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///////////////////////////////////////////////////////////////////////////////////
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// Copyright (C) 2019-2023 Edouard Griffiths, F4EXB <f4exb06@gmail.com> //
// Copyright (C) 2020 Kacper Michajłow <kasper93@gmail.com> //
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// //
// 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 as 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 V3 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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# include <cstdio>
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# include <complex.h>
# include <QTime>
# include <QDebug>
# include "util/stepfunctions.h"
# include "util/db.h"
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# include "util/messagequeue.h"
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# include "audio/audiooutputdevice.h"
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# include "dsp/dspengine.h"
# include "dsp/dspcommands.h"
# include "dsp/devicesamplemimo.h"
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# include "dsp/misc.h"
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# include "dsp/datafifo.h"
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# include "device/deviceapi.h"
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# include "maincore.h"
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# include "nfmdemodreport.h"
# include "nfmdemodsink.h"
const double NFMDemodSink : : afSqTones [ ] = { 1000.0 , 6000.0 } ; // {1200.0, 8000.0};
const double NFMDemodSink : : afSqTones_lowrate [ ] = { 1000.0 , 3500.0 } ;
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const unsigned NFMDemodSink : : FFT_FILTER_LENGTH = 1024 ;
const unsigned NFMDemodSink : : CTCSS_DETECTOR_RATE = 6000 ;
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NFMDemodSink : : NFMDemodSink ( ) :
m_channelSampleRate ( 48000 ) ,
m_channelFrequencyOffset ( 0 ) ,
m_audioSampleRate ( 48000 ) ,
m_audioBufferFill ( 0 ) ,
m_audioFifo ( 48000 ) ,
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m_rfFilter ( FFT_FILTER_LENGTH ) ,
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m_ctcssIndex ( 0 ) ,
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m_dcsCode ( 0 ) ,
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m_sampleCount ( 0 ) ,
m_squelchCount ( 0 ) ,
m_squelchGate ( 4800 ) ,
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m_filterTaps ( ( 48000 / 48 ) | 1 ) ,
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m_squelchLevel ( - 990 ) ,
m_squelchOpen ( false ) ,
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m_afSquelchOpen ( false ) ,
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m_magsq ( 0.0f ) ,
m_magsqSum ( 0.0f ) ,
m_magsqPeak ( 0.0f ) ,
m_magsqCount ( 0 ) ,
m_afSquelch ( ) ,
m_squelchDelayLine ( 24000 ) ,
m_messageQueueToGUI ( nullptr )
{
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m_audioBuffer . resize ( 1 < < 14 ) ;
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m_demodBuffer . resize ( 1 < < 12 ) ;
m_demodBufferFill = 0 ;
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m_dcsDetector . setSampleRate ( CTCSS_DETECTOR_RATE ) ;
m_dcsDetector . setEqWindow ( 23 ) ;
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applySettings ( m_settings , true ) ;
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applyChannelSettings ( m_channelSampleRate , m_channelFrequencyOffset , true ) ;
}
void NFMDemodSink : : feed ( const SampleVector : : const_iterator & begin , const SampleVector : : const_iterator & end )
{
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if ( m_channelSampleRate = = 0 ) {
return ;
}
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for ( SampleVector : : const_iterator it = begin ; it ! = end ; + + it )
{
Complex c ( it - > real ( ) , it - > imag ( ) ) ;
c * = m_nco . nextIQ ( ) ;
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Complex ci ;
fftfilt : : cmplx * rf ;
int rf_out = m_rfFilter . runFilt ( c , & rf ) ; // filter RF before demod
for ( int i = 0 ; i < rf_out ; i + + )
