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sdrangel/plugins/channelrx/demoddatv/leansdr/sdr.h

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// This file is part of LeanSDR Copyright (C) 2016-2019 <pabr@pabr.org>.
// See the toplevel README for more information.
//
// This program is free software: you can redistribute it and/or modify
// it under the terms of the GNU General Public License as published by
// the Free Software Foundation, either version 3 of the License, or
// (at your option) any later version.
//
// This program is distributed in the hope that it will be useful,
// but WITHOUT ANY WARRANTY; without even the implied warranty of
// MERCHANTABILITY or FITNESS FOR A PARTICULAR PURPOSE. See the
// GNU General Public License for more details.
//
// You should have received a copy of the GNU General Public License
// along with this program. If not, see <http://www.gnu.org/licenses/>.
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#ifndef LEANSDR_SDR_H
#define LEANSDR_SDR_H
#include <numeric>
#include <complex>
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#include "leansdr/dsp.h"
#include "leansdr/math.h"
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namespace leansdr
{
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// Abbreviations for floating-point types
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typedef float f32;
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typedef std::complex<u8> cu8;
typedef std::complex<s8> cs8;
typedef std::complex<u16> cu16;
typedef std::complex<s16> cs16;
typedef std::complex<f32> cf32;
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//////////////////////////////////////////////////////////////////////
// SDR blocks
//////////////////////////////////////////////////////////////////////
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// AUTO-NOTCH FILTER
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// Periodically detects the [nslots] strongest peaks with a FFT,
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// removes them with a first-order filter.
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template <typename T>
struct auto_notch : runnable
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{
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int decimation;
float k;
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auto_notch(
scheduler *sch,
pipebuf<std::complex<T>> &_in,
pipebuf<std::complex<T>> &_out,
int _nslots,
T _agc_rms_setpoint
) :
runnable(sch, "auto_notch"),
decimation(1024 * 4096),
k(0.002), // k(0.01)
fft(4096),
in(_in),
out(_out, fft.size()),
nslots(_nslots),
phase(0),
gain(1),
agc_rms_setpoint(_agc_rms_setpoint)
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{
__slots = new slot[nslots];
for (int s = 0; s < nslots; ++s)
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{
__slots[s].i = -1;
__slots[s].expj = new std::complex<float>[fft.size()];
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}
}
~auto_notch()
{
for (int s = 0; s < nslots; ++s) {
delete[] __slots[s].expj;
}
delete[] __slots;
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}
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void run()
{
while (in.readable() >= fft.size() && out.writable() >= fft.size())
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{
phase += fft.size();
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if (phase >= decimation)
{
phase -= decimation;
detect();
}
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process();
in.read(fft.size());
out.written(fft.size());
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}
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}
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void detect()
{
std::complex<T> *pin = in.rd();
std::complex<float> *data = new std::complex<float>[fft.size()];
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float m0 = 0, m2 = 0;
for (int i = 0; i < fft.size(); ++i)
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{
data[i] = pin[i];
m2 += (float) pin[i].real() * pin[i].real() + (float) pin[i].imag() * pin[i].imag();
if (gen_abs(pin[i].real()) > m0) {
m0 = gen_abs(pin[i].real());
}
if (gen_abs(pin[i].imag()) > m0) {
m0 = gen_abs(pin[i].imag());
}
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}
if (agc_rms_setpoint && m2)
{
float rms = gen_sqrt(m2 / fft.size());
if (sch->debug) {
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fprintf(stderr, "(pow %f max %f)", rms, m0);
}
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float new_gain = agc_rms_setpoint / rms;
gain = gain * 0.9 + new_gain * 0.1;
}
fft.inplace(data, true);
float *amp = new float[fft.size()];
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for (int i = 0; i < fft.size(); ++i) {
amp[i] = hypotf(data[i].real(), data[i].imag());
}
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for (slot *s = __slots; s < __slots + nslots; ++s)
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{
int iamax = 0;
for (int i = 0; i < fft.size(); ++i)
{
if (amp[i] > amp[iamax]) {
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iamax = i;
}
}
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if (iamax != s->i)
{
if (sch->debug) {
fprintf(stderr, "%s: slot %d new peak %d -> %d\n", name, (int)(s - __slots), s->i, iamax);
}
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s->i = iamax;
s->estim.real(0);
s->estim.imag(0);
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s->estt = 0;
for (int i = 0; i < fft.size(); ++i)
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{
float a = 2 * M_PI * s->i * i / fft.size();
s->expj[i].real(cosf(a));
s->expj[i].imag(sinf(a));
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}
}
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amp[iamax] = 0;
if (iamax - 1 >= 0) {
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amp[iamax - 1] = 0;
}
if (iamax + 1 < fft.size()) {
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amp[iamax + 1] = 0;
}
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}
delete[] amp;
delete[] data;
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}
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void process()
{
std::complex<T> *pin = in.rd(), *pend = pin + fft.size(), *pout = out.wr();
for (slot *s = __slots; s < __slots + nslots; ++s) {
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s->ej = s->expj;
}
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for (; pin < pend; ++pin, ++pout)
{
std::complex<float> out = *pin;
// TODO Optimize for nslots==1 ?
for (slot *s = __slots; s < __slots + nslots; ++s->ej, ++s)
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{
std::complex<float> bb(
pin->real() * s->ej->real() + pin->imag() * s->ej->imag(),
-pin->real() * s->ej->imag() + pin->imag() * s->ej->real()
);
s->estim.real(bb.real() * k + s->estim.real() * (1 - k));
s->estim.imag(bb.imag() * k + s->estim.imag() * (1 - k));
std::complex<float> sub(
s->estim.real() * s->ej->real() - s->estim.imag() * s->ej->imag(),
s->estim.real() * s->ej->imag() + s->estim.imag() * s->ej->real()
);
out.real(out.real() - sub.real());
out.imag(out.imag() - sub.imag());
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}
pout->real(gain * out.real());
pout->imag(gain * out.imag());
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}
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}
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private:
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cfft_engine<float> fft;
pipereader<std::complex<T>> in;
pipewriter<std::complex<T>> out;
int nslots;
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struct slot
{
int i;
std::complex<float> estim;
std::complex<float> *expj, *ej;
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int estt;
};
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slot *__slots;
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int phase;
float gain;
T agc_rms_setpoint;
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};
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// SIGNAL STRENGTH ESTIMATOR
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// Outputs RMS values.
