// General Root includes
#include <Riostream.h>
#include <TMath.h>
+#include <float.h>
#include <TFile.h> // only required for Tracking function?
#include <TObjArray.h>
#include <TClonesArray.h>
#include <TGeoNode.h>
#include <TGeoMaterial.h>
#include <TGeoMedium.h>
+#include "AliITSv11GeometrySupport.h"
// General AliRoot includes
#include "AliRun.h"
#include "AliMagF.h"
#include "AliITSClusterFinderSSD.h"
#include "AliITSBaseGeometry.h"
#include "AliITSv11.h"
-
-// Units, Convert from k?? to cm,degree,GeV,seconds,
-const Double_t kmm = 0.10; // Convert mm to TGeom's cm.
-const Double_t kcm = 1.00; // Convert cv to TGeom's cm.
-const Double_t kDegree = 1.0; // Convert degrees to TGeom's degrees
-const Double_t kRadian = TMath::DegToRad(); // conver to Radians
-
-#define SQ(A) ((A)*(A))
-
-#define printArb8(A) if(GetDebug()){\
- cout << A->GetName() << ":"; \
- for(Int_t iii=0;iii<8;iii+=2){ cout <<"("<<A->GetVertices()[iii]<<"," \
- <<A->GetVertices()[iii+1]<<","<<-A->GetDz()<<")";}\
- for(Int_t iii=8;iii<16;iii+=2){ cout <<"("<<A->GetVertices()[iii]<<"," \
- <<A->GetVertices()[iii+1]<<","<<A->GetDz()<<")";}\
- cout << endl; }
-
-#define printPcon(A) if(GetDebug()){\
- cout << A->GetName() << ": N=" << A->GetNz() << " Phi1=" << A->GetPhi1() \
- << ", Dphi=" << A->GetDphi() << endl; \
- cout << "i\t Z \t Rmin \t Rmax" << endl; \
- for(Int_t iii=0;iii<A->GetNz();iii++){ \
- cout << iii << "\t" << A->GetZ(iii) << "\t" << A->GetRmin(iii) \
- << "\t" << A->GetRmax(iii) << endl; \
- }} // end for iii
-
-#define printTube(A) if(GetDebug()){\
- cout << A->GetName() <<": Rmin="<<A->GetRmin()\
- <<" Rmax=" <<A->GetRmax()<<" Dz="<<A->GetDz()<<endl;}
-
-#define printTubeSeg(A) if(GetDebug()){\
- cout << A->GetName() <<": Phi1="<<A->GetPhi1()<< \
- " Phi2="<<A->GetPhi2()<<" Rmin="<<A->GetRmin()\
- <<" Rmax=" <<A->GetRmax()<<" Dz="<<A->GetDz()<<endl;}
-
-#define printConeSeg(A) if(GetDebug()){\
- cout << A->GetName() <<": Phi1="<<A->GetPhi1()<< \
- " Phi2="<<A->GetPhi2()<<" Rmin1="<<A->GetRmin1()\
- <<" Rmax1=" <<A->GetRmax1()<<" Rmin2="<<A->GetRmin2()\
- <<" Rmax2=" <<A->GetRmax2()<<" Dz="<<A->GetDz()<<endl;}
-
-#define printBBox(A) if(GetDebug()){\
- cout << A->GetName() <<": Dx="<<A->GetDX()<< \
- " Dy="<<A->GetDY()<<" Dz="<<A->GetDZ() <<endl;}
+#include "AliITSv11GeometrySupport.h"
ClassImp(AliITSv11)
ITSV->SetVisibility(kFALSE);
ALIC->AddNode(ITSV,1,0);
//
- SPDCone(ITSV);
- SDDCone(ITSV);
- SSDCone(ITSV);
- ServicesCableSupport(ITSV);
-}
-//______________________________________________________________________
-Double_t AliITSv11::RmaxFrom2Points(TGeoPcon *p,Int_t i1,Int_t i2,Double_t z){
- // functions Require at parts of Volume A to be already defined.
- // Retruns the value of Rmax corresponding to point z alone the line
- // defined by the two points p.Rmax(i1),p-GetZ(i1) and p->GetRmax(i2),
- // p->GetZ(i2).
-
- return p->GetRmax(i2)+(p->GetRmax(i1)-p->GetRmax(i2))*(z-p->GetZ(i2))/
- (p->GetZ(i1)-p->GetZ(i2));
-}
-//______________________________________________________________________
-Double_t AliITSv11::RminFrom2Points(TGeoPcon *p,Int_t i1,Int_t i2,Double_t z){
- // Retruns the value of Rmin corresponding to point z alone the line
- // defined by the two points p->GetRmin(i1),p->GetZ(i1) and
- // p->GetRmin(i2), p->GetZ(i2).
-
- return p->GetRmin(i2)+(p->GetRmin(i1)-p->GetRmin(i2))*(z-p->GetZ(i2))/
- (p->GetZ(i1)-p->GetZ(i2));
-}
-//______________________________________________________________________
-Double_t AliITSv11::RFrom2Points(Double_t *p,Double_t *Z,Int_t i1,
- Int_t i2,Double_t z){
- // Retruns the value of Rmin corresponding to point z alone the line
- // defined by the two points p->GetRmin(i1),p->GetZ(i1) and
- // p->GetRmin(i2), p->GetZ(i2).
-
- return p[i2]+(p[i1]-p[i2])*(z-Z[i2])/(Z[i1]-Z[i2]);
-}
-//______________________________________________________________________
-Double_t AliITSv11::Zfrom2MinPoints(TGeoPcon *p,Int_t i1,Int_t i2,Double_t r){
- // Retruns the value of Z corresponding to point R alone the line
- // defined by the two points p->GetRmin(i1),p->GetZ(i1) and
- // p->GetRmin(i2),p->GetZ(i2)
-
- return p->GetZ(i2)+(p->GetZ(i1)-p->GetZ(i2))*(r-p->GetRmin(i2))/
- (p->GetRmin(i1)-p->GetRmin(i2));
-}
-//______________________________________________________________________
-Double_t AliITSv11::Zfrom2MaxPoints(TGeoPcon *p,Int_t i1,Int_t i2,Double_t r){
- // Retruns the value of Z corresponding to point R alone the line
- // defined by the two points p->GetRmax(i1),p->GetZ(i1) and
- // p->GetRmax(i2),p->GetZ(i2)
-
- return p->GetZ(i2)+(p->GetZ(i1)-p->GetZ(i2))*(r-p->GetRmax(i2))/
- (p->GetRmax(i1)-p->GetRmax(i2));
-}
-//______________________________________________________________________
-Double_t AliITSv11::Zfrom2Points(Double_t *Z,Double_t *p,Int_t i1,
- Int_t i2,Double_t r){
- // Retruns the value of Z corresponding to point R alone the line
- // defined by the two points p->GetRmax(i1),p->GetZ(i1) and
- // p->GetRmax(i2),p->GetZ(i2)
-
- return Z[i2]+(Z[i1]-Z[i2])*(r-p[i2])/(p[i1]-p[i2]);
-}
-//______________________________________________________________________
-Double_t AliITSv11::RmaxFromZpCone(TGeoPcon *p,Double_t tc,Double_t z,
- Double_t th){
- // General SSD Outer Cone surface equation Rmax.
- Double_t tantc = TMath::Tan(tc*TMath::DegToRad());
- Double_t costc = TMath::Cos(tc*TMath::DegToRad());
-
- return -tantc*(z-p->GetZ(4))+p->GetRmax(4)+th/costc;
-}
-//______________________________________________________________________
-Double_t AliITSv11::RmaxFromZpCone(Double_t *GetRmax,Double_t *GetZ,
- Double_t tc,Double_t z,Double_t th){
- // General SSD Outer Cone surface equation Rmax.
- Double_t tantc = TMath::Tan(tc*TMath::DegToRad());
- Double_t costc = TMath::Cos(tc*TMath::DegToRad());
-
- return -tantc*(z-GetZ[4])+GetRmax[4]+th/costc;
-}
-//______________________________________________________________________
-Double_t AliITSv11::RminFromZpCone(TGeoPcon *p,Double_t tc,Double_t z,
- Double_t th){
- // General SSD Inner Cone surface equation Rmin.
- Double_t tantc = TMath::Tan(tc*TMath::DegToRad());
- Double_t costc = TMath::Cos(tc*TMath::DegToRad());
-
- return -tantc*(z-p->GetZ(3))+p->GetRmin(3)+th/costc;
-}
-//______________________________________________________________________
-Double_t AliITSv11::RminFromZpCone(Double_t *GetRmin,Double_t *GetZ,
- Double_t tc,Double_t z,Double_t th){
- // General SSD Inner Cone surface equation Rmin.
- Double_t tantc = TMath::Tan(tc*TMath::DegToRad());
- Double_t costc = TMath::Cos(tc*TMath::DegToRad());
-
- return -tantc*(z-GetZ[3])+GetRmin[3]+th/costc;
-}
-//______________________________________________________________________
-Double_t AliITSv11::ZFromRmaxpCone(TGeoPcon *p,Double_t tc,Double_t r,
- Double_t th){
- // General SSD Outer cone Surface equation for z.
