//void ConstructGeometry1(TGeoMedium *lead, TGeoMedium *pMed2)
void ConstructGeometry1(TGeoMedium *lead)
{
cout << endl;
cout << "create_target_geo.C-I- R3BTarget:: ConstructGeometry() "<< endl;
cout << "-I- R3BTarget Target type: Lead target (199mg/cm2) "<< endl;
cout << endl;
Double_t dx, dy, dz;
Double_t thx, thy, thz;
Double_t phx, phy, phz;
// Combi transformation:
dx = 0.000000;
dy = 0.000000;
dz = 0.000000; //-(0.15+half thickness)
// Rotation:
thx = 90.000000; phx = 0.000000;
thy = 90.000000; phy = 90.000000;
thz = 0.000000; phz = 0.000000;
TGeoRotation *pRot = new TGeoRotation("",thx,phx,thy,phy,thz,phz);
TGeoCombiTrans* pMatrix =
new TGeoCombiTrans("", dx,dy,dz,pRot);
/*
// Shape: TargetEnveloppe type: TGeoBBox
// TargetEnveloppe Tube 1
dx = 1.6000;
dy = 1.6000;
dz = 0.009000;
TGeoShape *pTargetEnveloppe = new TGeoBBox("TargetEnveloppe",dx,dy,dz);
TGeoVolume *pTargetEnveloppe_log = new TGeoVolume("TargetEnveloppe",pTargetEnveloppe, pMed2);
pTargetEnveloppe_log->SetVisLeaves(kTRUE);
TGeoCombiTrans* pGlobal = GetGlobalPosition(pMatrix);
gTop->AddNode(pTargetEnveloppe_log, 0, pGlobal);
*/
// Shape: LeadTarget type: TGeoBBox
dx = 1.500000; //s318
dy = 1.500000; //s318
dz = 0.008766520; //s318: 199mg/cm2 = 0.17533040mm
TGeoShape *pLeadTarget = new TGeoBBox("LeadTarget", dx,dy,dz);
TGeoVolume* pleadTarget_log
= new TGeoVolume("leadTarget_log",pLeadTarget, lead);
pleadTarget_log->SetVisLeaves(kTRUE);
TGeoVolumeAssembly *keep = new TGeoVolumeAssembly("Target");
keep->AddNode(pleadTarget_log, 0, pMatrix);
//pTargetEnveloppe_log->AddNode(pleadTarget_log, 0, pGlobal);
TGeoCombiTrans* pGlobal = GetGlobalPosition(pMatrix);
gTop->AddNode(keep, 0, pGlobal);
}
void ConstructGeometry6(TGeoMedium *pMed16)
{
cout << endl;
cout << "-I- R3BTarget::ConstructGeometry() "<< endl;
cout << "-I- R3BTarget Target type: CH2 target (2.31 mm) "<< endl;
cout << endl;
Double_t dx, dy, dz;
Double_t thx, thy, thz;
Double_t phx, phy, phz;
// Combi transformation:
dx = 0.000000;
dy = 0.000000;
dz = 0.000000; //-(0.15cm+half thickness)
// Rotation:
thx = 90.000000; phx = 0.000000;
thy = 90.000000; phy = 90.000000;
thz = 0.000000; phz = 0.000000;
TGeoRotation *pRot = new TGeoRotation("",thx,phx,thy,phy,thz,phz);
TGeoCombiTrans *pMatrix = new TGeoCombiTrans("", dx,dy,dz,pRot);
dx = 1.500000; //s318
dy = 1.500000; //s318
dz = 0.1155; //s318
TGeoShape *pCH2Target = new TGeoBBox("CH2Target", dx,dy,dz);
TGeoVolume *pCH2Target_log = new TGeoVolume("CH2Target_log",pCH2Target, pMed16);
pCH2Target_log->SetVisLeaves(kTRUE);
TGeoVolumeAssembly *keep = new TGeoVolumeAssembly("Target");
keep->AddNode(pCH2Target_log, 0, pMatrix);
TGeoCombiTrans* pGlobal = GetGlobalPosition(pMatrix);
gTop->AddNode(keep, 0, pGlobal);
}
/*
* CreateLambdaGeometry.C
*
* Created on: Mar 21, 2013
* Author: stockman
*/
startdetector1()
{
//-----------------------------
Double_t positionOfDisk1inZ = 40.0; //in cm
//Double_t positionOfDisk2inZ = 53.0; //in cm
//--------------------------------------------------------------------
gROOT->Macro("$VMCWORKDIR/gconfig/rootlogon.C");
// Load this libraries
gSystem->Load("libGeoBase");
gSystem->Load("libParBase");
gSystem->Load("libBase");
gSystem->Load("libPndData");
gSystem->Load("libPassive");
TString outfile= "../../geometry/startdetector.root";
TFile* fi = new TFile(outfile,"RECREATE");
FairGeoLoader* geoLoad = new FairGeoLoader("TGeo","FairGeoLoader");
FairGeoInterface *geoFace = geoLoad->getGeoInterface();
geoFace->setMediaFile("../../geometry/media_pnd.geo");
geoFace->readMedia();
geoFace->print();
FairGeoMedia *Media = geoFace->getMedia();
FairGeoBuilder *geobuild=geoLoad->getGeoBuilder();
FairGeoMedium *CbmMediumHYPdiamond = Media->getMedium("HYPdiamond");
FairGeoMedium *CbmMediumCarbon = Media->getMedium("carbon");
FairGeoMedium *CbmMediumCarbonFoam = Media->getMedium("carbonfoam");
FairGeoMedium *CbmMediumAluminium = Media->getMedium("aluminium");
Int_t nmed=geobuild->createMedium(CbmMediumHYPdiamond);
nmed=geobuild->createMedium(CbmMediumCarbon);
nmed=geobuild->createMedium(CbmMediumCarbonFoam);
nmed=geobuild->createMedium(CbmMediumAluminium);
TGeoManager* gGeoMan = (TGeoManager*)gROOT->FindObject("FAIRGeom");
TGeoVolume *top = new TGeoVolumeAssembly("top");
gGeoMan->SetTopVolume(top);
