* about the suitability of this software for any purpose. It is *
* provided "as is" without express or implied warranty. *
**************************************************************************/
-
/* $Id$ */
//_________________________________________________________________________
// Implementation version v0 of EMCAL Manager class
// An object of this class does not produce hits nor digits
// It is the one to use if you do not want to produce outputs in TREEH or TREED
-//
+// This class places a Geometry of the EMCAL in the ALICE Detector as defined in AliEMCALGeometry.cxx
//*-- Author: Yves Schutz (SUBATECH)
+//*-- and : Sahal Yacoob (LBL / UCT)
+
+// This Version of AliEMCALv0 reduces the number of volumes placed in XEN1 (the envelope) to less than five hundred
+// The Envelope is Placed in Alice, And the Aluminium layer. Mini envelopes (XU) are then placed in XEN1.
+// Each mini envelope contains 1 scintillator, and 1 lead layer, except the last one which contains just one scintillator layer.
+// At the moment I cannot place the 36 and above layers in the mini envelopes so all layers are still placed in XEN1
// --- ROOT system ---
+//#include "TPGON.h"
#include "TTUBS.h"
#include "TNode.h"
-#include "TRandom.h"
#include "TGeometry.h"
-
+#include "TVirtualMC.h"
+#include "TArrayI.h"
// --- Standard library ---
-#include <iostream.h>
+//#include <stdio.h>
// --- AliRoot header files ---
#include "AliEMCALv0.h"
#include "AliEMCALGeometry.h"
#include "AliRun.h"
-#include "AliMC.h"
ClassImp(AliEMCALv0)
-//____________________________________________________________________________
+//______________________________________________________________________
AliEMCALv0::AliEMCALv0(const char *name, const char *title):
AliEMCAL(name,title)
{
- // ctor/* $Id$ */
-
- cout << " $Id$ " << endl ;
+ // ctor : title is used to identify the layout
+ GetGeometry() ;
}
-//____________________________________________________________________________
+//______________________________________________________________________
void AliEMCALv0::BuildGeometry()
{
-
- const Int_t kColorEmcal = kGreen ;
- const Int_t kColorArm1 = kBlue ;
- const Int_t kColorArm2 = kBlue ;
- const Int_t kColorArm1Active = kRed ;
- const Int_t kColorArm2Active = kRed ;
-
- // make the container of entire calorimeter
-
- new TTUBS("EMCA", "Tubs that contains the calorimeter", "void",
- fGeom->GetEnvelop(0), // rmin
- fGeom->GetEnvelop(1), // rmax
- fGeom->GetEnvelop(2)/2.0, // half length in Z
- 0.,
- 360.
- ) ;
-
- // make the container of Arm1
-
- new TTUBS("Envelop1", "Tubs that contains arm 1", "void",
- fGeom->GetEnvelop(0), // rmin
- fGeom->GetEnvelop(1), // rmax
- fGeom->GetEnvelop(2)/2.0, // half length in Z
- fGeom->GetArm1PhiMin(), // minimun phi angle
- fGeom->GetArm1PhiMax() // maximun phi angle
- ) ;
- // Active material of Arm1
-
- new TTUBS("Arm1", "Active material of arm 1", "void",
- fGeom->GetEnvelop(0) + fGeom->GetGap2Active(), // rmin
- fGeom->GetEnvelop(0) + fGeom->GetGap2Active() + fGeom->GetLmat(),// rmax
- fGeom->GetEnvelop(2)/2.0, // half length in Z
- fGeom->GetArm1PhiMin(), // minimun phi angle
- fGeom->GetArm1PhiMax() // maximun phi angle
- ) ;
- // make the container of Arm2
-
- new TTUBS("Envelop2", "Tubs that contains arm 2", "void",
- fGeom->GetEnvelop(0), // rmin