- Double_t tantc = TMath::Tan(tc*TMath::DegToRad());
- Double_t costc = TMath::Cos(tc*TMath::DegToRad());
-
- return p->GetZ(4)+(p->GetRmax(4)+th/costc-r)/tantc;
-}
-//______________________________________________________________________
-Double_t AliITSv11::ZFromRmaxpCone(Double_t *GetRmax,Double_t *GetZ,
- Double_t tc,Double_t r,Double_t th){
- // General SSD Outer cone Surface equation for z.
- Double_t tantc = TMath::Tan(tc*TMath::DegToRad());
- Double_t costc = TMath::Cos(tc*TMath::DegToRad());
-
- return GetZ[4]+(GetRmax[4]+th/costc-r)/tantc;
-}
-//______________________________________________________________________
-Double_t AliITSv11::ZFromRminpCone(TGeoPcon *p,Double_t tc,Double_t r,
- Double_t th){
- // General SSD Inner cone Surface equation for z.
- Double_t tantc = TMath::Tan(tc*TMath::DegToRad());
- Double_t costc = TMath::Cos(tc*TMath::DegToRad());
-
- return p->GetZ(3)+(p->GetRmin(3)+th/costc-r)/tantc;
-}
-//______________________________________________________________________
-void AliITSv11::RadiusOfCurvature(Double_t rc,Double_t theta0,Double_t z0,
- Double_t r0,Double_t theta1,Double_t &z1,
- Double_t &r1){
- // Given a initial point z0,r0, the initial angle theta0, and the radius
- // of curvature, returns the point z1, r1 at the angle theta1. Theta
- // measured from the r axis in the clock wise direction [degrees].
- Double_t sin0 = TMath::Sin(theta0*TMath::DegToRad());
- Double_t cos0 = TMath::Cos(theta0*TMath::DegToRad());
- Double_t sin1 = TMath::Sin(theta1*TMath::DegToRad());
- Double_t cos1 = TMath::Cos(theta1*TMath::DegToRad());
-
- z1 = rc*(sin1-sin0)+z0;
- r1 = rc*(cos1-cos0)+r0;
- return;
-}
-//______________________________________________________________________
-void AliITSv11::SPDCone(TGeoVolume *Moth){
- // Define the detail SPD support cone geometry.
- // Inputs:
- // none.
- // Outputs:
- // none.
- // Return:
- // none.
-
- SPDThermalSheald(Moth);
-}
-//______________________________________________________________________
-void AliITSv11::SPDThermalSheald(TGeoVolume *Moth){
- // Define the detail SPD Thermal Sheld geometry.
- // Inputs:
- // none.
- // Outputs:
- // none.
- // Return:
- // none.
- // From ALICE-Thermal Screen (SPD) "Cylinder" file thermal-screen2_a3.ps
- // Volumes A1,A2,A2,Ah1,Ah2,Ah3, and B1,B2,B3,Bh1,Bh2,Bh3;
- // "CONE TRANSITION" file thermal-screen1_a3.ps Volumes C1,C2,C3,Ch1,Ch2,
- // Ch3; "FLANGE" file thermal-screen4_a3.ps Volumes D,Ds,Dw,Dws; and
- // "HALF ASSEMBLY" file thermal-screen3_a3.ps. This object, both halfs,
- // are incased inside of a single minimum sized mother volume called M,
- // which is a union of two parts M1 and 4 copies of M2.
- const Double_t TSCarbonFiberThA = 0.03*kmm; //
- //const Double_t TSCarbonFiberThB = 0.10*kmm; //
- const Double_t TSCLengthB = 50.0*kmm; //
- const Double_t TSCLengthA = 900.0*kmm-2.0*TSCLengthB; //
- const Double_t TSCLengthC = 290.0*kmm; //
- const Double_t TSCLengthD = 15.0*kmm; //
- const Double_t TSCAngle = 36.0*kDegree;//Rep. angle of cent. accordin
- const Double_t TSCRoutA = 99.255*kmm; // Outer radii
- const Double_t TSCRinA = 81.475*kmm; // Iner radii
- const Double_t TSCRoutB = 99.955*kmm; // Outer radii
- const Double_t TSCRinB = 80.775*kmm; // Iner radii
- const Double_t TSCRoutCp = 390.0*kmm; // Outer radii
- const Double_t TSCRinCp = 373.0*kmm; // Iner radii
- Double_t TSCRoutC,TSCRinC; // values need to be calculated
- const Double_t TSCRwingD = 492.5*kmm; // Outer radii
- const Double_t TSCRoutD = 0.5*840.*kmm;// Outer radii
- const Double_t TSCRinD = 373.0*kmm; // Iner radii
- const Double_t TSCAngleDD = 60.*kmm/TSCRwingD/kRadian;//angular wing width
- //angular wing width of fill material
- const Double_t TSCAngleDDs = (60.*kmm-2.*TSCarbonFiberThA)/TSCRwingD/kRadian;
- const Double_t TSCAngleD0 = 45.*kDegree;//Strting angle of wing
- const Double_t TSCoutSA = 24.372*kmm; // The other one Calculated
- const Double_t TSCinLA = 31.674*kmm; // The ohter one Calculated
- const Double_t TSCoutSB = 24.596*kmm; // The other one Calculated
- const Double_t TSCinLB = 31.453*kmm; // The ohter one Calculated
- const Double_t TSCoutSC = 148.831*kmm;// The other one Calculated
- const Double_t TSCinLC = 90.915*kmm; // The ohter one Calculated
- Int_t i,k;
- Double_t th;
- Double_t xo[7],yo[7],xi[7],yi[7];
- Double_t xbo[7],ybo[7],xbi[7],ybi[7];
- Double_t xco[7],yco[7],xci[7],yci[7];
- TGeoArb8 *A1,*A2,*A3,*Ah1,*Ah2,*Ah3,*B1,*B2,*B3,*Bh1,*Bh2,*Bh3;
- TGeoArb8 *C1,*C2,*C3,*Ch1,*Ch2,*Ch3;
- TGeoTube *D,*Ds;
- TGeoTubeSeg *Dw,*Dws,*M2;
- TGeoPcon *M1;
- TGeoCompositeShape *M;
- TGeoRotation *rot;
- TGeoTranslation *tranb,*tranbm,*tranc;
- TGeoTranslation *tranITSspdShealdVVt0;
- TGeoCombiTrans *rotITSspdShealdVVt1,*rotITSspdShealdVVt2;
- TGeoCombiTrans *rotITSspdShealdVVt3;
- TGeoMedium *SPDcf = 0; // SPD support cone Carbon Fiber materal number.
- TGeoMedium *SPDfs = 0; // SPD support cone inserto stesalite 4411w.
- TGeoMedium *SPDfo = 0; // SPD support cone foam, Rohacell 50A.
