/**************************************************************************
-
* Copyright(c) 1998-1999, ALICE Experiment at CERN, All rights reserved. *
-
* *
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* Author: The ALICE Off-line Project. *
-
* Contributors are mentioned in the code where appropriate. *
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* *
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* Permission to use, copy, modify and distribute this software and its *
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* documentation strictly for non-commercial purposes is hereby granted *
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* without fee, provided that the above copyright notice appears in all *
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* copies and that both the copyright notice and this permission notice *
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* appear in the supporting documentation. The authors make no claims *
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* about the suitability of this software for any purpose. It is *
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* provided "as is" without express or implied warranty. *
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**************************************************************************/
-
-
/* $Id$*/
-
-
//_________________________________________________________________________
-
// Geometry class for EMCAL : singleton
-
// EMCAL consists of layers of scintillator and lead
-
// Places the the Barrel Geometry of The EMCAL at Midrapidity
-
-// between 0 and 120 degrees of Phi and
-
+// between 80 and 180(or 190) degrees of Phi and
// -0.7 to 0.7 in eta
-
// Number of Modules and Layers may be controlled by
-
// the name of the instance defined
-
-// EMCALArch2x has more modules along both phi and eta
-
-// EMCALArchxa has less Layers in the Radial Direction
-
//*-- Author: Sahal Yacoob (LBL / UCT)
-
// and : Yves Schutz (SUBATECH)
-
// and : Jennifer Klay (LBL)
-
-
-
-// --- ROOT system ---
-
-
-
-// --- Standard library ---
-
-
-
-#include <iostream.h>
-#include <stdlib.h>
-
-
+// SHASHLYK : Aleksei Pavlinov (WSU)
+// SuperModules -> module(or tower) -> cell
// --- AliRoot header files ---
+#include <assert.h>
+#include "Riostream.h"
#include <TMath.h>
+#include <TVector3.h>
+ //#include <TArrayD.h>
+#include <TObjArray.h>
+#include <TGeoManager.h>
+#include <TGeoNode.h>
+#include <TGeoMatrix.h>
+#include <TMatrixD.h>
+#include <TObjString.h>
+#include <TClonesArray.h>
// -- ALICE Headers.
-
-#include "AliConst.h"
+//#include "AliConst.h"
+#include "AliLog.h"
// --- EMCAL headers
-
#include "AliEMCALGeometry.h"
+#include "AliEMCALShishKebabTrd1Module.h"
+#include "AliEMCALRecPoint.h"
+#include "AliEMCALDigit.h"
+#include "AliEMCALHistoUtilities.h"
+#include "AliEMCALAlignData.h"
+ClassImp(AliEMCALGeometry)
-
-ClassImp(AliEMCALGeometry);
-
-
-
-AliEMCALGeometry *AliEMCALGeometry::fgGeom = 0;
-
-Bool_t AliEMCALGeometry::fgInit = kFALSE;
+// these initialisations are needed for a singleton
+AliEMCALGeometry *AliEMCALGeometry::fgGeom = 0;
+Bool_t AliEMCALGeometry::fgInit = kFALSE;
+AliEMCALAlignData *AliEMCALGeometry::fgAlignData = 0;
+AliEMCALGeometry::AliEMCALGeometry() : AliGeometry()
+{
+ // default ctor only for internal usage (singleton)
+ // must be kept public for root persistency purposes, but should never be called by the outside world
+ // CreateListOfTrd1Modules();
+ AliDebug(2, "AliEMCALGeometry : default ctor ");
+}
+//______________________________________________________________________
+AliEMCALGeometry::AliEMCALGeometry(const Text_t* name, const Text_t* title) :
+AliGeometry(name, title) {// ctor only for internal usage (singleton)
+ AliDebug(2, Form("AliEMCALGeometry(%s,%s) ", name,title));
+ Init();
+ CreateListOfTrd1Modules();
+}
+//______________________________________________________________________
+AliEMCALGeometry::AliEMCALGeometry(const Text_t* name, const Text_t* title, AliEMCALAlignData* alignData) :
+ AliGeometry(name, title) {// Align data in action
+ fgAlignData = alignData;
+ Init();
+ CreateListOfTrd1Modules();
+};
//______________________________________________________________________
+AliEMCALGeometry::AliEMCALGeometry(const AliEMCALGeometry& geom):AliGeometry(geom) {
+ //copy ctor
+ fGeoName = geom.fGeoName;
+
+ fArrayOpts = geom.fArrayOpts;
+
+ fAlFrontThick = geom.fAlFrontThick;
+ fECPbRadThickness = geom.fECPbRadThickness;
+ fECScintThick = geom.fECScintThick;
+ fNECLayers = geom.fNECLayers;
+ fArm1PhiMin = geom.fArm1PhiMin;
+ fArm1PhiMax = geom.fArm1PhiMax;
+ fArm1EtaMin = geom.fArm1EtaMin;
+ fArm1EtaMax = geom.fArm1EtaMax;
+
+ fIPDistance = geom.fIPDistance;
+ fShellThickness = geom.fShellThickness;
+ fZLength = geom.fZLength;
+ fGap2Active = geom.fGap2Active;
+ fNZ = geom.fNZ;
+ fNPhi = geom.fNPhi;
+ fSampling = geom.fSampling;
+
+ fNumberOfSuperModules = geom.fNumberOfSuperModules;
+ fSteelFrontThick = geom.fSteelFrontThick;
+ fFrontSteelStrip = geom.fFrontSteelStrip;
+ fLateralSteelStrip = geom.fLateralSteelStrip;
+ fPassiveScintThick = geom.fPassiveScintThick;
+ fPhiModuleSize = geom.fPhiModuleSize;
+ fEtaModuleSize = geom.fEtaModuleSize;
+ fPhiTileSize = geom.fPhiTileSize;
+ fEtaTileSize = geom.fEtaTileSize;
+ fLongModuleSize = geom.fLongModuleSize;
+ fNPhiSuperModule = geom.fNPhiSuperModule;
+ fNPHIdiv = geom.fNPHIdiv;
+ fNETAdiv = geom.fNETAdiv;
+
+ fNCells = geom.fNCells;
+ fNCellsInSupMod = geom.fNCellsInSupMod;
+ fNCellsInTower = geom.fNCellsInTower;
+ fNTRU = geom.fNTRU;
+ fNTRUEta = geom.fNTRUEta;
+ fNTRUPhi = geom.fNTRUPhi;
+ fTrd1Angle = geom.fTrd1Angle;
+ f2Trd1Dx2 = geom.f2Trd1Dx2;
+ fPhiGapForSM = geom.fPhiGapForSM;
+ fKey110DEG = geom.fKey110DEG;
+ fTrd2AngleY = geom.fTrd2AngleY;
+ f2Trd2Dy2 = geom.f2Trd2Dy2;
+ fEmptySpace = geom.fEmptySpace;
+ fTubsR = geom.fTubsR;
+ fTubsTurnAngle = geom.fTubsTurnAngle;
+ fEtaCentersOfCells = geom.fEtaCentersOfCells;
+ fXCentersOfCells = geom.fXCentersOfCells;
+ fPhiCentersOfCells = geom.fPhiCentersOfCells;
+
+ fShishKebabTrd1Modules = geom.fShishKebabTrd1Modules;
+
+ fNAdditionalOpts = geom.fNAdditionalOpts;
+}
+//______________________________________________________________________
AliEMCALGeometry::~AliEMCALGeometry(void){
-
// dtor
-
}
-
//______________________________________________________________________
-
void AliEMCALGeometry::Init(void){
+ // Initializes the EMCAL parameters
+ // naming convention : GUV_WX_N_ gives the composition of a tower
+ // WX inform about the composition of the EM calorimeter section:
+ // thickness in mm of Pb radiator (W) and of scintillator (X), and number of scintillator layers (N)
+ // New geometry: EMCAL_55_25
+ // 24-aug-04 for shish-kebab
+ // SHISH_25 or SHISH_62
+ // 11-oct-05 - correction for pre final design
+ // Feb 06,2006 - decrease the weight of EMCAL
+
+ fAdditionalOpts[0] = "nl="; // number of sampling layers (fNECLayers)
+ fAdditionalOpts[1] = "pbTh="; // cm, Thickness of the Pb (fECPbRadThick)
+ fAdditionalOpts[2] = "scTh="; // cm, Thickness of the Sc (fECScintThick)
+ fAdditionalOpts[3] = "latSS="; // cm, Thickness of lateral steel strip (fLateralSteelStrip)
+
+ fNAdditionalOpts = sizeof(fAdditionalOpts) / sizeof(char*);
+
+ fgInit = kFALSE; // Assume failed until proven otherwise.