- fGeom->GetEnvelop(1), // rmax
- fGeom->GetEnvelop(2)/2.0, // half length in Z
- fGeom->GetArm2PhiMin(), // minimun phi angle
- fGeom->GetArm2PhiMax() // maximun phi angle
- ) ;
-
- // Active material of Arm2
-
- new TTUBS("Arm2", "Active material of arm 2", "void",
- fGeom->GetEnvelop(0) + fGeom->GetGap2Active(), // rmin
- fGeom->GetEnvelop(0) + fGeom->GetGap2Active() + fGeom->GetLmat(),// rmax
- fGeom->GetEnvelop(2)/2.0, // half length in Z
- fGeom->GetArm2PhiMin(), // minimun phi angle
- fGeom->GetArm2PhiMax() // maximun phi angle
- ) ;
-
- TNode * top = gAlice->GetGeometry()->GetNode("alice") ;
- top->cd();
-
- // Calorimeter inside alice
- TNode * emcanode = new TNode("EMCAL", "EMCAL Envelop", "EMCAL") ;
- emcanode->SetLineColor(kColorEmcal) ;
- fNodes->Add(emcanode) ;
-
- // Arm 1 inside Calorimeter
- emcanode->cd();
- TNode * envelop1node = new TNode("Envelop1", "Arm1 Envelop", "Envelop1") ;
- envelop1node->SetLineColor(kColorArm1) ;
- fNodes->Add(envelop1node) ;
-
- // Arm 2 inside alice
- TNode * envelop2node = new TNode("Envelop2", "Arm2 Envelop", "Envelop2") ;
- envelop2node->SetLineColor(kColorArm2) ;
- fNodes->Add(envelop2node) ;
-
- // active material inside Arm 1
- envelop1node->cd() ;
- TNode * arm1node = new TNode("Arm1", "Arm1 with Mat", "Arm1") ;
- arm1node->SetLineColor(kColorArm1Active) ;
- fNodes->Add(arm1node) ;
-
- // active material inside Arm 2
- envelop2node->cd() ;
- TNode * arm2node = new TNode("Arm2", "Arm2 with Mat", "Arm2") ;
- arm2node->SetLineColor(kColorArm2Active) ;
- fNodes->Add(arm2node) ;
-
+ // Display Geometry for display.C
+
+ const Int_t kColorArm1 = kBlue ;
+
+ AliEMCALGeometry * geom = GetGeometry() ;
+
+ // Define the shape of the Calorimeter
+ TNode * top = gAlice->GetGeometry()->GetNode("alice") ;
+ new TTUBS("Envelop1", "Tubs that contains arm 1", "void",
+ geom->GetEnvelop(0), // rmin
+ geom->GetEnvelop(1) +30 ,// rmax
+ geom->GetEnvelop(2)/2.0, // half length in Z
+ geom->GetArm1PhiMin(), // minimum phi angle
+ geom->GetArm1PhiMax() // maximum phi angle
+ );
+
+ // Place the Node
+ top->cd();
+ TNode * envelop1node = new TNode("Envelop1", "Arm1 Envelop", "Envelop1"
+ ,0., 0., 0., "") ;
+ envelop1node->SetLineColor(kColorArm1) ;
+ fNodes->Add(envelop1node) ;
}
-//____________________________________________________________________________
+//______________________________________________________________________
void AliEMCALv0::CreateGeometry()
{
// Create the EMCAL geometry for Geant
-
- AliEMCALv0 *emcaltmp = (AliEMCALv0*)gAlice->GetModule("EMCAL") ;
-
- if ( emcaltmp == NULL ) {
+ // Geometry of a tower
+ //|-----------------------------------------------------| XEN1
+ //| | | |
+ //| | Al thickness = GetAlFrontThickness() | |
+ //| | | |
+ //| | | |
+ //| | | |
+ //| ------------------------------------------------- |
+ //| | Air Gap = GetGap2Active() | |
+ //| | | |
+ //| ------------------------------------------------- |
+ //| | XU1 : XPST (ECAL e = GetECScintThick() ) | |
+ //| ------------------------------------------------- |
+ //| | XU1 : XPBX (ECAL e = GetECPbRadThick() ) | |
+ //| ------------------------------------------------- |
+ //| | XU1 : XPST (ECAL e = GetECScintThick() | |
+ //| ------------------------------------------------- |
+ //| | XU1 : XPBX (ECAL e = GetECPbRadThick() ) | |
