/* ======================================================================== *\ ! ! * ! * 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): Thomas Bretz 12/2000 ! Author(s): Harald Kornmayer 1/2001 ! ! Copyright: MAGIC Software Development, 2000-2009 ! ! \* ======================================================================== */ ////////////////////////////////////////////////////////////////////////////// // // MHCollectionArea // // Class Version 2: // ---------------- // + added //! to fMcEvt which was missing before // - removed obsolete data member fEnergy // ////////////////////////////////////////////////////////////////////////////// #include "MHCollectionArea.h" #include #include #include #include #include "MLog.h" #include "MLogManip.h" #include "MString.h" #include "MBinning.h" #include "MMcEvt.hxx" #include "MMcRunHeader.hxx" #include "MMcCorsikaRunHeader.h" #include "MParList.h" #include "MParameters.h" ClassImp(MHCollectionArea); using namespace std; // -------------------------------------------------------------------------- // // Creates the three necessary histograms: // - selected showers (input) // - all showers (input) // - collection area (result) // MHCollectionArea::MHCollectionArea(const char *name, const char *title) : fMcEvt(0), fHeader(0), fMcAreaRadius(-1), fTotalNumSimulatedShowers(0), fAllEvtsTriggered(kFALSE), fIsExtern(kFALSE) { // initialize the histogram for the distribution r vs E // // we set the energy range from 2 Gev to 20000 GeV (in log 4 orders // of magnitude) and for each order we take 25 subdivision --> 100 xbins // // we set the radius range from 0 m to 500 m with 10 m bin --> 50 ybins // fName = name ? name : "MHCollectionArea"; fTitle = title ? title : "Collection Area vs. Energy/Theta"; fHistSel.SetName("SelEvts"); fHistSel.SetTitle("Number of Events after cuts"); fHistSel.SetXTitle("\\Theta [deg]"); fHistSel.SetYTitle("E [GeV]"); fHistSel.SetDirectory(NULL); fHistSel.UseCurrentStyle(); fHistSel.SetLineColor(kBlue); fHistAll.SetName("AllEvts"); fHistAll.SetTitle("Number of events produced"); fHistAll.SetXTitle("\\Theta [deg]"); fHistAll.SetYTitle("E_{mc} [GeV]"); fHistAll.SetDirectory(NULL); fHistAll.UseCurrentStyle(); fHEnergy.SetName("CollEnergy"); fHEnergy.SetTitle("Collection Area"); fHEnergy.SetXTitle("E [GeV]"); fHEnergy.SetYTitle("A_{eff} [m^{2}]"); fHEnergy.SetDirectory(NULL); fHEnergy.UseCurrentStyle(); MBinning binsa, binse, binst; binse.SetEdgesLog(21, 6.3, 100000); binst.SetEdgesASin(67, -0.005, 0.665); binse.Apply(fHEnergy); MH::SetBinning(fHistSel, binst, binse); MH::SetBinning(fHistAll, binst, binse); // For some unknown reasons this must be called after // the binning has been initialized at least once fHistSel.Sumw2(); fHistAll.Sumw2(); fHEnergy.Sumw2(); } // -------------------------------------------------------------------------- // // Return the Area defined by fMcAreaRadius // Double_t MHCollectionArea::GetCollectionAreaAbs() const { return TMath::Pi()*fMcAreaRadius*fMcAreaRadius; } // -------------------------------------------------------------------------- // // Calculate the Efficiency (collection area) and set the 'ReadyToSave' // flag // void MHCollectionArea::CalcEfficiency() { TH1D *hsel = fHistSel.ProjectionY("Spy", -1, -1, "E");; TH1D *hall = fHistAll.ProjectionY("Apy", -1, -1, "E"); // // Impact parameter range. // const Float_t totalarea = GetCollectionAreaAbs();//TMath::Pi() * (r2*r2 - r1*r1); // "b" option: calculate binomial errors // Do not use totalarea