/* ======================================================================== *\ ! ! * ! * This file is part of CheObs, the Modular 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 appears 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): Qi Zhe, 06/2007 ! ! Copyright: CheObs Software Development, 2000-2010 ! ! \* ======================================================================== */ ///////////////////////////////////////////////////////////////////////////// // // MPhotonData // // Storage container to store Corsika events // // For details on the coordinate systems see our Wiki. // // Version 1: // ---------- // * First implementation // // Version 2: // ---------- // - fNumPhotons // ///////////////////////////////////////////////////////////////////////////// #include "MPhotonData.h" #include #include #include #include #include "MLog.h" #include "MLogManip.h" ClassImp(MPhotonData); using namespace std; // -------------------------------------------------------------------------- // // Default constructor. // MPhotonData::MPhotonData(/*const char *name, const char *title*/) : fPosX(0), fPosY(0), fCosU(0), fCosV(0), fTime(0), fWavelength(0), /*fNumPhotons(1),*/ fProductionHeight(0), fPrimary(MMcEvtBasic::kUNDEFINED), fTag(-1), fMirrorTag(-1), fWeight(1) { // fName = name ? name : "MPhotonData"; // fTitle = title ? title : "Corsika Event Data Information"; } /* MPhotonData::MPhotonData(const MPhotonData &ph) : fPosX(ph.fPosX), fPosY(ph.fPosY), fCosU(ph.fCosU), fCosV(ph.fCosV), fTime(ph.fTime), fWavelength(ph.fWavelength), fNumPhotons(ph.fNumPhotons), fProductionHeight(ph.fProductionHeight), fPrimary(ph.fPrimary), fTag(ph.fTag), fWeight(ph.fWeight) { } */ // -------------------------------------------------------------------------- // // Copy function. Copy all data members into obj. // void MPhotonData::Copy(TObject &obj) const { MPhotonData &d = static_cast(obj); // d.fNumPhotons = fNumPhotons; d.fPosX = fPosX; d.fPosY = fPosY; d.fCosU = fCosU; d.fCosV = fCosV; d.fWavelength = fWavelength; d.fPrimary = fPrimary; d.fTime = fTime; d.fTag = fTag; d.fWeight = fWeight; d.fProductionHeight = fProductionHeight; TObject::Copy(obj); } // -------------------------------------------------------------------------- // // Return the square cosine of the Theta-angle == 1-CosU^2-CosV^2 // Double_t MPhotonData::GetCosW2() const { return 1 - GetSinW2(); } // -------------------------------------------------------------------------- // // Return the square sine of the Theta-angle == CosU^2+CosV^2 // Double_t MPhotonData::GetSinW2() const { const Double_t sinw2 = fCosU*fCosU + fCosV*fCosV; return sinw2>1 ? 1 : sinw2; } // -------------------------------------------------------------------------- // // return the cosine of the Theta-angle == sqrt(1-CosU^2-CosV^2) // Double_t MPhotonData::GetCosW() const { return TMath::Sqrt(GetCosW2()); } // -------------------------------------------------------------------------- // // return the sine of the Theta-angle == sqrt(CosU^2+CosV^2) // Double_t MPhotonData::GetSinW() const { return TMath::Sqrt(GetSinW2()); } // -------------------------------------------------------------------------- // // Return the theta angle in radians // Double_t MPhotonData::GetTheta() const { return TMath::ASin(GetSinW()); } // -------------------------------------------------------------------------- // // Return a TQuaternion with the first three components x, y, and z // and the fourth component the time. // TQuaternion MPhotonData::GetPosQ() const { return TQuaternion(GetPos3(), fTime); } // -------------------------------------------------------------------------- // // return a TQuaternion with the first three components the direction // moving in space (GetDir3()) and the fourth component is the // one devided by the speed of light (converted to cm/ns) // // FIXME: v in air! // TQuaternion MPhotonData::GetDirQ() const { return TQuaternion(GetDir3(), 1./(TMath::C()*100/1e9)); } // -------------------------------------------------------------------------- // // Set the wavelength to a random lambda^-2 distributed value // between wmin and wmax. // void MPhotonData::SimWavelength(Float_t wmin, Float_t wmax) { const Double_t w = gRandom->Uniform(wmin, wmax); fWavelength = TMath::Nint(wmin*wmax / w); } // -------------------------------------------------------------------------- // // Set the data member according to the 8 floats read from a reflector-file. // This function MUST reset all data-members, no matter whether these are // contained in the input stream. // Int_t MPhotonData::FillRfl(Float_t f[8]) { // Check coordinate system!!!! fWavelength = TMath::Nint(f[0]); fPosX = f[1]; // [cm] fPosY = f[2]; // [cm] fCosU = f[3]; // cos