///////////////////////////////////////////////////////////////////////////////////
// Copyright (C) 2017 F4HKW //
// for F4EXB / 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 as version 3 of the License, or //
// //
// 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 . //
///////////////////////////////////////////////////////////////////////////////////
#include "atvdemod.h"
#include
#include
#include
#include
#include "audio/audiooutput.h"
#include "dsp/dspengine.h"
#include "dsp/pidcontroller.h"
MESSAGE_CLASS_DEFINITION(ATVDemod::MsgConfigureATVDemod, Message)
MESSAGE_CLASS_DEFINITION(ATVDemod::MsgConfigureRFATVDemod, Message)
MESSAGE_CLASS_DEFINITION(ATVDemod::MsgReportEffectiveSampleRate, Message)
const float ATVDemod::m_fltSecondToUs = 1000000.0f;
const int ATVDemod::m_ssbFftLen = 1024;
ATVDemod::ATVDemod() :
m_objSettingsMutex(QMutex::NonRecursive),
m_objRegisteredATVScreen(NULL),
m_intImageIndex(0),
m_intColIndex(0),
m_intRowIndex(0),
m_intSynchroPoints(0),
m_blnSynchroDetected(false),
m_blnLineSynchronized(false),
m_blnVerticalSynchroDetected(false),
m_intRowsLimit(0),
m_blnImageDetecting(false),
m_fltEffMin(2000000000.0f),
m_fltEffMax(-2000000000.0f),
m_fltAmpMin(-2000000000.0f),
m_fltAmpMax(2000000000.0f),
m_fltAmpDelta(1.0),
m_fltAmpLineAverage(0.0f),
m_intNumberSamplePerTop(0),
m_bfoPLL(200/1000000, 100/1000000, 0.01),
m_bfoFilter(200.0, 1000000.0, 0.9),
m_interpolatorDistanceRemain(0.0f),
m_interpolatorDistance(1.0f),
m_DSBFilter(0),
m_DSBFilterBuffer(0),
m_DSBFilterBufferIndex(0)
{
setObjectName("ATVDemod");
//*************** ATV PARAMETERS ***************
m_intNumberSamplePerLine=0;
m_intSynchroPoints=0;
m_intNumberOfLines=0;
m_intNumberOfRowsToDisplay=0;
m_objMagSqAverage.resize(32, 1.0);
m_DSBFilter = new fftfilt((2.0f * m_objRFConfig.m_fltRFBandwidth) / 1000000, 2 * m_ssbFftLen); // arbitrary 1 MS/s sample rate
m_DSBFilterBuffer = new Complex[m_ssbFftLen];
memset(m_DSBFilterBuffer, 0, sizeof(Complex)*(m_ssbFftLen));
memset((void*)m_fltBufferI,0,6*sizeof(float));
memset((void*)m_fltBufferQ,0,6*sizeof(float));
}
ATVDemod::~ATVDemod()
{
}
void ATVDemod::setATVScreen(ATVScreen *objScreen)
{
m_objRegisteredATVScreen = objScreen;
}
void ATVDemod::configure(
MessageQueue* objMessageQueue,
float fltLineDurationUs,
float fltTopDurationUs,
float fltFramePerS,
float fltRatioOfRowsToDisplay,
float fltVoltLevelSynchroTop,
float fltVoltLevelSynchroBlack,
bool blnHSync,
bool blnVSync,
bool blnInvertVideo)
{
Message* msgCmd = MsgConfigureATVDemod::create(
fltLineDurationUs,
fltTopDurationUs,
fltFramePerS,
fltRatioOfRowsToDisplay,
fltVoltLevelSynchroTop,
fltVoltLevelSynchroBlack,
blnHSync,
blnVSync,
blnInvertVideo);
objMessageQueue->push(msgCmd);
}
void ATVDemod::configureRF(
MessageQueue* objMessageQueue,
ATVModulation enmModulation,
float fltRFBandwidth,
float fltRFOppBandwidth,
bool blnFFTFiltering,
bool blnDecimatorEnable,
float fltBFOFrequency)
{
