1 /**************************************************************************
2 * Copyright(c) 1998-1999, ALICE Experiment at CERN, All rights reserved. *
4 * Author: The ALICE Off-line Project. *
5 * Contributors are mentioned in the code where appropriate. *
7 * Permission to usec, copy, modify and distribute this software and its *
8 * documentation strictly for non-commercial purposes is hereby granted *
9 * without fee, provided that the above copyright notice appears in all *
10 * copies and that both the copyright notice and this permission notice *
11 * appear in the supporting documentation. The authors make no claims *
12 * about the suitability of this software for any purpose. It is *
13 * provided "as is" without express or implied warranty. *
14 **************************************************************************/
16 //---------------------------------------------------------------------
17 // Jet Finder based on CDF algortihm
18 // Charged jet evolution and the underlying event in proton-antiproton collisions at 1.8 TeV
19 // Physical Review D, vol. 65, Issue 9, id. 092002
20 // http://www.phys.ufl.edu/~rfield/cdf/chgjet/chgjet_intro.html
21 // Authors : Adrian.Sevcenco@cern.ch (adriansev@spacescience.ro )
22 // Daniel.Felea@cern.ch (dfelea@spacescience.ro)
23 // Ciprian.Mihai.Mitu@cern.ch (mcm@spacescience.ro)
24 //---------------------------------------------------------------------
33 #include <Riostream.h>
39 #include <TClonesArray.h>
40 #include <TLorentzVector.h>
47 #include "AliJetReader.h"
48 #include "AliJetReaderHeader.h"
49 #include "AliAODJet.h"
50 #include "AliAODEvent.h"
51 #include "AliJetFinder.h"
53 #include "AliCdfJetFinder.h"
54 #include "AliCdfJetHeader.h"
56 ClassImp(AliCdfJetFinder)
58 //______________________________________________________________________________
59 AliCdfJetFinder::AliCdfJetFinder():
78 //______________________________________________________________________________
79 AliCdfJetFinder::~AliCdfJetFinder()
85 //______________________________________________________________________________
86 void AliCdfJetFinder::CreateOutputObjects(TList * const histos)
88 // Create the list of histograms. Only the list is owned.
91 // gStyle->SetOptStat(11111111);
93 TH1F *h1 = new TH1F ("histo1", "Pt distribution of jets", 200, 0,200); // 1GeV/bin
95 h1->GetXaxis()->SetTitle("P_{T} of jets");
96 h1->GetYaxis()->SetTitle("Number of jets");
97 h1->GetXaxis()->SetTitleColor(1);
98 h1->SetMarkerStyle(kFullCircle);
101 TH1F *h2 = new TH1F ("histo2", "Eta distribution of jets", 240, -1.2,1.2); // 1 unit of rapidity / 100 bin
103 h2->GetXaxis()->SetTitle("Eta of jets");
104 h2->GetYaxis()->SetTitle("Number of jets");
105 h2->GetXaxis()->SetTitleColor(1);
106 h2->SetMarkerStyle(kFullCircle);
109 TH1F *h3 = new TH1F ("histo3", "Phi distribution of jets", 400, -4,4);
111 h3->GetXaxis()->SetTitle("Phi of jets");
112 h3->GetYaxis()->SetTitle("Number of jets");
113 h3->GetXaxis()->SetTitleColor(1);
114 h3->SetMarkerStyle(kFullCircle);
117 TH1F *h4 = new TH1F ("histo4", "Multiplicity of jets", 40, 0,40); // 1 unit of multiplicity /bin
119 h4->GetXaxis()->SetTitle("Particles in jets");
120 h4->GetYaxis()->SetTitle("Number of jets");
121 h4->GetXaxis()->SetTitleColor(1);
122 h4->SetMarkerStyle(kFullCircle);
125 TH1F *h5 = new TH1F ("histo5", "Distribution of jets in events", 100, 0,100);
127 h5->GetXaxis()->SetTitle("Number of jets");
128 h5->GetYaxis()->SetTitle("Number of events");
129 h5->GetXaxis()->SetTitleColor(1);
130 h5->SetMarkerStyle(kFullCircle);
133 TH1F *h6 = new TH1F ("histo6", "Jet1 Charged Multiplicity Distribution", 30, 0,30);
135 h6->GetXaxis()->SetTitle("N_{chg}");
136 h6->GetYaxis()->SetTitle("Number of jets");
137 h6->GetXaxis()->SetTitleColor(1);
138 h6->SetMarkerStyle(kFullCircle);
141 TProfile * h7 = new TProfile ("histo7","N_{chg}(jet1) vs P_{T}(charged jet1)", 200, 0. ,200. , 0.,200. ) ;
143 h7->GetXaxis()->SetTitle("P_{T} (charged jet1) (GeV/c)");
144 h7->GetYaxis()->SetTitle("<N_{chg}(jet1)> in 1 GeV/c bin");
145 h7->GetXaxis()->SetTitleColor(1);
146 h7->SetMarkerStyle(kFullCircle);
149 TH1F *h8 = new TH1F ("histo8", "Charge momentum distribution for leading jet", 120, 0 , 1.2);
