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f0377b23 | 1 | /************************************************************************** |
2 | * Copyright(c) 1998-1999, ALICE Experiment at CERN, All rights reserved. * | |
3 | * * | |
4 | * Author: The ALICE Off-line Project. * | |
5 | * Contributors are mentioned in the code where appropriate. * | |
6 | * * | |
7 | * Permission to use, 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 | **************************************************************************/ | |
15 | /* $Id$ */ | |
f0377b23 | 16 | |
17 | //_________________________________________________________________________ | |
18 | // | |
19 | // Class for trigger analysis. | |
0964c2e9 | 20 | // Digits are grouped in TRU's (Trigger Units). A TRU consists of 384 |
85c25c2e | 21 | // modules ordered fNTRUPhi x fNTRUEta. The algorithm searches all possible 2x2 |
0964c2e9 | 22 | // and nxn (n is a multiple of 2) cell combinations per each TRU, adding the |
23 | // digits amplitude and finding the maximum. If found, look if it is isolated. | |
24 | // Maxima are transformed in ADC time samples. Each time bin is compared to the trigger | |
25 | // threshold until it is larger and then, triggers are set. Thresholds need to be fixed. | |
0b2ec9f7 | 26 | // Thresholds need to be fixed. Last 2 modules are half size in Phi, I considered |
27 | // that the number of TRU is maintained for the last modules but decision not taken. | |
28 | // If different, then this must be changed. | |
f0377b23 | 29 | // Usage: |
30 | // | |
31 | // //Inside the event loop | |
32 | // AliEMCALTrigger *tr = new AliEMCALTrigger();//Init Trigger | |
0b2ec9f7 | 33 | // tr->SetL0Threshold(100); //Arbitrary threshold values |
85c25c2e | 34 | // tr->SetL1GammaLowPtThreshold(1000); |
35 | // tr->SetL1GammaMediumPtThreshold(10000); | |
36 | // tr->SetL1GammaHighPtThreshold(20000); | |
0964c2e9 | 37 | // ... |
f0377b23 | 38 | // tr->Trigger(); //Execute Trigger |
39 | // tr->Print(""); //Print results | |
40 | // | |
41 | //*-- Author: Gustavo Conesa & Yves Schutz (IFIC, CERN) | |
42 | ////////////////////////////////////////////////////////////////////////////// | |
43 | ||
d1f9a8ab | 44 | #include <cassert> |
f0377b23 | 45 | |
46 | // --- ROOT system --- | |
85c25c2e | 47 | #include <TTree.h> |
48 | #include <TBranch.h> | |
49 | #include <TBrowser.h> | |
50 | #include <TH2F.h> | |
f0377b23 | 51 | |
52 | // --- ALIROOT system --- | |
f0377b23 | 53 | #include "AliRun.h" |
54 | #include "AliRunLoader.h" | |
55 | #include "AliTriggerInput.h" | |
56 | #include "AliEMCAL.h" | |
57 | #include "AliEMCALLoader.h" | |
58 | #include "AliEMCALDigit.h" | |
59 | #include "AliEMCALTrigger.h" | |
60 | #include "AliEMCALGeometry.h" | |
133abe1f | 61 | #include "AliEMCALRawUtils.h" |
f0377b23 | 62 | |
63 | ClassImp(AliEMCALTrigger) | |
64 | ||
85c25c2e | 65 | TString AliEMCALTrigger::fgNameOfJetTriggers("EMCALJetTriggerL1"); |
66 | ||
f0377b23 | 67 | //______________________________________________________________________ |
68 | AliEMCALTrigger::AliEMCALTrigger() | |
9946f2fe | 69 | : AliTriggerDetector(), fGeom(0), |
85c25c2e | 70 | f2x2MaxAmp(-1), f2x2ModulePhi(-1), f2x2ModuleEta(-1), |
18a21c7c | 71 | f2x2SM(0), |
85c25c2e | 72 | fnxnMaxAmp(-1), fnxnModulePhi(-1), fnxnModuleEta(-1), |
0b2ec9f7 | 73 | fnxnSM(0), |
0964c2e9 | 74 | fADCValuesHighnxn(0),fADCValuesLownxn(0), |
75 | fADCValuesHigh2x2(0),fADCValuesLow2x2(0), | |
76 | fDigitsList(0), | |
85c25c2e | 77 | fL0Threshold(100),fL1GammaLowPtThreshold(200), |
78 | fL1GammaMediumPtThreshold(500), fL1GammaHighPtThreshold(1000), | |
0964c2e9 | 79 | fPatchSize(1), fIsolPatchSize(1), |
80 | f2x2AmpOutOfPatch(-1), fnxnAmpOutOfPatch(-1), | |
81 | f2x2AmpOutOfPatchThres(100000), fnxnAmpOutOfPatchThres(100000), | |
82 | fIs2x2Isol(kFALSE), fIsnxnIsol(kFALSE), | |
85c25c2e | 83 | fSimulation(kTRUE), fIsolateInSuperModule(kTRUE), fTimeKey(kFALSE), |
84 | fAmpTrus(0),fTimeRtrus(0),fAmpSMods(0), | |
85 | fTriggerPosition(6), fTriggerAmplitudes(4), | |
86 | fNJetPatchPhi(3), fNJetPatchEta(3), fNJetThreshold(3), fL1JetThreshold(0), fJetMaxAmp(0), | |
87 | fAmpJetMatrix(0), fJetMatrixE(0), fAmpJetMax(6,1), fVZER0Mult(0.) | |
f0377b23 | 88 | { |
59264fa6 | 89 | //ctor |
0964c2e9 | 90 | fADCValuesHighnxn = 0x0; //new Int_t[fTimeBins]; |
91 | fADCValuesLownxn = 0x0; //new Int_t[fTimeBins]; | |
92 | fADCValuesHigh2x2 = 0x0; //new Int_t[fTimeBins]; | |
93 | fADCValuesLow2x2 = 0x0; //new Int_t[fTimeBins]; | |
59264fa6 | 94 | |
59264fa6 | 95 | SetName("EMCAL"); |
85c25c2e | 96 | // Define jet threshold - can not change from outside now |
97 | // fNJetThreshold = 7; // For MB Pythia suppression | |
98 | fNJetThreshold = 10; // Hijing | |
99 | fL1JetThreshold = new Double_t[fNJetThreshold]; | |
100 | if(fNJetThreshold == 7) { | |
101 | fL1JetThreshold[0] = 5./0.0153; | |
102 | fL1JetThreshold[1] = 8./0.0153; | |
103 | fL1JetThreshold[2] = 10./0.0153; | |
104 | fL1JetThreshold[3] = 12./0.0153; | |
105 | fL1JetThreshold[4] = 13./0.0153; | |
106 | fL1JetThreshold[5] = 14./0.0153; | |
107 | fL1JetThreshold[6] = 15./0.0153; | |
108 | } else if(fNJetThreshold == 10) { | |
109 | Double_t thGev[10]={5.,8.,10., 12., 13.,14.,15., 17., 20., 25.}; | |
110 | for(Int_t i=0; i<fNJetThreshold; i++) fL1JetThreshold[i] = thGev[i]/0.0153; | |
111 | } else { | |
112 | fL1JetThreshold[0] = 5./0.0153; | |
113 | fL1JetThreshold[1] = 10./0.0153; | |
114 | fL1JetThreshold[2] = 15./0.0153; | |
115 | fL1JetThreshold[3] = 20./0.0153; | |
116 | fL1JetThreshold[4] = 25./0.0153; | |
117 | } | |
118 | // | |
59264fa6 | 119 | CreateInputs(); |
85c25c2e | 120 | |
121 | fInputs.SetName("TriggersInputs"); | |
59264fa6 | 122 | //Print("") ; |
f0377b23 | 123 | } |
124 | ||
125 | ||
126 | ||
127 | //____________________________________________________________________________ | |
128 | AliEMCALTrigger::AliEMCALTrigger(const AliEMCALTrigger & trig) | |
18a21c7c | 129 | : AliTriggerDetector(trig), |
9946f2fe | 130 | fGeom(trig.fGeom), |
18a21c7c | 131 | f2x2MaxAmp(trig.f2x2MaxAmp), |
85c25c2e | 132 | f2x2ModulePhi(trig.f2x2ModulePhi), |
133 | f2x2ModuleEta(trig.f2x2ModuleEta), | |
18a21c7c | 134 | f2x2SM(trig.f2x2SM), |
0b2ec9f7 | 135 | fnxnMaxAmp(trig.fnxnMaxAmp), |
85c25c2e | 136 | fnxnModulePhi(trig.fnxnModulePhi), |
137 | fnxnModuleEta(trig.fnxnModuleEta), | |
0b2ec9f7 | 138 | fnxnSM(trig.fnxnSM), |
139 | fADCValuesHighnxn(trig.fADCValuesHighnxn), | |
140 | fADCValuesLownxn(trig.fADCValuesLownxn), | |
18a21c7c | 141 | fADCValuesHigh2x2(trig.fADCValuesHigh2x2), |
142 | fADCValuesLow2x2(trig.fADCValuesLow2x2), | |
143 | fDigitsList(trig.fDigitsList), | |
144 | fL0Threshold(trig.fL0Threshold), | |
85c25c2e | 145 | fL1GammaLowPtThreshold(trig.fL1GammaLowPtThreshold), |
146 | fL1GammaMediumPtThreshold(trig.fL1GammaMediumPtThreshold), | |
147 | fL1GammaHighPtThreshold(trig.fL1GammaHighPtThreshold), | |
0964c2e9 | 148 | fPatchSize(trig.fPatchSize), |
149 | fIsolPatchSize(trig.fIsolPatchSize), | |