- TGeoMedium *SPDss = 0; // SPD support cone screw material,Stainless steal
- TGeoMedium *SPDair = 0; // SPD support cone Air
- //TGeoMedium *SPDal = 0; // SPD support cone SDD mounting bracket Al
-
- TSCRoutC = TMath::Sqrt(TSCRoutCp*TSCRoutCp-0.25*TSCoutSC*TSCoutSC);
- TSCRinC = TMath::Sqrt(TSCRinCp *TSCRinCp -0.25*TSCinLC *TSCinLC );
- A1 = new TGeoArb8("ITS SPD Therm Screen Clyinder A1",0.5*TSCLengthA);
- A2 = new TGeoArb8("ITS SPD Therm Screen Clyinder A2",0.5*TSCLengthA);
- A3 = new TGeoArb8("ITS SPD Therm Screen Clyinder A3",0.5*TSCLengthA);
- Ah1 = new TGeoArb8("ITS SPD Therm Screen Cylinder Ah1",0.5*TSCLengthA);
- Ah2 = new TGeoArb8("ITS SPD Therm Screen Cylinder Ah2",0.5*TSCLengthA);
- Ah3 = new TGeoArb8("ITS SPD Therm Screen Cylinder Ah3",0.5*TSCLengthA);
- B1 = new TGeoArb8("ITS SPD Therm Screen Clyinder B1",0.5*TSCLengthB);
- B2 = new TGeoArb8("ITS SPD Therm Screen Clyinder B2",0.5*TSCLengthB);
- B3 = new TGeoArb8("ITS SPD Therm Screen Clyinder B3",0.5*TSCLengthB);
- Bh1 = new TGeoArb8("ITS SPD Therm Screen Cylinder Bh1",0.5*TSCLengthB);
- Bh2 = new TGeoArb8("ITS SPD Therm Screen Cylinder Bh2",0.5*TSCLengthB);
- Bh3 = new TGeoArb8("ITS SPD Therm Screen Cylinder Bh3",0.5*TSCLengthB);
- C1 = new TGeoArb8("ITS SPD Therm Screen Clyinder C1",0.5*TSCLengthC);
- C2 = new TGeoArb8("ITS SPD Therm Screen Clyinder C2",0.5*TSCLengthC);
- C3 = new TGeoArb8("ITS SPD Therm Screen Clyinder C3",0.5*TSCLengthC);
- Ch1 = new TGeoArb8("ITS SPD Therm Screen Cylinder Ch1",0.5*TSCLengthC);
- Ch2 = new TGeoArb8("ITS SPD Therm Screen Cylinder Ch2",0.5*TSCLengthC);
- Ch3 = new TGeoArb8("ITS SPD Therm Screen Cylinder Ch3",0.5*TSCLengthC);
- D = new TGeoTube("ITS SPD Therm Screen Flange D",TSCRinD,TSCRoutD,
- 0.5*TSCLengthD);
- Ds = new TGeoTube("ITS SPD Therm Screen Flange fill Ds",
- TSCRinD+TSCarbonFiberThA,TSCRoutD-TSCarbonFiberThA,
- 0.5*TSCLengthD);
- printTube(D);
- printTube(Ds);
- Dw = new TGeoTubeSeg("ITS SPD Therm Screen Flange Wing Dw",
- TSCRoutD,TSCRwingD ,0.5*TSCLengthD,
- TSCAngleD0-0.5*TSCAngleDD,TSCAngleD0+0.5*TSCAngleDD);
- Dws = new TGeoTubeSeg("ITS SPD Therm Screen Flange Wing Fill Ds",
- TSCRoutD,TSCRwingD-TSCarbonFiberThA,
- 0.5*TSCLengthD,TSCAngleD0-0.5*TSCAngleDDs,
- TSCAngleD0+0.5*TSCAngleDDs);
- printTubeSeg(Dw);
- printTubeSeg(Dws);
- k = 0;
- for(i=-1;i<2;i++){
- th = ((Double_t)(i+1))*TSCAngle*kRadian;
- xo[k] = TSCRoutA*TMath::Sin(th) - 0.5*TSCoutSA*TMath::Cos(th);
- yo[k] = TSCRoutA*TMath::Cos(th) + 0.5*TSCoutSA*TMath::Sin(th);
- xi[k] = TSCRinA *TMath::Sin(th) - 0.5*TSCinLA *TMath::Cos(th);
- yi[k] = TSCRinA *TMath::Cos(th) + 0.5*TSCinLA *TMath::Sin(th);
- xbo[k] = TSCRoutB*TMath::Sin(th) - 0.5*TSCoutSB*TMath::Cos(th);
- ybo[k] = TSCRoutB*TMath::Cos(th) + 0.5*TSCoutSB*TMath::Sin(th);
- xbi[k] = TSCRinB *TMath::Sin(th) - 0.5*TSCinLB *TMath::Cos(th);
- ybi[k] = TSCRinB *TMath::Cos(th) + 0.5*TSCinLB *TMath::Sin(th);
- xco[k] = TSCRoutC*TMath::Sin(th) - 0.5*TSCoutSC*TMath::Cos(th);
- yco[k] = TSCRoutC*TMath::Cos(th) + 0.5*TSCoutSC*TMath::Sin(th);
- xci[k] = TSCRinC *TMath::Sin(th) - 0.5*TSCinLC *TMath::Cos(th);
- yci[k] = TSCRinC *TMath::Cos(th) + 0.5*TSCinLC *TMath::Sin(th);
- k++;
- xo[k] = TSCRoutA*TMath::Sin(th) + 0.5*TSCoutSA*TMath::Cos(th);
- yo[k] = TSCRoutA*TMath::Cos(th) - 0.5*TSCoutSA*TMath::Sin(th);
- xi[k] = TSCRinA *TMath::Sin(th) + 0.5*TSCinLA *TMath::Cos(th);
- yi[k] = TSCRinA *TMath::Cos(th) - 0.5*TSCinLA *TMath::Sin(th);
- xbo[k] = TSCRoutB*TMath::Sin(th) + 0.5*TSCoutSB*TMath::Cos(th);
- ybo[k] = TSCRoutB*TMath::Cos(th) - 0.5*TSCoutSB*TMath::Sin(th);
- xbi[k] = TSCRinB *TMath::Sin(th) + 0.5*TSCinLB *TMath::Cos(th);
- ybi[k] = TSCRinB *TMath::Cos(th) - 0.5*TSCinLB *TMath::Sin(th);
- xco[k] = TSCRoutC*TMath::Sin(th) + 0.5*TSCoutSC*TMath::Cos(th);
- yco[k] = TSCRoutC*TMath::Cos(th) - 0.5*TSCoutSC*TMath::Sin(th);
- xci[k] = TSCRinC *TMath::Sin(th) + 0.5*TSCinLC *TMath::Cos(th);
- yci[k] = TSCRinC *TMath::Cos(th) - 0.5*TSCinLC *TMath::Sin(th);
- k++;
- } // end for i
- xo[6] = xo[5];
- yo[6] = 0.0;
- xi[6] = xi[5];
- yi[6] = 0.0;
- xbo[6] = xbo[5];
- ybo[6] = 0.0;
- xbi[6] = xbi[5];
- ybi[6] = 0.0;
- xco[6] = xco[5];
- yco[6] = 0.0;
- xci[6] = xci[5];
- yci[6] = 0.0;
- if(GetDebug()){
- cout.precision(4);
- cout.width(7);
- cout <<"i \t xo yo \t xi yi \t xbo ybo \t xbi ybi "
- "\t xco yco \t xci yxi"<<endl;
- for(i=0;i<7;i++){
- cout << i <<"\t"<<xo[i]<<","<<yo[i];
- cout <<"\t"<<xi[i]<<","<<yi[i];
- cout <<"\t"<<xbo[i]<<","<<ybo[i];
- cout <<"\t"<<xbi[i]<<","<<ybi[i];
- cout <<"\t"<<xco[i]<<","<<yco[i];
- cout <<"\t"<<xci[i]<<","<<yci[i];
- cout<<endl;}
- } // end if GetDebug()
- //+++++++++++++++++++++++++
- A1->SetVertex(0,xo[0],yo[0]);
- A1->SetVertex(1,xo[1],yo[1]);
- A1->SetVertex(2,xi[1],yi[1]);
- A1->SetVertex(3,xi[0],yi[0]);
- //
- A2->SetVertex(0,xo[1],yo[1]);
- A2->SetVertex(1,xo[2],yo[2]);
- A2->SetVertex(2,xi[2],yi[2]);
- A2->SetVertex(3,xi[1],yi[1]);
- //
- A3->SetVertex(0,xo[5],yo[5]);
- A3->SetVertex(1,xo[6],yo[6]);
- A3->SetVertex(2,xi[6],yi[6]);
- A3->SetVertex(3,xi[5],yi[5]);
- //--------------------------
- B1->SetVertex(0,xbo[0],ybo[0]);
- B1->SetVertex(1,xbo[1],ybo[1]);
- B1->SetVertex(2,xbi[1],ybi[1]);
- B1->SetVertex(3,xbi[0],ybi[0]);
- //
- B2->SetVertex(0,xbo[1],ybo[1]);
- B2->SetVertex(1,xbo[2],ybo[2]);
- B2->SetVertex(2,xbi[2],ybi[2]);
- B2->SetVertex(3,xbi[1],ybi[1]);
- //
- B3->SetVertex(0,xbo[5],ybo[5]);
- B3->SetVertex(1,xbo[6],ybo[6]);
- B3->SetVertex(2,xbi[6],ybi[6]);
- B3->SetVertex(3,xbi[5],ybi[5]);
- //--------------------------
- C1->SetVertex(0,xco[0],yco[0]);
- C1->SetVertex(1,xco[1],yco[1]);
- C1->SetVertex(2,xci[1],yci[1]);
- C1->SetVertex(3,xci[0],yci[0]);
- //
- C2->SetVertex(0,xco[1],yco[1]);
- C2->SetVertex(1,xco[2],yco[2]);
- C2->SetVertex(2,xci[2],yci[2]);
- C2->SetVertex(3,xci[1],yci[1]);
- //
- C3->SetVertex(0,xco[5],yco[5]);
- C3->SetVertex(1,xco[6],yco[6]);
- C3->SetVertex(2,xci[6],yci[6]);
- C3->SetVertex(3,xci[5],yci[5]);
- // Defining the hole, filled with air
- Double_t p1,c1,x,y,x7[3],y7[3];
- p1 = (xo[0]-xi[0])/(yo[0]-yi[0]);
- c1 = xo[0]+0.5*TSCarbonFiberThA*TMath::Sqrt(SQ(xo[0]-xi[0])+
- SQ(yo[0]-yi[0]))/(xo[0]-xi[0]);
- y = TSCRoutA-2.*TSCarbonFiberThA;
- x = p1*(y-yo[0])+c1;
- Ah1->SetVertex(0,x,y);
- Bh1->SetVertex(0,x,y);
- Ch1->SetVertex(4,x,y);
- y = TSCRinA+TSCarbonFiberThA;
- x = p1*(y-yo[0])+c1;
- Ah1->SetVertex(3,x,y);
- Bh1->SetVertex(3,x,y);
- x7[0] = x; y7[0] = y; // vortexing done after last point
- //Ch1->SetVertex(7,x,y);
- p1 = (xo[1]-xi[1])/(yo[1]-yi[1]);
- c1 = xo[1]-0.5*TSCarbonFiberThA*TMath::Sqrt(SQ(xo[1]-xi[1])+
- SQ(yo[1]-yi[1]))/(xo[1]-xi[1]);
- y = TSCRoutA-2.*TSCarbonFiberThA;
- x = p1*(y-yo[1])+c1;
- Ah1->SetVertex(1,x,y);
- Bh1->SetVertex(1,x,y);
- Ch1->SetVertex(5,x,y);
- y = TSCRinA+TSCarbonFiberThA;
- x = p1*(y-yo[1])+c1;
- Ah1->SetVertex(2,x,y);
- Bh1->SetVertex(2,x,y);
- Ch1->SetVertex(6,x,y);
- //
- // The easist way to get the points for the hole in volume A2 is to
- // rotate it to the Y axis where the y coordinates are easier to know
- // and then rotate it back.