+ fGeoName = GetName();
+ fGeoName.ToUpper();
+ fKey110DEG = 0;
+ if(fGeoName.Contains("110DEG")) fKey110DEG = 1; // for GetAbsCellId
+ fShishKebabTrd1Modules = 0;
+ fTrd2AngleY = f2Trd2Dy2 = fEmptySpace = fTubsR = fTubsTurnAngle = 0;
+
+ fNZ = 114; // granularity along Z (eta)
+ fNPhi = 168; // granularity in phi (azimuth)
+ fArm1PhiMin = 60.0; // degrees, Starting EMCAL Phi position
+ fArm1PhiMax = 180.0; // degrees, Ending EMCAL Phi position
+ fArm1EtaMin = -0.7; // pseudorapidity, Starting EMCAL Eta position
+ fArm1EtaMax = +0.7; // pseudorapidity, Ending EMCAL Eta position
+ fIPDistance = 454.0; // cm, Radial distance to inner surface of EMCAL
+ fPhiGapForSM = 0.; // cm, only for final TRD1 geometry
+ for(int i=0; i<12; i++) fMatrixOfSM[i] = 0;
+
+ // geometry
+ if(fGeoName.Contains("SHISH")){ // Only shahslyk now
+ // 7-sep-05; integration issue
+ fArm1PhiMin = 80.0; // 60 -> 80
+ fArm1PhiMax = 180.0; // 180 -> 190
+
+ fNumberOfSuperModules = 10; // 12 = 6 * 2 (6 in phi, 2 in Z);
+ fSteelFrontThick = 2.54; // 9-sep-04
+ fIPDistance = 460.0;
+ fFrontSteelStrip = fPassiveScintThick = 0.0; // 13-may-05
+ fLateralSteelStrip = 0.025; // before MAY 2005
+ fPhiModuleSize = fEtaModuleSize = 11.4;
+ fPhiTileSize = fEtaTileSize = 5.52; // (11.4-5.52*2)/2. = 0.18 cm (wall thickness)
+ fNPhi = 14;
+ fNZ = 30;
+ fAlFrontThick = fGap2Active = 0;
+ fNPHIdiv = fNETAdiv = 2;
+
+ fNECLayers = 62;
+ fECScintThick = fECPbRadThickness = 0.2;
+ fSampling = 1.; // 30-aug-04 - should be calculated
+ if(fGeoName.Contains("TWIST")) { // all about EMCAL module
+ fNZ = 27; // 16-sep-04
+ } else if(fGeoName.Contains("TRD")) {
+ fIPDistance = 428.0; // 11-may-05
+ fSteelFrontThick = 0.0; // 3.17 -> 0.0; 28-mar-05 : no stell plate
+ fNPhi = 12;
+ fSampling = 12.327;
+ fPhiModuleSize = fEtaModuleSize = 12.26;
+ fNZ = 26; // 11-oct-04
+ fTrd1Angle = 1.3; // in degree
+// 18-nov-04; 1./0.08112=12.327
+// http://pdsfweb01.nersc.gov/~pavlinov/ALICE/SHISHKEBAB/RES/linearityAndResolutionForTRD1.html
+ if(fGeoName.Contains("TRD1")) { // 30-jan-05
+ // for final design
+ fPhiGapForSM = 2.; // cm, only for final TRD1 geometry
+ if(fGeoName.Contains("MAY05") || fGeoName.Contains("WSUC") || fGeoName.Contains("FINAL")){
+ fNumberOfSuperModules = 12; // 20-may-05
+ if(fGeoName.Contains("WSUC")) fNumberOfSuperModules = 1; // 27-may-05
+ fNECLayers = 77; // (13-may-05 from V.Petrov)
+ fPhiModuleSize = 12.5; // 20-may-05 - rectangular shape
+ fEtaModuleSize = 11.9;
+ fECScintThick = fECPbRadThickness = 0.16;// (13-may-05 from V.Petrov)
+ fFrontSteelStrip = 0.025;// 0.025cm = 0.25mm (13-may-05 from V.Petrov)
+ fLateralSteelStrip = 0.01; // 0.01cm = 0.1mm (13-may-05 from V.Petrov) - was 0.025
+ fPassiveScintThick = 0.8; // 0.8cm = 8mm (13-may-05 from V.Petrov)
+ fNZ = 24;
+ fTrd1Angle = 1.5; // 1.3 or 1.5
+
+ if(fGeoName.Contains("FINAL")) { // 9-sep-05
+ fNumberOfSuperModules = 10;
+ if(fGeoName.Contains("110DEG")) {
+ fNumberOfSuperModules = 12;// last two modules have size 10 degree in phi (180<phi<190)
+ fArm1PhiMax = 200.0; // for XEN1 and turn angle of super modules
+ }
+ fPhiModuleSize = 12.26 - fPhiGapForSM / Float_t(fNPhi); // first assumption
+ fEtaModuleSize = fPhiModuleSize;
+ if(fGeoName.Contains("HUGE")) fNECLayers *= 3; // 28-oct-05 for analysing leakage
+ }
+ }
+ } else if(fGeoName.Contains("TRD2")) { // 30-jan-05
+ fSteelFrontThick = 0.0; // 11-mar-05
+ fIPDistance+= fSteelFrontThick; // 1-feb-05 - compensate absence of steel plate
+ fTrd1Angle = 1.64; // 1.3->1.64
+ fTrd2AngleY = fTrd1Angle; // symmetric case now
+ fEmptySpace = 0.2; // 2 mm
+ fTubsR = fIPDistance; // 31-jan-05 - as for Fred case
+
+ fPhiModuleSize = fTubsR*2.*TMath::Tan(fTrd2AngleY*TMath::DegToRad()/2.);
+ fPhiModuleSize -= fEmptySpace/2.; // 11-mar-05
+ fEtaModuleSize = fPhiModuleSize; // 20-may-05
+ fTubsTurnAngle = 3.;
+ }
+ fNPHIdiv = fNETAdiv = 2; // 13-oct-04 - division again
+ if(fGeoName.Contains("3X3")) { // 23-nov-04
+ fNPHIdiv = fNETAdiv = 3;
+ } else if(fGeoName.Contains("4X4")) {
+ fNPHIdiv = fNETAdiv = 4;
+ }
+ }
+ if(fGeoName.Contains("25")){
+ fNECLayers = 25;
+ fECScintThick = fECPbRadThickness = 0.5;
+ }
+ if(fGeoName.Contains("WSUC")){ // 18-may-05 - about common structure
+ fShellThickness = 30.; // should be change
+ fNPhi = fNZ = 4;
+ }
+
+ CheckAdditionalOptions();
+ DefineSamplingFraction();
+
+ fPhiTileSize = fPhiModuleSize/2. - fLateralSteelStrip; // 13-may-05
+ fEtaTileSize = fEtaModuleSize/2. - fLateralSteelStrip; // 13-may-05
+
+ // constant for transition absid <--> indexes
+ fNCellsInTower = fNPHIdiv*fNETAdiv;
+ fNCellsInSupMod = fNCellsInTower*fNPhi*fNZ;
+ fNCells = fNCellsInSupMod*fNumberOfSuperModules;
+ if(fGeoName.Contains("110DEG")) fNCells -= fNCellsInSupMod;
+
+ fLongModuleSize = fNECLayers*(fECScintThick + fECPbRadThickness);
+ if(fGeoName.Contains("MAY05")) fLongModuleSize += (fFrontSteelStrip + fPassiveScintThick);
+
+ // 30-sep-04
+ if(fGeoName.Contains("TRD")) {
+ f2Trd1Dx2 = fEtaModuleSize + 2.*fLongModuleSize*TMath::Tan(fTrd1Angle*TMath::DegToRad()/2.);
+ if(fGeoName.Contains("TRD2")) { // 27-jan-05
+ f2Trd2Dy2 = fPhiModuleSize + 2.*fLongModuleSize*TMath::Tan(fTrd2AngleY*TMath::DegToRad()/2.);
+ }
+ }
+ } else Fatal("Init", "%s is an undefined geometry!", fGeoName.Data()) ;
+
+ fNPhiSuperModule = fNumberOfSuperModules/2;
+ if(fNPhiSuperModule<1) fNPhiSuperModule = 1;
+ //There is always one more scintillator than radiator layer because of the first block of aluminium
+ fShellThickness = fAlFrontThick + fGap2Active + fNECLayers*GetECScintThick()+(fNECLayers-1)*GetECPbRadThick();
+ if(fGeoName.Contains("SHISH")) {
+ fShellThickness = fSteelFrontThick + fLongModuleSize;
+ if(fGeoName.Contains("TWIST")) { // 13-sep-04
+ fShellThickness = TMath::Sqrt(fLongModuleSize*fLongModuleSize + fPhiModuleSize*fEtaModuleSize);
+ fShellThickness += fSteelFrontThick;
+ } else if(fGeoName.Contains("TRD")) { // 1-oct-04
+ fShellThickness = TMath::Sqrt(fLongModuleSize*fLongModuleSize + f2Trd1Dx2*f2Trd1Dx2);
+ fShellThickness += fSteelFrontThick;
+ // Local coordinates
+ fParSM[0] = GetShellThickness()/2.;
+ fParSM[1] = GetPhiModuleSize() * GetNPhi()/2.;
+ fParSM[2] = 350./2.;
+ }
+ }
+
+ fZLength = 2.*ZFromEtaR(fIPDistance+fShellThickness,fArm1EtaMax); // Z coverage
+ fEnvelop[0] = fIPDistance; // mother volume inner radius
+ fEnvelop[1] = fIPDistance + fShellThickness; // mother volume outer r.