TGeoVolume *combinedLambdaDisks = new TGeoVolumeAssembly("CombinedLambdaDisks");
TGeoVolumeAssembly* lambdaDisk = new TGeoVolumeAssembly("LambdaDisk");
TGeoVolumeAssembly* largeRing = new TGeoVolumeAssembly("LargeRing");
TGeoVolumeAssembly* smallRing = new TGeoVolumeAssembly("SmallRing");
// lambdaDisk->AddNode(largeSensorVolume,0,trc1);
// TGeoShape* largeSensorShape = new TGeoTrd1("StripSensorActiveLargeShape", 3.4593/2, 1.9936/2,0.03/2, 5.5665/2);
Double_t points [16];
points[0] = -1.7297; points[1] = 2.7833;
points[2] = 1.7297; points[3] = 2.7833;
points[4] = 0.9968; points[5] = -2.7833;
points[6] = -0.9968; points[7] = -2.7833;
points[8] = -1.7297; points[9] = 2.7833;
points[10] = 1.7297; points[11] = 2.7833;
points[12] = 0.9968; points[13] = -2.7833;
points[14] = -0.9968; points[15] = -2.7833;
TGeoShape* largeSensorShape = new TGeoArb8("StripSensorActiveLargeShape", 0.03/2, points);
TGeoVolume* largeSensorVolume = new TGeoVolume("StripSensorActiveLargeTrap",largeSensorShape,gGeoMan->GetMedium("HYPdiamond"));
// TGeoRotation rotSensor("rotSensor",0,90,0);
TGeoRotation rotSensor("rotSensor",0,0,0);
TGeoTranslation transLargeSensor(0,(14.8669 + 5.5665)/2,0);
TGeoCombiTrans combined1(transLargeSensor, rotSensor);
for (int i = 0; i < 12; i++){
TString rotName("rotLargeSens");
rotName.Append(i+1);
TGeoRotation rotSens(rotName.Data(), 0,0, i*2 * 360/24);
TGeoHMatrix sens = rotSens * combined1;
largeRing->AddNode(largeSensorVolume, i, new TGeoHMatrix(sens));
}
Double_t pointsSmall [16];
pointsSmall[0] = -1.9579/2; pointsSmall[1] = 5.3358/2;
pointsSmall[2] = 1.9579/2; pointsSmall[3] = 5.3358/2;
pointsSmall[4] = 0.5529/2; pointsSmall[5] = -5.3358/2;
pointsSmall[6] = -0.5529/2; pointsSmall[7] = -5.3358/2;
pointsSmall[8] = -1.9579/2; pointsSmall[9] = 5.3358/2;
pointsSmall[10] = 1.9579/2; pointsSmall[11] = 5.3358/2;
pointsSmall[12] = 0.5529/2; pointsSmall[13] = -5.3358/2;
pointsSmall[14] = -0.5529/2; pointsSmall[15] = -5.3358/2;
// TGeoShape* smallSensorShape = new TGeoTrd1("StripSensorActiveSmallShape", 1.9579/2, 0.5529/2, 0.03/2, 5.3358/2);
TGeoShape* smallSensorShape = new TGeoArb8("StripSensorActiveSmallShape", 0.03/2, pointsSmall);
TGeoVolume* smallSensorVolume = new TGeoVolume("StripSensorActiveSmallTrap", smallSensorShape, gGeoMan->GetMedium("HYPdiamond"));
TGeoTranslation transSmallSensor(0,5.3358/2+2.1,0);
TGeoCombiTrans combined2(transSmallSensor, rotSensor);
for (int i = 0; i < 12; i++){
TString rotName("rotSmallSens");
rotName.Append(i+1);
TGeoRotation rotSens(rotName.Data(), 0,0, i*2 * 360/24);
TGeoHMatrix sens = rotSens * combined2;
smallRing->AddNode(smallSensorVolume, i+12, new TGeoHMatrix(sens));
}
lambdaDisk->AddNode(largeRing, 0, new TGeoTranslation(0,0,-0.5));
lambdaDisk->AddNode(largeRing, 1, new TGeoRotation("largeRingRot",0,0,360/24));
TGeoCombiTrans combiSmallRing2(TGeoTranslation(0,0,-1.5), TGeoRotation("smallRingRot",0,0,360/24));
lambdaDisk->AddNode(smallRing, 0, new TGeoTranslation(0,0,-1.0));
lambdaDisk->AddNode(smallRing, 1, new TGeoHMatrix(combiSmallRing2));
TGeoVolumeAssembly* supportDisk = new TGeoVolumeAssembly("SupportDisk");
TGeoVolumeAssembly* supportLarge = new TGeoVolumeAssembly("SupportLarge");
TGeoShape* carbonFoamShape = new TGeoBBox(3.4/2, 0.2/2, 3.5/2);
TGeoVolume* carbonFoam = new TGeoVolume("CarbonFoam", carbonFoamShape, gGeoMan->GetMedium("carbonfoam"));
TGeoShape* carbonFiberShape = new TGeoBBox(3.4/2, 0.02/2, 3.5/2);
TGeoVolume* carbonFiber = new TGeoVolume("CarbonFiber", carbonFiberShape, gGeoMan->GetMedium("carbon"));
TGeoShape* HYPdiamondReadoutShape = new TGeoBBox(3.4/2, 0.02/2, 3.5/2);
TGeoVolume* HYPdiamondReadout = new TGeoVolume("HYPdiamondReadout", HYPdiamondReadoutShape, gGeoMan->GetMedium("HYPdiamond"));
TGeoShape* aluCablesShape = new TGeoBBox(3.4/2, 0.4/2, 3.5/2);
TGeoVolume* aluCables = new TGeoVolume("AluCables", aluCablesShape, gGeoMan->GetMedium("aluminium"));
supportLarge->AddNode(carbonFoam, 1);
supportLarge->AddNode(carbonFiber, 1, new TGeoTranslation(0,(0.2 + 0.02)/2, 0));
supportLarge->AddNode(carbonFiber, 2, new TGeoTranslation(0,-(0.2 + 0.02)/2, 0));
supportLarge->AddNode(HYPdiamondReadout, 1, new TGeoTranslation(0,(0.2 + 0.02 + 0.02)/2, 0));
supportLarge->AddNode(HYPdiamondReadout, 2, new TGeoTranslation(0,-(0.2 + 0.02 + 0.02)/2, 0));