- Double_t xp,yp,xa,ya,xb,yb;
- th = 0.5*TSCAngle*kRadian;
- xa = TMath::Cos(th)*xo[1]-TMath::Sin(th)*yo[1];
- ya = TMath::Sin(th)*xo[1]+TMath::Cos(th)*yo[1];
- xb = TMath::Cos(th)*xi[1]-TMath::Sin(th)*yi[1];
- yb = TMath::Sin(th)*xi[1]+TMath::Cos(th)*yi[1];
- p1 = (xa-xb)/(ya-yb);
- c1 = xa+0.5*TSCarbonFiberThA*TMath::Sqrt(SQ(xa-xb)+SQ(ya-yb))/(xa-xb);
- y = ya-TSCarbonFiberThA;
- x = p1*(y-ya)+c1;
- xp = TMath::Cos(-th)*x-TMath::Sin(-th)*y;
- yp = TMath::Sin(-th)*x+TMath::Cos(-th)*y;
- Ah2->SetVertex(0,xp,yp);
- Bh2->SetVertex(0,xp,yp);
- Ch2->SetVertex(4,xp,yp);
- y = yb+2.0*TSCarbonFiberThA;
- x = p1*(y-ya)+c1;
- xp = TMath::Cos(-th)*x-TMath::Sin(-th)*y;
- yp = TMath::Sin(-th)*x+TMath::Cos(-th)*y;
- Ah2->SetVertex(3,xp,yp);
- Bh2->SetVertex(3,xp,yp);
- x7[1] = x; y7[1] = y; // vortexing done after last point
- //Ch2->SetVertex(7,xp,yp);
- xa = TMath::Cos(th)*xo[2]-TMath::Sin(th)*yo[2];
- ya = TMath::Sin(th)*xo[2]+TMath::Cos(th)*yo[2];
- xb = TMath::Cos(th)*xi[2]-TMath::Sin(th)*yi[2];
- yb = TMath::Sin(th)*xi[2]+TMath::Cos(th)*yi[2];
- p1 = (xa-xb)/(ya-yb);
- c1 = xa-0.5*TSCarbonFiberThA*TMath::Sqrt(SQ(xa-xb)+SQ(ya-yb))/(xa-xb);
- y = ya-TSCarbonFiberThA;
- x = p1*(y-ya)+c1;
- xp = TMath::Cos(-th)*x-TMath::Sin(-th)*y;
- yp = TMath::Sin(-th)*x+TMath::Cos(-th)*y;
- Ah2->SetVertex(1,xp,yp);
- Bh2->SetVertex(1,xp,yp);
- Ch2->SetVertex(5,xp,yp);
- y = yb+2.0*TSCarbonFiberThA;
- x = p1*(y-ya)+c1;
- xp = TMath::Cos(-th)*x-TMath::Sin(-th)*y;
- yp = TMath::Sin(-th)*x+TMath::Cos(-th)*y;
- Ah2->SetVertex(2,xp,yp);
- Bh2->SetVertex(2,xp,yp);
- Ch2->SetVertex(6,xp,yp);
- //
- p1 = (yo[5]-yi[5])/(xo[5]-xi[5]);
- c1 = yo[5]+0.5*TSCarbonFiberThA*TMath::Sqrt(SQ(yo[5]-yi[5])+
- SQ(xo[5]-xi[5]))/(yo[5]-yi[5]);
- x = xo[5]-TSCarbonFiberThA;
- y = p1*(x-xo[5])+c1;
- Ah3->SetVertex(0,x,y);
- Bh3->SetVertex(0,x,y);
- Ch3->SetVertex(4,x,y);
- x = xi[5]+2.0*TSCarbonFiberThA;
- y = p1*(x-xo[5])+c1;
- Ah3->SetVertex(3,x,y);
- Bh3->SetVertex(3,x,y);
- x7[2] = x; y7[2] = y; // vortexing done after last point
- //Ch3->SetVertex(7,x,y);
- y = 2.0*TSCarbonFiberThA;
- x = xo[5]-TSCarbonFiberThA;
- Ah3->SetVertex(1,x,y);
- Bh3->SetVertex(1,x,y);
- Ch3->SetVertex(5,x,y);
- y = 2.0*TSCarbonFiberThA;
- x = xi[5]+2.0*TSCarbonFiberThA;
- Ah3->SetVertex(2,x,y);
- Bh3->SetVertex(2,x,y);
- Ch3->SetVertex(6,x,y);
- //
- for(i=0;i<4;i++){ // define points at +dz
- A1->SetVertex(i+4,(A1->GetVertices())[2*i],(A1->GetVertices())[1+2*i]);
- A2->SetVertex(i+4,(A2->GetVertices())[2*i],(A2->GetVertices())[1+2*i]);
- A3->SetVertex(i+4,(A3->GetVertices())[2*i],(A3->GetVertices())[1+2*i]);
- //
- B1->SetVertex(i+4,(B1->GetVertices())[2*i],(B1->GetVertices())[1+2*i]);
- B2->SetVertex(i+4,(B2->GetVertices())[2*i],(B2->GetVertices())[1+2*i]);
- B3->SetVertex(i+4,(B3->GetVertices())[2*i],(B3->GetVertices())[1+2*i]);
- // C's are a cone which must match up with B's.
- C1->SetVertex(i+4,(B1->GetVertices())[2*i],(B1->GetVertices())[1+2*i]);
- C2->SetVertex(i+4,(B2->GetVertices())[2*i],(B2->GetVertices())[1+2*i]);
- C3->SetVertex(i+4,(B3->GetVertices())[2*i],(B3->GetVertices())[1+2*i]);
- //
- Ah1->SetVertex(i+4,(Ah1->GetVertices())[2*i],
- (Ah1->GetVertices())[1+2*i]);
- Ah2->SetVertex(i+4,(Ah2->GetVertices())[2*i],
- (Ah2->GetVertices())[1+2*i]);
- Ah3->SetVertex(i+4,(Ah3->GetVertices())[2*i],
- (Ah3->GetVertices())[1+2*i]);
- //
- Bh1->SetVertex(i+4,(Bh1->GetVertices())[2*i],
- (Bh1->GetVertices())[1+2*i]);
- Bh2->SetVertex(i+4,(Bh2->GetVertices())[2*i],
- (Bh2->GetVertices())[1+2*i]);
- Bh3->SetVertex(i+4,(Bh3->GetVertices())[2*i],
- (Bh3->GetVertices())[1+2*i]);
- } // end for
- //
- p1 = (xco[0]-xci[0])/(yco[0]-yci[0]);
- c1 = xco[0]+0.5*TSCarbonFiberThA*TMath::Sqrt(SQ(xco[0]-xci[0])+
- SQ(yco[0]-yci[0]))/(xco[0]-xci[0]);
- y = TSCRoutC-2.*TSCarbonFiberThA;
- x = p1*(y-yco[0])+c1;
- Ch1->SetVertex(0,x,y);
- y = TSCRinC+TSCarbonFiberThA;
- x = p1*(y-yci[0])+c1;
- Ch1->SetVertex(2,x,y);
- p1 = (xco[1]-xci[1])/(yco[1]-yci[1]);
- c1 = xco[1]-0.5*TSCarbonFiberThA*TMath::Sqrt(SQ(xco[1]-xci[1])+
- SQ(yco[1]-yci[1]))/(xco[1]-xci[1]);
- y = TSCRoutC-2.*TSCarbonFiberThA;
