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Fixed IF reduction not working with multivfo + Added beginning of IF notch code

pull/567/head
AlexandreRouma 2021-12-09 19:43:57 +01:00
rodzic f8ff67c5b0
commit 241632288e
3 zmienionych plików z 221 dodań i 34 usunięć
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81
core/src/dsp/noise_reduction.h
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@ -384,4 +384,85 @@ namespace dsp {
stream<complex_t>* _in;
};
class NotchFilter : public generic_block<NotchFilter> {
public:
NotchFilter() {}
NotchFilter(stream<complex_t>* in, float rate, float offset, float sampleRate) { init(in, rate, offset, sampleRate); }
void init(stream<complex_t>* in, float rate, float offset, float sampleRate) {
_in = in;
correctionRate = rate;
_offset = offset;
_sampleRate = sampleRate;
phaseDelta = lv_cmake(std::cos((-_offset / _sampleRate) * 2.0f * FL_M_PI), std::sin((-_offset / _sampleRate) * 2.0f * FL_M_PI));
phaseDeltaConj = {phaseDelta.real(), -phaseDelta.imag()};
generic_block<NotchFilter>::registerInput(_in);
generic_block<NotchFilter>::registerOutput(&out);
generic_block<NotchFilter>::_block_init = true;
}
void setInput(stream<complex_t>* in) {
assert(generic_block<NotchFilter>::_block_init);
std::lock_guard<std::mutex> lck(generic_block<NotchFilter>::ctrlMtx);
generic_block<NotchFilter>::tempStop();
generic_block<NotchFilter>::unregisterInput(_in);
_in = in;
generic_block<NotchFilter>::registerInput(_in);
generic_block<NotchFilter>::tempStart();
}
void setCorrectionRate(float rate) {
correctionRate = rate;
}
void setOffset(float offset) {
_offset = offset;
phaseDelta = lv_cmake(std::cos((-_offset / _sampleRate) * 2.0f * FL_M_PI), std::sin((-_offset / _sampleRate) * 2.0f * FL_M_PI));
phaseDeltaConj = {phaseDelta.real(), -phaseDelta.imag()};
}
void setSampleRate(float sampleRate) {
_sampleRate = sampleRate;
phaseDelta = lv_cmake(std::cos((-_offset / _sampleRate) * 2.0f * FL_M_PI), std::sin((-_offset / _sampleRate) * 2.0f * FL_M_PI));
phaseDeltaConj = {phaseDelta.real(), -phaseDelta.imag()};
}
int run() {
int count = _in->read();
if (count < 0) { return -1; }
volk_32fc_s32fc_x2_rotator_32fc((lv_32fc_t*)_in->readBuf, (lv_32fc_t*)_in->readBuf, phaseDelta, &inPhase, count);
for (int i = 0; i < count; i++) {
out.writeBuf[i] = _in->readBuf[i] - offset;
offset = offset + (out.writeBuf[i] * correctionRate);
}
volk_32fc_s32fc_x2_rotator_32fc((lv_32fc_t*)out.writeBuf, (lv_32fc_t*)out.writeBuf, phaseDeltaConj, &outPhase, count);
_in->flush();
if (!out.swap(count)) { return -1; }
return count;
}
stream<complex_t> out;
private:
stream<complex_t>* _in;
complex_t offset = {0, 0};
lv_32fc_t inPhase = {1, 0};
lv_32fc_t outPhase = {4, 0};
lv_32fc_t phaseDelta;
lv_32fc_t phaseDeltaConj;
float _offset;
float _sampleRate;
float correctionRate;
};
}

149
core/src/dsp/window.h
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@ -271,37 +271,125 @@ namespace dsp {
};
class NotchWindow : public filter_window::generic_window {
// class NotchWindow : public filter_window::generic_complex_window {
// public:
// NotchWindow() {}
// NotchWindow(float frequency, float width, float sampleRate, int tapCount) { init(frequency, width, sampleRate, tapCount); }
// ~NotchWindow() {
// if (fft_in) { fftwf_free(fft_in); }
// if (fft_out) { fftwf_free(fft_out); }
// fftwf_destroy_plan(fft_plan);
// }
// void init(float frequency, float width, float sampleRate, int tapCount) {