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{
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if ( m_interpolatorDistance = = 1.0f )
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{
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processOneSample ( rf [ i ] ) ;
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}
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else if ( m_interpolatorDistance < 1.0f ) // interpolate
{
while ( ! m_interpolator . interpolate ( & m_interpolatorDistanceRemain , rf [ i ] , & ci ) )
{
processOneSample ( ci ) ;
m_interpolatorDistanceRemain + = m_interpolatorDistance ;
}
}
else // decimate
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{
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if ( m_interpolator . decimate ( & m_interpolatorDistanceRemain , rf [ i ] , & ci ) )
{
processOneSample ( ci ) ;
m_interpolatorDistanceRemain + = m_interpolatorDistance ;
}
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}
}
}
}
void NFMDemodSink : : processOneSample ( Complex & ci )
{
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qint16 sample = 0 ;
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double magsqRaw ; // = ci.real()*ci.real() + c.imag()*c.imag();
Real deviation ;
Real demod = m_phaseDiscri . phaseDiscriminatorDelta ( ci , magsqRaw , deviation ) ;
Real magsq = magsqRaw / ( SDR_RX_SCALED * SDR_RX_SCALED ) ;
m_movingAverage ( magsq ) ;
m_magsqSum + = magsq ;
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m_magsqPeak = std : : max < double > ( magsq , m_magsqPeak ) ;
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m_magsqCount + + ;
m_sampleCount + + ;
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bool squelchOpen = m_afSquelchOpen & & m_settings . m_deltaSquelch ;
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if ( m_settings . m_deltaSquelch )
{
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if ( m_afSquelch . analyze ( demod ) )
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{
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m_afSquelchOpen = squelchOpen = m_afSquelch . evaluate ( ) ;
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if ( ! squelchOpen ) {
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m_squelchDelayLine . zeroBack ( m_audioSampleRate / 10 ) ; // zero out evaluation period
}
}
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}
else
{
squelchOpen = m_movingAverage > = m_squelchLevel ;
}
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if ( squelchOpen )
{
m_squelchDelayLine . write ( demod ) ;
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if ( m_squelchCount < 2 * m_squelchGate ) {
m_squelchCount + + ;
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}
}
else
{
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m_squelchDelayLine . write ( 0 ) ;
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if ( m_squelchCount > 0 ) {
m_squelchCount - - ;
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}
}
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m_squelchOpen = m_squelchCount > m_squelchGate ;
int ctcssIndex = m_squelchOpen & & m_settings . m_ctcssOn ? m_ctcssIndex : 0 ;
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unsigned int dcsCode = m_squelchOpen & & m_settings . m_dcsOn ? m_dcsCode : 0 ;
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if ( m_squelchOpen )
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{
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if ( m_settings . m_ctcssOn )
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{
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int factor = ( m_audioSampleRate / CTCSS_DETECTOR_RATE ) - 1 ; // decimate -> 6k
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if ( ( m_sampleCount & factor ) = = factor )
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{
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Real ctcssSample = m_ctcssLowpass . filter ( demod ) ;
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if ( m_ctcssDetector . analyze ( & ctcssSample ) )
{
int maxToneIndex ;
ctcssIndex = m_ctcssDetector . getDetectedTone ( maxToneIndex ) ? maxToneIndex + 1 : 0 ;
