/************************************************************************** * Copyright(c) 1998-1999, ALICE Experiment at CERN, All rights reserved. * * * * Author: The ALICE Off-line Project. * * Contributors are mentioned in the code where appropriate. * * * * Permission to use, copy, modify and distribute this software and its * * documentation strictly for non-commercial purposes is hereby granted * * without fee, provided that the above copyright notice appears in all * * copies and that both the copyright notice and this permission notice * * appear in the supporting documentation. The authors make no claims * * about the suitability of this software for any purpose. It is * * provided "as is" without express or implied warranty. * **************************************************************************/ /* $Id: AliACORDEv1.cxx,v 1.2 2007/12/03 08:40:00 hristov Exp $ */ /////////////////////////////////////////////////////////////////////////////// // // // ALICE Cosmic Ray Trigger // // // // This class contains the functions for final version of the ALICE Cosmic // // Ray Trigger. This version will be used to simulation comic rays in alice // // with all the detectors. It includes the last survey of 2009. // // It include geometry and hits (position and momentum) // // // // Author: Mario Rodriguez Cahuantzi, FCFM-BUAP, Puebla, Pue. Mexico // // // // Send comments to: // // // // Arturo Fernandez Tellez // // Eleazar Cuautle Flores // // Mario Rodriguez Cahuantzi // // // // Puebla, Pue. Mexico December 2007 // // // // Last Update: Nov. 17th 2009 // // Mario Rodriguez Cahuantzi // /////////////////////////////////////////////////////////////////////////////// #include #include #include #include #include #include "AliConst.h" #include "AliRun.h" #include "TGeoManager.h" #include "TGeoVolume.h" #include "TGeoPcon.h" #include "TGeoPgon.h" #include "TGeoTrd1.h" #include "TGeoCompositeShape.h" #include "TGeoPara.h" #include "AliACORDEv1.h" #include #include #include #include #include "AliRun.h" #include "AliConst.h" #include "AliACORDEhit.h" #include "AliACORDEConstants.h" #include "AliMC.h" #include "AliLog.h" ClassImp(AliACORDEv1) //_____________________________________________________________________________ AliACORDEv1::AliACORDEv1() : AliACORDE() { // // Default constructor fIshunt = 0; fHits = 0; // } //_____________________________________________________________________________ AliACORDEv1::AliACORDEv1(const char *name, const char *title) : AliACORDE(name, title) { // // Standard constructor // fIshunt = 1; // All hits are associated with primary particles fHits = new TClonesArray("AliACORDEhit",400); gAlice->GetMCApp()->AddHitList(fHits); } //_____________________________________________________________________________ AliACORDEv1::~AliACORDEv1() { // // Default destructor // } //_____________________________________________________________________________ void AliACORDEv1::CreateGeometry() { CreateAcorde(); } void AliACORDEv1::CreateAcorde() { // Call the global constants for the Modules AliACORDEConstants* constants = AliACORDEConstants::Instance(); // Get the Alice Volume TGeoVolume *alice = gGeoManager->GetVolume("ALIC"); // Define some materials & medium //*** Aluminium *** TGeoMedium* aluminium = gGeoManager->GetMedium("ACORDE_ALU_C0"); //*** Scintillator *** TGeoMedium* scintillator = gGeoManager->GetMedium("ACORDE_CPV scint.1"); //Define the mother volume for the ACORDE detector TGeoVolume *acorde = new TGeoVolumeAssembly("ACORDE"); // Define 2 main-daughter volumes for ACORDE TGeoVolume *supportBars = new TGeoVolumeAssembly("ACORDE_SUPPORTS_BARS"); TGeoVolume *acordeModules = new TGeoVolumeAssembly("ALL_ACORDE_MODULES"); // Define rotation Matrix for Side's faces in Alice TGeoRotation *idrotm231 = new TGeoRotation("idrotm231",90, 45, 90, 135, 0, 0); TGeoRotation *idrotm232 = new TGeoRotation("idrotm232",90, 315, 90, 45, 0, 0); // Begin the Geometry for ACORDE // *** Definition of ACORDE's Modules *** // Define Measures of ACORDE's Modules Float_t acoFrameBox1[3],acoFrameBox2[3]; acoFrameBox1[0] = constants->ModuleLength()/2; acoFrameBox1[1] = constants->ModuleHeight()/2; acoFrameBox1[2] = 2.50; acoFrameBox2[0] = 20.0; acoFrameBox2[1] = constants->ModuleHeight()/2; acoFrameBox2[2] = 10.0; // Define Measures of Scintillators Float_t acoScinBox[3]; acoScinBox[0] = constants->PlasticLength()/2; acoScinBox[1] = constants->PlasticHeight()/2; acoScinBox[2] = constants->PlasticWidth()/2; // Create the Modules of ACORDE, 1 aluminium frame and two scintillator plastics //*** Aluminium frame *** TGeoBBox *acordeModFrameBoxL = new TGeoBBox("acordeModFrameBoxL",acoFrameBox1[0],acoFrameBox1[1],acoFrameBox1[2]); TGeoBBox *acordeModFrameBoxH = new TGeoBBox("acordeModFrameBoxH",acoFrameBox2[0],acoFrameBox2[1],acoFrameBox2[2]); TGeoVolume *acordeModFrameVolumeL = new TGeoVolume("ACORDEMODFRAMEVOLUMEL",acordeModFrameBoxL,aluminium); TGeoVolume *acordeModFrameVolumeH = new