to x fCosV = f[4]; // cos to y fTime = f[5]; // [ns] fProductionHeight = f[6]; // f[7]: Camera inclination angle fPrimary = MMcEvtBasic::kUNDEFINED; // fNumPhotons = 1; fTag = -1; fWeight = 1; return kTRUE; } // -------------------------------------------------------------------------- // // Set the data member according to the 7 floats read from a corsika-file. // This function MUST reset all data-members, no matter whether these are // contained in the input stream. // // Currently we exchange x and y and set y=-y to convert Corsikas coordinate // system intpo our own. // Int_t MPhotonData::FillCorsika(Float_t f[7], Int_t i) { const UInt_t n = TMath::Nint(f[0]); if (n==0) // FIXME: Do we need to decode the rest anyway? return kCONTINUE; // Check reuse if (i >=0) { const Int_t reuse = (n/1000)%100; // Force this to be 1! if (reuse!=i) return kCONTINUE; } // This seems to be special to mmcs fWavelength = n%1000; fPrimary = MMcEvtBasic::ParticleId_t(n/100000); // x=north, y=west //fPosX = f[1]; // [cm] //fPosY = f[2]; // [cm] //fCosU = f[3]; // cos to x //fCosV = f[4]; // cos to y // x=west, y=south fPosX = f[2]; // [cm] fPosY = -f[1]; // [cm] fCosU = f[4]; // cos to x fCosV = -f[3]; // cos to y fTime = f[5]; // [ns] fProductionHeight = f[6]; // [cm] // Now reset all data members which are not in the stream fTag = -1; fWeight = 1; return kTRUE; } // -------------------------------------------------------------------------- // // Set the data member according to the 8 shorts read from a eventio-file. // This function MUST reset all data-members, no matter whether these are // contained in the input stream. // // Currently we exchange x and y and set y=-y to convert Corsikas coordinate // system into our own. // Int_t MPhotonData::FillEventIO(Short_t f[8]) { // From 5.5 compact_bunch: // https://www.mpi-hd.mpg.de/hfm/~bernlohr/iact-atmo/iact_refman.pdf // photons in this bunch f[6]/100. fPosY = -f[0]/10.; // ypos relative to telescope [cm] fPosX = f[1]/10.; // xpos relative to telescope [cm] fCosV = -f[2]/30000.; // cos to y fCosU = f[3]/30000.; // cos to x fTime = f[4]/10.; // a relative arival time [ns] fProductionHeight = pow(10, f[5]/1000.); // altitude of emission a.s.l. [cm] fWavelength = f[7]; // wavelength [nm]: 0 undetermined, <0 already in p.e. // Now reset all data members which are not in the stream fPrimary = MMcEvtBasic::kUNDEFINED; fTag = -1; fWeight = 1; return 1; } // -------------------------------------------------------------------------- // // Set the data member according to the 8 floats read from a eventio-file. // This function MUST reset all data-members, no matter whether these are // contained in the input stream. // // Currently we exchange x and y and set y=-y to convert Corsikas coordinate // system into our own. // Int_t MPhotonData::FillEventIO(Float_t f[8]) { // photons in this bunch const UInt_t n = TMath::Nint(f[6]); if (n==0) return 0; fPosX = f[1]; // xpos relative to telescope [cm] fPosY = -f[0]; // ypos relative to telescope [cm] fCosU = f[3]; // cos to x fCosV = -f[2]; // cos to y //fTime = f[4]; // a relative arival time [ns] //fProductionHeight = f[5]; // altitude of emission [cm] fWavelength = 0; // so far always zeor = unspec. [nm] // Now reset all data members which are not in the stream fPrimary = MMcEvtBasic::kUNDEFINED; fTag = -1; fWeight = 1; return n-1; } /* // -------------------------------------------------------------------------- // // Read seven floats from the stream and call FillCorsika for them. // Int_t MPhotonData::ReadCorsikaEvt(istream &fin) { Float_t f[7]; fin.read((char*)&f, 7*4); const Int_t rc = FillCorsika(f); return rc==kTRUE ? !fin.eof() : rc; } // -------------------------------------------------------------------------- // // Read eight floats from the stream and call FillRfl for them. // Int_t MPhotonData::ReadRflEvt(istream &fin) { Float_t f[8]; fin.read((char*)&f, 8*4); const Int_t rc = FillRfl(f); return rc==kTRUE ? !fin.eof() : rc; } */ // -------------------------------------------------------------------------- // // Print contents. The tag and Weight are only printed if they are different // from the default. // void MPhotonData::Print(Option_t *) const { gLog << inf << endl; // gLog << "Num Photons: " << fNumPhotons << " from " << MMcEvtBasic::GetParticleName(fPrimary) << endl; gLog << "Origin: " << MMcEvtBasic::GetParticleName(fPrimary) << endl; gLog << "Wavelength: " << fWavelength << "nm" << endl; gLog << "Pos X/Y Cos U/V: " << fPosX << "/" << fPosY << " " << fCosU << "/" << fCosV << endl; gLog << "Time/Prod.Height: " << fTime << "ns/" << fProductionHeight/100 << "m" << endl; if (fTag>=0) gLog << "Tag: " << fTag << endl; if (fWeight!=1) gLog << "Weight: " << fWeight << endl; }