+ fEnvelop[2] = 1.00001*fZLength; // add some padding for mother volume.
+
+ if(fgAlignData != NULL) {
+ // Number of modules is read from Alignment DB if exists
+ fNumberOfSuperModules = fgAlignData->GetNSuperModules();
+ }
+
+ fgInit = kTRUE;
+
+ if (AliDebugLevel()>=2) {
+ printf("Init: geometry of EMCAL named %s is as follows:\n", fGeoName.Data());
+ printf( " ECAL : %d x (%f cm Pb, %f cm Sc) \n",
+ GetNECLayers(), GetECPbRadThick(), GetECScintThick() ) ;
+ printf(" fSampling %5.2f \n", fSampling );
+ if(fGeoName.Contains("SHISH")){
+ printf(" fIPDistance %6.3f cm \n", fIPDistance);
+ if(fSteelFrontThick>0.)
+ printf(" fSteelFrontThick %6.3f cm \n", fSteelFrontThick);
+ printf(" fNPhi %i | fNZ %i \n", fNPhi, fNZ);
+ printf(" fNCellsInTower %i : fNCellsInSupMod %i : fNCells %i\n",fNCellsInTower, fNCellsInSupMod, fNCells);
+ if(fGeoName.Contains("MAY05")){
+ printf(" fFrontSteelStrip %6.4f cm (thickness of front steel strip)\n",
+ fFrontSteelStrip);
+ printf(" fLateralSteelStrip %6.4f cm (thickness of lateral steel strip)\n",
+ fLateralSteelStrip);
+ printf(" fPassiveScintThick %6.4f cm (thickness of front passive Sc tile)\n",
+ fPassiveScintThick);
+ }
+ printf(" X:Y module size %6.3f , %6.3f cm \n", fPhiModuleSize, fEtaModuleSize);
+ printf(" X:Y tile size %6.3f , %6.3f cm \n", fPhiTileSize, fEtaTileSize);
+ printf(" #of sampling layers %i(fNECLayers) \n", fNECLayers);
+ printf(" fLongModuleSize %6.3f cm \n", fLongModuleSize);
+ printf(" #supermodule in phi direction %i \n", fNPhiSuperModule );
+ }
+ if(fGeoName.Contains("TRD")) {
+ printf(" fTrd1Angle %7.4f\n", fTrd1Angle);
+ printf(" f2Trd1Dx2 %7.4f\n", f2Trd1Dx2);
+ if(fGeoName.Contains("TRD2")) {
+ printf(" fTrd2AngleY %7.4f\n", fTrd2AngleY);
+ printf(" f2Trd2Dy2 %7.4f\n", f2Trd2Dy2);
+ printf(" fTubsR %7.2f cm\n", fTubsR);
+ printf(" fTubsTurnAngle %7.4f\n", fTubsTurnAngle);
+ printf(" fEmptySpace %7.4f cm\n", fEmptySpace);
+ } else if(fGeoName.Contains("TRD1") && fGeoName.Contains("FINAL")){
+ printf("SM dimensions(TRD1) : dx %7.2f dy %7.2f dz %7.2f (SMOD, BOX)\n",
+ fParSM[0],fParSM[1],fParSM[2]);
+ printf(" fPhiGapForSM %7.4f cm \n", fPhiGapForSM);
+ if(fGeoName.Contains("110DEG"))printf(" Last two modules have size 10 degree in phi (180<phi<190)\n");
+ }
+ }
+ printf("Granularity: %d in eta and %d in phi\n", GetNZ(), GetNPhi()) ;
+ printf("Layout: phi = (%7.1f, %7.1f), eta = (%5.2f, %5.2f), IP = %7.2f\n",
+ GetArm1PhiMin(), GetArm1PhiMax(),GetArm1EtaMin(), GetArm1EtaMax(), GetIPDistance() );
+ }
+ //TRU parameters. These parameters values are not the final ones.
+ fNTRU = 3 ;
+ fNTRUEta = 3 ;
+ fNTRUPhi = 1 ;
+}
- // Initializes the EMCAL parameters
-
-
-
- fgInit = kFALSE; // Assume failer untill proven otherwise.
-
-
-
- TString name(GetName()) ;
-
-
-
- if( name != "EMCALArch1a" &&
-
- name != "EMCALArch1b" &&
-
- name != "EMCALArch2a" &&
-
- name != "EMCALArch2b" ){
-
- cerr << "ERROR: " << ClassName() << "::Init -> " << name.Data()
-
- << " is not a known geometry (choose among EMCALArch1a, EMCALArch1b, EMCALArch2a and EMCALArch2b)"
-
- << endl ;
-
- abort() ;
-
- } // end if
-
- //
-
- if ( name == "EMCALArch1a" ||
-
- name == "EMCALArch1b" ) {
-
- fNZ = 96;
-
- fNPhi = 144;
-
- } // end if
-
- if ( name == "EMCALArch2a" ||
-
- name, "EMCALArch2b" ) {
-
- fNZ = 112;
-
- fNPhi = 168;
-
- } // end if
-
- if ( name == "EMCALArch1a" ||
-
- name == "EMCALArch2a" ) {
-
- fNLayers = 21;
-
- } // end if
-
- if ( name == "EMCALArch1b" ||
-
- name == "EMCALArch2b" ) {
-
- fNLayers = 25;
-
- } // end if
-
-
-
- // geometry
-
- fAirGap = 5.0; // cm, air gap between EMCAL mother volume and
-
- // active material.
-
- fAlFrontThick = 3.18; // cm, Thickness of front Al layer
-
- fPbRadThickness = 0.5; // cm, Thickness of theh Pb radiators.