inside the binomial error calculation: // it is not a weight. fHEnergy.Divide(hsel, hall, 1, 1, "b"); #if ROOT_VERSION_CODE < ROOT_VERSION(5,13,04) MH::SetBinomialErrors(fHEnergy, *hsel, *hall); #endif if (fMcAreaRadius>0) fHEnergy.Scale(totalarea); delete hsel; delete hall; } Bool_t MHCollectionArea::SetupFill(const MParList *pl) { fHistSel.Reset(); if (!fIsExtern) fHistAll.Reset(); fHeader = (MMcRunHeader*)pl->FindObject("MMcRunHeader"); if (!fHeader) { *fLog << err << "MMcRunHeader not found... abort." << endl; return kFALSE; } fMcEvt = (MMcEvt*)pl->FindObject("MMcEvt"); if (!fMcEvt) { *fLog << err << "MMcEvt not found... abort." << endl; return kFALSE; } /* fEnergy = (MParameterD*)pl->FindObject("MEnergyEst", "MParameterD"); if (!fEnergy) { *fLog << err << "MEnergyEst [MParameterD] not found... abort." << endl; return kFALSE; } */ MBinning binst, binse; binst.SetEdges(fHistAll, 'x'); binse.SetEdges(fHistAll, 'y'); //if (!fIsExtern) { MBinning *bins = (MBinning*)pl->FindObject("BinningTheta", "MBinning"); if (bins) binst.SetEdges(*bins); bins = (MBinning*)pl->FindObject("BinningEnergyEst", "MBinning"); if (bins) binse.SetEdges(*bins); } binse.Apply(fHEnergy); MH::SetBinning(fHistSel, binst, binse); MH::SetBinning(fHistAll, binst, binse); fMcAreaRadius = -1; fCorsikaVersion = 0; return kTRUE; } void MHCollectionArea::GetImpactMax() { if (fHeader->GetImpactMax()<=fMcAreaRadius*100 || fHeader->GetImpactMax()<0) return; fMcAreaRadius = 0.01*fHeader->GetImpactMax(); // cm->m *fLog << inf << "Maximum simulated impact: " << fMcAreaRadius << "m" << endl; } Bool_t MHCollectionArea::ReInit(MParList *plist) { GetImpactMax(); if (fCorsikaVersion!=0 && fCorsikaVersion!=fHeader->GetCorsikaVersion()) { *fLog << warn; *fLog << "Warning - Read files have different Corsika versions..." << endl; *fLog << " Last file=" << fCorsikaVersion << " New file=" << fHeader->GetCorsikaVersion() << endl; } fCorsikaVersion = fHeader->GetCorsikaVersion(); if (fIsExtern) return kTRUE; fTotalNumSimulatedShowers += fHeader->GetNumSimulatedShowers(); *fLog << inf << "Total Number of Simulated showers: " << fTotalNumSimulatedShowers << endl; fAllEvtsTriggered |= fHeader->GetAllEvtsTriggered(); *fLog << inf << "Only triggered events avail: " << (fAllEvtsTriggered?"yes":"no") << endl; MMcCorsikaRunHeader *crh = (MMcCorsikaRunHeader*)plist->FindObject("MMcCorsikaRunHeader"); if (!crh) { *fLog << err << "MMcCorsikaRunHeader not found... abort." << endl; return kFALSE; } // // Calculate approximately the original number of events in each // energy bin: // const Float_t emin = crh->GetELowLim(); const Float_t emax = crh->GetEUppLim(); const Float_t expo = 1 + crh->GetSlopeSpec(); const Float_t k = fHeader->GetNumSimulatedShowers() / (pow(emax,expo) - pow(emin,expo)); const Int_t nbiny = fHistAll.GetNbinsY(); TAxis &axe = *fHistAll.GetYaxis(); for (Int_t i = 1; i <= nbiny; i++) { const Float_t e1 = axe.GetBinLowEdge(i); const Float_t e2 = axe.GetBinLowEdge(i+1); if (e1 < emin || e2 > emax) continue; const Float_t events = k * (pow(e2, expo) - pow(e1, expo)); // // We fill the i-th energy bin, with the total number of events // Second argument of Fill would be impact parameter of each // event, but we don't really need it for the collection area, // so we just put a dummy value (1.) // const Float_t energy = (e1+e2)/2.; for (int j=0; j A_{max}=%.0fm^{2}", fMcAreaRadius, GetCollectionAreaAbs()); TLatex text(0.31, 0.95, txt); text.SetBit(TLatex::kTextNDC); text.SetTextSize(0.04); text.Paint(); return; } TVirtualPad *pad; TPaveStats *st=0; for (int x=0; x<4; x++) { pad=gPad->GetPad(x+1); if (!pad || !