150 | f2x2AmpOutOfPatch(trig.f2x2AmpOutOfPatch), | |
151 | fnxnAmpOutOfPatch(trig.fnxnAmpOutOfPatch), | |
152 | f2x2AmpOutOfPatchThres(trig.f2x2AmpOutOfPatchThres), | |
153 | fnxnAmpOutOfPatchThres(trig.fnxnAmpOutOfPatchThres), | |
154 | fIs2x2Isol(trig.fIs2x2Isol), | |
155 | fIsnxnIsol(trig.fIsnxnIsol), | |
156 | fSimulation(trig.fSimulation), | |
85c25c2e | 157 | fIsolateInSuperModule(trig.fIsolateInSuperModule), |
158 | fTimeKey(trig.fTimeKey), | |
159 | fAmpTrus(trig.fAmpTrus), | |
160 | fTimeRtrus(trig.fTimeRtrus), | |
161 | fAmpSMods(trig.fAmpSMods), | |
162 | fTriggerPosition(trig.fTriggerPosition), | |
163 | fTriggerAmplitudes(trig.fTriggerAmplitudes), | |
164 | fNJetPatchPhi(trig.fNJetPatchPhi), | |
165 | fNJetPatchEta(trig.fNJetPatchEta), | |
166 | fNJetThreshold(trig.fNJetThreshold), | |
167 | fL1JetThreshold(trig.fL1JetThreshold), | |
168 | fJetMaxAmp(trig.fJetMaxAmp), | |
169 | fAmpJetMatrix(trig.fAmpJetMatrix), | |
170 | fJetMatrixE(trig.fJetMatrixE), | |
171 | fAmpJetMax(trig.fAmpJetMax), | |
172 | fVZER0Mult(trig.fVZER0Mult) | |
f0377b23 | 173 | { |
f0377b23 | 174 | // cpy ctor |
f0377b23 | 175 | } |
176 | ||
c35bbfd4 | 177 | AliEMCALTrigger::~AliEMCALTrigger() { |
85c25c2e | 178 | if(GetTimeKey()) { |
179 | delete [] fADCValuesHighnxn; | |
180 | delete [] fADCValuesLownxn; | |
181 | delete [] fADCValuesHigh2x2; | |
182 | delete [] fADCValuesLow2x2; | |
183 | } | |
184 | if(fAmpTrus) {fAmpTrus->Delete(); delete fAmpTrus;} | |
185 | if(fTimeRtrus) {fTimeRtrus->Delete(); delete fTimeRtrus;} | |
186 | if(fAmpSMods) {fAmpSMods->Delete(); delete fAmpSMods;} | |
187 | if(fAmpJetMatrix) delete fAmpJetMatrix; | |
188 | if(fJetMatrixE) delete fJetMatrixE; | |
189 | if(fL1JetThreshold) delete [] fL1JetThreshold; | |
c35bbfd4 | 190 | } |
191 | ||
f0377b23 | 192 | //---------------------------------------------------------------------- |
193 | void AliEMCALTrigger::CreateInputs() | |
194 | { | |
195 | // inputs | |
196 | ||
197 | // Do not create inputs again!! | |
198 | if( fInputs.GetEntriesFast() > 0 ) return; | |
85c25c2e | 199 | |
200 | // Second parameter should be detector name = "EMCAL" | |
201 | TString det("EMCAL"); // Apr 29, 2008 | |
202 | fInputs.AddLast( new AliTriggerInput( det+"_L0", det, 0x02) ); | |
203 | fInputs.AddLast( new AliTriggerInput( det+"_GammaHPt_L1", det, 0x04 ) ); | |
204 | fInputs.AddLast( new AliTriggerInput( det+"_GammaMPt_L1", det, 0x08 ) ); | |
205 | fInputs.AddLast( new AliTriggerInput( det+"_GammaLPt_L1", det, 0x016 ) ); | |
206 | ||
207 | if(fNJetThreshold<=0) return; | |
208 | // Jet Trigger(s) | |
209 | UInt_t level = 0x032; | |
210 | for(Int_t i=0; i<fNJetThreshold; i++ ) { | |
7e42cd80 | 211 | TString name(GetNameOfJetTrigger(i)); |
85c25c2e | 212 | TString title("EMCAL Jet triger L1 :"); // unused now |
213 | // 0.0153 - hard coded now | |
214 | title += Form("Th %i(%5.1f GeV) :", (Int_t)fL1JetThreshold[i], fL1JetThreshold[i] * 0.0153); | |
215 | title += Form("patch %ix%i~(%3.2f(#phi)x%3.2f(#eta)) ", | |
216 | fNJetPatchPhi, fNJetPatchEta, 0.11*(fNJetPatchPhi), 0.11*(fNJetPatchEta)); | |
217 | fInputs.AddLast( new AliTriggerInput(name, det, UChar_t(level)) ); | |
218 | level *= 2; | |
219 | } | |
f0377b23 | 220 | |
221 | } | |
222 | ||
223 | //____________________________________________________________________________ | |
0964c2e9 | 224 | Bool_t AliEMCALTrigger::IsPatchIsolated(Int_t iPatchType, const TClonesArray * ampmatrixes, const Int_t iSM, const Int_t mtru, const Float_t maxamp, const Int_t maxphi, const Int_t maxeta) { |
225 | ||
85c25c2e | 226 | // Nov 8, 2007 |
227 | // EMCAL RTU size is 4modules(phi) x 24modules (eta) | |
228 | // So maximum size of patch is 4modules x 4modules (EMCAL L0 trigger). | |
229 | // Calculate if the maximum patch found is isolated, find amplitude around maximum (2x2 or nxn) patch, | |
230 | // inside isolation patch . iPatchType = 0 means calculation for 2x2 patch, | |
231 | // iPatchType = 1 means calculation for nxn patch. | |
232 | // In the next table there is an example of the different options of patch size and isolation patch size: | |
233 | // Patch Size (fPatchSize) | |
234 | // 0 1 | |
235 | // fIsolPatchSize 0 2x2 (not overlap) 4x4 (overlapped) | |
236 | // 1 4x4 8x8 | |
0964c2e9 | 237 | |
238 | Bool_t b = kFALSE; | |
0964c2e9 | 239 | |
85c25c2e | 240 | // Get matrix of TRU or Module with maximum amplitude patch. |
241 | Int_t itru = mtru + iSM * fGeom->GetNTRU(); //number of tru, min 0 max 3*12=36. | |
0964c2e9 | 242 | TMatrixD * ampmatrix = 0x0; |
243 | Int_t colborder = 0; | |
244 | Int_t rowborder = 0; | |
85c25c2e | 245 | static int keyPrint = 0; |
246 | if(keyPrint) printf(" IsPatchIsolated : iSM %i mtru %i itru %i maxphi %i maxeta %i \n", iSM, mtru, itru, maxphi, maxeta); | |
0964c2e9 | 247 | |
85c25c2e | 248 | if(fIsolateInSuperModule){ // ? |
0964c2e9 | 249 | ampmatrix = dynamic_cast<TMatrixD *>(ampmatrixes->At(iSM)) ; |
85c25c2e | 250 | rowborder = fGeom->GetNPhi(); |
251 | colborder = fGeom->GetNZ(); | |
0964c2e9 | 252 | AliDebug(2,"Isolate trigger in Module"); |
85c25c2e | 253 | } else{ |
0964c2e9 | 254 | ampmatrix = dynamic_cast<TMatrixD *>(ampmatrixes->At(itru)) ; |
85c25c2e | 255 | rowborder = fGeom->GetNModulesInTRUPhi(); |
256 | colborder = fGeom->GetNModulesInTRUEta(); | |
0964c2e9 | 257 | AliDebug(2,"Isolate trigger in TRU"); |
258 | } | |
85c25c2e | 259 | if(iSM>9) rowborder /= 2; // half size in phi |
0964c2e9 | 260 | |
85c25c2e | 261 | //Define patch modules - what is this ?? |
262 | Int_t isolmodules = fIsolPatchSize*(1+iPatchType); | |
263 | Int_t ipatchmodules = 2*(1+fPatchSize*iPatchType); | |
264 | Int_t minrow = maxphi - isolmodules; | |
265 | Int_t mincol = maxeta - isolmodules; | |
266 | Int_t maxrow = maxphi + isolmodules + ipatchmodules; | |
267 | Int_t maxcol = maxeta + isolmodules + ipatchmodules; | |
268 | ||
269 | minrow = minrow<0?0 :minrow; | |
270 | mincol = mincol<0?0 :mincol; | |
271 | ||
272 | maxrow = maxrow>rowborder?rowborder :maxrow; | |
273 | maxcol = maxcol>colborder?colborder :maxcol; | |
9946f2fe | 274 | |
85c25c2e | 275 | //printf("%s\n",Form("Number of added Isol Modules %d, Patch Size %d",isolmodules, ipatchmodules)); |
276 | //printf("%s\n",Form("Patch: minrow %d, maxrow %d, mincol %d, maxcol %d",minrow,maxrow,mincol,maxcol)); | |
277 | // AliDebug(2,Form("Number of added Isol Modules %d, Patch Size %d",isolmodules, ipatchmodules)); | |
278 | //AliDebug(2,Form("Patch: minrow %d, maxrow %d, mincol %d, maxcol %d",minrow,maxrow,mincol,maxcol)); | |
0964c2e9 | 279 | |
0964c2e9 | 280 | //Add amplitudes in all isolation patch |
85c25c2e | 281 | Float_t amp = 0.; |
0964c2e9 | 282 | for(Int_t irow = minrow ; irow < maxrow; irow ++) |
283 | for(Int_t icol = mincol ; icol < maxcol ; icol ++) | |
284 | amp += (*ampmatrix)(irow,icol); | |
285 | ||
286 | AliDebug(2,Form("Type %d, Maximum amplitude %f, patch+isol square %f",iPatchType, maxamp, amp)); | |
287 | ||
288 | if(amp < maxamp){ | |
