mirror of
https://github.com/AlexandreRouma/SDRPlusPlus.git
synced 2025-01-15 04:37:11 +01:00
729 lines
26 KiB
C++
729 lines
26 KiB
C++
#pragma once
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#include <dsp/block.h>
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#include <volk/volk.h>
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#include <dsp/filter.h>
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#include <dsp/processing.h>
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#include <dsp/routing.h>
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#include <spdlog/spdlog.h>
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#include <dsp/pll.h>
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#include <dsp/clock_recovery.h>
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#include <dsp/math.h>
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#include <dsp/convertion.h>
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#include <dsp/audio.h>
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#include <dsp/stereo_fm.h>
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#define FAST_ATAN2_COEF1 FL_M_PI / 4.0f
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#define FAST_ATAN2_COEF2 3.0f * FAST_ATAN2_COEF1
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inline float fast_arctan2(float y, float x) {
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float abs_y = fabsf(y);
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float r, angle;
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if (x == 0.0f && y == 0.0f) { return 0.0f; }
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if (x>=0.0f) {
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r = (x - abs_y) / (x + abs_y);
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angle = FAST_ATAN2_COEF1 - FAST_ATAN2_COEF1 * r;
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}
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else {
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r = (x + abs_y) / (abs_y - x);
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angle = FAST_ATAN2_COEF2 - FAST_ATAN2_COEF1 * r;
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}
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if (y < 0.0f) {
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return -angle;
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}
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return angle;
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}
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namespace dsp {
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class FloatFMDemod : public generic_block<FloatFMDemod> {
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public:
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FloatFMDemod() {}
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FloatFMDemod(stream<complex_t>* in, float sampleRate, float deviation) { init(in, sampleRate, deviation); }
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void init(stream<complex_t>* in, float sampleRate, float deviation) {
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_in = in;
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_sampleRate = sampleRate;
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_deviation = deviation;
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phasorSpeed = (2 * FL_M_PI) / (_sampleRate / _deviation);
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generic_block<FloatFMDemod>::registerInput(_in);
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generic_block<FloatFMDemod>::registerOutput(&out);
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generic_block<FloatFMDemod>::_block_init = true;
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}
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void setInput(stream<complex_t>* in) {
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assert(generic_block<FloatFMDemod>::_block_init);
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std::lock_guard<std::mutex> lck(generic_block<FloatFMDemod>::ctrlMtx);
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generic_block<FloatFMDemod>::tempStop();
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generic_block<FloatFMDemod>::unregisterInput(_in);
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_in = in;
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generic_block<FloatFMDemod>::registerInput(_in);
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generic_block<FloatFMDemod>::tempStart();
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}
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void setSampleRate(float sampleRate) {
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assert(generic_block<FloatFMDemod>::_block_init);
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std::lock_guard<std::mutex> lck(generic_block<FloatFMDemod>::ctrlMtx);
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generic_block<FloatFMDemod>::tempStop();
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_sampleRate = sampleRate;
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phasorSpeed = (2 * FL_M_PI) / (_sampleRate / _deviation);
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generic_block<FloatFMDemod>::tempStart();
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}
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float getSampleRate() {
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assert(generic_block<FloatFMDemod>::_block_init);
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return _sampleRate;
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}
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void setDeviation(float deviation) {
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assert(generic_block<FloatFMDemod>::_block_init);
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std::lock_guard<std::mutex> lck(generic_block<FloatFMDemod>::ctrlMtx);
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generic_block<FloatFMDemod>::tempStop();
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_deviation = deviation;
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phasorSpeed = (2 * FL_M_PI) / (_sampleRate / _deviation);
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generic_block<FloatFMDemod>::tempStart();
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}
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float getDeviation() {
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assert(generic_block<FloatFMDemod>::_block_init);
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return _deviation;
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}
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int run() {
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int count = _in->read();
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if (count < 0) { return -1; }
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// This is somehow faster than volk...