-
- fPreShowerSintThick = 0.6; // cm, Thickness of the sintilator for the
-
- // preshower part of the calorimeter
-
- fFullShowerSintThick = 0.5; // cm, Thickness of the sintilator for the
-
- // full shower part of the calorimeter
-
- fArm1PhiMin = 60.0; // degrees, Starting EMCAL Phi position
-
- fArm1PhiMax = 180.0; // degrees, Ending EMCAL Phi position
-
- fArm1EtaMin = -0.7; // pseudorapidity, Starting EMCAL Eta position
-
- fArm1EtaMax = +0.7; // pseudorapidity, Ending EMCAL Eta position
-
- fIPDistance = 454.0; // cm, Radial distance to inner surface of EMCAL
-
- fShellThickness = GetAlFrontThickness() + 2.*GetPreSintThick() +
-
- (fNLayers-2)*GetFullSintThick()+(fNLayers-1)*GetPbRadThick();
-
- //below; cm, Z lenght of the EMCAL.
+//______________________________________________________________________
- fZLength = 2.*ZFromEtaR(fIPDistance+fShellThickness,fArm1EtaMax);
+void AliEMCALGeometry::CheckAdditionalOptions()
+{
+ // Feb 06,2006
+ //Additional options that
+ //can be used to select
+ //the specific geometry of
+ //EMCAL to run
+
+ fArrayOpts = new TObjArray;
+ Int_t nopt = AliEMCALHistoUtilities::ParseString(fGeoName, *fArrayOpts);
+ if(nopt==1) { // no aditional option(s)
+ fArrayOpts->Delete();
+ delete fArrayOpts;
+ fArrayOpts = 0;
+ return;
+ }
+ for(Int_t i=1; i<nopt; i++){
+ TObjString *o = (TObjString*)fArrayOpts->At(i);
+
+ TString addOpt = o->String();
+ Int_t indj=-1;
+ for(Int_t j=0; j<fNAdditionalOpts; j++) {
+ TString opt = fAdditionalOpts[j];
+ if(addOpt.Contains(opt,TString::kIgnoreCase)) {
+ indj = j;
+ break;
+ }
+ }
+ if(indj<0) {
+ AliDebug(2,Form("<E> option |%s| unavailable : ** look to the file AliEMCALGeometry.h **\n",
+ addOpt.Data()));
+ assert(0);
+ } else {
+ AliDebug(2,Form("<I> option |%s| is valid : number %i : |%s|\n",
+ addOpt.Data(), indj, fAdditionalOpts[indj]));
+ if (addOpt.Contains("NL=",TString::kIgnoreCase)) {// number of sampling layers
+ sscanf(addOpt.Data(),"NL=%i", &fNECLayers);
+ AliDebug(2,Form(" fNECLayers %i (new) \n", fNECLayers));
+ } else if(addOpt.Contains("PBTH=",TString::kIgnoreCase)) {//Thickness of the Pb(fECPbRadThicknes)
+ sscanf(addOpt.Data(),"PBTH=%f", &fECPbRadThickness);
+ } else if(addOpt.Contains("SCTH=",TString::kIgnoreCase)) {//Thickness of the Sc(fECScintThick)
+ sscanf(addOpt.Data(),"SCTH=%f", &fECScintThick);
+ } else if(addOpt.Contains("LATSS=",TString::kIgnoreCase)) {// Thickness of lateral steel strip (fLateralSteelStrip)
+ sscanf(addOpt.Data(),"LATSS=%f", &fLateralSteelStrip);
+ AliDebug(2,Form(" fLateralSteelStrip %f (new) \n", fLateralSteelStrip));
+ }
+ }
+ }
+}
- fEnvelop[0] = fIPDistance; // mother volume inner radius
+void AliEMCALGeometry::DefineSamplingFraction()
+{
+ // Jun 05,2006
+ // Look http://rhic.physics.wayne.edu/~pavlinov/ALICE/SHISHKEBAB/RES/linearityAndResolutionForTRD1.html
+ // Keep for compatibilty
+ //
+ if(fNECLayers == 69) { // 10% layer reduction
+ fSampling = 12.55;
+ } else if(fNECLayers == 61) { // 20% layer reduction
+ fSampling = 12.80;
+ } else if(fNECLayers == 77) {
+ if (fECScintThick>0.175 && fECScintThick<0.177) { // 10% Pb thicknes reduction
+ fSampling = 10.5; // fECScintThick = 0.176, fECPbRadThickness=0.144;
+ } else if(fECScintThick>0.191 && fECScintThick<0.193) { // 20% Pb thicknes reduction
+ fSampling = 8.93; // fECScintThick = 0.192, fECPbRadThickness=0.128;
+ }
+ }
+}
- fEnvelop[1] = fIPDistance + fShellThickness; // mother volume outer r.
+//____________________________________________________________________________
+void AliEMCALGeometry::FillTRU(const TClonesArray * digits, TClonesArray * ampmatrix, TClonesArray * timeRmatrix) {
- fEnvelop[2] = 1.00001*fZLength; // add some padding for mother volume.
- fGap2Active = 1.0; // cm, Gap between
+// Orders digits ampitudes list in fNTRU TRUs (384 cells) per supermodule.
+// Each TRU is a TMatrixD, and they are kept in TClonesArrays. The number of
+// TRU in phi is fNTRUPhi, and the number of TRU in eta is fNTRUEta.
+// Last 2 modules are half size in Phi, I considered that the number of TRU
+// is maintained for the last modules but decision not taken. If different,
+// then this must be changed.
+
- fgInit = kTRUE;
+ //Check data members
+
+ if(fNTRUEta*fNTRUPhi != fNTRU)
+ Error("FillTRU"," Wrong number of TRUS per Eta or Phi");
+
+ //Initilize and declare variables
+ //List of TRU matrices initialized to 0.
+ Int_t nCellsPhi = fNPhi*2/fNTRUPhi;
+ Int_t nCellsPhi2 = fNPhi/fNTRUPhi; //HalfSize modules
+ Int_t nCellsEta = fNZ*2/fNTRUEta;
+ Int_t id = -1;
+ Float_t amp = -1;
+ Float_t timeR = -1;
+ Int_t iSupMod = -1;
+ Int_t nTower = -1;
+ Int_t nIphi = -1;
+ Int_t nIeta = -1;
+ Int_t iphi = -1;
+ Int_t ieta = -1;
+
+ //List of TRU matrices initialized to 0.
+ for(Int_t k = 0; k < fNTRU*fNumberOfSuperModules; k++){
+ TMatrixD * amptrus = new TMatrixD(nCellsPhi,nCellsEta) ;
+ TMatrixD * timeRtrus = new TMatrixD(nCellsPhi,nCellsEta) ;
+ for(Int_t i = 0; i < nCellsPhi; i++){
+ for(Int_t j = 0; j < nCellsEta; j++){
+ (*amptrus)(i,j) = 0.0;
+ (*timeRtrus)(i,j) = 0.0;
+ }
+ }
+ new((*ampmatrix)[k]) TMatrixD(*amptrus) ;
+ new((*timeRmatrix)[k]) TMatrixD(*timeRtrus) ;
+ }
+
+ AliEMCALDigit * dig ;
+
+ //Digits loop to fill TRU matrices with amplitudes.
+ for(Int_t idig = 0 ; idig < digits->GetEntriesFast() ; idig++){
+
+ dig = dynamic_cast<AliEMCALDigit *>(digits->At(idig)) ;
+ amp = dig->GetAmp() ; // Energy of the digit (arbitrary units)
+ id = dig->GetId() ; // Id label of the cell
+ timeR = dig->GetTimeR() ; // Earliest time of the digit
+
+ //Get eta and phi cell position in supermodule
+ Bool_t bCell = GetCellIndex(id, iSupMod, nTower, nIphi, nIeta) ;
+ if(!bCell)
+ Error("FillTRU","Wrong cell id number") ;
+
+ GetCellPhiEtaIndexInSModule(iSupMod,nTower,nIphi, nIeta,iphi,ieta);
+
+ //Check to which TRU in the supermodule belongs the cell.
+ //Supermodules are divided in a TRU matrix of dimension
+ //(fNTRUPhi,fNTRUEta).
+ //Each TRU is a cell matrix of dimension (nCellsPhi,nCellsEta)
+
+ //First calculate the row and column in the supermodule
+ //of the TRU to which the cell belongs.