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template <typename T>
struct ss_estimator : runnable
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{
unsigned long window_size; // Samples per estimation
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unsigned long decimation; // Output rate
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ss_estimator(
scheduler *sch,
pipebuf<std::complex<T>> &_in,
pipebuf<T> &_out
) :
runnable(sch, "SS estimator"),
window_size(1024),
decimation(1024),
in(_in),
out(_out),
phase(0)
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{
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}
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void run()
{
while (in.readable() >= window_size && out.writable() >= 1)
{
phase += window_size;
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if (phase >= decimation)
{
phase -= decimation;
std::complex<T> *p = in.rd(), *pend = p + window_size;
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float s = 0;
for (; p < pend; ++p) {
s += (float)p->real() * p->real() + (float)p->imag() * p->imag();
}
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out.write(sqrtf(s / window_size));
}
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in.read(window_size);
}
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}
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private:
pipereader<std::complex<T>> in;
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pipewriter<T> out;
unsigned long phase;
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};
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template <typename T>
struct ss_amp_estimator : runnable
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{
unsigned long window_size; // Samples per estimation
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unsigned long decimation; // Output rate
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ss_amp_estimator(
scheduler *sch,
pipebuf<std::complex<T>> &_in,
pipebuf<T> &_out_ss,
pipebuf<T> &_out_ampmin,
pipebuf<T> &_out_ampmax
) :
runnable(sch, "SS estimator"),
window_size(1024),
decimation(1024),
in(_in),
out_ss(_out_ss),
out_ampmin(_out_ampmin),
out_ampmax(_out_ampmax),
phase(0)
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{
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}
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void run()
{
while (in.readable() >= window_size && out_ss.writable() >= 1 && out_ampmin.writable() >= 1 && out_ampmax.writable() >= 1)
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{
phase += window_size;
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if (phase >= decimation)
{
phase -= decimation;
std::complex<T> *p = in.rd(), *pend = p + window_size;
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float s2 = 0;
float amin = 1e38, amax = 0;
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for (; p < pend; ++p)
{
float mag2 = (float)p->real() * p->real() + (float)p->imag() * p->imag();
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s2 += mag2;
float mag = sqrtf(mag2);
if (mag < amin) {
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amin = mag;
}
if (mag > amax) {
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amax = mag;
}
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}
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out_ss.write(sqrtf(s2 / window_size));
out_ampmin.write(amin);
out_ampmax.write(amax);
}
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in.read(window_size);
}
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}
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private:
pipereader<std::complex<T>> in;
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pipewriter<T> out_ss, out_ampmin, out_ampmax;
unsigned long phase;
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};
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// AGC
template <typename T>
struct simple_agc : runnable
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{
float out_rms; // Desired RMS output power
float bw; // Bandwidth
float estimated; // Input power
static const int chunk_size = 128;
simple_agc(
scheduler *sch,
pipebuf<std::complex<T>> &_in,
pipebuf<std::complex<T>> &_out
) :
runnable(sch, "AGC"),
out_rms(1),
bw(0.001),
estimated(0),
in(_in),
out(_out, chunk_size)
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{
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}
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private:
pipereader<std::complex<T>> in;
pipewriter<std::complex<T>> out;
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void run()
{
while (in.readable() >= chunk_size && out.writable() >= chunk_size)
{
std::complex<T> *pin = in.rd(), *pend = pin + chunk_size;
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float amp2 = 0;
for (; pin < pend; ++pin) {
amp2 += pin->real() * pin->real() + pin->imag() * pin->imag();
}
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amp2 /= chunk_size;
if (!estimated) {
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estimated = amp2;
}
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estimated = estimated * (1 - bw) + amp2 * bw;
float gain = estimated ? out_rms / sqrtf(estimated) : 0;
pin = in.rd();
std::complex<T> *pout = out.wr();
float bwcomp = 1 - bw;
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for (; pin < pend; ++pin, ++pout)
{
pout->real() = pin->real() * gain;
pout->imag() = pin->imag() * gain;
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}
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in.read(chunk_size);
out.written(chunk_size);
}
}
};
// simple_agc
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typedef uint16_t u_angle; // [0,2PI[ in 65536 steps
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typedef int16_t s_angle; // [-PI,PI[ in 65536 steps
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// GENERIC CONSTELLATION DECODING BY LOOK-UP TABLE.
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// Metrics and phase errors are pre-computed on a RxR grid.
// R must be a power of 2.
// Up to 256 symbols.
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struct softsymbol
{ // TBD obsolete
int16_t cost; // For Viterbi with TBM=int16_t
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uint8_t symbol;
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};
// Target RMS amplitude for AGC
//const float cstln_amp = 73; // Best for 32APSK 9/10
//const float cstln_amp = 90; // Best for QPSK
//const float cstln_amp = 64; // Best for BPSK
//const float cstln_amp = 75; // Best for BPSK at 45°
const float cstln_amp = 75; // Trade-off
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// A struct that temporarily holds all the info we precompute for the LUT.
struct full_ss
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{
uint8_t nearest; // Index of nearest in constellation
uint16_t dists2[256]; // Squared distances
float p[8]; // 0..1 probability of bits being 1
};
// Options for soft-symbols.
// These functions are overloaded to keep cstln_lut<SOFTSYMB> generic:
// to_softsymb(const full_ss *fss, SOFTSYMB *ss)
// softsymb_harden(SOFTSYMB *ss) {
// softsymb_to_dump(const SOFTSYMB &ss, int bit) To grey 0..255
// For LUT initialization only. Performance is not critical.
// Hard decision soft-symbols.
// Value is the symbol index, 0..255.
typedef uint8_t hard_ss;
void to_softsymb(const full_ss *fss, hard_ss *ss);
void softsymb_harden(hard_ss *ss);
uint8_t softsymb_to_dump(const hard_ss &ss, int bit);
// Euclidian QPSK soft-symbols.
// Additive metric suitable for Viterbi.
// Backward-compatible with simplified Viterbi (TBD remove)
struct eucl_ss
{
static const int MAX_SYMBOLS = 4;
uint16_t dists2[MAX_SYMBOLS];
uint16_t discr2; // 2nd_nearest - nearest
uint8_t nearest;
};
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void to_softsymb(const full_ss *fss, eucl_ss *ss);
void softsymb_harden(eucl_ss *ss);
uint8_t softsymb_to_dump(const eucl_ss &ss, int bit);
// Log-Likelihood Ratios soft-symbols
typedef int8_t llr_t; // log(p(0)/p(1)), clip -127=1 +127=0
inline bool llr_harden(llr_t v)
{
return v & 128;
}
struct llr_ss
{
llr_t bits[8]; // Up to 8 bit considered independent
};
void to_softsymb(const full_ss *fss, llr_ss *ss);
void softsymb_harden(llr_ss *ss);
uint8_t softsymb_to_dump(const llr_ss &ss, int bit);
struct cstln_base
{
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enum predef
{
BPSK, // DVB-S2 (and DVB-S variant)
QPSK, // DVB-S
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PSK8,
APSK16,
APSK32, // DVB-S2
APSK64E, // DVB-S2X
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QAM16,
QAM64,
QAM256, // For experimentation only
COUNT
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};
static const char *names[];
float amp_max; // Max amplitude. 1 for PSK, 0 if not applicable.
std::complex<int8_t> *symbols;
int nsymbols;
int nrotations;
};
// cstln_base
template <typename SOFTSYMB, int R>
struct cstln_lut : cstln_base
{
cstln_lut(
cstln_base::predef type,
float mer = 10,
float gamma1 = 0,
float gamma2 = 0,
float gamma3 = 0
)
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{
symbols = nullptr;
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switch (type)
{
case BPSK:
amp_max = 1;
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nrotations = 2;
nsymbols = 2;
symbols = new std::complex<signed char>[nsymbols];
#if 0 // BPSK at 0°
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symbols[0] = polar(1, 2, 0);
symbols[1] = polar(1, 2, 1);
printf("cstln_lut::cstln_lut: BPSK at 0 degrees\n");
#else // BPSK at 45°
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symbols[0] = polar(1, 8, 1);
symbols[1] = polar(1, 8, 5);
printf("cstln_lut::cstln_lut: BPSK at 45 degrees\n");
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#endif
make_lut_from_symbols(mer);
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break;
case QPSK:
amp_max = 1;
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// EN 300 421, section 4.5 Baseband shaping and modulation
// EN 302 307, section 5.4.1
nrotations = 4;
nsymbols = 4;
symbols = new std::complex<signed char>[nsymbols];
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symbols[0] = polar(1, 4, 0.5);
symbols[1] = polar(1, 4, 3.5);
symbols[2] = polar(1, 4, 1.5);
symbols[3] = polar(1, 4, 2.5);
make_lut_from_symbols(mer);
printf("cstln_lut::cstln_lut: QPSK\n");
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break;
case PSK8:
amp_max = 1;
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// EN 302 307, section 5.4.2
nrotations = 8;
nsymbols = 8;
symbols = new std::complex<signed char>[nsymbols];
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symbols[0] = polar(1, 8, 1);
symbols[1] = polar(1, 8, 0);
symbols[2] = polar(1, 8, 4);
symbols[3] = polar(1, 8, 5);
symbols[4] = polar(1, 8, 2);
symbols[5] = polar(1, 8, 7);
symbols[6] = polar(1, 8, 3);
symbols[7] = polar(1, 8, 6);
make_lut_from_symbols(mer);
printf("cstln_lut::cstln_lut: PSK8\n");
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break;
case APSK16:
{
// Default gamma for non-DVB-S2 applications.