151 h8->GetXaxis()->SetTitle("Jets");
152 h8->GetYaxis()->SetTitle("Particle distribution");
153 h8->GetXaxis()->SetTitleColor(1);
154 h8->SetMarkerStyle(kFullCircle);
157 TProfile *h9 = new TProfile ("histo9", "N_{chg} vs the Azimuthal Angle from Charged Jet1", 50 , 0. , 180. , 0 , 20 );
159 h9->GetXaxis()->SetTitle("#Delta#phi (degrees)");
160 h9->GetYaxis()->SetTitle("<N_{chg}> in 3.6 degree bin");
161 h9->GetXaxis()->SetTitleColor(1);
162 h9->SetMarkerStyle(kFullCircle);
165 TProfile *h10 = new TProfile ("histo10", "P_{T} sum vs the Azimuthal Angle from Charged Jet1", 50 , 0. , 180. , 0 , 100 );
166 h10->SetStats(kTRUE);
167 h10->GetXaxis()->SetTitle("#Delta#phi (degrees)");
168 h10->GetYaxis()->SetTitle("<P_{T} sum> in 3.6 degree bin");
169 h10->GetXaxis()->SetTitleColor(1);
170 h10->SetMarkerStyle(kFullCircle);
173 TH1F *h11 = new TH1F ("histo11", " \"Transverse\" Pt Distribution ", 70, 0 , 14);
174 h11->SetStats(kTRUE);
175 h11->GetXaxis()->SetTitle("P_{T} (GeV/c)");
176 h11->GetYaxis()->SetTitle("dN_{chg}/dP_{T} (1/GeV/c)");
177 h11->GetXaxis()->SetTitleColor(1);
178 h11->SetMarkerStyle(kFullCircle);
181 TH1F *h20 = new TH1F ("histo20", "Distribution of R in leading jet", 400, 0.,4.);
182 h20->SetStats(kTRUE);
183 h20->GetXaxis()->SetTitle("R [formula]");
184 h20->GetYaxis()->SetTitle("dN/dR");
185 h20->GetXaxis()->SetTitleColor(1);
186 h20->SetMarkerStyle(kFullCircle);
189 TProfile * h21 = new TProfile ("histo21","N_{chg}(in the event - including jet1) vs P_{T}(charged jet1)", 200, 0., 50. , 0., 30. ) ;
190 h21->SetStats(kTRUE);
191 h21->GetXaxis()->SetTitle("P_{T} (charged jet1) (GeV/c)");
192 h21->GetYaxis()->SetTitle("<N_{chg}(in the event - including jet1)> in 1 GeV/c bin");
193 h21->GetXaxis()->SetTitleColor(1);
194 h21->SetMarkerStyle(kFullCircle);
197 TProfile * h22 = new TProfile ("histo22","PT_{sum}(in the event - including jet1) vs P_{T}(charged jet1)", 200, 0. , 50. , 0., 50. ) ;
198 h22->SetStats(kTRUE);
199 h22->GetXaxis()->SetTitle("P_{T} (charged jet1) (GeV/c)");
200 h22->GetYaxis()->SetTitle("<PT_{sum}(in the event - including jet1)> in 1 GeV/c bin");
201 h22->GetXaxis()->SetTitleColor(1);
202 h22->SetMarkerStyle(kFullCircle);
205 TProfile * h21Toward = new TProfile ("histo21_toward","N_{chg}(in the event - including jet1) vs P_{T}(charged jet1)", 200, 0., 50. , 0., 12. ) ;
206 h21Toward->SetStats(kTRUE);
207 h21Toward->GetXaxis()->SetTitle("P_{T} (charged jet1) (GeV/c)");
208 h21Toward->GetYaxis()->SetTitle("<N_{chg}(in the event - including jet1)> in 1 GeV/c bin");
209 h21Toward->GetXaxis()->SetTitleColor(1);
210 h21Toward->SetMarkerStyle(kFullCircle);
211 fHistos->Add(h21Toward);
213 TProfile * h21Transverse = new TProfile ("histo21_transverse","N_{chg}(in the event - including jet1) vs P_{T}(charged jet1)", 200, 0., 50. , 0., 12. ) ;
214 h21Transverse->SetStats(kTRUE);
215 h21Transverse->GetXaxis()->SetTitle("P_{T} (charged jet1) (GeV/c)");
216 h21Transverse->GetYaxis()->SetTitle("<N_{chg}(in the event - including jet1)> in 1 GeV/c bin");
217 h21Transverse->GetXaxis()->SetTitleColor(1);
218 h21Transverse->SetMarkerStyle(kFullCircle);
219 fHistos->Add(h21Transverse);
221 TProfile * h21Away = new TProfile ("histo21_away","N_{chg}(in the event - including jet1) vs P_{T}(charged jet1)", 200, 0., 50. , 0., 12. ) ;
222 h21Away->SetStats(kTRUE);
223 h21Away->GetXaxis()->SetTitle("P_{T} (charged jet1) (GeV/c)");
224 h21Away->GetYaxis()->SetTitle("<N_{chg}(in the event - including jet1)> in 1 GeV/c bin");
225 h21Away->GetXaxis()->SetTitleColor(1);
226 h21Away->SetMarkerStyle(kFullCircle);
227 fHistos->Add(h21Away);
229 TProfile * h22Toward = new TProfile ("histo22_toward","PT_{sum}(in the event - including jet1) vs P_{T}(charged jet1)", 200, 0. , 50. , 0., 50. ) ;
230 h22Toward->SetStats(kTRUE);
231 h22Toward->GetXaxis()->SetTitle("P_{T} (charged jet1) (GeV/c)");
232 h22Toward->GetYaxis()->SetTitle("<PT_{sum}(in the event - including jet1)> in 1 GeV/c bin");
233 h22Toward->GetXaxis()->SetTitleColor(1);
234 h22Toward->SetMarkerStyle(kFullCircle);
235 fHistos->Add(h22Toward);
237 TProfile * h22Transverse = new TProfile ("histo22_transverse","PT_{sum}(in the event - including jet1) vs P_{T}(charged jet1)", 200, 0. , 50. , 0., 50. ) ;