- x = p1*(y-yco[1])+c1;
- Ch1->SetVertex(1,x,y);
- y = TSCRinC+TSCarbonFiberThA;
- x = p1*(y-yci[1])+c1;
- Ch1->SetVertex(3,x,y);
- //
- th = 0.5*TSCAngle*kRadian;
- xa = TMath::Cos(th)*xco[1]-TMath::Sin(th)*yco[1];
- ya = TMath::Sin(th)*xco[1]+TMath::Cos(th)*yco[1];
- xb = TMath::Cos(th)*xci[1]-TMath::Sin(th)*yci[1];
- yb = TMath::Sin(th)*xci[1]+TMath::Cos(th)*yci[1];
- p1 = (xa-xb)/(ya-yb);
- c1 = xa+0.5*TSCarbonFiberThA*TMath::Sqrt(SQ(xa-xb)+SQ(ya-yb))/(xa-xb);
- y = ya-TSCarbonFiberThA;
- x = p1*(y-ya)+c1;
- xp = TMath::Cos(-th)*x-TMath::Sin(-th)*y;
- yp = TMath::Sin(-th)*x+TMath::Cos(-th)*y;
- yp = ya-TSCarbonFiberThA;
- xp = p1*(y-ya)+c1;
- Ch2->SetVertex(0,xp,yp);
- y = yb+2.0*TSCarbonFiberThA;
- x = p1*(y-ya)+c1;
- xp = TMath::Cos(-th)*x-TMath::Sin(-th)*y;
- yp = TMath::Sin(-th)*x+TMath::Cos(-th)*y;
- Ch2->SetVertex(2,xp,yp);
- xa = TMath::Cos(th)*xco[2]-TMath::Sin(th)*yco[2];
- ya = TMath::Sin(th)*xco[2]+TMath::Cos(th)*yco[2];
- xb = TMath::Cos(th)*xci[2]-TMath::Sin(th)*yci[2];
- yb = TMath::Sin(th)*xci[2]+TMath::Cos(th)*yci[2];
- p1 = (xa-xb)/(ya-yb);
- c1 = xa-0.5*TSCarbonFiberThA*TMath::Sqrt(SQ(xa-xb)+SQ(ya-yb))/(xa-xb);
- y = ya-TSCarbonFiberThA;
- x = p1*(y-ya)+c1;
- xp = TMath::Cos(-th)*x-TMath::Sin(-th)*y;
- yp = TMath::Sin(-th)*x+TMath::Cos(-th)*y;
- Ch2->SetVertex(1,xp,yp);
- y = yb+2.0*TSCarbonFiberThA;
- x = p1*(y-ya)+c1;
- xp = TMath::Cos(-th)*x-TMath::Sin(-th)*y;
- yp = TMath::Sin(-th)*x+TMath::Cos(-th)*y;
- Ch2->SetVertex(3,xp,yp);
- //
- p1 = (yco[5]-yci[5])/(xco[5]-xci[5]);
- c1 = yco[5]+0.5*TSCarbonFiberThA*TMath::Sqrt(SQ(yco[5]-yci[5])+
- SQ(xco[5]-xci[5]))/(yco[5]-yci[5]);
- x = xco[5]-TSCarbonFiberThA;
- y = p1*(x-xco[5])+c1;
- Ch3->SetVertex(0,x,y);
- x = xci[5]+2.0*TSCarbonFiberThA;
- y = p1*(x-xci[5])+c1;
- Ch3->SetVertex(2,x,y);
- y = 2.0*TSCarbonFiberThA;
- x = xco[5]-TSCarbonFiberThA;
- Ch3->SetVertex(1,x,y);
- y = 2.0*TSCarbonFiberThA;
- x = xci[5]+2.0*TSCarbonFiberThA;
- Ch3->SetVertex(3,x,y);
- Ch1->SetVertex(7,x7[0],y7[0]); // 7th point most be done last ???
- Ch2->SetVertex(7,x7[1],y7[1]); // 7th point most be done last ???
- Ch3->SetVertex(7,x7[2],y7[2]); // 7th point most be done last ???
- printArb8(A1);
- printArb8(Ah1);
- printArb8(A2);
- printArb8(Ah2);
- printArb8(A3);
- printArb8(Ah3);
- printArb8(B1);
- printArb8(Bh1);
- printArb8(B2);
- printArb8(Bh2);
- printArb8(B3);
- printArb8(Bh3);
- printArb8(C1);
- printArb8(Ch1);
- printArb8(C2);
- printArb8(Ch2);
- printArb8(C3);
- printArb8(Ch3);
- //
- // Define Minimal volume to inclose this SPD Thermal Sheald.
- M1 = new TGeoPcon("ITSspdShealdVV",0.0,360.0,9);
- M1->Z(0) = 0.5*TSCLengthA+TSCLengthB;
- M1->Rmin(0) = TSCRinB;
- x = B1->GetVertices()[0]; // [0][0]
- y = B1->GetVertices()[1]; // [0][1]
- M1->Rmax(0) = TMath::Sqrt(x*x+y*y);
- M1->Z(1) = M1->GetZ(0)-TSCLengthB;
- M1->Rmin(1) = M1->GetRmin(0);
- M1->Rmax(1) = M1->GetRmax(0);
- M1->Z(2) = M1->GetZ(1);
- M1->Rmin(2) = TSCRinA;
- x = A1->GetVertices()[0]; // [0]0]
- y = A1->GetVertices()[1]; // [0][1]
- M1->Rmax(2) = TMath::Sqrt(x*x+y*y);
- M1->Z(3) = -(M1->GetZ(0)-TSCLengthB);
- M1->Rmin(3) = M1->GetRmin(2);
- M1->Rmax(3) = M1->GetRmax(2);
- M1->Z(4) = M1->GetZ(3);
- M1->Rmin(4) = M1->GetRmin(1);
- M1->Rmax(4) = M1->GetRmax(1);
- M1->Z(5) = -(M1->GetZ(0));
- M1->Rmin(5) = M1->GetRmin(0);
- M1->Rmax(5) = M1->GetRmax(0);
- M1->Z(6) = M1->GetZ(5) - TSCLengthC;
- M1->Rmin(6) = TSCRinC;
- x = C1->GetVertices()[0]; // [0][0]
- y = C1->GetVertices()[1]; // [0][1]
- M1->Rmax(6) = TMath::Sqrt(x*x+y*y);
- M1->Z(7) = M1->GetZ(6);
- M1->Rmin(7) = D->GetRmin();
- M1->Rmax(7) = D->GetRmax();
- M1->Z(8) = M1->Z(7) - TSCLengthD;
- M1->Rmin(8) = M1->GetRmin(7);
- M1->Rmax(8) = M1->GetRmax(7);
- M2 = new TGeoTubeSeg("ITSspdShealdWingVV",
- M1->GetRmax(8),Dw->GetRmax(),Dw->GetDz(),Dw->GetPhi1(),Dw->GetPhi2());
- printTubeSeg(M2);
- //
- x = 0.5*(M1->GetZ(8) + M1->GetZ(7));
- tranITSspdShealdVVt0 = new TGeoTranslation("ITSspdShealdVVt0",0.0,0.0,x);
- tranITSspdShealdVVt0->RegisterYourself();
- TGeoRotation rotz90("",0.0,0.0,90.0); // never registered.