if (gamma1 == 0)
gamma1 = 2.57;
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// EN 302 307, section 5.4.3
float r1 = sqrtf(4.0f / (1.0f + 3.0f * gamma1 * gamma1));
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float r2 = gamma1 * r1;
amp_max = r2;
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nrotations = 4;
nsymbols = 16;
symbols = new std::complex<signed char>[nsymbols];
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symbols[0] = polar(r2, 12, 1.5);
symbols[1] = polar(r2, 12, 10.5);
symbols[2] = polar(r2, 12, 4.5);
symbols[3] = polar(r2, 12, 7.5);
symbols[4] = polar(r2, 12, 0.5);
symbols[5] = polar(r2, 12, 11.5);
symbols[6] = polar(r2, 12, 5.5);
symbols[7] = polar(r2, 12, 6.5);
symbols[8] = polar(r2, 12, 2.5);
symbols[9] = polar(r2, 12, 9.5);
symbols[10] = polar(r2, 12, 3.5);
symbols[11] = polar(r2, 12, 8.5);
symbols[12] = polar(r1, 4, 0.5);
symbols[13] = polar(r1, 4, 3.5);
symbols[14] = polar(r1, 4, 1.5);
symbols[15] = polar(r1, 4, 2.5);
make_lut_from_symbols(mer);
printf("cstln_lut::cstln_lut: APSK16: gamma1=%f r1=%f r2=%f\n", gamma1, r1, r2);
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break;
}
case APSK32:
{
// Default gammas for non-DVB-S2 applications.
if (gamma1 == 0)
gamma1 = 2.53;
if (gamma2 == 0)
gamma2 = 4.30;
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// EN 302 307, section 5.4.3
float r1 = sqrtf(
8.0f / (1.0f + 3.0f * gamma1 * gamma1 + 4 * gamma2 * gamma2));
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float r2 = gamma1 * r1;
float r3 = gamma2 * r1;
amp_max = r3;
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nrotations = 4;
nsymbols = 32;
symbols = new std::complex<signed char>[nsymbols];
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symbols[0] = polar(r2, 12, 1.5);
symbols[1] = polar(r2, 12, 2.5);
symbols[2] = polar(r2, 12, 10.5);
symbols[3] = polar(r2, 12, 9.5);
symbols[4] = polar(r2, 12, 4.5);
symbols[5] = polar(r2, 12, 3.5);
symbols[6] = polar(r2, 12, 7.5);
symbols[7] = polar(r2, 12, 8.5);
symbols[8] = polar(r3, 16, 1);
symbols[9] = polar(r3, 16, 3);
symbols[10] = polar(r3, 16, 14);
symbols[11] = polar(r3, 16, 12);
symbols[12] = polar(r3, 16, 6);
symbols[13] = polar(r3, 16, 4);
symbols[14] = polar(r3, 16, 9);
symbols[15] = polar(r3, 16, 11);
symbols[16] = polar(r2, 12, 0.5);
symbols[17] = polar(r1, 4, 0.5);
symbols[18] = polar(r2, 12, 11.5);
symbols[19] = polar(r1, 4, 3.5);
symbols[20] = polar(r2, 12, 5.5);
symbols[21] = polar(r1, 4, 1.5);
symbols[22] = polar(r2, 12, 6.5);
symbols[23] = polar(r1, 4, 2.5);
symbols[24] = polar(r3, 16, 0);
symbols[25] = polar(r3, 16, 2);
symbols[26] = polar(r3, 16, 15);
symbols[27] = polar(r3, 16, 13);
symbols[28] = polar(r3, 16, 7);
symbols[29] = polar(r3, 16, 5);
symbols[30] = polar(r3, 16, 8);
symbols[31] = polar(r3, 16, 10);
make_lut_from_symbols(mer);
printf("cstln_lut::cstln_lut: APSK32: gamma1=%f gamma2=%f, r1=%f r2=%f r3=%f\n", gamma1, gamma2, r1, r2, r3);
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break;
}
case APSK64E:
{
// Default gammas for non-DVB-S2 applications.
if (gamma1 == 0)
gamma1 = 2.4;
if (gamma2 == 0)
gamma2 = 4.3;
if (gamma3 == 0)
gamma3 = 7.0;
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// EN 302 307-2, section 5.4.5, Table 13e
float r1 = sqrtf(
64.0f / (4.0f + 12.0f * gamma1 * gamma1 + 20.0f * gamma2 * gamma2 + 28.0f * gamma3 * gamma3));
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float r2 = gamma1 * r1;
float r3 = gamma2 * r1;
float r4 = gamma3 * r1;
amp_max = r4;
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nrotations = 4;
nsymbols = 64;
symbols = new std::complex<signed char>[nsymbols];
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polar2(0, r4, 1.0 / 4, 7.0 / 4, 3.0 / 4, 5.0 / 4);
polar2(4, r4, 13.0 / 28, 43.0 / 28, 15.0 / 28, 41.0 / 28);
polar2(8, r4, 1.0 / 28, 55.0 / 28, 27.0 / 28, 29.0 / 28);
polar2(12, r1, 1.0 / 4, 7.0 / 4, 3.0 / 4, 5.0 / 4);
polar2(16, r4, 9.0 / 28, 47.0 / 28, 19.0 / 28, 37.0 / 28);
polar2(20, r4, 11.0 / 28, 45.0 / 28, 17.0 / 28, 39.0 / 28);
polar2(24, r3, 1.0 / 20, 39.0 / 20, 19.0 / 20, 21.0 / 20);
polar2(28, r2, 1.0 / 12, 23.0 / 12, 11.0 / 12, 13.0 / 12);
polar2(32, r4, 5.0 / 28, 51.0 / 28, 23.0 / 28, 33.0 / 28);
polar2(36, r3, 9.0 / 20, 31.0 / 20, 11.0 / 20, 29.0 / 20);
polar2(40, r4, 3.0 / 28, 53.0 / 28, 25.0 / 28, 31.0 / 28);
polar2(44, r2, 5.0 / 12, 19.0 / 12, 7.0 / 12, 17.0 / 12);
polar2(48, r3, 1.0 / 4, 7.0 / 4, 3.0 / 4, 5.0 / 4);
polar2(52, r3, 7.0 / 20, 33.0 / 20, 13.0 / 20, 27.0 / 20);
polar2(56, r3, 3.0 / 20, 37.0 / 20, 17.0 / 20, 23.0 / 20);
polar2(60, r2, 1.0 / 4, 7.0 / 4, 3.0 / 4, 5.0 / 4);
make_lut_from_symbols(mer);
printf("cstln_lut::cstln_lut: APSK64E: gamma1=%f gamma2=%f, gamm3=%f r1=%f r2=%f r3=%f r4=%f\n", gamma1, gamma2, gamma3, r1, r2, r3, r4);
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break;
}
case QAM16:
amp_max = 0;
make_qam(16, mer);
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break;
case QAM64:
amp_max = 1;
make_qam(64, mer);
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break;
case QAM256:
amp_max = 1;
make_qam(256, mer);
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break;
default:
fail("Constellation not implemented");
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}
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}
~cstln_lut()
{
if (symbols) {
delete[] symbols;
}
}
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struct result
{
SOFTSYMB ss;
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s_angle phase_error;
uint8_t symbol; // Nearest symbol, useful for C&T recovery
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};
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inline result *lookup(float I, float Q)
{
// Handling of overflows beyond the lookup table:
// - For BPSK/QPSK/8PSK we only care about the phase,
// so the following is harmless and improves locking at low SNR.
// - For amplitude modulations this is not appropriate.
// However, if there is enough noise to cause overflow,
// demodulation would probably fail anyway.
//
// Comment-out for better throughput at high SNR.
