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sdrangel/wdsp/ssql.hpp

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/* ssql.h
This file is part of a program that implements a Software-Defined Radio.
Copyright (C) 2023 Warren Pratt, NR0V
Copyright (C) 2024 Edouard Griffiths, F4EXB Adapted to SDRangel
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 2
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, write to the Free Software
Foundation, Inc., 51 Franklin Street, Fifth Floor, Boston, MA 02110-1301, USA.
The author can be reached by email at
warren@pratt.one
*/
#ifndef wdsp_ssql_h
#define wdsp_ssql_h
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#include <vector>
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#include "export.h"
namespace WDSP {
class WDSP_API FTOV // Frequency to Voltage Converter
{
public:
int run; // 0 => don't run; 1 => run
int size; // buffer size
int rate; // sample-rate
int rsize; // rate * time_to_fill_ring, e.g., 48K/s * 50ms = 2400
double fmax; // frequency (Hz) for full output, e.g., 2000 (Hz)
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float* in; // pointer to the intput buffer for ftov
float* out; // pointer to the output buffer for ftov
std::vector<int> ring; // the ring
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int rptr; // index into the ring
double inlast; // holds last sample from previous buffer
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int rcount; // count of zero-crossings currently in the ring
double div; // divisor for 'rcount' to produce output of 1.0 at 'fmax'
double eps; // minimum input change to count as a signal edge transition
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FTOV(
int run,
int size,
int rate,
int rsize,
double fmax,
float* in,
float* out
);
FTOV(const FTOV&) = delete;
FTOV& operator=(FTOV& other) = delete;
~FTOV() = default;
void flush();
void execute();
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};
class CBL;
class FTDV;
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class DBQLP;
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class WDSP_API SSQL // Syllabic Squelch
{
public:
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enum class SSQLState
{
MUTED,
INCREASE,
UNMUTED,
DECREASE
};
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int run; // 0 if squelch system is OFF; 1 if it's ON
int size; // size of input/output buffers
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float* in; // squelch input signal buffer
float* out; // squelch output signal buffer
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int rate; // sample rate
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SSQLState state; // state machine control
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int count; // count variable for raised cosine transitions
double tup; // time for turn-on transition
double tdown; // time for turn-off transition
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int ntup; // number of samples for turn-on transition
int ntdown; // number of samples for turn-off transition
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std::vector<double> cup; // coefficients for up-slew
std::vector<double> cdown; // coefficients for down-slew
double muted_gain; // audio gain while muted; 0.0 for complete silence
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std::vector<float> b1; // buffer to hold output of dc-block function
std::vector<float> ibuff; // buffer containing only 'I' component
std::vector<float> ftovbuff; // buffer containing output of f to v converter
std::vector<float> lpbuff; // buffer containing output of low-pass filter
std::vector<int> wdbuff; // buffer containing output of window detector
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CBL *dcbl; // pointer to DC Blocker data structure
FTOV *cvtr; // pointer to F to V Converter data structure
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DBQLP *filt; // pointer to Bi-Quad Low-Pass Filter data structure
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int ftov_rsize; // ring size for f_to_v converter
double ftov_fmax; // fmax for f_to_v converter
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// window detector
double wdtau; // window detector time constant
double wdmult; // window detector time constant multiplier
double wdaverage; // average signal value
double wthresh; // window threshold above/below average
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// trigger
double tr_thresh; // trigger threshold: 100K/(100K+22K)=0.8197
double tr_tau_unmute; // trigger unmute time-constant: (100K||220K)*10uF = 0.6875
double tr_ss_unmute; // trigger steady-state level for unmute: 100K/(100K+220K)=0.3125
double tr_tau_mute; // trigger mute time-constant: 220K*10uF = 2.2
double tr_ss_mute; // trigger steady-state level for mute: 1.0
double tr_voltage; // trigger voltage
double mute_mult; // multiplier for successive voltage calcs when muted
double unmute_mult; // multiplier for successive voltage calcs when unmuted
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std::vector<int> tr_signal; // trigger signal, 0 or 1
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SSQL(
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int run,
int size,
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float* in,
float* out,
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int rate,
double tup,
double tdown,
double muted_gain,
double tau_mute,
double tau_unmute,
double wthresh,
double tr_thresh,
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int rsize,
double fmax
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);
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SSQL(const SSQL&) = delete;
SSQL& operator=(const SSQL& other) = delete;
~SSQL();
void flush();
void execute();
void setBuffers(float* in, float* out);
void setSamplerate(int rate);
void setSize(int size);
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// RXA Properties
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void setRun(int run);
void setThreshold(double threshold);
void setTauMute(double tau_mute);
void setTauUnMute(double tau_unmute);
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private:
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void compute_slews();
void calc();
void decalc();
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};
} // namespace WDSP
#endif