/* ======================================================================== *\ ! ! * ! * 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): Wolfgang Wittek, 04/2003 ! ! Copyright: MAGIC Software Development, 2000-2003 ! ! \* ======================================================================== */ ///////////////////////////////////////////////////////////////////////////// // // // MCT1SupercutsCalc // // // // this class calculates the hadronness for the supercuts // // the parameters of the supercuts are taken // // from the container MCT1Supercuts // // // // // ///////////////////////////////////////////////////////////////////////////// #include "MCT1SupercutsCalc.h" #include #include #include "TFile.h" #include "TArrayD.h" #include "MParList.h" #include "MHillasExt.h" #include "MHillasSrc.h" #include "MNewImagePar.h" #include "MMcEvt.hxx" #include "MCerPhotEvt.h" #include "MGeomCam.h" #include "MHadronness.h" #include "MHMatrix.h" #include "MCT1Supercuts.h" #include "MLog.h" #include "MLogManip.h" ClassImp(MCT1SupercutsCalc); using namespace std; // -------------------------------------------------------------------------- // // constructor // MCT1SupercutsCalc::MCT1SupercutsCalc(const char *hilname, const char *hilsrcname, const char *name, const char *title) : fHadronnessName("MHadronness"), fHilName(hilname), fHilSrcName(hilsrcname), fHilExtName("MHillasExt"), fNewParName("MNewImagePar"), fSuperName("MCT1Supercuts") { fName = name ? name : "MCT1SupercutsCalc"; fTitle = title ? title : "Class to evaluate the Supercuts"; fMatrix = NULL; } // -------------------------------------------------------------------------- // Int_t MCT1SupercutsCalc::PreProcess(MParList *pList) { MGeomCam *cam = (MGeomCam*)pList->FindObject("MGeomCam"); if (!cam) { *fLog << err << "MGeomCam (Camera Geometry) not found... aborting." << endl; return kFALSE; } fMm2Deg = cam->GetConvMm2Deg(); fHadronness = (MHadronness*)pList->FindCreateObj("MHadronness", fHadronnessName); if (!fHadronness) { *fLog << err << fHadronnessName << " [MHadronness] not found... aborting." << endl; return kFALSE; } fSuper = (MCT1Supercuts*)pList->FindObject(fSuperName, "MCT1Supercuts"); if (!fSuper) { *fLog << err << fSuperName << " [MCT1Supercuts] not found... aborting." << endl; return kFALSE; } if (fMatrix) return kTRUE; //----------------------------------------------------------- fHil = (MHillas*)pList->FindObject(fHilName, "MHillas"); if (!fHil) { *fLog << err << fHilName << " [MHillas] not found... aborting." << endl; return kFALSE; } fHilExt = (MHillasExt*)pList->FindObject(fHilExtName, "MHillasExt"); if (!fHilExt) { *fLog << err << fHilExtName << " [MHillasExt] not found... aborting." << endl; return kFALSE; } fHilSrc = (MHillasSrc*)pList->FindObject(fHilSrcName, "MHillasSrc"); if (!fHilSrc) { *fLog << err << fHilSrcName << " [MHillasSrc] not found... aborting." << endl; return kFALSE; } fNewPar = (MNewImagePar*)pList->FindObject(fNewParName, "MNewImagePar"); if (!fNewPar) { *fLog << err << fNewParName << " [MNewImagePar] not found... aborting." << endl; return kFALSE; } fMcEvt = (MMcEvt*)pList->FindObject("MMcEvt"); if (!fMcEvt) { *fLog << err << "MMcEvt not