TGeoVolume("ACORDEMODFRAMEVOLUMEH",acordeModFrameBoxH,aluminium); //*** Scintillators *** TGeoBBox *acordeScintillatorBox = new TGeoBBox("acordeScintillatorBox",acoScinBox[0],acoScinBox[1],acoScinBox[2]); TGeoVolume *acordeScintillatorVolume = new TGeoVolume("ACORDESCINTILLATORMODULE",acordeScintillatorBox,scintillator); // Here I create a single ACORDE module and then we make 60 copies of it TGeoVolume *acordeSingleModule = new TGeoVolumeAssembly("ACORDE_MODULE"); acordeSingleModule->AddNode(acordeModFrameVolumeL,1,new TGeoTranslation("acordeFrame_01",0,0,12.5)); acordeSingleModule->AddNode(acordeModFrameVolumeL,2,new TGeoTranslation("acordeFrame_02",0,0,-12.5)); acordeSingleModule->AddNode(acordeModFrameVolumeH,3,new TGeoTranslation("acordeFrame_03",130,0,0)); acordeSingleModule->AddNode(acordeModFrameVolumeH,4,new TGeoTranslation("acordeFrame_04",-130,0,0)); acordeSingleModule->AddNode(acordeScintillatorVolume,5, new TGeoTranslation("acordeScintillator_01",0,1,0)); acordeSingleModule->AddNode(acordeScintillatorVolume,6, new TGeoTranslation("acordeScintillator_01",0,-1,0)); // Put the Modules of In-Face for(Int_t iAcordeModule=1;iAcordeModule<9;iAcordeModule++) { Float_t posx = constants->CenterModulePositionX(iAcordeModule); Float_t posy = constants->CenterModulePositionY(iAcordeModule); Float_t posz = constants->CenterModulePositionZ(iAcordeModule); acordeModules->AddNode(acordeSingleModule,iAcordeModule, new TGeoCombiTrans("aco01",posx,posy,posz,idrotm232)); } for(Int_t iAcordeModule=10;iAcordeModule<20;iAcordeModule++) { Float_t posx = constants->CenterModulePositionX(iAcordeModule); Float_t posy = constants->CenterModulePositionY(iAcordeModule); Float_t posz = constants->CenterModulePositionZ(iAcordeModule); acordeModules->AddNode(acordeSingleModule,iAcordeModule, new TGeoCombiTrans("aco01",posx,posy,posz,idrotm232)); } // Put he Modules of Up-Face for(Int_t iAcordeModule=20;iAcordeModule<40;iAcordeModule++) { Float_t posx = constants->CenterModulePositionX(iAcordeModule); Float_t posy = constants->CenterModulePositionY(iAcordeModule); Float_t posz = constants->CenterModulePositionZ(iAcordeModule); acordeModules->AddNode(acordeSingleModule,iAcordeModule,new TGeoTranslation("aco01",posx,posy,posz)); } // Put the Modules of Out-Face for(Int_t iAcordeModule=40;iAcordeModule<50;iAcordeModule++) { Float_t posx = constants->CenterModulePositionX(iAcordeModule); Float_t posy = constants->CenterModulePositionY(iAcordeModule); Float_t posz = constants->CenterModulePositionZ(iAcordeModule); acordeModules->AddNode(acordeSingleModule,iAcordeModule, new TGeoCombiTrans("aco01",posx,posy,posz,idrotm231)); } // Put the Modules of Out-Face for(Int_t iAcordeModule=51;iAcordeModule<59;iAcordeModule++) { Float_t posx = constants->CenterModulePositionX(iAcordeModule); Float_t posy = constants->CenterModulePositionY(iAcordeModule); Float_t posz = constants->CenterModulePositionZ(iAcordeModule); acordeModules->AddNode(acordeSingleModule,iAcordeModule, new TGeoCombiTrans("aco01",posx,posy,posz,idrotm231)); } // Put the 4-central modules (Old-ITS modules) if (Get4CentralModulesGeometry()) { acordeModules->AddNode(acordeSingleModule,0, new TGeoTranslation("Mod0_0",constants->CenterModulePositionX(0),constants->CenterModulePositionY(0),constants->CenterModulePositionZ(0))); acordeModules->AddNode(acordeSingleModule,9, new TGeoTranslation("Mod0_9",constants->CenterModulePositionX(9),constants->CenterModulePositionY(9),constants->CenterModulePositionZ(9))); acordeModules->AddNode(acordeSingleModule,50, new TGeoTranslation("Mod0_50",constants->CenterModulePositionX(50),constants->CenterModulePositionY(50),constants->CenterModulePositionZ(50))); acordeModules->AddNode(acordeSingleModule,59, new TGeoTranslation("Mod0_59",constants->CenterModulePositionX(59),constants->CenterModulePositionY(59),constants->CenterModulePositionZ(59))); } // Create a dummy support & bars of Aluminium (it doesn't exist a survey of this structure) Float_t boxLongSupport[3],boxThinSupport[3]; boxLongSupport[0]=10.0; boxLongSupport[1]=0.5; boxLongSupport[2]=500.0; boxThinSupport[0]=1.0; boxThinSupport[1]=7.0; boxThinSupport[2]=500.0; TGeoBBox *acordeLongSupport = new TGeoBBox("ACORDELONGSUPPORT",boxLongSupport[0],boxLongSupport[1],boxLongSupport[2]); TGeoBBox *acordeThinSupport = new TGeoBBox("ACORDETHINSUPPORT",boxThinSupport[0],boxThinSupport[1],boxThinSupport[2]); TGeoVolume *acordeLSupport = new TGeoVolume("ACORDELS",acordeLongSupport,aluminium); TGeoVolume *acordeTSupport = new TGeoVolume("ACORDETS",acordeThinSupport,aluminium); TGeoVolume *acordeMainSupport = new TGeoVolumeAssembly("ACORDE_SUPPORT"); acordeMainSupport->AddNode(acordeLSupport,1,new TGeoTranslation("ACOLSA",0,7.5,0)); acordeMainSupport->AddNode(acordeLSupport,2,new TGeoTranslation("ACOLSB",0,-7.5,0)); acordeMainSupport->AddNode(acordeTSupport,3); // Set the values for the bars support Float_t boxSingleBar[3]; boxSingleBar[0]=10; boxSingleBar[1]=37;//36.722; // Correction to avoid overlaps with the L3 magnet