33 using namespace isodeposit;
40 virtual void endJob()
override;
52 TH1F *
IsoZ,* IsoW,* IsoOther ;
53 TH1F *
TkrPt,* EcalEt,* HcalEt ;
56 TH1F *
Z_eta,* W_eta,* Other_eta;
58 TH1F *
Z_pt,* W_pt,* Other_pt;
61 enum MuTag { muFromZ, muFromW, muFromOther };
63 MuTag muTag(
const T &
mu)
const;
65 void histo(TH1F*
hist,
const char* cx,
const char* cy)
const;
75 int sizem = p->numberOfMothers();
85 int pdgId1 = moth1->
pdgId();
95 int pdgId2 = moth2->
pdgId();
100 if(
abs(pdgId2)==24)
return muFromW;
108 for(IsoDeposit::const_iterator it= isodep->
begin(); it!= isodep->
end(); ++it){
109 if(it->dR()<dR_max) {
110 double theta= 2*(TMath::ATan(TMath::Exp(-(it->eta() ) ) ) );
112 hist->Fill(it->value()/TMath::Sin(theta));
118 hist->GetXaxis()->SetTitle(cx);
119 hist->GetYaxis()->SetTitle(cy);
120 hist->GetXaxis()->SetTitleOffset(1);
121 hist->GetYaxis()->SetTitleOffset(1.2);
122 hist->GetXaxis()->SetTitleSize(0.04);
123 hist->GetYaxis()->SetTitleSize(0.04);
124 hist->GetXaxis()->SetLabelSize(0.03);
125 hist->GetYaxis()->SetLabelSize(0.03);
130 dRVeto(pset.getUntrackedParameter<double>(
"veto")),
131 dRTrk(pset.getUntrackedParameter<double>(
"deltaRTrk")),
132 dREcal(pset.getUntrackedParameter<double>(
"deltaREcal")),
133 dRHcal(pset.getUntrackedParameter<double>(
"deltaRHcal")),
134 ptThreshold(pset.getUntrackedParameter<double>(
"ptThreshold")),
135 etEcalThreshold(pset.getUntrackedParameter<double>(
"etEcalThreshold")),
136 etHcalThreshold(pset.getUntrackedParameter<double>(
"etHcalThreshold")),
137 alpha(pset.getUntrackedParameter<double>(
"alpha")),
138 beta(pset.getUntrackedParameter<double>(
"beta")),
139 pt(pset.getUntrackedParameter<double>(
"pt")),
140 eta(pset.getUntrackedParameter<double>(
"eta")),
141 iso_cut(pset.getUntrackedParameter<double>(
"isoCut")) {
143 std::ostringstream str1,str2,str3,str4,str5,str6,str7,str8,str9,str10,n_tracks;
144 str1 <<
"muons from Z with p_{t} > " <<
ptThreshold <<
" GeV/c"<<
" and #Delta R < "<<
dRTrk;
145 str2 <<
"muons from W with p_{t} > " <<
ptThreshold <<
" GeV/c"<<
" and #Delta R < "<<
dRTrk;
146 str3 <<
"muons from Others with p_{t} > " <<
ptThreshold <<
" GeV/c"<<
" and #Delta R < "<<
dRTrk;
147 str4 <<
"muons from Z with p_{t} > " <<
ptThreshold <<
" GeV/c"<<
" and #Delta R < "<<dRTrk<<
" (alpha = "<<
alpha<<
" , "<<
"beta = "<<
beta<<
" )";
148 str5 <<
"muons from W with p_{t} > " <<
ptThreshold <<
" GeV/c"<<
" and #Delta R < "<<dRTrk<<
" (alpha = "<<
alpha<<
" , "<<
"beta = "<<beta<<
" )";
149 str6 <<
"muons from Other with p_{t} > " <<
ptThreshold <<
" GeV/c"<<
" and #Delta R < "<<dRTrk<<
" (alpha = "<<
alpha<<
" , "<<
"beta = "<<beta<<
" )";
150 n_tracks <<
"Number of tracks for muon with p_{t} > " <<
ptThreshold <<
" and #Delta R < "<<dRTrk<<
" GeV/c";
151 str7<<
"Isolation Vs p_{t} with p_{t} > " <<
ptThreshold <<
" GeV/c"<<
" and #Delta R < "<<dRTrk<<
"(Tracker)";
152 str8<<
"Isolation Vs p_{t} with p_{t} > " <<
ptThreshold <<
" GeV/c"<<
" and #Delta R < "<<dRTrk<<