+ //| ------------------------------------------------- |
+ //| etc ..... GetNECLayers() - 1 times |
+ //| ------------------------------------------------- |
+ //| | XUNLayer : XPST (ECAL e = GetECScintThick() | |
+ //| ------------------------------------------------- |
+
+ Float_t etamin,etamax;
+ Float_t *dum=0;
+
+ AliEMCALGeometry * geom = GetGeometry() ;
+
+ if(!(geom->IsInitialized())){
+ Error("CreateGeometry","EMCAL Geometry class has not been set up.");
+ } // end if
+
+ // Get pointer to the array containing media indices
+ Int_t *idtmed = fIdtmed->GetArray() - 1599 ;
+
+ Int_t idrotm = 1;
+ AliMatrix(idrotm, 90.0, 0., 90.0, 90.0, 0.0, 0.0) ;
+
+ // Create the EMCAL Mother Volume (a polygone) within which to place the Detector and named XEN1
+
+ Float_t envelopA[10];
+ envelopA[0] = geom->GetArm1PhiMin(); // minimum phi angle
+ envelopA[1] = geom->GetArm1PhiMax() - geom->GetArm1PhiMin(); // angular range in phi
+ envelopA[2] = geom->GetNPhi(); // number of sections in phi
+ envelopA[3] = 2; // 2 z coordinates
+ envelopA[4] = geom->ZFromEtaR(geom->GetEnvelop(1),
+ geom->GetArm1EtaMin()); // z coordinate 1
+ //add some padding for mother volume
+ envelopA[5] = geom->GetEnvelop(0) ; // rmin at z1
+ envelopA[6] = geom->GetEnvelop(1) ; // rmax at z1
+ envelopA[7] = geom->ZFromEtaR(geom->GetEnvelop(1),
+ geom->GetArm1EtaMax()); // z coordinate 2
+ envelopA[8] = envelopA[5] ; // radii are the same.
+ envelopA[9] = envelopA[6] ; // radii are the same.
+
+ gMC->Gsvolu("XEN1", "PGON ", idtmed[1599], envelopA, 10) ; // Polygone filled with air
+
+ // Position the EMCAL Mother Volume (XEN1) in Alice (ALIC)
+
+ gMC->Gspos("XEN1", 1, "ALIC", 0.0, 0.0, 0.0, idrotm, "ONLY") ;
- fprintf(stderr, "EMCAL detector not found!\n") ;
- return;
+ if (gDebug==2) {
+ printf("CreateGeometry: XEN1 = %f, %f\n", envelopA[5], envelopA[6]);
+ printf("CreateGeometry: XU0 = %f, %f\n", envelopA[5], envelopA[6]);
+ }
+ // Create mini-envelopes which will contain the Tower scintillator-radiator
- }
- // Get pointer to the array containing media indices
- Int_t *idtmed = fIdtmed->GetArray() - 1599 ;
-
- // Create the EMCA volume that contains entirely EMCAL
-
- Float_t envelopA[5] ;
- envelopA[0] = fGeom->GetEnvelop(0) ; // rmin
- envelopA[1] = fGeom->GetEnvelop(1) ; // rmax
- envelopA[2] = fGeom->GetEnvelop(2) / 2.0 ; // dz
- envelopA[3] = 0. ;
- envelopA[4] = 360.;
-
- gMC->Gsvolu("EMCA", "TUBS ", idtmed[1599], envelopA, 5) ; // filled with air
-
- // Create tube sectors that contains Arm 1 & 2
+ TString label ;
+
+ envelopA[5] = envelopA[5] + geom->GetGap2Active() // we are at the first scintllator
+ + geom->GetAlFrontThickness(); // rmin at z1
+ envelopA[6] = envelopA[5] ;
+
+
+ Int_t i ;
+
+ Int_t nLayers = geom->GetNECLayers();
+
+ for (i = 0; i < (nLayers-1); i++ ){
+ label = "XU" ;
+ label += i ;
+ Float_t tseg ;
+ tseg = geom->GetECScintThick()+geom->GetECPbRadThick(); // thickness of scintillator+Pb in E Cal
+ envelopA[5] = envelopA[6] ; // rmin at z1
+ envelopA[4] = geom->ZFromEtaR(envelopA[5] + tseg,
+ geom->GetArm1EtaMin()); // z coordinate 1
+ envelopA[7] = geom->ZFromEtaR(envelopA[5] + tseg,
+ geom->GetArm1EtaMax()); // z coordinate 2
+ envelopA[6] = envelopA[5] + tseg ; // rmax at z1
+ envelopA[8] = envelopA[5] ; // radii are the same.
