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source: svn/trunk/Resolutions_ATLAS.cpp@ 452

Last change on this file since 452 was 447, checked in by Xavier Rouby, 15 years ago
update resolutions CMS/ATLAS
File size: 15.5 KB

Line
1	/***********************************************************************
2
3	/----------------------------------------------\
4	\| Delphes, a framework for the fast simulation \|
5	\| of a generic collider experiment \|
6	\------------- arXiv:0903.2225v1 ------------/
7
8
9	This package uses:
10	------------------
11	ROOT: Nucl. Inst. & Meth. in Phys. Res. A389 (1997) 81-86
12	FastJet algorithm: Phys. Lett. B641 (2006) [hep-ph/0512210]
13	Hector: JINST 2:P09005 (2007) [physics.acc-ph:0707.1198v2]
14	FROG: [hep-ex/0901.2718v1]
15	HepMC: Comput. Phys. Commun.134 (2001) 41
16
17	------------------------------------------------------------------
18
19	Main authors:
20	-------------
21
22	Severine Ovyn Xavier Rouby
23	severine.ovyn@uclouvain.be xavier.rouby@cern
24
25	Center for Particle Physics and Phenomenology (CP3)
26	Universite catholique de Louvain (UCL)
27	Louvain-la-Neuve, Belgium
28
29	Copyright (C) 2008-2009,
30	All rights reserved.
31
32	***********************************************************************/
33
34	/// \file Resolution.cpp
35	/// \brief Prepares the resolution calculation
36
37	#include "TChain.h"
38	#include "TApplication.h"
39	#include "TFile.h"
40
41	#include "ExRootTreeReader.h"
42	#include "ExRootTreeWriter.h"
43	#include "ExRootTreeBranch.h"
44	#include "TreeClasses.h"
45
46	#include "DataConverter.h"
47	#include "HEPEVTConverter.h"
48	#include "LHEFConverter.h"
49	#include "STDHEPConverter.h"
50
51	#include "SmearUtil.h"
52	#include "JetsUtil.h"
53	#include "BFieldProp.h"
54
55	//#include "PseudoJet.hh"
56	//#include "ClusterSequence.hh"
57
58	#include<vector>
59	#include<iostream>
60
61	using namespace std;
62
63	//------------------------------------------------------------------------------
64
65	// //******************************** PYTHIA INFORMATION*******************************
66
67	TSimpleArray<TRootGenParticle> TauHadr(const TClonesArray *GEN)
68	{
69	TIter it((TCollection*)GEN);
70	it.Reset();
71	TRootGenParticle *gen1;
72	TSimpleArray<TRootGenParticle> array,array2;
73
74	while((gen1 = (TRootGenParticle*) it.Next()))
75	{
76	array.Add(gen1);
77	}
78	it.Reset();
79	bool tauhad;
80	while((gen1 = (TRootGenParticle*) it.Next()))
81	{
82	tauhad=false;
83	if(abs(gen1->PID)==15)
84	{
85	int d1=gen1->D1;
86	int d2=gen1->D2;
87	if((d1 < array.GetEntries()) && (d1 > 0) && (d2 < array.GetEntries()) && (d2 > 0))
88	{
89	tauhad=true;
90	for(int d=d1; d < d2+1; d++)
91	{
92	if(abs(array[d]->PID)== pE \|\| abs(array[d]->PID)== pMU)tauhad=false;
93	}
94	}
95	}
96	if(tauhad)array2.Add(gen1);
97	}
98	return array2;
99	}
100
101	double EnergySmallCone(const vector<TLorentzVector> &towers, const float eta, const float phi,float energy_scone,float JET_seed) {
102	double Energie=0;
103	for(unsigned int i=0; i < towers.size(); i++) {
104	if(towers[i].Pt() < JET_seed) continue;
105	if((DeltaR(phi,eta,towers[i].Phi(),towers[i].Eta()) < energy_scone)) {
106	Energie += towers[i].E();
107	}
108	}
109	return Energie;
110	}
111
112
113	void PairingJet(TLorentzVector &JETSm, const TLorentzVector &JET, const TClonesArray *branchJet, const float dR=0.25)
114	{
115	JETSm.SetPxPyPzE(0,0,0,0);
116	float deltaRtest=5000;
117	TIter itJet((TCollection*)branchJet);
118	TRootJet *jet;
119	itJet.Reset();