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float diff, currentPhase;
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for (int i = 0; i < count; i++) {
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currentPhase = fast_arctan2(_in->readBuf[i].im, _in->readBuf[i].re);
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diff = currentPhase - phase;
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if (diff > 3.1415926535f) { diff -= 2 * 3.1415926535f; }
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else if (diff <= -3.1415926535f) { diff += 2 * 3.1415926535f; }
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out.writeBuf[i] = diff / phasorSpeed;
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phase = currentPhase;
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}
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_in->flush();
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if (!out.swap(count)) { return -1; }
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return count;
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}
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stream<float> out;
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private:
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float phase = 0;
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float phasorSpeed, _sampleRate, _deviation;
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stream<complex_t>* _in;
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};
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class FMDemod : public generic_block<FMDemod> {
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public:
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FMDemod() {}
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FMDemod(stream<complex_t>* in, float sampleRate, float deviation) { init(in, sampleRate, deviation); }
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void init(stream<complex_t>* in, float sampleRate, float deviation) {
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_in = in;
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_sampleRate = sampleRate;
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_deviation = deviation;
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phasorSpeed = (2 * FL_M_PI) / (_sampleRate / _deviation);
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generic_block<FMDemod>::registerInput(_in);
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generic_block<FMDemod>::registerOutput(&out);
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generic_block<FMDemod>::_block_init = true;
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}
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void setInput(stream<complex_t>* in) {
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assert(generic_block<FMDemod>::_block_init);
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std::lock_guard<std::mutex> lck(generic_block<FMDemod>::ctrlMtx);
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generic_block<FMDemod>::tempStop();
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generic_block<FMDemod>::unregisterInput(_in);
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_in = in;
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generic_block<FMDemod>::registerInput(_in);
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generic_block<FMDemod>::tempStart();
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}
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void setSampleRate(float sampleRate) {
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assert(generic_block<FMDemod>::_block_init);
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std::lock_guard<std::mutex> lck(generic_block<FMDemod>::ctrlMtx);
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generic_block<FMDemod>::tempStop();
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_sampleRate = sampleRate;
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phasorSpeed = (2 * FL_M_PI) / (_sampleRate / _deviation);
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generic_block<FMDemod>::tempStart();
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}
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float getSampleRate() {
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assert(generic_block<FMDemod>::_block_init);
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return _sampleRate;
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}
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void setDeviation(float deviation) {
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assert(generic_block<FMDemod>::_block_init);
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_deviation = deviation;
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phasorSpeed = (2 * FL_M_PI) / (_sampleRate / _deviation);
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}
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float getDeviation() {
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assert(generic_block<FMDemod>::_block_init);
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return _deviation;
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}
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int run() {
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int count = _in->read();
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if (count < 0) { return -1; }
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// This is somehow faster than volk...
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float diff, currentPhase;
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for (int i = 0; i < count; i++) {