boxSingleBar[2]=10; Float_t boxUnionUp[3]; boxUnionUp[0]=10; boxUnionUp[1]=0.5; boxUnionUp[2]=15; Float_t boxUnionDown[3]; boxUnionDown[0]=20; boxUnionDown[1]=1; boxUnionDown[2]=20; // Volume and Box for the bar TGeoBBox *acordeSingleBarSupport = new TGeoBBox("ACORDESBARS",boxSingleBar[0],boxSingleBar[1],boxSingleBar[2]); TGeoVolume *acordeBarSupport = new TGeoVolume("ACORDEBARSUPPORT",acordeSingleBarSupport,aluminium); // Volume and Box for the bar union with the long support (Up-with supports and Down with L3 magnet) TGeoBBox *acordeSingleBoxUnionUp = new TGeoBBox("ACORDEBUP",boxUnionUp[0],boxUnionUp[1],boxUnionUp[2]); TGeoVolume *acordeBoxUnionUp = new TGeoVolume("ACORDEBOXUNIONUP",acordeSingleBoxUnionUp,aluminium); TGeoBBox *acordeSingleBoxUnionDown = new TGeoBBox("ACORDEBDOWN",boxUnionDown[0],boxUnionDown[1],boxUnionDown[2]); TGeoVolume *acordeBoxUnionDown = new TGeoVolume("ACORDEBOXUNIONDOWN",acordeSingleBoxUnionDown,aluminium); TGeoVolume *acordeMainBar = new TGeoVolumeAssembly("ACORDE_BAR"); acordeMainBar->AddNode(acordeBoxUnionUp,1,new TGeoTranslation("ACOBAR01",0,boxSingleBar[1]+boxUnionUp[1],0)); acordeMainBar->AddNode(acordeBarSupport,2); acordeMainBar->AddNode(acordeBoxUnionDown,3,new TGeoTranslation("ACOBAR01",0,-boxSingleBar[1]-boxUnionDown[1],0)); // Volume for the Full support (supports and bars) UP face of L3 Magnet Float_t supportPosXIn = constants->CenterModulePositionX(20); Float_t supportPosY = 859.044-7.5-5.5; // Minimum module position Y less the heigh of the support Float_t supportPosZ = 0; Float_t supportPosXOut = constants->CenterModulePositionX(30); Float_t deltaXA = 120.; Float_t deltaXB = 60.; TGeoVolume *acordeFullSupportUpFace = new TGeoVolumeAssembly("ACORDE_FULL_SUPPORT_UPFACE"); acordeFullSupportUpFace->AddNode(acordeMainSupport,1,new TGeoTranslation("ACOFSB01",supportPosXIn+deltaXA,supportPosY,supportPosZ)); acordeFullSupportUpFace->AddNode(acordeMainSupport,2,new TGeoTranslation("ACOFSB02",supportPosXIn+deltaXB,supportPosY,supportPosZ)); acordeFullSupportUpFace->AddNode(acordeMainSupport,3,new TGeoTranslation("ACOFSB03",supportPosXIn-deltaXA,supportPosY,supportPosZ)); acordeFullSupportUpFace->AddNode(acordeMainSupport,4,new TGeoTranslation("ACOFSB04",supportPosXIn-deltaXB,supportPosY,supportPosZ)); acordeFullSupportUpFace->AddNode(acordeMainSupport,5,new TGeoTranslation("ACOFSB05",supportPosXOut+deltaXA,supportPosY,supportPosZ)); acordeFullSupportUpFace->AddNode(acordeMainSupport,6,new TGeoTranslation("ACOFSB06",supportPosXOut+deltaXB,supportPosY,supportPosZ)); acordeFullSupportUpFace->AddNode(acordeMainSupport,7,new TGeoTranslation("ACOFSB07",supportPosXOut-deltaXA,supportPosY,supportPosZ)); acordeFullSupportUpFace->AddNode(acordeMainSupport,8,new TGeoTranslation("ACOFSB08",supportPosXOut-deltaXB,supportPosY,supportPosZ)); // Put the bars in the main volume acordeFullSupportUpFace Float_t barPosXIn = constants->CenterModulePositionX(20); Float_t barPosY = supportPosY-boxSingleBar[1]-boxUnionUp[1]-boxUnionDown[1]-7.5; Float_t barPosZ = 0; Int_t barIndex = 9; for(Int_t iBarModule = 20; iBarModule<30; iBarModule+=2) { barPosZ = constants->CenterModulePositionZ(iBarModule); acordeFullSupportUpFace->AddNode(acordeMainBar,barIndex,new TGeoTranslation("ACOFSB09",barPosXIn+deltaXA,barPosY,barPosZ)); acordeFullSupportUpFace->AddNode(acordeMainBar,barIndex+1,new TGeoTranslation("ACOFSB09",barPosXIn+deltaXB,barPosY,barPosZ)); acordeFullSupportUpFace->AddNode(acordeMainBar,barIndex+2,new TGeoTranslation("ACOFSB09",barPosXIn-deltaXA,barPosY,barPosZ)); acordeFullSupportUpFace->AddNode(acordeMainBar,barIndex+3,new TGeoTranslation("ACOFSB09",barPosXIn-deltaXB,barPosY,barPosZ)); barIndex+=4; } Float_t barPosXOut = constants->CenterModulePositionX(30); for(Int_t iBarModule = 30; iBarModule<40; iBarModule+=2) { barPosZ = constants->CenterModulePositionZ(iBarModule); acordeFullSupportUpFace->AddNode(acordeMainBar,barIndex,new TGeoTranslation("ACOFSB09",barPosXOut+deltaXA,barPosY,barPosZ)); acordeFullSupportUpFace->AddNode(acordeMainBar,barIndex+1,new TGeoTranslation("ACOFSB09",barPosXOut+deltaXB,barPosY,barPosZ)); acordeFullSupportUpFace->AddNode(acordeMainBar,barIndex+2,new TGeoTranslation("ACOFSB09",barPosXOut-deltaXA,barPosY,barPosZ)); acordeFullSupportUpFace->AddNode(acordeMainBar,barIndex+3,new TGeoTranslation("ACOFSB09",barPosXOut-deltaXB,barPosY,barPosZ)); barIndex+=4; } // Supports and bars for the InSide of L3 Magnet TGeoVolume *acordeFullSupportInFace = new TGeoVolumeAssembly("ACORDE_FULL_SUPPORT_INFACE"); Float_t supportPosXInA = constants->CenterModulePositionX(1)+deltaXA; Float_t supportPosYInA = 592.017-7.5-5.5; Float_t x0 = constants->CenterModulePositionX(1); Float_t y0 = constants->CenterModulePositionY(1); Float_t theta = -1*TMath::Pi()/4; Float_t supportPosXInPA = x0+(supportPosXInA-x0)*TMath::Cos(theta)-(supportPosYInA-y0)*TMath::Sin(theta); Float_t supportPosYInPA = y0+(supportPosYInA-y0)*TMath::Cos(theta)+(supportPosXInA-x0)*TMath::Sin(theta); Float_t supportPosZInIn = 