Message* msgCmd = MsgConfigureRFATVDemod::create(
enmModulation,
fltRFBandwidth,
fltRFOppBandwidth,
blnFFTFiltering,
blnDecimatorEnable,
fltBFOFrequency);
objMessageQueue->push(msgCmd);
}
void ATVDemod::feed(const SampleVector::const_iterator& begin, const SampleVector::const_iterator& end, bool firstOfBurst)
{
float fltDivSynchroBlack = 1.0f - m_objRunning.m_fltVoltLevelSynchroBlack;
float fltI;
float fltQ;
float fltNormI;
float fltNormQ;
Complex ci;
float fltNorm=0.00f;
float fltVal;
int intVal;
qint16 * ptrBufferToRelease = 0;
bool blnComputeImage=false;
int intSynchroTimeSamples= (3*m_intNumberSamplePerLine)/4;
float fltSynchroTrameLevel = 0.5f*((float)intSynchroTimeSamples) * m_objRunning.m_fltVoltLevelSynchroBlack;
//********** Let's rock and roll buddy ! **********
m_objSettingsMutex.lock();
//********** Accessing ATV Screen context **********
if(m_intImageIndex==0)
{
if(m_intNumberOfLines%2==1)
{
m_intRowsLimit = m_intNumberOfLines;
}
else
{
m_intRowsLimit = m_intNumberOfLines-2;
}
}
#ifdef EXTENDED_DIRECT_SAMPLE
qint16 * ptrBuffer;
qint32 intLen;
//********** Reading direct samples **********
SampleVector::const_iterator it = begin;
intLen = it->intLen;
ptrBuffer = it->ptrBuffer;
ptrBufferToRelease = ptrBuffer;
++it;
for(qint32 intInd=0; intIndreal();
fltQ = it->imag();
#endif
Complex c(fltI, fltQ);
if (m_objRFRunning.m_intFrequencyOffset != 0)
{
c *= m_nco.nextIQ();
}
if (m_objRFRunning.m_blndecimatorEnable)
{
if (m_interpolator.decimate(&m_interpolatorDistanceRemain, c, &ci))
{
demod(ci);
m_interpolatorDistanceRemain += m_interpolatorDistance;
}
}
else
{
demod(c);
}
}
if (ptrBufferToRelease != 0)
{
delete ptrBufferToRelease;
}
m_objSettingsMutex.unlock();
}
void ATVDemod::demod(Complex& c)
{
float fltDivSynchroBlack = 1.0f - m_objRunning.m_fltVoltLevelSynchroBlack;
int intSynchroTimeSamples= (3*m_intNumberSamplePerLine)/4;
float fltSynchroTrameLevel = 0.5f*((float)intSynchroTimeSamples) * m_objRunning.m_fltVoltLevelSynchroBlack;
float fltNormI;
float fltNormQ;
float fltNorm;
float fltVal;
int intVal;
//********** FFT filtering **********
if (m_objRFRunning.m_blnFFTFiltering)
{
int n_out;
fftfilt::cmplx *filtered;
n_out = m_DSBFilter->runAsym(c, &filtered, m_objRFRunning.m_enmModulation != ATV_LSB); // all usb except explicitely lsb
if (n_out > 0)
{
memcpy((void *) m_DSBFilterBuffer, (const void *) filtered, n_out*sizeof(Complex));
m_DSBFilterBufferIndex = 0;
}
m_DSBFilterBufferIndex++;
}
//********** demodulation **********
#if defined(_WINDOWS_)
float fltI = m_objRFRunning.m_blnFFTFiltering ? m_DSBFilterBuffer[m_DSBFilterBufferIndex-1].real() : c.real();
float fltQ = m_objRFRunning.m_blnFFTFiltering ? m_DSBFilterBuffer[m_DSBFilterBufferIndex-1].imag() : c.imag();
#else
float& fltI = m_objRFRunning.m_blnFFTFiltering ? m_DSBFilterBuffer[m_DSBFilterBufferIndex-1].real() : c.real();
float& fltQ = m_objRFRunning.m_blnFFTFiltering ? m_DSBFilterBuffer[m_DSBFilterBufferIndex-1].imag() : c.imag();