238 h22Transverse->SetStats(kTRUE);
239 h22Transverse->GetXaxis()->SetTitle("P_{T} (charged jet1) (GeV/c)");
240 h22Transverse->GetYaxis()->SetTitle("<PT_{sum}(in the event - including jet1)> in 1 GeV/c bin");
241 h22Transverse->GetXaxis()->SetTitleColor(1);
242 h22Transverse->SetMarkerStyle(kFullCircle);
243 fHistos->Add(h22Transverse);
245 TProfile * h22Away = new TProfile ("histo22_away","PT_{sum}(in the event - including jet1) vs P_{T}(charged jet1)", 200, 0. , 50. , 0., 50. ) ;
246 h22Away->SetStats(kTRUE);
247 h22Away->GetXaxis()->SetTitle("P_{T} (charged jet1) (GeV/c)");
248 h22Away->GetYaxis()->SetTitle("<PT_{sum}(in the event - including jet1)> in 1 GeV/c bin");
249 h22Away->GetXaxis()->SetTitleColor(1);
250 h22Away->SetMarkerStyle(kFullCircle);
251 fHistos->Add(h22Away);
253 TH1F *h23Toward = new TH1F ("histo23_toward","'Toward' Pt Distribution of charged particles", 200, 0., 14.);
254 h23Toward->SetStats(kTRUE);
255 h23Toward->GetXaxis()->SetTitle("P_{T} (charged) (GeV/c)");
256 h23Toward->GetYaxis()->SetTitle("dN_{chg}/dP_{T} (1/GeV/c)");
257 h23Toward->GetXaxis()->SetTitleColor(1);
258 h23Toward->SetMarkerStyle(kFullCircle);
259 fHistos->Add(h23Toward);
261 TH1F *h23Transverse = new TH1F ("histo23_transverse","'Transverse' Pt Distribution of charged particles", 200, 0., 14.);
262 h23Transverse->SetStats(kTRUE);
263 h23Transverse->GetXaxis()->SetTitle("P_{T} (charged) (GeV/c)");
264 h23Transverse->GetYaxis()->SetTitle("dN_{chg}/dP_{T} (1/GeV/c)");
265 h23Transverse->GetXaxis()->SetTitleColor(1);
266 h23Transverse->SetMarkerStyle(kFullCircle);
267 fHistos->Add(h23Transverse);
269 TH1F *h23Away = new TH1F ("histo23_away","'Away' Pt Distribution of charged particles", 200, 0., 14.);
270 h23Away->SetStats(kTRUE);
271 h23Away->GetXaxis()->SetTitle("P_{T} (charged) (GeV/c)");
272 h23Away->GetYaxis()->SetTitle("dN_{chg}/dP_{T} (1/GeV/c)");
273 h23Away->GetXaxis()->SetTitleColor(1);
274 h23Away->SetMarkerStyle(kFullCircle);
275 fHistos->Add(h23Away);
277 TProfile * h24 = new TProfile ("histo24","Jet1 Size vs P_{T}(charged jet1)", 200, 0., 50. , 0., 0.5) ;
278 h24->SetStats(kTRUE);
279 h24->GetXaxis()->SetTitle("P_{T} (charged jet1) (GeV/c)");
280 h24->GetYaxis()->SetTitle("<R(chgjet1)> in 1 GeV/c bin");
281 h24->GetXaxis()->SetTitleColor(1);
282 h24->SetMarkerStyle(kFullCircle);
285 TProfile * h25 = new TProfile ("histo25","Jet1 Size vs P_{T}(charged jet1)", 200, 0., 50. , 0., 0.5) ;
286 h25->SetStats(kTRUE);
287 h25->GetXaxis()->SetTitle("P_{T} (charged jet1) (GeV/c)");
288 h25->GetYaxis()->SetTitle("<R(chgjet1)> in 1 GeV/c bin");
289 h25->GetXaxis()->SetTitleColor(1);
290 h25->SetMarkerStyle(kFullCircle);
293 TProfile *h26 = new TProfile ("histo26", "N_{chg} vs the Distance R from Charged Jet1", 30, 0., 0.6, 0., 0.8);
294 h26->SetStats(kTRUE);
295 h26->GetXaxis()->SetTitle("Distance R");
296 h26->GetYaxis()->SetTitle("<N_{chg}> in 0.02 bin");
297 h26->GetXaxis()->SetTitleColor(1);
298 h26->SetMarkerStyle(kFullCircle);
301 TProfile *h27 = new TProfile ("histo27", "N_{chg} vs the Distance R from Charged Jet1", 30, 0., 0.6, 0., 0.8);
302 h27->SetStats(kTRUE);
303 h27->GetXaxis()->SetTitle("Distance R");
304 h27->GetYaxis()->SetTitle("<N_{chg}> in 0.02 bin");
305 h27->GetXaxis()->SetTitleColor(1);
306 h27->SetMarkerStyle(kFullCircle);
309 TProfile *h28 = new TProfile ("histo28", "PT_{sum} vs the Distance R from Charged Jet1", 30, 0., 0.6, 0.01, 10.);
310 h28->SetStats(kTRUE);
311 h28->GetXaxis()->SetTitle("Distance R");
312 h28->GetYaxis()->SetTitle("<PT_{sum} (GeV/c)> in 0.02 bin");
313 h28->GetXaxis()->SetTitleColor(1);
314 h28->SetMarkerStyle(kFullCircle);
317 TProfile *h29 = new TProfile ("histo29", "PT_{sum} vs the Distance R from Charged Jet1", 30, 0., 0.6, 0.01, 10.);
318 h29->SetStats(kTRUE);
319 h29->GetXaxis()->SetTitle("Distance R");
320 h29->GetYaxis()->SetTitle("<PT_{sum} (GeV/c)> in 0.02 bin");
321 h29->GetXaxis()->SetTitleColor(1);
322 h29->SetMarkerStyle(kFullCircle);
327 //______________________________________________________________________________
328 void AliCdfJetFinder::FindJets()
331 // * Order all charged particles according to their PT.