"(Ecal)";
153 str9<<
"Isolation Vs p_{t} with p_{t} > " <<
ptThreshold <<
" GeV/c"<<
" and #Delta R < "<<dRTrk<<
"(Hcal)";
154 str10<<
"Isolation Vs p_{t} with p_{t} > " <<
ptThreshold <<
" GeV/c"<<
" and #Delta R < "<<dRTrk<<
" (alpha = "<<
alpha<<
" , "<<
"beta = "<<beta<<
" )";
155 h_IsoZ_tk = fs->
make<TH1F>(
"ZIso_Tk",str1.str().c_str(),100,0.,20.);
156 h_IsoW_tk = fs->
make<TH1F>(
"WIso_Tk",str2.str().c_str(),100,0.,20.);
158 h_IsoZ_ecal = fs->
make<TH1F>(
"ZIso_ecal",str1.str().c_str(),100,0.,20.);
159 h_IsoW_ecal = fs->
make<TH1F>(
"WIso_ecal",str2.str().c_str(),100,0.,20.);
161 h_IsoZ_hcal = fs->
make<TH1F>(
"ZIso_hcal",str1.str().c_str(),100,0.,20.);
162 h_IsoW_hcal = fs->
make<TH1F>(
"WIso_hcal",str2.str().c_str(),100,0.,20.);
164 IsoZ = fs->
make<TH1F>(
"ZIso",str4.str().c_str(),100,0.,20.);
165 IsoW = fs->
make<TH1F>(
"WIso",str5.str().c_str(),100,0.,20.);
166 IsoOther = fs->
make<TH1F>(
"otherIso",str6.str().c_str(),100,0.,20.);
169 Z_eta = fs->
make<TH1F>(
"Z_eta",
"#eta distribution for muons coming from Z",40,-
eta,
eta);
170 W_eta = fs->
make<TH1F>(
"W_eta",
"#eta distribution for muons coming from W",40,-
eta,
eta);
171 Other_eta = fs->
make<TH1F>(
"Other_eta",
"#eta distribution for muons coming from other",40,-
eta,
eta);
176 Z_pt = fs->
make<TH1F>(
"Z_pt",
"p_{T} distribution for muons coming from Z",40,
pt,150.);
177 W_pt = fs->
make<TH1F>(
"W_pt",
"p_{T} distribution for muons coming from W",40,
pt,150.);
178 Other_pt = fs->
make<TH1F>(
"Other_pt",
"p_{T} distribution for muons coming from other",40,
pt,150.);
179 Z_pt_postSelection = fs->
make<TH1F>(
"Z_pt_postSelection",
"p_{T} distribution for muons coming from Z after iso selection",40,
pt,150.);
180 W_pt_postSelection = fs->
make<TH1F>(
"W_pt_postSelection",
"p_{t} distribution for muons coming from W after iso selection",40,
pt,150.);
181 Other_pt_postSelection = fs->
make<TH1F>(
"Other_pt_postSelection",
"p_{t} distribution for muons coming from other after iso selection",40,
pt,150.);
184 TkrPt = fs->
make<TH1F>(
"TkrPt",
"IsoDeposit p distribution in the Tracker",100,0.,10.);
185 EcalEt = fs->
make<TH1F>(
"EcalEt",
"IsoDeposit E distribution in the Ecal",100,0.,5.);
186 HcalEt = fs->
make<TH1F>(
"HcalEt",
"IsoDeposit E distribution in the Hcal",100,0.,5.);
188 EcalEtZ = fs->
make<TH1F>(
"VetoEcalEt",
" #Sigma E_{T} deposited in veto cone in the Ecal",100,0.,10.);
189 HcalEtZ = fs->
make<TH1F>(
"VetoHcalEt",
" #Sigma E_{T} deposited in veto cone in the Hcal",100,0.,10.);
196 for(
unsigned int i=0;
i < dimuons->size(); ++
i ) {
225 vetos_mu_ecal.push_back(
new ConeVeto( muDir, 0. ));
229 vetos_tk_ecal.push_back(
new ConeVeto( tkDir, 0. ));
233 vetos_mu_hcal.push_back(
new ConeVeto( muDir, 0. ));
237 vetos_tk_hcal.push_back(
new ConeVeto( tkDir, 0. ));
253 double iso_value=
TMath::Max(iso_value0,iso_value1);
259 IsoZ->Fill(iso_value);
286 IsoW->Fill(iso_value);
double candEnergy() const
Get energy or pT attached to cand trajectory.
