/* ======================================================================== *\ ! ! * ! * This file is part of MARS, the MAGIC Analysis and Reconstruction ! * Software. It is distributed to you in the hope that it can be a useful ! * and timesaving tool in analysing Data of imaging Cerenkov telescopes. ! * It is distributed WITHOUT ANY WARRANTY. ! * ! * Permission to use, copy, modify and distribute this software and its ! * documentation for any purpose is hereby granted without fee, ! * provided that the above copyright notice appear in all copies and ! * that both that copyright notice and this permission notice appear ! * in supporting documentation. It is provided "as is" without express ! * or implied warranty. ! * ! ! ! Author(s): Markus Gaug 11/2003 ! ! Copyright: MAGIC Software Development, 2000-2004 ! ! \* ======================================================================== */ ///////////////////////////////////////////////////////////////////////////// // // MCalibrationIntensityChargeCam // // Storage container for intensity charge calibration results. // // Individual MCalibrationChargeCam's can be retrieved with: // - GetCam() yielding the current cam. // - GetCam("name") yielding the current camera with name "name". // - GetCam(i) yielding the i-th camera. // // See also: MCalibrationIntensityCam, MCalibrationChargeCam, // MCalibrationChargePix, MCalibrationChargeCalc, MCalibrationQECam // MCalibrationBlindCam, MCalibrationChargePINDiode // MHCalibrationChargePix, MHCalibrationChargeCam // ///////////////////////////////////////////////////////////////////////////// #include "MCalibrationIntensityChargeCam.h" #include #include #include #include #include #include "MLog.h" #include "MLogManip.h" #include "MHCamera.h" #include "MGeomCamMagic.h" #include "MGeomCam.h" #include "MGeomPix.h" #include "MCalibrationChargeCam.h" #include "MCalibrationChargePix.h" ClassImp(MCalibrationIntensityChargeCam); using namespace std; // -------------------------------------------------------------------------- // // Default constructor. // MCalibrationIntensityChargeCam::MCalibrationIntensityChargeCam(const char *name, const char *title) { fName = name ? name : "MCalibrationIntensityChargeCam"; fTitle = title ? title : "Results of the Intensity Calibration"; InitSize(1); } // ------------------------------------------------------------------- // // Add MCalibrationChargeCam's in the ranges from - to. // void MCalibrationIntensityChargeCam::Add(const UInt_t from, const UInt_t to) { for (UInt_t i=from; iAddAt(new MCalibrationChargeCam,i); } // ------------------------------------------------------------------- // // Returns a TGraphErrors with the number of photo-electrons vs. // the extracted signal of pixel "pixid". // TGraphErrors *MCalibrationIntensityChargeCam::GetPheVsCharge( const UInt_t pixid, const MCalibrationCam::PulserColor_t col) { Int_t size = CountNumEntries(col); if (size == 0) return NULL; TArrayF phe(size); TArrayF pheerr(size); TArrayF sig(size); TArrayF sigerr(size); Int_t cnt = 0; for (Int_t i=0;iGetPulserColor() != col) continue; // // Get the calibration pix from the calibration cam // MCalibrationChargePix &pix = (MCalibrationChargePix&)(*cam)[pixid]; // // Don't use bad pixels // if (!pix.IsFFactorMethodValid()) continue; // phe[cnt] = pix.GetPheFFactorMethod(); pheerr[cnt] = pix.GetPheFFactorMethodErr(); // // For the calculation of Q, we have to use the // converted value! // sig [cnt] = pix.GetConvertedMean(); sigerr[cnt] = pix.GetConvertedMeanErr(); cnt++; } TGraphErrors *gr = new TGraphErrors(size, sig.GetArray(),phe.GetArray(), sigerr.GetArray(),pheerr.GetArray()); gr->SetTitle(Form("%s%3i","Pixel ",pixid)); gr->GetXaxis()->SetTitle("Q [FADC counts]"); gr->GetYaxis()->SetTitle("photo-electrons [1]"); return gr; } // ------------------------------------------------------------------- // // Returns a TGraphErrors with the mean effective number of photo-electrons divided by // the mean charge of that pixel vs. the mean number of photo-electrons. // TGraphErrors *MCalibrationIntensityChargeCam::GetPhePerCharge( const UInt_t pixid, const MGeomCam &geom, const MCalibrationCam::PulserColor_t col) { Int_t size = CountNumValidEntries(pixid,col); if (size == 0) return NULL; TArrayF phepersig(size); TArrayF phepersigerr(size); TArrayF sig(size); TArrayF sigerr(size); Int_t cnt = 0; for (Int_t i=0;iGetPulserColor() != col) continue; // // Get the calibration pix from the calibration cam // const MCalibrationChargePix &pix = (MCalibrationChargePix&)(*cam)[pixid]; // // Don't use bad pixels // if (!pix.IsFFactorMethodValid()) continue; // // For the calculation of Q, we have to use the // converted value! // const Int_t aidx = geom[pixid].GetAidx(); const MCalibrationChargePix &apix = (MCalibrationChargePix&)cam->GetAverageArea(aidx); const Float_t q = pix.GetConvertedMean(); const Float_t qerr = pix.GetConvertedMeanErr(); // const Float_t phe = apix.GetPheFFactorMethod(); const Float_t pheerr = apix.GetPheFFactorMethodErr(); sig[cnt] = phe; sigerr[cnt] = pheerr; phepersig[cnt] = q > 0.00001 ? phe/q : -1.; Float_t var = 0.; if (q > 0.00001 && phe > 0.00001) { var = pheerr * pheerr / phe / phe + qerr*qerr/q/q; if (var > 0.00001) var = TMath::Sqrt(var)*phepersig[cnt]; } phepersigerr[cnt] = var; cnt++; } TGraphErrors *gr = new TGraphErrors(size, sig.GetArray(),phepersig.GetArray(), sigerr.GetArray(),phepersigerr.GetArray()); gr->SetTitle(Form("%s%3i","Pixel ",pixid)); gr->GetXaxis()->SetTitle(" [1]"); gr->GetYaxis()->SetTitle(" / [FADC cts^{-1}]"); return gr; } // ------------------------------------------------------------------- // // Returns a TGraphErrors with the mean effective number of photo-electrons divided by // the mean charge of that pixel vs. the mean number of photo-electrons. // TGraphErrors *MCalibrationIntensityChargeCam::GetPhePerChargePerArea( const Int_t aidx, const MGeomCam &geom, const MCalibrationCam::PulserColor_t col) { Int_t size = CountNumEntries(col); if (size == 0) return NULL; TArrayF phepersig(size); TArrayF phepersigerr(size); TArrayF sig(size); TArrayF sigerr(size); Int_t cnt = 0; for (Int_t i=0;iGetPulserColor() != col) continue; // // Get the calibration pix from the calibration cam // const MCalibrationChargePix &apix = (MCalibrationChargePix&)cam->GetAverageArea(aidx); const Float_t phe = apix.GetPheFFactorMethod(); const Float_t pherelvar = apix.GetPheFFactorMethodRelVar(); const Float_t pheerr = apix.GetPheFFactorMethodErr(); sig[cnt] = phe; sigerr[cnt] = pheerr; Double_t sig = 0.; Double_t sig2 = 0.; Int_t num = 0; for (Int_t i=0; iGetSize(); i++) { const MCalibrationChargePix &pix = (MCalibrationChargePix&)(*cam)[i]; // // Don't use bad pixels // if (!pix.IsFFactorMethodValid()) continue; // // if (aidx != geom[i].GetAidx()) continue; sig += pix.GetConvertedMean(); sig2 += pix.GetConvertedMean() * pix.GetConvertedMean(); num++; } if (num > 1) { sig /= num; Double_t var = (sig2 - sig*sig*num) / (num-1); var /= sig*sig; var += pherelvar; phepersig[cnt] = phe/sig; if (var > 0.) phepersigerr[cnt] = TMath::Sqrt(var) * phepersig[cnt]; else phepersigerr[cnt] = 0.; } else { phepersig[cnt] = -1.; phepersigerr[cnt] = 0.; } cnt++; } TGraphErrors *gr = new TGraphErrors(size, sig.GetArray(),phepersig.GetArray(), sigerr.GetArray(),phepersigerr.GetArray()); gr->SetTitle(Form("Conv. Factors Area %d Average",aidx)); gr->GetXaxis()->SetTitle(" [1]"); gr->GetYaxis()->SetTitle(" / [FADC cts^{-1}]"); return gr; } // ------------------------------------------------------------------- // // Returns a TGraphErrors with the number of photo-electrons vs. // the extracted signal over all pixels with area index "aidx". // // The points represent the means of the pixels values, while the error bars // the sigma of the pixels values. // TGraphErrors *MCalibrationIntensityChargeCam::GetPheVsChargePerArea( const Int_t aidx, const MCalibrationCam::PulserColor_t col) { Int_t size = CountNumEntries(col); TArrayF phe(size); TArrayF pheerr(size); TArrayF sig(size); TArrayF sigerr(size); Int_t cnt = 0; for (Int_t i=0;iGetPulserColor() != col) continue; // // Get the area calibration pix from the calibration cam // MCalibrationChargePix &pix = (MCalibrationChargePix&)(cam->GetAverageArea(aidx)); phe[cnt] = pix.GetPheFFactorMethod(); pheerr[cnt] = pix.GetPheFFactorMethodErr(); // // For the calculation of Q, we have to use the // converted value! // sig [cnt] = pix.GetConvertedMean(); sigerr[cnt] = pix.GetConvertedMeanErr(); cnt++; } TGraphErrors *gr = new TGraphErrors(size, sig.GetArray(),phe.GetArray(), sigerr.GetArray(),pheerr.GetArray()); gr->SetTitle(Form("%s%3i","Area Index ",aidx)); gr->GetXaxis()->SetTitle("Q [FADC counts]"); gr->GetYaxis()->SetTitle("photo-electrons [1]"); return gr; } // ------------------------------------------------------------------- // // Returns a TGraphErrors with the 'Razmik plot' of pixel "pixid". // The Razmik plot shows the value of 'R' vs. 1/Q where: // // sigma^2 F^2 // R = ------- = ------ // ^2 // // and 1/Q is the inverse (mean) extracted signal // TGraphErrors *MCalibrationIntensityChargeCam::GetRazmikPlot( const UInt_t pixid ) { const Int_t size = GetSize(); TArrayF r(size); TArrayF rerr(size); TArrayF oneoverq(size); TArrayF oneoverqerr(size); for (Int_t i=0;i^2 ^2 // const Float_t mean = pix.GetMean(); const Float_t meanerr = pix.GetMeanErr(); const Float_t rsigma = pix.GetRSigma(); const Float_t rsigmaerr = pix.GetRSigmaErr(); r[i] = rsigma*rsigma/mean/mean; const Float_t rrelvar = 4.*rsigmaerr*rsigmaerr/rsigma/rsigma + 4.*meanerr*meanerr/mean/mean; rerr[i] = rrelvar * r[i] * r[i]; rerr[i] = rerr[i] <= 0 ? 0. : TMath::Sqrt(rerr[i]); // // For the calculation of 1/Q, we have to use the // converted value! // const Float_t q = pix.GetConvertedMean(); const Float_t qe = pix.GetConvertedMeanErr(); oneoverq [i] = 1./q; oneoverqerr[i] = qe / (q * q); } TGraphErrors *gr = new TGraphErrors(size, oneoverq.GetArray(),r.GetArray(), oneoverqerr.GetArray(),rerr.GetArray()); gr->SetTitle(Form("%s%3i","Pixel ",pixid)); gr->GetXaxis()->SetTitle("1/Q [FADC counts^{-1}]"); gr->GetYaxis()->SetTitle("\\sigma_{red}^{2}/Q^{2} [1]"); return gr; } // ------------------------------------------------------------------- // // Returns a 2-dimensional histogram with the fit results of the // 'Razmik plot' for each pixel of area index "aidx" (see GetRazmikPlot()) // // The results of the polynomial fit of grade 1 are: // // x-axis: Offset (Parameter 0 of the polynomial) // y-axis: Slope (Parameter 1 of the polynomial) // // The offset is a measure of how well-known the supposed additional contributions // to the value "reduced sigma" are. Because a photo-multiplier is a linear instrument, // the excess fluctuations are linear w.r.t. the signal amplitude and can be expressed by // the proportionality constant F (the "F-Factor"). // Adding noise from outside (e.g. night sky background) modifies the recorded noise, but // not the mean extracted signal, due to the AC-coupling. Thus, noise contributions from outside // (e.g. calculating the pedestal RMS)have to be subtracted from the recorded signal fluctuations // in order to retrieve the linearity relation: // // sigma(signal)^2 / mean(signal)^2 = sigma^2 / ^2 = F^2 / (1) // // Any systematic offset in the sigma(signal) will produce an offset in the "Razmik plot"), // characterized by the Offset of the polynomial fit. Thus, in an ideal case, all pixels have their // "offset" centered very closely around zero. // // The "slope" is the proportionality constant F^2, multiplied with the conversion factor // phe's to mean signal (because the "Razmik plot" plots the left side of eq. (1) w.r.t. // 1/ instead of 1/. However, the mean number of photo-electrons can be // expressed by with the relation: // // = c_phe * (2) // // Thus: // // 1/ = 1/c_phe * 1/ (3) // // and: // // Slope = F^2 / c_phe // // In the ideal case of having equal photo-multipliers and a perfectly flat-fielded camera, // the "slope" -values should thus all be closely centered around F^2/c_phe. // TH2F *MCalibrationIntensityChargeCam::GetRazmikPlotResults( const Int_t aidx, const MGeomCam &geom) { TH2F *hist = new TH2F("hist","R vs. Inverse Charges - Fit results",45,-0.02,0.02,45,0.,30.); hist->SetXTitle("Offset [FADC counts^{-1}]"); hist->SetYTitle("F^{2} / / [FADC count / phe]"); hist->SetFillColor(kRed+aidx); MCalibrationChargeCam *cam = (MCalibrationChargeCam*)GetCam(); for (Int_t npix=0;npixGetSize();npix++) { if (geom[npix].GetAidx() == aidx) { TGraph *gr = GetRazmikPlot(npix); gr->Fit("pol1","Q"); hist->Fill(gr->GetFunction("pol1")->GetParameter(0),gr->GetFunction("pol1")->GetParameter(1)); } } return hist; } // -------------------------------------------------------------------- // // Returns the number of camera entries matching the required colour // and the requirement that pixel "pixid" has been correctly calibrated // Int_t MCalibrationIntensityChargeCam::CountNumValidEntries(const UInt_t pixid, const MCalibrationCam::PulserColor_t col) const { Int_t nvalid = 0; for (Int_t i=0;iGetPulserColor() == col) { if (pix.IsFFactorMethodValid()) nvalid++; } } } return nvalid; } // ------------------------------------------------------------------- // // Returns a TGraphErrors with the development of the number of // photo-electrons vs. camera number for pixel 'pixid' // TGraphErrors *MCalibrationIntensityChargeCam::GetVarVsTime( const Int_t pixid , const Option_t *varname ) { const Int_t size = GetSize(); if (size == 0) return NULL; TString option(varname); option.ToLower(); TArrayF nr(size); TArrayF nrerr(size); TArrayF var (size); TArrayF varerr(size); for (Int_t i=0;iGetAverageArea(0); const Float_t mean = pix.GetConvertedMean(); const Float_t phe = apix.GetPheFFactorMethod(); var[i] = phe/mean; varerr[i] = TMath::Sqrt(apix.GetPheFFactorMethodErr()*apix.GetPheFFactorMethodErr()/mean/mean + phe*phe/mean/mean/mean/mean*pix.GetConvertedMeanErr()*pix.GetConvertedMeanErr()); } } TGraphErrors *gr = new TGraphErrors(size, nr.GetArray(),var.GetArray(), nrerr.GetArray(),varerr.GetArray()); gr->SetTitle(Form("%s%3i","Pixel ",pixid)); gr->GetXaxis()->SetTitle("Camera Nr."); // gr->GetYaxis()->SetTitle(" [FADC cnts]"); return gr; } // -------------------------------------------------------------------------------- // // Returns a TGraphErrors with a pre-defined variable with name (handed over in 'opt') // per area index 'aidx' vs. the calibration camera number // TGraphErrors *MCalibrationIntensityChargeCam::GetVarPerAreaVsTime( const Int_t aidx, const MGeomCam &geom, const Option_t *varname) { const Int_t size = GetSize(); if (size == 0) return NULL; TString option(varname); option.ToLower(); TArrayF vararea(size); TArrayF varareaerr(size); TArrayF nr(size); TArrayF nrerr(size); TH1D *h = 0; for (Int_t i=0;iGetSize(); j++) { const MCalibrationChargePix &pix = (MCalibrationChargePix&)(*cam)[j]; // // Don't use bad pixels // if (!pix.IsFFactorMethodValid()) continue; // // if (aidx != geom[j].GetAidx()) continue; pvar = 0.; if (option.Contains("rsigma")) pvar = pix.GetRSigma(); if (option.Contains("abstimemean")) pvar = pix.GetAbsTimeMean(); if (option.Contains("abstimerms")) pvar = pix.GetAbsTimeRms(); if (option.Contains("conversionhilo")) pvar = pix.GetConversionHiLo(); if (option.Contains("convertedmean")) pvar = pix.GetConvertedMean(); if (option.Contains("convertedsigma")) pvar = pix.GetConvertedSigma(); if (option.Contains("convertedrsigma")) pvar = pix.GetConvertedRSigma(); if (option.Contains("meanconvfadc2phe")) pvar = pix.GetMeanConvFADC2Phe(); if (option.Contains("meanffactorfadc2phot")) pvar = pix.GetMeanFFactorFADC2Phot(); if (option.Contains("ped")) pvar = pix.GetPed(); if (option.Contains("pedrms")) pvar = pix.GetPedRms(); if (option.Contains("pheffactormethod")) pvar = pix.GetPheFFactorMethod(); if (option.Contains("rsigmapercharge")) pvar = pix.GetRSigmaPerCharge(); if (option.Contains("conversionfactor")) { const MCalibrationChargePix &apix = (MCalibrationChargePix&)cam->GetAverageArea(aidx); pvar = apix.GetPheFFactorMethod()/pix.GetConvertedMean(); } variab += pvar; variab2 += pvar*pvar; num++; camcharge.Fill(j,pvar); camcharge.SetUsed(j); } if (num > 1) { variab /= num; variance = (variab2 - variab*variab*num) / (num-1); vararea[i] = variab; varareaerr[i] = variance>0 ? TMath::Sqrt(variance/num) : 999999999.; // // Make also a Gauss-fit to the distributions. The RMS can be determined by // outlier, thus we look at the sigma and the RMS and take the smaller one, afterwards. // h = camcharge.ProjectionS(TArrayI(),TArrayI(1,&aidx),"_py",750); h->SetDirectory(NULL); h->Fit("gaus","QL"); TF1 *fit = h->GetFunction("gaus"); Float_t ci2 = fit->GetChisquare(); Float_t sigma = fit->GetParameter(2); if (ci2 > 500. || sigma > varareaerr[i]) { h->Fit("gaus","QLM"); fit = h->GetFunction("gaus"); ci2 = fit->GetChisquare(); sigma = fit->GetParameter(2); } const Float_t mean = fit->GetParameter(1); const Float_t ndf = fit->GetNDF(); *fLog << inf << "Camera Nr: " << i << endl; *fLog << inf << option.Data() << " area idx: " << aidx << " Results: " << endl; *fLog << inf << "Mean: " << Form("%4.3f",mean) << "+-" << Form("%4.3f",fit->GetParError(1)) << " Sigma: " << Form("%4.3f",sigma) << "+-" << Form("%4.3f",fit->GetParError(2)) << " Chisquare: " << Form("%4.3f",ci2) << " NDF : " << ndf << endl; delete h; gROOT->GetListOfFunctions()->Remove(fit); if (sigma2 && ci2<500.) { vararea [i] = mean; varareaerr[i] = sigma/TMath::Sqrt((Float_t)num); } } else { vararea[i] = -1.; varareaerr[i] = 0.; } nr[i] = i; nrerr[i] = 0.; } TGraphErrors *gr = new TGraphErrors(size, nr.GetArray(),vararea.GetArray(), nrerr.GetArray(),varareaerr.GetArray()); gr->SetTitle(Form("%s Area %3i Average",option.Data(),aidx)); gr->GetXaxis()->SetTitle("Camera Nr."); // gr->GetYaxis()->SetTitle(" [1]"); return gr; } // ------------------------------------------------------------------- // // Returns a TGraphErrors with the mean effective number of photon // vs. the calibration camera number. With the string 'method', different // calibration methods can be called. // TGraphErrors *MCalibrationIntensityChargeCam::GetPhotVsTime( const Option_t *method ) { const Int_t size = GetSize(); if (size == 0) return NULL; TString option(method); TArrayF photarr(size); TArrayF photarrerr(size); TArrayF nr(size); TArrayF nrerr(size); for (Int_t i=0;iGetNumPhotonsBlindPixelMethod(); photerr = cam->GetNumPhotonsBlindPixelMethodErr(); } if (option.Contains("FFactor")) { phot = cam->GetNumPhotonsFFactorMethod(); photerr = cam->GetNumPhotonsFFactorMethodErr(); } if (option.Contains("PINDiode")) { phot = cam->GetNumPhotonsPINDiodeMethod(); photerr = cam->GetNumPhotonsPINDiodeMethodErr(); } photarr[i] = phot; photarrerr[i] = photerr; nr[i] = i; nrerr[i] = 0.; } TGraphErrors *gr = new TGraphErrors(size, nr.GetArray(),photarr.GetArray(), nrerr.GetArray(),photarrerr.GetArray()); gr->SetTitle("Photons Average"); gr->GetXaxis()->SetTitle("Camera Nr."); gr->GetYaxis()->SetTitle(" [1]"); return gr; } // ------------------------------------------------------------------- // // Returns a TGraphErrors with the mean effective number of photo-electrons per // area index 'aidx' vs. the calibration camera number // TGraphErrors *MCalibrationIntensityChargeCam::GetPhePerAreaVsTime( const Int_t aidx, const MGeomCam &geom) { const Int_t size = GetSize(); if (size == 0) return NULL; TArrayF phearea(size); TArrayF pheareaerr(size); TArrayF time(size); TArrayF timeerr(size); for (Int_t i=0;iGetAverageArea(aidx); const Float_t phe = apix.GetPheFFactorMethod(); const Float_t pheerr = apix.GetPheFFactorMethodErr(); phearea[i] = phe; pheareaerr[i] = pheerr; time[i] = i; timeerr[i] = 0.; } TGraphErrors *gr = new TGraphErrors(size, time.GetArray(),phearea.GetArray(), timeerr.GetArray(),pheareaerr.GetArray()); gr->SetTitle(Form("Phes Area %d Average",aidx)); gr->GetXaxis()->SetTitle("Camera Nr."); gr->GetYaxis()->SetTitle(" [1]"); return gr; } // ------------------------------------------------------------------- // // Returns a TGraphErrors with the event-by-event averaged charge per // area index 'aidx' vs. the calibration camera number // TGraphErrors *MCalibrationIntensityChargeCam::GetChargePerAreaVsTime( const Int_t aidx, const MGeomCam &geom) { const Int_t size = GetSize(); if (size == 0) return NULL; TArrayF chargearea(size); TArrayF chargeareaerr(size); TArrayF nr(size); TArrayF nrerr(size); for (Int_t i=0;iGetAverageArea(aidx); const Float_t charge = apix.GetConvertedMean(); const Float_t chargeerr = apix.GetConvertedSigma(); chargearea[i] = charge; chargeareaerr[i] = chargeerr; nr[i] = i; nrerr[i] = 0.; } TGraphErrors *gr = new TGraphErrors(size, nr.GetArray(),chargearea.GetArray(), nrerr.GetArray(),chargeareaerr.GetArray()); gr->SetTitle(Form("Averaged Charges Area Idx %d",aidx)); gr->GetXaxis()->SetTitle("Camera Nr."); gr->GetYaxis()->SetTitle(" [FADC cnts]"); return gr; } TH1F *MCalibrationIntensityChargeCam::GetVarFluctuations( const Int_t aidx, const MGeomCam &geom, const Option_t *varname ) { const Int_t size = GetSize(); if (size == 0) return NULL; TString option(varname); option.ToLower(); TH1F *hist = new TH1F("hist",Form("%s - Rel. Fluctuations %s Pixel",option.Data(),aidx ? "Outer" : "Inner"), 200,0.,100.); hist->SetXTitle("Relative Fluctuation [%]"); hist->SetYTitle("Nr. channels [1]"); hist->SetFillColor(kRed+aidx); MCalibrationChargeCam *cam = (MCalibrationChargeCam*)GetCam(); // // Loop over pixels // for (Int_t npix=0;npixGetSize();npix++) { if (geom[npix].GetAidx() != aidx) continue; Double_t variab = 0.; Double_t variab2 = 0.; Double_t variance = 0.; Int_t num = 0; Float_t pvar = 0.; Float_t relrms = 99.9; // // Loop over the Cams for each pixel // for (Int_t i=0; iGetAverageArea(0); pvar = apix.GetPheFFactorMethod()/pix.GetConvertedMean(); } variab += pvar; variab2 += pvar*pvar; num++; } if (num > 1) { variab /= num; variance = (variab2 - variab*variab*num) / (num-1); if (variance > 0.) relrms = TMath::Sqrt(variance)/variab * 100.; } hist->Fill(relrms); } return hist; } void MCalibrationIntensityChargeCam::DrawRazmikPlot( const UInt_t pixid ) { TGraphErrors *gr = GetRazmikPlot(pixid ); gr->SetBit(kCanDelete); gr->Draw("A*"); } void MCalibrationIntensityChargeCam::DrawPheVsCharge( const UInt_t pixid, const MCalibrationCam::PulserColor_t col) { TGraphErrors *gr = GetPheVsCharge(pixid,col); gr->SetBit(kCanDelete); gr->Draw("A*"); } void MCalibrationIntensityChargeCam::DrawPhePerCharge( const UInt_t pixid, const MCalibrationCam::PulserColor_t col) { TGraphErrors *gr = GetPhePerCharge(pixid,MGeomCamMagic(),col); gr->SetBit(kCanDelete); gr->Draw("A*"); } void MCalibrationIntensityChargeCam::DrawPhePerChargePerArea( const Int_t aidx, const MCalibrationCam::PulserColor_t col) { TGraphErrors *gr = GetPhePerChargePerArea(aidx,MGeomCamMagic(),col); gr->SetBit(kCanDelete); gr->Draw("A*"); } void MCalibrationIntensityChargeCam::DrawPheVsChargePerArea( const Int_t aidx, const MCalibrationCam::PulserColor_t col) { TGraphErrors *gr = GetPheVsChargePerArea(aidx,col); gr->SetBit(kCanDelete); gr->Draw("A*"); } void MCalibrationIntensityChargeCam::DrawRazmikPlotResults( const Int_t aidx) { TH2F *h = GetRazmikPlotResults(aidx,MGeomCamMagic()); h->SetBit(kCanDelete); h->Draw(); } void MCalibrationIntensityChargeCam::DrawChargePerAreaVsTime( const Int_t aidx) { TGraphErrors *gr = GetChargePerAreaVsTime(aidx,MGeomCamMagic()); gr->SetBit(kCanDelete); gr->Draw("A*"); } void MCalibrationIntensityChargeCam::DrawPhePerAreaVsTime( const Int_t aidx) { TGraphErrors *gr = GetPhePerAreaVsTime(aidx,MGeomCamMagic()); gr->SetBit(kCanDelete); gr->Draw("A*"); } void MCalibrationIntensityChargeCam::DrawPhotVsTime( const Option_t *method) { TGraphErrors *gr = GetPhotVsTime(method); gr->SetBit(kCanDelete); gr->Draw("A*"); } void MCalibrationIntensityChargeCam::DrawVarPerAreaVsTime( const Int_t aidx, const Option_t *varname ) { TGraphErrors *gr = GetVarPerAreaVsTime(aidx,MGeomCamMagic(),varname ); gr->SetBit(kCanDelete); gr->Draw("A*"); } void MCalibrationIntensityChargeCam::DrawVarVsTime( const Int_t pixid , const Option_t *varname ) { TGraphErrors *gr = GetVarVsTime(pixid,varname ); gr->SetBit(kCanDelete); gr->Draw("A*"); } void MCalibrationIntensityChargeCam::DrawVarFluctuations( const Int_t aidx, const Option_t *varname) { TH1F *h = GetVarFluctuations( aidx,MGeomCamMagic(),varname); h->SetBit(kCanDelete); h->Draw(); }