(st = (TPaveStats*)pad->GetPrimitive("stats"))) continue; if (st->GetOptStat()==11) continue; const Double_t y1 = st->GetY1NDC(); const Double_t y2 = st->GetY2NDC(); const Double_t x1 = st->GetX1NDC(); const Double_t x2 = st->GetX2NDC(); st->SetY1NDC((y2-y1)/3+y1); st->SetX1NDC((x2-x1)/3+x1); st->SetOptStat(11); } pad = gPad; TH1 *h1=0, *h2=0; pad->cd(1); if (gPad->FindObject("ProjSelX")) fHistSel.ProjectionX("ProjSelX", -1, -1, "E"); pad->cd(2); if (gPad->FindObject("ProjAllY")) h1=fHistAll.ProjectionY("ProjAllY", -1, -1, "E"); if (gPad->FindObject("ProjSelY")) h2=fHistSel.ProjectionY("ProjSelY", -1, -1, "E"); if (h1 && h1->GetMaximum()>0) { gPad->SetLogx(); gPad->SetLogy(); } pad->cd(3); TH1 *h=dynamic_cast(gPad->FindObject("Efficiency")); if (h1 && h2 && h) { h->Divide(h2, h1, 1, 1, "b"); #if ROOT_VERSION_CODE < ROOT_VERSION(5,13,04) MH::SetBinomialErrors(*h, *h2, *h1); #endif h->SetMinimum(0); } pad->cd(4); CalcEfficiency(); if (fHEnergy.GetMaximum()>0) { gPad->SetLogx(); gPad->SetLogy(); } } void MHCollectionArea::Draw(Option_t *option) { TVirtualPad *pad = gPad ? gPad : MakeDefCanvas(this); // Do the projection before painting the histograms into // the individual pads AppendPad(); pad->SetBorderMode(0); pad->Divide(2,2); TH1 *h=0, *h1=0, *h2=0; if (fHistSel.GetNbinsX()>1) { pad->cd(1); gPad->SetBorderMode(0); gPad->SetGridx(); gPad->SetGridy(); /* h = fHistAll.ProjectionX("ProjAllX", -1, -1, "E"); h->SetXTitle("\\Theta [#circ]"); h->SetDirectory(NULL); h->SetLineColor(kGreen); h->SetBit(kCanDelete); h->Draw(); */ h = fHistSel.ProjectionX("ProjSelX", -1, -1, "E"); h->SetXTitle("\\Theta [#circ]"); h->SetDirectory(NULL); h->SetLineColor(kRed); h->SetBit(kCanDelete); h->Draw("hist"/*"same"*/); } else delete pad->GetPad(1); if (fHistSel.GetNbinsY()>1) { pad->cd(2); gPad->SetBorderMode(0); gPad->SetGridx(); gPad->SetGridy(); h1 = fHistAll.ProjectionY("ProjAllY", -1, -1, "E"); h1->SetDirectory(NULL); h1->SetLineColor(kGreen); h1->SetXTitle("E [GeV]"); h1->SetBit(kCanDelete); h1->Draw(); h2 = fHistSel.ProjectionY("ProjSelY", -1, -1, "E"); h2->SetDirectory(NULL); h2->SetLineColor(kRed); h2->SetBit(kCanDelete); h2->Draw("same"); } else delete pad->GetPad(2); if (h1 && h2) { pad->cd(3); gPad->SetBorderMode(0); gPad->SetGridx(); gPad->SetGridy(); gPad->SetLogx(); h = h2->DrawCopy(); h->Divide(h2, h1, 1, 1, "b"); #if ROOT_VERSION_CODE < ROOT_VERSION(5,13,04) MH::SetBinomialErrors(*h, *h2, *h1); #endif h->SetNameTitle("Efficiency", "Efficiency"); h->SetDirectory(NULL); //AppendPad("paint3"); } else delete pad->GetPad(4); if (fHEnergy.GetNbinsX()>1) { pad->cd(4); gPad->SetBorderMode(0); gPad->SetGridx(); gPad->SetGridy(); fHEnergy.Draw(); AppendPad("paint4"); } else delete pad->GetPad(4); } Int_t MHCollectionArea::Fill(const MParContainer *par, const Stat_t weight) { // This is not perfect because it selects the maximum impact only // from the selected events. Hoever, it will get overwritten // in finalize anyway. const Double_t impact = fMcEvt->GetImpact()*0.01; // cm->m if (impact>fMcAreaRadius) fMcAreaRadius = impact; const Double_t energy = fMcEvt->GetEnergy(); const Double_t theta = fMcEvt->GetTelescopeTheta()*TMath::RadToDeg(); fHistSel.Fill(theta, energy, weight); return kTRUE; } Bool_t MHCollectionArea::Finalize() { GetImpactMax(); *fLog << all << "Maximum simulated impact found: " << fMcAreaRadius << "m" << endl; CalcEfficiency(); return kTRUE; }