) {
|
|
// require 12dB SNR
|
|
continue;
|
|
}
|
|
|
|
unsigned f1f2_signal = (f1_signal + f2_signal) / 2;
|
|
|
|
// look at X1, X2, X3 which should be quiet
|
|
// (sample 0 may have part of the previous bit, but
|
|
// it always covers the quiet part of it)
|
|
unsigned x1_clock = f1_clock + (87 * 7);
|
|
unsigned x1_sample = x1_clock / 25;
|
|
unsigned x1_noise = (m[x1_sample + 0] + m[x1_sample + 1] + m[x1_sample + 2]) / 3;
|
|
if (x1_noise * 4 >= f1f2_signal)
|
|
continue;
|
|
|
|
unsigned x2_clock = f1_clock + (87 * 15);
|
|
unsigned x2_sample = x2_clock / 25;
|
|
unsigned x2_noise = (m[x2_sample + 0] + m[x2_sample + 1] + m[x2_sample + 2]) / 3;
|
|
if (x2_noise * 4 >= f1f2_signal)
|
|
continue;
|
|
|
|
unsigned x3_clock = f1_clock + (87 * 16);
|
|
unsigned x3_sample = x3_clock / 25;
|
|
unsigned x3_noise = (m[x3_sample + 0] + m[x3_sample + 1] + m[x3_sample + 2]) / 3;
|
|
if (x3_noise * 4 >= f1f2_signal)
|
|
continue;
|
|
|
|
unsigned x1x2x3_noise = (x1_noise + x2_noise + x3_noise) / 3;
|
|
if (x1x2x3_noise * 4 >= f1f2_signal) // require 12dB separation
|
|
continue;
|
|
|
|
// ----- F1/F2 average signal
|
|
// ^
|
|
// | at least 3dB
|
|
// v
|
|
// ----- minimum signal level we accept as "on"
|
|
// ^
|
|
// | 3dB
|
|
// v
|
|
// ---- midpoint between F1/F2 and X1/X2/X3
|
|
// ^
|
|
// | 3dB
|
|
// v
|
|
// ----- maximum signal level we accept as "off"
|
|
// ^
|
|
// | at least 3dB
|
|
// v
|
|
// ----- X1/X2/X3 average noise
|
|
|
|
float midpoint = sqrtf(x1x2x3_noise * f1f2_signal); // so that signal/midpoint == midpoint/noise
|
|
unsigned quiet_threshold = (unsigned) midpoint;
|
|
unsigned noise_threshold = (unsigned) (midpoint * 0.707107 + 0.5); // -3dB from midpoint
|
|
unsigned signal_threshold = (unsigned) (midpoint * 1.414214 + 0.5); // +3dB from midpoint
|
|
|
|
#if 0
|
|
fprintf(stderr, "f1f2 %u x1x2x3 %u midpoint %.0f noise_threshold %u signal_threshold %u\n",
|
|
f1f2_signal, x1x2x3_noise, midpoint, noise_threshold, signal_threshold);
|
|
|
|
fprintf(stderr, "f1 %u f2 %u x1 %u x2 %u x3 %u\n",
|
|
f1_signal, f2_signal, x1_noise, x2_noise, x3_noise);
|
|
#endif
|
|
|
|
// recheck F/X bits just in case
|
|
if (f1_signal < signal_threshold)
|
|
continue;
|
|
if (f2_signal < signal_threshold)
|
|
continue;
|
|
if (x1_noise > noise_threshold)
|
|
continue;
|
|
if (x2_noise > noise_threshold)
|
|
continue;
|
|
if (x3_noise > noise_threshold)
|
|
continue;
|
|
|
|
// Looks like a real signal. Demodulate all the bits.