#if 1
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while (I < -128 || I > 127 || Q < -128 || Q > 127)
{
I *= 0.5;
Q *= 0.5;
}
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#endif
return &lut[(u8)(s8)I][(u8)(s8)Q];
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}
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inline result *lookup(int I, int Q)
{
// Ignore wrapping modulo 256
return &lut[(u8)I][(u8)Q];
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}
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private:
std::complex<signed char> polar(float r, int n, float i)
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{
float a = i * 2 * M_PI / n;
return std::complex<signed char>(
r * cosf(a) * cstln_amp,
r * sinf(a) * cstln_amp
);
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}
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// Helper function for some constellation tables
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void polar2(int i, float r, float a0, float a1, float a2, float a3)
{
float a[] = {a0, a1, a2, a3};
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for (int j = 0; j < 4; ++j)
{
float phi = a[j] * M_PI;
symbols[i + j] = std::complex<signed char>(
r * cosf(phi) * cstln_amp,
r * sinf(phi) * cstln_amp
);
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}
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}
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void make_qam(int n, float mer)
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{
nrotations = 4;
nsymbols = n;
symbols = new std::complex<signed char>[nsymbols];
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int m = sqrtl(n);
float scale;
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{ // Average power in first quadrant with unit grid
int q = m / 2;
float avgpower = 2 * (q * 0.25 + (q - 1) * q / 2.0 + (q - 1) * q * (2 * q - 1) / 6.0) / q;
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scale = 1.0 / sqrtf(avgpower);
}
// Arbitrary mapping
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int s = 0;
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for (int x = 0; x < m; ++x)
{
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for (int y = 0; y < m; ++y)
{
float I = x - (float)(m - 1) / 2;
float Q = y - (float)(m - 1) / 2;
symbols[s].real(I * scale * cstln_amp);
symbols[s].imag(Q * scale * cstln_amp);
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++s;
}
}
make_lut_from_symbols(mer);
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}
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result lut[R][R];
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void make_lut_from_symbols(float mer)
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{
// Note: Excessively low values of MER will break 16APSK and 32APSK.
float sigma = cstln_amp * pow(10.0, (-mer / 20));
// Precomputed values.
// Shared scope so that we don't have to reset dists2[nsymbols..] to -1.
struct full_ss fss;
for (int s = 0; s < 256; ++s) {
fss.dists2[s] = -1;
}
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for (int I = -R / 2; I < R / 2; ++I)
{
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for (int Q = -R / 2; Q < R / 2; ++Q)
{
// Nearest symbol
fss.nearest = 0;
fss.dists2[0] = 65535;
// Conditional probabilities:
// Sum likelyhoods from all candidate symbols.
//
// P(TX[b]==B | RX==IQ) =
// sum(S=0..nsymbols-1, P(TX[b]==B | RX==IQ && TXs==S))
//
// P(TX[b] == B | RX==IQ && TX==S) =
// P(TX[b]==B && RX==IQ && TX==S) / P(RX==IQ && TX==S)
float probs[8][2];
memset(probs, 0, sizeof(probs));
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for (int s = 0; s < nsymbols; ++s)
{
float d2 = ((I - symbols[s].real()) * (I - symbols[s].real()) + (Q - symbols[s].imag()) * (Q - symbols[s].imag()));
if (d2 < fss.dists2[fss.nearest]) {
fss.nearest = s;
}
fss.dists2[s] = d2;
float p = expf(-d2 / (2 * sigma * sigma)) / (sqrtf(2 * M_PI) * sigma);
for (int bit = 0; bit < 8; ++bit) {
probs[bit][(s >> bit) & 1] += p;
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}
}
// Normalize
for (int b = 0; b < 8; ++b)
{
float p = probs[b][1] / (probs[b][0] + probs[b][1]);
// Avoid trouble when sigma is unrealistically low.
if (!isnormal(p)) {
p = 0;
}
fss.p[b] = p;
}
result *pr = &lut[I & (R - 1)][Q & (R - 1)];
to_softsymb(&fss, &pr->ss);
// Always record nearest symbol and phase error for C&T.
pr->symbol = fss.nearest;
float ph_symbol = atan2f(
symbols[pr->symbol].imag(),
symbols[pr->symbol].real()
);
float ph_err = atan2f(Q, I) - ph_symbol;
pr->phase_error = (int32_t)(ph_err * 65536 / (2 * M_PI)); // Mod 65536
}
}
}
public:
void dump(FILE *f)
{
int bps = log2(nsymbols);
fprintf(f, "P5\n%d %d\n255\n", R, R * (bps + 1));
for (int bit = 0; bit < bps + 1; ++bit)
{
for (int Q = R / 2 - 1; Q >= -R / 2; --Q)
{
for (int I = -R / 2; I < R / 2; ++I)
{
result *pr = &lut[I & (R - 1)][Q & (R - 1)];
uint8_t v;
if (bit < bps) {
v = softsymb_to_dump(pr->ss, bit);
} else {
v = 128 + pr->phase_error / 64;
}
// Highlight the constellation symbols.
for (int s = 0; s < nsymbols; ++s)
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{
if (symbols[s].real() == I && symbols[s].imag() == Q) {
v ^= 128;
}
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}
fputc(v, f);
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}
}
}
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}
// Convert soft metric to Hamming distance
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void harden()
{
for (int i = 0; i < R; ++i)
{
for (int q = 0; q < R; ++q) {
softsymb_harden(&lut[i][q].ss);
}
}
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}
int m_typeCode;
int m_rateCode;
bool m_setByModcod;
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};
// cstln_lut
// SAMPLER INTERFACE FOR CSTLN_RECEIVER
template <typename T>
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struct sampler_interface
{
virtual ~sampler_interface() {
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}
virtual std::complex<T> interp(const std::complex<T> *pin, float mu, float phase) = 0;
virtual void update_freq(float freqw, int weight = 0)
{
(void) freqw;
(void) weight;
} // 65536 = 1 Hz
virtual int readahead() = 0;
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};
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// NEAREST-SAMPLE SAMPLER FOR CSTLN_RECEIVER
// Suitable for bandpass-filtered, oversampled signals only
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template <typename T>
struct nearest_sampler : sampler_interface<T>
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{
int readahead() {
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return 0;
}
std::complex<T> interp(const std::complex<T> *pin, float mu, float phase)
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{
(void) mu;
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return pin[0] * trig.expi(-phase);
}
private:
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trig16 trig;
};
// nearest_sampler
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// LINEAR SAMPLER FOR CSTLN_RECEIVER
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template <typename T>
struct linear_sampler : sampler_interface<T>
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{
int readahead() {
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return 1;
}
std::complex<T> interp(const std::complex<T> *pin, float mu, float phase)
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{
// Derotate pin[0] and pin[1]
std::complex<T> s0 = pin[0] * trig.expi(-phase);
std::complex<T> s1 = pin[1] * trig.expi(-(phase + freqw));
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// Interpolate linearly
return s0 * (1 - mu) + s1 * mu;
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}
void update_freq(float _freqw, int weight = 0)
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{
(void) weight;
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freqw = _freqw;
}
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private:
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trig16 trig;
float freqw;
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};
// linear_sampler
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// FIR SAMPLER FOR CSTLN_RECEIVER
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template <typename T, typename Tc>
struct fir_sampler : sampler_interface<T>
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{
fir_sampler(int _ncoeffs, Tc *_coeffs, int _subsampling = 1) :
ncoeffs(_ncoeffs),
coeffs(_coeffs),
subsampling(_subsampling),
update_freq_phase(0)
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{
shifted_coeffs = new std::complex<T>[ncoeffs];
do_update_freq(0); // In case application never calls update_freq()
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}
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virtual ~fir_sampler()
{
delete[] shifted_coeffs;
}
int readahead() {
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return ncoeffs - 1;
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}
std::complex<T> interp(const std::complex<T> *pin, float mu, float phase)
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{
// Apply FIR filter with subsampling
std::complex<T> acc(0, 0);
std::complex<T> *pc = shifted_coeffs + (int)((1 - mu) * subsampling);
std::complex<T> *pcend = shifted_coeffs + ncoeffs;
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if (subsampling == 1)
{
// Special case for heavily oversampled signals,
// where filtering is expensive.
// gcc-4.9.2 can vectorize this form with NEON on ARM.
while (pc < pcend) {
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acc += (*pc++) * (*pin++);
}
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}
else
{
// Not vectorized because the coefficients are not
// guaranteed to be contiguous in memory.
for (; pc < pcend; pc += subsampling, ++pin) {
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acc += (*pc) * (*pin);
}
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}
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// Derotate
return trig.expi(-phase) * acc;
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}
void update_freq(float freqw, int weight = 0)
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{
if (!weight) {
update_freq_phase = 0; // Force refresh.