// _frequency = frequency;
// _width = width;
// _sampleRate = sampleRate;
// _tapCount = tapCount;
// // Ensure the number of taps is even
// if (_tapCount & 1) { _tapCount++; }
// fft_in = (complex_t*)fftwf_malloc(_tapCount * sizeof(complex_t));
// fft_out = (complex_t*)fftwf_malloc(_tapCount * sizeof(complex_t));
// fft_plan = fftwf_plan_dft_1d(_tapCount, (fftwf_complex*)fft_in, (fftwf_complex*)fft_out, FFTW_BACKWARD, FFTW_ESTIMATE);
// }
// void setFrequency(float frequency) {
// _frequency = frequency;
// }
// void setWidth(float width) {
// _width = width;
// }
// void setSampleRate(float sampleRate) {
// _sampleRate = sampleRate;
// }
// void setTapCount(int count) {
// _tapCount = count;
// // Ensure the number of taps is even
// // Free buffers
// if (fft_in) { fftwf_free(fft_in); }
// if (fft_out) { fftwf_free(fft_out); }
// fftwf_destroy_plan(fft_plan);
// // Reallocate
// fft_in = (complex_t*)fftwf_malloc(_tapCount * sizeof(complex_t));
// fft_out = (complex_t*)fftwf_malloc(_tapCount * sizeof(complex_t));
// // Create new plan
// fft_plan = fftwf_plan_dft_1d(_tapCount, (fftwf_complex*)fft_in, (fftwf_complex*)fft_out, FFTW_BACKWARD, FFTW_ESTIMATE);
// }
// int getTapCount() {
// return _tapCount;
// }
// void createTaps(complex_t* taps, int tapCount, float factor = 1.0f) {
// float ratio = _sampleRate / (float)tapCount;
// int thalf = tapCount / 2;
// float start = _frequency - (_width / 2.0f);
// float stop = _frequency + (_width / 2.0f);
// // Fill taps
// float freq;
// float pratio = 2.0f * FL_M_PI / (float)tapCount;
// complex_t phaseDiff = {cosf(pratio), -sinf(pratio)};
// complex_t phasor = {1, 0};
// for (int i = 0; i < tapCount; i++) {
// freq = (i < thalf) ? ((float)i * ratio) : -((float)(tapCount - i) * ratio);
// if (freq >= start && freq <= stop) {
// fft_in[i] = {0, 0};
// }
// else {
// fft_in[i] = phasor;
// }
// phasor = phasor * phaseDiff;
// }
// // Run IFFT
// fftwf_execute(fft_plan);
// // Apply window and copy to output
// for (int i = 0; i < tapCount; i++) {
// taps[tapCount - i - 1] = fft_out[i] / (float)tapCount;
// }
// }
// private:
// complex_t* fft_in = NULL;
// complex_t* fft_out = NULL;
// float _frequency, _width, _sampleRate;
// int _tapCount;
// fftwf_plan fft_plan;
// };
class NotchWindow : public filter_window::generic_complex_window {
public:
NotchWindow() {}
NotchWindow(float frequency, float width, float sampleRate, int tapCount) { init(frequency, width, sampleRate, tapCount); }
~NotchWindow() {
if (fft_in) { fftwf_free(fft_in); }
if (fft_out) { fftwf_free(fft_out); }
fftwf_destroy_plan(fft_plan);
}
void init(float frequency, float width, float sampleRate, int tapCount) {
_frequency = frequency;
_width = width;
_sampleRate = sampleRate;
_tapCount = _tapCount;
fft_in = (complex_t*)fftwf_malloc(_tapCount * sizeof(complex_t));
fft_out = (complex_t*)fftwf_malloc(_tapCount * sizeof(complex_t));
fft_plan = fftwf_plan_dft_1d(_tapCount, (fftwf_complex*)fft_in, (fftwf_complex*)fft_out, FFTW_BACKWARD, FFTW_ESTIMATE);
_tapCount = tapCount;
}
void setFrequency(float frequency) {
_frequency = frequency;
}
void setWidth(float width) {
_width = width;
}
void setWidth(float width) {}
void setSampleRate(float sampleRate) {
_sampleRate = sampleRate;
@ -309,31 +397,28 @@ namespace dsp {
void setTapCount(int count) {
_tapCount = count;
if (fft_in) { fftwf_free(fft_in); }