332 // * Start with the highest PT particle and include in the "jet" all particles within the "radius" R = 0.7
333 // (considering each particle in the order of decreasing PT and recalculating the centroid of the jet after
334 // each new particle is added to the jet).
335 // * Go to the next highest PT particle (not already included in a jet) and include in the "jet" all particles
336 // (not already included in a jet) within the radius R =0.7.
337 // * Continue until all particles are in a "jet".
338 if (fDebug) { printf("AliCDJetfinder::FindJets() %d \n", __LINE__ ); }
339 AliCdfJetHeader *header = (AliCdfJetHeader*)fHeader;
343 fDebug = header->GetDebug();
344 fAODwrite = header->IsAODwrite() ; // write jets to AOD
345 fAODtracksWrite = header->IsAODtracksWrite() ; // write jet tracks to AOD
346 fRadius = header->GetRadius(); // get Radius from jet finder header
347 fMinJetParticles = header->GetMinPartJet (); // get minimum multiplicity of an jet
348 fJetPtCut = header->GetJetPtCut (); // get minimum of jet pt
351 { cout << "Header not found" << endl; return; }
355 fFromAod = !strcmp(fReader->ClassName(),"AliJetAODReader");
356 if (fFromAod) { fRefArr = fReader->GetReferences(); }
363 cout << "entries = 0 ; Event empty !!!" << endl ;
365 // no need to call clean, InitData does not
366 // create pointers if npart == 0
368 } // if event empty then exit
372 ComputeConesWeight();
375 if(fDebug)cout << "Writing AOD" << endl ;
379 if (fAnalyseJets) AnalizeJets();
385 //______________________________________________________________________________
386 void AliCdfJetFinder::InitData()
388 // initialisation of variables and data members
390 TClonesArray * vectArray = fReader->GetMomentumArray() ;
391 if ( vectArray == 0 ) { cout << "Could not get the momentum array" << endl; return; }
393 fNPart = vectArray->GetEntries() ; // n particles in this event;
395 if ( fNPart == 0 ) { return ; } // if event empty then exit
397 fVectParticle = new varContainer* [fNPart]; // container for Particles
399 fPtArray = new Double_t [fNPart] ; // momentum array
400 fIdxArray = new Int_t [fNPart] ; // index array of sorted pts
402 // initialisation of momentum and index arrays
403 for ( Int_t i = 0 ; i < fNPart ; i++ )
404 {// SORTING STEP :: fPtArray with data from TClonesArray of TLorentzVector
405 TLorentzVector * lv = (TLorentzVector*) vectArray->At(i);
407 // INITIALISATION of local arrays for temporary storage
408 varContainer *aParticle = new varContainer;
409 aParticle->pt = lv->Pt();
410 aParticle->eta = lv->Eta();
411 aParticle->phi = TVector2::Phi_mpi_pi ( lv->Phi() ); // normalize to -pi,pi
412 aParticle->njet = -999;
414 fVectParticle[i] = aParticle; // vector of Particles
416 // initializing arrays
417 fIdxArray [i] = -999 ;
418 fPtArray [i] = aParticle->pt ;
421 TMath::Sort ( fNPart, fPtArray, fIdxArray ) ; // get a sorted array of indexes with TClonesArray.Size()
426 //______________________________________________________________________________
427 void AliCdfJetFinder::FindCones()
429 // parsing of particles in event and estlabish jets (label them with jet index)
431 Double_t ptSeed = 0. , etaSeed = 0. , phiSeed = 0. ; // leading particle params
432 Double_t pttmp = 0. , etatmp = 0. , phitmp = 0. ; // temporary variables to be used in various calculations
433 Double_t deta = 0. , dphi = 0. , dcomputed = 0. ;
436 fNJets = -1 ; // n jets in this event
437 Int_t idxPtSort = -1 ; // index of array of sorted pt indexes
439 if (fDebug) { cout << "\n\n\n\n\n\n------------------\nBegin Event Analysis\n------------------\n\n" << endl ;}
441 if(fDebug)cout << "fNPart = " << fNPart << endl;
443 TBits lkupTable ( fNPart ) ; // bit container ; 1-to-1 corespondence with fIdxArray
445 while ( lkupTable.CountBits() != (UInt_t)fNPart )
446 { // loop over particles in event until all flags are set
447 UInt_t firstnonflagged = lkupTable.FirstNullBit() ; // set the index to the first NON flagged bit ; less conditions
449 if(fDebug)cout << "\n\nfirst_non_flagged : " << firstnonflagged << endl;
451 ++fNJets; // incrementing the jet counter
452 if (fDebug) { printf("JET %d \n", fNJets); }
454 ptSeed = 0. ; etaSeed = 0. ; phiSeed = 0. ; // reseting leading particle params
456 for ( UInt_t ipart = firstnonflagged ; ipart < (UInt_t)fNPart ; ipart++ )