#endif
double magSq = fltI*fltI + fltQ*fltQ;
m_objMagSqAverage.feed(magSq);
fltNorm = sqrt(magSq);
if ((m_objRFRunning.m_enmModulation == ATV_FM1) || (m_objRFRunning.m_enmModulation == ATV_FM2))
{
//Amplitude FM
fltNormI= fltI/fltNorm;
fltNormQ= fltQ/fltNorm;
//-2 > 2 : 0 -> 1 volt
//0->0.3 synchro 0.3->1 image
if (m_objRFRunning.m_enmModulation == ATV_FM1)
{
//YDiff Cd
fltVal = m_fltBufferI[0]*(fltNormQ - m_fltBufferQ[1]);
fltVal -= m_fltBufferQ[0]*(fltNormI - m_fltBufferI[1]);
fltVal += 2.0f;
fltVal /=4.0f;
}
else
{
//YDiff Folded
fltVal = m_fltBufferI[2]*((m_fltBufferQ[5]-fltNormQ)/16.0f + m_fltBufferQ[1] - m_fltBufferQ[3]);
fltVal -= m_fltBufferQ[2]*((m_fltBufferI[5]-fltNormI)/16.0f + m_fltBufferI[1] - m_fltBufferI[3]);
fltVal += 2.125f;
fltVal /=4.25f;
m_fltBufferI[5]=m_fltBufferI[4];
m_fltBufferQ[5]=m_fltBufferQ[4];
m_fltBufferI[4]=m_fltBufferI[3];
m_fltBufferQ[4]=m_fltBufferQ[3];
m_fltBufferI[3]=m_fltBufferI[2];
m_fltBufferQ[3]=m_fltBufferQ[2];
m_fltBufferI[2]=m_fltBufferI[1];
m_fltBufferQ[2]=m_fltBufferQ[1];
}
m_fltBufferI[1]=m_fltBufferI[0];
m_fltBufferQ[1]=m_fltBufferQ[0];
m_fltBufferI[0]=fltNormI;
m_fltBufferQ[0]=fltNormQ;
}
else if (m_objRFRunning.m_enmModulation == ATV_AM)
{
//Amplitude AM
fltVal = fltNorm;
//********** Mini and Maxi Amplitude tracking **********
if(fltValm_fltEffMax)
{
m_fltEffMax=fltVal;
}
//Normalisation
fltVal -= m_fltAmpMin;
fltVal /=m_fltAmpDelta;
}
else if ((m_objRFRunning.m_enmModulation == ATV_USB) || (m_objRFRunning.m_enmModulation == ATV_LSB))
{
Real bfoValues[2];
float fltFiltered = m_bfoFilter.run(fltI);
m_bfoPLL.process(fltFiltered, bfoValues);
// do the mix
float mixI = fltI * bfoValues[0] - fltQ * bfoValues[1];
float mixQ = fltI * bfoValues[1] + fltQ * bfoValues[0];
if (m_objRFRunning.m_enmModulation == ATV_USB) {
fltVal = (mixI + mixQ);
} else {
fltVal = (mixI - mixQ);
}
//********** Mini and Maxi Amplitude tracking **********
if(fltValm_fltEffMax)
{
m_fltEffMax=fltVal;
}
//Normalisation
fltVal -= m_fltAmpMin;
fltVal /=m_fltAmpDelta;
}
else
{
fltVal = 0.0f;
}
fltVal = m_objRunning.m_blnInvertVideo ? 1.0f - fltVal : fltVal;
m_fltAmpLineAverage += fltVal;
//********** gray level **********
//-0.3 -> 0.7
intVal = (int) 255.0*(fltVal - m_objRunning.m_fltVoltLevelSynchroBlack) / fltDivSynchroBlack;
//0 -> 255
if(intVal<0)
{
intVal=0;
}
else if(intVal>255)
{
intVal=255;
}
//********** Filling pixels **********
bool blnComputeImage = (m_objRunning.m_fltRatioOfRowsToDisplay != 0.5f);
if (!blnComputeImage)
{
blnComputeImage = ((m_intImageIndex/2) % 2 == 0);
}
if (blnComputeImage)
{
m_objRegisteredATVScreen->setDataColor(m_intColIndex,intVal, intVal, intVal);
}
m_intColIndex++;
//////////////////////
m_blnSynchroDetected=false;
if((m_objRunning.m_blnHSync) && (m_intRowIndex>1))
{
//********** Line Synchro 0-0-0 -> 0.3-0.3 0.3 **********
if(m_blnImageDetecting==false)
{
//Floor Detection 0
if (fltVal <= m_objRunning.m_fltVoltLevelSynchroTop)
{