85c25c2e | 289 | // AliError(Form("Bad sum: Type %d, Maximum amplitude %f, patch+isol square %f",iPatchType, maxamp, amp)); |
290 | // ampmatrix->Print(); | |
0964c2e9 | 291 | return kFALSE; |
85c25c2e | 292 | } else { |
0964c2e9 | 293 | amp-=maxamp; //Calculate energy in isolation patch that do not comes from maximum patch. |
85c25c2e | 294 | } |
0964c2e9 | 295 | |
296 | AliDebug(2, Form("Maximum amplitude %f, Out of patch %f",maxamp, amp)); | |
297 | ||
298 | //Fill isolation amplitude data member and say if patch is isolated. | |
299 | if(iPatchType == 0){ //2x2 case | |
300 | f2x2AmpOutOfPatch = amp; | |
85c25c2e | 301 | if(amp < f2x2AmpOutOfPatchThres) b=kTRUE; |
302 | } else if(iPatchType == 1){ //nxn case | |
0964c2e9 | 303 | fnxnAmpOutOfPatch = amp; |
85c25c2e | 304 | if(amp < fnxnAmpOutOfPatchThres) b=kTRUE; |
0964c2e9 | 305 | } |
306 | ||
85c25c2e | 307 | if(keyPrint) printf(" IsPatchIsolated - OUT \n"); |
308 | ||
0964c2e9 | 309 | return b; |
310 | ||
311 | } | |
312 | ||
85c25c2e | 313 | /* |
0964c2e9 | 314 | //____________________________________________________________________________ |
c35bbfd4 | 315 | void AliEMCALTrigger::MakeSlidingCell(const TClonesArray * amptrus, const TClonesArray * timeRtrus, const Int_t isupermod,TMatrixD &max2, TMatrixD &maxn){ |
f0377b23 | 316 | |
85c25c2e | 317 | //Sums energy of all possible 2x2 (L0) and nxn (L1) modules per each TRU. |
318 | //Fast signal in the experiment is given by 2x2 modules, | |
319 | //for this reason we loop inside the TRU modules by 2. | |
33d0b833 | 320 | |
59264fa6 | 321 | //Declare and initialize variables |
9946f2fe | 322 | Int_t nCellsPhi = fGeom->GetNCellsInTRUPhi(); |
33d0b833 | 323 | if(isupermod > 9) |
59264fa6 | 324 | nCellsPhi = nCellsPhi / 2 ; //Half size SM. Not Final. |
f0377b23 | 325 | // 12(tow)*2(cell)/1 TRU, cells in Phi in one TRU |
9946f2fe | 326 | Int_t nCellsEta = fGeom->GetNCellsInTRUEta(); |
327 | Int_t nTRU = fGeom->GetNTRU(); | |
f0377b23 | 328 | // 24(mod)*2(tower)/3 TRU, cells in Eta in one TRU |
0964c2e9 | 329 | //Int_t nTRU = geom->GeNTRU();//3 TRU per super module |
f0377b23 | 330 | |
59264fa6 | 331 | Float_t amp2 = 0 ; |
0b2ec9f7 | 332 | Float_t ampn = 0 ; |
33d0b833 | 333 | for(Int_t i = 0; i < 4; i++){ |
9946f2fe | 334 | for(Int_t j = 0; j < nTRU; j++){ |
c35bbfd4 | 335 | ampmax2(i,j) = -1; |
336 | ampmaxn(i,j) = -1; | |
59264fa6 | 337 | } |
338 | } | |
f0377b23 | 339 | |
59264fa6 | 340 | //Create matrix that will contain 2x2 amplitude sums |
0b2ec9f7 | 341 | //used to calculate the nxn sums |
c35bbfd4 | 342 | TMatrixD tru2x2(nCellsPhi/2,nCellsEta/2) ; |
59264fa6 | 343 | for(Int_t i = 0; i < nCellsPhi/2; i++) |
344 | for(Int_t j = 0; j < nCellsEta/2; j++) | |
c35bbfd4 | 345 | tru2x2(i,j) = -1; |
59264fa6 | 346 | |
347 | //Loop over all TRUS in a supermodule | |
9946f2fe | 348 | for(Int_t itru = 0 + isupermod * nTRU ; itru < (isupermod+1)*nTRU ; itru++) { |
59264fa6 | 349 | TMatrixD * amptru = dynamic_cast<TMatrixD *>(amptrus->At(itru)) ; |
350 | TMatrixD * timeRtru = dynamic_cast<TMatrixD *>(timeRtrus->At(itru)) ; | |
9946f2fe | 351 | Int_t mtru = itru-isupermod*nTRU ; //Number of TRU in Supermodule |
33d0b833 | 352 | |
59264fa6 | 353 | //Sliding 2x2, add 2x2 amplitudes (NOT OVERLAP) |
354 | for(Int_t irow = 0 ; irow < nCellsPhi; irow += 2){ | |
355 | for(Int_t icol = 0 ; icol < nCellsEta ; icol += 2){ | |
356 | amp2 = (*amptru)(irow,icol)+(*amptru)(irow+1,icol)+ | |
357 | (*amptru)(irow,icol+1)+(*amptru)(irow+1,icol+1); | |
33d0b833 | 358 | |
0964c2e9 | 359 | //Fill matrix with added 2x2 cells for use in nxn sums |
c35bbfd4 | 360 | tru2x2(irow/2,icol/2) = amp2 ; |
59264fa6 | 361 | //Select 2x2 maximum sums to select L0 |
c35bbfd4 | 362 | if(amp2 > ampmax2(0,mtru)){ |
363 | ampmax2(0,mtru) = amp2 ; | |
364 | ampmax2(1,mtru) = irow; | |
365 | ampmax2(2,mtru) = icol; | |
59264fa6 | 366 | } |
367 | } | |
368 | } | |
369 | ||
370 | //Find most recent time in the selected 2x2 cell | |
c35bbfd4 | 371 | ampmax2(3,mtru) = 1 ; |
372 | Int_t row2 = static_cast <Int_t> (ampmax2(1,mtru)); | |
373 | Int_t col2 = static_cast <Int_t> (ampmax2(2,mtru)); | |
59264fa6 | 374 | for(Int_t i = 0; i<2; i++){ |
375 | for(Int_t j = 0; j<2; j++){ | |
376 | if((*amptru)(row2+i,col2+j) > 0 && (*timeRtru)(row2+i,col2+j)> 0){ | |
c35bbfd4 | 377 | if((*timeRtru)(row2+i,col2+j) < ampmax2(3,mtru) ) |
378 | ampmax2(3,mtru) = (*timeRtru)(row2+i,col2+j); | |
59264fa6 | 379 | } |
380 | } | |
381 | } | |
0b2ec9f7 | 382 | |
383 | //Sliding nxn, add nxn amplitudes (OVERLAP) | |
384 | if(fPatchSize > 0){ | |
385 | for(Int_t irow = 0 ; irow < nCellsPhi/2; irow++){ | |
386 | for(Int_t icol = 0 ; icol < nCellsEta/2 ; icol++){ | |
387 | ampn = 0; | |
388 | if( (irow+fPatchSize) < nCellsPhi/2 && (icol+fPatchSize) < nCellsEta/2){//Avoid exit the TRU | |
389 | for(Int_t i = 0 ; i <= fPatchSize ; i++) | |
390 | for(Int_t j = 0 ; j <= fPatchSize ; j++) | |
c35bbfd4 | 391 | ampn += tru2x2(irow+i,icol+j); |
0b2ec9f7 | 392 | //Select nxn maximum sums to select L1 |
c35bbfd4 | 393 | if(ampn > ampmaxn(0,mtru)){ |
394 | ampmaxn(0,mtru) = ampn ; | |
395 | ampmaxn(1,mtru) = irow*2; | |
396 | ampmaxn(2,mtru) = icol*2; | |
0b2ec9f7 | 397 | } |
59264fa6 | 398 | } |
399 | } | |
400 | } | |
0b2ec9f7 | 401 | |
402 | //Find most recent time in selected nxn cell | |
c35bbfd4 | 403 | ampmaxn(3,mtru) = 1 ; |
404 | Int_t rown = static_cast <Int_t> (ampmaxn(1,mtru)); | |
405 | Int_t coln = static_cast <Int_t> (ampmaxn(2,mtru)); | |
0b2ec9f7 | 406 | for(Int_t i = 0; i<4*fPatchSize; i++){ |
407 | for(Int_t j = 0; j<4*fPatchSize; j++){ | |
9946f2fe | 408 | if( (rown+i) < nCellsPhi && (coln+j) < nCellsEta){//Avoid exit the TRU |
0b2ec9f7 | 409 | if((*amptru)(rown+i,coln+j) > 0 && (*timeRtru)(rown+i,coln+j)> 0){ |
c35bbfd4 | 410 | if((*timeRtru)(rown+i,coln+j) < ampmaxn(3,mtru) ) |
411 | ampmaxn(3,mtru) = (*timeRtru)(rown+i,coln+j); | |
0b2ec9f7 | 412 | } |
413 | } | |
59264fa6 | 414 | } |
415 | } | |
416 | } | |
0b2ec9f7 | 417 | else { |
c35bbfd4 | 418 | ampmaxn(0,mtru) = ampmax2(0,mtru); |
419 | ampmaxn(1,mtru) = ampmax2(1,mtru); | |
420 | ampmaxn(2,mtru) = ampmax2(2,mtru); | |
421 | ampmaxn(3,mtru) = ampmax2(3,mtru); | |
0b2ec9f7 | 422 | } |
f0377b23 | 423 | } |
f0377b23 | 424 | } |
85c25c2e | 425 | */ |
426 | //____________________________________________________________________________ | |
427 | void AliEMCALTrigger::MakeSlidingTowers(const TClonesArray * amptrus, const TClonesArray * timeRtrus, | |
428 | const Int_t isupermod,TMatrixD &max2, TMatrixD &maxn){ | |
429 | ||
430 | // Output from module (2x2 cells from one module) | |
431 | Int_t nModulesPhi = fGeom->GetNModulesInTRUPhi(); // now 4 modules (3 div in phi) | |
432 | if(isupermod > 9) | |
433 | nModulesPhi = nModulesPhi / 2 ; // Half size SM. Not Final. | |
434 | // | |
435 | Int_t nModulesEta = fGeom->GetNModulesInTRUEta(); // now 24 modules (no division in eta) | |
436 | Int_t nTRU = fGeom->GetNTRU(); | |
437 | static int keyPrint = 0; | |