supportLarge->AddNode(aluCables, 1, new TGeoTranslation(0,(0.2 + 0.02 + 0.02 + 0.4)/2, 0));
supportLarge->AddNode(aluCables, 2, new TGeoTranslation(0,-(0.2 + 0.02 + 0.02 + 0.4)/2, 0));
TGeoTranslation transSupportLarge(0,(14.8669)/2 + 5.5665 + 1,0);
for (int i = 0; i < 24; i++){
TString rotName("rotSupportLarge");
rotName.Append(i+1);
TGeoRotation rotSens(rotName.Data(), 0,0, i * 360/24);
TGeoHMatrix sens = rotSens * transSupportLarge;
supportDisk->AddNode(supportLarge, i+1, new TGeoHMatrix(sens));
}
TGeoVolumeAssembly* supportSmall = new TGeoVolumeAssembly("SupportSmall");
TGeoShape* carbonFoamShapeSmall = new TGeoBBox(1.8/2, 0.2/2, 3.5/2);
TGeoVolume* carbonFoamSmall = new TGeoVolume("CarbonFoamSmall", carbonFoamShapeSmall, gGeoMan->GetMedium("carbonfoam"));
TGeoShape* carbonFiberShapeSmall = new TGeoBBox(1.8/2, 0.02/2, 3.5/2);
TGeoVolume* carbonFiberSmall = new TGeoVolume("CarbonFiberSmall", carbonFiberShapeSmall, gGeoMan->GetMedium("carbon"));
TGeoShape* HYPdiamondReadoutShapeSmall = new TGeoBBox(1.8/2, 0.02/2, 3.5/2);
TGeoVolume* HYPdiamondReadoutSmall = new TGeoVolume("HYPdiamondReadoutSmall", HYPdiamondReadoutShapeSmall, gGeoMan->GetMedium("HYPdiamond"));
TGeoShape* aluCablesShapeSmall = new TGeoBBox(1.8/2, 0.4/2, 3.5/2);
TGeoVolume* aluCablesSmall = new TGeoVolume("AluCablesSmall", aluCablesShapeSmall, gGeoMan->GetMedium("aluminium"));
supportSmall->AddNode(carbonFoamSmall, 1);
supportSmall->AddNode(carbonFiberSmall, 1, new TGeoTranslation(0,(0.2 + 0.02)/2, 0));
supportSmall->AddNode(carbonFiberSmall, 2, new TGeoTranslation(0,-(0.2 + 0.02)/2, 0));
supportSmall->AddNode(HYPdiamondReadoutSmall, 1, new TGeoTranslation(0,(0.2 + 0.02 + 0.02)/2, 0));
supportSmall->AddNode(HYPdiamondReadoutSmall, 2, new TGeoTranslation(0,-(0.2 + 0.02 + 0.02)/2, 0));
supportSmall->AddNode(aluCablesSmall, 1, new TGeoTranslation(0,(0.2 + 0.02 + 0.02 + 0.4)/2, 0));
supportSmall->AddNode(aluCablesSmall, 2, new TGeoTranslation(0,-(0.2 + 0.02 + 0.02 + 0.4)/2, 0));
TGeoTranslation transSupportSmall(0,2.1 + 5.3358 + 0.5,0);
for (int i = 0; i < 24; i++){
TString rotName("rotSupportSmall");
rotName.Append(i+1);
TGeoRotation rotSens(rotName.Data(), 0,0, i * 360/24);
TGeoHMatrix sens = rotSens * transSupportSmall;
supportDisk->AddNode(supportSmall, i+1, new TGeoHMatrix(sens));
}
combinedLambdaDisks->AddNode(lambdaDisk,1,new TGeoTranslation(0,0,positionOfDisk1inZ));
//combinedLambdaDisks->AddNode(lambdaDisk,2,new TGeoTranslation(0,0,positionOfDisk2inZ));
//combinedLambdaDisks->AddNode(supportDisk,1, new TGeoTranslation(0,0,(positionOfDisk1inZ + positionOfDisk2inZ)/2));
top->AddNode(combinedLambdaDisks,0);
gGeoMan->CloseGeometry();
top->Write();
fi->Close();
// gGeoManager->Export(outfile);
gGeoManager->SetVisLevel(30);
top->Draw("ogl");
}
void create_mtof_geo(const char* geoTag)
{
// ------- Load media from media file -----------------------------------
FairGeoLoader* geoLoad = new FairGeoLoader("TGeo","FairGeoLoader");
FairGeoInterface* geoFace = geoLoad->getGeoInterface();
TString geoPath = gSystem->Getenv("VMCWORKDIR");
TString medFile = geoPath + "/geometry/media_r3b.geo";
geoFace->setMediaFile(medFile);
geoFace->readMedia();
gGeoMan = gGeoManager;
// --------------------------------------------------------------------------
// ------- Geometry file name (output) ----------------------------------
TString geoFileName = geoPath + "/geometry/mtof_";
geoFileName = geoFileName + geoTag + ".geo.root";
// --------------------------------------------------------------------------
// ----------------- Get and create the required media -----------------
FairGeoMedia* geoMedia = geoFace->getMedia();
FairGeoBuilder* geoBuild = geoLoad->getGeoBuilder();
FairGeoMedium* mAir = geoMedia->getMedium("Air");
if ( ! mAir ) Fatal("Main", "FairMedium Air not found");
geoBuild->createMedium(mAir);
TGeoMedium* pMed2 = gGeoMan->GetMedium("Air");
if ( ! pMed2 ) Fatal("Main", "Medium Air not found");
FairGeoMedium* mTof = geoMedia->getMedium("plasticFormTOF");
if ( ! mTof ) Fatal("Main", "FairMedium plasticFormTOF not found");
geoBuild->createMedium(mTof);
TGeoMedium* pMed34 = gGeoMan->GetMedium("plasticFormTOF");
if ( ! pMed34 ) Fatal("Main", "Medium plasticFormTOF not found");
// --------------------------------------------------------------------------