120	while( (jet = (TRootJet*) itJet.Next()) )
121	{
122	TLorentzVector Att;
123	Att.SetPtEtaPhiE(jet->PT,jet->Eta,jet->Phi,jet->E);
124	if(DeltaR(JET.Phi(),JET.Eta(),Att.Phi(),Att.Eta()) < deltaRtest)
125	{
126	deltaRtest = DeltaR(JET.Phi(),JET.Eta(),Att.Phi(),Att.Eta());
127	if(deltaRtest < dR)
128	{
129	JETSm = Att;
130	}
131	}
132	}
133	}
134
135	void PairingElec(TLorentzVector &ELECSm, const TLorentzVector &ELEC, const TClonesArray *branchElec)
136	{
137	ELECSm.SetPxPyPzE(0,0,0,0);
138	float deltaRtest=5000;
139	TIter itElec((TCollection*)branchElec);
140	TRootElectron *elec;
141	itElec.Reset();
142	while( (elec = (TRootElectron*) itElec.Next()) )
143	{
144	TLorentzVector Att;
145	Att.SetPtEtaPhiE(elec->PT,elec->Eta,elec->Phi,elec->E);
146	if(DeltaR(ELEC.Phi(),ELEC.Eta(),Att.Phi(),Att.Eta()) < deltaRtest)
147	{
148	deltaRtest = DeltaR(ELEC.Phi(),ELEC.Eta(),Att.Phi(),Att.Eta());
149	if(deltaRtest < 0.025)
150	{
151	ELECSm = Att;
152	}
153	}
154	}
155	}
156
157	void PairingMuon(TLorentzVector &MUONSm, const TLorentzVector &MUON, const TClonesArray *branchMuon)
158	{
159	MUONSm.SetPxPyPzE(0,0,0,0);
160	float deltaRtest=5000;
161	TIter itMuon((TCollection*)branchMuon);
162	TRootMuon *muon;
163	itMuon.Reset();
164	while( (muon = (TRootMuon*) itMuon.Next()) )
165	{
166	TLorentzVector Att;
167	Att.SetPxPyPzE(muon->Px,muon->Py,muon->Pz,muon->E);
168	if(DeltaR(MUON.Phi(),MUON.Eta(),Att.Phi(),Att.Eta()) < deltaRtest)
169	{
170	deltaRtest = DeltaR(MUON.Phi(),MUON.Eta(),Att.Phi(),Att.Eta());
171	if(deltaRtest < 0.025)
172	{
173	MUONSm = Att;
174	}
175	}
176	}
177	}
178
179	unsigned int NumTracks(const TClonesArray *branchTracks, const float pt_track, const float eta, const float phi,float track_scone) {
180	unsigned int numtrack=0;
181	TIter itTrack((TCollection*)branchTracks);
182	TRootTracks *track;
183	itTrack.Reset();
184	while( (track = (TRootTracks*) itTrack.Next()) )
185	{
186	if((track->PT < pt_track )\|\|
187	(DeltaR(phi,eta,track->Phi,track->Eta) > track_scone)
188	)continue;
189	numtrack++;
190	}
191	return numtrack;
192	}
193
194
195
196	int main(int argc, char *argv[])
197	{
198	int appargc = 2;
199	char *appName = "Resolution";
200	char *appargv[] = {appName, "-b"};
201	TApplication app(appName, &appargc, appargv);
202
203	if(argc != 3) {
204	cout << " Usage: " << argv[0] << " input_file" << " output_file" << endl;
205	cout << " input_file - input file in Delphes-root format," << endl;
206	cout << " output_file - output file." << endl;
207	exit(1);
208	}
209
210	srand (time (NULL)); /* Initialisation du gÃ©nÃ©rateur */
211
212	//read the input TROOT file
213	string inputfilename(argv[1]), outputfilename(argv[2]);
214
215	if(outputfilename.find(".root") > outputfilename.length() ) {
216	cout << "output_file should be a .root file!\n";
217	return -1;
218	}
219
220
221
222	TFile *outputFile = TFile::Open(outputfilename.c_str(), "RECREATE");// Creates the file, but should be closed just after
223	outputFile->Close();
224
225	TChain chainGEN("GEN");
226	chainGEN.Add(inputfilename.c_str());
227	ExRootTreeReader *treeReaderGEN = new ExRootTreeReader(&chainGEN);
228	TChain chain("Analysis");
229	chain.Add(inputfilename.c_str());
230	ExRootTreeReader *treeReader = new ExRootTreeReader(&chain);
231	const TClonesArray *branchJet = treeReader->UseBranch("Jet");
232	const TClonesArray *branchElec = treeReader->UseBranch("Electron");
233	const TClonesArray *branchMuon = treeReader->UseBranch("Muon");
234	const TClonesArray *branchTracks = treeReader->UseBranch("Tracks");
