kopia lustrzana https://github.com/kgoba/ft8_lib
Added candidate search for decoding
rodzic
b8fc6e92d8
commit
8397509c85
4
Makefile
4
Makefile
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@ -3,7 +3,7 @@ LDFLAGS = -lm
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.PHONY: run_tests all
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all: gen_ft8 wav_decode test
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all: gen_ft8 decode_ft8 test
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run_tests: test
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@./test
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@ -15,4 +15,4 @@ test: test.o ft8/encode.o ft8/pack.o ft8/text.o ft8/pack_v2.o ft8/encode_v2.o f
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$(CXX) $(LDFLAGS) -o $@ $^
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decode_ft8: decode_ft8.o fft/kiss_fftr.o fft/kiss_fft.o ft8/ldpc.o common/wave.o
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$(CXX) $(LDFLAGS) -o $@ $^
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$(CXX) $(LDFLAGS) -o $@ $^
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173
decode_ft8.cpp
173
decode_ft8.cpp
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@ -24,6 +24,159 @@ float hann_i(int i, int N) {
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}
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struct Candidate {
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int16_t score;
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uint16_t time_offset;
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uint16_t freq_offset;
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uint8_t time_alt;
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uint8_t freq_alt;
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};
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void find_candidates(int num_blocks, int num_bins, const uint8_t * power,
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int num_candidates, Candidate heap[num_candidates]) {
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// Costas 7x7 tone pattern
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const uint8_t ICOS7[] = { 2,5,6,0,4,1,3 };
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int heap_size = 0;
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for (int alt = 0; alt < 4; ++alt) {
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for (int i = 0; i < num_blocks - NN; ++i) {
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for (int j = 0; j < num_bins - 8; ++j) {
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int score = 0;
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// Compute score over bins 0-7, 36-43, 72-79
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for (int m = 0; m <= 72; m += 36) {
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for (int k = 0; k < 7; ++k) {
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int offset = ((i + k + m) * 4 + alt) * num_bins + j;
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// score += 8 * (int)power[i + k + m][alt][j + ICOS7[k]] -
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score += 8 * (int)power[offset + ICOS7[k]] -
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power[offset + 0] - power[offset + 1] -
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power[offset + 2] - power[offset + 3] -
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power[offset + 4] - power[offset + 5] -
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power[offset + 6] - power[offset + 7];
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}
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}
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// update the candidate list
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if (heap_size == num_candidates && score > heap[0].score) {
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//printf("Removing score %d\n", heap[0].score);
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// extract the least promising candidate
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heap[0] = heap[heap_size - 1];
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--heap_size;
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// heapify from the root down
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int current = 0;
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while (true) {
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int largest = current;
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int left = 2 * current + 1;
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int right = left + 1;
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if (left < heap_size && heap[left].score < heap[largest].score) {
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largest = left;
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}
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if (right < heap_size && heap[right].score < heap[largest].score) {
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largest = right;
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}
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if (largest == current) {
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break;
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}
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Candidate tmp = heap[largest];
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heap[largest] = heap[current];
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heap[current] = tmp;
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current = largest;
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}
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}
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if (heap_size < num_candidates) {
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// add the current candidate
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//printf("Adding score %d\n", score);
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heap[heap_size].score = score;
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heap[heap_size].time_offset = i;
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heap[heap_size].freq_offset = j;
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++heap_size;
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// heapify from the last node up
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int current = heap_size - 1;
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while (current > 0) {
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int parent = (current - 1) / 2;
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if (heap[current].score >= heap[parent].score) {
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break;
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}
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Candidate tmp = heap[parent];
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heap[parent] = heap[current];
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heap[current] = tmp;
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current = parent;
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}
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}
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}
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}
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}
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}
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void extract_power(const float *signal, int num_samples, int num_bins, uint8_t * power) {
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const int block_size = 2 * num_bins; // Average over 2 bins per FSK tone
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const int nfft = 2 * block_size; // We take FFT of two blocks, advancing by one
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const int num_blocks = (num_samples - (block_size/2) - block_size) / block_size;
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float window[nfft];
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for (int i = 0; i < nfft; ++i) {
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window[i] = hann_i(i, nfft);
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}
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size_t fft_work_size;
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kiss_fftr_alloc(nfft, 0, 0, &fft_work_size);
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printf("N_FFT = %d\n", nfft);
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printf("FFT work area = %lu\n", fft_work_size);
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void * fft_work = malloc(fft_work_size);
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kiss_fftr_cfg fft_cfg = kiss_fftr_alloc(nfft, 0, fft_work, &fft_work_size);
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int offset = 0;
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for (int i = 0; i < num_blocks; ++i) {
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// Loop over two possible time offsets (0 and block_size/2)
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for (int time_offset = 0; time_offset <= block_size/2; time_offset += block_size/2) {
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kiss_fft_scalar timedata[nfft];
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kiss_fft_cpx freqdata[nfft/2 + 1];
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float mag_db[nfft/2 + 1];
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// Extract windowed signal block
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for (int j = 0; j < nfft; ++j) {
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timedata[j] = window[j] * signal[i * block_size + j + time_offset];
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}
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kiss_fftr(fft_cfg, timedata, freqdata);
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// Compute log magnitude in decibels
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for (int j = 0; j < nfft/2 + 1; ++j) {
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float mag2 = (freqdata[j].i * freqdata[j].i + freqdata[j].r * freqdata[j].r);
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mag_db[j] = 10.0f * logf(1.0E-10f + mag2);
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}
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// Loop over two possible frequency bin offsets (for averaging)
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for (int freq_offset = 0; freq_offset <= 1; ++freq_offset) {
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for (int j = 0; j < num_bins; ++j) {
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float db1 = mag_db[j * 2 + freq_offset];
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float db2 = mag_db[j * 2 + freq_offset + 1];
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float db = (db1 + db2) / 2;
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// Scale decibels to unsigned 8-bit range
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int scaled = (int)(0.5f + 2 * (db + 100));
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power[offset] = (scaled < 0) ? 0 : ((scaled > 255) ? 255 : scaled);
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++offset;
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}
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}
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}
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}
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free(fft_work);
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}
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int main(int argc, char **argv) {
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// Expect one command-line argument
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if (argc < 2) {
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@ -42,22 +195,18 @@ int main(int argc, char **argv) {
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return -1;
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}
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//return 0;
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const int num_bins = (int)(sample_rate / 2 / 6.25);
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const int block_size = 2 * num_bins;
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const int num_blocks = (num_samples - (block_size/2) - block_size) / block_size;
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const int nfft = 2 * (int)(sample_rate / 6.25); // 2 bins per FSK tone
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uint8_t power[num_blocks * 4 * num_bins]; // [num_blocks][4][num_bins] ~ 200 KB
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size_t fft_work_size;
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kiss_fftr_alloc(nfft, 0, 0, &fft_work_size);
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extract_power(signal, num_samples, num_bins, power);
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printf("N_FFT = %d\n", nfft);
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printf("FFT work area = %lu\n", fft_work_size);
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const int num_candidates = 200;
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Candidate heap[num_candidates];
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void *fft_work = malloc(fft_work_size);
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kiss_fftr_cfg fft_cfg = kiss_fftr_alloc(nfft, 0, fft_work, &fft_work_size);
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kiss_fft_scalar timedata[nfft];
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kiss_fft_cpx freqdata[nfft/2 + 1];
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kiss_fftr(fft_cfg, timedata, freqdata);
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find_candidates(num_blocks, num_bins, power, num_candidates, heap);
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return 0;
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}
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