private void ProcDSPAngle() { this.adBlock = new ADBlock(SampleRate * 2, SampleRate); APFFT apfft = new APFFT(this.SampleRate); try { while (true) { float[] adData = adBlock.GetAdData(-1); if (adData == null) { continue; } this.Angle = apfft.CalAngle(adData); eventDSP.Set(); } } catch (Exception) { } }
private void ProcDSP() { DSPUtil util = new DSPUtil(); FFTPlan fftPlan = null; float[] data1 = null; float[] data2 = null; float[] fftData = null; float[] dataSpectrum = null; int PeakNum = 6; float[] ypDiff = new float[PeakNum - 1]; float[] peakVal = new float[PeakNum]; int[] peakIndexLeft = new int[PeakNum]; int[] peakIndexLeftTmp = new int[PeakNum]; int[] peakIndexRight = new int[PeakNum]; float[] dcacAmpl = new float[2]; float[] amplDense = new float[250]; // float[] amplDenseDC = new float[25]; float dcAmpl = 0; float acAmpl = 0; float prevCarrier = -1; float prevLow = -1; int diffCnt = 0; float carrierFreq = 0; float lowFreq = 0; float standard = 0; SignalArgs args; List <float> curveList = new List <float>(); bool curveStart = false; float[] ypList = new float[] { 8.5f, 9.0f, 9.5f, 11.0f, 12.5f, 13.5f, 15.0f, 16.5f, 17.5f, 18.5f, 20.0f, 21.5f, 22.5f, 23.5f, 24.5f, 26.0f }; Queue <float> queueACCurve = new Queue <float>(); int maxCurveCnt = 0; int MAXPT = 40 * 25; int PRENUM = 5; this.adBlock = new ADBlock(SampleRate, SampleRate); try { while (true) { float[] adData = adBlock.GetAdData(-1); if (SignalArgsChanged == null) { eventDSP.Set(); continue; } if (adData == null) { continue; } if (DecodeCurve > 0) //计算道岔曲线 ,不计算载频和低频 { int calCnt = (int)(1000 / this.TimeInterval); int amplCnt = this.SampleRate / calCnt; //40ms一个点 for (int i = 0; i < calCnt; i++) { if (DecodeCurve == 1) { amplDense[i] = util.CalACAmpl(adData, i * amplCnt, amplCnt); amplDense[i] = CalRealVal(amplDense[i], 50); //道岔电流都是交流50Hz } else if (DecodeCurve == 2) { amplDense[i] = util.CalDCAmpl(adData, i * amplCnt, amplCnt); amplDense[i] = CalRealVal(amplDense[i], 0); } if (curveStart == false) { if (queueACCurve.Count >= PRENUM) { float[] prevVals = queueACCurve.ToArray(); for (int j = 0; j < prevVals.Length - 1; j++) { if (prevVals[j] > 0.001f) { float rate = (prevVals[prevVals.Length - 1] - prevVals[j]) / prevVals[j]; if (rate > 5) { curveStart = true; curveList.AddRange(prevVals); maxCurveCnt = MAXPT; break; } } } } } else { curveList.Add(amplDense[i]); if (amplDense[i] < 0.06f) { if (maxCurveCnt >= MAXPT) { maxCurveCnt = curveList.Count + 5; } } if (curveList.Count >= maxCurveCnt) //最大40秒 { args = new SignalArgs(recordFile.TimeExport.AddMilliseconds(-1 * this.TimeInterval * curveList.Count + i * 1000f / calCnt), curveList.ToArray()); SignalArgsChanged(this, args); curveStart = false; maxCurveCnt = 0; curveList.Clear(); queueACCurve.Clear(); } } if (queueACCurve.Count >= PRENUM) { queueACCurve.Dequeue(); } queueACCurve.Enqueue(amplDense[i]); } eventDSP.Set(); continue; } if (fftPlan == null) { fftPlan = new FFTPlan(SampleRate); data1 = new float[SampleRate * 2]; data2 = new float[SampleRate * 2]; fftData = new float[SampleRate * 2]; dataSpectrum = new float[SampleRate]; } //将实数变为复数 for (int i = 0; i < adData.Length; i++) { data1[i * 2] = adData[i]; data1[i * 2 + 1] = 0; } fftPlan.FFTForward(data1, fftData); Array.Copy(fftData, data2, data2.Length); //计算频谱 int spectrumLen = adData.Length / 2; for (int i = 0; i < spectrumLen; i++) { dataSpectrum[i] = (float)Math.Sqrt(data2[i * 2] * data2[i * 2] + data2[i * 2 + 1] * data2[i * 2 + 1]); } //计算交直流幅度 util.CalDCACAmpl(adData, 0, this.SampleRate, dcacAmpl); dcAmpl = CalRealVal(dcacAmpl[0], 0); acAmpl = CalRealVal(dcacAmpl[1], 0); int ignoreLow = DecodeFM?400: 5; int ignoreHigh = DecodeFM ? 