438 | if(keyPrint) printf("MakeSlidingTowers : nTRU %i nModulesPhi %i nModulesEta %i ", | |
439 | nTRU, nModulesPhi, nModulesEta ); | |
440 | ||
441 | Float_t amp2 = 0 ; | |
442 | Float_t ampn = 0 ; | |
443 | for(Int_t i = 0; i < 4; i++){ | |
444 | for(Int_t j = 0; j < nTRU; j++){ | |
445 | ampmax2(i,j) = ampmaxn(i,j) = -1; | |
446 | } | |
447 | } | |
448 | ||
449 | // Create matrix that will contain 2x2 amplitude sums | |
450 | // used to calculate the nxn sums | |
451 | TMatrixD tru2x2(nModulesPhi/2,nModulesEta/2); | |
452 | ||
453 | // Loop over all TRUS in a supermodule | |
454 | for(Int_t itru = 0 + isupermod * nTRU ; itru < (isupermod+1)*nTRU ; itru++) { | |
455 | TMatrixD * amptru = dynamic_cast<TMatrixD *>(amptrus->At(itru)) ; | |
456 | TMatrixD * timeRtru = dynamic_cast<TMatrixD *>(timeRtrus->At(itru)) ; | |
457 | Int_t mtru = itru - isupermod*nTRU ; // Number of TRU in Supermodule !! | |
458 | ||
459 | // Sliding 2x2, add 2x2 amplitudes (NOT OVERLAP) | |
460 | for(Int_t irow = 0 ; irow < nModulesPhi; irow +=2){ | |
461 | for(Int_t icol = 0 ; icol < nModulesEta ; icol +=2){ | |
462 | amp2 = (*amptru)(irow,icol) +(*amptru)(irow+1,icol)+ | |
463 | (*amptru)(irow,icol+1)+(*amptru)(irow+1,icol+1); | |
464 | ||
465 | //Fill matrix with added 2x2 towers for use in nxn sums | |
466 | tru2x2(irow/2,icol/2) = amp2 ; | |
467 | //Select 2x2 maximum sums to select L0 | |
468 | if(amp2 > ampmax2(0,mtru)){ | |
469 | ampmax2(0,mtru) = amp2 ; | |
470 | ampmax2(1,mtru) = irow; | |
471 | ampmax2(2,mtru) = icol; | |
472 | } | |
473 | } | |
474 | } | |
475 | ||
476 | ampmax2(3,mtru) = 0.; | |
477 | if(GetTimeKey()) { | |
478 | // Find most recent time in the selected 2x2 towers | |
479 | Int_t row2 = static_cast <Int_t> (ampmax2(1,mtru)); | |
480 | Int_t col2 = static_cast <Int_t> (ampmax2(2,mtru)); | |
481 | for(Int_t i = 0; i<2; i++){ | |
482 | for(Int_t j = 0; j<2; j++){ | |
483 | if((*amptru)(row2+i,col2+j) > 0 && (*timeRtru)(row2+i,col2+j)> 0){ | |
484 | if((*timeRtru)(row2+i,col2+j) > ampmax2(3,mtru) ) | |
485 | ampmax2(3,mtru) = (*timeRtru)(row2+i,col2+j); // max time | |
486 | } | |
487 | } | |
488 | } | |
489 | } | |
490 | ||
491 | //Sliding nxn, add nxn amplitudes (OVERLAP) | |
492 | if(fPatchSize > 0){ | |
493 | for(Int_t irow = 0 ; irow < nModulesPhi/2; irow++){ | |
494 | for(Int_t icol = 0 ; icol < nModulesEta/2; icol++){ | |
495 | ampn = 0; | |
496 | if( (irow+fPatchSize) < nModulesPhi/2 && (icol+fPatchSize) < nModulesEta/2){ //Avoid exit the TRU | |
497 | for(Int_t i = 0 ; i <= fPatchSize ; i++) | |
498 | for(Int_t j = 0 ; j <= fPatchSize ; j++) | |
499 | ampn += tru2x2(irow+i,icol+j); | |
500 | //Select nxn maximum sums to select L1 | |
501 | if(ampn > ampmaxn(0,mtru)){ | |
502 | ampmaxn(0,mtru) = ampn ; | |
503 | ampmaxn(1,mtru) = irow; | |
504 | ampmaxn(2,mtru) = icol; | |
505 | } | |
506 | } | |
507 | } | |
508 | } | |
509 | ||
510 | ampmaxn(3,mtru) = 0.; // Was 1 , I don't know why | |
511 | if(GetTimeKey()) { | |
512 | //Find most recent time in selected nxn cell | |
513 | Int_t rown = static_cast <Int_t> (ampmaxn(1,mtru)); | |
514 | Int_t coln = static_cast <Int_t> (ampmaxn(2,mtru)); | |
515 | for(Int_t i = 0; i<4*fPatchSize; i++){ | |
516 | for(Int_t j = 0; j<4*fPatchSize; j++){ | |
517 | if( (rown+i) < nModulesPhi && (coln+j) < nModulesEta){//Avoid exit the TRU | |
518 | if((*amptru)(rown+i,coln+j) > 0 && (*timeRtru)(rown+i,coln+j)> 0){ | |
519 | if((*timeRtru)(rown+i,coln+j) > ampmaxn(3,mtru) ) | |
520 | ampmaxn(3,mtru) = (*timeRtru)(rown+i,coln+j); // max time | |
521 | } | |
522 | } | |
523 | } | |
524 | } | |
525 | } | |
526 | } else { // copy 2x2 to nxn | |
527 | ampmaxn(0,mtru) = ampmax2(0,mtru); | |
528 | ampmaxn(1,mtru) = ampmax2(1,mtru); | |
529 | ampmaxn(2,mtru) = ampmax2(2,mtru); | |
530 | ampmaxn(3,mtru) = ampmax2(3,mtru); | |
531 | } | |
532 | } | |
533 | if(keyPrint) printf(" : MakeSlidingTowers -OUt \n"); | |
534 | } | |
f0377b23 | 535 | |
536 | //____________________________________________________________________________ | |
537 | void AliEMCALTrigger::Print(const Option_t * opt) const | |
538 | { | |
539 | ||
540 | //Prints main parameters | |
541 | ||
542 | if(! opt) | |
543 | return; | |
544 | AliTriggerInput* in = 0x0 ; | |
85c25c2e | 545 | printf( " fSimulation %i (input option) : #digits %i\n", fSimulation, fDigitsList->GetEntries()); |
546 | printf( " fTimeKey %i \n ", fTimeKey); | |
59264fa6 | 547 | |
548 | printf( " Maximum Amplitude after Sliding Cell, \n") ; | |
549 | printf( " -2x2 cells sum (not overlapped): %10.2f, in Super Module %d\n", | |
550 | f2x2MaxAmp,f2x2SM) ; | |
85c25c2e | 551 | printf( " -2x2 from row %d to row %d and from column %d to column %d\n", f2x2ModulePhi, f2x2ModulePhi+2, f2x2ModuleEta, f2x2ModuleEta+2) ; |
0964c2e9 | 552 | printf( " -2x2 Isolation Patch %d x %d, Amplitude out of 2x2 patch is %f, threshold %f, Isolated? %d \n", |
553 | 2*fIsolPatchSize+2, 2*fIsolPatchSize+2, f2x2AmpOutOfPatch, f2x2AmpOutOfPatchThres,static_cast<Int_t> (fIs2x2Isol)) ; | |
0b2ec9f7 | 554 | if(fPatchSize > 0){ |
0964c2e9 | 555 | printf( " Patch Size, n x n: %d x %d cells\n",2*(fPatchSize+1), 2*(fPatchSize+1)); |
0b2ec9f7 | 556 | printf( " -nxn cells sum (overlapped) : %10.2f, in Super Module %d\n", |
557 | fnxnMaxAmp,fnxnSM) ; | |
85c25c2e | 558 | printf( " -nxn from row %d to row %d and from column %d to column %d\n", fnxnModulePhi, fnxnModulePhi+4*fPatchSize, fnxnModuleEta, fnxnModuleEta+4*fPatchSize) ; |
0964c2e9 | 559 | printf( " -nxn Isolation Patch %d x %d, Amplitude out of nxn patch is %f, threshold %f, Isolated? %d \n", |
560 | 4*fIsolPatchSize+2*(fPatchSize+1),4*fIsolPatchSize+2*(fPatchSize+1) , fnxnAmpOutOfPatch, fnxnAmpOutOfPatchThres,static_cast<Int_t> (fIsnxnIsol) ) ; | |
0b2ec9f7 | 561 | } |
0964c2e9 | 562 | |
563 | printf( " Isolate in SuperModule? %d\n", | |
564 | fIsolateInSuperModule) ; | |
565 | ||
59264fa6 | 566 | printf( " Threshold for LO %10.2f\n", |
567 | fL0Threshold) ; | |
568 | in = (AliTriggerInput*)fInputs.FindObject( "EMCAL_L0" ); | |
f0377b23 | 569 | if(in->GetValue()) |
59264fa6 | 570 | printf( " *** EMCAL LO is set ***\n") ; |
f0377b23 | 571 | |
85c25c2e | 572 | printf( " Gamma Low Pt Threshold for L1 %10.2f\n", |
573 | fL1GammaLowPtThreshold) ; | |
574 | in = (AliTriggerInput*)fInputs.FindObject( "EMCAL_GammaLPt_L1" ); | |
f0377b23 | 575 | if(in->GetValue()) |
85c25c2e | 576 | printf( " *** EMCAL Gamma Low Pt for L1 is set ***\n") ; |
f0377b23 | 577 | |
85c25c2e | 578 | printf( " Gamma Medium Pt Threshold for L1 %10.2f\n", |
579 | fL1GammaMediumPtThreshold) ; | |
580 | in = (AliTriggerInput*) fInputs.FindObject( "EMCAL_GammaMPt_L1" ); | |
f0377b23 | 581 | if(in->GetValue()) |
85c25c2e | 582 | printf( " *** EMCAL Gamma Medium Pt for L1 is set ***\n") ; |
f0377b23 | 583 | |
85c25c2e | 584 | printf( " Gamma High Pt Threshold for L1 %10.2f\n", |
585 | fL1GammaHighPtThreshold) ; | |
586 | in = (AliTriggerInput*) fInputs.FindObject( "EMCAL_GammaHPt_L1" ); | |