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currentPhase = fast_arctan2(_in->readBuf[i].im, _in->readBuf[i].re);
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diff = currentPhase - phase;
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if (diff > 3.1415926535f) { diff -= 2 * 3.1415926535f; }
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else if (diff <= -3.1415926535f) { diff += 2 * 3.1415926535f; }
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out.writeBuf[i].l = diff / phasorSpeed;
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out.writeBuf[i].r = diff / phasorSpeed;
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phase = currentPhase;
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}
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_in->flush();
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if (!out.swap(count)) { return -1; }
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return count;
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}
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stream<stereo_t> out;
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private:
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float phase = 0;
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float phasorSpeed, _sampleRate, _deviation;
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stream<complex_t>* _in;
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};
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class AMDemod : public generic_block<AMDemod> {
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public:
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AMDemod() {}
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AMDemod(stream<complex_t>* in) { init(in); }
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void init(stream<complex_t>* in) {
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_in = in;
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generic_block<AMDemod>::registerInput(_in);
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generic_block<AMDemod>::registerOutput(&out);
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generic_block<AMDemod>::_block_init = true;
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}
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void setInput(stream<complex_t>* in) {
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assert(generic_block<AMDemod>::_block_init);
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std::lock_guard<std::mutex> lck(generic_block<AMDemod>::ctrlMtx);
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generic_block<AMDemod>::tempStop();
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generic_block<AMDemod>::unregisterInput(_in);
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_in = in;
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generic_block<AMDemod>::registerInput(_in);
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generic_block<AMDemod>::tempStart();
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}
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int run() {
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int count = _in->read();
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if (count < 0) { return -1; }
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volk_32fc_magnitude_32f(out.writeBuf, (lv_32fc_t*)_in->readBuf, count);
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_in->flush();
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for (int i = 0; i < count; i++) {
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out.writeBuf[i] -= avg;
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avg += out.writeBuf[i] * 10e-4;
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}
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if (!out.swap(count)) { return -1; }
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return count;
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}
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stream<float> out;
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private:
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stream<complex_t>* _in;
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float avg = 0;
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};
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class SSBDemod : public generic_block<SSBDemod> {
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public:
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SSBDemod() {}
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SSBDemod(stream<complex_t>* in, float sampleRate, float bandWidth, int mode) { init(in, sampleRate, bandWidth, mode); }
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~SSBDemod() {
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if (!generic_block<SSBDemod>::_block_init) { return; }
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generic_block<SSBDemod>::stop();
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delete[] buffer;
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generic_block<SSBDemod>::_block_init = false;
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}
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enum {
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MODE_USB,
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MODE_LSB,
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MODE_DSB
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};
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void init(stream<complex_t>* in, float sampleRate, float bandWidth, int mode) {
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_in = in;