found... aborting." << endl; return kFALSE; } return kTRUE; } // -------------------------------------------------------------------------- // // Calculation of upper and lower limits // Double_t MCT1SupercutsCalc::CtsMCut(const Double_t* a, Double_t ls, Double_t ct, Double_t ls2, Double_t dd2) const { // define cut-function // // dNOMLOGSIZE = 4.1 (=log(60.0) // dNOMCOSZA = 1.0 // // a: array of cut parameters // ls: log(SIZE) - dNOMLOGSIZE // ls2: ls^2 // ct: Cos(ZA.) - dNOMCOSZA // dd2: DIST^2 const Double_t limit = a[0] + a[1] * dd2 + a[2] * ct + ls * (a[3] + a[4] * dd2 + a[5] * ct) + ls2 * (a[6] + a[7] * dd2); //*fLog << "MCT1SupercutsCalc::CtsMCut; *a = " // << *a << ", " << *(a+1) << ", " << *(a+2) << ", " // << *(a+3) << ", " << *(a+4) << ", " << *(a+5) << ", " // << *(a+6) << ", " << *(a+7) << endl; //*fLog << "MCT1SupercutsCalc::CtsMCut; ls, ls2, ct, dd2, limit = " << ls // << ", " << ls2 << ", " << ct << ", " << dd2 << ", " // << limit << endl; return limit; } // -------------------------------------------------------------------------- // // Returns the mapped value from the Matrix // Double_t MCT1SupercutsCalc::GetVal(Int_t i) const { Double_t val = (*fMatrix)[fMap[i]]; //*fLog << "MCT1SupercutsCalc::GetVal; i, fMatrix, fMap, val = " // << i << ", " << fMatrix << ", " << fMap[i] << ", " << val << endl; return val; } // -------------------------------------------------------------------------- // // You can use this function if you want to use a MHMatrix instead of the // given containers. This function adds all necessary columns to the // given matrix. Afterward you should fill the matrix with the corresponding // data (eg from a file by using MHMatrix::Fill). If you now loop // through the matrix (eg using MMatrixLoop) MEnergyEstParam::Process // will take the values from the matrix instead of the containers. // void MCT1SupercutsCalc::InitMapping(MHMatrix *mat) { if (fMatrix) return; fMatrix = mat; fMap[0] = fMatrix->AddColumn("MMcEvt.fTelescopeTheta"); fMap[1] = fMatrix->AddColumn("MHillas.fWidth"); fMap[2] = fMatrix->AddColumn("MHillas.fLength"); fMap[3] = fMatrix->AddColumn("MHillas.fSize"); fMap[4] = fMatrix->AddColumn("MHillas.fMeanX"); fMap[5] = fMatrix->AddColumn("MHillas.fMeanY"); fMap[6] = fMatrix->AddColumn("MHillasSrc.fDist"); fMap[7] = fMatrix->AddColumn("fabs(MHillasSrc.fAlpha)"); fMap[8] = fMatrix->AddColumn("sgn(MHillasSrc.fCosDeltaAlpha)*(MHillasExt.fM3Long)"); fMap[9] = fMatrix->AddColumn("MNewImagePar.fConc"); fMap[10]= fMatrix->AddColumn("MNewImagePar.fLeakage1"); } // --------------------------------------------------------------------------- // // Evaluate dynamical supercuts // // set hadronness to 0.25 if cuts are fullfilled // 0.75 otherwise // Int_t MCT1SupercutsCalc::Process() { const Double_t kNomLogSize = 4.1; const Double_t kNomCosZA = 1.0; const Double_t theta = fMatrix ? GetVal(0) : fMcEvt->GetTelescopeTheta(); const Double_t width0 = fMatrix ? GetVal(1) : fHil->GetWidth(); const Double_t length0 = fMatrix ? GetVal(2) : fHil->GetLength(); const Double_t size = fMatrix ? GetVal(3) : fHil->GetSize(); const Double_t meanx = fMatrix ? GetVal(4) : fHil->GetMeanX(); const Double_t meany = fMatrix ? GetVal(5) : fHil->GetMeanY(); const Double_t dist0 = fMatrix ? GetVal(6) : fHilSrc->GetDist(); Double_t help; if (!fMatrix) help = TMath::Sign(fHilExt->GetM3Long(), fHilSrc->GetCosDeltaAlpha()); const Double_t asym0 = fMatrix ? GetVal(8) : help; const Double_t conc = fMatrix ? GetVal(9) : fNewPar->GetConc(); const Double_t leakage = fMatrix ? GetVal(10): fNewPar->GetLeakage1(); const Double_t newdist = dist0 * fMm2Deg; const Double_t dist2 = meanx*meanx + meany*meany; const Double_t dist = sqrt(dist2) * fMm2Deg; const Double_t dd2 = dist*dist; const Double_t dmls = log(size) - kNomLogSize; const Double_t dmls2 = dmls * dmls; const Double_t dmcza = cos(theta) - kNomCosZA; const Double_t length = length0 * fMm2Deg; const Double_t width = width0 * fMm2Deg; const Double_t asym = asym0 * fMm2Deg; /* *fLog << "newdist, length, width, asym, dist, conc, leakage = " << newdist << ", " << length << ", " << width << ", " << asym << ", " << dist << ", " << conc << ", " << leakage << endl; *fLog << "upper cuts in newdist, length, width, asym, dist, conc, leakage = " << CtsMCut (fSuper->GetDistUp(), dmls, dmcza, dmls2, dd2) << ", " << CtsMCut (fSuper->GetDistLo(), dmls, dmcza, dmls2, dd2) << ", " << CtsMCut (fSuper->GetLengthUp(), dmls, dmcza, dmls2, dd2) << ", " << CtsMCut (fSuper->GetLengthLo(), dmls, dmcza, dmls2, dd2) << ", " << CtsMCut (fSuper->GetWidthUp(), dmls, dmcza, dmls2, dd2) << ", " << CtsMCut (fSuper->GetWidthLo(), dmls, dmcza, dmls2, dd2) << ", " << CtsMCut (fSuper->GetAsymUp(), dmls, dmcza, dmls2, dd2) << ", " << CtsMCut (fSuper->GetAsymLo(), dmls, dmcza, dmls2, dd2) << ", " << CtsMCut (fSuper->GetDistUp(), dmls, dmcza, dmls2, dd2) << ", " << CtsMCut (fSuper->GetDistLo(), dmls, dmcza, dmls2, dd2) << ", " << CtsMCut (fSuper->GetConcUp(), dmls, dmcza, dmls2, dd2) << ", " << CtsMCut (fSuper->GetConcLo(), dmls, dmcza, dmls2, dd2) << ", " << CtsMCut (fSuper->GetLeakage1Up(), dmls, dmcza, dmls2, dd2) << ", " << CtsMCut (fSuper->GetLeakage1Lo(), dmls, dmcza, dmls2, dd2) << ", " << endl; */ if ( //dist < 1.05 && //newdist < 1.05 && newdist < CtsMCut (fSuper->GetDistUp(), dmls, dmcza, dmls2, dd2) && newdist > CtsMCut (fSuper->GetDistLo(), dmls, dmcza, dmls2, dd2) && length < CtsMCut (fSuper->GetLengthUp(), dmls, dmcza, dmls2, dd2) && length > CtsMCut (fSuper->GetLengthLo(), dmls, dmcza, dmls2, dd2) && width < CtsMCut (fSuper->GetWidthUp(), dmls, dmcza, dmls2, dd2) && width > CtsMCut (fSuper->GetWidthLo(), dmls, dmcza, dmls2, dd2) && asym < CtsMCut (fSuper->GetAsymUp(), dmls, dmcza, dmls2, dd2) && asym > CtsMCut (fSuper->GetAsymLo(), dmls, dmcza, dmls2, dd2) && dist < CtsMCut (fSuper->GetDistUp(), dmls, dmcza, dmls2, dd2) && dist > CtsMCut (fSuper->GetDistLo(), dmls, dmcza, dmls2, dd2) && conc < CtsMCut (fSuper->GetConcUp(), dmls, dmcza, dmls2, dd2) && conc > CtsMCut (fSuper->GetConcLo(), dmls, dmcza, dmls2, dd2) && leakage < CtsMCut (fSuper->GetLeakage1Up(),dmls, dmcza, dmls2, dd2) && leakage > CtsMCut (fSuper->GetLeakage1Lo(),dmls, dmcza, dmls2, dd2) ) fHadronness->SetHadronness(0.25); else fHadronness->SetHadronness(0.75); //*fLog << "SChadroness = " << fHadronness->GetHadronness() << endl; fHadronness->SetReadyToSave(); return kTRUE; }