457 {// iteration over particles in event
458 // the loop is done over sorted array of pt
459 idxPtSort = fIdxArray[ipart] ; // index of particle ! fIdxArray is an index list pt sorted
461 if ( lkupTable.TestBitNumber(ipart) ) { continue; } // if 4vector is already flagged skip it
463 //init computed and used vars
464 pttmp = 0. ; etatmp = 0. ; phitmp = 0. ;
465 deta = 0. ; dphi = 0. ; dcomputed = 0. ; injet = 0 ;
467 //taking info from fVectParticle ;
468 pttmp = fVectParticle[idxPtSort]->pt ;
469 etatmp = fVectParticle[idxPtSort]->eta ;
470 phitmp = fVectParticle[idxPtSort]->phi ;
472 if ( ipart == firstnonflagged )
473 {// this is first particle in event; leading particle
474 // begin the search around this particle in a fRadius
477 ptSeed = pttmp ; etaSeed = etatmp ; phiSeed = phitmp ; // seeding the jet with first particle idxPtSort
479 lkupTable.SetBitNumber ( ipart ) ; // flag the index of particle in lkup_table
480 fVectParticle[idxPtSort]->njet = fNJets ; // associate particle with current jet number
482 if (fDebug) { printf("\nLeading particle :: particle index = %d ; at sorted index %d ; in jet %d \n", idxPtSort, ipart, fNJets); }
483 if (fDebug) { printf("pt= %g ; eta= %g ; phi = %g \n", pttmp, etatmp, phitmp) ; }
484 if (fDebug) { lkupTable.Print() ;}
486 continue ; // skip to next particle
489 // condition to be in jet
490 deta = etatmp - etaSeed ;
491 dphi = TVector2::Phi_mpi_pi (phitmp - phiSeed) ; // computing dphi and normalizing to (0,2pi) interval in one step
493 dcomputed = TMath::Hypot(deta, dphi) ; // Distance(fRadius) to (eta,phi) seed
495 injet = ( ( fRadius - dcomputed ) >= 0.000000001 ) ? 1 : 0 ; // if r_computed is within jet_r in_jet == 1 else 0
498 { // calculus of jet variables
499 lkupTable.SetBitNumber ( ipart ) ; // flag the index of particle in lkup_table
500 fVectParticle[idxPtSort]->njet = fNJets ; // setting in particle list the associated jet
502 if (fDebug) { printf("\njet particle :: particle index = %d ; at sorted index %d ; in jet %d ; found at radius %g ; \n", idxPtSort, ipart, fNJets, dcomputed); }
503 if (fDebug) { printf("pt= %g ; eta= %g ; phi = %g \n", pttmp, etatmp, phitmp) ; }
504 if (fDebug) { lkupTable.Print() ;}
506 continue ; // skip to next particle
510 // end of iteration over event; one jet definition of content ; jet parameters to be computed later
515 //______________________________________________________________________________
516 void AliCdfJetFinder::ComputeConesWeight()
518 // computing of jets Pt, Eta and Phi (centre of weight in (eta,phi) plane)
519 // rescan the vector of particles by identify them by asociate jet number for computing of weight centre
522 fVectJet = new varContainer* [fNJets]; // container for Jets
524 Double_t ptJet, ptJet2 , etaJet , phiJet ; Int_t npartJet ;
525 Double_t pttmp = 0. , etatmp = 0. , phitmp = 0. ; // temporary variables to be used in various calculations
526 Int_t idxPtSort = -999 ; // index of array of sorted pt indexes
528 for( Int_t jet = 0 ; jet < fNJets ; jet++ )
530 if (fDebug) { printf("\n\n--- Computing weight of Jet %d \n", jet ); }
531 npartJet = 0 ; ptJet = 0. ; etaJet = 0. ; phiJet = 0. ; // reset variables for a new computation
533 for ( Int_t ipart = 0 ; ipart < fNPart ; ipart++ )
534 {// iteration over particles in event
535 // the loop is done over sorted array of pt
536 idxPtSort = fIdxArray[ipart] ; // index of particle ! fIdxArray is an index list pt sorted
538 if ( fVectParticle[idxPtSort]->njet == jet )
540 ++npartJet; // incrementing the counter of jet particles
542 //taking info from fVectParticle ;
543 pttmp = fVectParticle[idxPtSort]->pt ;
544 etatmp = fVectParticle[idxPtSort]->eta ;
545 phitmp = TVector2::Phi_mpi_pi (fVectParticle[idxPtSort]->phi) ;
547 // jet_new_angular_coordinate = jet_old_angular_coordinate * jet_old_pt / jet_new_pt +
548 // part[i]_angular_coordinate * part[i]_pt/jet_new_pt
550 ptJet2 = ptJet + pttmp ;
552 etaJet = etaJet * ptJet / ptJet2 + etatmp * pttmp / ptJet2 ;
553 phiJet = phiJet * ptJet / ptJet2 + phitmp * pttmp / ptJet2 ;
558 // add a particle and recalculation of centroid
560 // end of 1 jet computation
562 varContainer *aJet = new varContainer; // Jet container
563 aJet->pt = ptJet; aJet->eta = etaJet; aJet->phi = phiJet; aJet->njet = npartJet; // setting jet vars in container