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_sampleRate = sampleRate;
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_bandWidth = bandWidth;
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_mode = mode;
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phase = lv_cmake(1.0f, 0.0f);
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switch (_mode) {
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case MODE_USB:
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phaseDelta = lv_cmake(std::cos((_bandWidth / _sampleRate) * FL_M_PI), std::sin((_bandWidth / _sampleRate) * FL_M_PI));
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break;
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case MODE_LSB:
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phaseDelta = lv_cmake(std::cos(-(_bandWidth / _sampleRate) * FL_M_PI), std::sin(-(_bandWidth / _sampleRate) * FL_M_PI));
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break;
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case MODE_DSB:
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phaseDelta = lv_cmake(1.0f, 0.0f);
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break;
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}
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buffer = new lv_32fc_t[STREAM_BUFFER_SIZE];
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generic_block<SSBDemod>::registerInput(_in);
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generic_block<SSBDemod>::registerOutput(&out);
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generic_block<SSBDemod>::_block_init = true;
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}
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void setInput(stream<complex_t>* in) {
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assert(generic_block<SSBDemod>::_block_init);
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std::lock_guard<std::mutex> lck(generic_block<SSBDemod>::ctrlMtx);
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generic_block<SSBDemod>::tempStop();
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generic_block<SSBDemod>::unregisterInput(_in);
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_in = in;
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generic_block<SSBDemod>::registerInput(_in);
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generic_block<SSBDemod>::tempStart();
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}
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void setSampleRate(float sampleRate) {
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assert(generic_block<SSBDemod>::_block_init);
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_sampleRate = sampleRate;
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switch (_mode) {
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case MODE_USB:
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phaseDelta = lv_cmake(std::cos((_bandWidth / _sampleRate) * FL_M_PI), std::sin((_bandWidth / _sampleRate) * FL_M_PI));
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break;
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case MODE_LSB:
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phaseDelta = lv_cmake(std::cos(-(_bandWidth / _sampleRate) * FL_M_PI), std::sin(-(_bandWidth / _sampleRate) * FL_M_PI));
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break;
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case MODE_DSB:
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phaseDelta = lv_cmake(1.0f, 0.0f);
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break;
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}
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}
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void setBandWidth(float bandWidth) {
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assert(generic_block<SSBDemod>::_block_init);
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_bandWidth = bandWidth;
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switch (_mode) {
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case MODE_USB:
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phaseDelta = lv_cmake(std::cos((_bandWidth / _sampleRate) * FL_M_PI), std::sin((_bandWidth / _sampleRate) * FL_M_PI));
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break;
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case MODE_LSB:
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phaseDelta = lv_cmake(std::cos(-(_bandWidth / _sampleRate) * FL_M_PI), std::sin(-(_bandWidth / _sampleRate) * FL_M_PI));
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break;
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case MODE_DSB:
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phaseDelta = lv_cmake(1.0f, 0.0f);
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break;
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}
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}
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void setMode(int mode) {
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assert(generic_block<SSBDemod>::_block_init);
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_mode = mode;
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switch (_mode) {
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case MODE_USB:
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phaseDelta = lv_cmake(std::cos((_bandWidth / _sampleRate) * FL_M_PI), std::sin((_bandWidth / _sampleRate) * FL_M_PI));
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break;
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case MODE_LSB:
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phaseDelta = lv_cmake(std::cos(-(_bandWidth / _sampleRate) * FL_M_PI), std::sin(-(_bandWidth / _sampleRate) * FL_M_PI));
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break;
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case MODE_DSB:
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phaseDelta = lv_cmake(1.0f, 0.0f);
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break;
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}
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}
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int run() {
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int count = _in->read();
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if (count < 0) { return -1; }
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volk_32fc_s32fc_x2_rotator_32fc(buffer, (lv_32fc_t*)_in->readBuf, phaseDelta, &phase, count);
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volk_32fc_deinterleave_real_32f(out.writeBuf, buffer, count);
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_in->flush();
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if (!out.swap(count)) { return -1; }
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return count;
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}
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stream<float> out;
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private:
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int _mode;
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float _sampleRate, _bandWidth;
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stream<complex_t>* _in;
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lv_32fc_t* buffer;
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lv_32fc_t phase;
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lv_32fc_t phaseDelta;
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};
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class MSKDemod : public generic_hier_block<MSKDemod> {
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public:
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MSKDemod() {}
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MSKDemod(stream<complex_t>* input, float sampleRate, float deviation, float baudRate, float omegaGain = (0.01*0.01) / 4, float muGain = 0.01f, float omegaRelLimit = 0.005f) {
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init(input, sampleRate, deviation, baudRate, omegaGain, muGain, omegaRelLimit);
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}
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void init(stream<complex_t>* input, float sampleRate, float deviation, float baudRate, float omegaGain = (0.01*0.01) / 4, float muGain = 0.01f, float omegaRelLimit = 0.005f) {
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_sampleRate = sampleRate;
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_deviation = deviation;
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_baudRate = baudRate;
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_omegaGain = omegaGain;
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_muGain = muGain;
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_omegaRelLimit = omegaRelLimit;
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demod.init(input, _sampleRate, _deviation);
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recov.init(&demod.out, _sampleRate / _baudRate, _omegaGain, _muGain, _omegaRelLimit);
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out = &recov.out;
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generic_hier_block<MSKDemod>::registerBlock(&demod);
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generic_hier_block<MSKDemod>::registerBlock(&recov);
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generic_hier_block<MSKDemod>::_block_init = true;
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}
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void setSampleRate(float sampleRate) {
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assert(generic_hier_block<MSKDemod>::_block_init);
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generic_hier_block<MSKDemod>::tempStop();
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_sampleRate = sampleRate;
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demod.setSampleRate(_sampleRate);
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recov.setOmega(_sampleRate / _baudRate, _omegaRelLimit);
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generic_hier_block<MSKDemod>::tempStart();
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}
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void setDeviation(float deviation) {
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assert(generic_hier_block<MSKDemod>::_block_init);
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_deviation = deviation;
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demod.setDeviation(deviation);
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}
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void setBaudRate(float baudRate, float omegaRelLimit) {
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assert(generic_hier_block<MSKDemod>::_block_init);
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_baudRate = baudRate;
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_omegaRelLimit = omegaRelLimit;
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recov.setOmega(_sampleRate / _baudRate, _omegaRelLimit);
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}
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void setMMGains(float omegaGain, float myGain) {