f0377b23 | 587 | if(in->GetValue()) |
85c25c2e | 588 | printf( " *** EMCAL Gamma High Pt for L1 is set ***\n") ; |
f0377b23 | 589 | |
590 | } | |
591 | ||
592 | //____________________________________________________________________________ | |
0964c2e9 | 593 | void AliEMCALTrigger::SetTriggers(const TClonesArray * ampmatrix,const Int_t iSM, |
c35bbfd4 | 594 | const TMatrixD &max2, |
9946f2fe | 595 | const TMatrixD &maxn) |
f0377b23 | 596 | { |
0b2ec9f7 | 597 | //Checks the 2x2 and nxn maximum amplitude per each TRU and |
59264fa6 | 598 | //compares with the different L0 and L1 triggers thresholds |
599 | Float_t max2[] = {-1,-1,-1,-1} ; | |
0b2ec9f7 | 600 | Float_t maxn[] = {-1,-1,-1,-1} ; |
0964c2e9 | 601 | Int_t mtru2 = -1 ; |
602 | Int_t mtrun = -1 ; | |
f0377b23 | 603 | |
9946f2fe | 604 | Int_t nTRU = fGeom->GetNTRU(); |
605 | ||
59264fa6 | 606 | //Find maximum summed amplitude of all the TRU |
607 | //in a Super Module | |
9946f2fe | 608 | for(Int_t i = 0 ; i < nTRU ; i++){ |
c35bbfd4 | 609 | if(max2[0] < ampmax2(0,i) ){ |
610 | max2[0] = ampmax2(0,i) ; // 2x2 summed max amplitude | |
611 | max2[1] = ampmax2(1,i) ; // corresponding phi position in TRU | |
612 | max2[2] = ampmax2(2,i) ; // corresponding eta position in TRU | |
613 | max2[3] = ampmax2(3,i) ; // corresponding most recent time | |
0964c2e9 | 614 | mtru2 = i ; |
59264fa6 | 615 | } |
c35bbfd4 | 616 | if(maxn[0] < ampmaxn(0,i) ){ |
617 | maxn[0] = ampmaxn(0,i) ; // nxn summed max amplitude | |
618 | maxn[1] = ampmaxn(1,i) ; // corresponding phi position in TRU | |
619 | maxn[2] = ampmaxn(2,i) ; // corresponding eta position in TRU | |
620 | maxn[3] = ampmaxn(3,i) ; // corresponding most recent time | |
0964c2e9 | 621 | mtrun = i ; |
59264fa6 | 622 | } |
623 | } | |
624 | ||
625 | //--------Set max amplitude if larger than in other Super Modules------------ | |
626 | Float_t maxtimeR2 = -1 ; | |
0b2ec9f7 | 627 | Float_t maxtimeRn = -1 ; |
133abe1f | 628 | static AliEMCALRawUtils rawUtil; |
629 | Int_t nTimeBins = rawUtil.GetRawFormatTimeBins() ; | |
59264fa6 | 630 | |
631 | //Set max of 2x2 amplitudes and select L0 trigger | |
632 | if(max2[0] > f2x2MaxAmp ){ | |
85c25c2e | 633 | // if(max2[0] > 5) printf(" L0 : iSM %i: max2[0] %5.0f : max2[3] %5.0f (maxtimeR2) \n", |
634 | // iSM, max2[0], max2[3]); | |
59264fa6 | 635 | f2x2MaxAmp = max2[0] ; |
636 | f2x2SM = iSM ; | |
637 | maxtimeR2 = max2[3] ; | |
85c25c2e | 638 | fGeom->GetModulePhiEtaIndexInSModuleFromTRUIndex(mtru2, |
59264fa6 | 639 | static_cast<Int_t>(max2[1]), |
640 | static_cast<Int_t>(max2[2]), | |
85c25c2e | 641 | f2x2ModulePhi,f2x2ModuleEta); |
59264fa6 | 642 | |
0964c2e9 | 643 | //Isolated patch? |
644 | if(fIsolateInSuperModule) | |
85c25c2e | 645 | fIs2x2Isol = IsPatchIsolated(0, ampmatrix, iSM, mtru2, f2x2MaxAmp, f2x2ModulePhi,f2x2ModuleEta) ; |
0964c2e9 | 646 | else |
647 | fIs2x2Isol = IsPatchIsolated(0, ampmatrix, iSM, mtru2, f2x2MaxAmp, static_cast<Int_t>(max2[1]), static_cast<Int_t>(max2[2])) ; | |
648 | ||
85c25c2e | 649 | if(GetTimeKey()) { |
59264fa6 | 650 | //Transform digit amplitude in Raw Samples |
85c25c2e | 651 | if (fADCValuesLow2x2 == 0) { |
652 | fADCValuesLow2x2 = new Int_t[nTimeBins]; | |
653 | fADCValuesHigh2x2 = new Int_t[nTimeBins]; | |
654 | } | |
655 | //printf(" maxtimeR2 %12.5e (1)\n", maxtimeR2); | |
656 | rawUtil.RawSampledResponse(maxtimeR2 * AliEMCALRawUtils::GetRawFormatTimeBin(), | |
657 | f2x2MaxAmp, fADCValuesHigh2x2, fADCValuesLow2x2) ; | |
59264fa6 | 658 | |
85c25c2e | 659 | // Set Trigger Inputs, compare ADC time bins until threshold is attained |
660 | // Set L0 | |
661 | for(Int_t i = 0 ; i < nTimeBins ; i++){ | |
662 | // printf(" fADCValuesHigh2x2[%i] %i : %i \n", i, fADCValuesHigh2x2[i], fADCValuesLow2x2[i]); | |
663 | if(fADCValuesHigh2x2[i] >= fL0Threshold || fADCValuesLow2x2[i] >= fL0Threshold){ | |
664 | SetInput("EMCAL_L0") ; | |
665 | break; | |
666 | } | |
667 | } | |
668 | } else { | |
669 | // Nov 5 - no analysis of time information | |
670 | if(f2x2MaxAmp >= fL0Threshold) { // should add the low amp too | |
671 | SetInput("EMCAL_L0"); | |
59264fa6 | 672 | } |
673 | } | |
f0377b23 | 674 | } |
59264fa6 | 675 | |
0b2ec9f7 | 676 | //------------Set max of nxn amplitudes and select L1 trigger--------- |
677 | if(maxn[0] > fnxnMaxAmp ){ | |
678 | fnxnMaxAmp = maxn[0] ; | |
679 | fnxnSM = iSM ; | |
680 | maxtimeRn = maxn[3] ; | |
85c25c2e | 681 | fGeom->GetModulePhiEtaIndexInSModuleFromTRUIndex(mtrun, |
0b2ec9f7 | 682 | static_cast<Int_t>(maxn[1]), |
683 | static_cast<Int_t>(maxn[2]), | |
85c25c2e | 684 | fnxnModulePhi,fnxnModuleEta) ; |
0964c2e9 | 685 | |
686 | //Isolated patch? | |
687 | if(fIsolateInSuperModule) | |
85c25c2e | 688 | fIsnxnIsol = IsPatchIsolated(1, ampmatrix, iSM, mtrun, fnxnMaxAmp, fnxnModulePhi, fnxnModuleEta) ; |
0964c2e9 | 689 | else |
690 | fIsnxnIsol = IsPatchIsolated(1, ampmatrix, iSM, mtrun, fnxnMaxAmp, static_cast<Int_t>(maxn[1]), static_cast<Int_t>(maxn[2])) ; | |
691 | ||
85c25c2e | 692 | if(GetTimeKey()) { |
59264fa6 | 693 | //Transform digit amplitude in Raw Samples |
85c25c2e | 694 | if (fADCValuesLownxn == 0) { |
695 | fADCValuesHighnxn = new Int_t[nTimeBins]; | |
696 | fADCValuesLownxn = new Int_t[nTimeBins]; | |
697 | } | |
698 | rawUtil.RawSampledResponse(maxtimeRn * AliEMCALRawUtils::GetRawFormatTimeBin(), | |
699 | fnxnMaxAmp, fADCValuesHighnxn, fADCValuesLownxn) ; | |
59264fa6 | 700 | |
701 | //Set Trigger Inputs, compare ADC time bins until threshold is attained | |
702 | //SetL1 Low | |
85c25c2e | 703 | for(Int_t i = 0 ; i < nTimeBins ; i++){ |
704 | if(fADCValuesHighnxn[i] >= fL1GammaLowPtThreshold || fADCValuesLownxn[i] >= fL1GammaLowPtThreshold){ | |
705 | SetInput("EMCAL_GammaLPt_L1") ; | |
706 | break; | |
707 | } | |
59264fa6 | 708 | } |
59264fa6 | 709 | |
710 | //SetL1 Medium | |
85c25c2e | 711 | for(Int_t i = 0 ; i < nTimeBins ; i++){ |
712 | if(fADCValuesHighnxn[i] >= fL1GammaMediumPtThreshold || fADCValuesLownxn[i] >= fL1GammaMediumPtThreshold){ | |
713 | SetInput("EMCAL_GammaMPt_L1") ; | |
714 | break; | |
715 | } | |
59264fa6 | 716 | } |
59264fa6 | 717 | |
718 | //SetL1 High | |
85c25c2e | 719 | for(Int_t i = 0 ; i < nTimeBins ; i++){ |
720 | if(fADCValuesHighnxn[i] >= fL1GammaHighPtThreshold || fADCValuesLownxn[i] >= fL1GammaHighPtThreshold){ | |
721 | SetInput("EMCAL_GammaHPt_L1") ; | |
722 | break; | |
723 | } | |
724 | } | |
725 | } else { | |
726 | // Nov 5 - no analysis of time information | |
727 | if(fnxnMaxAmp >= fL1GammaLowPtThreshold) { // should add the low amp too | |
728 | SetInput("EMCAL_GammaLPt_L1") ; //SetL1 Low | |
729 | } | |
730 | if(fnxnMaxAmp >= fL1GammaMediumPtThreshold) { // should add the low amp too | |
731 | SetInput("EMCAL_GammaMPt_L1") ; //SetL1 Medium | |
732 | } | |
733 | if(fnxnMaxAmp >= fL1GammaHighPtThreshold) { // should add the low amp too | |
734 | SetInput("EMCAL_GammaHPt_L1") ; //SetL1 High | |
59264fa6 | 735 | } |
736 | } | |
85c25c2e | 737 | } |
59264fa6 | 738 | } |