- rotITSspdShealdVVt1 = new TGeoCombiTrans(*tranITSspdShealdVVt0,rotz90);
- rotITSspdShealdVVt1->SetName("ITSspdShealdVVt1");
- rotITSspdShealdVVt1->RegisterYourself();
- TGeoRotation rotz180("",0.0,0.0,180.0); // never registered
- rotITSspdShealdVVt2 = new TGeoCombiTrans(*tranITSspdShealdVVt0,rotz180);
- rotITSspdShealdVVt2->SetName("ITSspdShealdVVt2");
- rotITSspdShealdVVt2->RegisterYourself();
- TGeoRotation rotz270("",0.0,0.0,270.0); // never registered
- rotITSspdShealdVVt3 = new TGeoCombiTrans(*tranITSspdShealdVVt0,rotz270);
- rotITSspdShealdVVt3->SetName("ITSspdShealdVVt3");
- rotITSspdShealdVVt3->RegisterYourself();
- M = new TGeoCompositeShape("ITS SPD Thermal sheald volume",
- "(((ITSspdShealdVV+"
- "ITSspdShealdWingVV:ITSspdShealdVVt0)+"
- "ITSspdShealdWingVV:ITSspdShealdVVt1)+"
- "ITSspdShealdWingVV:ITSspdShealdVVt2)+"
- "ITSspdShealdWingVV:ITSspdShealdVVt3");
- //
- TGeoManager *mgr = gGeoManager;
- SPDcf = mgr->GetMedium("ITSspdCarbonFiber");
- SPDfs = mgr->GetMedium("ITSspdStaselite4411w");
- SPDfo = mgr->GetMedium("ITSspdRohacell50A");
- SPDss = mgr->GetMedium("ITSspdStainlessSteal");
- SPDair= mgr->GetMedium("ITSspdAir");
- TGeoVolume *A1v,*A2v,*A3v,*Ah1v,*Ah2v,*Ah3v;
- TGeoVolume *B1v,*B2v,*B3v,*Bh1v,*Bh2v,*Bh3v;
- TGeoVolume *C1v,*C2v,*C3v,*Ch1v,*Ch2v,*Ch3v;
- TGeoVolume *Dv,*Dsv,*Dwv,*Dwsv,*Mv;
- Mv = new TGeoVolume("ITSspdThermalSheald",M,SPDair);
- Mv->SetVisibility(kTRUE);
- Mv->SetLineColor(7); // light Blue
- Mv->SetLineWidth(1);
- Mv->SetFillColor(Mv->GetLineColor());
- Mv->SetFillStyle(4090); // 90% transparent
- Moth->AddNode(Mv,1,0); ///////////////////// Virtual Volume ////////
- A1v = new TGeoVolume("ITSspdCentCylA1CF",A1,SPDcf);
- A1v->SetVisibility(kTRUE);
- A1v->SetLineColor(4);
- A1v->SetLineWidth(1);
- A2v = new TGeoVolume("ITSspdCentCylA2CF",A2,SPDcf);
- A2v->SetVisibility(kTRUE);
- A2v->SetLineColor(4);
- A2v->SetLineWidth(1);
- A3v = new TGeoVolume("ITSspdCentCylA3CF",A3,SPDcf);
- A3v->SetVisibility(kTRUE);
- A3v->SetLineColor(4);
- A3v->SetLineWidth(1);
- B1v = new TGeoVolume("ITSspdCentCylB1CF",B1,SPDcf);
- B1v->SetVisibility(kTRUE);
- B1v->SetLineColor(4);
- B1v->SetLineWidth(1);
- B2v = new TGeoVolume("ITSspdCentCylB2CF",B2,SPDcf);
- B2v->SetVisibility(kTRUE);
- B2v->SetLineColor(4);
- B2v->SetLineWidth(1);
- B3v = new TGeoVolume("ITSspdCentCylB3CF",B3,SPDcf);
- B3v->SetVisibility(kTRUE);
- B3v->SetLineColor(4);
- B3v->SetLineWidth(1);
- C1v = new TGeoVolume("ITSspdCentCylC1CF",C1,SPDcf);
- C1v->SetVisibility(kTRUE);
- C1v->SetLineColor(4);
- C1v->SetLineWidth(1);
- C2v = new TGeoVolume("ITSspdCentCylC2CF",C2,SPDcf);
- C2v->SetVisibility(kTRUE);
- C2v->SetLineColor(4);
- C2v->SetLineWidth(1);
- C3v = new TGeoVolume("ITSspdCentCylC3CF",C3,SPDcf);
- C3v->SetVisibility(kTRUE);
- C3v->SetLineColor(4);
- C3v->SetLineWidth(1);
- Ah1v = new TGeoVolume("ITSspdCentCylA1AirA",Ah1,SPDair);
- Ah1v->SetVisibility(kTRUE);
- Ah1v->SetLineColor(5); // Yellow
- Ah1v->SetFillColor(Ah1v->GetLineColor());
- Ah1v->SetFillStyle(4090); // 90% transparent
- Ah2v = new TGeoVolume("ITSspdCentCylA2AirA",Ah2,SPDair);
- Ah2v->SetVisibility(kTRUE);
- Ah2v->SetLineColor(5); // Yellow
- Ah2v->SetFillColor(Ah2v->GetLineColor());
- Ah2v->SetFillStyle(4090); // 90% transparent
- Ah3v = new TGeoVolume("ITSspdCentCylA3AirA",Ah3,SPDair);
- Ah3v->SetVisibility(kTRUE);
- Ah3v->SetLineColor(5); // Yellow
- Ah3v->SetFillColor(Ah3v->GetLineColor());
- Ah3v->SetFillStyle(4090); // 90% transparent
- Bh1v = new TGeoVolume("ITSspdCentCylA1AirB",Bh1,SPDair);
- Bh1v->SetVisibility(kTRUE);
- Bh1v->SetLineColor(5); // Yellow
- Bh1v->SetFillColor(Bh1v->GetLineColor());
- Bh1v->SetFillStyle(4090); // 90% transparent
- Bh2v = new TGeoVolume("ITSspdCentCylA2AirB",Bh2,SPDair);
- Bh2v->SetVisibility(kTRUE);
- Bh2v->SetLineColor(5); // Yellow
- Bh2v->SetFillColor(Bh2v->GetLineColor());
- Bh2v->SetFillStyle(4090); // 90% transparent
- Bh3v = new TGeoVolume("ITSspdCentCylA3AirB",Bh3,SPDair);
- Bh3v->SetVisibility(kTRUE);
- Bh3v->SetLineColor(5); // Yellow
- Bh3v->SetFillColor(Bh3v->GetLineColor());
- Bh3v->SetFillStyle(4090); // 90% transparent
- Ch1v = new TGeoVolume("ITSspdCentCylA1AirC",Ch1,SPDair);
- Ch1v->SetVisibility(kTRUE);
- Ch1v->SetLineColor(5); // Yellow
- Ch1v->SetFillColor(Ch1v->GetLineColor());
- Ch1v->SetFillStyle(4090); // 90% transparent
- Ch2v = new TGeoVolume("ITSspdCentCylA2AirC",Ch2,SPDair);
- Ch2v->SetVisibility(kTRUE);
- Ch2v->SetLineColor(5); // Yellow
- Ch2v->SetFillColor(Ch2v->GetLineColor());
- Ch2v->SetFillStyle(4090); // 90% transparent
- Ch3v = new TGeoVolume("ITSspdCentCylA3AirC",Ch3,SPDair);
- Ch3v->SetVisibility(kTRUE);
- Ch3v->SetLineColor(5); // Yellow
- Ch3v->SetFillColor(Ch3v->GetLineColor());
- Ch3v->SetFillStyle(4090); // 90% transparent
- Dv = new TGeoVolume("ITSspdCentCylA1CD",D,SPDcf);
- Dv->SetVisibility(kTRUE);
- Dv->SetLineColor(4);
- Dv->SetLineWidth(1);
- Dwv = new TGeoVolume("ITSspdCentCylA1CDw",Dw,SPDcf);
- Dwv->SetVisibility(kTRUE);
- Dwv->SetLineColor(4);
- Dwv->SetLineWidth(1);
- Dsv = new TGeoVolume("ITSspdCentCylA1Dfill",Ds,SPDfs);
- Dsv->SetVisibility(kTRUE);
- Dsv->SetLineColor(3); // Green
- Dsv->SetFillColor(Dsv->GetLineColor());
- Dsv->SetFillStyle(4010); // 10% transparent
- Dwsv = new TGeoVolume("ITSspdCentCylA1DwingFill",Dws,SPDfs);
- Dwsv->SetVisibility(kTRUE);
- Dwsv->SetLineColor(3); // Green
- Dwsv->SetFillColor(Dwsv->GetLineColor());
- Dwsv->SetFillStyle(4010); // 10% transparent
- //
- A1v->AddNode(Ah1v,1,0);
- A2v->AddNode(Ah2v,1,0);
- A3v->AddNode(Ah3v,1,0);
- B1v->AddNode(Bh1v,1,0);
- B2v->AddNode(Bh2v,1,0);
- B3v->AddNode(Bh3v,1,0);
- C1v->AddNode(Ch1v,1,0);
- C2v->AddNode(Ch2v,1,0);
- C3v->AddNode(Ch3v,1,0);
- Dv ->AddNode(Dsv ,1,0);
- Dwv->AddNode(Dwsv,1,0);
- //
- Mv->AddNode(A1v,1,0);
- Mv->AddNode(A2v,1,0);
- Mv->AddNode(A3v,1,0);
- tranb = new TGeoTranslation("",0.0,0.0,0.5*(TSCLengthA+TSCLengthB));
- tranbm = new TGeoTranslation("",0.0,0.0,0.5*(-TSCLengthA-TSCLengthB));
- Mv->AddNode(B1v,1,tranb);
- Mv->AddNode(B2v,1,tranb);
- Mv->AddNode(B3v,1,tranb);
- Mv->AddNode(B1v,2,tranbm);
- Mv->AddNode(B2v,2,tranbm);
- Mv->AddNode(B3v,2,tranbm);
- // Muon side (rb26) is at -Z.
