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MassResolution.cc
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MassResolution.cc
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#include "MassResolution.h"
//----------------------------------------------------------//
// Project: MassResolution
// Author: Matt Kenzie (matthew.william.kenzie@cern.ch)
// Modified: 25/08/2011
// Admins: Matth Kenzie (matthew.william.kenzie@cern.ch)
//---------------------------------------------------------//
/*
See MassResolution.h for instructions
*/
MassResolution::MassResolution(){}
void MassResolution::Setup(LoopAll &l, PhotonReducedInfo *leadInfo, PhotonReducedInfo *subleadInfo,int vtx_index,EnergySmearer::energySmearingParameters eSmearPars, int nR9Categories, int nEtaCategories, double beamspotSigma_in, bool usethisvtx) {
beamspotSigma= beamspotSigma_in;
leadPhoton= leadInfo;
subleadPhoton= subleadInfo;
vertex = (TVector3*)l.vtx_std_xyz->At(vtx_index);
vtx_dxdydz = (TVector3*)l.vtx_std_dxdydz->At(vtx_index);
//lead_sc_pos = leadPhoton->caloPosition();
//sublead_sc_pos = subleadPhoton->caloPosition();
lead_Eres = leadPhoton->corrEnergyErr() / leadPhoton->corrEnergy();
sublead_Eres = subleadPhoton->corrEnergyErr() / subleadPhoton->corrEnergy();
lead_r9 = leadPhoton->r9();
sublead_r9 = subleadPhoton->r9();
lead_iDet = leadPhoton->iDet();
sublead_iDet = subleadPhoton->iDet();
TLorentzVector lead_p4=leadPhoton->p4(vertex->X(),vertex->Y(),vertex->Z());
TLorentzVector sublead_p4=subleadPhoton->p4(vertex->X(),vertex->Y(),vertex->Z());
higgsMass=(lead_p4+sublead_p4).M();
_eSmearPars=eSmearPars;
}
void MassResolution::Setup(LoopAll &l, PhotonReducedInfo *leadInfo, PhotonReducedInfo *subleadInfo,int diphoton_index,EnergySmearer::energySmearingParameters eSmearPars, int nR9Categories, int nEtaCategories, double beamspotSigma_in)
{
Setup(l, leadInfo, subleadInfo, l.dipho_vtxind[diphoton_index], eSmearPars, nR9Categories, nEtaCategories, beamspotSigma_in, true);
}
// return the mass resolution given correct vertex
double MassResolution::relMassResolutionCorrVtx(){
TLorentzVector lead_p4=leadPhoton->p4(vertex->X(),vertex->Y(),vertex->Z());
TLorentzVector sublead_p4=subleadPhoton->p4(vertex->X(),vertex->Y(),vertex->Z());
double alpha = lead_p4.Angle(sublead_p4.Vect());
double lead_sig = leadRelPhotonResolution();
double sublead_sig = subleadRelPhotonResolution();
double alpha_sig = angleResolutionCorrVtx();
return 0.5*TMath::Sqrt((lead_sig*lead_sig)+(sublead_sig*sublead_sig)
+((alpha_sig*alpha_sig)*(TMath::Sin(alpha)/(1.-TMath::Cos(alpha)))*(TMath::Sin(alpha)/(1.-TMath::Cos(alpha)))));
}
double MassResolution::relMassResolutionCorrVtxNoSmear(){
TLorentzVector lead_p4=leadPhoton->p4(vertex->X(),vertex->Y(),vertex->Z());
TLorentzVector sublead_p4=subleadPhoton->p4(vertex->X(),vertex->Y(),vertex->Z());
double alpha = lead_p4.Angle(sublead_p4.Vect());
double lead_sig = leadRelPhotonResolutionNoSmear();
double sublead_sig = subleadRelPhotonResolutionNoSmear();
double alpha_sig = angleResolutionCorrVtx();
return 0.5*TMath::Sqrt((lead_sig*lead_sig)+(sublead_sig*sublead_sig)
+((alpha_sig*alpha_sig)*(TMath::Sin(alpha)/(1.-TMath::Cos(alpha)))*(TMath::Sin(alpha)/(1.-TMath::Cos(alpha)))));
}
// return the mass resolution wrong vertex
double MassResolution::relMassResolutionWrongVtx(){
double alpha_sig = 0.5*angleResolutionWrongVtx();
double sigmaM = relMassResolutionEonly();
return TMath::Sqrt((sigmaM*sigmaM)+(alpha_sig*alpha_sig));
}
double MassResolution::relMassResolutionWrongVtxNoSmear(){
double alpha_sig = 0.5*angleResolutionWrongVtx();
double sigmaM = relMassResolutionEonlyNoSmear();
return TMath::Sqrt((sigmaM*sigmaM)+(alpha_sig*alpha_sig));
}
// return energy contribution to mass resolution only
double MassResolution::relMassResolutionEonly() {
double lead_sig = leadRelPhotonResolution();
double sublead_sig = subleadRelPhotonResolution();
return 0.5*TMath::Sqrt((lead_sig*lead_sig)+(sublead_sig*sublead_sig));
}
double MassResolution::relMassResolutionEonlyNoSmear(){
double lead_sig = leadRelPhotonResolutionNoSmear();
double sublead_sig = subleadRelPhotonResolutionNoSmear();
return 0.5*TMath::Sqrt((lead_sig*lead_sig)+(sublead_sig*sublead_sig));
}