+ envelopA[9] = envelopA[6] ; // radii are the same.
- envelopA[3] = fGeom->GetArm1PhiMin() ; // minimun phi angle
- envelopA[4] = fGeom->GetArm1PhiMax() ; // maximun phi angle
-
- gMC->Gsvolu("XEN1", "TUBS ", idtmed[1599], envelopA, 5) ; // filled with air
+ gMC->Gsvolu(label.Data(), "PGON", idtmed[1599], envelopA, 10);// Polygone filled with air
- envelopA[3] = fGeom->GetArm2PhiMin() ; // minimun phi angle
- envelopA[4] = fGeom->GetArm2PhiMax() ; // maximun phi angle
-
- gMC->Gsvolu("XEN2", "TUBS ", idtmed[1599], envelopA, 5) ; // filled with air
-
- // Create a tube sector that contains active material Arm 1 & 2
-
- envelopA[0] = fGeom->GetEnvelop(0) + fGeom->GetGap2Active() ;
- envelopA[1] = envelopA[0] + fGeom->GetLmat() ;
- envelopA[3] = fGeom->GetArm1PhiMin() ; // minimun phi angle
- envelopA[4] = fGeom->GetArm1PhiMax() ; // maximun phi angle
+ // Position XUi in XEN1
+
+ gMC->Gspos(label.Data(), 1, "XEN1", 0.0, 0.0, 0.0, idrotm, "ONLY") ;
- gMC->Gsvolu("XAR1", "TUBS ", idtmed[1601], envelopA, 5) ; // filled with active material (average)
+ if (gDebug == 2)
+ printf("CreateGeometry: XU%d = %f, %f\n", i, envelopA[5], envelopA[6]);
- envelopA[3] = fGeom->GetArm2PhiMin() ; // minimun phi angle
- envelopA[4] = fGeom->GetArm2PhiMax() ; // maximun phi angle
+ } // end i
- gMC->Gsvolu("XAR2", "TUBS ", idtmed[1601], envelopA, 5) ; // filled with active material (average)
- Int_t idrotm = 1;
- AliMatrix(idrotm, 90.0, 0., 90.0, 90.0, 0.0, 0.0) ;
-
- // Position Calorimeter in ALICE
- gMC->Gspos("EMCA", 1, "ALIC", 0.0, 0.0, 0.0, idrotm, "ONLY") ;
+ // Create one mini-envelope which will contain the last scintillator XU(nlayers-1) because there is one more scintillator than Pb layer XU(nlayers-1)
+
+ label = "XU" ;
+ label += i ;
+ envelopA[5] = envelopA[6] ; // rmin at z1
+ envelopA[4] = geom->ZFromEtaR(envelopA[5] + geom->GetECScintThick(),
+ geom->GetArm1EtaMin()); // z coordinate 1
+ envelopA[7] = geom->ZFromEtaR(envelopA[5] + geom->GetECScintThick(),
+ geom->GetArm1EtaMax()); // z coordinate 2
+ envelopA[6] = envelopA[5] + geom->GetECScintThick() ; // rmax at z1
+ envelopA[8] = envelopA[5] ; // radii are the same.
+ envelopA[9] = envelopA[6] ; // radii are the same.