+ Int_t col = ieta/nCellsEta;
+ Int_t row = iphi/nCellsPhi;
+ if(iSupMod > 9)
+ row = iphi/nCellsPhi2;
+ //Calculate label number of the TRU
+ Int_t itru = row + col*fNTRUPhi + iSupMod*fNTRU ;
+
+ //Fill TRU matrix with cell values
+ TMatrixD * amptrus = dynamic_cast<TMatrixD *>(ampmatrix->At(itru)) ;
+ TMatrixD * timeRtrus = dynamic_cast<TMatrixD *>(timeRmatrix->At(itru)) ;
+
+ //Calculate row and column of the cell inside the TRU with number itru
+ Int_t irow = iphi - row * nCellsPhi;
+ if(iSupMod > 9)
+ irow = iphi - row * nCellsPhi2;
+ Int_t icol = ieta - col * nCellsEta;
+
+ (*amptrus)(irow,icol) = amp ;
+ (*timeRtrus)(irow,icol) = timeR ;
+ }
}
//______________________________________________________________________
+void AliEMCALGeometry::GetCellPhiEtaIndexInSModuleFromTRUIndex(const Int_t itru, const Int_t iphitru, const Int_t ietatru, Int_t &iphiSM, Int_t &ietaSM) const
+{
+
+ // This method transforms the (eta,phi) index of cells in a
+ // TRU matrix into Super Module (eta,phi) index.
+
+ // Calculate in which row and column where the TRU are
+ // ordered in the SM
+
+ Int_t col = itru/ fNTRUPhi ;
+ Int_t row = itru - col*fNTRUPhi ;
+
+ //Calculate the (eta,phi) index in SM
+ Int_t nCellsPhi = fNPhi*2/fNTRUPhi;
+ Int_t nCellsEta = fNZ*2/fNTRUEta;
+
+ iphiSM = nCellsPhi*row + iphitru ;
+ ietaSM = nCellsEta*col + ietatru ;
+}
+//______________________________________________________________________
AliEMCALGeometry * AliEMCALGeometry::GetInstance(){
-
// Returns the pointer of the unique instance
-
-
- return static_cast<AliEMCALGeometry *>( fgGeom ) ;
-
+ AliEMCALGeometry * rv = static_cast<AliEMCALGeometry *>( fgGeom );
+ return rv;
}
//______________________________________________________________________
-
AliEMCALGeometry* AliEMCALGeometry::GetInstance(const Text_t* name,
-
const Text_t* title){
-
// Returns the pointer of the unique instance
-
-
AliEMCALGeometry * rv = 0;
-
if ( fgGeom == 0 ) {
-
if ( strcmp(name,"") == 0 ) rv = 0;
-
- else {
-
+ else {
fgGeom = new AliEMCALGeometry(name, title);
-
if ( fgInit ) rv = (AliEMCALGeometry * ) fgGeom;
-
else {
-
rv = 0;
-
delete fgGeom;
-
fgGeom = 0;
-
} // end if fgInit
-
} // end if strcmp(name,"")
-
}else{
-
- if ( strcmp(fgGeom->GetName(), name) != 0 ) {
-
- cout << "AliEMCALGeometry <E> : current geometry is "
-
- << fgGeom->GetName() << endl
-
- << " you cannot call " << name
-
- << endl;
-
+ if ( strcmp(fgGeom->GetName(), name) != 0) {
+ printf("\ncurrent geometry is %s : ", fgGeom->GetName());
+ printf(" you cannot call %s ", name);
}else{
-
- rv = (AliEMCALGeometry *) fgGeom;
-
- } // end if
-
+ rv = (AliEMCALGeometry *) fgGeom;
+ } // end
} // end if fgGeom
-
return rv;
-
}
-//______________________________________________________________________
-
-Int_t AliEMCALGeometry::TowerIndex(Int_t ieta,Int_t iphi,Int_t ipre) const {
-
- // Returns the tower index number from the based on the Z and Phi
-
- // index numbers. There are 2 times the number of towers to separate
-
- // out the full towsers from the pre-towsers.
-
- // Inputs:
-
- // Int_t ieta // index allong z axis [1-fNZ]
-
- // Int_t iphi // index allong phi axis [1-fNPhi]
-
- // Int_t ipre // 0 = Full tower, 1 = Pre-shower tower only. [0,1]
-
- // Outputs:
-
- // none.
-
- // Returned
-
- // Int_t the absoulute tower index. [1-2*fNZ*fNPhi]
-
- Int_t index;
-
-
-
- if((ieta<=0 || ieta>GetNEta()) || (iphi<=0 || iphi>GetNPhi()) ||
-
- (ipre<0 || ipre>1) ){
-
- cout << "inputs out of range ieta=" << ieta << " [1-" << GetNEta();
-
- cout << "] iphi=" << iphi << " [1-" << GetNPhi() << "] ipre=";
-
- cout << ipre << "[0,1]. returning -1" << endl;
-
- return -1;
-
- } // end if
-
- index = iphi + GetNPhi()*(ieta-1) + ipre*(GetNPhi()*GetNEta());
-
- return index;
-
-}
-
-//______________________________________________________________________
-
-void AliEMCALGeometry::TowerIndexes(Int_t index,Int_t &ieta,Int_t &iphi,
-
- Int_t &ipre) const {
-
- // given the tower index number it returns the based on the Z and Phi
-
- // index numbers and if it is for the full tower or the pre-tower number.
-
- // There are 2 times the number of towers to separate
-
- // out the full towsers from the pre-towsers.
-
- // Inputs:
-
- // Int_t index // Tower index number [1-2*fNZ*fNPhi]
-
- // Outputs:
-
- // Int_t ieta // index allong z axis [1-fNZ]
-
- // Int_t iphi // index allong phi axis [1-fNPhi]
-
- // Int_t ipre // 0 = Full tower, 1 = Pre-shower tower only. [0,1]
-
- // Returned
-
- // none.
-
- Int_t itowers;
-
-
-
- itowers = GetNEta()*GetNPhi();
-
- if(index<1 || index>2*itowers){
-
- cout << "index=" << index <<" is out of range [1-";
-
- cout << 2*itowers << "], returning -1 for all." << endl;
-
- ieta = -1; iphi = -1; ipre = -1;
-
- return ;
-
- } // end if
-
- ipre = 0;
-
- if(index>itowers){ // pre shower indexs
-
- ipre = 1;
-
- index = index - itowers;
-
- } // end if
-
- ieta = 1+ (Int_t)((index-1)/GetNPhi());
-
- iphi = index - GetNPhi()*(ieta-1);
-
- return;
-
+Bool_t AliEMCALGeometry::IsInEMCAL(Double_t x, Double_t y, Double_t z) const {
+ // Checks whether point is inside the EMCal volume, used in AliEMCALv*.cxx
+ //
+ // Code uses cylindrical approximation made of inner radius (for speed)
+ //
+ // Points behind EMCAl, i.e. R > outer radius, but eta, phi in acceptance
+ // are considered to inside
+
+ Double_t r=sqrt(x*x+y*y);
+
+ if ( r > fEnvelop[0] ) {
+ Double_t theta;
+ theta = TMath::ATan2(r,z);
+ Double_t eta;
+ if(theta == 0)
+ eta = 9999;
+ else
+ eta = -TMath::Log(TMath::Tan(theta/2.));
+ if (eta < fArm1EtaMin || eta > fArm1EtaMax)
+ return 0;
+
+ Double_t phi = TMath::ATan2(y,x) * 180./TMath::Pi();
+ if (phi > fArm1PhiMin && phi < fArm1PhiMax)
+ return 1;
+ }
+ return 0;
}
-
-//______________________________________________________________________
-
-void AliEMCALGeometry::EtaPhiFromIndex(Int_t index,Float_t &eta,Float_t &phi) const {
-
- // given the tower index number it returns the based on the eta and phi
-
- // of the tower.