m_intSynchroPoints ++;
}
else
{
m_intSynchroPoints=0;
}
if(m_intSynchroPoints>=m_intNumberSamplePerTop)
{
m_blnSynchroDetected=true;
m_blnImageDetecting=true;
m_intSynchroPoints=0;
}
}
else
{
//Image detection Sub Black 0.3
if (fltVal >= m_objRunning.m_fltVoltLevelSynchroBlack)
{
m_intSynchroPoints ++;
}
else
{
m_intSynchroPoints=0;
}
if(m_intSynchroPoints>=m_intNumberSamplePerTop)
{
m_blnSynchroDetected=false;
m_blnImageDetecting=false;
m_intSynchroPoints=0;
}
}
}
//********** Rendering if necessary **********
// Vertical Synchro : 3/4 a line necessary
if(!m_blnVerticalSynchroDetected && m_objRunning.m_blnVSync)
{
if(m_intColIndex>=intSynchroTimeSamples)
{
if(m_fltAmpLineAverage<=fltSynchroTrameLevel) //(m_fltLevelSynchroBlack*(float)(m_intColIndex-((m_intNumberSamplePerLine*12)/64)))) //75
{
m_blnVerticalSynchroDetected=true;
m_intRowIndex=m_intImageIndex%2;
if(blnComputeImage)
{
m_objRegisteredATVScreen->selectRow(m_intRowIndex);
}
}
}
}
//Horizontal Synchro
if((m_intColIndex>=m_intNumberSamplePerLine)
|| (m_blnSynchroDetected==true))
{
m_blnSynchroDetected=false;
m_blnImageDetecting=true;
m_intColIndex=0;
if((m_blnSynchroDetected==false) || (m_blnLineSynchronized==true))
{
//New line + Interleaving
m_intRowIndex ++;
m_intRowIndex ++;
if(m_intRowIndexselectRow(m_intRowIndex);
}
m_blnLineSynchronized=false;
}
else
{
m_blnLineSynchronized=m_blnSynchroDetected;
}
m_fltAmpLineAverage=0.0f;
}
//////////////////////
if(m_intRowIndex>=m_intRowsLimit)
{
m_blnVerticalSynchroDetected=false;
m_fltAmpLineAverage=0.0f;
//Interleave Odd/Even images
m_intRowIndex=m_intImageIndex%2;
m_intColIndex=0;
if(blnComputeImage)
{
m_objRegisteredATVScreen->selectRow(m_intRowIndex);
}
//Rendering when odd image processed
if(m_intImageIndex%2==1)
{
//interleave
if(blnComputeImage)
{
m_objRegisteredATVScreen->renderImage(NULL);
}
m_intRowsLimit = m_intNumberOfLines-1;
if (m_objRFRunning.m_enmModulation == ATV_AM)
{
m_fltAmpMin=m_fltEffMin;
m_fltAmpMax=m_fltEffMax;
m_fltAmpDelta=m_fltEffMax-m_fltEffMin;
if(m_fltAmpDelta<=0.0)
{
m_fltAmpDelta=1.0f;
}
//Reset extrema
m_fltEffMin=2000000.0f;
m_fltEffMax=-2000000.0f;
}
}
else
{
if(m_intNumberOfLines%2==1)
{
m_intRowsLimit = m_intNumberOfLines;
}
else
{
m_intRowsLimit = m_intNumberOfLines-2;
}
}
m_intImageIndex ++;
}
}
void ATVDemod::start()
{
//m_objTimer.start();
}
void ATVDemod::stop()
{
}
bool ATVDemod::handleMessage(const Message& cmd)
{
qDebug() << "ATVDemod::handleMessage";
if (DownChannelizer::MsgChannelizerNotification::match(cmd))
{
DownChannelizer::MsgChannelizerNotification& objNotif = (DownChannelizer::MsgChannelizerNotification&) cmd;
m_objConfig.m_intSampleRate = objNotif.getSampleRate();
m_objRFConfig.m_intFrequencyOffset = objNotif.getFrequencyOffset();
qDebug() << "ATVDemod::handleMessage: MsgChannelizerNotification:"
<< " m_intSampleRate: " << m_objConfig.m_intSampleRate
<< " m_intFrequencyOffset: " << m_objRFConfig.m_intFrequencyOffset;