// -------------- Create geometry and top volume -------------------------
gGeoMan = (TGeoManager*)gROOT->FindObject("FAIRGeom");
gGeoMan->SetName("mTOFgeom");
TGeoVolume* top = new TGeoVolumeAssembly("TOP");
gGeoMan->SetTopVolume(top);
// --------------------------------------------------------------------------
// out-of-file geometry definition
Double_t dx,dy,dz;
Double_t a;
Double_t thx, phx, thy, phy, thz, phz;
Double_t z, density, w;
Int_t nel, numed;
// TRANSFORMATION MATRICES
// Combi transformation:
//NTF position
//dx = -154.815998;//Justyna
//dy = 0.000000; //Justyna
//dz = 761.755160;//Justyna
//dx = -157.536214;//Justyna new
//dy = -0.010000; //Justyna new
////dz = 760.939056;//Justyna new
//dz = 760.139056;//Justyna
//dx = -155.709;//dE tracker
//dy = 0.524;
////dz = 761.487;
//dz = 760.687; //try -0.8 like Justyna
//LABPOS(FTF,-155.824045,0.523976,761.870346)
dx = -155.824045;//dE tracker, correction due to wrong angle
dy = 0.523976;
dz = 761.870346;
// Rotation:
thx = -106.700000; phx = 0.000000;
thy = 90.000000; phy = 90.000000;
thz = -16.700000; phz = 0.000000;
/* dx = -171.1;
dy = 2.400000;
dz = 548.95;
// dz = 0.;
// Rotation:
thx = -121.000000; phx = 0.000000;
thy = 90.000000; phy = 90.000000;
thz = -31.000000; phz = 0.000000;*/
TGeoRotation *pMatrix3 = new TGeoRotation("",thx,phx,thy,phy,thz,phz);
TGeoCombiTrans*
pMatrix2 = new TGeoCombiTrans("", dx,dy,dz,pMatrix3);
/*
// TRANSFORMATION MATRICES
// Combi transformation:
dx = 151.000000;
dy = 0.000000;
dz = 758.000000;
// Rotation:
thx = 106.700000; phx = 0.000000;
thy = 90.000000; phy = 90.000000;
thz = 16.700000; phz = 0.000000;
TGeoRotation *pMatrix3 = new TGeoRotation("",thx,phx,thy,phy,thz,phz);
TGeoCombiTrans*
pMatrix2 = new TGeoCombiTrans("", dx,dy,dz,pMatrix3);
*/
// Shape: World type: TGeoBBox
TGeoVolume* pWorld = gGeoManager->GetTopVolume();
pWorld->SetVisLeaves(kTRUE);
// Create a global Mother Volume
/*
dx = 200.000000;
dy = 200.000000;
dz = 200.000000;
TGeoShape *pBoxWorld = new TGeoBBox("mTofBoxWorld", dx,dy,dz);
TGeoVolume*
pWorld = new TGeoVolume("mTofBoxLogWorld",pBoxWorld, pMed2);
pWorld->SetVisLeaves(kTRUE);
TGeoCombiTrans *pGlobalc = GetGlobalPosition();
// add the sphere as Mother Volume
pAWorld->AddNode(pWorld, 0, pGlobalc);
*/
// SHAPES, VOLUMES AND GEOMETRICAL HIERARCHY
// Shape: mTOFBox type: TGeoBBox
dx = 24.000000;
dy = 24.000000;
//dz = 0.250000; //wrong: should be 0.5->1cm total
dz = 0.500000;
/* dx = 94.450000; //TFW size
dy = 73.450000;
dz = 0.500000;*/
TGeoShape *pmTOFBox = new TGeoBBox("mTOFBox", dx,dy,dz);
// Volume: mTOFLog
TGeoVolume *
pmTOFLog = new TGeoVolume("mTOFLog",pmTOFBox, pMed34);
pmTOFLog->SetVisLeaves(kTRUE);
TGeoVolumeAssembly *pmTof = new TGeoVolumeAssembly("mTOF");
TGeoCombiTrans *t0 = new TGeoCombiTrans("t0");
pmTof->AddNode(pmTOFLog, 0, t0);
TGeoCombiTrans *pGlobal = GetGlobalPosition(pMatrix2);
if (pGlobal){
pWorld->AddNode(pmTof, 0, pGlobal);
}else{
pWorld->AddNode(pmTof, 0, pMatrix2);
}
// AddSensitiveVolume(pmTOFLog);
// fNbOfSensitiveVol+=1;
// --------------- Finish -----------------------------------------------
gGeoMan->CloseGeometry();
gGeoMan->CheckOverlaps(0.001);
gGeoMan->PrintOverlaps();
gGeoMan->Test();
TFile* geoFile = new TFile(geoFileName, "RECREATE");
top->Write();
geoFile->Close();
// --------------------------------------------------------------------------
}
void create_tof_geo(const char* geoTag)
{
fGlobalTrans->SetTranslation(0.0,0.0,0.0);
// ------- Load media from media file -----------------------------------
FairGeoLoader* geoLoad = new FairGeoLoader("TGeo","FairGeoLoader");
FairGeoInterface* geoFace = geoLoad->getGeoInterface();
TString geoPath = gSystem->Getenv("VMCWORKDIR");
TString medFile = geoPath + "/geometry/media_r3b.geo";
geoFace->setMediaFile(medFile);
geoFace->readMedia();
gGeoMan = gGeoManager;
// --------------------------------------------------------------------------
// ------- Geometry file name (output) ----------------------------------
TString geoFileName = geoPath + "/geometry/tof_";
geoFileName = geoFileName + geoTag + ".geo.root";
// --------------------------------------------------------------------------
// ----------------- Get and create the required media -----------------