-
- // Inputs:
-
- // Int_t index // Tower index number [1-2*fNZ*fNPhi]
-
- // Outputs:
-
- // Float_t eta // eta of center of tower in pseudorapidity
-
- // Float_t phi // phi of center of tower in degrees
-
- // Returned
-
- // none.
-
- Int_t ieta,iphi,ipre;
-
- Double_t deta,dphi,phid;
-
-
-
- TowerIndexes(index,ieta,iphi,ipre);
-
- deta = (GetArm1EtaMax()-GetArm1EtaMin())/((Float_t)GetNEta());
-
- eta = GetArm1EtaMin() + (((Float_t)ieta)-0.5)*deta;
-
- dphi = (GetArm1PhiMax() - GetArm1PhiMin())/((Float_t)GetNPhi()); // in degrees.
-
- phid = GetArm1PhiMin() + dphi*((Float_t)iphi -0.5);//iphi range [1-fNphi].
-
- phi = phid;
-
+// ==
+
+//
+// == Shish-kebab cases ==
+//
+Int_t AliEMCALGeometry::GetAbsCellId(Int_t nSupMod, Int_t nTower, Int_t nIphi, Int_t nIeta) const
+{
+ // 27-aug-04;
+ // corr. 21-sep-04;
+ // 13-oct-05; 110 degree case
+ // May 31, 2006; ALICE numbering scheme:
+ // 0 <= nSupMod < fNumberOfSuperModules
+ // 0 <= nTower < fNPHI * fNZ ( fNPHI * fNZ/2 for fKey110DEG=1)
+ // 0 <= nIphi < fNPHIdiv
+ // 0 <= nIeta < fNETAdiv
+ // 0 <= absid < fNCells
+ static Int_t id=0; // have to change from 0 to fNCells-1
+ if(fKey110DEG == 1 && nSupMod >= 10) { // 110 degree case; last two supermodules
+ id = fNCellsInSupMod*10 + (fNCellsInSupMod/2)*(nSupMod-10);
+ } else {
+ id = fNCellsInSupMod*nSupMod;
+ }
+ id += fNCellsInTower *nTower;
+ id += fNPHIdiv *nIphi;
+ id += nIeta;
+ if(id<0 || id >= fNCells) {
+// printf(" wrong numerations !!\n");
+// printf(" id %6i(will be force to -1)\n", id);
+// printf(" fNCells %6i\n", fNCells);
+// printf(" nSupMod %6i\n", nSupMod);
+// printf(" nTower %6i\n", nTower);
+// printf(" nIphi %6i\n", nIphi);
+// printf(" nIeta %6i\n", nIeta);
+ id = -TMath::Abs(id); // if negative something wrong
+ }
+ return id;
}
-//______________________________________________________________________
-
-Int_t AliEMCALGeometry::TowerIndexFromEtaPhi(Float_t eta,Float_t phi) const {
-
- // returns the tower index number based on the eta and phi of the tower.
-
- // Inputs:
-
- // Float_t eta // eta of center of tower in pseudorapidity
-
- // Float_t phi // phi of center of tower in degrees
-
- // Outputs:
-
- // none.
-
- // Returned
-
- // Int_t index // Tower index number [1-fNZ*fNPhi]
-
- Int_t ieta,iphi;
-
-
-
- ieta = 1 + (Int_t)(((Float_t)GetNEta())*(eta-GetArm1EtaMin())/
-
- (GetArm1EtaMax() - GetArm1EtaMin()));
-
- if(ieta<=0 || ieta>GetNEta()){
-
- cout << "TowerIndexFromEtaPhi:";
-
- cout << "ieta = "<< ieta << " eta=" << eta << " is outside of EMCAL. etamin=";
-
- cout << GetArm1EtaMin() << " to etamax=" << GetArm1EtaMax();
-
- cout << " returning -1" << endl;
-
- return -1;
-
- } // end if
-
- iphi = 1 + (Int_t)(((Float_t)GetNPhi())*(phi-GetArm1PhiMin())/
-
- ((Float_t)(GetArm1PhiMax() - GetArm1PhiMin())));
-
- if(iphi<=0 || iphi>GetNPhi()){
-
- cout << "TowerIndexFromEtaPhi:";
-
- cout << "iphi=" << iphi << " phi=" << phi << " is outside of EMCAL.";
-
- cout << " Phimin=" << GetArm1PhiMin() << " PhiMax=" << GetArm1PhiMax();
-
- cout << " returning -1" << endl;
-
- return -1;
-
- } // end if
-
- return TowerIndex(ieta,iphi,0);
-
+Bool_t AliEMCALGeometry::CheckAbsCellId(Int_t absId) const
+{
+ // May 31, 2006; only trd1 now
+ if(absId<0 || absId >= fNCells) return kFALSE;
+ else return kTRUE;
}
-//______________________________________________________________________
-
-Int_t AliEMCALGeometry::PreTowerIndexFromEtaPhi(Float_t eta,Float_t phi) const {
-
- // returns the pretower index number based on the eta and phi of the tower.
-
- // Inputs:
-
- // Float_t eta // eta of center of tower in pseudorapidity
-
- // Float_t phi // phi of center of tower in degrees
-
- // Outputs:
-
- // none.
-
- // Returned
-
- // Int_t index // PreTower index number [fNZ*fNPhi-2*fNZ*fNPhi]
-
-
-
- return GetNEta()*GetNPhi()+TowerIndexFromEtaPhi(eta,phi);
-
+Bool_t AliEMCALGeometry::GetCellIndex(Int_t absId,Int_t &nSupMod,Int_t &nTower,Int_t &nIphi,Int_t &nIeta) const
+{
+ // 21-sep-04; 19-oct-05;
+ // May 31, 2006; ALICE numbering scheme:
+ static Int_t tmp=0, sm10=0;
+ if(!CheckAbsCellId(absId)) return kFALSE;
+
+ sm10 = fNCellsInSupMod*10;
+ if(fKey110DEG == 1 && absId >= sm10) { // 110 degree case; last two supermodules
+ nSupMod = (absId-sm10) / (fNCellsInSupMod/2) + 10;
+ tmp = (absId-sm10) % (fNCellsInSupMod/2);
+ } else {
+ nSupMod = absId / fNCellsInSupMod;
+ tmp = absId % fNCellsInSupMod;
+ }
+
+ nTower = tmp / fNCellsInTower;
+ tmp = tmp % fNCellsInTower;
+ nIphi = tmp / fNPHIdiv;
+ nIeta = tmp % fNPHIdiv;
+
+ return kTRUE;
}
-//______________________________________________________________________
-
-Bool_t AliEMCALGeometry::AbsToRelNumbering(Int_t AbsId, Int_t *relid) const {
-
- // Converts the absolute numbering into the following array/
-
- // relid[0] = EMCAL Arm number 1:1
-
- // relid[1] = 0 Not in Pre Shower layers
-
- // = -1 In Pre Shower
-
- // relid[2] = Row number inside EMCAL
-
- // relid[3] = Column number inside EMCAL
-
- // Input:
+void AliEMCALGeometry::GetModulePhiEtaIndexInSModule(Int_t nSupMod, Int_t nTower, int &iphim, int &ietam) const
+{
+ // added nSupMod; have to check - 19-oct-05 !
+ // Alice numbering scheme - Jun 01,2006
+ static Int_t nphi;
- // Int_t AbsId // Tower index number [1-2*fNZ*fNPhi]
-
- // Outputs:
-
- // Int_t *relid // array of 5. Discribed above.
-
- Bool_t rv = kTRUE ;
-
- Int_t ieta=0,iphi=0,ipre=0,index=AbsId;
-
-
-
- TowerIndexes(index,ieta,iphi,ipre);
-
- relid[0] = 1;
-
- relid[1] = 0;
-
- if(ipre==1)
-
- relid[1] = -1;
-
- relid[2] = ieta;
-
- relid[3] = iphi;
-
-
-
- return rv;
+ if(fKey110DEG == 1 && nSupMod>=10) nphi = fNPhi/2;
+ else nphi = fNPhi;
+ ietam = nTower/nphi; // have to change from 0 to fNZ-1
+ iphim = nTower%nphi; // have to change from 0 to fNPhi-1
}
-//______________________________________________________________________
-
-void AliEMCALGeometry::PosInAlice(const Int_t *relid,Float_t &theta,
-
- Float_t &phi) const {
-
- // Converts the relative numbering into the local EMCAL-module (x, z)
-
- // coordinates
-
- Int_t ieta = relid[2]; // offset along x axis
-
- Int_t iphi = relid[3]; // offset along z axis
-
- Int_t ipre = relid[1]; // indicates -1 preshower, or 0 full tower.
