/* ======================================================================== *\ ! ! * ! * 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): Josep Flix, 01/2004 ! Javier Rico, 01/2004 ! Markus Gaug, 03/2004 ! ! (based on bootcampstandardanalysis.C by Javier López) ! ! ! Copyright: MAGIC Software Development, 2000-2004 ! ! \* ======================================================================== */ ///////////////////////////////////////////////////////////////////////////// // // pedphotcalc.C // // This macro is an example of the use of MPedPhotCalc. It computes // the pedestal mean and rms from pedestal files undergoing the // signal extraction + calibration chain, in units of photons. It // produces plots of the relevant computed quantities. // // Needs as arguments the run number of a pedestal file ("*_P_*.root"), // one of a calibration file ("*_C_*.root"). // performs the pedestal calculation, the calibration /// constants calculation and the calibration of the pedestals. // // The TString inpath has to be set correctly. // // The macro searches for the pulser colour which corresponds to the calibration // run number. If the run number is smaller than 20000, pulser colour "CT1" // is assumed, otherwise, it searches for the strings "green", "blue", "uv" or // "ct1" in the filenames. If no colour or multiple colours are found, the // execution is aborted. // //////////////////////////////////////////////////////////////////////////////////// #include "MParList.h" #include "MTaskList.h" #include "MJPedestal.h" #include "MJCalibration.h" #include "MPedestalCam.h" #include "MPedestalPix.h" #include "MReadMarsFile.h" #include "MGeomApply.h" #include "MGeomCamMagic.h" #include "MEvtLoop.h" #include "MCalibrationCam.h" #include "MCalibrationChargeCam.h" #include "MCalibrationChargePix.h" #include "MCalibrationQECam.h" #include "MCalibrationQEPix.h" #include "MExtractedSignalCam.h" #include "MExtractSlidingWindow.h" #include "MExtractFixedWindow.h" #include "MCerPhotEvt.h" #include "MCalibrate.h" #include "MPedPhotCalc.h" #include "MPedPhotCam.h" #include "MPedPhotPix.h" #include "MHCamera.h" #include "MRunIter.h" #include "MDirIter.h" #include "MStatusDisplay.h" #include "MHCamera.h" #include "TTimer.h" #include "TString.h" #include "TCanvas.h" #include "TStyle.h" #include "TF1.h" #include "TLegend.h" #include #include "Getline.h" const TString inpath = "/mnt/Data/rootdata/CrabNebula/2004_02_10/"; const Int_t dpedrun = 14607; const Int_t dcalrun1 = 14608; const Int_t dcalrun2 = 0; const Bool_t usedisplay = kTRUE; void DrawProjection(MHCamera *obj1, Int_t fit) { TH1D *obj2 = (TH1D*)obj1->Projection(obj1->GetName()); obj2->SetDirectory(0); obj2->Draw(); obj2->SetBit(kCanDelete); gPad->SetLogy(); if (obj1->GetGeomCam().InheritsFrom("MGeomCamMagic")) { TArrayI s0(3); s0[0] = 6; s0[1] = 1; s0[2] = 2; TArrayI s1(3); s1[0] = 3; s1[1] = 4; s1[2] = 5; TArrayI inner(1); inner[0] = 0; TArrayI outer(1); outer[0] = 1; // Just to get the right (maximum) binning TH1D *half[4]; half[0] = obj1->ProjectionS(s0, inner, "Sector 6-1-2 Inner"); half[1] = obj1->ProjectionS(s1, inner, "Sector 3-4-5 Inner"); half[2] = obj1->ProjectionS(s0, outer, "Sector 6-1-2 Outer"); half[3] = obj1->ProjectionS(s1, outer, "Sector 3-4-5 Outer"); for (int