0; Float_t supportPosXInB = constants->CenterModulePositionX(1)+deltaXB; Float_t supportPosXInPB = x0+(supportPosXInB-x0)*TMath::Cos(theta)-(supportPosYInA-y0)*TMath::Sin(theta); Float_t supportPosYInPB = y0+(supportPosYInA-y0)*TMath::Cos(theta)+(supportPosXInB-x0)*TMath::Sin(theta); Float_t supportPosXInC = constants->CenterModulePositionX(1)-deltaXA; Float_t supportPosXInPC = x0+(supportPosXInC-x0)*TMath::Cos(theta)-(supportPosYInA-y0)*TMath::Sin(theta); Float_t supportPosYInPC = y0+(supportPosYInA-y0)*TMath::Cos(theta)+(supportPosXInC-x0)*TMath::Sin(theta); Float_t supportPosXInD = constants->CenterModulePositionX(1)-deltaXB; Float_t supportPosXInPD = x0+(supportPosXInD-x0)*TMath::Cos(theta)-(supportPosYInA-y0)*TMath::Sin(theta); Float_t supportPosYInPD = y0+(supportPosYInA-y0)*TMath::Cos(theta)+(supportPosXInD-x0)*TMath::Sin(theta); acordeFullSupportInFace->AddNode(acordeMainSupport,1,new TGeoCombiTrans("ACOFSBIN01",supportPosXInPA,supportPosYInPA,supportPosZInIn,idrotm232)); acordeFullSupportInFace->AddNode(acordeMainSupport,2,new TGeoCombiTrans("ACOFSBIN02",supportPosXInPB,supportPosYInPB,supportPosZInIn,idrotm232)); acordeFullSupportInFace->AddNode(acordeMainSupport,3,new TGeoCombiTrans("ACOFSBIN03",supportPosXInPC,supportPosYInPC,supportPosZInIn,idrotm232)); acordeFullSupportInFace->AddNode(acordeMainSupport,4,new TGeoCombiTrans("ACOFSBIN04",supportPosXInPD,supportPosYInPD,supportPosZInIn,idrotm232)); Float_t supportPosXInE = constants->CenterModulePositionX(10)+deltaXA; Float_t supportPosYInE = 806.312-7.5-5.5; Float_t x00 = constants->CenterModulePositionX(10); Float_t y00 = constants->CenterModulePositionY(10); Float_t supportPosXInPE = x00+(supportPosXInE-x00)*TMath::Cos(theta)-(supportPosYInE-y00)*TMath::Sin(theta); Float_t supportPosYInPE = y00+(supportPosYInE-y00)*TMath::Cos(theta)+(supportPosXInE-x00)*TMath::Sin(theta); Float_t supportPosXInF = constants->CenterModulePositionX(10)+deltaXB; Float_t supportPosXInPF = x00+(supportPosXInF-x00)*TMath::Cos(theta)-(supportPosYInE-y00)*TMath::Sin(theta); Float_t supportPosYInPF = y00+(supportPosYInE-y00)*TMath::Cos(theta)+(supportPosXInF-x00)*TMath::Sin(theta); Float_t supportPosXInG = constants->CenterModulePositionX(10)-deltaXA+100; Float_t supportPosXInPG = x00+(supportPosXInG-x00)*TMath::Cos(theta)-(supportPosYInE-y00)*TMath::Sin(theta); Float_t supportPosYInPG = y00+(supportPosYInE-y00)*TMath::Cos(theta)+(supportPosXInG-x00)*TMath::Sin(theta); acordeFullSupportInFace->AddNode(acordeMainSupport,5,new TGeoCombiTrans("ACOFSBIN05",supportPosXInPE,supportPosYInPE,supportPosZInIn,idrotm232)); acordeFullSupportInFace->AddNode(acordeMainSupport,6,new TGeoCombiTrans("ACOFSBIN06",supportPosXInPF,supportPosYInPF,supportPosZInIn,idrotm232)); acordeFullSupportInFace->AddNode(acordeMainSupport,7,new TGeoCombiTrans("ACOFSBIN07",supportPosXInPG,supportPosYInPG,supportPosZInIn,idrotm232)); // Put the bars in the main volume acordeFullSupportInFace Int_t barIndexIn = 8; for (Int_t iBarModule=1; iBarModule<9; iBarModule+=2) { Float_t barPosXInIn = constants->CenterModulePositionX(iBarModule)+deltaXA; Float_t barPosYInIn = supportPosYInA-boxSingleBar[1]-boxUnionUp[1]-boxUnionDown[1]-7.5; Float_t barPosZInIn = constants->CenterModulePositionZ(iBarModule); Float_t barPosXInP = x0+(barPosXInIn-x0)*TMath::Cos(theta)-(barPosYInIn-y0)*TMath::Sin(theta); Float_t barPosYInP = y0+(barPosYInIn-y0)*TMath::Cos(theta)+(barPosXInIn-x0)*TMath::Sin(theta); Float_t barPosXInInA = constants->CenterModulePositionX(iBarModule)+deltaXB; Float_t barPosYInInA = supportPosYInA-boxSingleBar[1]-boxUnionUp[1]-boxUnionDown[1]-7.5; Float_t barPosZInInA = constants->CenterModulePositionZ(iBarModule); Float_t barPosXInPA = x0+(barPosXInInA-x0)*TMath::Cos(theta)-(barPosYInInA-y0)*TMath::Sin(theta); Float_t barPosYInPA = y0+(barPosYInInA-y0)*TMath::Cos(theta)+(barPosXInInA-x0)*TMath::Sin(theta); Float_t barPosXInInB = constants->CenterModulePositionX(iBarModule)-deltaXA; Float_t barPosYInInB = supportPosYInA-boxSingleBar[1]-boxUnionUp[1]-boxUnionDown[1]-7.5; Float_t barPosZInInB = constants->CenterModulePositionZ(iBarModule); Float_t barPosXInPB = x0+(barPosXInInB-x0)*TMath::Cos(theta)-(barPosYInInB-y0)*TMath::Sin(theta); Float_t barPosYInPB = y0+(barPosYInInB-y0)*TMath::Cos(theta)+(barPosXInInB-x0)*TMath::Sin(theta); Float_t barPosXInInC = constants->CenterModulePositionX(iBarModule)-deltaXB; Float_t barPosYInInC = supportPosYInA-boxSingleBar[1]-boxUnionUp[1]-boxUnionDown[1]-7.5; Float_t barPosZInInC = constants->CenterModulePositionZ(iBarModule); Float_t barPosXInPC = x0+(barPosXInInC-x0)*TMath::Cos(theta)-(barPosYInInC-y0)*TMath::Sin(theta); Float_t barPosYInPC = y0+(barPosYInInC-y0)*TMath::Cos(theta)+(barPosXInInC-x0)*TMath::Sin(theta); acordeFullSupportInFace->AddNode(acordeMainBar,barIndexIn,new TGeoCombiTrans("ACOFSBIN08",barPosXInP,barPosYInP,barPosZInIn,idrotm232)); acordeFullSupportInFace->AddNode(acordeMainBar,barIndexIn+1,new