- tranc = new TGeoTranslation("",0.0,0.0,
- 0.5*(-TSCLengthA-TSCLengthB-TSCLengthC));
- Mv->AddNode(C1v,1,tranc);
- Mv->AddNode(C2v,1,tranc);
- Mv->AddNode(C3v,1,tranc);
- Mv->AddNode(Dv,1,tranITSspdShealdVVt0);
- Mv->AddNode(Dwv,1,tranITSspdShealdVVt0);
- Mv->AddNode(Dwv,2,rotITSspdShealdVVt1);
- Mv->AddNode(Dwv,3,rotITSspdShealdVVt2);
- Mv->AddNode(Dwv,4,rotITSspdShealdVVt3);
- k=2;
- for(i=1;i<10;i++) {
- th = ((Double_t)i)*TSCAngle*kDegree;
- rot = new TGeoRotation("",0.0,0.0,th);
- Mv->AddNode(A1v,i+1,rot);
- Mv->AddNode(B1v,i+2,new TGeoCombiTrans(*tranb,*rot));
- Mv->AddNode(B1v,i+12,new TGeoCombiTrans(*tranbm,*rot));
- Mv->AddNode(C1v,i+1,new TGeoCombiTrans(*tranc,*rot));
- if(i!=0||i!=2||i!=7){
- Mv->AddNode(A2v,k++,rot);
- Mv->AddNode(B2v,k++,new TGeoCombiTrans(*tranb,*rot));
- Mv->AddNode(B2v,k++,new TGeoCombiTrans(*tranbm,*rot));
- Mv->AddNode(C2v,k++,new TGeoCombiTrans(*tranc,*rot));
- } // end if
- if(i==5) {
- Mv->AddNode(A3v,2,rot);
- Mv->AddNode(B3v,3,new TGeoCombiTrans(*tranb,*rot));
- Mv->AddNode(B3v,4,new TGeoCombiTrans(*tranbm,*rot));
- Mv->AddNode(C3v,2,new TGeoCombiTrans(*tranc,*rot));
- } // end if
- } // end for i
- rot = new TGeoRotation("",180.,0.0,0.0);
- Mv->AddNode(A3v,3,rot);
- Mv->AddNode(B3v,5,new TGeoCombiTrans(*tranb,*rot));
- Mv->AddNode(B3v,6,new TGeoCombiTrans(*tranbm,*rot));
- Mv->AddNode(C3v,3,new TGeoCombiTrans(*tranc,*rot));
- rot = new TGeoRotation("",180.,0.0,180.0);
- Mv->AddNode(A3v,4,rot);
- Mv->AddNode(B3v,7,new TGeoCombiTrans(*tranb,*rot));
- Mv->AddNode(B3v,8,new TGeoCombiTrans(*tranbm,*rot));
- Mv->AddNode(C3v,4,new TGeoCombiTrans(*tranc,*rot));
- if(GetDebug()){
- A1v->PrintNodes();
- Ah1v->PrintNodes();
- A2v->PrintNodes();
- Ah2v->PrintNodes();
- A3v->PrintNodes();
- Ah3v->PrintNodes();
- B1v->PrintNodes();
- Bh1v->PrintNodes();
- B2v->PrintNodes();
- Bh2v->PrintNodes();
- B3v->PrintNodes();
- Bh3v->PrintNodes();
- C1v->PrintNodes();
- Ch1v->PrintNodes();
- C2v->PrintNodes();
- Ch2v->PrintNodes();
- C3v->PrintNodes();
- Ch3v->PrintNodes();
- Dv->PrintNodes();
- Dsv->PrintNodes();
- Dwv->PrintNodes();
- Dwsv->PrintNodes();
- //Mv->PrintNodes();
- } // end if
-}
-//______________________________________________________________________
-void AliITSv11::SDDCone(TGeoVolume *Moth){
- // Define the detail SDD support cone geometry.
- // Inputs:
- // none.
- // Outputs:
- // none.
- // Return:
- // none.
- //
- // From Cilindro Centrale - Lavorazioni, ALR 0816/1 04/08/03 File
- // name SDD/Cilindro.hpgl
- const Double_t TSLength = 790.0*kmm; // Thermal Sheeld length
- const Double_t TSInsertoLength= 15.0*kmm; // ????
- const Double_t TSOuterR = 0.5*(220.+10.)*kmm; // ????
- const Double_t TSInnerR = 0.5*(220.-10.)*kmm; // ????
- const Double_t TSCarbonFiberth= 0.02*kmm; // ????
- const Double_t TSBoltDiameter = 6.0*kmm; // M6 screw
- const Double_t TSBoltDepth = 6.0*kmm; // in volume C
- const Double_t TSBoltRadius = 0.5*220.*kmm; // Radius in volume C
- const Double_t TSBoltAngle0 = 0.0*kDegree; // Angle in volume C
- const Double_t TSBoltdAngle = 30.0*kDegree; // Angle in Volume C
- Double_t x,y,z,t,t0;
- Int_t i,n;
- TGeoTube *A,*B,*C,*D;
- TGeoTranslation *tran;
- TGeoRotation *rot;
- TGeoCombiTrans *rotran;
- TGeoMedium *SDDcf,*SDDfs,*SDDfo,*SDDss;
-
- A = new TGeoTube("ITS SDD Central Cylinder",TSInnerR,TSOuterR,.5*TSLength);
- B = new TGeoTube("ITS SDD CC Foam",TSInnerR+TSCarbonFiberth,
- TSOuterR-TSCarbonFiberth,
- 0.5*(TSLength-2.0*TSInsertoLength));
- C = new TGeoTube("ITS SDD CC Inserto",TSInnerR+TSCarbonFiberth,
- TSOuterR-TSCarbonFiberth,0.5*TSLength);
- D = new TGeoTube("ITS SDD CC M6 bolt end",0.0,0.5*TSBoltDiameter,
- 0.5*TSBoltDepth);
- printTube(A);
- printTube(B);
- printTube(C);
- printTube(D);
- //
- TGeoManager *mgr = gGeoManager;
- SDDcf = mgr->GetMedium("ITSssdCarbonFiber");
- SDDfs = mgr->GetMedium("ITSssdStaselite4411w");
- SDDfo = mgr->GetMedium("ITSssdRohacell50A");
- SDDss = mgr->GetMedium("ITSssdStainlessSteal");
- TGeoVolume *Av,*Bv,*Cv,*Dv;
- Av = new TGeoVolume("ITSsddCentCylCF",A,SDDcf);
- Av->SetVisibility(kTRUE);
- Av->SetLineColor(4);
- Av->SetLineWidth(1);
- Av->SetFillColor(Av->GetLineColor());
- Av->SetFillStyle(4000); // 0% transparent
- Bv = new TGeoVolume("ITSsddCentCylF",B,SDDfo);
- Bv->SetVisibility(kTRUE);
- Bv->SetLineColor(3);
- Bv->SetLineWidth(1);
- Bv->SetFillColor(Bv->GetLineColor());
- Bv->SetFillStyle(4000); // 0% transparent
- Cv = new TGeoVolume("ITSsddCentCylSt",C,SDDfs);
- Cv->SetVisibility(kTRUE);
- Cv->SetLineColor(2);
- Cv->SetLineWidth(1);
- Cv->SetFillColor(Cv->GetLineColor());
- Cv->SetFillStyle(4000); // 0% transparent
- Dv = new TGeoVolume("ITSsddCentCylSS",D,SDDss);
- Dv->SetVisibility(kTRUE);
- Dv->SetLineColor(1);
- Dv->SetLineWidth(1);
- Dv->SetFillColor(Dv->GetLineColor());
- Dv->SetFillStyle(4000); // 0% transparent
- //
- Moth->AddNode(Av,1,0);
- Av->AddNode(Cv,1,0);
- Cv->AddNode(Bv,1,0);
- n = (Int_t)((360.*kDegree)/TSBoltdAngle);
- for(i=0;i<n;i++){
- t = TSBoltAngle0+((Double_t)i)*TSBoltdAngle;
- x = TSBoltRadius*TMath::Cos(t*kRadian);
- y = TSBoltRadius*TMath::Sin(t*kRadian);
- z = 0.5*(TSLength-TSBoltDepth);
- tran = new TGeoTranslation("",x,y,z);
- Cv->AddNode(Dv,i+1,tran);
- tran = new TGeoTranslation("",x,y,-z);
- Cv->AddNode(Dv,i+n+1,tran);
- } // end for i
- if(GetDebug()){
- Av->PrintNodes();
- Bv->PrintNodes();
- Cv->PrintNodes();
- Dv->PrintNodes();
- } // end if
- // SDD Suport Cone
- //
- //
- const Double_t Thickness = 10.5*kmm; // Thickness of Rohacell+carbon fiber
- const Double_t Cthick = 1.5*kmm; // Carbon finber thickness
- const Double_t Rcurv = 15.0*kmm; // Radius of curvature.
- const Double_t Tc = 45.0; // angle of SSD cone [degrees].
- const Double_t Sintc = TMath::Sin(Tc*TMath::DegToRad());
- const Double_t Costc = TMath::Cos(Tc*TMath::DegToRad());
- const Double_t Tantc = TMath::Tan(Tc*TMath::DegToRad());
- const Double_t ZouterMilled = 23.0*kmm;
- const Double_t Zcylinder = 186.0*kmm;
- const Double_t Z0 = Zcylinder + 0.5*TSLength;
- //const Int_t Nspoaks = 12;
- //const Int_t Nmounts = 4;
- //const Double_t DmountAngle = 9.0; // degrees
- const Double_t RoutMax = 0.5*560.0*kmm;
- const Double_t RoutMin = 0.5*539.0*kmm;
- // Holes in cone for cables
- const Double_t PhiHole1 = 0.0*kDegree;
- const Double_t dPhiHole1 = 25.0*kDegree;
- const Double_t RholeMax1 = 0.5*528.*kmm;
- const Double_t RholeMin1 = 0.5*464.*kmm;
- const Double_t PhiHole2 = 0.0*kDegree;
- const Double_t dPhiHole2 = 50.0*kDegree;
- const Double_t RholeMax2 = 0.5*375.*kmm;
- const Double_t RholeMin2 = 0.5*280.*kmm;
- //
- //const Int_t NpostsOut = 6;
- //const Int_t NpostsIn = 3;
- //const Double_t Phi0PostOut = 0.0; // degree
- //const Double_t Phi0PostIn = 0.0; // degree
- //const Double_t dRpostOut = 16.0*kmm;
- //const Double_t dRpostIn = 16.0*kmm;
- //const Double_t ZpostMaxOut = 116.0*kmm;
- //const Double_t ZpostMaxIn = 190.0*kmm;
- const Double_t RinMax = 0.5*216*kmm;
- const Double_t RinCylinder = 0.5*231.0*kmm;
- //const Double_t RinHole = 0.5*220.0*kmm;
- const Double_t RinMin = 0.5*210.0*kmm;
- const Double_t dZin = 15.0*kmm; // ???
