public int setSignals(Signals signals)
{
if ((signals != null) &&
(signals.NrLeads > 0))
{
// Decide wich encoding to use.
switch (_EncodingType)
{
case EncodingType.None:
((SCPSection2)_Default[2]).UseNoHuffman();
break;
case EncodingType.OptimizedHuffman:
// not implemented!
((SCPSection2)_Default[2]).UseStandard();
break;
case EncodingType.DefaultHuffman:
default:
((SCPSection2)_Default[2]).UseStandard();
break;
}
if (((ISignal)_Default[3]).setSignals(signals) != 0)
{
return(2);
}
SCPSection5 median = (SCPSection5)_Default[5];
median.setAVM(signals.MedianAVM);
median.setSamplesPerSecond(signals.MedianSamplesPerSecond);
SCPSection6 rhythm = (SCPSection6)_Default[6];
rhythm.setAVM(signals.RhythmAVM);
rhythm.setSamplesPerSecond(signals.RhythmSamplesPerSecond);
short[][] rhythmData = new short[signals.NrLeads][];
short[][] medianData = new short[signals.NrLeads][];
for (int loper = 0; loper < signals.NrLeads; loper++)
{
if (signals[loper].Rhythm == null)
{
return(4);
}
rhythmData[loper] = signals[loper].Rhythm;
if ((medianData == null) ||
(signals[loper].Median == null))
{
medianData = null;
}
else
{
medianData[loper] = signals[loper].Median;
}
}
if (medianData != null)
{
if (((ISignal)_Default[4]).setSignals(signals) != 0)
{
return(8);
}
if (signals.MedianSamplesPerSecond < signals.RhythmSamplesPerSecond)
{
median.setSamplesPerSecond(signals.RhythmSamplesPerSecond);
ECGTool.ResampleSignal(medianData, signals.MedianSamplesPerSecond, signals.RhythmSamplesPerSecond, out medianData);
}
if (median.EncodeData(medianData, (SCPSection2)_Default[2], (ushort)((signals.MedianLength * signals.MedianSamplesPerSecond) / 1000), (_EncodingType == EncodingType.None ? (byte)0 : _DifferenceDataSection5Used)) != 0)
{
return(16);
}
if (signals.QRSZone != null)
{
if (signals.RhythmAVM <= signals.MedianAVM)
{
ECGTool.ChangeMultiplier(medianData, signals.MedianAVM, signals.RhythmAVM);
}
else
{
ECGTool.ChangeMultiplier(rhythmData, signals.RhythmAVM, signals.MedianAVM);
rhythm.setAVM(signals.MedianAVM);
}
}
ECGTool.ResampleSignal(rhythmData, signals.RhythmSamplesPerSecond, median.getSamplesPerSecond(), out rhythmData);
if (_QRSSubtractionSupport &&
(signals.QRSZone != null))
{
((SCPSection3)_Default[3]).setMediansUsed(true);
((SCPSection4)_Default[4]).SubtractMedians((SCPSection3)_Default[3], rhythmData, medianData);
}
}
if (_BimodalCompressionUsed &&
(_BimodalCompressionRate > 0) &&
(medianData != null) &&
(signals.QRSZone != null))
{
// Bimodal Compression must be set in set section 6.
