private void FftAnalyzerIf_FftCalculated(object sender, FftEventArgs e)
{
var bin = new FrequencyBins(e,
new BinParameters
{
MinimumIntensityDb = _model.Settings.IfParameter.MinimumIntensityDb,
SamplingRate = 100000000,
BinsPerPoint = IfSpectrumView.SelectedResolution.Resolution,
CalibrationAmplitude = _model.Settings.IfParameter.CalibrationAmplitude,
CalibrationOffset = _model.Settings.IfParameter.CalibrationOffset
});
if (SpectrumAnalyzerIf != null)
{
SpectrumAnalyzerIf.Update(bin);
}
if (Waterfall != null)
{
Waterfall.Update(bin);
}
/*
* if (!VideoFilter)
* bin = new FrequencyBins(e, _model.Radio.BinParametersDefault());
* else
* bin = new FrequencyBins(e, _model.Radio.BinParametersVideoFilter(_model.FftAnalyzerIf.FftLength, VideoPoints));
*/
/*
* FrequencyBins bin = new FrequencyBins(e, new BinParameters
* {
* BinsPerPoint = 4,
* CalibrationAmplitude = 1.1, //1.5,//1.0 in sweeper is better
* CalibrationOffset = 20,//8,
* MinimumIntensityDb = -150,
* Relative = true,
* SamplingRate = 100000000
* });
*/
/*
* if (_model.Settings.AsyncAnalyze)
* TaskUtility.Run(() => Analyze(e, bin));
* else
* Analyze(e, bin);
*
* UpdateSquelch();
*
* if (AutoStep)
* FrequencyStep = (uint)Math.Abs(MeterView.FrequencyErrorValue * 500000);
*
* if (AfcState)
* {
* if (Math.Abs(MeterView.FrequencyErrorValue * 1000000) > _model.Settings.AfcThreshold) //1000 as default
* FrequencyValue = (uint)(MeterView.PeakFrequencyValue * 1000000);
* }
* RecordingView.Tick();
*/
}
private void Analyze(FftEventArgs e, FrequencyBins bin)
{
var detailedBin = _model.Settings.DetailedAnalyze
? new FrequencyBins(e, _model.Radio.BinParametersDetailed())
: bin;
UpdateMeterView(detailedBin);
}
void LiveIf_FftCalculated(object sender, FftEventArgs e)
{
var bin = new FrequencyBins(e, _model.Radio.BinParametersDefault());
Debug.Print("peak at:{0}", bin.MaxIntensityAt());
spectrumAnalyzer.Update(bin);
}
private void FftAnalyzerDdc2_FftCalculated(object sender, FftEventArgs e)
{
var bin = new FrequencyBins(e,
new BinParameters
{
MinimumIntensityDb = _model.Settings.Ddc2Parameter.MinimumIntensityDb,
SamplingRate = _model.Radio.Ddc2(0).DdcArgs().Info.SampleRate,
// CarrierFrequency = (uint)Ddc2AbsoluteFrequency,
BinsPerPoint = Ddc2SpectrumView.SelectedResolution.Resolution,
CalibrationAmplitude = _model.Settings.Ddc2Parameter.CalibrationAmplitude,
CalibrationOffset = _model.Settings.Ddc2Parameter.CalibrationOffset
}, false);
if (SpectrumAnalyzerDdc2 != null)
{
SpectrumAnalyzerDdc2.Update(bin);
}
/*
* FrequencyBins bin = new FrequencyBins(e, new BinParameters
* {
* MinimumIntensityDb = -150,
* SamplingRate = _model.Radio.Ddc2(_index).DdcArgs().Info.SampleRate,
* Relative = true,
* CarrierFrequency = _model.Ddc1Frequency,
* BinsPerPoint = 4,
* CalibrationAmplitude = 1.1, //1.5,//1.0 in sweeper is better
* CalibrationOffset = 20,//8,
* });
*/
// MeterViewDemodulator.Update(e, bin);
MeterViewDemodulator.Update(bin);
SquelchView.UpdateSquelch(MeterViewDemodulator.RmsDbm);
UpdateVolume();
if (AutoStep)
{
FrequencyStep = (uint)Math.Abs(MeterViewDemodulator.FrequencyErrorValue * 500000);
}
if (AfcState)
{
if (Math.Abs(MeterViewDemodulator.FrequencyErrorValue * 1000000) > _model.Settings.AfcThreshold) //1000 as default
{
DemodulatorFrequency = (int)(MeterViewDemodulator.PeakFrequency * 1000000);
}
}
/*
* RecordingView.Tick();
*/
}
public void Update(FftEventArgs e, FrequencyBins bin)
{
if (_model.Settings.AsyncAnalyze)
{
TaskUtility.Run(() => Analyze(e, bin));
}
else
{
Analyze(e, bin);
}
}
public void Update(FrequencyBins bins)
{
var data = bins.Intensities().ToArray();
try
{
Dispatcher.Invoke(new Action(() => _waveform.FeedData(data)));
}
catch (TaskCanceledException)
{
//closing app
}
}
private void UpdateMeterView(FrequencyBins detailedBin)
{
_updateMeterStep++;
_updateMeterStep %= _model.Settings.MeterUpdateSpeed; //5;
if (_updateMeterStep != 0)
{
return;
}
MeterView.PeakFrequencyValue = (detailedBin.MaxIntensityAt() / 1000000);
MeterView.FrequencyErrorValue = (detailedBin.MaxIntensityAt() - FrequencyValue) / 1000000;
MeterView.PowerDbmValue = _model.Radio.Demodulator().SignalStrength();
MeterView.PowerUVoltsValue = RfMath.DbmToMicroVolts(_model.Radio.Demodulator().SignalStrength());