3000 : this.SampleRate / 2; util.FindComplexPeaks(data2, ignoreLow, ignoreHigh, peakVal, peakIndexLeft); //忽略直流信息 // int freqCenter= util.CalFreqCenter(dataSpectrum, 400); if (peakIndexLeft[0] < 0) { args = new SignalArgs(recordFile.TimeExport, dcAmpl, acAmpl, 0, 0); SignalArgsChanged(this, args); eventDSP.Set(); continue; //不存在极点 } float freq = peakIndexLeft[0]; acAmpl = CalAmplByFreq(fftData, (int)freq); acAmpl = CalRealVal(acAmpl, freq); if (DecodeFM == false) { args = new SignalArgs(recordFile.TimeExport, dcAmpl, acAmpl, 0, 0); SignalArgsChanged(this, args); eventDSP.Set(); continue; } if (DecodeFM) { if (acAmpl < 0.1) { eventDSP.Set(); continue; } bool matchYP = true; bool matchUM71 = true; float freqShift = 0; int underSampleCount = 1; for (int i = 0; i < peakIndexLeft.Length; i++) { if ((peakIndexLeft[i] < 1600 - 200) || (peakIndexLeft[i] > 2600 + 200)) { matchUM71 = false; } if ((peakIndexLeft[i] < 550 - 100) || (peakIndexLeft[i] > 850 + 100)) { matchYP = false; } } if ((matchYP == false) && (matchUM71 == false)) { carrierFreq = peakIndexLeft[0]; lowFreq = 0; } if (matchYP) { float tmpShiftDiff = float.MaxValue; for (int i = 0; i < peakIndexLeft.Length - 2; i++) { for (int j = i + 1; j < peakIndexLeft.Length - 1; j++) { float tmpShift = (peakIndexLeft[i] + peakIndexLeft[j]) / 2f; if (Math.Abs(tmpShift - 550) < tmpShiftDiff) { freqShift = tmpShift; tmpShiftDiff = Math.Abs(tmpShift - 550); } if (Math.Abs(tmpShift - 650) < tmpShiftDiff) { freqShift = tmpShift; tmpShiftDiff = Math.Abs(tmpShift - 650); } if (Math.Abs(tmpShift - 750) < tmpShiftDiff) { freqShift = tmpShift; tmpShiftDiff = Math.Abs(tmpShift - 750); } if (Math.Abs(tmpShift - 850) < tmpShiftDiff) { freqShift = tmpShift; tmpShiftDiff = Math.Abs(tmpShift - 850); } } } util.FindComplexPeaks(data2, (int)freqShift, ignoreHigh, peakVal, peakIndexLeft); standard = Math.Abs(peakIndexLeft[0] - peakIndexLeft[1]); underSampleCount = 30; } if (matchUM71) { freqShift = peakIndexLeft[0] - 40; underSampleCount = 40; } util.ShiftSignal(data1, freqShift, this.SampleRate); //频谱搬移 util.ComplexFilter(data1, data2); //滤波 util.UnderSample(data2, underSampleCount); //欠采样 fftPlan.FFTForward(data2, data1); //频谱分析 if (matchYP) { int signalLength = data1.Length / 2; util.FindComplexPeaks(data1, 0, signalLength / 2, peakVal, peakIndexLeft); float diffMinYp = 1.5f; //最大不能差1.5 lowFreq = -1; for (int j = 0; j < peakIndexLeft.Length - 1; j++) { for (int k = j + 1; k < peakIndexLeft.Length; k++) { float tmpLow = Math.Abs(peakIndexLeft[k] - peakIndexLeft[j]) * 1f / underSampleCount; if (tmpLow > 8 && tmpLow < 28) { if (Math.Abs(tmpLow - standard) < diffMinYp) { lowFreq = tmpLow; diffMinYp = Math.Abs(tmpLow - standard); } } } if (lowFreq > 0) { break; } } util.FindComplexPeaks(data1, signalLength / 2, signalLength, peakVal, peakIndexRight); carrierFreq = freqShift; } if (matchUM71) { util.FindComplexPeaks(data1, peakVal, peakIndexLeft); carrierFreq = freqShift + peakIndexLeft[0] * 1f / underSampleCount; lowFreq = Math.Abs(peakIndexLeft[1] - peakIndexLeft[2]) / 2f / underSampleCount; if (lowFreq < 9 || lowFreq > 31) { lowFreq = -1; } } } acAmpl = CalAmplByFreq(fftData, (int)carrierFreq); acAmpl = CalRealVal(acAmpl, carrierFreq); if (Math.Abs(carrierFreq - prevCarrier) > 10 || Math.Abs(lowFreq - prevLow) > 1) { diffCnt++; if (diffCnt >= 2) { prevCarrier = carrierFreq; prevLow = lowFreq; diffCnt = 0; } else { carrierFreq = prevCarrier; lowFreq = prevLow; } } else { prevCarrier = carrierFreq; prevLow = lowFreq; diffCnt = 0; } args = new SignalArgs(recordFile.TimeExport, dcAmpl, acAmpl, carrierFreq, lowFreq); SignalArgsChanged(this, args); eventDSP.Set(); } } catch (Exception) { if (fftPlan != null) { fftPlan.Dispose(); } } }