TGeoCombiTrans("ACOFSBIN09",barPosXInPA,barPosYInPA,barPosZInInA,idrotm232)); acordeFullSupportInFace->AddNode(acordeMainBar,barIndexIn+2,new TGeoCombiTrans("ACOFSBIN10",barPosXInPB,barPosYInPB,barPosZInInB,idrotm232)); acordeFullSupportInFace->AddNode(acordeMainBar,barIndexIn+3,new TGeoCombiTrans("ACOFSBIN11",barPosXInPC,barPosYInPC,barPosZInInC,idrotm232)); barIndexIn+=4; } for (Int_t iBarModule=10; iBarModule<20; iBarModule+=2) { Float_t barPosXInIn = constants->CenterModulePositionX(iBarModule)+deltaXA; Float_t barPosYInIn = supportPosYInE-boxSingleBar[1]-boxUnionUp[1]-boxUnionDown[1]-7.5; Float_t barPosZInIn = constants->CenterModulePositionZ(iBarModule); Float_t barPosXInP = x00+(barPosXInIn-x00)*TMath::Cos(theta)-(barPosYInIn-y00)*TMath::Sin(theta); Float_t barPosYInP = y00+(barPosYInIn-y00)*TMath::Cos(theta)+(barPosXInIn-x00)*TMath::Sin(theta); Float_t barPosXInInA = constants->CenterModulePositionX(iBarModule)+deltaXB; Float_t barPosYInInA = supportPosYInE-boxSingleBar[1]-boxUnionUp[1]-boxUnionDown[1]-7.5; Float_t barPosZInInA = constants->CenterModulePositionZ(iBarModule); Float_t barPosXInPA = x00+(barPosXInInA-x00)*TMath::Cos(theta)-(barPosYInInA-y00)*TMath::Sin(theta); Float_t barPosYInPA = y00+(barPosYInInA-y00)*TMath::Cos(theta)+(barPosXInInA-x00)*TMath::Sin(theta); Float_t barPosXInInB = constants->CenterModulePositionX(iBarModule)-deltaXA+100; Float_t barPosYInInB = supportPosYInE-boxSingleBar[1]-boxUnionUp[1]-boxUnionDown[1]-7.5; Float_t barPosZInInB = constants->CenterModulePositionZ(iBarModule); Float_t barPosXInPB = x00+(barPosXInInB-x00)*TMath::Cos(theta)-(barPosYInInB-y00)*TMath::Sin(theta); Float_t barPosYInPB = y00+(barPosYInInB-y00)*TMath::Cos(theta)+(barPosXInInB-x00)*TMath::Sin(theta); acordeFullSupportInFace->AddNode(acordeMainBar,barIndexIn,new TGeoCombiTrans("ACOFSBIN08",barPosXInP,barPosYInP,barPosZInIn,idrotm232)); acordeFullSupportInFace->AddNode(acordeMainBar,barIndexIn+1,new TGeoCombiTrans("ACOFSBIN09",barPosXInPA,barPosYInPA,barPosZInInA,idrotm232)); acordeFullSupportInFace->AddNode(acordeMainBar,barIndexIn+2,new TGeoCombiTrans("ACOFSBIN10",barPosXInPB,barPosYInPB,barPosZInInB,idrotm232)); barIndexIn+=4; } // Construction of the support and bars for the OutSide TGeoVolume *acordeFullSupportOutFace = new TGeoVolumeAssembly("ACORDE_FULL_SUPPORT_OUTFACE"); Float_t supportPosXOutA = constants->CenterModulePositionX(45)+deltaXA-90; Float_t supportPosYOutA = 807.2915-7.5-5.5; Float_t x000 = constants->CenterModulePositionX(45); Float_t y000 = constants->CenterModulePositionY(45); Float_t theta1 = 1*TMath::Pi()/4; Float_t supportPosXOutPA = x000+(supportPosXOutA-x000)*TMath::Cos(theta1)-(supportPosYOutA-y000)*TMath::Sin(theta1); Float_t supportPosYOutPA = y000+(supportPosYOutA-y000)*TMath::Cos(theta1)+(supportPosXOutA-x000)*TMath::Sin(theta1); Float_t supportPosZOutIn = 0; Float_t supportPosXOutC = constants->CenterModulePositionX(45)-deltaXA; Float_t supportPosXOutPC = x000+(supportPosXOutC-x000)*TMath::Cos(theta1)-(supportPosYOutA-1-y000)*TMath::Sin(theta1); Float_t supportPosYOutPC = y000+(supportPosYOutA-1-y000)*TMath::Cos(theta1)+(supportPosXOutC-x000)*TMath::Sin(theta1); Float_t supportPosXOutD = constants->CenterModulePositionX(45)-deltaXB; Float_t supportPosXOutPD = x000+(supportPosXOutD-x000)*TMath::Cos(theta1)-(supportPosYOutA-1-y000)*TMath::Sin(theta1); Float_t supportPosYOutPD = y000+(supportPosYOutA-1-y000)*TMath::Cos(theta1)+(supportPosXOutD-x000)*TMath::Sin(theta1); acordeFullSupportOutFace->AddNode(acordeMainSupport,1,new TGeoCombiTrans("ACOFSBOUT01",supportPosXOutPA,supportPosYOutPA,supportPosZOutIn,idrotm231)); acordeFullSupportOutFace->AddNode(acordeMainSupport,2,new TGeoCombiTrans("ACOFSBOUT02",supportPosXOutPC,supportPosYOutPC,supportPosZOutIn,idrotm231)); acordeFullSupportOutFace->AddNode(acordeMainSupport,3,new TGeoCombiTrans("ACOFSBOUT03",supportPosXOutPD,supportPosYOutPD,supportPosZOutIn,idrotm231)); Float_t supportPosXOutE = constants->CenterModulePositionX(52)+deltaXA; Float_t supportPosYOutE = 585.616-7.5-5.5-0.1; Float_t x0000 = constants->CenterModulePositionX(52); Float_t y0000 = constants->CenterModulePositionY(52); Float_t supportPosXOutEP = x0000+(supportPosXOutE-x0000)*TMath::Cos(theta1)-(supportPosYOutE-y0000)*TMath::Sin(theta1); Float_t supportPosYOutEP = y0000+(supportPosYOutE-y0000)*TMath::Cos(theta1)+(supportPosXOutE-x0000)*TMath::Sin(theta1); Float_t supportPosXOutF = constants->CenterModulePositionX(52)+deltaXB; Float_t supportPosXOutFP = x0000+(supportPosXOutF-x0000)*TMath::Cos(theta1)-(supportPosYOutE-y0000)*TMath::Sin(theta1); Float_t supportPosYOutFP = y0000+(supportPosYOutE-y0000)*TMath::Cos(theta1)+(supportPosXOutF-x0000)*TMath::Sin(theta1); Float_t supportPosXOutG = constants->CenterModulePositionX(52)-deltaXA; Float_t supportPosXOutGP = x0000+(supportPosXOutG-x0000)*TMath::Cos(theta1)-(supportPosYOutE-y0000)*TMath::Sin(theta1); Float_t supportPosYOutGP = y0000+(supportPosYOutE-y0000)*TMath::Cos(theta1)+(supportPosXOutG-x0000)*TMath::Sin(theta1); Float_t supportPosXOutH = constants->CenterModulePositionX(52)-deltaXB; Float_t supportPosXOutHP = x0000+(supportPosXOutH-x0000)*TMath::Cos(theta1)-(supportPosYOutE-0.4-y0000)*TMath::Sin(theta1); Float_t supportPosYOutHP = y0000+(supportPosYOutE-0.4-y0000)*TMath::Cos(theta1)+(supportPosXOutH-x0000)*TMath::Sin(theta1); acordeFullSupportOutFace->AddNode(acordeMainSupport,4,new TGeoCombiTrans("ACOFSBOUT04",supportPosXOutEP,supportPosYOutEP,supportPosZOutIn,idrotm231)); acordeFullSupportOutFace->AddNode(acordeMainSupport,5,new TGeoCombiTrans("ACOFSBOUT05",supportPosXOutFP,supportPosYOutFP,supportPosZOutIn,idrotm231)); acordeFullSupportOutFace->AddNode(acordeMainSupport,6,new TGeoCombiTrans("ACOFSBOUT06",supportPosXOutGP,supportPosYOutGP,supportPosZOutIn,idrotm231)); acordeFullSupportOutFace->AddNode(acordeMainSupport,7,new TGeoCombiTrans("ACOFSBOUT07",supportPosXOutHP,supportPosYOutHP,supportPosZOutIn,idrotm231)); // Put the bars of the PutFace Side 2 L3-Magnet Int_t indexBar0=8; for(Int_t iAcoBar = 40;iAcoBar < 50 ; iAcoBar+=2) { Float_t barPosXOutIn = constants->CenterModulePositionX(iAcoBar)+deltaXA-90; Float_t barPosYOutIn = supportPosYOutA-boxSingleBar[1]-boxUnionUp[1]-boxUnionDown[1]-7.5; Float_t barPosZOutIn = constants->CenterModulePositionZ(iAcoBar); Float_t barPosXOutP = x000+(barPosXOutIn-x000)*TMath::Cos(theta1)-(barPosYOutIn-y000)*TMath::Sin(theta1); Float_t barPosYOutP = y000+(barPosYOutIn-y000)*TMath::Cos(theta1)+(barPosXOutIn-x000)*TMath::Sin(theta1); Float_t barPosXOutInA = constants->CenterModulePositionX(iAcoBar)-deltaXA; Float_t barPosYOutInA = supportPosYOutA-boxSingleBar[1]-boxUnionUp[1]-boxUnionDown[1]-7.5-1.; Float_t barPosZOutInA = constants->CenterModulePositionZ(iAcoBar); Float_t barPosXOutPA = x000+(barPosXOutInA-x000)*TMath::Cos(theta1)-(barPosYOutInA-y000)*TMath::Sin(theta1); Float_t barPosYOutPA = y000+(barPosYOutInA-y000)*TMath::Cos(theta1)+(barPosXOutInA-x000)*TMath::Sin(theta1); Float_t barPosXOutInB = constants->CenterModulePositionX(iAcoBar)-deltaXB; Float_t barPosYOutInB = supportPosYOutA-boxSingleBar[1]-boxUnionUp[1]-boxUnionDown[1]-7.5-1.; Float_t barPosZOutInB = constants->CenterModulePositionZ(iAcoBar); Float_t barPosXOutPB = x000+(barPosXOutInB-x000)*TMath::Cos(theta1)-(barPosYOutInB-y000)*TMath::Sin(theta1); Float_t barPosYOutPB = y000+(barPosYOutInB-y000)*TMath::Cos(theta1)+(barPosXOutInB-x000)*TMath::Sin(theta1); acordeFullSupportOutFace->AddNode(acordeMainBar,indexBar0,new TGeoCombiTrans("ACOFSBOUT08",barPosXOutP,barPosYOutP,barPosZOutIn,idrotm231)); acordeFullSupportOutFace->AddNode(acordeMainBar,indexBar0+1,new TGeoCombiTrans("ACOFSBOUT08",barPosXOutPA,barPosYOutPA,barPosZOutInA,idrotm231)); acordeFullSupportOutFace->AddNode(acordeMainBar,indexBar0+2,new TGeoCombiTrans("ACOFSBOUT08",barPosXOutPB,barPosYOutPB,barPosZOutInB,idrotm231)); indexBar0+=4; } for(Int_t iAcoBar = 51;iAcoBar < 54 ; iAcoBar+=2) { Float_t barPosXOutInC = constants->CenterModulePositionX(iAcoBar)+deltaXA; Float_t barPosYOutInC = supportPosYOutE-boxSingleBar[1]-boxUnionUp[1]-boxUnionDown[1]-7.5; Float_t barPosZOutInC = constants->CenterModulePositionZ(iAcoBar); Float_t barPosXOutPC = x0000+(barPosXOutInC-x0000)*TMath::Cos(theta1)-(barPosYOutInC-y0000)*TMath::Sin(theta1); Float_t barPosYOutPC = y0000+(barPosYOutInC-y0000)*TMath::Cos(theta1)+(barPosXOutInC-x0000)*TMath::Sin(theta1); Float_t barPosXOutInD = constants->CenterModulePositionX(iAcoBar)+deltaXB; Float_t barPosYOutInD = supportPosYOutE-boxSingleBar[1]-boxUnionUp[1]-boxUnionDown[1]-7.5; Float_t barPosZOutInD = constants->CenterModulePositionZ(iAcoBar); Float_t barPosXOutPD = x0000+(barPosXOutInD-x0000)*TMath::Cos(theta1)-(barPosYOutInD-y0000)*TMath::Sin(theta1); Float_t barPosYOutPD = y0000+(barPosYOutInD-y0000)*TMath::Cos(theta1)+(barPosXOutInD-x0000)*TMath::Sin(theta1); Float_t barPosXOutInE = constants->CenterModulePositionX(iAcoBar)-deltaXA; Float_t barPosYOutInE = supportPosYOutE-boxSingleBar[1]-boxUnionUp[1]-boxUnionDown[1]-7.5; Float_t barPosZOutInE = constants->CenterModulePositionZ(iAcoBar); Float_t barPosXOutPE = x0000+(barPosXOutInE-x0000)*TMath::Cos(theta1)-(barPosYOutInE-y0000)*TMath::Sin(theta1); Float_t barPosYOutPE = y0000+(barPosYOutInE-y0000)*TMath::Cos(theta1)+(barPosXOutInE-x0000)*TMath::Sin(theta1); Float_t barPosXOutInF = constants->CenterModulePositionX(iAcoBar)-deltaXB; Float_t barPosYOutInF = supportPosYOutE-boxSingleBar[1]-boxUnionUp[1]-boxUnionDown[1]-7.5; Float_t barPosZOutInF = constants->CenterModulePositionZ(iAcoBar); Float_t barPosXOutPF = x0000+(barPosXOutInF-x0000)*TMath::Cos(theta1)-(barPosYOutInF-0.4-y0000)*TMath::Sin(theta1); Float_t barPosYOutPF = y0000+(barPosYOutInF-0.4-y0000)*TMath::Cos(theta1)+(barPosXOutInF-x0000)*TMath::Sin(theta1); acordeFullSupportOutFace->AddNode(acordeMainBar,indexBar0,new TGeoCombiTrans("ACOFSBOUT08",barPosXOutPC,barPosYOutPC,barPosZOutInC,idrotm231)); acordeFullSupportOutFace->AddNode(acordeMainBar,indexBar0+1,new TGeoCombiTrans("ACOFSBOUT08",barPosXOutPD,barPosYOutPD,barPosZOutInD,idrotm231)); acordeFullSupportOutFace->AddNode(acordeMainBar,indexBar0+2,new