}
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// Throttling: Update one coeff per 16 processed samples,
// to keep the overhead of freq tracking below about 10%.
update_freq_phase -= weight;
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if (update_freq_phase <= 0)
{
update_freq_phase = ncoeffs * 16;
do_update_freq(freqw);
}
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}
private:
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void do_update_freq(float freqw)
{
float f = freqw / subsampling;
for (int i = 0; i < ncoeffs; ++i) {
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shifted_coeffs[i] = trig.expi(-f * (i - ncoeffs / 2)) * coeffs[i];
}
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}
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trig16 trig;
int ncoeffs;
Tc *coeffs;
int subsampling;
cf32 *shifted_coeffs;
int update_freq_phase;
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};
// fir_sampler
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// CONSTELLATION RECEIVER
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// Linear interpolation: good enough for 1.2 samples/symbol,
// but higher oversampling is recommended.
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template <typename T, typename SOFTSYMB>
struct cstln_receiver : runnable
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{
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sampler_interface<T> *sampler;
cstln_lut<SOFTSYMB, 256> *cstln;
unsigned long meas_decimation; // Measurement rate
float omega, min_omega, max_omega; // Samples per symbol
float freqw, min_freqw, max_freqw; // Freq offs (65536 = 1 Hz)
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float pll_adjustment;
bool allow_drift; // Follow carrier beyond safe limits
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static const unsigned int chunk_size = 128;
float kest;
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cstln_receiver(
scheduler *sch,
sampler_interface<T> *_sampler,
pipebuf<std::complex<T>> &_in,
pipebuf<SOFTSYMB> &_out,
pipebuf<float> *_freq_out = nullptr,
pipebuf<float> *_ss_out = nullptr,
pipebuf<float> *_mer_out = nullptr,
pipebuf<cf32> *_cstln_out = nullptr
) :
runnable(sch, "Constellation receiver"),
sampler(_sampler),
cstln(nullptr),
meas_decimation(1048576),
pll_adjustment(1.0),
allow_drift(false),
kest(0.01),
in(_in),
out(_out, chunk_size),
est_insp(cstln_amp * cstln_amp),
agc_gain(1),
mu(0),
phase(0),
est_sp(0),
est_ep(0),
meas_count(0)
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{
set_omega(1);
set_freq(0);
freq_out = _freq_out ? new pipewriter<float>(*_freq_out) : nullptr;
ss_out = _ss_out ? new pipewriter<float>(*_ss_out) : nullptr;
mer_out = _mer_out ? new pipewriter<float>(*_mer_out) : nullptr;
cstln_out = _cstln_out ? new pipewriter<cf32>(*_cstln_out) : nullptr;
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for (int i = 0; i < 3; i++)
{
hist[i].p = 0;
hist[i].c = 0;
}
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}
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~cstln_receiver()
{
if (freq_out) {
delete freq_out;
}
if (ss_out) {
delete ss_out;
}
if (mer_out) {
delete mer_out;
}
if (cstln_out) {
delete cstln_out;
}
}
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void set_omega(float _omega, float tol = 10e-6)
{
omega = _omega;
min_omega = omega * (1 - tol);
max_omega = omega * (1 + tol);
update_freq_limits();
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}
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void set_freq(float freq)
{
freqw = freq * 65536;
update_freq_limits();
refresh_freq_tap();
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}
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void set_allow_drift(bool d)
{
allow_drift = d;
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}
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void update_freq_limits()
{
// Prevent PLL from crossing +-SR/n/2 and locking at +-SR/n.
int n = 4;
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if (cstln)
{
switch (cstln->nsymbols)
{
case 2:
n = 2;
break; // BPSK
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case 4:
n = 4;
break; // QPSK
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case 8:
n = 8;
break; // 8PSK
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case 16:
n = 12;
break; // 16APSK
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case 32:
n = 16;
break; // 32APSK
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default:
n = 4;
break;
}
}
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min_freqw = freqw - 65536 / max_omega / n / 2;
max_freqw = freqw + 65536 / max_omega / n / 2;
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}
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void run()
{
if (!cstln) {
fail("constellation not set");
}
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// Magic constants that work with the qa recordings.
float freq_alpha = 0.04;
float freq_beta = 0.0012 / omega * pll_adjustment;
float gain_mu = 0.02 / (cstln_amp * cstln_amp) * 2;
int max_meas = chunk_size / meas_decimation + 1;
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// Large margin on output_size because mu adjustments
// can lead to more than chunk_size/min_omega symbols.
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while (in.readable() >= chunk_size + sampler->readahead() &&
out.writable() >= chunk_size &&
(!freq_out || freq_out->writable() >= max_meas) &&
(!ss_out || ss_out->writable() >= max_meas) &&
(!mer_out || mer_out->writable() >= max_meas) &&
(!cstln_out || cstln_out->writable() >= max_meas))
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{
sampler->update_freq(freqw, chunk_size);
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std::complex<T> *pin = in.rd(), *pin0 = pin, *pend = pin + chunk_size;
SOFTSYMB *pout = out.wr(), *pout0 = pout;
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// These are scoped outside the loop for SS and MER estimation.
std::complex<float> sg{0.0f, 0.0f}; // Symbol before AGC;
std::complex<float> s; // For MER estimation and constellation viewer
std::complex<signed char> *cstln_point = nullptr;
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while (pin < pend)
{
// Here mu is the time of the next symbol counted from 0 at pin.
if (mu < 1)
{
// Here 0<=mu<1 is the fractional time of the next symbol
// between pin and pin+1.
sg = sampler->interp(pin, mu, phase + mu * freqw);
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s = sg * agc_gain;
// Constellation look-up
typename cstln_lut<SOFTSYMB, 256>::result *cr =
cstln->lookup(s.real(), s.imag());
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*pout = cr->ss;
++pout;
// PLL
phase += cr->phase_error * freq_alpha;
freqw += cr->phase_error * freq_beta;
// Modified Mueller and Müller
// mu[k]=real((c[k]-c[k-2])*conj(p[k-1])-(p[k]-p[k-2])*conj(c[k-1]))
// =dot(c[k]-c[k-2],p[k-1]) - dot(p[k]-p[k-2],c[k-1])
// p = received signals
// c = decisions (constellation points)
hist[2] = hist[1];
hist[1] = hist[0];
hist[0].p.real(s.real());
hist[0].p.imag(s.imag());
cstln_point = &cstln->symbols[cr->symbol];
hist[0].c.real(cstln_point->real());
hist[0].c.imag(cstln_point->imag());
float muerr = ((hist[0].p.real() - hist[2].p.real()) * hist[1].c.real() + (hist[0].p.imag() - hist[2].p.imag()) * hist[1].c.imag())
- ((hist[0].c.real() - hist[2].c.real()) * hist[1].p.real() + (hist[0].c.imag() - hist[2].c.imag()) * hist[1].p.imag());
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float mucorr = muerr * gain_mu;
const float max_mucorr = 0.1;
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// TBD Optimize out statically
if (mucorr < -max_mucorr) {
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mucorr = -max_mucorr;
}
if (mucorr > max_mucorr) {
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mucorr = max_mucorr;
}
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mu += mucorr;
mu += omega; // Next symbol time;
} // mu<1
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// Next sample
++pin;
--mu;
phase += freqw;
} // chunk_size
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in.read(pin - pin0);
out.written(pout - pout0);
// Normalize phase so that it never exceeds 32 bits.
// Max freqw is 2^31/65536/chunk_size = 256 Hz
// (this may happen with leandvb --drift --decim).
phase = fmodf(phase, 65536); // Rounding direction irrelevant
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if (cstln_point)
{
// Output the last interpolated PSK symbol, max once per chunk_size
if (cstln_out) {
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cstln_out->write(s);
}
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// AGC
// For APSK we must do AGC on the symbols, not the whole signal.