FairGeoMedia* geoMedia = geoFace->getMedia();
FairGeoBuilder* geoBuild = geoLoad->getGeoBuilder();
FairGeoMedium* mAir = geoMedia->getMedium("Air");
if ( ! mAir ) Fatal("Main", "FairMedium Air not found");
geoBuild->createMedium(mAir);
TGeoMedium* pMed2 = gGeoMan->GetMedium("Air");
if ( ! pMed2 ) Fatal("Main", "Medium Air not found");
FairGeoMedium* mTof = geoMedia->getMedium("plasticForTOF");
if ( ! mTof ) Fatal("Main", "FairMedium plasticForTOF not found");
geoBuild->createMedium(mTof);
TGeoMedium* pMed34 = gGeoMan->GetMedium("plasticForTOF");
if ( ! pMed34 ) Fatal("Main", "Medium plasticForTOF not found");
// --------------------------------------------------------------------------
// -------------- Create geometry and top volume -------------------------
gGeoMan = (TGeoManager*)gROOT->FindObject("FAIRGeom");
gGeoMan->SetName("TOFgeom");
TGeoVolume* top = new TGeoVolumeAssembly("TOP");
gGeoMan->SetTopVolume(top);
// --------------------------------------------------------------------------
// out-of-file geometry definition
Double_t dx,dy,dz;
Double_t a;
// Double_t thx, phx, thy, phy, thz, phz;
Double_t z, density, w;
Int_t nel, numed;
// TRANSFORMATION MATRICES
// Combi transformation:
dx = -417.359574; //Justyna
dy = 2.400000; //Justyna
dz = 960.777114; //Justyna
// dx = -421.33683; //Christoph
// dy = 2.12; //Christoph
// dz = 958.387337; //Christoph
/* dx = -171.1; //position directrly (15cm) after DCH2
dy = 2.400000;
dz = 548.95;*/
// dz = 0.;
/* // Rotation:
thx = -121.000000; phx = 0.000000;
thy = 90.000000; phy = 90.000000;
thz = -31.000000; phz = 0.000000;*/ //this
// TGeoRotation *pMatrix3 = new TGeoRotation("",thx,phx,thy,phy,thz,phz); //this
TGeoRotation *gRot = new TGeoRotation();
gRot->RotateX(0.);
gRot->RotateY(-31.000000);
gRot->RotateZ(0.);
TGeoCombiTrans*
// pMatrix2 = new TGeoCombiTrans("", dx,dy,dz,pMatrix3); //this
pMatrix2 = new TGeoCombiTrans("", dx,dy,dz,gRot); //this
/* PREVIOUS!!!
// TRANSFORMATION MATRICES
// Combi transformation:
dx = 419.700000;
dy = 0.000000;
dz = 952.400000;
// dz = 0.;
// Rotation:
thx = 121.000000; phx = 0.000000;
thy = 90.000000; phy = 90.000000;
thz = 31.000000; phz = 0.000000;
TGeoRotation *pMatrix3 = new TGeoRotation("",thx,phx,thy,phy,thz,phz);
TGeoCombiTrans*
pMatrix2 = new TGeoCombiTrans("", dx,dy,dz,pMatrix3);
*/
//Top Volume
TGeoVolume* pWorld = gGeoManager->GetTopVolume();
pWorld->SetVisLeaves(kTRUE);
TGeoVolumeAssembly *ptof = new TGeoVolumeAssembly("TOF");
// SHAPES, VOLUMES AND GEOMETRICAL HIERARCHY
// Shape: TOFBox type: TGeoBBox
dx = 94.450000;
dy = 73.450000;
dz = 0.500000;
TGeoShape *pTOFBox = new TGeoBBox("TOFBox", dx,dy,dz);
// Volume: TOFLog
TGeoVolume*
pTOFLog = new TGeoVolume("TOFLog",pTOFBox, pMed34);
pTOFLog->SetVisLeaves(kTRUE);
TGeoCombiTrans *t0 = new TGeoCombiTrans("t0");
ptof->AddNode(pTOFLog, 0, t0);
TGeoCombiTrans *pGlobal = GetGlobalPosition(pMatrix2);
if (pGlobal) {
pWorld->AddNode(ptof, 0, pGlobal);
} else {
pWorld->AddNode(ptof, 0, pMatrix2);
}
// AddSensitiveVolume(pTOFLog);
// fNbOfSensitiveVol+=1;
// --------------- Finish -----------------------------------------------
gGeoMan->CloseGeometry();
gGeoMan->CheckOverlaps(0.001);
gGeoMan->PrintOverlaps();
gGeoMan->Test();
TFile* geoFile = new TFile(geoFileName, "RECREATE");
top->Write();
geoFile->Close();
// --------------------------------------------------------------------------
}
KVFAZIABlock::KVFAZIABlock() : TGeoVolumeAssembly("STRUCT_BLOCK")
{
// Default constructor
SetMedium(gGeoManager->GetMedium("Vacuum"));//to avoid warnings about STRUCT_BLOCK has dummy medium
KVMaterial mat_si("Si");
TGeoMedium *Silicon = mat_si.GetGeoMedium();
KVMaterial mat_csi("CsI");
TGeoMedium *CesiumIodide = mat_csi.GetGeoMedium();
KVMaterial mat_plomb("Lead");
TGeoMedium *Plomb = mat_plomb.GetGeoMedium();
TGeoVolumeAssembly* quartet = gGeoManager->MakeVolumeAssembly("STRUCT_QUARTET");
quartet->SetMedium(gGeoManager->GetMedium("Vacuum"));//to avoid warnings about STRUCT_QUARTET has dummy medium
TGeoVolume* si = 0;
TGeoVolume* csi = 0;
Double_t distance_si2_si1 = 0.220;
Double_t distance_csi_si2 = 0.434;
Double_t side_si = 2;
Double_t side_csi_front = 2.050;
Double_t side_csi_back = 2.272;
Double_t inter_si = 0.24;
Double_t thick_si1 = 300 * KVUnits::um;
Double_t thick_si2 = 500 * KVUnits::um;