TGeoCombiTrans("ACOFSBOUT08",barPosXOutPE,barPosYOutPE,barPosZOutInE,idrotm231)); acordeFullSupportOutFace->AddNode(acordeMainBar,indexBar0+3,new TGeoCombiTrans("ACOFSBOUT08",barPosXOutPF,barPosYOutPF,barPosZOutInF,idrotm231)); indexBar0+=4; } for(Int_t iAcoBar = 57;iAcoBar < 58 ; iAcoBar+=2) { Float_t barPosXOutInC = constants->CenterModulePositionX(iAcoBar)+deltaXA; Float_t barPosYOutInC = supportPosYOutE-boxSingleBar[1]-boxUnionUp[1]-boxUnionDown[1]-7.5; Float_t barPosZOutInC = constants->CenterModulePositionZ(iAcoBar); Float_t barPosXOutPC = x0000+(barPosXOutInC-x0000)*TMath::Cos(theta1)-(barPosYOutInC-y0000)*TMath::Sin(theta1); Float_t barPosYOutPC = y0000+(barPosYOutInC-y0000)*TMath::Cos(theta1)+(barPosXOutInC-x0000)*TMath::Sin(theta1); Float_t barPosXOutInD = constants->CenterModulePositionX(iAcoBar)+deltaXB; Float_t barPosYOutInD = supportPosYOutE-boxSingleBar[1]-boxUnionUp[1]-boxUnionDown[1]-7.5; Float_t barPosZOutInD = constants->CenterModulePositionZ(iAcoBar); Float_t barPosXOutPD = x0000+(barPosXOutInD-x0000)*TMath::Cos(theta1)-(barPosYOutInD-y0000)*TMath::Sin(theta1); Float_t barPosYOutPD = y0000+(barPosYOutInD-y0000)*TMath::Cos(theta1)+(barPosXOutInD-x0000)*TMath::Sin(theta1); Float_t barPosXOutInE = constants->CenterModulePositionX(iAcoBar)-deltaXA; Float_t barPosYOutInE = supportPosYOutE-boxSingleBar[1]-boxUnionUp[1]-boxUnionDown[1]-7.5; Float_t barPosZOutInE = constants->CenterModulePositionZ(iAcoBar); Float_t barPosXOutPE = x0000+(barPosXOutInE-x0000)*TMath::Cos(theta1)-(barPosYOutInE-y0000)*TMath::Sin(theta1); Float_t barPosYOutPE = y0000+(barPosYOutInE-y0000)*TMath::Cos(theta1)+(barPosXOutInE-x0000)*TMath::Sin(theta1); Float_t barPosXOutInF = constants->CenterModulePositionX(iAcoBar)-deltaXB; Float_t barPosYOutInF = supportPosYOutE-boxSingleBar[1]-boxUnionUp[1]-boxUnionDown[1]-7.5; Float_t barPosZOutInF = constants->CenterModulePositionZ(iAcoBar); Float_t barPosXOutPF = x0000+(barPosXOutInF-x0000)*TMath::Cos(theta1)-(barPosYOutInF-0.4-y0000)*TMath::Sin(theta1); Float_t barPosYOutPF = y0000+(barPosYOutInF-0.4-y0000)*TMath::Cos(theta1)+(barPosXOutInF-x0000)*TMath::Sin(theta1); acordeFullSupportOutFace->AddNode(acordeMainBar,indexBar0,new TGeoCombiTrans("ACOFSBOUT08",barPosXOutPC,barPosYOutPC,barPosZOutInC,idrotm231)); acordeFullSupportOutFace->AddNode(acordeMainBar,indexBar0+1,new TGeoCombiTrans("ACOFSBOUT08",barPosXOutPD,barPosYOutPD,barPosZOutInD,idrotm231)); acordeFullSupportOutFace->AddNode(acordeMainBar,indexBar0+2,new TGeoCombiTrans("ACOFSBOUT08",barPosXOutPE,barPosYOutPE,barPosZOutInE,idrotm231)); acordeFullSupportOutFace->AddNode(acordeMainBar,indexBar0+3,new TGeoCombiTrans("ACOFSBOUT08",barPosXOutPF,barPosYOutPF,barPosZOutInF,idrotm231)); indexBar0+=4; } Float_t barPosXOutInC = constants->CenterModulePositionX(52)+deltaXA; Float_t barPosYOutInC = supportPosYOutE-boxSingleBar[1]-boxUnionUp[1]-boxUnionDown[1]-7.5; Float_t barPosZOutInC = constants->CenterModulePositionZ(55); Float_t barPosXOutPC = x0000+(barPosXOutInC-x0000)*TMath::Cos(theta1)-(barPosYOutInC-y0000)*TMath::Sin(theta1); Float_t barPosYOutPC = y0000+(barPosYOutInC-y0000)*TMath::Cos(theta1)+(barPosXOutInC-x0000)*TMath::Sin(theta1); Float_t barPosXOutInD = constants->CenterModulePositionX(52)+deltaXB; Float_t barPosYOutInD = supportPosYOutE-boxSingleBar[1]-boxUnionUp[1]-boxUnionDown[1]-7.5; Float_t barPosXOutPD = x0000+(barPosXOutInD-x0000)*TMath::Cos(theta1)-(barPosYOutInD-y0000)*TMath::Sin(theta1); Float_t barPosYOutPD = y0000+(barPosYOutInD-y0000)*TMath::Cos(theta1)+(barPosXOutInD-x0000)*TMath::Sin(theta1); Float_t barPosXOutInE = constants->CenterModulePositionX(52)-deltaXA; Float_t barPosYOutInE = supportPosYOutE-boxSingleBar[1]-boxUnionUp[1]-boxUnionDown[1]-7.5; Float_t barPosXOutPE = x0000+(barPosXOutInE-x0000)*TMath::Cos(theta1)-(barPosYOutInE-y0000)*TMath::Sin(theta1); Float_t barPosYOutPE = y0000+(barPosYOutInE-y0000)*TMath::Cos(theta1)+(barPosXOutInE-x0000)*TMath::Sin(theta1); Float_t barPosXOutInF = constants->CenterModulePositionX(52)-deltaXB; Float_t barPosYOutInF = supportPosYOutE-boxSingleBar[1]-boxUnionUp[1]-boxUnionDown[1]-7.5; Float_t barPosXOutPF = x0000+(barPosXOutInF-x0000)*TMath::Cos(theta1)-(barPosYOutInF-0.4-y0000)*TMath::Sin(theta1); Float_t barPosYOutPF = y0000+(barPosYOutInF-0.4-y0000)*TMath::Cos(theta1)+(barPosXOutInF-x0000)*TMath::Sin(theta1); acordeFullSupportOutFace->AddNode(acordeMainBar,indexBar0,new TGeoCombiTrans("ACOFSBOUT08",barPosXOutPC,barPosYOutPC,barPosZOutInC,idrotm231)); acordeFullSupportOutFace->AddNode(acordeMainBar,indexBar0+1,new TGeoCombiTrans("ACOFSBOUT08",barPosXOutPD,barPosYOutPD,barPosZOutInC,idrotm231)); acordeFullSupportOutFace->AddNode(acordeMainBar,indexBar0+2,new TGeoCombiTrans("ACOFSBOUT08",barPosXOutPE,barPosYOutPE,barPosZOutInC,idrotm231)); acordeFullSupportOutFace->AddNode(acordeMainBar,indexBar0+3,new