564 fVectJet[jet] = aJet; // store the number of the jet(fNJets) and increment afterwards
566 if (fDebug) { printf ("=== current jet %d : npartjet= %d ; pt_jet= %g ; eta_jet = %g ; phi_jet = %g \n\n\n",
567 jet, npartJet, ptJet, etaJet, phiJet ) ; }
575 //______________________________________________________________________________
576 void AliCdfJetFinder::WriteJets()
578 // Writing AOD jets and AOD tracks
580 for( Int_t jetnr = 0 ; jetnr < fNJets ; jetnr++ )
582 Double_t pt = 0., eta = 0., phi = 0., // jet variables
583 px = 0., py = 0., pz = 0., en = 0.; // convert to 4-vector
584 pt = fVectJet[ jetnr ]->pt ; // pt of jet
585 eta = fVectJet[ jetnr ]->eta ; // eta of jet
586 phi = fVectJet[ jetnr ]->phi ; // phi of jet
588 px = pt * TMath::Cos ( phi ) ;
589 py = pt * TMath::Sin ( phi ) ;
590 pz = pt / TMath::Tan ( 2.0 * TMath::ATan ( TMath::Exp ( -eta ) ) ) ;
591 en = TMath::Sqrt ( px * px + py * py + pz * pz );
593 AliAODJet jet (px, py, pz, en);
596 if (fDebug) jet.Print("");
598 if (fFromAod && fAODtracksWrite)
600 for ( Int_t jetTrack = 0; jetTrack < fNPart; jetTrack++ )
601 { if ( fVectParticle[jetTrack]->njet == jetnr ) { jet.AddTrack(fRefArr->At(jetTrack)) ; } }
603 // tracks REFs written in AOD
607 //jets vector parsed and written to AOD
611 //______________________________________________________________________________
612 void AliCdfJetFinder::AnalizeJets()
614 // analyzing of jets and filling of histograms
616 const Double_t kPI = TMath::Pi();
618 //persistent pointer to histo20
619 TH1F *hR = (TH1F*)fHistos->FindObject("histo20");
621 Int_t *jetsptidx = 0; // sorted array of jets pt
622 Double_t *jetspt = 0; // array of jets pts
623 Int_t leadingjetindex = -1 ; // index of leading jet from fVectJet
624 Int_t partleadjet = 0 ; // number of particles in leading jet
625 Double_t ptleadjet = 0. ; // pt of leading jet
626 Double_t etaleadjet = 0. ; // eta of leading jet
627 Double_t phileadjet = 0. ; // phi of leading jet
629 jetsptidx = new Int_t [fNJets] ;
630 jetspt = new Double_t [fNJets] ;
632 //________________________________________________________________________________________
633 // Jet sorting and finding the leading jet that coresponds to cuts in pt and multiplicity
634 //________________________________________________________________________________________
636 // filing the idx_ptjets array
637 if (fDebug) printf("List of unsorted jets:\n");
638 for( Int_t i = 0 ; i < fNJets ; i++ )
641 jetspt [i] = fVectJet[i]->pt ;
642 if (fDebug) { cout << " jet found: " << i << " npartjet=" << fVectJet[i]->njet << " ; jets_pt = " << jetspt[i] << endl; }
645 TMath::Sort ( fNJets, jetspt , jetsptidx ) ; // sorting pt of jets
647 // selection of leading jet
648 // looping over jets searching for __first__ one that coresponds to cuts
649 for( Int_t i = 0 ; i < fNJets ; i++ )
651 if ( ( fVectJet[ jetsptidx[i] ]->njet >= fMinJetParticles ) && ( fVectJet[ jetsptidx[i] ]->pt >= fJetPtCut ) )
653 leadingjetindex = jetsptidx[i] ;
654 partleadjet = fVectJet[ leadingjetindex ]->njet ; // number of particles in leading jet
655 ptleadjet = fVectJet[ leadingjetindex ]->pt ; // pt of leading jet
656 etaleadjet = fVectJet[ leadingjetindex ]->eta ; // eta of leading jet
657 phileadjet = fVectJet[ leadingjetindex ]->phi ; // phi of leading jet
660 { printf("Leading jet %d : npart= %d ; pt= %g ; eta = %g ; phi = %g \n", leadingjetindex, partleadjet, ptleadjet, etaleadjet, phileadjet ); }
665 // end of selection of leading jet
669 //////////////////////////////////////////////////
670 //// Computing of values used in histograms
671 //////////////////////////////////////////////////
673 //___________________________________________________________________________
674 // pt_sum of all particles in event
675 //___________________________________________________________________________
676 cout << "Computing sum of pt in event" << endl ;
677 Double_t ptsumevent = 0.;
678 for ( Int_t i = 0 ; i< fNPart ; i++ ) { ptsumevent += fVectParticle[i]->pt ; }
679 printf ("Sum of all Pt in event : pt_sum_event = %g", ptsumevent) ;
681 //___________________________________________________________________________
682 // Filling an array with indexes of leading jet particles