double MassResolution::relMassResolutionAonly(){
double aRes = angleResolution();
return 0.5*aRes;
}
// return angle resolution given the vertex choice is correct
double MassResolution::angleResolutionCorrVtx() {
return propagateDz(dzResolutionCorrVtx());
}
// return angle resolution given the vertex choice is wrong
double MassResolution::angleResolutionWrongVtx() {
return propagateDz(dzResolutionWrongVtx());
}
// return angle resolution given a convolution of correct/wrong vertex as func of higgsPt
double MassResolution::angleResolution() {
return propagateDz(dzResolution());
}
// return lead photon resolution without smearing
double MassResolution::leadRelPhotonResolutionNoSmear() {
return lead_Eres;
}
// return sublead photon resolution without smearing
double MassResolution::subleadRelPhotonResolutionNoSmear() {
return sublead_Eres;
}
// return lead photon resolution
double MassResolution::leadRelPhotonResolution() {
bool sphericalLeadPhoton_=leadPhoton->isSphericalPhoton();
return getRelPhotonResolution(lead_Eres, *leadPhoton);
}
// return sublead photon resolution
double MassResolution::subleadRelPhotonResolution() {
bool sphericalSubleadPhoton_=subleadPhoton->isSphericalPhoton();
return getRelPhotonResolution(sublead_Eres,*subleadPhoton);
}
// Actually compute resolution given a photon
double MassResolution::getRelPhotonResolution(double photonResolution, const PhotonReducedInfo &info) {
// Get the photon-category sigma
std::string myCategory = EnergySmearer::photonCategory(_eSmearPars, info);
double categoryResolution = EnergySmearer::getSmearingSigma(_eSmearPars, myCategory, info.corrEnergy(),
info.caloPosition().Eta(), 0.);
return TMath::Sqrt(categoryResolution*categoryResolution + photonResolution*photonResolution);
}
//return dz resolution given correct vertex (used 10mm)
double MassResolution::dzResolutionCorrVtx() {
return 0.1;
}
//return dz resolution given wrong vertex (using sqrt(2)*5.8cm)
double MassResolution::dzResolutionWrongVtx() {
return TMath::Sqrt(2.)*beamspotSigma;
}
//return dz resolution from dz wrong and dz right (stored in TGraph as func of higgsPt)
double MassResolution::dzResolution() {
return dz;
}
// propagate error on z to error on angle
double MassResolution::propagateDz(double dz){
// TLorentzVector lead_p4=leadPhoton->p4(vertex->X(),vertex->Y(),vertex->Z());
// TLorentzVector sublead_p4=subleadPhoton->p4(vertex->X(),vertex->Y(),vertex->Z());
// double alpha = //lead_p4.Angle(sublead_p4.Vect());
// if (alpha!= sublead_p4.Angle(lead_p4.Vect())) std::cout << "Error: Angle between photons not consistent" << std::endl;
TVector3 LeadPosition = (leadPhoton->caloPosition()) - *vertex;
TVector3 SubLeadPosition = (subleadPhoton->caloPosition()) - *vertex;
/*
double x1 = leadPhoton->caloPosition().X();
double y1 = leadPhoton->caloPosition().Y();
double z1 = leadPhoton->caloPosition().Z();
double x2 = subleadPhoton->caloPosition().X();
double y2 = subleadPhoton->caloPosition().Y();
double z2 = subleadPhoton->caloPosition().Z();
*/
double x1 = leadPhoton->caloPosition().X()-vertex->X();
double y1 = leadPhoton->caloPosition().Y()-vertex->Y();
double z1 = leadPhoton->caloPosition().Z()-vertex->Z();
double x2 = subleadPhoton->caloPosition().X()-vertex->X();
double y2 = subleadPhoton->caloPosition().Y()-vertex->Y();
double z2 = subleadPhoton->caloPosition().Z()-vertex->Z();
double r1 = TMath::Sqrt(x1*x1+y1*y1+z1*z1);
double r2 = TMath::Sqrt(x2*x2+y2*y2+z2*z2);
double cos_term = TMath::Cos(LeadPosition.Phi()-SubLeadPosition.Phi());
double sech1 = SecH(LeadPosition.Eta());
double sech2 = SecH(SubLeadPosition.Eta());
double tanh1 = TanH(LeadPosition.Eta());
double tanh2 = TanH(SubLeadPosition.Eta());
double numerator1 = sech1*(sech1*tanh2-tanh1*sech2*cos_term);
double numerator2 = sech2*(sech2*tanh1-tanh2*sech1*cos_term);
double denominator = 1. - tanh1*tanh2 - sech1*sech2*cos_term;
double ResTerm = (-1.*dz/denominator)*(numerator1/r1 + numerator2/r2);
//double angleResolution = ResTerm*(1.-TMath::Cos(alpha))/TMath::Sin(alpha);
double angleResolution = ResTerm;
return angleResolution;
}
// utility functions
double MassResolution::SecH(double x){
return 1.0/TMath::CosH(x);
}
double MassResolution::TanH(double x){
return TMath::TanH(x);
}