TGeoCombiTrans("ACOFSBOUT08",barPosXOutPF,barPosYOutPF,barPosZOutInC,idrotm231)); supportBars->AddNode(acordeFullSupportUpFace,1); supportBars->AddNode(acordeFullSupportInFace,2); supportBars->AddNode(acordeFullSupportOutFace,3); acorde->AddNode(acordeModules,1); acorde->AddNode(supportBars,2); alice->AddNode(acorde,1);//---> put volume of ACORDE over ALICE's volume } //__________________________________________________________________________ void AliACORDEv1::Init() { // Initialise L3 magnet after it has been built Int_t i; if(AliLog::GetGlobalDebugLevel()>0) { printf("\n%s: ",ClassName()); for(i=0;i<35;i++) printf("*"); printf(" ACORDEv1_INIT "); for(i=0;i<35;i++) printf("*"); printf("\n%s: ",ClassName()); // Here the ACORDEv initialisation code (if any!) for(i=0;i<80;i++) printf("*"); printf("\n"); } // AliACORDE::Init(); } //____________________________________________________________________________ void AliACORDEv1::StepManager() { // // Called for every step in the Cosmic Ray Trigger // // volume: // [0] = module number 1-60 (1==>(0-0), 60 (5-9) // [1] = Plastic number: 0 (down) to 1 (up) static Int_t vol[2]; // // hit // [0] = PID // [1-3] = x, y, z // [4] = time // [5-7] = px, py, pz // [8] = energy // [9] = energy loss // [10] = length of track through plastic static Float_t hits[11]; // local static variables static Float_t eloss; static Float_t step; // scintillator volume static Int_t idScint = gMC->VolId("ACORDESCINTILLATORMODULE"); // local variables Int_t copy; TLorentzVector pos; TLorentzVector mom; // only charged tracks if ( !gMC->TrackCharge() || !gMC->IsTrackAlive() ) return; // only in sensitive material if (gMC->CurrentVolID(copy) == idScint) { step += gMC->TrackStep(); eloss += gMC->Edep(); // set all hit variables except eloss which is resetted // set volume variables if (gMC->IsTrackEntering()) { eloss = 0.0; step = 0.0; gMC->TrackPosition(pos); gMC->TrackMomentum(mom); // hit // [0] = PID // [1-3] = x, y, z // [4] = time // [5-7] = px, py, pz // [8] = energy // [9] = energy loss hits[0] = (Float_t ) gMC->TrackPid(); hits[1] = pos[0]; hits[2] = pos[1]; hits[3] = pos[2]; hits[4] = gMC->TrackTime(); hits[5] = mom[0]; hits[6] = mom[1]; hits[7] = mom[2]; hits[8] = gMC->Etot(); // volume: // [0] = module number 1-60 (1==>(0-0), 60 (5-9) // [1] = Plastic number: 0 (down) to 1 (up) Int_t copyPlastic; // plastic: down=1, up=2 Int_t copyModule; // module: 1-60 gMC->CurrentVolID(copyPlastic); gMC->CurrentVolOffID(1, copyModule); // module vol[0] = copyModule; // plastic: 0 = down, 1 = up vol[1] = copyPlastic - 4 ; // !!!!!!! // vol[1] = copyPlastic; } // end if gMC->IsTrackEntering() // set hit[9] = total energy loss and book hit if( gMC->IsTrackExiting() || gMC->IsTrackStop() || gMC->IsTrackDisappeared()){ hits[9] = eloss; hits[10] = step; eloss = 0.0; step = 0.0; AddHit(gAlice->GetMCApp()->GetCurrentTrackNumber(),vol, hits); } } } //_____________________________________________________________________________ void AliACORDEv1::AddHit(Int_t track, Int_t *vol, Float_t *hits) { // // Add an ACORDE hit // TClonesArray &lhits = *fHits; new(lhits[fNhits++]) AliACORDEhit(fIshunt,track,vol,hits); } //_____________________________________________________________________________ void AliACORDEv1::AddDigits(Int_t* track, Int_t module, Float_t time) { // Adds Digit TClonesArray &ldigits = *fDigits; new(ldigits[fNdigits++]) AliACORDEdigit(track,module,time); } //_____________________________________________________________________________ void AliACORDEv1::MakeBranch(Option_t *option) { // Creates new branches in the current Root Tree char branchname[10]; //sprintf(branchname,"%s",GetName()); AliDebug(2,Form("fBufferSize = %d",fBufferSize)); const char *cH = strstr(option,"H"); if (fHits && fLoader->TreeH() && cH) { fLoader->TreeH()->Branch(branchname,&fHits, fBufferSize); AliDebug(2,Form("Making Branch %s for hits",branchname)); } const char *cD = strstr(option,"D"); if (fDigits && fLoader->TreeD() && cD) { fLoader->TreeD()->Branch(branchname,&fDigits, fBufferSize); AliDebug(2,Form("Making Branch %s for digits",branchname)); } } //_____________________________________________________________________________ void AliACORDEv1::AddAlignableVolumes() const { // // Create entries for alignable volumes associating the symbolic volume // name with the corresponding volume path. Needs to be syncronized with // eventual changes in the geometry. // // The alignable volumes are only the "ACORDE_MODULE_%d" // // Structure of ACORDE's Geometry // // ALIC_1 // |---> ACORDE_1 // |----> ALL_ACORDE_MODULES_1/ACORDE_MODULE_%d (d:0->to->59) // |----> ACORDE_SUPPORT_BARS_2 |--> BARS&SUPPORTS // // Send comments to: Mario Rodriguez Cahuantzi TString vpstr1 = "ALIC_1/ACORDE_1/ALL_ACORDE_MODULES_1/ACORDE_MODULE_"; TString snstr1 = "ACORDE/Array"; TString volpath, symname; for(Int_t dy=0; dy<60 ; dy++) { volpath = vpstr1; volpath += dy; symname = snstr1; symname += dy; if(!gGeoManager->SetAlignableEntry(symname.Data(),volpath.Data())) AliFatal(Form("Alignable entry %s not created. Volume path %s not valid", symname.Data(),volpath.Data())); } }