683 //___________________________________________________________________________
684 Int_t * idxpartLJ = new Int_t [partleadjet] ;
685 Int_t counterpartleadjet = 0;
687 cout << "Filling an array with indexes of leading jet particles" << endl;
689 for( Int_t i = 0 ; i < fNPart ; i++ )
691 if ( fVectParticle[i]->njet == leadingjetindex )
692 { idxpartLJ[counterpartleadjet++] = i ; }
695 if ( (counterpartleadjet-1) > partleadjet ) { cout << " Counter_part_lead_jet > part_leadjet !!!!" << endl;}
698 //___________________________________________________________________________
699 // Calculus of part distribution in leading jet
700 //___________________________________________________________________________
702 Double_t *zpartljet = new Double_t [ partleadjet ] ; // array of z of particles in leading jet
704 cout << "Entering loop of calculus of part distribution in leading jet" << endl ;
706 for( Int_t j = 0 ; j < partleadjet ; j++ )
708 Double_t zj = fVectParticle[idxpartLJ[j]]->pt ;
711 cout << "idx_leadjet_part[j] = " << idxpartLJ[j]
712 << " p of particle = " << zj
713 << " pt lead jet = " << ptleadjet
714 << " Z = " << z << endl;
718 //___________________________________________________________________________
719 // array of delta phi's between phi of particles and leading jet phi
720 //___________________________________________________________________________
721 cout << "array of delta phi's between phi of particles and leading jet phi" << endl;
722 Double_t dphipartLJ = 0. ;
723 Double_t *dphipartljet = new Double_t [fNPart];
724 for( Int_t part = 0 ; part < fNPart ; part++ )
726 dphipartLJ = fVectParticle[part]->phi - phileadjet ;
727 dphipartLJ = TVector2::Phi_mpi_pi (dphipartLJ) ; // restrict the delta phi to (-pi,pi) interval
728 dphipartljet [part] = dphipartLJ ;
729 printf("part= %d ; dphi_partLJ = %g \n", part, dphipartLJ );
733 //______________________________________________________________________________
734 // Pt distribution for all particles
735 //______________________________________________________________________________
736 TH1F * hpt = (TH1F*)fHistos->FindObject("histo11");
737 if ( hpt ) { for ( Int_t i = 0 ; i < fNPart ; i++ ) { hpt->Fill( fVectParticle[i]->pt ); } }
739 //___________________________________________________________________________
740 // Recomputing of radius of particles in leading jet
741 //___________________________________________________________________________
742 if (fDebug) { printf(" Searching particles with jet index %d\n", leadingjetindex); }
744 Double_t ddeta = 0. , ddphi = 0. , rpart = 0. ;
746 for( Int_t j = 0 ; j < partleadjet ; j++ )
748 ddeta = etaleadjet - fVectParticle[idxpartLJ[j]]->eta;
750 Double_t phitmp = fVectParticle[idxpartLJ[j]]->phi ;
752 ddphi = TVector2::Phi_mpi_pi ( phileadjet - phitmp ) ; // restrict the delta phi to (-pi,pi) interval
754 rpart = TMath::Hypot (ddeta, ddphi) ;
756 printf ("Particle %d with Re-Computed radius = %f ", idxpartLJ[j], rpart) ;
757 if ( (rpart - fRadius) >= 0.00000001 )
758 { printf (" bigger than selected radius of %f\n", fRadius ); }
762 if (hR) hR->Fill(rpart);
768 //_______________________________________________________________________
769 // Computing of radius that contain 80% of Leading Jet ( PT and multiplicity )
770 //_______________________________________________________________________
771 Double_t corepartleadjet = 0.8 * partleadjet ;
772 Double_t coreptleadjet = 0.8 * ptleadjet ;
773 Int_t countercorepart = 0 ;
774 Double_t countercorept = 0. ;
775 Int_t sortedindex = -1 ;
777 TProfile * hprof24 = (TProfile*)fHistos->FindObject("histo24");
778 TProfile * hprof25 = (TProfile*)fHistos->FindObject("histo25");
780 TProfile * hprof26 = (TProfile*)fHistos->FindObject("histo26");
781 TProfile * hprof27 = (TProfile*)fHistos->FindObject("histo27");
782 TProfile * hprof28 = (TProfile*)fHistos->FindObject("histo28");
783 TProfile * hprof29 = (TProfile*)fHistos->FindObject("histo29");
786 if ((hprof24) && (hprof25) && (hprof26) && (hprof27) && (hprof28) && (hprof29) )
788 for( Int_t part = 0 ; part < fNPart ; part++ )
790 Double_t pttmp = 0. ; Double_t etatmp = 0. ; Double_t phitmp = 0. ; // temporary variables
791 Double_t dpart = 0. ;
792 sortedindex = fIdxArray[part] ;
794 if ( fVectParticle [ sortedindex ]->njet == leadingjetindex )