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assert(generic_hier_block<MSKDemod>::_block_init);
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_omegaGain = omegaGain;
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_muGain = myGain;
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recov.setGains(_omegaGain, _muGain);
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}
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void setOmegaRelLimit(float omegaRelLimit) {
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assert(generic_hier_block<MSKDemod>::_block_init);
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_omegaRelLimit = omegaRelLimit;
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recov.setOmegaRelLimit(_omegaRelLimit);
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}
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stream<float>* out = NULL;
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private:
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FloatFMDemod demod;
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MMClockRecovery<float> recov;
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float _sampleRate;
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float _deviation;
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float _baudRate;
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float _omegaGain;
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float _muGain;
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float _omegaRelLimit;
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};
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template<int ORDER, bool OFFSET>
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class PSKDemod : public generic_hier_block<PSKDemod<ORDER, OFFSET>> {
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public:
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PSKDemod() {}
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PSKDemod(stream<complex_t>* input, float sampleRate, float baudRate, int RRCTapCount = 31, float RRCAlpha = 0.32f, float agcRate = 10e-4, float costasLoopBw = 0.004f, float omegaGain = (0.01*0.01) / 4, float muGain = 0.01f, float omegaRelLimit = 0.005f) {
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init(input, sampleRate, baudRate, RRCTapCount, RRCAlpha, agcRate, costasLoopBw, omegaGain, muGain, omegaRelLimit);
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}
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void init(stream<complex_t>* input, float sampleRate, float baudRate, int RRCTapCount = 31, float RRCAlpha = 0.32f, float agcRate = 10e-4, float costasLoopBw = 0.004f, float omegaGain = (0.01*0.01) / 4, float muGain = 0.01f, float omegaRelLimit = 0.005f) {
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_RRCTapCount = RRCTapCount;
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_RRCAlpha = RRCAlpha;
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_sampleRate = sampleRate;
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_agcRate = agcRate;
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_costasLoopBw = costasLoopBw;
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_baudRate = baudRate;
|
|
_omegaGain = omegaGain;
|
|
_muGain = muGain;
|
|
_omegaRelLimit = omegaRelLimit;
|
|
|
|
agc.init(input, 1.0f, 65535, _agcRate);
|
|
taps.init(_RRCTapCount, _sampleRate, _baudRate, _RRCAlpha);
|
|
rrc.init(&agc.out, &taps);
|
|
demod.init(&rrc.out, _costasLoopBw);
|
|
|
|
generic_hier_block<PSKDemod<ORDER, OFFSET>>::registerBlock(&agc);
|
|
generic_hier_block<PSKDemod<ORDER, OFFSET>>::registerBlock(&rrc);
|
|
generic_hier_block<PSKDemod<ORDER, OFFSET>>::registerBlock(&demod);
|
|
|
|
if constexpr (OFFSET) {
|
|
delay.init(&demod.out);
|
|
recov.init(&delay.out, _sampleRate / _baudRate, _omegaGain, _muGain, _omegaRelLimit);
|
|
generic_hier_block<PSKDemod<ORDER, OFFSET>>::registerBlock(&delay);
|
|
}
|
|
else {
|
|
recov.init(&demod.out, _sampleRate / _baudRate, _omegaGain, _muGain, _omegaRelLimit);
|
|
}
|
|
|
|
generic_hier_block<PSKDemod<ORDER, OFFSET>>::registerBlock(&recov);
|
|
|
|
out = &recov.out;
|
|
|
|
generic_hier_block<PSKDemod<ORDER, OFFSET>>::_block_init = true;
|
|
}
|
|
|
|
void setInput(stream<complex_t>* input) {
|
|
assert((generic_hier_block<PSKDemod<ORDER, OFFSET>>::_block_init));
|
|
agc.setInput(input);
|
|
}
|
|
|
|
void setSampleRate(float sampleRate) {
|
|
assert((generic_hier_block<PSKDemod<ORDER, OFFSET>>::_block_init));
|
|
_sampleRate = sampleRate;
|
|
rrc.tempStop();
|
|
recov.tempStop();
|
|
taps.setSampleRate(_sampleRate);
|
|
rrc.updateWindow(&taps);
|
|
recov.setOmega(_sampleRate / _baudRate, _omegaRelLimit);
|
|
rrc.tempStart();
|
|
recov.tempStart();
|
|
}
|
|
|
|
void setBaudRate(float baudRate) {
|
|
assert((generic_hier_block<PSKDemod<ORDER, OFFSET>>::_block_init));
|
|
_baudRate = baudRate;
|
|
rrc.tempStop();
|
|
recov.tempStop();
|
|
taps.setBaudRate(_baudRate);
|
|
rrc.updateWindow(&taps);
|
|
recov.setOmega(_sampleRate / _baudRate, _omegaRelLimit);
|
|
rrc.tempStart();
|
|
recov.tempStart();
|
|
}
|
|
|
|
void setRRCParams(int RRCTapCount, float RRCAlpha) {
|
|
assert((generic_hier_block<PSKDemod<ORDER, OFFSET>>::_block_init));
|
|
_RRCTapCount = RRCTapCount;
|
|
_RRCAlpha = RRCAlpha;
|
|
taps.setTapCount(_RRCTapCount);
|
|
taps.setAlpha(RRCAlpha);
|
|
rrc.updateWindow(&taps);
|
|
}
|
|
|
|
void setAgcRate(float agcRate) {
|
|
assert((generic_hier_block<PSKDemod<ORDER, OFFSET>>::_block_init));
|
|
_agcRate = agcRate;
|
|
agc.setRate(_agcRate);
|
|
}
|
|
|
|
void setCostasLoopBw(float costasLoopBw) {
|
|
assert((generic_hier_block<PSKDemod<ORDER, OFFSET>>::_block_init));
|
|
_costasLoopBw = costasLoopBw;
|
|