Double_t thick_csi = 10;
Double_t adjust_csi = 0.0165;
Int_t ndet = 1;;
TGeoTranslation* tr = 0;
Double_t shift = side_si / 2 + inter_si / 2;
//printf("%lf\n", shift);
Double_t coefx[4] = { -1., -1., 1., 1.};
Double_t coefy[4] = {1., -1., -1., 1.};
for (Int_t nt = 1; nt <= 4; nt += 1) {
shift = side_si / 2 + inter_si / 2;
si = gGeoManager->MakeBox(Form("DET_SI1-T%d", nt), Silicon, side_si / 2, side_si / 2, thick_si1 / 2.);
tr = new TGeoTranslation(coefx[nt - 1]*shift, coefy[nt - 1]*shift, thick_si1 / 2.);
quartet->AddNode(si, ndet++, tr);
((TGeoNodeMatrix*)quartet->GetNodes()->Last())->SetName(Form("DET_SI1-T%d", nt));
si = gGeoManager->MakeBox(Form("DET_SI2-T%d", nt), Silicon, side_si / 2, side_si / 2, thick_si2 / 2.);
tr = new TGeoTranslation(coefx[nt - 1]*shift, coefy[nt - 1]*shift, thick_si2 / 2. + distance_si2_si1);
quartet->AddNode(si, ndet++, tr);
((TGeoNodeMatrix*)quartet->GetNodes()->Last())->SetName(Form("DET_SI2-T%d", nt));
shift = side_si / 2 + inter_si / 2 + adjust_csi;
csi = gGeoManager->MakeTrd2(Form("DET_CSI-T%d", nt), CesiumIodide, side_csi_front / 2, side_csi_back / 2, side_csi_front / 2, side_csi_back / 2, thick_csi / 2.);
tr = new TGeoTranslation(coefx[nt - 1]*shift, coefy[nt - 1]*shift, thick_csi / 2. + distance_csi_si2);
quartet->AddNode(csi, ndet++, tr);
((TGeoNodeMatrix*)quartet->GetNodes()->Last())->SetName(Form("DET_CSI-T%d", nt));
}
Int_t nbl = 1;
TGeoVolume* blindage = 0;
//Double_t thick_bld = thick_si1+distance_si2_si1+thick_si2;
/* l'epaisseur du si1 est compris dans la distance_si2_si1 */
Double_t thick_bld = distance_si2_si1 + thick_si2;
Double_t shift_bld = (side_si + inter_si) / 2.;
///Croix inter quartet
//
// Separation des 4 télescopes
//
//
blindage = gGeoManager->MakeBox("DEADZONE_BLINDAGE_1", Plomb, inter_si / 2, (side_si + inter_si / 2), thick_bld / 2.);
//printf("%s\n", blindage->GetMaterial()->GetTitle());
tr = new TGeoTranslation(0, 0, thick_bld / 2.);
quartet->AddNode(blindage, nbl++, tr);
blindage = gGeoManager->MakeBox("DEADZONE_BLINDAGE_2", Plomb, (side_si / 2), inter_si / 2, thick_bld / 2.);
tr = new TGeoTranslation(-1 * shift_bld, 0, thick_bld / 2.);
quartet->AddNode(blindage, nbl++, tr);
tr = new TGeoTranslation(+1 * shift_bld, 0, thick_bld / 2.);
quartet->AddNode(blindage, nbl++, tr);
///Contour de l ensemble du quartet
//
//Délimiation des bords exterieurs
//
//
shift_bld = (side_si + inter_si);
blindage = gGeoManager->MakeBox("DEADZONE_BLINDAGE_3", Plomb, (side_si + inter_si / 2), inter_si / 2, thick_bld / 2.);
tr = new TGeoTranslation(0, shift_bld, thick_bld / 2.);
quartet->AddNode(blindage, nbl++, tr);
tr = new TGeoTranslation(0, -1 * shift_bld, thick_bld / 2.);
quartet->AddNode(blindage, nbl++, tr);
///
blindage = gGeoManager->MakeBox("DEADZONE_BLINDAGE_4", Plomb, inter_si / 2, (side_si + inter_si * 1.5), thick_bld / 2.);
tr = new TGeoTranslation(shift_bld, 0, thick_bld / 2.);
quartet->AddNode(blindage, nbl++, tr);
tr = new TGeoTranslation(-1 * shift_bld, 0, thick_bld / 2.);
quartet->AddNode(blindage, nbl++, tr);
fTotSidWBlind = 4 * side_si + 5 * inter_si;
//Coordonnées extraite des côtes données par Yvan M.
//vecteur pointant le milieu d un quartet
//X=-2.231625
//Y=-2.230525
//Z=99.950350
// Mag=100.000139
// Theta=1.808104
// Phi = -135.014124
TVector3* placement = new TVector3(-2.231625, -2.230525, 99.950350);
TVector3* Centre = new TVector3();
TGeoRotation rot1, rot2;
TGeoTranslation trans;
TGeoTranslation invZtrans(0, 0, -100);
TGeoHMatrix h;
TGeoHMatrix* ph = 0;
//Boucle sur les 4 quartets d un block
Double_t tx[4] = {1, -1, -1, 1};
Double_t ty[4] = {1, 1, -1, -1};
Double_t theta = 0;
Double_t phi = 0;
Double_t trans_z = 0;
for (Int_t nq = 1; nq <= 4; nq += 1) {
Centre->SetXYZ(placement->X()*tx[nq - 1], placement->Y()*ty[nq - 1], placement->Z());
theta = Centre->Theta() * TMath::RadToDeg();
phi = Centre->Phi() * TMath::RadToDeg();
trans_z = Centre->Mag() + thick_si1 / 2.;
rot2.SetAngles(phi + 90., theta, 0.);
rot1.SetAngles(-1.*phi, 0., 0.);
trans.SetDz(trans_z);
h = invZtrans * rot2 * trans * rot1;
ph = new TGeoHMatrix(h);
AddNode(quartet, nq, ph);
}
}
int main(int argc, char * argv[]) {
TApplication app("app", &argc, argv);
plottingEngine.SetDefaultStyle();
const bool debug = true;
// Load the field map.