+
+ gMC->Gsvolu(label.Data(), "PGON", idtmed[1599], envelopA, 10); // Polygone filled with air
+
+ // Position the last minienvelope in XEN1
+
+ gMC->Gspos(label.Data(), 1, "XEN1", 0.0, 0.0, 0.0, idrotm, "ONLY") ;
+
+ if(gDebug == 2)
+ printf("CreateGeometry: XEN%d = %f, %f\n", i, envelopA[5], envelopA[6]);
+
+ // Create the shapes of active material (LEAD/Aluminium/Scintillator)
+ // to be placed
+ Float_t envelopB[10]; // First Layer of Aluminium
+ Float_t envelopC[10]; // Scintillator Layers
+ Float_t envelopD[10]; // Lead Layers
+
+ envelopC[0] = envelopD[0] = envelopB[0] = envelopA[0] ; // starting position in Phi
+ envelopC[1] = envelopD[1] = envelopB[1] = envelopA[1] ; // angular range in phi
+ envelopC[2] = envelopD[2] = envelopB[2] = envelopA[2] ; // number of sections in Phi
+ envelopC[3] = envelopD[3] = envelopB[3] = envelopA[3] ; // 2 z coordinates
+
+ Float_t dist = geom->GetEnvelop(0) + geom->GetAlFrontThickness() + geom->GetGap2Active() ;
+ envelopB[4] = geom->ZFromEtaR(dist,
+ geom->GetArm1EtaMin()); // z co-ordinate 1
+ envelopB[5] = geom->GetEnvelop(0) ; // rmin at z1
+ envelopB[6] = envelopB[5] + geom->GetAlFrontThickness();// rmax at z1
+ envelopB[7] = geom->ZFromEtaR(dist,
+ geom->GetArm1EtaMax()); // z co-ordinate 2
+ envelopB[8] = envelopB[5] ; // radii are the same.
+ envelopB[9] = envelopB[6] ; // radii are the same.
+
+ // Define active volumes completely
+
+ gMC->Gsvolu("XALU", "PGON", idtmed[1602], envelopB, 10); // PGON filled with Al
+
+ gMC->Gspos("XALU", 1, "XEN1", 0.0, 0.0, 0.0 , idrotm, "ONLY") ; // Position Aluminium Layer in XEN1
- // Position ENV1 container in EMCA
- gMC->Gspos("XEN1", 1, "EMCA", 0.0, 0.0, 0.0, idrotm, "ONLY") ;
+ gMC->Gsvolu("XPST", "PGON", idtmed[1601], dum, 0); // PGON filled with Scintillator (shape to be defined by GSPOSP)
- // Position ARM1 into ENV1
- gMC->Gspos("XAR1", 1, "XEN1", 0.0, 0.0, 0.0, idrotm, "ONLY") ;
+ gMC->Gsvolu("XPBX", "PGON", idtmed[1600], dum, 0); // PGON filled with Lead (shape to be defined by GSPOSP)
+
+ //gMC->Gsvolu("XCUX", "PGON", idtmed[1603], dum, 0); // PGON filled with Copper (shape to be defined by GSPOSP)
- // Position ENV2 container in ALIC
- gMC->Gspos("XEN2", 1, "EMCA", 0.0, 0.0, 0.0, idrotm, "ONLY") ;
+ gMC->Gsdvn("XPHI", "XPST", geom->GetNPhi(), 2); // Divide eta section of scintillators into phi segments.
+
+ // Position alternatively scintillator and Lead Layers in XUi.