|
|
unsigned noisy_bits = 0;
|
|
unsigned bits = 0;
|
|
unsigned bit;
|
|
unsigned clock;
|
|
for (bit = 0, clock = f1_clock; bit < 24; ++bit, clock += 87) {
|
|
unsigned sample = clock / 25;
|
|
|
|
bits <<= 1;
|
|
noisy_bits <<= 1;
|
|
|
|
// check for excessive noise in the quiet period
|
|
if (m[sample+2] >= quiet_threshold) {
|
|
//fprintf(stderr, "bit %u was not quiet (%u > %u)\n", bit, m[sample+2], quiet_threshold);
|
|
noisy_bits |= 1;
|
|
continue;
|
|
}
|
|
|
|
// decide if this bit is on or off
|
|
unsigned bit_signal = (m[sample+0] + m[sample+1]) / 2;
|
|
if (bit_signal >= signal_threshold) {
|
|
bits |= 1;
|
|
} else if (bit_signal > noise_threshold) {
|
|
/* not certain about this bit */
|
|
//fprintf(stderr, "bit %u was uncertain (%u < %u < %u)\n", bit, noise_threshold, bit_signal, signal_threshold);
|
|
noisy_bits |= 1;
|
|
} else {
|
|
/* this bit is off */
|
|
}
|
|
}
|
|
|
|
#if 0
|
|
fprintf(stderr, "bits: %06X noisy: %06X\n", bits, noisy_bits);
|
|
|
|
unsigned j, sample;
|
|
static const char *names[24] = {
|
|
"F1", "C1", "A1", "C2",
|
|
"A2", "C4", "A4", "X1",
|
|
"B1", "D1", "B2", "D2",
|
|
"B4", "D4", "F2", "X2",
|
|
"X3", "SPI", "X4", "X5",
|
|
"X6", "X7", "X8", "X9"
|
|
};
|
|
|
|
fprintf(stderr, "-1 ... %6u\n", m[f1_sample-1]);
|
|
for (j = 0; j < 24; ++j) {
|
|
clock = f1_clock + 87 * j;
|
|
sample = clock / 25;
|
|
fprintf(stderr, "%2u %-3s %6u %6u %6u %6u ", j, names[j], m[sample+0], m[sample+1], m[sample+2], m[sample+3]);
|
|
if ((m[sample+0] + m[sample+1])/2 >= signal_threshold) {
|
|
fprintf(stderr, "ON\n");
|
|
} else if ((m[sample+0] + m[sample+1])/2 <= noise_threshold) {
|
|
fprintf(stderr, "OFF\n");
|
|
} else {
|
|
fprintf(stderr, "UNCERTAIN\n");
|
|
}
|
|
}
|
|
#endif
|
|
|
|
if (noisy_bits) {
|
|
/* XX debug */
|
|
continue;
|
|
}
|
|
|
|
// framing bits must be on
|
|
if ((bits & 0x800200) != 0x800200) {
|
|
continue;
|
|
}
|
|
|
|
// quiet bits must be off
|
|
if ((bits & 0x0101BF) != 0) {
|
|
continue;
|
|
}
|
|
|
|
// Convert to the form that we use elsewhere:
|
|
// 00 A4 A2 A1 00 B4 B2 B1 SPI C4 C2 C1 00 D4 D2 D1
|
|
unsigned modeac =
|
|
((bits & 0x400000) ? 0x0010 : 0) | // C1
|
|
((bits & 0x200000) ? 0x1000 : 0) | // A1
|
|
((bits & 0x100000) ? 0x0020 : 0) | // C2
|
|
((bits & 0x080000) ? 0x2000 : 0) | // A2
|
|
((bits & 0x040000) ? 0x0040 : 0) | // C4
|
|
((bits & 0x020000) ? 0x4000 : 0) | // A4
|
|
((bits & 0x008000) ? 0x0100 : 0) | // B1
|
|
((bits & 0x004000) ? 0x0001 : 0) | // D1
|
|
((bits & 0x002000) ? 0x0200 : 0) | // B2
|
|
((bits & 0x001000) ? 0x0002 : 0) | // D2
|
|
((bits & 0x000800) ? 0x0400 : 0) | // B4
|
|
((bits & 0x000400) ? 0x0004 : 0) | // D4
|
|
((bits & 0x000040) ? 0x0080 : 0); // SPI
|
|
|
|
// This message looks good, submit it
|
|
|
|
// compute message receive time as block-start-time + difference in the 12MHz clock
|
|
mm.timestampMsg = mag->sampleTimestamp + f1_clock / 5; // 60MHz -> 12MHz
|
|
mm.sysTimestampMsg = mag->sysTimestamp; // start of block time
|
|
mm.sysTimestampMsg.tv_nsec += receiveclock_ns_elapsed(mag->sampleTimestamp, mm.timestampMsg);
|
|
normalize_timespec(&mm.sysTimestampMsg);
|
|
|
|
decodeModeAMessage(&mm, modeac);
|
|
|
|
// Pass data to the next layer
|
|
useModesMessage(&mm);
|
|
|
|
f1_sample += (24*87 / 25);
|
|
Modes.stats_current.demod_modeac++;
|
|
}
|
|
}
|