rhythm.setBimodal(true);
rhythm.setSamplesPerSecond(signals.MedianSamplesPerSecond / _BimodalCompressionRate);
// Determine QRS zones for bimodal compression
GlobalMeasurements global;
((IGlobalMeasurement)_Default[7]).getGlobalMeasurements(out global);
((SCPSection4)_Default[4]).setProtected(global, median.getSamplesPerSecond(), _BimodalCompressionRate, ((SCPSection3)_Default[3]).getMinBegin(), ((SCPSection3)_Default[3]).getMaxEnd());
}
if (rhythm.EncodeData(rhythmData, (SCPSection2)_Default[2], (SCPSection3)_Default[3], (SCPSection4)_Default[4], signals.MedianSamplesPerSecond, (_EncodingType == EncodingType.None ? (byte)0 : _DifferenceDataSection6Used)) != 0)
{
return(32);
}
return(0);
}
return(1);
}
public int getSignalsToObj(Signals signals)
{
if (signals != null)
{
if (((ISignal)_Default[3]).getSignalsToObj(signals) != 0)
{
return(2);
}
short[][] medianData = null;
if (((ISignal)_Default[4]).getSignalsToObj(signals) == 0)
{
SCPSection5 median = (SCPSection5)_Default[5];
if (median == null)
{
return(4);
}
medianData = median.DecodeData((SCPSection2)_Default[2], signals.MedianLength);
signals.MedianAVM = median.getAVM();
signals.MedianSamplesPerSecond = median.getSamplesPerSecond();
for (int loper = 0; loper < signals.NrLeads; loper++)
{
signals[loper].Median = medianData[loper];
}
}
else
{
// this will make sure that Decoding of rhythm data will work also for strange files
signals.MedianAVM = 0;
signals.MedianLength = 0;
signals.MedianSamplesPerSecond = 0;
}
SCPSection6 rhythm = (SCPSection6)_Default[6];
short[][] rhythmData = rhythm.DecodeData((SCPSection2)_Default[2], (SCPSection3)_Default[3], (SCPSection4)_Default[4], signals.MedianSamplesPerSecond);
signals.RhythmAVM = rhythm.getAVM();
if (rhythmData == null)
{
return(8);
}
if ((medianData != null) &&
(((SCPSection3)_Default[3]).isMediansUsed()))
{
// check this because corpuls ECG are in violation of this rule, but don't use median subtraction
if (((signals.MedianSamplesPerSecond % signals.RhythmSamplesPerSecond) != 0) ||
((signals.MedianSamplesPerSecond / signals.RhythmSamplesPerSecond) < 1) ||
((signals.MedianSamplesPerSecond / signals.RhythmSamplesPerSecond) > 4))
{
return(16);
}
if (signals.RhythmAVM <= signals.MedianAVM)
{
ECGTool.ChangeMultiplier(medianData, signals.MedianAVM, signals.RhythmAVM);
signals.MedianAVM = signals.RhythmAVM;
}
else
{
ECGTool.ChangeMultiplier(rhythmData, signals.RhythmAVM, signals.MedianAVM);
signals.RhythmAVM = signals.MedianAVM;
}
signals.RhythmSamplesPerSecond = signals.MedianSamplesPerSecond;
((SCPSection4)_Default[4]).AddMedians((SCPSection3)_Default[3], rhythmData, medianData);
}
else
{
signals.RhythmAVM = rhythm.getAVM();
signals.RhythmSamplesPerSecond = rhythm.getSamplesPerSecond();
// Begin: special correction for SCP-ECG by corpuls (part 2)
if ((_Default[5] != null) &&
_Default[5].Works())
{
SCPSection5 medianSpecial = (SCPSection5)_Default[5];
signals.MedianLength = 1000;
signals.MedianAVM = medianSpecial.getAVM();
signals.MedianSamplesPerSecond = medianSpecial.getSamplesPerSecond();
medianData = medianSpecial.DecodeData((SCPSection2)_Default[2], signals.MedianLength);
if (medianData != null)
{
for (int loper = 0; loper < signals.NrLeads; loper++)
{
signals[loper].Median = medianData[loper];
}
}
else
{
signals.MedianLength = 0;
signals.MedianAVM = 0;
signals.MedianSamplesPerSecond = 0;
}
}
// End: special correction for SCP-ECG by corpuls (part 2)
}
for (int loper = 0; loper < signals.NrLeads; loper++)
{
signals[loper].Rhythm = rhythmData[loper];
}
return(0);
}
return(1);
}