MeterView.PowerWattsValue = RfMath.DbmToMicroWatts(_model.Radio.Demodulator().SignalStrength());
MeterView.SMeterValue = RfMath.DbmToSUnit(_model.Radio.Demodulator().SignalStrength());
}
private void FftAnalyzer_FftCalculated(object sender, FftEventArgs e)
{
FrequencyBins bin;
// _spectrumAnalyzer.Clear();
if (!VideoFilter)
{
bin = new FrequencyBins(e, _model.Radio.BinParametersDefault());
}
else
{
bin = new FrequencyBins(e,
_model.Radio.BinParametersVideoFilter(_model.FftAnalyzer.FftLength, VideoPoints));
}
SpectrumAnalyzer.Update(bin);
if (_model.Settings.AsyncAnalyze)
{
TaskUtility.Run(() => Analyze(e, bin));
}
else
{
Analyze(e, bin);
}
UpdateSquelch();
if (AutoStep)
{
FrequencyStep = (uint)Math.Abs(MeterView.FrequencyErrorValue * 500000);
}
if (AfcState)
{
if (Math.Abs(MeterView.FrequencyErrorValue * 1000000) > _model.Settings.AfcThreshold) //1000 as default
{
FrequencyValue = (uint)(MeterView.PeakFrequencyValue * 1000000);
}
}
RecordingView.Tick();
}
private void UpdateMeterView(FrequencyBins detailedBin)
{
_updateMeterStep++;
_updateMeterStep %= _model.Settings.MeterUpdateSpeed; //5;
if (_updateMeterStep != 0)
{
return;
}
Signal = _model.Ddc2[_channel].Signal;
PeakFrequency = detailedBin.MaxIntensityAt() / 1000000.0;
PeakPower = detailedBin.MaxIntensity();
FrequencyErrorValue = detailedBin.MaxIntensityAt() / 1000000;
PowerDbmValue = PeakDbm;
PowerUVoltsValue = RfMath.DbmToMicroVolts(PeakDbm);
PowerWattsValue = RfMath.DbmToMicroWatts(PeakDbm);
SMeterValue = RfMath.DbmToSUnit(PeakDbm);
}
private SweepedFrequency SweepFrequency(FrequencyBins bin, double f)
{
var current = bin.Intensity(f);
var min = current;
var max = current;
if (!_current.ContainsKey(f))
{
_current.Add(f, current);
}
else
{
_current[f] = current;
}
if (!_min.ContainsKey(f))
{
_min.Add(f, current);
}
else
{
min = Math.Min(_min[f], current);
_min[f] = min;
}
if (!_max.ContainsKey(f))
{
_max.Add(f, current);
}
else
{
max = Math.Max(_max[f], current);
_max[f] = max;
}
var data = new SweepedFrequency(f, min, max, current);
return(data);
}
private void SweepBins(FftEventArgs e)
{
//mark frequencies based on current IF2 in [-10Khz, 10KHz] domain
var bin = new FrequencyBins(e, /*_radio.BinParametersDefault()*/ _radio.BinParametersWideSpectrum());
var frequency = _radio.Frequency();
var minFrequency = frequency - _sweepParameters.SweepSpan;
var maxFrequency = frequency + _sweepParameters.SweepSpan;
var sweeped = new List <SweepedFrequency>();
var frequnecies = bin.Frequencies();
foreach (var f in frequnecies)
{
if (f > _lastFrequency && f >= minFrequency && f <= maxFrequency)
{
_lastFrequency = f;
var data = SweepFrequency(bin, f);
sweeped.Add(data);
}
}
OnFrequencySweeped(sweeped, frequency, _sweepParameters.Precision);
}
public void Update(FrequencyBins bin)
{
if (bin.BinsCount != _bins)
{
_bins = bin.BinsCount;
CalculateXScale();
}
var intensities = bin.Intensities().ToArray();
for (int n = 0; n < bin.BinsCount - _binsPerPoint; n += 1)
{
// averaging out bins
double yPos = 0;
for (int b = 0; b < _binsPerPoint; b++)
{
yPos += GetYPosLog(intensities[n + b], bin.MinimumIntensity);
}
AddResult(n / _binsPerPoint, yPos / _binsPerPoint);
}
Draw(bin.SpectralWidth);
}
private void FftAnalyzer_FftCalculated(object sender, FftEventArgs e)
{
FrequencyBins bin;
spectrumAnalyzer.Clear();
if (!_model.VideoFilter)
{
bin = new FrequencyBins(e, _model.Radio.BinParametersDefault());
}
else
{
bin = new FrequencyBins(e,
_model.Radio.BinParametersVideoFilter(_model.FftAnalyzer.FftLength, _model.VideoPoints));
}
Debug.Print("peak at:{0}: {1}", bin.MaxIntensityAt(), bin.MaxIntensity());
spectrumAnalyzer.Update(bin);
TaskUtility.Run(() =>
{
Invoke(new Action(() =>
{
try
{
labelPeakFrequency.Text = (bin.MaxIntensityAt() / 1000000).ToString();
labelFrequenccyError.Text =
((bin.MaxIntensityAt() - (double)numericUpDownFrequency.Value) / 1000000).ToString();
labelPowerDbm.Text = _model.Radio.Demodulator().SignalStrength().ToString();
labelPowerUVolt.Text =
RfMath.DbmToMicroVolts(_model.Radio.Demodulator().SignalStrength()).ToString();
}
catch
{
}
}));
});
}
public void Update(FrequencyBins bin)
{
UpdateMeterView(bin);
}