applySettings();
return true;
}
else if (MsgConfigureATVDemod::match(cmd))
{
MsgConfigureATVDemod& objCfg = (MsgConfigureATVDemod&) cmd;
m_objConfig = objCfg.m_objMsgConfig;
qDebug() << "ATVDemod::handleMessage: MsgConfigureATVDemod:"
<< " m_fltVoltLevelSynchroBlack:" << m_objConfig.m_fltVoltLevelSynchroBlack
<< " m_fltVoltLevelSynchroTop:" << m_objConfig.m_fltVoltLevelSynchroTop
<< " m_fltFramePerS:" << m_objConfig.m_fltFramePerS
<< " m_fltLineDurationUs:" << m_objConfig.m_fltLineDurationUs
<< " m_fltRatioOfRowsToDisplay:" << m_objConfig.m_fltRatioOfRowsToDisplay
<< " m_fltTopDurationUs:" << m_objConfig.m_fltTopDurationUs
<< " m_blnHSync:" << m_objConfig.m_blnHSync
<< " m_blnVSync:" << m_objConfig.m_blnVSync;
applySettings();
return true;
}
else if (MsgConfigureRFATVDemod::match(cmd))
{
MsgConfigureRFATVDemod& objCfg = (MsgConfigureRFATVDemod&) cmd;
m_objRFConfig = objCfg.m_objMsgConfig;
qDebug() << "ATVDemod::handleMessage: MsgConfigureRFATVDemod:"
<< " m_enmModulation:" << m_objRFConfig.m_enmModulation
<< " m_fltRFBandwidth:" << m_objRFConfig.m_fltRFBandwidth
<< " m_fltRFOppBandwidth:" << m_objRFConfig.m_fltRFOppBandwidth
<< " m_blnFFTFiltering:" << m_objRFConfig.m_blnFFTFiltering
<< " m_blnDecimatorEnable:" << m_objRFConfig.m_blndecimatorEnable
<< " m_fltBFOFrequency:" << m_objRFConfig.m_fltBFOFrequency;
applySettings();
return true;
}
else
{
return false;
}
}
void ATVDemod::applySettings()
{
if (m_objConfig.m_intSampleRate == 0)
{
return;
}
if((m_objRFConfig.m_intFrequencyOffset != m_objRFRunning.m_intFrequencyOffset)
|| (m_objRFConfig.m_enmModulation != m_objRFRunning.m_enmModulation)
|| (m_objConfig.m_intSampleRate != m_objRunning.m_intSampleRate))
{
m_nco.setFreq(-m_objRFConfig.m_intFrequencyOffset, m_objConfig.m_intSampleRate);
}
if ((m_objConfig.m_intSampleRate != m_objRunning.m_intSampleRate)
|| (m_objRFConfig.m_fltRFBandwidth != m_objRFRunning.m_fltRFBandwidth))
{
m_objSettingsMutex.lock();
m_objConfigPrivate.m_intTVSampleRate = (m_objConfig.m_intSampleRate / 1000000) * 1000000; // make sure working sample rate is a multiple of rate units
if (m_objConfigPrivate.m_intTVSampleRate > 0)
{
m_interpolatorDistance = (Real) m_objConfigPrivate.m_intTVSampleRate / (Real) m_objConfig.m_intSampleRate;
}
else
{
m_objConfigPrivate.m_intTVSampleRate = m_objConfig.m_intSampleRate;
m_interpolatorDistance = 1.0f;
}
m_interpolatorDistanceRemain = 0;
m_interpolator.create(24,
m_objConfigPrivate.m_intTVSampleRate,
m_objRFConfig.m_fltRFBandwidth / getRFBandwidthDivisor(m_objRFConfig.m_enmModulation),
3.0);
m_objSettingsMutex.unlock();
}
if((m_objConfig.m_fltFramePerS != m_objRunning.m_fltFramePerS)
|| (m_objConfig.m_fltLineDurationUs != m_objRunning.m_fltLineDurationUs)
|| (m_objConfig.m_intSampleRate != m_objRunning.m_intSampleRate)
|| (m_objConfig.m_fltTopDurationUs != m_objRunning.m_fltTopDurationUs)
|| (m_objConfig.m_fltRatioOfRowsToDisplay != m_objRunning.m_fltRatioOfRowsToDisplay))
{