}
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}
}
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else if ( m_settings . m_dcsOn )
{
int factor = ( m_audioSampleRate / CTCSS_DETECTOR_RATE ) - 1 ; // decimate -> 6k (same decimation as for CTCSS)
if ( ( m_sampleCount & factor ) = = factor )
{
Real dcsSample = m_ctcssLowpass . filter ( demod ) ;
unsigned int dcsCodeDetected ;
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if ( m_dcsDetector . analyze ( & dcsSample , dcsCodeDetected ) ) {
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dcsCode = DCSCodes : : m_toCanonicalCode . value ( dcsCodeDetected , 0 ) ;
}
}
}
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if ( ! m_settings . m_audioMute & &
( ! m_settings . m_ctcssOn | | m_ctcssIndexSelected = = ctcssIndex | | m_ctcssIndexSelected = = 0 ) & &
( ! m_settings . m_dcsOn | | m_dcsCodeSeleted = = dcsCode | | m_dcsCodeSeleted = = 0 ) )
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{
Real audioSample = m_squelchDelayLine . readBack ( m_squelchGate ) ;
audioSample = m_settings . m_highPass ? m_bandpass . filter ( audioSample ) : m_lowpass . filter ( audioSample ) ;
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audioSample * = m_settings . m_volume * std : : numeric_limits < int16_t > : : max ( ) ;
sample = clamp < float > ( std : : rint ( audioSample ) , std : : numeric_limits < int16_t > : : lowest ( ) , std : : numeric_limits < int16_t > : : max ( ) ) ;
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}
}
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if ( ctcssIndex ! = m_ctcssIndex )
{
auto * guiQueue = getMessageQueueToGUI ( ) ;
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if ( guiQueue )
{
guiQueue - > push ( NFMDemodReport : : MsgReportCTCSSFreq : : create (
ctcssIndex ? m_ctcssDetector . getToneSet ( ) [ ctcssIndex - 1 ] : 0 ) ) ;
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}
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m_ctcssIndex = ctcssIndex ;
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}
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if ( dcsCode ! = m_dcsCode )
{
auto * guiQueue = getMessageQueueToGUI ( ) ;
if ( guiQueue ) {
guiQueue - > push ( NFMDemodReport : : MsgReportDCSCode : : create ( dcsCode ) ) ;
}
m_dcsCode = dcsCode ;
}
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m_audioBuffer [ m_audioBufferFill ] . l = sample ;
m_audioBuffer [ m_audioBufferFill ] . r = sample ;
+ + m_audioBufferFill ;
if ( m_audioBufferFill > = m_audioBuffer . size ( ) )
{
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std : : size_t res = m_audioFifo . write ( ( const quint8 * ) & m_audioBuffer [ 0 ] , std : : min ( m_audioBufferFill , m_audioBuffer . size ( ) ) ) ;
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if ( res ! = m_audioBufferFill )
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{
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qDebug ( " NFMDemodSink::processOneSample: %lu/%lu audio samples written m_audioSampleRate: %u m_channelSampleRate: %d " ,
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res , m_audioBufferFill , m_audioSampleRate , m_channelSampleRate ) ;
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}
m_audioBufferFill = 0 ;
}
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m_demodBuffer [ m_demodBufferFill ] = sample ;
+ + m_demodBufferFill ;
if ( m_demodBufferFill > = m_demodBuffer . size ( ) )
{
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QList < ObjectPipe * > dataPipes ;
MainCore : : instance ( ) - > getDataPipes ( ) . getDataPipes ( m_channel , " demod " , dataPipes ) ;
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if ( dataPipes . size ( ) > 0 )
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{
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QList < ObjectPipe * > : : iterator it = dataPipes . begin ( ) ;
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for ( ; it ! = dataPipes . end ( ) ; + + it )
{
DataFifo * fifo = qobject_cast < DataFifo * > ( ( * it ) - > m_element ) ;
if ( fifo ) {