f0377b23 | 739 | |
c35bbfd4 | 740 | //____________________________________________________________________________ |
9946f2fe | 741 | void AliEMCALTrigger::FillTRU(const TClonesArray * digits, TClonesArray * ampmatrix, TClonesArray * ampmatrixsmod, TClonesArray * timeRmatrix) { |
c35bbfd4 | 742 | |
743 | // Orders digits ampitudes list in fNTRU TRUs (384 cells) per supermodule. | |
744 | // Each TRU is a TMatrixD, and they are kept in TClonesArrays. The number of | |
745 | // TRU in phi is fNTRUPhi, and the number of TRU in eta is fNTRUEta. | |
746 | // Last 2 modules are half size in Phi, I considered that the number of TRU | |
747 | // is maintained for the last modules but decision not taken. If different, | |
748 | // then this must be changed. Also fill a matrix with all amplitudes in supermodule for isolation studies. | |
749 | ||
85c25c2e | 750 | // Initilize and declare variables |
751 | // List of TRU matrices initialized to 0. | |
752 | // printf("<I> AliEMCALTrigger::FillTRU() started : # digits %i\n", digits->GetEntriesFast()); | |
753 | ||
754 | // Nov 2, 2007. | |
755 | // One input per EMCAL module so size of matrix is reduced by 4 (2x2 division case) | |
756 | ||
757 | Int_t nPhi = fGeom->GetNPhi(); | |
758 | Int_t nZ = fGeom->GetNZ(); | |
759 | Int_t nTRU = fGeom->GetNTRU(); | |
760 | // Int_t nTRUPhi = fGeom->GetNTRUPhi(); | |
761 | Int_t nModulesPhi = fGeom->GetNModulesInTRUPhi(); | |
762 | Int_t nModulesPhi2 = fGeom->GetNModulesInTRUPhi(); | |
763 | Int_t nModulesEta = fGeom->GetNModulesInTRUEta(); | |
764 | // printf("<I> AliEMCALTrigger::FillTRU() nTRU %i nTRUPhi %i : nModulesPhi %i nModulesEta %i \n", | |
765 | // nTRU, nTRUPhi, nModulesPhi, nModulesEta); | |
c35bbfd4 | 766 | |
767 | Int_t id = -1; | |
768 | Float_t amp = -1; | |
769 | Float_t timeR = -1; | |
770 | Int_t iSupMod = -1; | |
771 | Int_t nModule = -1; | |
772 | Int_t nIphi = -1; | |
773 | Int_t nIeta = -1; | |
774 | Int_t iphi = -1; | |
775 | Int_t ieta = -1; | |
85c25c2e | 776 | // iphim, ietam - module indexes in SM |
777 | Int_t iphim = -1; | |
778 | Int_t ietam = -1; | |
c35bbfd4 | 779 | |
780 | //List of TRU matrices initialized to 0. | |
9946f2fe | 781 | Int_t nSup = fGeom->GetNumberOfSuperModules(); |
782 | for(Int_t k = 0; k < nTRU*nSup; k++){ | |
85c25c2e | 783 | TMatrixD amptrus(nModulesPhi,nModulesEta) ; |
784 | TMatrixD timeRtrus(nModulesPhi,nModulesEta) ; | |
c35bbfd4 | 785 | // Do we need to initialise? I think TMatrixD does it by itself... |
85c25c2e | 786 | for(Int_t i = 0; i < nModulesPhi; i++){ |
787 | for(Int_t j = 0; j < nModulesEta; j++){ | |
c35bbfd4 | 788 | amptrus(i,j) = 0.0; |
789 | timeRtrus(i,j) = 0.0; | |
790 | } | |
791 | } | |
792 | new((*ampmatrix)[k]) TMatrixD(amptrus) ; | |
793 | new((*timeRmatrix)[k]) TMatrixD(timeRtrus) ; | |
794 | } | |
795 | ||
85c25c2e | 796 | // List of Modules matrices initialized to 0. |
c35bbfd4 | 797 | for(Int_t k = 0; k < nSup ; k++){ |
85c25c2e | 798 | int mphi = nPhi; |
799 | // if(nSup>9) mphi = nPhi/2; // the same size | |
800 | TMatrixD ampsmods( mphi, nZ); | |
801 | for(Int_t i = 0; i < mphi; i++){ | |
802 | for(Int_t j = 0; j < nZ; j++){ | |
c35bbfd4 | 803 | ampsmods(i,j) = 0.0; |
804 | } | |
805 | } | |
85c25c2e | 806 | new((*ampmatrixsmod)[k]) TMatrixD(ampsmods) ; |
c35bbfd4 | 807 | } |
808 | ||
809 | AliEMCALDigit * dig ; | |
810 | ||
811 | //Digits loop to fill TRU matrices with amplitudes. | |
812 | for(Int_t idig = 0 ; idig < digits->GetEntriesFast() ; idig++){ | |
813 | ||
814 | dig = dynamic_cast<AliEMCALDigit *>(digits->At(idig)) ; | |
85c25c2e | 815 | amp = Float_t(dig->GetAmp()); // Energy of the digit (arbitrary units) |
816 | id = dig->GetId() ; // Id label of the cell | |
817 | timeR = dig->GetTimeR() ; // Earliest time of the digit | |
818 | if(amp<=0.0) printf("<I> AliEMCALTrigger::FillTRU : id %i amp %f \n", id, amp); | |
819 | // printf(" FILLTRU : timeR %10.5e time %10.5e : amp %10.5e \n", timeR, dig->GetTime(), amp); | |
820 | // Get eta and phi cell position in supermodule | |
9946f2fe | 821 | Bool_t bCell = fGeom->GetCellIndex(id, iSupMod, nModule, nIphi, nIeta) ; |
c35bbfd4 | 822 | if(!bCell) |
85c25c2e | 823 | Error("FillTRU","%i Wrong cell id number %i ", idig, id) ; |
c35bbfd4 | 824 | |
9946f2fe | 825 | fGeom->GetCellPhiEtaIndexInSModule(iSupMod,nModule,nIphi, nIeta,iphi,ieta); |
85c25c2e | 826 | // iphim, ietam - module indexes in SM |
827 | fGeom->GetModuleIndexesFromCellIndexesInSModule(iSupMod,iphi,ieta, iphim, ietam, nModule); | |
828 | //if(iSupMod >9) | |
829 | //printf("iSupMod %i nModule %i iphi %i ieta %i iphim %i ietam %i \n", | |
830 | //iSupMod,nModule, iphi, ieta, iphim, ietam); | |
c35bbfd4 | 831 | |
85c25c2e | 832 | // Check to which TRU in the supermodule belongs the cell. |
833 | // Supermodules are divided in a TRU matrix of dimension | |
834 | // (fNTRUPhi,fNTRUEta). | |
835 | // Each TRU is a cell matrix of dimension (nModulesPhi,nModulesEta) | |
c35bbfd4 | 836 | |
85c25c2e | 837 | // First calculate the row and column in the supermodule |
838 | // of the TRU to which the cell belongs. | |
839 | Int_t row = iphim / nModulesPhi; | |
840 | Int_t col = ietam / nModulesEta; | |
c35bbfd4 | 841 | //Calculate label number of the TRU |
85c25c2e | 842 | Int_t itru = fGeom->GetAbsTRUNumberFromNumberInSm(row, col, iSupMod); |
c35bbfd4 | 843 | |
844 | //Fill TRU matrix with cell values | |
845 | TMatrixD * amptrus = dynamic_cast<TMatrixD *>(ampmatrix->At(itru)) ; | |
846 | TMatrixD * timeRtrus = dynamic_cast<TMatrixD *>(timeRmatrix->At(itru)) ; | |
847 | ||
85c25c2e | 848 | //Calculate row and column of the module inside the TRU with number itru |
849 | Int_t irow = iphim - row * nModulesPhi; | |
c35bbfd4 | 850 | if(iSupMod > 9) |
85c25c2e | 851 | irow = iphim - row * nModulesPhi2; // size of matrix the same |
852 | Int_t icol = ietam - col * nModulesEta; | |
c35bbfd4 | 853 | |
85c25c2e | 854 | (*amptrus)(irow,icol) += amp ; |
855 | if((*timeRtrus)(irow,icol) <0.0 || (*timeRtrus)(irow,icol) <= timeR){ // ?? | |
856 | (*timeRtrus)(irow,icol) = timeR ; | |
857 | } | |
858 | //printf(" ieta %i iphi %i iSM %i || col %i row %i : itru %i -> amp %f\n", | |
859 | // ieta, iphi, iSupMod, col, row, itru, amp); | |
c35bbfd4 | 860 | //####################SUPERMODULE MATRIX ################## |
861 | TMatrixD * ampsmods = dynamic_cast<TMatrixD *>(ampmatrixsmod->At(iSupMod)) ; | |
85c25c2e | 862 | (*ampsmods)(iphim,ietam) += amp ; |
863 | // printf(" id %i iphim %i ietam %i SM %i : irow %i icol %i itru %i : amp %6.0f\n", | |
864 | //id, iphim, ietam, iSupMod, irow, icol, itru, amp); | |
c35bbfd4 | 865 | } |
85c25c2e | 866 | //assert(0); |
867 | //printf("<I> AliEMCALTrigger::FillTRU() is ended \n"); | |
c35bbfd4 | 868 | } |
59264fa6 | 869 | //____________________________________________________________________________ |
870 | void AliEMCALTrigger::Trigger() | |
871 | { | |
85c25c2e | 872 | TH1::AddDirectory(0); |
59264fa6 | 873 | //Main Method to select triggers. |