- // Position ARM2 into ENV2
- gMC->Gspos("XAR2", 1, "XEN2", 0.0, 0.0, 0.0, idrotm, "ONLY") ;
-
+ envelopD[6] = envelopB[6] + geom->GetGap2Active() ;// gap between Al layer and XU0
+
+ for (int i = 0; i < nLayers; i++ ){
+ label = "XU" ;
+ label += i ; // we will place one layer in each mini envelope)
+
+ Float_t scthick ; // scintillator thickness
+ scthick = geom->GetECScintThick() ;
+
+ envelopC[5] = envelopD[6] ; //rmin
+ envelopC[6] = envelopC[5] + scthick ; //rmax
+ envelopC[8] = envelopC[5] ; //rmin
+ envelopC[9] = envelopC[6] ; //rmax
+
+ if(gDebug == 2 )
+ printf("CreateGeometry: volume = %s, name = XPST thickness = %f deb = %f/%f fin = %f/%f", label.Data(), scthick, envelopC[5], envelopC[8], envelopC[6], envelopC[9]) ;
+
+ for (int j =0; j < (geom->GetNEta()) ; j++){
+ etamin = geom->GetArm1EtaMin()+
+ (j*geom->GetDeltaEta());
+ etamax = geom->GetArm1EtaMin()+
+ ((j+1)*geom->GetDeltaEta());
+ envelopC[4] = geom->ZFromEtaR(envelopC[5],etamin); //z begin
+ envelopC[7] = geom->ZFromEtaR(envelopC[5],etamax);// z end
+
+ gMC->Gsposp("XPST",1+j+i*(geom->GetNEta()), label.Data(),
+ 0.0, 0.0, 0.0 , idrotm, "ONLY", envelopC, 10); // Position and define layer
+ } // end for j
+
+ Float_t radthick ; // radiator thickness
+ TString radname ; // radiator name
+ radthick = geom->GetECPbRadThick();
+ radname = "XPBX" ;
+
+ if ( i < nLayers -1 ) { // except for the last XU which contains only one scintillator layer
+
+ envelopD[5] = envelopC[6] ; //rmin
+ envelopD[8] = envelopD[5] ; //rmin
+ envelopD[6] = envelopD[5] + radthick ; // rmax
+ envelopD[9] = envelopD[6] ; //rmax
+
+ if(gDebug == 2 )
+ printf("CreateGeometry: volume = %s, name = %s thickness = %f deb = %f/%f fin = %f/%f", label.Data(), radname.Data(), radthick, envelopD[5], envelopD[8], envelopD[6], envelopD[9]) ;
+
+ for (int j =0; j < (geom->GetNEta()) ; j++){
+ etamin = geom->GetArm1EtaMin()+
+ (j*geom->GetDeltaEta());
+ etamax = geom->GetArm1EtaMin()+
+ ((j+1)*geom->GetDeltaEta());
+ envelopD[4] = geom->ZFromEtaR(envelopD[5],etamin);//z begin
+ envelopD[7] = geom->ZFromEtaR(envelopD[5],etamax);// z end
+
+ // Position and Define Layer
+
+ gMC->Gsposp(radname.Data(),1+j+i*(geom->GetNEta()), label.Data(),
+ 0.0, 0.0, 0.0 , idrotm, "ONLY", envelopD, 10);
+ } // end for j
+ } // if not last layer
+ } // for i
}
-//____________________________________________________________________________
+//______________________________________________________________________
void AliEMCALv0::Init(void)
{
- // Just prints an information message
-
- Int_t i;
-
- printf("\n");
- for(i=0;i<35;i++) printf("*");
- printf(" EMCAL_INIT ");
- for(i=0;i<35;i++) printf("*");
- printf("\n");
-
- // Here the EMCAL initialisation code (if any!)
-
- if (fGeom!=0)
- cout << "AliEMCAL" << Version() << " : EMCAL geometry intialized for " << fGeom->GetName() << endl ;
- else
- cout << "AliEMCAL" << Version() << " : EMCAL geometry initialization failed !" << endl ;
-
- for(i=0;i<80;i++) printf("*");
- printf("\n");
+ // Just prints an information message
+ if(fDebug) {
+ TString message("\n") ;
+ message += "*****************************************\n" ;
+
+ // Here the EMCAL initialisation code (if any!)
+
+ AliEMCALGeometry * geom = GetGeometry() ;
+
+ if (geom!=0) {
+ message += "AliEMCAL " ;
+ message += Version() ;
+ message += "EMCAL geometry initialized for " ;
+ message += geom->GetName() ;
+ }
+ else {
+ message += "AliEMCAL " ;
+ message += Version() ;
+ message += "EMCAL geometry initialization failed !" ;
+ }
+ message += "\n*****************************************" ;
+ printf(message.Data() ) ;
+ }
}
-