i=0; i<4; i++) { half[i]->SetLineColor(kRed+i); half[i]->SetDirectory(0); half[i]->SetBit(kCanDelete); half[i]->Draw("same"); } } const Double_t min = obj2->GetBinCenter(obj2->GetXaxis()->GetFirst()); const Double_t max = obj2->GetBinCenter(obj2->GetXaxis()->GetLast()); const Double_t integ = obj2->Integral("width")/2.5066283; const Double_t mean = obj2->GetMean(); const Double_t rms = obj2->GetRMS(); const Double_t width = max-min; if (rms==0 || width==0) return; const TString dgausformula("([0]-[3])/[2]*exp(-0.5*(x-[1])*(x-[1])/[2]/[2])" "+[3]/[5]*exp(-0.5*(x-[4])*(x-[4])/[5]/[5])"); TF1 *f=0; switch (fit) { // FIXME: MAYBE add function to TH1? case 0: f = new TF1("sgaus", "gaus(0)", min, max); f->SetLineColor(kYellow); f->SetBit(kCanDelete); f->SetParNames("Area", "#mu", "#sigma"); f->SetParameters(integ/rms, mean, rms); f->SetParLimits(0, 0, integ); f->SetParLimits(1, min, max); f->SetParLimits(2, 0, width/1.5); obj2->Fit(f, "QLRM"); break; case 1: f = new TF1("dgaus", dgausformula, min, max); f->SetLineColor(kYellow); f->SetBit(kCanDelete); f->SetParNames("A_{tot}", "#mu_{1}", "#sigma_{1}", "A_{2}", "#mu_{2}", "#sigma_{2}"); f->SetParameters(integ, (min+mean)/2, width/4, integ/width/2, (max+mean)/2, width/4); // The left-sided Gauss f->SetParLimits(0, integ-1.5, integ+1.5); f->SetParLimits(1, min+(width/10), mean); f->SetParLimits(2, 0, width/2); // The right-sided Gauss f->SetParLimits(3, 0, integ); f->SetParLimits(4, mean, max-(width/10)); f->SetParLimits(5, 0, width/2); obj2->Fit(f, "QLRM"); break; default: obj2->Fit("gaus", "Q"); obj2->GetFunction("gaus")->SetLineColor(kYellow); break; } } void CamDraw(TCanvas &c, Int_t x, Int_t y, MHCamera &cam1, Int_t fit) { c.cd(x); gPad->SetBorderMode(0); MHCamera *obj1=(MHCamera*)cam1.DrawCopy("hist"); c.cd(x+y); gPad->SetBorderMode(0); obj1->Draw(); c.cd(x+2*y); gPad->SetBorderMode(0); DrawProjection(obj1, fit); } void pedphotcalc(const Int_t prun=dpedrun, // pedestal file const Int_t crun1=dcalrun1, const Int_t crun2=dcalrun2 // calibration file(s) ) { MExtractFixedWindow extractor; MRunIter pruns; MRunIter cruns; pruns.AddRun(prun,inpath); if (crun2==0) cruns.AddRun(crun1,inpath); else cruns.AddRuns(crun1,crun2,inpath); // // Now setup the tasks and tasklist for the pedestals: // --------------------------------------------------- // MGeomCamMagic geomcam; MGeomApply geomapl; MStatusDisplay *display = NULL; /************************************/ /* FIRST LOOP: PEDESTAL COMPUTATION */ /************************************/ MJPedestal pedloop; pedloop.SetInput(&pruns); if (usedisplay) { display = new MStatusDisplay; display->SetUpdateTime(3000); display->Resize(850,700); display->SetBit(kCanDelete); pedloop.SetDisplay(display); } cout << "*************************" << endl; cout << "** COMPUTING PEDESTALS **" << endl; cout << "*************************" << endl; if (!pedloop.Process()) return; MPedestalCam pedcam = pedloop.GetPedestalCam(); /****************************/ /* SECOND LOOP: CALIBRATION */ /****************************/ // // Now setup the new tasks for the calibration: // --------------------------------------------------- // MJCalibration calloop; calloop.SetInput(&cruns); // // Use as signal extractor MExtractSignal: // calloop.SetExtractor(&extractor); // // The next two commands are for the display: // if (usedisplay) { calloop.SetDisplay(display); calloop.SetDataCheck(); } cout << "***********************************" << endl; cout << "** COMPUTING CALIBRATION FACTORS **" << endl; cout << "***********************************" << endl; if (!calloop.Process(pedcam)) return; MCalibrationChargeCam &calcam = calloop.GetCalibrationCam(); MCalibrationQECam &qecam = calloop.GetQECam(); /************************************************************************/ /* THIRD LOOP: PEDESTAL COMPUTATION USING EXTRACTED SIGNAL (IN PHOTONS) */ /************************************************************************/ // Create an empty Parameter List and an empty Task List MParList plist3; MTaskList tlist3; plist3.AddToList(&tlist3); // containers MCerPhotEvt photcam; MPedPhotCam pedphotcam; MExtractedSignalCam extedsig; plist3.AddToList(&geomcam); plist3.AddToList(&pedcam ); plist3.AddToList(&calcam ); plist3.AddToList(&qecam ); plist3.AddToList(&photcam); plist3.AddToList(&extedsig); plist3.AddToList(&pedphotcam); //tasks MReadMarsFile read3("Events"); read3.DisableAutoScheme(); static_cast(read3).AddFiles(pruns); MCalibrate photcalc; photcalc.SetCalibrationMode(MCalibrate::kFfactor); MPedPhotCalc pedphotcalc; tlist3.AddToList(&read3); tlist3.AddToList(&geomapl); tlist3.AddToList(&extractor); tlist3.AddToList(&photcalc); tlist3.AddToList(&pedphotcalc); // Create and execute eventloop MEvtLoop evtloop3; evtloop3.SetParList(&plist3); cout << "*************************************************************" << endl; cout << "** COMPUTING PEDESTALS USING EXTRACTED SIGNAL (IN PHOTONS) **" << endl; cout << "*************************************************************" << endl; if (!evtloop3.Eventloop()) return; tlist3.PrintStatistics(); /**********************/ /* PRODUCE NICE PLOTS */ /**********************/ if (usedisplay) { MHCamera disp0(geomcam, "MPedPhotCam;ped", "Pedestals"); MHCamera disp1(geomcam, "MPedPhotCam;rms", "Sigma Pedestal"); disp0.SetCamContent(pedphotcam, 0); disp0.SetCamError (pedphotcam, 1); disp1.SetCamContent(pedphotcam, 1); disp0.SetYTitle("Pedestal signal [photons]"); disp1.SetYTitle("Pedestal signal RMS [photons]"); // // Display data // TCanvas &c1 = display->AddTab("PedPhotCam"); c1.Divide(2,3); CamDraw(c1, 1, 2, disp0, 0); CamDraw(c1, 2, 2, disp1, 1); } #if 0 const UShort_t npix = 577; // declare histograms // pedestals TH1F* pedhist = new TH1F("pedhist","Pedestal",npix,0,npix); TH1F* pedrmshist = new TH1F("pedrmshist","Pedestal RMS",npix,0,npix); TH1F* peddist = new TH1F("peddist","Pedestal",100,0,20); TH1F* pedrmsdist = new TH1F("pedrmsdist","Pedestal RMS",100,0,15); // calibration factors TH1F* calhist = new TH1F("calhist","Calibration factors",npix,0,npix); TH1F* caldist = new TH1F("caldist","Calibration factors",100,0,1); TH1F* qehist = new TH1F("qehist", "Quantrum efficiencies",npix,0,npix); TH1F* qedist = new TH1F("qedist", "Quantrum efficiencies",100,0,1); // pedestal signals TH1F* pedphothist = new TH1F("pedphothist","Pedestal Signal",npix,0,npix); TH1F* pedphotrmshist = new TH1F("pedphotrmshist","Pedestal Signal RMS",npix,0,npix); TH1F* pedphotdist = new TH1F("pedphotdist","Pedestal Signal",100,-0.4,0.4); TH1F* pedphotrmsdist = new TH1F("pedphotrmsdist","Pedestal Signal RMS",100,0,25); // fill histograms for(int