c787fb51 | 874 | AliRunLoader *runLoader = AliRunLoader::GetRunLoader(); |
85c25c2e | 875 | AliEMCALLoader *emcalLoader = 0; |
876 | if(runLoader) { | |
877 | emcalLoader = dynamic_cast<AliEMCALLoader*>(runLoader->GetDetectorLoader("EMCAL")); | |
878 | } | |
0964c2e9 | 879 | |
59264fa6 | 880 | //Load EMCAL Geometry |
85c25c2e | 881 | if (runLoader && runLoader->GetAliRun() && runLoader->GetAliRun()->GetDetector("EMCAL")) |
9946f2fe | 882 | fGeom = dynamic_cast<AliEMCAL*>(runLoader->GetAliRun()->GetDetector("EMCAL"))->GetGeometry(); |
0964c2e9 | 883 | |
384c0bba | 884 | if (fGeom == 0) |
885 | fGeom = AliEMCALGeometry::GetInstance(AliEMCALGeometry::GetDefaultGeometryName()); | |
886 | ||
9946f2fe | 887 | if (fGeom==0) |
59264fa6 | 888 | AliFatal("Did not get geometry from EMCALLoader"); |
0964c2e9 | 889 | |
59264fa6 | 890 | //Define parameters |
9946f2fe | 891 | Int_t nSuperModules = fGeom->GetNumberOfSuperModules() ; //12 SM in EMCAL |
85c25c2e | 892 | Int_t nTRU = fGeom->GetNTRU(); // 3 TRU per super module |
59264fa6 | 893 | |
894 | //Intialize data members each time the trigger is called in event loop | |
85c25c2e | 895 | f2x2MaxAmp = -1; f2x2ModulePhi = -1; f2x2ModuleEta = -1; |
896 | fnxnMaxAmp = -1; fnxnModulePhi = -1; fnxnModuleEta = -1; | |
59264fa6 | 897 | |
85c25c2e | 898 | // Take the digits list if simulation |
899 | if(fSimulation && runLoader && emcalLoader){ // works than run seperate macros | |
c787fb51 | 900 | runLoader->LoadDigits("EMCAL"); |
59264fa6 | 901 | fDigitsList = emcalLoader->Digits() ; |
85c25c2e | 902 | runLoader->LoadSDigits("EMCAL"); |
59264fa6 | 903 | } |
85c25c2e | 904 | // Digits list should be set by method SetDigitsList(TClonesArray * digits) |
59264fa6 | 905 | if(!fDigitsList) |
906 | AliFatal("Digits not found !") ; | |
907 | ||
908 | //Take the digits list | |
909 | ||
85c25c2e | 910 | // Delete old if unzero |
911 | if(fAmpTrus) {fAmpTrus->Delete(); delete fAmpTrus;} | |
912 | if(fTimeRtrus) {fTimeRtrus->Delete(); delete fTimeRtrus;} | |
913 | if(fAmpSMods) {fAmpSMods->Delete(); delete fAmpSMods;} | |
914 | // Fill TRU and SM matrix | |
915 | fAmpTrus = new TClonesArray("TMatrixD",nTRU); | |
916 | fAmpTrus->SetName("AmpTrus"); | |
917 | fTimeRtrus = new TClonesArray("TMatrixD",nTRU); | |
918 | fTimeRtrus->SetName("TimeRtrus"); | |
919 | fAmpSMods = new TClonesArray("TMatrixD",nSuperModules); | |
920 | fAmpSMods->SetName("AmpSMods"); | |
0964c2e9 | 921 | |
85c25c2e | 922 | FillTRU(fDigitsList, fAmpTrus, fAmpSMods, fTimeRtrus); |
923 | ||
924 | // Jet staff - only one case, no fredom here | |
925 | if(fGeom->GetNEtaSubOfTRU() == 6) { | |
926 | if(fAmpJetMatrix) {delete fAmpJetMatrix; fAmpJetMatrix=0;} | |
927 | if(fJetMatrixE) {delete fJetMatrixE; fJetMatrixE=0;} | |
928 | ||
929 | fAmpJetMatrix = new TMatrixD(17,12); // 17-phi(row), 12-eta(col) | |
930 | fJetMatrixE = new TH2F("fJetMatrixE"," E of max patch in (#phi,#eta)", | |
931 | 17, 80.*TMath::DegToRad(), (180.+20.*2/3.)*TMath::DegToRad(), 12, -0.7, 0.7); | |
932 | for(Int_t row=0; row<fAmpJetMatrix->GetNrows(); row++) { | |
933 | for(Int_t col=0; col<fAmpJetMatrix->GetNcols(); col++) { | |
934 | (*fAmpJetMatrix)(row,col) = 0.; | |
935 | } | |
936 | } | |
937 | FillJetMatrixFromSMs(fAmpSMods, fAmpJetMatrix, fGeom); | |
938 | } | |
939 | if(!CheckConsistentOfMatrixes()) assert(0); | |
59264fa6 | 940 | |
85c25c2e | 941 | // Do Tower Sliding and select Trigger |
942 | // Initialize varible that will contain maximum amplitudes and | |
943 | // its corresponding tower position in eta and phi, and time. | |
944 | TMatrixD ampmax2(4,nTRU) ; // 0-max amp, 1-irow, 2-icol, 3-timeR | |
9946f2fe | 945 | TMatrixD ampmaxn(4,nTRU) ; |
0964c2e9 | 946 | |
33d0b833 | 947 | for(Int_t iSM = 0 ; iSM < nSuperModules ; iSM++) { |
0b2ec9f7 | 948 | //Do 2x2 and nxn sums, select maximums. |
85c25c2e | 949 | |
950 | MakeSlidingTowers(fAmpTrus, fTimeRtrus, iSM, ampmax2, ampmaxn); | |
0964c2e9 | 951 | |
85c25c2e | 952 | // Set the trigger |
953 | if(fIsolateInSuperModule) // here some discripency between tru and SM | |
954 | SetTriggers(fAmpSMods,iSM,ampmax2,ampmaxn) ; | |
0964c2e9 | 955 | if(!fIsolateInSuperModule) |
85c25c2e | 956 | SetTriggers(fAmpTrus,iSM,ampmax2,ampmaxn) ; |
59264fa6 | 957 | } |
0964c2e9 | 958 | |
85c25c2e | 959 | // Do patch sliding and select Jet Trigger |
960 | // 0-max amp-meanFromVZERO(if), 1-irow, 2-icol, 3-timeR, | |
961 | // 4-max amp , 5-meanFromVZERO (Nov 25, 2007) | |
962 | // fAmpJetMax(6,1) | |
963 | MakeSlidingPatch((*fAmpJetMatrix), fNJetPatchPhi, fAmpJetMax); // no timing information here | |
964 | ||
0964c2e9 | 965 | //Print(); |
85c25c2e | 966 | // fDigitsList = 0; |
967 | } | |
968 | ||
969 | void AliEMCALTrigger::GetTriggerInfo(TArrayF &triggerPosition, TArrayF &triggerAmplitudes) | |
970 | { | |
971 | // Template - should be defined; Nov 5, 2007 | |
972 | triggerPosition[0] = 0.; | |
973 | triggerAmplitudes[0] = 0.; | |
974 | } | |
975 | ||
976 | void AliEMCALTrigger::FillJetMatrixFromSMs(TClonesArray *ampmatrixsmod, TMatrixD* jetMat, AliEMCALGeometry *g) | |
977 | { | |
978 | // Nov 5, 2007 | |
979 | // Fill matrix for jet trigger from SM matrixes of modules | |
980 | // | |
981 | static int keyPrint = 0; | |
982 | ||
983 | if(ampmatrixsmod==0 || jetMat==0 || g==0) return; | |
984 | Double_t amp = 0.0, ampSum=0.0; | |
0964c2e9 | 985 | |
85c25c2e | 986 | Int_t nEtaModSum = g->GetNZ() / g->GetNEtaSubOfTRU(); // should be 4 |
987 | Int_t nPhiModSum = g->GetNPhi() / g->GetNTRUPhi(); // should be 4 | |
988 | ||
989 | if(keyPrint) printf("%s",Form(" AliEMCALTrigger::FillJetMatrixFromSMs | nEtaModSum %i : nPhiModSum %i \n", | |
990 | nEtaModSum, nPhiModSum)); | |
991 | Int_t jrow=0, jcol=0; // indexes of jet matrix | |
992 | Int_t nEtaSM=0, nPhiSM=0; | |
993 | for(Int_t iSM=0; iSM<ampmatrixsmod->GetEntries(); iSM++) { | |
994 | TMatrixD * ampsmods = dynamic_cast<TMatrixD *>(ampmatrixsmod->At(iSM)); | |
995 | Int_t nrow = ampsmods->GetNrows(); | |
996 | Int_t ncol = ampsmods->GetNcols(); | |
997 | //printf("%s",Form(" ######## SM %i : nrow %i : ncol %i ##### \n", iSM, nrow, ncol)); | |
998 | for(Int_t row=0; row<nrow; row++) { | |
999 | for(Int_t col=0; col<ncol; col++) { | |
1000 | amp = (*ampsmods)(row,col); | |
1001 | nPhiSM = iSM / 2; | |
1002 | nEtaSM = iSM % 2; | |
1003 | if (amp>0.0) { | |
1004 | if(keyPrint) printf("%s",Form(" ** nPhiSm %i : nEtaSM %i : row %2.2i : col %2.2i -> ", | |
1005 | nPhiSM, nEtaSM, row, col)); | |
1006 | if(nEtaSM == 0) { // positive Z | |
1007 | jrow = 3*nPhiSM + row/nPhiModSum; | |
1008 | jcol = 6 + col / nEtaModSum; | |
1009 | } else { // negative Z | |
1010 | if(iSM<=9) jrow = 3*nPhiSM + 2 - row/nPhiModSum; | |
1011 | else jrow = 3*nPhiSM + 1 - row/nPhiModSum; // half size | |
1012 | jcol = 5 - col / nEtaModSum; | |
1013 | } | |
1014 | if(keyPrint) printf("%s",Form(" jrow %2.2i : jcol %2.2i : amp %f (jetMat) \n", jrow, jcol, amp)); | |
1015 | ||
1016 | (*jetMat)(jrow,jcol) += amp; | |