fifo - > write ( ( quint8 * ) & m_demodBuffer [ 0 ] , m_demodBuffer . size ( ) * sizeof ( qint16 ) , DataFifo : : DataTypeI16 ) ;
}
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}
}
m_demodBufferFill = 0 ;
}
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}
void NFMDemodSink : : applyChannelSettings ( int channelSampleRate , int channelFrequencyOffset , bool force )
{
qDebug ( ) < < " NFMDemodSink::applyChannelSettings: "
< < " channelSampleRate: " < < channelSampleRate
< < " channelFrequencyOffset: " < < channelFrequencyOffset ;
if ( ( channelFrequencyOffset ! = m_channelFrequencyOffset ) | |
( channelSampleRate ! = m_channelSampleRate ) | | force )
{
m_nco . setFreq ( - channelFrequencyOffset , channelSampleRate ) ;
}
if ( ( channelSampleRate ! = m_channelSampleRate ) | | force )
{
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m_interpolator . create ( 16 , channelSampleRate , m_settings . m_rfBandwidth / 2.2 ) ;
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m_interpolatorDistance = Real ( channelSampleRate ) / Real ( m_audioSampleRate ) ;
m_interpolatorDistanceRemain = m_interpolatorDistance ;
Real lowCut = - Real ( m_settings . m_fmDeviation ) / channelSampleRate ;
Real hiCut = Real ( m_settings . m_fmDeviation ) / channelSampleRate ;
m_rfFilter . create_filter ( lowCut , hiCut ) ;
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}
m_channelSampleRate = channelSampleRate ;
m_channelFrequencyOffset = channelFrequencyOffset ;
}
void NFMDemodSink : : applySettings ( const NFMDemodSettings & settings , bool force )
{
qDebug ( ) < < " NFMDemodSink::applySettings: "
< < " m_inputFrequencyOffset: " < < settings . m_inputFrequencyOffset
< < " m_rfBandwidth: " < < settings . m_rfBandwidth
< < " m_afBandwidth: " < < settings . m_afBandwidth
< < " m_fmDeviation: " < < settings . m_fmDeviation
< < " m_volume: " < < settings . m_volume
< < " m_squelchGate: " < < settings . m_squelchGate
< < " m_deltaSquelch: " < < settings . m_deltaSquelch
< < " m_squelch: " < < settings . m_squelch
< < " m_ctcssIndex: " < < settings . m_ctcssIndex
< < " m_ctcssOn: " < < settings . m_ctcssOn
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< < " m_dcsOn: " < < settings . m_dcsOn
< < " m_dcsCode: " < < settings . m_dcsCode
< < " m_dcsPositive: " < < settings . m_dcsPositive
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< < " m_highPass: " < < settings . m_highPass
< < " m_audioMute: " < < settings . m_audioMute
< < " m_audioDeviceName: " < < settings . m_audioDeviceName
< < " force: " < < force ;
if ( ( settings . m_rfBandwidth ! = m_settings . m_rfBandwidth ) | | force )
{
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m_interpolator . create ( 16 , m_channelSampleRate , settings . m_rfBandwidth / 2.2 ) ;
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m_interpolatorDistance = Real ( m_channelSampleRate ) / Real ( m_audioSampleRate ) ;
m_interpolatorDistanceRemain = m_interpolatorDistance ;
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}
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if ( ( settings . m_fmDeviation ! = m_settings . m_fmDeviation ) | | force ) {
Real lowCut = - Real ( settings . m_fmDeviation ) / m_channelSampleRate ;
Real hiCut = Real ( settings . m_fmDeviation ) / m_channelSampleRate ;
m_rfFilter . create_filter ( lowCut , hiCut ) ;
m_phaseDiscri . setFMScaling ( Real ( m_audioSampleRate ) / ( 2.0f * settings . m_fmDeviation ) ) ;
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}
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if ( ( settings . m_afBandwidth ! = m_settings . m_afBandwidth ) | | force )
{
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m_bandpass . create ( m_filterTaps , m_audioSampleRate , 300.0 , settings . m_afBandwidth ) ;
m_lowpass . create ( m_filterTaps , m_audioSampleRate , settings . m_afBandwidth ) ;
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}
if ( ( settings . m_squelchGate ! = m_settings . m_squelchGate ) | | force )
{
m_squelchGate = ( m_audioSampleRate / 100 ) * settings . m_squelchGate ; // gate is given in 10s of ms at 48000 Hz audio sample rate
m_squelchCount = 0 ; // reset squelch open counter
}
if ( ( settings . m_squelch ! = m_settings . m_squelch ) | |