235	const TClonesArray *branchTowers = treeReader->UseBranch("CaloTower");
236	const TClonesArray *branchGen = treeReaderGEN->UseBranch("Particle");
237	TIter itGen((TCollection*)branchGen);
238
239	//write the output root file
240	ExRootTreeWriter *treeWriter = new ExRootTreeWriter(outputfilename, "Analysis");
241	ExRootTreeBranch *branchjet = treeWriter->NewBranch("JetPTResol", RESOLJET::Class());
242	ExRootTreeBranch *branchelec = treeWriter->NewBranch("ElecEResol", RESOLELEC::Class());
243	ExRootTreeBranch *branchmuon = treeWriter->NewBranch("MuonPTResol", RESOLMUON::Class());
244	ExRootTreeBranch *branchtaujet = treeWriter->NewBranch("TauJetPTResol", TAUHAD::Class());
245	ExRootTreeBranch *branchetmis = treeWriter->NewBranch("ETmisResol",ETMIS::Class());
246
247	TRootGenParticle *particle;
248
249	RESOLELEC * elementElec;
250	RESOLMUON *elementMuon;
251	RESOLJET *elementJet;
252	TAUHAD *elementTaujet;
253	ETMIS *elementEtmis;
254
255	int numTau=0;
256	int numTauRec=0;
257
258	RESOLution *DET = new RESOLution();
259	/*
260	string detectorcard = "data/DetectorCard_CMS.dat";
261	const float dR_jetpairing = 0.25;
262	const float jet_pt_cut = 1;
263	*/
264	string detectorcard = "data/DetectorCard_ATLAS.dat";
265	const float dR_jetpairing = 0.2;
266	const float jet_pt_cut = 7;
267	DET->ReadDataCard(detectorcard);
268
269
270	//Jet information
271	JetsUtil *JETRUN = new JetsUtil(detectorcard);
272
273	TLorentzVector genMomentum(0,0,0,0);//TLorentzVector containing generator level information
274	TLorentzVector recoMomentum(0,0,0,0);//TLorentzVector containing generator level information
275	LorentzVector jetMomentum;
276
277	vector<fastjet::PseudoJet> input_particlesGEN;//for FastJet algorithm
278	vector<fastjet::PseudoJet> sorted_jetsGEN;
279	vector<int> NTrackJet;
280	vector<TLorentzVector> towers;
281
282	// Loop over all events
283	Long64_t entry, allEntries = treeReader->GetEntries();
284	cout << "** Chain contains " << allEntries << " events" << endl;
285	for(entry = 0; entry < allEntries; ++entry)
286	{
287	TLorentzVector PTmisReco(0,0,0,0);
288	TLorentzVector PTmisGEN(0,0,0,0);
289	treeReader->ReadEntry(entry);
290	treeReaderGEN->ReadEntry(entry);
291	treeWriter->Clear();
292	if((entry % 100) == 0 && entry > 0 ) cout << "** Processing element # " << entry << endl;
293
294	TSimpleArray<TRootGenParticle> bGen;
295	itGen.Reset();
296	TSimpleArray<TRootGenParticle> NFCentralQ;
297
298	input_particlesGEN.clear();
299	towers.clear();
300
301	// Loop over all particles in event
302	while( (particle = (TRootGenParticle*) itGen.Next()) )
303	{
304	genMomentum.SetPxPyPzE(particle->Px, particle->Py, particle->Pz, particle->E);
305
306	int pid = abs(particle->PID);
307	float eta = fabs(particle->Eta);
308
309	//input generator level particle for jet algorithm
310	if(particle->Status == 1 && eta < DET->CEN_max_calo_fwd)
311	{
312	input_particlesGEN.push_back(fastjet::PseudoJet(genMomentum.Px(),genMomentum.Py(),genMomentum.Pz(), genMomentum.E()));
313	}
314
315	//Calculate ETMIS from generated particles
316	if((pid == pNU1) \|\| (pid == pNU2) \|\| (pid == pNU3))PTmisGEN = PTmisGEN + genMomentum;
317
318	//Electrons and muons
319	if( (particle->Status == 1) &&
320	((pid != pNU1) && (pid != pNU2) && (pid != pNU3)) &&
321	(fabs(particle->Eta) < DET->CEN_max_calo_fwd)
322	)
323	{
324	eta=fabs(genMomentum.Eta());
325
326	switch(pid) {
327
328	case pE: // all electrons with eta < DET->MAX_CALO_FWD
329	PairingElec(recoMomentum,genMomentum,branchElec);
330	if(recoMomentum.E()!=0){