1017 | ampSum += amp; // For controling | |
1018 | } else if(amp<0.0) { | |
1019 | printf("%s",Form(" jrow %2.2i : jcol %2.2i : amp %f (jetMat: amp<0) \n", jrow, jcol, amp)); | |
1020 | assert(0); | |
1021 | } | |
1022 | } | |
1023 | } | |
1024 | } // cycle on SM | |
1025 | if(ampSum <= 0.0) Warning("FillJetMatrixFromSMs","ampSum %f (<=0.0) ", ampSum); | |
1026 | } | |
1027 | ||
1028 | void AliEMCALTrigger::MakeSlidingPatch(const TMatrixD &jm, const Int_t nPatchSize, TMatrixD &JetMax) | |
1029 | { | |
1030 | // Sliding patch : nPatchSize x nPatchSize (OVERLAP) | |
1031 | static int keyPrint = 0; | |
1032 | if(keyPrint) printf(" AliEMCALTrigger::MakeSlidingPatch() was started \n"); | |
1033 | Double_t ampCur = 0.0, e=0.0; | |
1034 | ampJetMax(0,0) = 0.0; | |
1035 | ampJetMax(3,0) = 0.0; // unused now | |
1036 | ampJetMax(4,0) = ampJetMax(5,0) = 0.0; | |
1037 | for(Int_t row=0; row<fAmpJetMatrix->GetNrows(); row ++) { | |
1038 | for(Int_t col=0; col<fAmpJetMatrix->GetNcols(); col++) { | |
1039 | ampCur = 0.; | |
1040 | // check on patch size | |
1041 | if( (row+nPatchSize-1) < fAmpJetMatrix->GetNrows() && (col+nPatchSize-1) < fAmpJetMatrix->GetNcols()){ | |
1042 | for(Int_t i = 0 ; i < nPatchSize ; i++) { | |
1043 | for(Int_t j = 0 ; j < nPatchSize ; j++) { | |
1044 | ampCur += jm(row+i, col+j); | |
1045 | } | |
1046 | } // end cycle on patch | |
1047 | if(ampCur > ampJetMax(0,0)){ | |
1048 | ampJetMax(0,0) = ampCur; | |
1049 | ampJetMax(1,0) = row; | |
1050 | ampJetMax(2,0) = col; | |
1051 | } | |
1052 | } // check on patch size | |
1053 | } | |
1054 | } | |
1055 | if(keyPrint) printf(" ampJetMax %i row %2i->%2i col %2i->%2i \n", | |
1056 | Int_t(ampJetMax(0,0)), Int_t(ampJetMax(1,0)), Int_t(ampJetMax(1,0))+nPatchSize-1, | |
1057 | Int_t(ampJetMax(2,0)), Int_t(ampJetMax(2,0))+nPatchSize-1); | |
1058 | ||
1059 | Double_t eCorrJetMatrix=0.0; | |
1060 | if(fVZER0Mult > 0.0) { | |
1061 | // Correct patch energy (adc) and jet patch matrix energy | |
1062 | Double_t meanAmpBG = GetMeanEmcalPatchEnergy(Int_t(fVZER0Mult), nPatchSize)/0.0153; | |
1063 | ampJetMax(4,0) = ampJetMax(0,0); | |
1064 | ampJetMax(5,0) = meanAmpBG; | |
1065 | ||
1066 | Double_t eCorr = ampJetMax(0,0) - meanAmpBG; | |
1067 | printf(" ampJetMax(0,0) %f meanAmpBG %f eCorr %f : ampJetMax(4,0) %f \n", | |
1068 | ampJetMax(0,0), meanAmpBG, eCorr, ampJetMax(5,0)); | |
1069 | ampJetMax(0,0) = eCorr; | |
1070 | // -- | |
1071 | eCorrJetMatrix = GetMeanEmcalEnergy(Int_t(fVZER0Mult)) / 208.; | |
1072 | } | |
1073 | // Fill patch energy matrix | |
1074 | for(int row=Int_t(ampJetMax(1,0)); row<Int_t(ampJetMax(1,0))+nPatchSize; row++) { | |
1075 | for(int col=Int_t(ampJetMax(2,0)); col<Int_t(ampJetMax(2,0))+nPatchSize; col++) { | |
1076 | e = Double_t(jm(row,col)*0.0153); // 0.0153 - hard coded now | |
1077 | if(eCorrJetMatrix > 0.0) { // BG subtraction case | |
1078 | e -= eCorrJetMatrix; | |
1079 | fJetMatrixE->SetBinContent(row+1, col+1, e); | |
1080 | } else if(e > 0.0) { | |
1081 | fJetMatrixE->SetBinContent(row+1, col+1, e); | |
1082 | } | |
1083 | } | |
1084 | } | |
1085 | // PrintJetMatrix(); | |
1086 | // Set the jet trigger(s), multiple threshold now, Nov 19,2007 | |
1087 | for(Int_t i=0; i<fNJetThreshold; i++ ) { | |
1088 | if(ampJetMax(0,0) >= fL1JetThreshold[i]) { | |
7e42cd80 | 1089 | SetInput(GetNameOfJetTrigger(i)); |
85c25c2e | 1090 | } |
1091 | } | |
1092 | } | |
1093 | ||
1094 | Double_t AliEMCALTrigger::GetEmcalSumAmp() const | |
1095 | { | |
1096 | // Return sum of amplidutes from EMCal | |
1097 | // Used calibration coefficeint for transition to energy | |
1098 | return fAmpJetMatrix >0 ?fAmpJetMatrix->Sum() :0.0; | |
1099 | } | |
1100 | ||
1101 | ||
1102 | void AliEMCALTrigger::PrintJetMatrix() const | |
1103 | { | |
1104 | // fAmpJetMatrix : (17,12); // 17-phi(row), 12-eta(col) | |
1105 | if(fAmpJetMatrix == 0) return; | |
1106 | ||
1107 | printf("\n #### jetMatrix : (%i,%i) ##### \n ", | |
1108 | fAmpJetMatrix->GetNrows(), fAmpJetMatrix->GetNcols()); | |
1109 | PrintMatrix(*fAmpJetMatrix); | |
1110 | } | |
1111 | ||
1112 | void AliEMCALTrigger::PrintAmpTruMatrix(Int_t ind) const | |
1113 | { | |
1114 | TMatrixD * tru = dynamic_cast<TMatrixD *>(fAmpTrus->At(ind)); | |
1115 | if(tru == 0) return; | |
1116 | printf("\n #### Amp TRU matrix(%i) : (%i,%i) ##### \n ", | |
1117 | ind, tru->GetNrows(), tru->GetNcols()); | |
1118 | PrintMatrix(*tru); | |
1119 | } | |
1120 | ||
1121 | void AliEMCALTrigger::PrintAmpSmMatrix(Int_t ind) const | |
1122 | { | |
1123 | TMatrixD * sm = dynamic_cast<TMatrixD *>(fAmpSMods->At(ind)); | |
1124 | if(sm == 0) return; | |
1125 | printf("\n #### Amp SM matrix(%i) : (%i,%i) ##### \n ", | |
1126 | ind, sm->GetNrows(), sm->GetNcols()); | |
1127 | PrintMatrix(*sm); | |
1128 | } | |
1129 | ||
1130 | void AliEMCALTrigger::PrintMatrix(const TMatrixD &mat) const | |
1131 | { | |
1132 | for(Int_t col=0; col<mat.GetNcols(); col++) printf(" %3i ", col); | |
1133 | printf("\n -- \n"); | |
1134 | for(Int_t row=0; row<mat.GetNrows(); row++) { | |
1135 | printf(" row:%2i ", row); | |
1136 | for(Int_t col=0; col<mat.GetNcols(); col++) { | |
1137 | printf(" %4i", (Int_t)mat(row,col)); | |
1138 | } | |
1139 | printf("\n"); | |
1140 | } | |
1141 | } | |
1142 | ||
1143 | Bool_t AliEMCALTrigger::CheckConsistentOfMatrixes(const Int_t pri) | |
1144 | { | |
1145 | Double_t sumSM = 0.0, smCur=0.0; | |
1146 | Double_t sumTru=0.0, sumTruInSM = 0.0, truSum=0.0; | |
1147 | // Bool_t key = kTRUE; | |
1148 | ||
1149 | for(Int_t i=0; i<fAmpSMods->GetEntries(); i++) { | |
1150 | TMatrixD * sm = dynamic_cast<TMatrixD *>(fAmpSMods->At(i)); | |
1151 | if(sm) { | |
1152 | smCur = sm->Sum(); | |
1153 | sumSM += smCur; | |
1154 | ||
1155 | sumTruInSM = 0.0; | |
1156 | for(Int_t itru=0; itru<3; itru++) { // Cycle on tru inside SM | |
1157 | Int_t ind = 3*i + itru; | |
1158 | TMatrixD *tru = dynamic_cast<TMatrixD *>(fAmpTrus->At(ind)); | |
1159 | if(tru) { | |
1160 | truSum = tru->Sum(); | |
1161 | sumTruInSM += truSum; | |
1162 | } | |
1163 | } | |
1164 | sumTru += sumTruInSM; | |
1165 | ||
1166 | if(sumTruInSM != smCur) { | |
1167 | printf(" sm %i : smCur %f -> sumTruInSM %f \n", i, smCur, sumTruInSM); | |
1168 | return kFALSE; | |
1169 | } | |
1170 | } | |
1171 | } | |
1172 | Double_t sumJetMat = fAmpJetMatrix->Sum(); | |
1173 | if(pri || sumSM != sumTru || sumSM != sumJetMat) | |
1174 | printf(" sumSM %f : sumTru %f : sumJetMat %f \n", sumSM, sumTru, sumJetMat); | |
1175 | if(sumSM != sumTru || sumSM != sumJetMat) return kFALSE; | |
1176 | else return kTRUE; | |
1177 | } | |
1178 | ||
1179 | ||
1180 | void AliEMCALTrigger::Browse(TBrowser* b) | |
1181 | { | |
1182 | if(&fInputs) b->Add(&fInputs); | |
1183 | if(fAmpTrus) b->Add(fAmpTrus); | |
1184 | if(fTimeRtrus) b->Add(fTimeRtrus); | |
1185 | if(fAmpSMods) b->Add(fAmpSMods); | |
1186 | if(fAmpJetMatrix) b->Add(fAmpJetMatrix); | |
1187 | if(fJetMatrixE) b->Add(fJetMatrixE); | |
1188 | // if(c) b->Add(c); | |
f0377b23 | 1189 | } |