i=0;iFill(i,ped); peddist->Fill(ped); pedrmshist->Fill(i,pedrms); pedrmsdist->Fill(pedrms); calhist->Fill(i,cal); caldist->Fill(cal); qehist->Fill(i,qe); qedist->Fill(qe); pedphothist->Fill(i,pedphot); pedphotdist->Fill(pedphot); pedphotrmshist->Fill(i,pedphotrms); pedphotrmsdist->Fill(pedphotrms); } // Draw gROOT->Reset(); gStyle->SetCanvasColor(0); TCanvas* canvas = new TCanvas("canvas","pedphotcalc.C", 0, 100, 650, 800); canvas->SetBorderMode(0); // Delete the Canvas' border line canvas->cd(); canvas->Divide(2,5); // draw pedestal histo canvas->cd(1); gPad->cd(); gPad->SetBorderMode(0); pedhist->SetStats(kFALSE); pedhist->GetXaxis()->SetTitle("Pixel SW Id"); pedhist->GetYaxis()->SetTitle("Pedestal (ADC counts)"); pedrmshist->SetStats(kFALSE); pedrmshist->SetLineColor(2); pedhist->Draw(); pedrmshist->Draw("same"); TLegend* leg1 = new TLegend(.14,.68,.39,.88); leg1->SetHeader(""); leg1->AddEntry(pedhist,"Pedestal","L"); leg1->AddEntry(pedrmshist,"Pedestal RMS","L"); leg1->SetFillColor(0); leg1->SetLineColor(0); leg1->SetBorderSize(0); leg1->Draw(); // draw pedestal distribution canvas->cd(2); gPad->cd(); gPad->SetBorderMode(0); peddist->GetXaxis()->SetTitle("Pedestal (ADC counts)"); pedrmsdist->SetLineColor(2); peddist->Draw(); pedrmsdist->Draw("same"); TLegend* leg2 = new TLegend(.14,.68,.39,.88); leg2->SetHeader(""); leg2->AddEntry(pedhist,"Pedestal","L"); leg2->AddEntry(pedrmshist,"Pedestal RMS","L"); leg2->SetFillColor(0); leg2->SetLineColor(0); leg2->SetBorderSize(0); leg2->Draw(); // draw calibration histo canvas->cd(3); gPad->cd(); gPad->SetBorderMode(0); calhist->GetXaxis()->SetTitle("Pixel SW Id"); calhist->SetMaximum(1); calhist->SetMinimum(0); calhist->GetYaxis()->SetTitle("Calibration factor (phe/ADC count)"); calhist->SetStats(kFALSE); calhist->Draw(); // draw calibration distribution canvas->cd(4); gPad->cd(); gPad->SetBorderMode(0); caldist->GetXaxis()->SetTitle("Calibration factor (phe/ADC count)"); caldist->Draw(); // draw qe histo canvas->cd(5); gPad->cd(); gPad->SetBorderMode(0); qehist->GetXaxis()->SetTitle("Pixel SW Id"); qehist->SetMaximum(1); qehist->SetMinimum(0); qehist->GetYaxis()->SetTitle("Quantum efficiency for cascades"); qehist->SetStats(kFALSE); qehist->Draw(); // draw qe distribution canvas->cd(6); gPad->cd(); gPad->SetBorderMode(0); qedist->GetXaxis()->SetTitle("Quantum efficiency for cascades"); qedist->Draw(); // draw pedestal signal histo canvas->cd(7); gPad->cd(); gPad->SetBorderMode(0); pedphothist->GetXaxis()->SetTitle("Pixel SW Id"); pedphothist->GetYaxis()->SetTitle("Pedestal signal (photons)"); pedphothist->SetStats(kFALSE); pedphothist->Draw(); // draw pedestal signal distribution canvas->cd(8); gPad->cd(); gPad->SetBorderMode(0); pedphotdist->GetXaxis()->SetTitle("Pedestal signal (photons)"); pedphotdist->Draw(); // draw pedestal signal rms histo canvas->cd(9); gPad->cd(); gPad->SetBorderMode(0); pedphotrmshist->GetXaxis()->SetTitle("Pixel SW Id"); pedphotrmshist->GetYaxis()->SetTitle("Pedestal signal rms (photons)"); pedphotrmshist->SetStats(kFALSE); pedphotrmshist->Draw(); // draw pedestal signal rms distribution canvas->cd(10); gPad->cd(); gPad->SetBorderMode(0); pedphotrmsdist->GetXaxis()->SetTitle("Pedestal signal rms (photons)"); pedphotrmsdist->Draw(); canvas->SaveAs("pedphotcalc.root"); #endif }