virtual const Candidate * daughter(size_type i) const =0
return daughter at a given position, i = 0, ... numberOfDaughters() - 1 (read only mode) ...
virtual const Candidate * mother(size_type i=0) const =0
return pointer to mother
TH1F * Z_eta_postSelection
#define DEFINE_FWK_MODULE(type)
EDGetTokenT< CandidateView > srcToken
Geom::Theta< T > theta() const
virtual double phi() const final
momentum azimuthal angle
T * make(const Args &...args) const
make new ROOT object
const IsoDeposit * isoDeposit(IsolationKeys key) const
Returns the IsoDeposit associated with some key, or a null pointer if it is not available.
virtual void endJob() override
const IsoDeposit * isoDeposit(IsolationKeys key) const
Returns the IsoDeposit associated with some key, or a null pointer if it is not available.
double sumWithin(double coneSize, const AbsVetos &vetos=AbsVetos(), bool skipDepositVeto=false) const
TH1F * W_pt_postSelection
TH1F * Z_pt_postSelection
Analysis-level Generic Particle class (e.g. for hadron or muon not fully reconstructed) ...
Abs< T >::type abs(const T &t)
TH1F * Other_pt_postSelection
ZMuMuIsolationAnalyzer(const edm::ParameterSet &pset)
void Deposits(const pat::IsoDeposit *isodep, double dR_max, TH1F *hist)
How EventSelector::AcceptEvent() decides whether to accept an event for output otherwise it is excluding the probing of A single or multiple positive and the trigger will pass if any such matching triggers are PASS or EXCEPTION[A criterion thatmatches no triggers at all is detected and causes a throw.] A single negative with an expectation of appropriate bit checking in the decision and the trigger will pass if any such matching triggers are FAIL or EXCEPTION A wildcarded negative criterion that matches more than one trigger in the trigger but the state exists so we define the behavior If all triggers are the negative crieriion will lead to accepting the event(this again matches the behavior of"!*"before the partial wildcard feature was incorporated).The per-event"cost"of each negative criterion with multiple relevant triggers is about the same as!*was in the past
bool isNull() const
Checks for null.
const_iterator begin() const
virtual int pdgId() const =0
PDG identifier.
TH1F * Other_eta_postSelection
TH1F * W_eta_postSelection
std::vector< AbsVeto * > AbsVetos
virtual double eta() const final
momentum pseudorapidity
MuTag muTag(const T &mu) const
isodeposit::AbsVetos AbsVetos
const_iterator end() const
void histo(TH1F *hist, const char *cx, const char *cy) const
Analysis-level muon class.
virtual double pt() const final
transverse momentum
virtual void analyze(const edm::Event &event, const edm::EventSetup &setup) override
virtual const CandidateBaseRef & masterClone() const =0