m_objSettingsMutex.lock();
m_intNumberSamplePerLine = (int) ((m_objConfig.m_fltLineDurationUs * m_objConfig.m_intSampleRate) / m_fltSecondToUs);
m_intNumberOfLines = (int) ((m_fltSecondToUs / m_objConfig.m_fltFramePerS) /round(m_objConfig.m_fltLineDurationUs));
m_objRegisteredATVScreen->resizeATVScreen(m_intNumberSamplePerLine, m_intNumberOfLines);
m_intNumberSamplePerTop = (int) ((m_objConfig.m_fltTopDurationUs * m_objConfig.m_intSampleRate) / m_fltSecondToUs);
m_intNumberOfRowsToDisplay = (int) ((m_objConfig.m_fltRatioOfRowsToDisplay * m_objConfig.m_fltLineDurationUs * m_objConfig.m_intSampleRate) / m_fltSecondToUs);
m_intRowsLimit = m_intNumberOfLines-1;
m_intImageIndex = 0;
m_intColIndex=0;
m_intRowIndex=0;
m_intRowsLimit=0;
m_objSettingsMutex.unlock();
}
if ((m_objConfigPrivate.m_intTVSampleRate != m_objRunningPrivate.m_intTVSampleRate)
|| (m_objConfig.m_intSampleRate != m_objRunning.m_intSampleRate)
|| (m_objRFConfig.m_blndecimatorEnable != m_objRFRunning.m_blndecimatorEnable))
{
int sampleRate = m_objRFConfig.m_blndecimatorEnable ? m_objConfigPrivate.m_intTVSampleRate : m_objConfig.m_intSampleRate;
MsgReportEffectiveSampleRate *report;
report = MsgReportEffectiveSampleRate::create(sampleRate);
getOutputMessageQueue()->push(report);
}
if ((m_objConfigPrivate.m_intTVSampleRate != m_objRunningPrivate.m_intTVSampleRate)
|| (m_objRFConfig.m_fltRFBandwidth != m_objRFRunning.m_fltRFBandwidth)
|| (m_objRFConfig.m_fltRFOppBandwidth != m_objRFRunning.m_fltRFOppBandwidth))
{
m_objSettingsMutex.lock();
m_DSBFilter->create_asym_filter(m_objRFConfig.m_fltRFOppBandwidth / m_objConfigPrivate.m_intTVSampleRate,
m_objRFConfig.m_fltRFBandwidth / m_objConfigPrivate.m_intTVSampleRate);
memset(m_DSBFilterBuffer, 0, sizeof(Complex)*(m_ssbFftLen));
m_DSBFilterBufferIndex = 0;
m_objSettingsMutex.unlock();
}
if ((m_objConfigPrivate.m_intTVSampleRate != m_objRunningPrivate.m_intTVSampleRate)
|| (m_objRFConfig.m_fltBFOFrequency != m_objRFRunning.m_fltBFOFrequency))
{
m_bfoPLL.configure(m_objRFConfig.m_fltBFOFrequency / m_objConfigPrivate.m_intTVSampleRate,
100.0 / m_objConfigPrivate.m_intTVSampleRate,
0.01);
m_bfoFilter.setFrequencies(m_objRFConfig.m_fltBFOFrequency, m_objConfigPrivate.m_intTVSampleRate);
}
m_objRunning = m_objConfig;
m_objRFRunning = m_objRFConfig;
m_objRunningPrivate = m_objConfigPrivate;
}
int ATVDemod::getSampleRate()
{
return m_objRunning.m_intSampleRate;
}
int ATVDemod::getEffectiveSampleRate()
{
return m_objRFRunning.m_blndecimatorEnable ? m_objRunningPrivate.m_intTVSampleRate : m_objRunning.m_intSampleRate;
}
bool ATVDemod::getBFOLocked()
{
if ((m_objRFRunning.m_enmModulation == ATV_USB) || (m_objRFRunning.m_enmModulation == ATV_LSB))
{
return m_bfoPLL.locked();
}
else
{
return false;
}
}
float ATVDemod::getRFBandwidthDivisor(ATVModulation modulation)
{
switch(modulation)
{
case ATV_USB:
case ATV_LSB:
return 1.05f;
break;
case ATV_FM1:
case ATV_FM2:
case ATV_AM:
default:
return 2.2f;
}
}