-
- Int_t index;
-
- Float_t eta;
-
-
-
- if(ipre==-1) ipre = 1;
-
- index = TowerIndex(ieta,iphi,ipre);
-
- EtaPhiFromIndex(index,eta,phi);
-
- theta = 180.*(2.0*TMath::ATan(TMath::Exp(-eta)))/TMath::Pi();
-
-
-
- return;
-
+void AliEMCALGeometry::GetCellPhiEtaIndexInSModule(Int_t nSupMod, Int_t nTower, Int_t nIphi, Int_t nIeta,
+int &iphi, int &ieta) const
+{
+ // added nSupMod; Nov 25, 05
+ // Alice numbering scheme - Jun 01,2006
+ static Int_t iphim, ietam;
+
+ GetModulePhiEtaIndexInSModule(nSupMod,nTower, iphim, ietam);
+ // have to change from 0 to (fNZ*fNETAdiv-1)
+ ieta = ietam*fNETAdiv + (1-nIeta); // x(module) = -z(SM)
+ // iphi - have to change from 0 to (fNPhi*fNPHIdiv-1)
+ iphi = iphim*fNPHIdiv + nIphi; // y(module) = y(SM)
}
+Int_t AliEMCALGeometry::GetSuperModuleNumber(Int_t absId) const
+{
+ //return the number of the
+ //supermodule given the absolute
+ //ALICE numbering
-
-//______________________________________________________________________
-
-void AliEMCALGeometry::XYZFromIndex(const Int_t *relid,Float_t &x,Float_t &y, Float_t &z) const {
-
- // given the tower relative number it returns the X, Y and Z
-
- // of the tower.
-
-
-
- // Outputs:
-
- // Float_t x // x of center of tower in cm
-
- // Float_t y // y of center of tower in cm
-
- // Float_t z // z of centre of tower in cm
-
- // Returned
-
- // none.
-
-
-
- Float_t eta,theta, phi,cyl_radius,kDeg2Rad;
-
-
-
- Int_t ieta = relid[2]; // offset along x axis
-
- Int_t iphi = relid[3]; // offset along z axis
-
- Int_t ipre = relid[1]; // indicates -1 preshower, or 0 full tower.
-
- Int_t index;
-
-
-
-
-
- if(ipre==-1) ipre = 1;
-
- index = TowerIndex(ieta,iphi,ipre);
-
- EtaPhiFromIndex(index,eta,phi);
-
- theta = 180.*(2.0*TMath::ATan(TMath::Exp(-eta)))/TMath::Pi();
-
-
-
-
-
-
-
- kDeg2Rad = TMath::Pi() / static_cast<Double_t>(180) ;
-
- cyl_radius = GetIPDistance()+ GetAirGap() ;
-
- x = cyl_radius * TMath::Cos(phi * kDeg2Rad ) ;
-
- y = cyl_radius * TMath::Cos(phi * kDeg2Rad ) ;
-
- z = cyl_radius / TMath::Tan(theta * kDeg2Rad ) ;
-
-
-
- return;
-
+ static Int_t nSupMod, nTower, nIphi, nIeta;
+ GetCellIndex(absId, nSupMod, nTower, nIphi, nIeta);
+ return nSupMod;
}
+// Methods for AliEMCALRecPoint - Feb 19, 2006
+Bool_t AliEMCALGeometry::RelPosCellInSModule(Int_t absId, Double_t &xr, Double_t &yr, Double_t &zr) const
+{
+ // Look to see what the relative
+ // position inside a given cell is
+ // for a recpoint.
+ // Alice numbering scheme - Jun 08, 2006
+ static Int_t nSupMod, nTower, nIphi, nIeta, iphi, ieta;
+ static Int_t phiIndexShift=6;
+ if(!CheckAbsCellId(absId)) return kFALSE;
-//______________________________________________________________________
-
-/*
-
-Boot_t AliEMCALGeometry::AreNeighbours(Int_t index1,Int_t index2) const {
-
- // Returns kTRUE if the two towers are neighbours or not, including
-
- // diagonals. Both indexes are required to be either towers or preshower.
-
- // Inputs:
-
- // Int_t index1 // index of tower 1
-
- // Int_t index2 // index of tower 2
+ GetCellIndex(absId, nSupMod, nTower, nIphi, nIeta);
+ GetCellPhiEtaIndexInSModule(nSupMod,nTower,nIphi,nIeta, iphi, ieta);
+
+ xr = fXCentersOfCells.At(ieta);
+ zr = fEtaCentersOfCells.At(ieta);
+
+ if(nSupMod<10) {
+ yr = fPhiCentersOfCells.At(iphi);
+ } else {
+ yr = fPhiCentersOfCells.At(iphi + phiIndexShift);
+ // cout<<" absId "<<absId<<" nSupMod "<<nSupMod << " iphi "<<iphi<<" ieta "<<ieta;
+ // cout<< " xr " << xr << " yr " << yr << " zr " << zr <<endl;
+ }
+
+ return kTRUE;
+}
- // Outputs:
+Bool_t AliEMCALGeometry::RelPosCellInSModule(Int_t absId, Double_t loc[3]) const
+{
+ // Alice numbering scheme - Jun 03, 2006
+ loc[0] = loc[1] = loc[2]=0.0;
+ if(RelPosCellInSModule(absId, loc[0],loc[1],loc[2])) {
+ return kTRUE;
+ }
+ return kFALSE;
+}
- // none.