// TODO Use a better estimator at low SNR.
float insp = sg.real() * sg.real() + sg.imag() * sg.imag();
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est_insp = insp * kest + est_insp * (1 - kest);
if (est_insp) {
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agc_gain = cstln_amp / gen_sqrt(est_insp);
}
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// SS and MER
std::complex<float> ev(
s.real() - cstln_point->real(),
s.imag() - cstln_point->imag()
);
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float sig_power, ev_power;
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if (cstln->nsymbols == 2)
{
// Special case for BPSK: Ignore quadrature component of noise.
// TBD Projection on I axis assumes BPSK at 45°
float sig_real = (cstln_point->real() + cstln_point->imag()) * 0.707;
float ev_real = (ev.real() + ev.imag()) * 0.707;
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sig_power = sig_real * sig_real;
ev_power = ev_real * ev_real;
}
else
{
sig_power = (int)cstln_point->real() * cstln_point->real() + (int)cstln_point->imag() * cstln_point->imag();
ev_power = ev.real() * ev.real() + ev.imag() * ev.imag();
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}
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est_sp = sig_power * kest + est_sp * (1 - kest);
est_ep = ev_power * kest + est_ep * (1 - kest);
}
// This is best done periodically ouside the inner loop,
// but will cause non-deterministic output.
if (!allow_drift)
{
if (freqw < min_freqw || freqw > max_freqw) {
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freqw = (max_freqw + min_freqw) / 2;
}
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}
// Output measurements
refresh_freq_tap();
meas_count += pin - pin0;
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while (meas_count >= meas_decimation)
{
meas_count -= meas_decimation;
if (freq_out) {
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freq_out->write(freq_tap);
}
if (ss_out) {
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ss_out->write(sqrtf(est_insp));
}
if (mer_out) {
mer_out->write(est_ep ? 10 * log10f(est_sp / est_ep) : 0);
}
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}
} // Work to do
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}
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float freq_tap;
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void refresh_freq_tap()
{
freq_tap = freqw / 65536;
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}
private:
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struct
{
std::complex<float> p; // Received symbol
std::complex<float> c; // Matched constellation point
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} hist[3];
pipereader<std::complex<T>> in;
pipewriter<SOFTSYMB> out;
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float est_insp, agc_gain;
float mu; // PSK time expressed in clock ticks
float phase; // 65536=2pi
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// Signal estimation
float est_sp; // Estimated RMS signal power
float est_ep; // Estimated RMS error vector power
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unsigned long meas_count;
pipewriter<float> *freq_out, *ss_out, *mer_out;
pipewriter<cf32> *cstln_out;
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};
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// FAST QPSK RECEIVER
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// Optimized for u8 input, no AGC, uses phase information only.
// Outputs hard symbols.
template <typename T>
struct fast_qpsk_receiver : runnable
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{
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typedef u8 hardsymbol;
unsigned long meas_decimation; // Measurement rate
float omega, min_omega, max_omega; // Samples per symbol
signed long freqw, min_freqw, max_freqw; // Freq offs (angle per sample)
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float pll_adjustment;
bool allow_drift; // Follow carrier beyond safe limits
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static const unsigned int chunk_size = 128;
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fast_qpsk_receiver(
scheduler *sch,
pipebuf<std::complex<T>> &_in,
pipebuf<hardsymbol> &_out,
pipebuf<float> *_freq_out = nullptr,
pipebuf<std::complex<T>> *_cstln_out = nullptr
) :
runnable(sch, "Fast QPSK receiver"),
meas_decimation(1048576),
pll_adjustment(1.0),
allow_drift(false),
in(_in),
out(_out, chunk_size),
mu(0),
phase(0),
meas_count(0)
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{
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set_omega(1);
set_freq(0);
freq_out = _freq_out ? new pipewriter<float>(*_freq_out) : nullptr;
cstln_out = _cstln_out ? new pipewriter<std::complex<T>>(*_cstln_out) : nullptr;
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memset(hist, 0, sizeof(hist));
init_lookup_tables();
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}
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~fast_qpsk_receiver()
{
if (freq_out) {
delete freq_out;
}
if (cstln_out) {
delete cstln_out;
}
}
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void set_omega(float _omega, float tol = 10e-6)
{
omega = _omega;
min_omega = omega * (1 - tol);
max_omega = omega * (1 + tol);
update_freq_limits();
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}
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void set_freq(float freq)
{
freqw = freq * 65536;
update_freq_limits();
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}
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void update_freq_limits()
{
// Prevent PLL from locking at +-symbolrate/4.
// TODO The +-SR/8 limit is suitable for QPSK only.
min_freqw = freqw - 65536 / max_omega / 8;
max_freqw = freqw + 65536 / max_omega / 8;
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}
static const int RLUT_BITS = 8;
static const int RLUT_ANGLES = 1 << RLUT_BITS;
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void run()
{
// Magic constants that work with the qa recordings.
signed long freq_alpha = 0.04 * 65536;
signed long freq_beta = 0.0012 * 256 * 65536 / omega * pll_adjustment;
if (!freq_beta) {
fail("Excessive oversampling");
}
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float gain_mu = 0.02 / (cstln_amp * cstln_amp) * 2;
int max_meas = chunk_size / meas_decimation + 1;
// Largin margin on output_size because mu adjustments
// can lead to more than chunk_size/min_omega symbols.
while (in.readable() >= chunk_size + 1 && // +1 for interpolation
out.writable() >= chunk_size && (!freq_out || freq_out->writable() >= max_meas) && (!cstln_out || cstln_out->writable() >= max_meas))
{
std::complex<T> *pin = in.rd(), *pin0 = pin, *pend = pin + chunk_size;
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hardsymbol *pout = out.wr(), *pout0 = pout;
cu8 s;
u_angle symbol_arg = 0; // Exported for constellation viewer
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while (pin < pend)
{
// Here mu is the time of the next symbol counted from 0 at pin.
if (mu < 1)
{
// Here 0<=mu<1 is the fractional time of the next symbol
// between pin and pin+1.