ComponentAnsys123* fm = new ComponentAnsys123();
const std::string efile = "ELIST.lis";
const std::string nfile = "NLIST.lis";
const std::string mfile = "MPLIST.lis";
const std::string sfile = "PRNSOL.lis";
fm->Initialise(efile, nfile, mfile, sfile, "mm");
fm->EnableMirrorPeriodicityX();
fm->EnableMirrorPeriodicityY();
fm->PrintRange();
// Dimensions of the GEM
const double pitch = 0.014;
const double kapton = 50.e-4;
const double metal = 5.e-4;
const double outdia = 70.e-4;
const double middia = 50.e-4;
const bool plotField = false;
if (plotField) {
ViewField* fieldView = new ViewField();
fieldView->SetComponent(fm);
fieldView->SetPlane(0., -1., 0., 0., 0., 0.);
fieldView->SetArea(-pitch / 2., -0.02, pitch / 2., 0.02);
fieldView->SetVoltageRange(-160., 160.);
TCanvas* cF = new TCanvas();
fieldView->SetCanvas(cF);
fieldView->PlotContour();
}
// Setup the gas.
MediumMagboltz* gas = new MediumMagboltz();
gas->SetComposition("ar", 70., "co2", 30.);
gas->SetTemperature(293.15);
gas->SetPressure(760.);
gas->EnableDebugging();
gas->Initialise();
gas->DisableDebugging();
// Set the Penning transfer efficiency.
const double rPenning = 0.57;
const double lambdaPenning = 0.;
gas->EnablePenningTransfer(rPenning, lambdaPenning, "ar");
// Load the ion mobilities.
gas->LoadIonMobility("IonMobility_Ar+_Ar.txt");
// Associate the gas with the corresponding field map material.
const int nMaterials = fm->GetNumberOfMaterials();
for (int i = 0; i < nMaterials; ++i) {
const double eps = fm->GetPermittivity(i);
if (fabs(eps - 1.) < 1.e-3) fm->SetMedium(i, gas);
}
fm->PrintMaterials();
// Create the sensor.
Sensor* sensor = new Sensor();
sensor->AddComponent(fm);
sensor->SetArea(-5 * pitch, -5 * pitch, -0.03,
5 * pitch, 5 * pitch, 0.03);
AvalancheMicroscopic* aval = new AvalancheMicroscopic();
aval->SetSensor(sensor);
AvalancheMC* drift = new AvalancheMC();
drift->SetSensor(sensor);
drift->SetDistanceSteps(2.e-4);
const bool plotDrift = true;
ViewDrift* driftView = new ViewDrift();
if (plotDrift) {
driftView->SetArea(-2 * pitch, -2 * pitch, -0.02,
2 * pitch, 2 * pitch, 0.02);
// Plot every 10 collisions (in microscopic tracking).
aval->SetCollisionSteps(10);
aval->EnablePlotting(driftView);
drift->EnablePlotting(driftView);
}
// Histograms
int nBinsGain = 100;
double gmin = 0.;
double gmax = 100.;
TH1F* hElectrons = new TH1F("hElectrons", "Number of electrons",
nBinsGain, gmin, gmax);
TH1F* hIons = new TH1F("hIons", "Number of ions",
nBinsGain, gmin, gmax);
int nBinsChrg = 100;
TH1F* hChrgE = new TH1F("hChrgE", "Electrons on plastic",
nBinsChrg, -0.5e4 * kapton, 0.5e4 * kapton);
TH1F* hChrgI = new TH1F("hChrgI", "Ions on plastic",
nBinsChrg, -0.5e4 * kapton, 0.5e4 * kapton);
double sumIonsTotal = 0.;
double sumIonsDrift = 0.;
double sumIonsPlastic = 0.;
double sumElectronsTotal = 0.;
double sumElectronsPlastic = 0.;
double sumElectronsUpperMetal = 0.;
double sumElectronsLowerMetal = 0.;
double sumElectronsTransfer = 0.;
double sumElectronsOther = 0.;
const int nEvents = 10;
for (int i = nEvents; i--;) {
if (debug || i % 10 == 0) std::cout << i << "/" << nEvents << "\n";
// Randomize the initial position.