331	elementElec=(RESOLELEC*) branchelec->NewEntry();
332	elementElec->E = genMomentum.E();
333	elementElec->SmearedE = recoMomentum.E();}
334	break; // case pE
335	case pMU: // all muons with eta < DET->MAX_MU
336	PairingMuon(recoMomentum,genMomentum,branchMuon);
337	if(recoMomentum.E()!=0){
338	elementMuon = (RESOLMUON*) branchmuon->NewEntry();
339	elementMuon->OverPT = 1./genMomentum.Pt();
340	elementMuon->OverSmearedPT = 1./recoMomentum.Pt();}
341	break; // case pMU
342	default:
343	break;
344	} // switch (pid)
345	}
346
347	} // while
348
349	//compute missing transverse energy from calo towers
350	TIter itCalo((TCollection*)branchTowers);
351	TRootCalo *calo;
352	itCalo.Reset();
353	TLorentzVector Att(0.,0.,0.,0.);
354	float ScalarEt=0;
355	while( (calo = (TRootCalo*) itCalo.Next()) )
356	{
357	if(calo->E !=0){
358	Att.SetPtEtaPhiE(calo->getET(),calo->Eta,calo->Phi,calo->E);
359	towers.push_back(Att);
360	if(fabs(Att.Eta()) < DET->CEN_max_calo_fwd)
361	{
362	ScalarEt = ScalarEt + calo->getET();
363	PTmisReco = PTmisReco + Att;
364	}
365	}
366	}
367	elementEtmis= (ETMIS*) branchetmis->NewEntry();
368	elementEtmis->Et = (PTmisGEN).Pt();
369	elementEtmis->Ex = (-PTmisGEN).Px();
370	elementEtmis->SEt = ScalarEt;
371	elementEtmis->EtSmeare = (PTmisReco).Pt()-(PTmisGEN).Pt();
372	elementEtmis->ExSmeare = (-PTmisReco).Px()-(PTmisGEN).Px();
373
374	//*****************************
375	sorted_jetsGEN=JETRUN->RunJetsResol(input_particlesGEN);
376
377	TSimpleArray<TRootGenParticle> TausHadr = TauHadr(branchGen);
378	TLorentzVector JETreco(0,0,0,0);
379	for (unsigned int i = 0; i < sorted_jetsGEN.size(); i++) {
380	TLorentzVector JETgen(0,0,0,0);
381	JETgen.SetPxPyPzE(sorted_jetsGEN[i].px(),sorted_jetsGEN[i].py(),sorted_jetsGEN[i].pz(),sorted_jetsGEN[i].E());
382	PairingJet(JETreco,JETgen,branchJet);
383	if(JETreco.Pt()>jet_pt_cut)
384	{
385	elementJet= (RESOLJET*) branchjet->NewEntry();
386	elementJet->PT = JETgen.Et();
387	elementJet->SmearedPT = JETreco.Et()/JETgen.Et();
388	elementJet->E = JETgen.E();
389	elementJet->dE = (JETreco.E()-JETgen.E())/JETgen.E() ;
390	elementJet->dE2 = pow( (JETreco.E()-JETgen.E())/JETgen.E() , 2.) ;
391	}
392	}
393	numTau = numTau+TausHadr.GetEntries();
394
395	TIter itJet((TCollection*)branchJet);
396	TRootJet *jet;
397	itJet.Reset();
398	while( (jet = (TRootJet*) itJet.Next()) )
399	{
400	TLorentzVector JETT(0,0,0,0);
401	JETT.SetPxPyPzE(jet->Px,jet->Py,jet->Pz,jet->E);
402	if(fabs(JETT.Eta()) < (DET->CEN_max_tracker - DET->TAU_track_scone))
403	{
404	for(Int_t i=0; i<TausHadr.GetEntries();i++)
405	{
406	if(DeltaR(TausHadr[i]->Phi,TausHadr[i]->Eta,JETT.Phi(),JETT.Eta())<0.1)
407	{
408	elementTaujet= (TAUHAD*) branchtaujet->NewEntry();
409	elementTaujet->EnergieCen = EnergySmallCone(towers,JETT.Eta(),JETT.Phi(),DET->TAU_energy_scone,DET->JET_seed)/JETT.E();
410	elementTaujet->NumTrack = NumTracks(branchTracks,DET->TAU_track_pt,JETT.Eta(),JETT.Phi(),DET->TAU_track_scone);
411	if( (EnergySmallCone(towers,JETT.Eta(),JETT.Phi(),DET->TAU_energy_scone,DET->JET_seed)/JETT.E()) > 0.95
412	&& (NumTracks(branchTracks,DET->TAU_track_pt,JETT.Eta(),JETT.Phi(),DET->TAU_track_scone))==1)numTauRec++;
413	}
414	}
415	}
416
417
418	} // for itJet : loop on all jets
419
420	treeWriter->Fill();
421	} // Loop over all events
422	treeWriter->Write();
423
424	cout << detectorcard << " has been used.\n";
425	cout << "** Exiting..." << endl;
426
427	delete treeWriter;
428	delete treeReader;
429	delete DET;
430	}
431

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