( settings . m_deltaSquelch ! = m_settings . m_deltaSquelch ) | | force )
{
if ( settings . m_deltaSquelch )
{ // input is a value in negative centis
m_squelchLevel = ( - settings . m_squelch ) / 100.0 ;
m_afSquelch . setThreshold ( m_squelchLevel ) ;
m_afSquelch . reset ( ) ;
}
else
{ // input is a value in deci-Bels
m_squelchLevel = std : : pow ( 10.0 , settings . m_squelch / 10.0 ) ;
m_movingAverage . reset ( ) ;
}
m_squelchCount = 0 ; // reset squelch open counter
}
if ( ( settings . m_ctcssIndex ! = m_settings . m_ctcssIndex ) | | force ) {
setSelectedCtcssIndex ( settings . m_ctcssIndex ) ;
}
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if ( ( settings . m_dcsCode ! = m_settings . m_dcsCode ) | |
( settings . m_dcsPositive ! = m_settings . m_dcsPositive ) | | force )
{
setSelectedDcsCode ( settings . m_dcsCode , settings . m_dcsPositive ) ;
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}
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m_settings = settings ;
}
void NFMDemodSink : : applyAudioSampleRate ( unsigned int sampleRate )
{
qDebug ( " NFMDemodSink::applyAudioSampleRate: %u m_channelSampleRate: %d " , sampleRate , m_channelSampleRate ) ;
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m_filterTaps = ( sampleRate / 48 ) | 1 ;
m_ctcssLowpass . create ( ( CTCSS_DETECTOR_RATE / 48 ) | 1 , CTCSS_DETECTOR_RATE , 250.0 ) ;
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m_bandpass . create ( m_filterTaps , sampleRate , 300.0 , m_settings . m_afBandwidth ) ;
m_lowpass . create ( m_filterTaps , sampleRate , m_settings . m_afBandwidth ) ;
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m_squelchGate = ( sampleRate / 100 ) * m_settings . m_squelchGate ; // gate is given in 10s of ms at 48000 Hz audio sample rate
m_squelchCount = 0 ; // reset squelch open counter
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m_ctcssDetector . setCoefficients ( sampleRate / 16 , CTCSS_DETECTOR_RATE ) ; // 0.5s / 2 Hz resolution
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if ( sampleRate < 16000 ) {
m_afSquelch . setCoefficients ( sampleRate / 2000 , 600 , sampleRate , 200 , 0 , afSqTones_lowrate ) ; // 0.5ms test period, 300ms average span, audio SR, 100ms attack, no decay
} else {
m_afSquelch . setCoefficients ( sampleRate / 2000 , 600 , sampleRate , 200 , 0 , afSqTones ) ; // 0.5ms test period, 300ms average span, audio SR, 100ms attack, no decay
}
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m_afSquelch . setThreshold ( m_squelchLevel ) ;
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m_phaseDiscri . setFMScaling ( Real ( sampleRate ) / ( 2.0f * m_settings . m_fmDeviation ) ) ;
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m_audioFifo . setSize ( sampleRate ) ;
m_squelchDelayLine . resize ( sampleRate / 2 ) ;
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m_interpolatorDistance = Real ( m_channelSampleRate ) / Real ( sampleRate ) ;
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m_interpolatorDistanceRemain = m_interpolatorDistance ;
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m_audioSampleRate = sampleRate ;
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QList < ObjectPipe * > pipes ;
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MainCore : : instance ( ) - > getMessagePipes ( ) . getMessagePipes ( m_channel , " reportdemod " , pipes ) ;
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if ( pipes . size ( ) > 0 )
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{
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for ( const auto & pipe : pipes )
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{
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MessageQueue * messageQueue = qobject_cast < MessageQueue * > ( pipe - > m_element ) ;
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MainCore : : MsgChannelDemodReport * msg = MainCore : : MsgChannelDemodReport : : create ( m_channel , sampleRate ) ;
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messageQueue - > push ( msg ) ;
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}
}
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}