if (fft_out) { fftwf_free(fft_out); }
fftwf_destroy_plan(fft_plan);
fft_in = (complex_t*)fftwf_malloc(_tapCount * sizeof(complex_t));
fft_out = (complex_t*)fftwf_malloc(_tapCount * sizeof(complex_t));
fft_plan = fftwf_plan_dft_1d(_tapCount, (fftwf_complex*)fft_in, (fftwf_complex*)fft_out, FFTW_BACKWARD, FFTW_ESTIMATE);
}
int getTapCount() {
return _tapCount;
}
void createTaps(float* taps, int tapCount, float factor = 1.0f) {
void createTaps(complex_t* taps, int tapCount, float factor = 1.0f) {
// Generate exponential decay
float fact = 1.0f / (float)tapCount;
for (int i = 0; i < tapCount; i++) {
taps[tapCount - i - 1] = {expf(-fact*i) * (float)window_function::blackman(i, tapCount - 1), 0};
}
// Frequency translate it to the right place
lv_32fc_t phase = lv_cmake(1.0f, 0.0f);
lv_32fc_t phaseDelta = lv_cmake(std::cos((-_frequency / _sampleRate) * 2.0f * FL_M_PI), std::sin((-_frequency / _sampleRate) * 2.0f * FL_M_PI));
volk_32fc_s32fc_x2_rotator_32fc((lv_32fc_t*)taps, (lv_32fc_t*)taps, phaseDelta, &phase, tapCount);
}
private:
complex_t* fft_in = NULL;
complex_t* fft_out = NULL;
float _frequency, _width, _sampleRate;
float _frequency, _sampleRate;
int _tapCount;
fftwf_plan fft_plan;
};
}

25
decoder_modules/radio/src/radio_module.h
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@ -60,10 +60,12 @@ public:
ifChain.init(vfo->output, &ifChainOutputChanged);
fmnr.block.init(NULL, 32);
notch.block.init(NULL, 0.5, 0, 250000); // TODO: The rate has to depend on IF sample rate so the width is always the same
squelch.block.init(NULL, MIN_SQUELCH);
ifChain.add(&fmnr);
ifChain.add(&notch);
ifChain.add(&squelch);
ifChain.add(&fmnr);
// Load configuration for and enabled all demodulators
EventHandler<dsp::stream<dsp::stereo_t>*> _demodOutputChangeHandler;
@ -256,9 +258,20 @@ private:
}
if (!_this->squelchEnabled && _this->enabled) { style::endDisabled(); }
// // Notch filter
// if (ImGui::Checkbox("Notch##_radio_notch_ena_", &_this->notchEnabled)) {
// _this->ifChain.setState(&_this->notch, _this->notchEnabled);
// }
// if (ImGui::SliderFloat(("NF##_radio_notch_freq_" + _this->name).c_str(), &_this->notchPos, -7500, 7500)) {
// _this->notch.block.setOffset(_this->notchPos);
// }
// if (ImGui::SliderFloat(("NW##_radio_notch_width_" + _this->name).c_str(), &_this->notchWidth, 0, 1000)) {
// // TODO: Implement
// }
// FM IF Noise Reduction
if (_this->FMIFNRAllowed) {
if (ImGui::Checkbox("IF Noise Reduction##_radio_fmifnr_ena_", &_this->FMIFNREnabled)) {
if (ImGui::Checkbox(("IF Noise Reduction##_radio_fmifnr_ena_" + _this->name).c_str(), &_this->FMIFNREnabled)) {
_this->setFMIFNREnabled(_this->FMIFNREnabled);
}
}
@ -343,6 +356,9 @@ private:
// Configure FM IF Noise Reduction
setFMIFNREnabled(FMIFNRAllowed ? FMIFNREnabled : false);
// Configure notch
notch.block.setSampleRate(selectedDemod->getIFSampleRate());
// Configure squelch
squelch.block.setLevel(squelchLevel);
setSquelchEnabled(squelchEnabled);
@ -550,6 +566,7 @@ private:
// IF chain
dsp::Chain<dsp::complex_t> ifChain;
dsp::ChainLink<dsp::FMIFNoiseReduction, dsp::complex_t> fmnr;
dsp::ChainLink<dsp::NotchFilter, dsp::complex_t> notch;
dsp::ChainLink<dsp::Squelch, dsp::complex_t> squelch;
// Audio chain
@ -579,6 +596,10 @@ private:
bool FMIFNRAllowed;
bool FMIFNREnabled = false;
bool notchEnabled = false;
float notchPos = 0;
float notchWidth = 500;
const double MIN_SQUELCH = -100.0;
const double MAX_SQUELCH = 0.0;