demod.setLoopBandwidth(_costasLoopBw);
|
|
}
|
|
|
|
void setMMGains(float omegaGain, float myGain) {
|
|
assert((generic_hier_block<PSKDemod<ORDER, OFFSET>>::_block_init));
|
|
_omegaGain = omegaGain;
|
|
_muGain = myGain;
|
|
recov.setGains(_omegaGain, _muGain);
|
|
}
|
|
|
|
void setOmegaRelLimit(float omegaRelLimit) {
|
|
assert((generic_hier_block<PSKDemod<ORDER, OFFSET>>::_block_init));
|
|
_omegaRelLimit = omegaRelLimit;
|
|
recov.setOmegaRelLimit(_omegaRelLimit);
|
|
}
|
|
|
|
stream<complex_t>* out = NULL;
|
|
|
|
private:
|
|
dsp::ComplexAGC agc;
|
|
dsp::RRCTaps taps;
|
|
dsp::FIR<dsp::complex_t> rrc;
|
|
CostasLoop<ORDER> demod;
|
|
DelayImag delay;
|
|
MMClockRecovery<dsp::complex_t> recov;
|
|
|
|
int _RRCTapCount;
|
|
float _RRCAlpha;
|
|
float _sampleRate;
|
|
float _agcRate;
|
|
float _baudRate;
|
|
float _costasLoopBw;
|
|
float _omegaGain;
|
|
float _muGain;
|
|
float _omegaRelLimit;
|
|
};
|
|
|
|
class PMDemod : public generic_hier_block<PMDemod> {
|
|
public:
|
|
PMDemod() {}
|
|
|
|
PMDemod(stream<complex_t>* input, float sampleRate, float baudRate, float agcRate = 0.02e-3f, float pllLoopBandwidth = (0.06f*0.06f) / 4.0f, int rrcTapCount = 31, float rrcAlpha = 0.6f, float omegaGain = (0.01*0.01) / 4, float muGain = 0.01f, float omegaRelLimit = 0.005f) {
|
|
init(input, sampleRate, baudRate, agcRate, pllLoopBandwidth, rrcTapCount, rrcAlpha, omegaGain, muGain, omegaRelLimit);
|
|
}
|
|
|
|
void init(stream<complex_t>* input, float sampleRate, float baudRate, float agcRate = 0.02e-3f, float pllLoopBandwidth = (0.06f*0.06f) / 4.0f, int rrcTapCount = 31, float rrcAlpha = 0.6f, float omegaGain = (0.01*0.01) / 4, float muGain = 0.01f, float omegaRelLimit = 0.005f) {
|
|
_sampleRate = sampleRate;
|
|
_baudRate = baudRate;
|
|
_agcRate = agcRate;
|
|
_pllLoopBandwidth = pllLoopBandwidth;
|
|
_rrcTapCount = rrcTapCount;
|
|
_rrcAlpha = rrcAlpha;
|
|
_omegaGain = omegaGain;
|
|
_muGain = muGain;
|
|
_omegaRelLimit = omegaRelLimit;
|
|
|
|
agc.init(input, 1.0f, 65535, _agcRate);
|
|
pll.init(&agc.out, _pllLoopBandwidth);
|
|
rrcwin.init(_rrcTapCount, _sampleRate, _baudRate, _rrcAlpha);
|
|
rrc.init(&pll.out, &rrcwin);
|
|
recov.init(&rrc.out, _sampleRate / _baudRate, _omegaGain, _muGain, _omegaRelLimit);
|
|
|
|
out = &recov.out;
|
|
|
|
generic_hier_block<PMDemod>::registerBlock(&agc);
|
|
generic_hier_block<PMDemod>::registerBlock(&pll);
|
|
generic_hier_block<PMDemod>::registerBlock(&rrc);
|
|
generic_hier_block<PMDemod>::registerBlock(&recov);
|
|
generic_hier_block<PMDemod>::_block_init = true;
|
|
}
|
|
|
|
void setInput(stream<complex_t>* input) {
|
|
assert(generic_hier_block<PMDemod>::_block_init);
|
|
agc.setInput(input);
|
|
}
|
|
|
|
void setAgcRate(float agcRate) {
|
|
assert(generic_hier_block<PMDemod>::_block_init);
|
|
_agcRate = agcRate;
|
|
agc.setRate(_agcRate);
|
|
}
|
|
|
|
void setPllLoopBandwidth(float pllLoopBandwidth) {
|
|
assert(generic_hier_block<PMDemod>::_block_init);
|
|
_pllLoopBandwidth = pllLoopBandwidth;
|
|
pll.setLoopBandwidth(_pllLoopBandwidth);
|
|
}
|
|
|
|
void setRRCParams(int rrcTapCount, float rrcAlpha) {
|
|
assert(generic_hier_block<PMDemod>::_block_init);
|
|
_rrcTapCount = rrcTapCount;
|
|
_rrcAlpha = rrcAlpha;
|
|
rrcwin.setTapCount(_rrcTapCount);
|
|
rrcwin.setAlpha(_rrcAlpha);
|
|
rrc.updateWindow(&rrcwin);
|
|
}
|
|
|
|
void setMMGains(float omegaGain, float muGain) {
|
|
assert(generic_hier_block<PMDemod>::_block_init);
|
|
_omegaGain = omegaGain;
|
|
_muGain = muGain;
|
|
recov.setGains(_omegaGain, _muGain);
|
|
}
|
|
|
|
void setOmegaRelLimit(float omegaRelLimit) {
|
|
assert(generic_hier_block<PMDemod>::_block_init);
|
|
_omegaRelLimit = omegaRelLimit;
|
|
recov.setOmegaRelLimit(_omegaRelLimit);
|
|
}
|
|
|
|
stream<float>* out = NULL;
|
|
|
|
private:
|
|
dsp::ComplexAGC agc;
|
|
dsp::CarrierTrackingPLL<float> pll;
|
|
dsp::RRCTaps rrcwin;
|
|
dsp::FIR<float> rrc;
|
|
dsp::MMClockRecovery<float> recov;
|
|
|
|
float _sampleRate;
|
|
float _baudRate;
|
|
float _agcRate;
|
|
float _pllLoopBandwidth;
|
|
int _rrcTapCount;
|
|
float _rrcAlpha;
|
|
float _omegaGain;
|
|
float _muGain;
|
|
float _omegaRelLimit;
|
|
};
|
|
|
|
class StereoFMDemod : public generic_hier_block<StereoFMDemod> {
|
|
public:
|
|
StereoFMDemod() {}
|
|
|
|
StereoFMDemod(stream<complex_t>* input, float sampleRate, float deviation) {
|
|
init(input, sampleRate, deviation);
|
|
}
|
|
|
|
void init(stream<complex_t>* input, float sampleRate, float deviation) {
|
|
_sampleRate = sampleRate;
|
|
|
|
PilotFirWin.init(18750, 19250, 3000, _sampleRate);
|
|
|
|
demod.init(input, _sampleRate, deviation);
|
|
|
|
r2c.init(&demod.out);
|
|
|
|
pilotFilter.init(&r2c.out, &PilotFirWin);
|
|
|
|
demux.init(&pilotFilter.dataOut, &pilotFilter.pilotOut, 1.0f);
|
|
|
|
recon.init(&demux.AplusBOut, &demux.AminusBOut);
|
|
|
|
out = &recon.out;
|
|
|
|
generic_hier_block<StereoFMDemod>::registerBlock(&demod);
|
|
generic_hier_block<StereoFMDemod>::registerBlock(&r2c);
|
|
generic_hier_block<StereoFMDemod>::registerBlock(&pilotFilter);
|
|
generic_hier_block<StereoFMDemod>::registerBlock(&demux);
|
|
generic_hier_block<StereoFMDemod>::registerBlock(&recon);
|
|
generic_hier_block<StereoFMDemod>::_block_init = true;
|
|
}
|
|
|
|
void setInput(stream<float>* input) {
|
|
assert(generic_hier_block<StereoFMDemod>::_block_init);
|
|
r2c.setInput(input);
|
|
}
|
|
|
|
void setDeviation(float deviation) {
|
|
demod.setDeviation(deviation);
|
|
}
|
|
|
|
stream<stereo_t>* out = NULL;
|
|
|
|
private:
|
|
filter_window::BandPassBlackmanWindow PilotFirWin;
|
|
|
|
FloatFMDemod demod;
|
|
|
|
RealToComplex r2c;
|
|
|
|
FMStereoDemuxPilotFilter pilotFilter;
|
|
|
|
FMStereoDemux demux;
|
|
|
|
FMStereoReconstruct recon;
|
|
|
|
float _sampleRate;
|
|
};
|
|
} |