796 pttmp = fVectParticle[sortedindex]->pt ;
797 etatmp = fVectParticle[sortedindex]->eta ;
798 phitmp = fVectParticle[sortedindex]->phi ;
801 countercorept += pttmp ;
803 dpart = TMath::Hypot ( etaleadjet - etatmp, TVector2::Phi_mpi_pi (phileadjet - phitmp) ) ;
805 if ( countercorepart <= corepartleadjet ) { hprof24->Fill(ptleadjet, dpart); }
806 if ( countercorept <= coreptleadjet ) { hprof25->Fill(ptleadjet, dpart); }
808 if (ptleadjet > 5.) { hprof26->Fill(dpart, countercorepart); hprof28->Fill(dpart, countercorept); }
809 if (ptleadjet > 30.) { hprof27->Fill(dpart, countercorepart); hprof29->Fill(dpart, countercorept); }
815 TH1F *hjetpt = (TH1F*)fHistos->FindObject("histo1");
816 TH1F *hjeteta = (TH1F*)fHistos->FindObject("histo2");
817 TH1F *hjetphi = (TH1F*)fHistos->FindObject("histo3");
818 TH1F *hjetnjet = (TH1F*)fHistos->FindObject("histo4");
820 for( Int_t jet = 0 ; jet < fNJets ; jet++ )
822 if (hjetpt) hjetpt ->Fill ( fVectJet[jet]->pt ) ;
823 if (hjeteta) hjeteta ->Fill ( fVectJet[jet]->eta ) ;
824 if (hjetphi) hjetphi ->Fill ( fVectJet[jet]->phi ) ;
825 if (hjetnjet) hjetnjet ->Fill ( fVectJet[jet]->njet ) ;
828 TH1F *hjets = (TH1F*)fHistos->FindObject("histo5");
829 if (hjets) hjets->Fill(fNJets);
831 TH1F *hleadpart = (TH1F*)fHistos->FindObject("histo6");
832 if (hleadpart) hleadpart->Fill(partleadjet);
834 TProfile * hprof = (TProfile*)fHistos->FindObject("histo7");
835 if (hprof) hprof->Fill(ptleadjet,partleadjet);
837 TH1F *hMD = (TH1F*)fHistos->FindObject("histo8");
838 for( Int_t k = 0 ; k < partleadjet ; k++)
839 { hMD->Fill( zpartljet[k] ); }
841 TProfile * hphi = (TProfile*)fHistos->FindObject("histo9");
842 for( Int_t k = 0 ; k < partleadjet ; k++)
843 { hphi->Fill( TMath::RadToDeg() * dphipartljet [k] , fNPart ) ; }
845 TProfile * htpd = (TProfile*)fHistos->FindObject("histo10");
846 for( Int_t k = 0 ; k < fNPart ; k++)
847 { htpd->Fill( TMath::RadToDeg() * dphipartljet [k] , ptsumevent ) ; }
850 TProfile * hprof1 = (TProfile*)fHistos->FindObject("histo21");
851 if (hprof1) hprof1->Fill(ptleadjet, fNPart);
853 TProfile * hprof2 = (TProfile*)fHistos->FindObject("histo22");
854 if (hprof2) hprof2->Fill(ptleadjet, ptsumevent);
856 TProfile * hprof1toward = (TProfile*)fHistos->FindObject("histo21_toward");
857 TProfile * hprof1transverse = (TProfile*)fHistos->FindObject("histo21_transverse");
858 TProfile * hprof1away = (TProfile*)fHistos->FindObject("histo21_away");
859 TProfile * hprof2toward = (TProfile*)fHistos->FindObject("histo22_toward");
860 TProfile * hprof2transverse = (TProfile*)fHistos->FindObject("histo22_transverse");
861 TProfile * hprof2away = (TProfile*)fHistos->FindObject("histo22_away");
862 TH1F * hpttoward = (TH1F*)fHistos->FindObject("histo23_toward");
863 TH1F * hpttransverse = (TH1F*)fHistos->FindObject("histo23_transverse");
864 TH1F * hptaway = (TH1F*)fHistos->FindObject("histo23_away");
866 if ( (hprof1toward) && (hprof1transverse) && (hprof1away) && (hprof2toward) && (hprof2transverse) && (hprof2away) )
868 for( Int_t part = 0 ; part < fNPart ; part++)
870 Double_t ptpart = fVectParticle[part]->pt ; // pt of particle
871 if ( ( dphipartljet[part] >=0.) && ( dphipartljet[part] < kPI/3. ) )
873 hprof1toward->Fill( ptleadjet, fNPart );
874 hprof2toward->Fill( ptleadjet, ptsumevent);
875 hpttoward->Fill( ptpart );
878 if ( ( dphipartljet[part] >= (kPI/3.)) && ( dphipartljet[part] < (2.*kPI/3.)) )
880 hprof1transverse->Fill( ptleadjet, fNPart );
881 hprof2transverse->Fill( ptleadjet, ptsumevent);
882 hpttransverse->Fill( ptpart );
885 if ( ( dphipartljet[part] >= ( 2.*kPI/3.)) && ( dphipartljet[part] < kPI ) )
887 hprof1away->Fill( ptleadjet, fNPart );
888 hprof2away->Fill( ptleadjet, ptsumevent);
889 hptaway->Fill( ptpart );
897 //______________________________________________________________________________
898 void AliCdfJetFinder::Clean()
901 for ( Int_t i = 0 ; i < fNPart ; i++ ){
902 delete fVectParticle[i];
903 fVectParticle[i] = 0;
905 delete [] fVectParticle;fVectParticle = 0;
907 for ( Int_t i = 0 ; i < fNJets ; i++ ){
911 delete [] fVectJet;fVectJet = 0;
913 delete [] fPtArray;fPtArray = 0;
914 delete [] fIdxArray;fIdxArray = 0;
919 //______________________________________________________________________________
920 void AliCdfJetFinder::FinishRun()