const double smear = pitch / 2.;
double x0 = -smear + RndmUniform() * smear;
double y0 = -smear + RndmUniform() * smear;
double z0 = 0.025;
double t0 = 0.;
double e0 = 0.1;
aval->AvalancheElectron(x0, y0, z0, t0, e0, 0., 0., 0.);
int ne = 0, ni = 0;
aval->GetAvalancheSize(ne, ni);
hElectrons->Fill(ne);
hIons->Fill(ni);
const int np = aval->GetNumberOfElectronEndpoints();
double xe1, ye1, ze1, te1, e1;
double xe2, ye2, ze2, te2, e2;
double xi1, yi1, zi1, ti1;
double xi2, yi2, zi2, ti2;
int status;
for (int j = np; j--;) {
aval->GetElectronEndpoint(j, xe1, ye1, ze1, te1, e1,
xe2, ye2, ze2, te2, e2, status);
sumElectronsTotal += 1.;
if (ze2 > -kapton / 2. && ze2 < kapton / 2.) {
hChrgE->Fill(ze2 * 1.e4);
sumElectronsPlastic += 1.;
} else if (ze2 >= kapton / 2. && ze2 <= kapton / 2. + metal) {
sumElectronsUpperMetal += 1.;
} else if (ze2 <= -kapton / 2. && ze2 >= -kapton / 2. - metal) {
sumElectronsLowerMetal += 1.;
} else if (ze2 < -kapton / 2. - metal) {
sumElectronsTransfer += 1.;
} else {
sumElectronsOther += 1.;
}
drift->DriftIon(xe1, ye1, ze1, te1);
drift->GetIonEndpoint(0, xi1, yi1, zi1, ti1,
xi2, yi2, zi2, ti2, status);
if (zi1 < 0.01) {
sumIonsTotal += 1.;
if (zi2 > 0.01) sumIonsDrift += 1.;
}
if (zi2 > -kapton / 2. && zi2 < kapton / 2.) {
hChrgI->Fill(zi2 * 1.e4);
sumIonsPlastic += 1.;
}
}
}
double fFeedback = 0.;
if (sumIonsTotal > 0.) fFeedback = sumIonsDrift / sumIonsTotal;
std::cout << "Fraction of ions drifting back: " << fFeedback << "\n";
const double neMean = hElectrons->GetMean();
std::cout << "Mean number of electrons: " << neMean << "\n";
const double niMean = hIons->GetMean();
std::cout << "Mean number of ions: " << niMean << "\n";
std::cout << "Mean number of electrons on plastic: "
<< sumElectronsPlastic / nEvents << "\n";
std::cout << "Mean number of ions on plastic: "
<< sumIonsPlastic / nEvents << "\n";
std::cout << "Electron endpoints:\n";
const double fUpperMetal = sumElectronsUpperMetal / sumElectronsTotal;
const double fPlastic = sumElectronsPlastic / sumElectronsTotal;
const double fLowerMetal = sumElectronsLowerMetal / sumElectronsTotal;
const double fTransfer = sumElectronsTransfer / sumElectronsTotal;
const double fOther = sumElectronsOther / sumElectronsTotal;
std::cout << " upper metal: " << fUpperMetal * 100. << "%\n";
std::cout << " plastic: " << fPlastic * 100. << "%\n";
std::cout << " lower metal: " << fLowerMetal * 100. << "%\n";
std::cout << " transfer: " << fTransfer * 100. << "%\n";
std::cout << " other: " << fOther * 100. << "%\n";
TCanvas* cD = new TCanvas();
const bool plotGeo = true;
if (plotGeo && plotDrift) {
// Build the geometry in Root.
TGeoManager* geoman = new TGeoManager("world", "geometry");
TGeoMaterial* matVacuum = new TGeoMaterial("Vacuum", 0, 0, 0);
TGeoMedium* medVacuum = new TGeoMedium("Vacuum", 1, matVacuum);
TGeoMaterial* matKapton = new TGeoMaterial("Kapton", 12, 6, 1.42);
TGeoMedium* medKapton = new TGeoMedium("Kapton", 2, matKapton);
TGeoMaterial* matCopper = new TGeoMaterial("Copper", 63, 29, 8.94);
TGeoMedium* medCopper = new TGeoMedium("Copper", 3, matCopper);
TGeoVolume* volTop = geoman->MakeBox("TOP",
medVacuum, pitch, pitch, 0.02);
volTop->SetVisibility(0);
TGeoBBox* shpKapton = new TGeoBBox("K", pitch / 2.,
pitch / 2.,
kapton / 2.);
TGeoPcon* shpHole = new TGeoPcon("H", 0., 360., 3);
shpHole->DefineSection(0, -kapton / 2., 0., outdia / 2.);
shpHole->DefineSection(1, 0., 0., middia / 2.);
shpHole->DefineSection(2, kapton / 2., 0., outdia / 2.);
TGeoCompositeShape* shpGem = new TGeoCompositeShape("G", "K - H");
TGeoVolume* volKapton = new TGeoVolume("Kapton", shpGem, medKapton);
volKapton->SetLineColor(kGreen);
volKapton->SetTransparency(50);
TGeoBBox* shpMetal = new TGeoBBox("M", pitch / 2.,
pitch / 2.,
metal / 2.);
TGeoTube* shpTube = new TGeoTube("T", 0., outdia / 2., metal / 2.);
TGeoCompositeShape* shpElectrode = new TGeoCompositeShape("E", "M - T");
TGeoVolume* volElectrode = new TGeoVolume("Electrode",
shpElectrode, medCopper);
volElectrode->SetLineColor(kBlue);
volElectrode->SetTransparency(50);
TGeoVolumeAssembly* volGem = new TGeoVolumeAssembly("Gem");
const double shift = 0.5 * (metal + kapton);
volGem->AddNode(volKapton, 1);
volGem->AddNode(volElectrode, 2, new TGeoTranslation(0., 0., shift));
volGem->AddNode(volElectrode, 3, new TGeoTranslation(0., 0., -shift));
volTop->AddNode(volGem, 1);
volTop->AddNode(volGem, 2, new TGeoTranslation(-pitch, 0., 0.));
volTop->AddNode(volGem, 3, new TGeoTranslation(+pitch, 0., 0.));
volTop->AddNode(volGem, 4,
new TGeoTranslation(-pitch / 2., sqrt(3) * pitch / 2., 0.));
volTop->AddNode(volGem, 5,
new TGeoTranslation(+pitch / 2., sqrt(3) * pitch / 2., 0.));
volTop->AddNode(volGem, 6,
new TGeoTranslation(-pitch / 2., -sqrt(3) * pitch / 2., 0.));
volTop->AddNode(volGem, 7,
new TGeoTranslation(+pitch / 2., -sqrt(3) * pitch / 2., 0.));
geoman->SetVerboseLevel(0);
geoman->SetTopVolume(volTop);
geoman->CloseGeometry();
geoman->CheckOverlaps(0.1e-4);
geoman->SetNmeshPoints(100000);
cD->cd();
geoman->GetTopVolume()->Draw("ogl");
}
if (plotDrift) {
driftView->SetCanvas(cD);
driftView->Plot();
}
const bool plotHistogram = true;
if (plotHistogram) {
TCanvas* cH = new TCanvas("cH", "Histograms", 800, 700);
cH->Divide(2, 2);
cH->cd(1);
hElectrons->Draw();
cH->cd(2);
hIons->Draw();
cH->cd(3);
hChrgE->Draw();
cH->cd(4);
hChrgI->Draw();
}
app.Run(kTRUE);
}