// Derotate and interpolate
#if 0 /* Phase only (does not work)
Careful with the float/signed/unsigned casts */
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u_angle a0 = fast_arg(pin[0]) - phase;
u_angle a1 = fast_arg(pin[1]) - (phase+freqw);
s_angle da = a1 - a0;
symbol_arg = a0 + (s_angle)(da*mu);
s = arg_to_symbol(symbol_arg);
#elif 1 // Linear by lookup-table. 1.2M on bench3bishs
polar *p0 = &lut_polar[pin[0].real()][pin[0].imag()];
u_angle a0 = (u_angle)(p0->a - phase) >> (16 - RLUT_BITS);
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cu8 *p0r = &lut_rect[a0][p0->r >> 1];
polar *p1 = &lut_polar[pin[1].real()][pin[1].imag()];
u_angle a1 = (u_angle)(p1->a - (phase + freqw)) >> (16 - RLUT_BITS);
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cu8 *p1r = &lut_rect[a1][p1->r >> 1];
s.real((int)(p0r->real() + (p1r->real() - p0r->real()) * mu));
s.imag((int)(p0r->imag() + (p1r->imag() - p0r->imag()) * mu));
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symbol_arg = fast_arg(s);
#else // Linear floating-point, for reference
float a0 = -(int)phase * M_PI / 32768;
float cosa0 = cosf(a0), sina0 = sinf(a0);
std::complex<float>
p0r(((float)pin[0].real() - 128) * cosa0 - ((float)pin[0].imag() - 128) * sina0,
((float)pin[0].real() - 128) * sina0 + ((float)pin[0].imag() - 128) * cosa0);
float a1 = -(int)(phase + freqw) * M_PI / 32768;
float cosa1 = cosf(a1), sina1 = sinf(a1);
std::complex<float>
p1r(((float)pin[1].real() - 128) * cosa1 - ((float)pin[1].imag() - 128) * sina1,
((float)pin[1].real() - 128) * sina1 + ((float)pin[1].imag() - 128) * cosa1);
s.real() = (int)(128 + p0r.real() + (p1r.real() - p0r.real()) * mu);
s.imag() = (int)(128 + p0r.imag() + (p1r.imag() - p0r.imag()) * mu);
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symbol_arg = fast_arg(s);
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#endif
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int quadrant = symbol_arg >> 14;
static unsigned char quadrant_to_symbol[4] = {0, 2, 3, 1};
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*pout = quadrant_to_symbol[quadrant];
++pout;
// PLL
s_angle phase_error = (s_angle)(symbol_arg & 16383) - 8192;
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phase += (phase_error * freq_alpha + 32768) >> 16;
freqw += (phase_error * freq_beta + 32768 * 256) >> 24;
// Modified Mueller and Müller
// mu[k]=real((c[k]-c[k-2])*conj(p[k-1])-(p[k]-p[k-2])*conj(c[k-1]))
// =dot(c[k]-c[k-2],p[k-1]) - dot(p[k]-p[k-2],c[k-1])
// p = received signals
// c = decisions (constellation points)
hist[2] = hist[1];
hist[1] = hist[0];
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#define HIST_FLOAT 0
#if HIST_FLOAT
hist[0].p.real() = (float)s.real() - 128;
hist[0].p.imag() = (float)s.imag() - 128;
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cu8 cp = arg_to_symbol((symbol_arg & 49152) + 8192);
hist[0].c.real() = (float)cp.real() - 128;
hist[0].c.imag() = (float)cp.imag() - 128;
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float muerr =
((hist[0].p.real() - hist[2].p.real()) * hist[1].c.real() +
(hist[0].p.imag() - hist[2].p.imag()) * hist[1].c.imag()) -
((hist[0].c.real() - hist[2].c.real()) * hist[1].p.real() +
(hist[0].c.imag() - hist[2].c.imag()) * hist[1].p.imag());
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#else
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hist[0].p = s;
hist[0].c = arg_to_symbol((symbol_arg & 49152) + 8192);
int muerr =
((signed char)(hist[0].p.real() - hist[2].p.real()) * ((int)hist[1].c.real() - 128) + (signed char)(hist[0].p.imag() - hist[2].p.imag()) * ((int)hist[1].c.imag() - 128)) - ((signed char)(hist[0].c.real() - hist[2].c.real()) * ((int)hist[1].p.real() - 128) + (signed char)(hist[0].c.imag() - hist[2].c.imag()) * ((int)hist[1].p.imag() - 128));
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#endif
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float mucorr = muerr * gain_mu;
const float max_mucorr = 0.1;
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// TBD Optimize out statically
if (mucorr < -max_mucorr) {
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mucorr = -max_mucorr;
}
if (mucorr > max_mucorr) {
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mucorr = max_mucorr;
}
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mu += mucorr;
mu += omega; // Next symbol time;
} // mu<1
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// Next sample
++pin;
--mu;
phase += freqw;
} // chunk_size
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in.read(pin - pin0);
out.written(pout - pout0);
if (symbol_arg && cstln_out) {
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// Output the last interpolated PSK symbol, max once per chunk_size
cstln_out->write(s);
}
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// This is best done periodically ouside the inner loop,
// but will cause non-deterministic output.
if (!allow_drift)
{
if (freqw < min_freqw || freqw > max_freqw) {
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freqw = (max_freqw + min_freqw) / 2;
}
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}
// Output measurements
meas_count += pin - pin0;
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while (meas_count >= meas_decimation)
{
meas_count -= meas_decimation;
if (freq_out) {
freq_out->write((float)freqw / 65536);
}
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}
} // Work to do
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}
private:
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struct polar
{
u_angle a;
unsigned char r;
} lut_polar[256][256];
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u_angle fast_arg(const cu8 &c)
{
// TBD read cu8 as u16 index, same endianness as in init()
return lut_polar[c.real()][c.imag()].a;
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}
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cu8 lut_rect[RLUT_ANGLES][256];
cu8 lut_sincos[65536];
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cu8 arg_to_symbol(u_angle a)
{
return lut_sincos[a];
}
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void init_lookup_tables()
{
for (int i = 0; i < 256; ++i)
{
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for (int q = 0; q < 256; ++q)
{
// Don't cast float to unsigned directly
lut_polar[i][q].a = (s_angle)(atan2f(q - 128, i - 128) * 65536 / (2 * M_PI));
lut_polar[i][q].r = (int)hypotf(i - 128, q - 128);
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}
}
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for (unsigned long a = 0; a < 65536; ++a)
{
float f = 2 * M_PI * a / 65536;
lut_sincos[a].real() = 128 + cstln_amp * cosf(f);
lut_sincos[a].imag() = 128 + cstln_amp * sinf(f);
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}
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for (int a = 0; a < RLUT_ANGLES; ++a)
{
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for (int r = 0; r < 256; ++r)
{
lut_rect[a][r].real() = (int)(128 + r * cos(2 * M_PI * a / RLUT_ANGLES));
lut_rect[a][r].imag() = (int)(128 + r * sin(2 * M_PI * a / RLUT_ANGLES));
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}
}
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}
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struct
{
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#if HIST_FLOAT
std::complex<float> p; // Received symbol
std::complex<float> c; // Matched constellation point
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#else
cu8 p; // Received symbol
cu8 c; // Matched constellation point
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#endif
} hist[3];
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pipereader<cu8> in;
pipewriter<hardsymbol> out;
float mu; // PSK time expressed in clock ticks. TBD fixed point.
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u_angle phase;
unsigned long meas_count;
pipewriter<float> *freq_out, *mer_out;
pipewriter<cu8> *cstln_out;
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};
// fast_qpsk_receiver
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// CONSTELLATION TRANSMITTER
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// Maps symbols to I/Q points.
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template <typename Tout, int Zout>
struct cstln_transmitter : runnable
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{
cstln_lut<hard_ss, 256> *cstln;
cstln_transmitter(
scheduler *sch,
pipebuf<u8> &_in,
pipebuf<std::complex<Tout>> &_out
) :
runnable(sch, "cstln_transmitter"),
in(_in),
out(_out),
cstln(nullptr)
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{
}
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void run()
{
if (!cstln) {
fail("constellation not set");
}
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int count = min(in.readable(), out.writable());
u8 *pin = in.rd(), *pend = pin + count;
std::complex<Tout> *pout = out.wr();
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for (; pin < pend; ++pin, ++pout)
{
std::complex<signed char> *cp = &cstln->symbols[*pin];
pout->real(Zout + cp->real());
pout->imag(Zout + cp->imag());
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}
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in.read(count);
out.written(count);
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}
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private:
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pipereader<u8> in;
pipewriter<std::complex<Tout>> out;
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};
// cstln_transmitter
// FREQUENCY SHIFTER
// Resolution is sample_freq/65536.