+Bool_t AliEMCALGeometry::RelPosCellInSModule(Int_t absId, TVector3 &vloc) const
+{
+ static Double_t loc[3];
+ if(RelPosCellInSModule(absId,loc)) {
+ vloc.SetXYZ(loc[0], loc[1], loc[2]);
+ return kTRUE;
+ } else {
+ vloc.SetXYZ(0,0,0);
+ return kFALSE;
+ }
+ // Alice numbering scheme - Jun 03, 2006
+}
- // Returned
+void AliEMCALGeometry::CreateListOfTrd1Modules()
+{
+ //Generate the list of Trd1 modules
+ //which will make up the EMCAL
+ //geometry
+
+ AliDebug(2,Form(" AliEMCALGeometry::CreateListOfTrd1Modules() started "));
+
+ AliEMCALShishKebabTrd1Module *mod=0, *mTmp=0; // current module
+ if(fShishKebabTrd1Modules == 0) {
+ fShishKebabTrd1Modules = new TList;
+ for(int iz=0; iz< GetNZ(); iz++) {
+ if(iz==0) {
+ mod = new AliEMCALShishKebabTrd1Module(TMath::Pi()/2.,this);
+ } else {
+ mTmp = new AliEMCALShishKebabTrd1Module(*mod);
+ mod = mTmp;
+ }
+ fShishKebabTrd1Modules->Add(mod);
+ }
+ } else {
+ AliDebug(2,Form(" Already exits : "));
+ }
+ AliDebug(2,Form(" fShishKebabTrd1Modules has %i modules \n",
+ fShishKebabTrd1Modules->GetSize()));
+ // Feb 20,2006;
+ // Jun 01, 2006 - ALICE numbering scheme
+ // define grid for cells in eta(z) and x directions in local coordinates system of SM
+ // fEtaCentersOfCells = new TArrayD(fNZ *fNETAdiv);
+ // fXCentersOfCells = new TArrayD(fNZ *fNETAdiv);
+ fEtaCentersOfCells.Set(fNZ *fNETAdiv);
+ fXCentersOfCells.Set(fNZ *fNETAdiv);
+ AliDebug(2,Form(" Cells grid in eta directions : size %i\n", fEtaCentersOfCells.GetSize()));
+ Int_t iphi=0, ieta=0, nTower=0;
+ Double_t xr, zr;
+ for(Int_t it=0; it<fNZ; it++) { // array index
+ AliEMCALShishKebabTrd1Module *trd1 = GetShishKebabModule(it);
+ nTower = fNPhi*it;
+ for(Int_t ic=0; ic<fNETAdiv; ic++) { // array index
+ trd1->GetCenterOfCellInLocalCoordinateofSM(ic, xr, zr);
+ GetCellPhiEtaIndexInSModule(0, nTower, 0, ic, iphi, ieta); // don't depend from phi - ieta in action
+ fXCentersOfCells.AddAt(float(xr) - fParSM[0],ieta);
+ fEtaCentersOfCells.AddAt(float(zr) - fParSM[2],ieta);
+ }
+ }
+ for(Int_t i=0; i<fEtaCentersOfCells.GetSize(); i++) {
+ AliDebug(2,Form(" ind %2.2i : z %8.3f : x %8.3f", i+1,
+ fEtaCentersOfCells.At(i),fXCentersOfCells.At(i)));
+ }
+
+ // define grid for cells in phi(y) direction in local coordinates system of SM
+ // fPhiCentersOfCells = new TArrayD(fNPhi*fNPHIdiv);
+ fPhiCentersOfCells.Set(fNPhi*fNPHIdiv);
+ AliDebug(2,Form(" Cells grid in phi directions : size %i\n", fPhiCentersOfCells.GetSize()));
+ Int_t ind=0;
+ for(Int_t it=0; it<fNPhi; it++) { // array index
+ Float_t ytLeftCenterModule = -fParSM[1] + fPhiModuleSize*(2*it+1)/2; // module
+ for(Int_t ic=0; ic<fNPHIdiv; ic++) { // array index
+ Float_t ytLeftCenterCell = ytLeftCenterModule + fPhiTileSize *(2*ic-1)/2.; // tower(cell)
+ fPhiCentersOfCells.AddAt(ytLeftCenterCell,ind);
+ AliDebug(2,Form(" ind %2.2i : y %8.3f ", ind, fPhiCentersOfCells.At(ind)));
+ ind++;
+ }
+ }
+}
- // Boot_t kTRUE if the towers are neighbours otherwise false.
+void AliEMCALGeometry::GetTransformationForSM()
+{
+ //Uses the geometry manager to
+ //load the transformation matrix
+ //for the supermodules
+
+ static Bool_t transInit=kFALSE;
+ if(transInit) return;
+
+ int i=0;
+ if(gGeoManager == 0) {
+ Info("CreateTransformationForSM() "," Load geometry : TGeoManager::Import()");
+ assert(0);
+ }
+ TGeoNode *tn = gGeoManager->GetTopNode();
+ TGeoNode *node=0, *xen1 = 0;
+ for(i=0; i<tn->GetNdaughters(); i++) {
+ node = tn->GetDaughter(i);
+ TString ns(node->GetName());
+ if(ns.Contains(GetNameOfEMCALEnvelope())) {
+ xen1 = node;
+ break;
+ }
+ }
+ if(!xen1) {
+ Info("CreateTransformationForSM() "," geometry has not EMCAL envelope with name %s",
+ GetNameOfEMCALEnvelope());
+ assert(0);
+ }
+ printf(" i %i : EMCAL Envelope is %s : #SM %i \n", i, xen1->GetName(), xen1->GetNdaughters());
+ for(i=0; i<xen1->GetNdaughters(); i++) {
+ TGeoNodeMatrix *sm = (TGeoNodeMatrix*)xen1->GetDaughter(i);
+ fMatrixOfSM[i] = sm->GetMatrix();
+ //Compiler doesn't like this syntax...
+ // printf(" %i : matrix %x \n", i, fMatrixOfSM[i]);
+ }
+ transInit = kTRUE;
+}
- Boot_t anb = kFALSE;
+void AliEMCALGeometry::GetGlobal(const Double_t *loc, Double_t *glob, int ind) const
+{
+ // Figure out the global numbering
+ // of a given supermodule from the
+ // local numbering
+ // Alice numbering - Jun 03,2006
+ // if(fMatrixOfSM[0] == 0) GetTransformationForSM();
+
+ if(ind>=0 && ind < GetNumberOfSuperModules()) {
+ fMatrixOfSM[ind]->LocalToMaster(loc, glob);
+ }
+}
- Int_t ieta1 = 0, ieta2 = 0, iphi1 = 0, iphi2 = 0, ipre1 = 0, ipre2 = 0;
+void AliEMCALGeometry::GetGlobal(const TVector3 &vloc, TVector3 &vglob, int ind) const
+{
+ //Figure out the global numbering
+ //of a given supermodule from the
+ //local numbering given a 3-vector location
+ static Double_t tglob[3], tloc[3];
+ vloc.GetXYZ(tloc);
+ GetGlobal(tloc, tglob, ind);
+ vglob.SetXYZ(tglob[0], tglob[1], tglob[2]);
+}
+void AliEMCALGeometry::GetGlobal(Int_t absId , double glob[3]) const
+{
+ // Alice numbering scheme - Jun 03, 2006
+ static Int_t nSupMod, nModule, nIphi, nIeta;
+ static double loc[3];
+
+ glob[0]=glob[1]=glob[2]=0.0; // bad case
+ if(RelPosCellInSModule(absId, loc)) {
+ GetCellIndex(absId, nSupMod, nModule, nIphi, nIeta);
+ fMatrixOfSM[nSupMod]->LocalToMaster(loc, glob);
+ }
+}
- TowerIndexes(index1,ieta1,iphi1,ipre1);
+void AliEMCALGeometry::GetGlobal(Int_t absId , TVector3 &vglob) const
+{
+ // Alice numbering scheme - Jun 03, 2006
+ static Double_t glob[3];
- TowerIndexes(index2,ieta2,iphi2,ipre2);
+ GetGlobal(absId, glob);
+ vglob.SetXYZ(glob[0], glob[1], glob[2]);
- if(ipre1!=ipre2) return anb;
+}
- if((ieta1>=ieta2-1 && ieta1<=ieta2+1) && (iphi1>=iphi2-1 &&iphi1<=iphi2+1))
+void AliEMCALGeometry::GetGlobal(const AliRecPoint *rp, TVector3 &vglob) const
+{
+ // Figure out the global numbering
+ // of a given supermodule from the
+ // local numbering for RecPoints
- anb = kTRUE;
+ static TVector3 vloc;
+ static Int_t nSupMod, nModule, nIphi, nIeta;
- return anb;
+ AliRecPoint *rpTmp = (AliRecPoint*)rp; // const_cast ??
+ if(!rpTmp) return;
+ AliEMCALRecPoint *rpEmc = (AliEMCALRecPoint*)rpTmp;
+ GetCellIndex(rpEmc->GetAbsId(0), nSupMod, nModule, nIphi, nIeta);
+ rpTmp->GetLocalPosition(vloc);
+ GetGlobal(vloc, vglob, nSupMod);
}
- */
+void AliEMCALGeometry::EtaPhiFromIndex(Int_t absId,Float_t &eta,Float_t &phi) const
+{
+ // Jun 03, 2006 - version for TRD1
+ static TVector3 vglob;
+ GetGlobal(absId, vglob);
+ eta = vglob.Eta();
+ phi = vglob.Phi();
+}
+AliEMCALShishKebabTrd1Module* AliEMCALGeometry::GetShishKebabModule(Int_t neta=0)
+{
+ //This method was too long to be
+ //included in the header file - the
+ //rule checker complained about it's
+ //length, so we move it here. It returns the
+ //shishkebabmodule at a given eta index point.
+
+ static AliEMCALShishKebabTrd1Module* trd1=0;
+ if(fShishKebabTrd1Modules && neta>=0 && neta<fShishKebabTrd1Modules->GetSize()) {
+ trd1 = (AliEMCALShishKebabTrd1Module*)fShishKebabTrd1Modules->At(neta);
+ } else trd1 = 0;
+ return trd1;
+}