1 | #ifndef MARS_MExtralgoDigitalFilter
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2 | #define MARS_MExtralgoDigitalFilter
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3 |
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4 | #ifndef ROOT_TMatrix
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5 | #include <TMatrix.h>
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6 | #endif
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7 |
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8 | class TH1;
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9 | class TH2;
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10 | class TH1F;
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11 | class TH2F;
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12 | class TArrayF;
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13 |
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14 | class MExtralgoDigitalFilter
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15 | {
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16 | private:
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17 | // Input
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18 | const Float_t *fVal;
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19 | Int_t fNum;
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20 |
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21 | Float_t const *fWeightsAmp;
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22 | Float_t const *fWeightsTime;
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23 | Float_t const *fPulseShape;
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24 |
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25 | // const TMatrix *fAinv;
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26 |
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27 | const Int_t fWeightsPerBin; // Number of weights per data bin
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28 | const Int_t fWindowSize;
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29 |
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30 | // Result
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31 | Float_t fTime;
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32 | Float_t fTimeDev;
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33 | Float_t fSignal;
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34 | Float_t fSignalDev;
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35 |
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36 | Float_t GetChisq(const Int_t maxp, const Int_t frac, const Float_t sum) const;
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37 |
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38 | inline Double_t ChiSq(const Double_t sum, const Int_t startv, const Int_t startw=0) const
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39 | {
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40 | //
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41 | // Slide with a window of size windowsize over the sample
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42 | // and multiply the entries with the corresponding weights
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43 | //
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44 | Double_t chisq = 0;
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45 |
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46 | // Shift the start of the weight to the center of sample 0
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47 | Float_t const *w = fPulseShape + startw;
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48 |
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49 | const Float_t *beg = fVal+startv;
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50 | for (Float_t const *pex=beg; pex<beg+fWindowSize; pex++)
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51 | {
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52 | const Double_t c = *w - *pex/sum;
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53 | chisq += c*c;
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54 | w += fWeightsPerBin;
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55 | }
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56 | return chisq;
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57 | }
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58 |
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59 | // Weights: Weights to evaluate
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60 | // Startv: Index of first bin of data
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61 | // startw: Offset on the weights
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62 | inline Double_t Eval(Float_t const *weights, const Int_t startv, const Int_t startw=0) const
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63 | {
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64 | //
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65 | // Slide with a window of size windowsize over the sample
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66 | // and multiply the entries with the corresponding weights
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67 | //
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68 | Double_t sum = 0;
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69 |
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70 | // Shift the start of the weight to the center of sample 0
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71 | Float_t const *w = weights + startw;
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72 |
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73 | const Float_t *beg = fVal+startv;
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74 | for (Float_t const *pex=beg; pex<beg+fWindowSize; pex++)
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75 | {
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76 | sum += *w * *pex;
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77 | w += fWeightsPerBin;
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78 | }
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79 | return sum;
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80 | }
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81 |
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82 | inline void AlignIntoLimits(Int_t &maxp, Int_t &frac) const
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83 | {
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84 | // Align maxp into available range (TO BE CHECKED)
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85 | if (maxp < 0)
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86 | {
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87 | maxp = 0;
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88 | frac = fWeightsPerBin/2-1; // Assume peak at the end of the last slice
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89 | }
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90 | if (maxp > fNum-fWindowSize)
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91 | {
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92 | maxp = fNum-fWindowSize;
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93 | frac = -fWeightsPerBin/2; // Assume peak at the beginning of the first slice
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94 | }
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95 | }
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96 |
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97 | Int_t AlignExtractionWindow(Int_t &maxp, Int_t &frac, const Double_t ampsum);
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98 | void AlignExtractionWindow(Int_t &maxp, Int_t &frac)
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99 | {
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100 | const Double_t amp = Eval(fWeightsAmp, maxp, frac);
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101 | if (amp!=0)
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102 | AlignExtractionWindow(maxp, frac, amp);
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103 | }
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104 |
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105 | public:
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106 | MExtralgoDigitalFilter(Int_t res, Int_t windowsize, Float_t *wa, Float_t *wt, Float_t *ps=0, TMatrix *ainv=0)
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107 | : fVal(0), fNum(0), fWeightsAmp(wa+res/2), fWeightsTime(wt+res/2),
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108 | fPulseShape(ps), /*fAinv(ainv),*/ fWeightsPerBin(res), fWindowSize(windowsize),
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109 | fTime(0), fTimeDev(-1), fSignal(0), fSignalDev(-1)
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110 | {
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111 | }
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112 |
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113 | void SetData(Int_t n, Float_t const *val) { fNum=n; fVal=val; }
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114 |
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115 | Float_t GetTime() const { return fTime; }
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116 | Float_t GetSignal() const { return fSignal; }
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117 |
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118 | Float_t GetTimeDev() const { return fTimeDev; }
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119 | Float_t GetSignalDev() const { return fSignalDev; }
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120 |
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121 | void GetSignal(Float_t &sig, Float_t &dsig) const { sig=fSignal; dsig=fSignalDev; }
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122 | void GetTime(Float_t &sig, Float_t &dsig) const { sig=fTime; dsig=fTimeDev; }
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123 |
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124 | Float_t ExtractNoise() const;
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125 | void Extract(Int_t maxpos=-1);
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126 |
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127 | static Int_t CalculateWeights(TH1 &shape, const TH2 &autocorr, TArrayF &wa, TArrayF &wt, Int_t wpb=-1);
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128 | static Int_t CalculateWeights2(TH1 &shape, const TH2 &autocorr, TArrayF &wa, TArrayF &wt, Int_t wpb=-1);
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129 | };
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130 |
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131 |
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132 | #endif
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