template <typename T>
struct rotator : runnable
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{
rotator(
scheduler *sch,
pipebuf<std::complex<T>> &_in,
pipebuf<std::complex<T>> &_out,
float freq
) :
runnable(sch, "rotator"),
in(_in),
out(_out),
index(0)
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{
int ifreq = freq * 65536;
if (sch->debug) {
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fprintf(stderr, "Rotate: req=%f real=%f\n", freq, ifreq / 65536.0);
}
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for (int i = 0; i < 65536; ++i)
{
lut_cos[i] = cosf(2 * M_PI * i * ifreq / 65536);
lut_sin[i] = sinf(2 * M_PI * i * ifreq / 65536);
}
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}
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void run()
{
unsigned long count = min(in.readable(), out.writable());
std::complex<T> *pin = in.rd(), *pend = pin + count;
std::complex<T> *pout = out.wr();
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for (; pin < pend; ++pin, ++pout, ++index)
{
float c = lut_cos[index];
float s = lut_sin[index];
pout->real(pin->real() * c - pin->imag() * s);
pout->imag(pin->real() * s + pin->imag() * c);
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}
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in.read(count);
out.written(count);
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}
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private:
pipereader<std::complex<T>> in;
pipewriter<std::complex<T>> out;
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float lut_cos[65536];
float lut_sin[65536];
unsigned short index; // Current phase
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};
// rotator
// SPECTRUM-BASED CNR ESTIMATOR
// Assumes that the spectrum is as follows:
//
// ---|--noise---|-roll-off-|---carrier+noise----|-roll-off-|---noise--|---
// | (bw/2) | (bw) | (bw/2) | (bw) | (bw/2) |
//
// Maximum roll-off 0.5
template <typename T>
struct cnr_fft : runnable
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{
cnr_fft(
scheduler *sch,
pipebuf<std::complex<T>> &_in,
pipebuf<float> &_out,
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float _bandwidth,
int nfft = 4096
) :
runnable(sch, "cnr_fft"),
bandwidth(_bandwidth),
freq_tap(nullptr),
tap_multiplier(1),
decimation(1048576),
kavg(0.1),
in(_in),
out(_out),
fft(nfft < 128 ? 128 : nfft > 4096 ? 4096 : nfft),
avgpower(nullptr),
sorted(nullptr),
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data(nullptr),
power(nullptr),
phase(0),
cslots_ratio(0.2),
nslots_shift_ratio(0.65),
nslots_ratio(0.1)
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{
fprintf(stderr, "cnr_fft::cnr_fft: bw: %f FFT: %d\n", bandwidth, fft.size());
if (bandwidth > 0.25) {
fail("cnr_fft::cnr_fft: CNR estimator requires Fsampling > 4x Fsignal");
}
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}
~cnr_fft()
{
if (avgpower) {
delete[] avgpower;
}
if (sorted) {
delete[] sorted;
}
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if (data) {
delete[] data;
}
if (power) {
delete[] power;
}
}
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void run()
{
while (in.readable() >= fft.size() && out.writable() >= 1)
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{
phase += fft.size();
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if (phase >= decimation)
{
phase -= decimation;
do_cnr();
}
in.read(fft.size());
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}
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}
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float bandwidth;
float *freq_tap, tap_multiplier;
int decimation;
float kavg;
private:
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void do_cnr()
{
if (!sorted) {
sorted = new T[fft.size()];
}
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if (!data) {
data = new std::complex<T>[fft.size()];
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}
if (!power) {
power = new T[fft.size()];
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}
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float center_freq = freq_tap ? *freq_tap * tap_multiplier : 0;
int icf = floor(center_freq * fft.size() + 0.5);
memcpy(data, in.rd(), fft.size() * sizeof(data[0]));
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fft.inplace(data, true);
for (int i = 0; i < fft.size(); ++i)
power[i] = data[i].real() * data[i].real() + data[i].imag() * data[i].imag();
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if (!avgpower)
{
// Initialize with first spectrum
avgpower = new T[fft.size()];
memcpy(avgpower, power, fft.size() * sizeof(avgpower[0]));
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}
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// Accumulate and low-pass filter (exponential averaging)
for (int i = 0; i < fft.size(); ++i) {
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avgpower[i] = avgpower[i] * (1 - kavg) + power[i] * kavg;
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}
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#define LEANDVB_SDR_CNR_METHOD 2
#if LEANDVB_SDR_CNR_METHOD == 0
int bwslots = (bandwidth / 4) * fft.size();
if (!bwslots) {
return;
}
// Measure carrier+noise in center band
float c2plusn2 = avgslots(icf-bwslots, icf+bwslots);
// Measure noise left and right of roll-off zones
float n2 = ( avgslots(icf-bwslots*4, icf-bwslots*3) +
avgslots(icf+bwslots*3, icf+bwslots*4) ) / 2;
#elif LEANDVB_SDR_CNR_METHOD == 1
int cbwslots = bandwidth * cslots_ratio * fft.size();
int nstart = bandwidth * nslots_shift_ratio * fft.size();
int nstop = nstart + bandwidth * nslots_ratio * fft.size();
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if (!cbwslots || !nstart || !nstop) {
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return;
}
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// Measure carrier+noise in center band
float c2plusn2 = avgslots(icf - cbwslots, icf + cbwslots);
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// Measure noise left and right of roll-off zones
float n2 = (avgslots(icf - nstop, icf - nstart) +
avgslots(icf + nstart, icf + nstop)) / 2;
#elif LEANDVB_SDR_CNR_METHOD == 2
int bw = bandwidth * 0.75 * fft.size();
float c2plusn2 = 0;
float n2 = 0;
minmax(icf - bw, icf + bw, n2, c2plusn2);
#endif
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float c2 = c2plusn2 - n2;
float cnr = (c2 > 0 && n2 > 0) ? 10 * log10f(c2 / n2) : -50;
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out.write(cnr);
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}
float avgslots(int i0, int i1)
{ // i0 <= i1
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T s = 0;
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for (int i = i0; i <= i1; ++i)
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{
int j = i < 0 ? fft.size() + i : i;
s += avgpower[j < 0 ? 0 : j >= fft.size() ? fft.size()-1 : j];
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}
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return s / (i1 - i0 + 1);
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}
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void minmax(int i0, int i1, float& min, float&max)
{
int l = 0;
for (int i = i0; i <= i1 && l < fft.size(); ++i, ++l)
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{
int j = i < 0 ? fft.size() + i : i;
sorted[l] = avgpower[j < 0 ? 0 : j >= fft.size() ? fft.size()-1 : j];
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}
std::sort(sorted, &sorted[l]);
int m = l/5;
min = std::accumulate<T*>(&sorted[0], &sorted[m], (T) 0) / (m+1);
max = std::accumulate<T*>(&sorted[l-m], &sorted[l], (T) 0) / (m+1);
// fprintf(stderr, "l: %d m: %d min: %f max: %f\n", l, m, min, max);
}
pipereader<std::complex<T>> in;
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pipewriter<float> out;
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cfft_engine<T> fft;
T *avgpower;
T *sorted;
std::complex<T> *data;
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T *power;
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int phase;
float cslots_ratio;
float nslots_shift_ratio;
float nslots_ratio;
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};
// cnr_fft
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template <typename T, int NFFT>
struct spectrum : runnable
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{
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int decimation;
float kavg;
int decim;
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spectrum(
scheduler *sch,
pipebuf<std::complex<T>> &_in,
pipebuf<float[NFFT]> &_out
) :
runnable(sch, "spectrum"),
decimation(1048576),
kavg(0.1),
decim(1), in(_in),
out(_out),
fft(NFFT),
avgpower(nullptr),
phase(0)
{
}
~spectrum()
{
if (avgpower) {
delete avgpower;
}
}
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void run()
{
while (in.readable() >= fft.n * decim && out.writable() >= 1)
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{
phase += fft.n * decim;
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if (phase >= decimation)
{
phase -= decimation;
do_spectrum();
}
in.read(fft.n * decim);
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}
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}
private:
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void do_spectrum()
{
std::complex<T> data[fft.n];
if (decim == 1)
{
memcpy(data, in.rd(), fft.n * sizeof(data[0]));
}
else
{
std::complex<T> *pin = in.rd();
for (int i = 0; i < fft.n; ++i, pin += decim) {
data[i] = *pin;
}
}
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fft.inplace(data, true);
float power[NFFT];
for (int i = 0; i < fft.n; ++i) {
power[i] = (float)data[i].real() * data[i].real() + (float)data[i].imag() * data[i].imag();
}
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if (!avgpower)
{
// Initialize with first spectrum
avgpower = new float[fft.n];
memcpy(avgpower, power, fft.n * sizeof(avgpower[0]));
}
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// Accumulate and low-pass filter
for (int i = 0; i < fft.n; ++i)
avgpower[i] = avgpower[i] * (1 - kavg) + power[i] * kavg;
// Reuse power[]
for (int i = 0; i < fft.n / 2; ++i)
{
power[i] = 10 * log10f(avgpower[NFFT / 2 + i]);
power[NFFT / 2 + i] = 10 * log10f(avgpower[i]);
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}
memcpy(out.wr(), power, sizeof(power[0]) * NFFT);
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out.written(1);
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}
pipereader<std::complex<T>> in;
pipewriter<float[NFFT]> out;
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cfft_engine<T> fft;
T *avgpower;
int phase;
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};
// spectrum
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} // namespace leansdr
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#endif // LEANSDR_SDR_H