- //
- Double_t dza = Thickness/Sintc-(RoutMax-RoutMin)/Tantc;
- Double_t Z,Rmin,Rmax; // Temp variables.
- if(dza<=0){ // The number or order of the points are in error for a proper
- // call to pcons!
- Error("SDDcone","The definition of the points for a call to PCONS is"
- " in error. abort.");
- return;
- } // end if
- TGeoPcon *E = new TGeoPcon("ITSsddSuportConeCarbonFiberSurfaceE",
- 0.0,360.0,12);
- E->Z(0) = 0.0;
- E->Rmin(0) = RoutMin;
- E->Rmax(0) = RoutMax;
- E->Z(1) = ZouterMilled - dza;
- E->Rmin(1) = E->GetRmin(0);
- E->Rmax(1) = E->GetRmax(0);
- E->Z(2) = ZouterMilled;
- E->Rmax(2) = E->GetRmax(0);
- RadiusOfCurvature(Rcurv,0.,E->GetZ(1),E->GetRmin(1),Tc,Z,Rmin);
- E->Z(3) = Z;
- E->Rmin(3) = Rmin;
- E->Rmin(2) = RminFrom2Points(E,3,1,E->GetZ(2));
- RadiusOfCurvature(Rcurv,0.,E->GetZ(2),E->GetRmax(2),Tc,Z,Rmax);
- E->Z(4) = Z;
- E->Rmax(4) = Rmax;
- E->Rmin(4) = RminFromZpCone(E,Tc,E->GetZ(4),0.0);
- E->Rmax(3) = RmaxFrom2Points(E,4,2,E->GetZ(3));
- E->Rmin(7) = RinMin;
- E->Rmin(8) = RinMin;
- RadiusOfCurvature(Rcurv,90.0,0.0,RinMax,90.0-Tc,Z,Rmax);
- E->Rmax(8) = Rmax;
- E->Z(8) = ZFromRmaxpCone(E,Tc,E->GetRmax(8));
- E->Z(9) = Zcylinder;
- E->Rmin(9) = RinMin;
- E->Z(10) = E->GetZ(9);
- E->Rmin(10) = RinCylinder;
- E->Rmin(11) = RinCylinder;
- E->Rmax(11) = E->GetRmin(11);
- Rmin = E->GetRmin(8);
- RadiusOfCurvature(Rcurv,90.0-Tc,E->GetZ(8),E->GetRmax(8),90.0,Z,Rmax);
- Rmax = RinMax;
- E->Z(11) = Z+(E->GetZ(8)-Z)*(E->GetRmax(11)-Rmax)/(E->GetRmax(8)-Rmax);
- E->Rmax(9) = RmaxFrom2Points(E,11,8,E->GetZ(9));
- E->Rmax(10) = E->GetRmax(9);
- E->Z(6) = Z-dZin;
- E->Z(7) = E->GetZ(6);
- E->Rmax(6) = RmaxFromZpCone(E,Tc,E->GetZ(6));
- E->Rmax(7) = E->GetRmax(6);
- RadiusOfCurvature(Rcurv,90.,E->GetZ(6),0.0,90.0-Tc,Z,Rmin);
- E->Z(5) = Z;
- E->Rmin(5) = RminFromZpCone(E,Tc,Z);
- E->Rmax(5) = RmaxFromZpCone(E,Tc,Z);
- RadiusOfCurvature(Rcurv,90.-Tc,0.0,E->Rmin(5),90.0,Z,Rmin);
- E->Rmin(6) = Rmin;
- printPcon(E);
- // Inner Core, Inserto material
- TGeoPcon *F = new TGeoPcon("ITSsddSuportConeInsertoStesaliteF",0.,360.0,9);
- F->Z(0) = E->GetZ(0);
- F->Rmin(0) = E->GetRmin(0)+Cthick;
- F->Rmax(0) = E->GetRmax(0)-Cthick;
- F->Z(1) = E->GetZ(1);
- F->Rmin(1) = F->GetRmin(0);
- F->Rmax(1) = F->GetRmax(0);
- F->Z(2) = E->GetZ(2);
- F->Rmax(2) = F->GetRmax(1);
- RadiusOfCurvature(Rcurv-Cthick,0.,F->GetZ(1),F->GetRmax(1),Tc,Z,Rmin);
- F->Z(3) = Z;
- F->Rmin(3) = Rmin;
- F->Rmin(2) = RminFrom2Points(F,3,1,F->GetZ(2));
- RadiusOfCurvature(Rcurv+Cthick,0.,F->GetZ(2),F->GetRmax(2),Tc,Z,Rmax);
- F->Z(4) = Z;
- F->Rmax(4) = Rmax;
- F->Rmin(4) = RmaxFromZpCone(E,Tc,F->GetZ(4),-Cthick);
- F->Rmax(3) = RmaxFrom2Points(F,4,2,F->GetZ(3));
- F->Rmin(7) = E->GetRmin(7);
- F->Rmin(8) = E->GetRmin(8);
- F->Z(6) = E->GetZ(6)+Cthick;
- F->Rmin(6) = E->GetRmin(6);
- F->Z(7) = F->GetZ(6);
- F->Rmax(8) = E->GetRmax(8)-Cthick*Sintc;
- RadiusOfCurvature(Rcurv+Cthick,90.,F->GetZ(6),F->GetRmin(6),90.-Tc,Z,Rmin);
- F->Z(5) = Z;
- F->Rmin(5) = Rmin;
- F->Rmax(5) = RmaxFromZpCone(F,Tc,Z);
- F->Rmax(6) = RmaxFromZpCone(F,Tc,F->GetZ(6));
- F->Rmax(7) = F->GetRmax(6);
- F->Z(8) = ZFromRmaxpCone(F,Tc,F->GetRmax(8),-Cthick);
- printPcon(F);
- // Inner Core, Inserto material
- TGeoPcon *G = new TGeoPcon("ITSsddSuportConeFoamCoreG",0.0,360.0,4);
- RadiusOfCurvature(Rcurv+Cthick,0.0,F->GetZ(1),F->GetRmin(1),Tc,Z,Rmin);
- G->Z(0) = Z;
- G->Rmin(0) = Rmin;
- G->Rmax(0) = G->GetRmin(0);
- G->Z(1) = G->GetZ(0)+(Thickness-2.0*Cthick)/Sintc;;
- G->Rmin(1) = RminFromZpCone(F,Tc,G->GetZ(1));
- G->Rmax(1) = RmaxFromZpCone(F,Tc,G->GetZ(1));
- G->Z(2) = E->GetZ(5)-Cthick;
- G->Rmin(2) = RminFromZpCone(F,Tc,G->GetZ(2));
- G->Rmax(2) = RmaxFromZpCone(F,Tc,G->GetZ(2));
- G->Z(3) = F->GetZ(5)+(Thickness-2.0*Cthick)*Costc;
- G->Rmax(3) = RmaxFromZpCone(F,Tc,G->GetZ(3));
- G->Rmin(3) = G->GetRmax(3);
- printPcon(G);
- //
- TGeoPcon *H = new TGeoPcon("ITSsddSuportConeHoleH",PhiHole1,dPhiHole1,4);
- H->Rmin(0) = RholeMax1;
- H->Rmax(0) = H->GetRmin(0);
- H->Z(0) = ZFromRminpCone(E,Tc,H->GetRmin(0));
- H->Rmax(1) = H->GetRmax(0);
- H->Z(1) = ZFromRmaxpCone(E,Tc,H->GetRmax(1));
- H->Rmin(1) = RminFromZpCone(E,Tc,H->GetZ(1));
- H->Rmin(2) = RholeMin1;
- H->Z(2) = ZFromRminpCone(E,Tc,H->GetRmin(2));
- H->Rmax(2) = RmaxFromZpCone(E,Tc,H->GetZ(2));
- H->Rmin(3) = H->GetRmin(2);
- H->Rmax(3) = H->GetRmin(3);
- H->Z(3) = ZFromRminpCone(E,Tc,H->GetRmin(3));
- printPcon(H);
- //
- x = Cthick/(0.5*(RholeMax1+RholeMin1));
- t0 = PhiHole1 - x/kRadian;
- t = dPhiHole1 + 2.0*x/kRadian;
- TGeoPcon *I = new TGeoPcon("ITSsddSuportConeHoleI",t0,t,4);
- I->Rmin(0) = RholeMax1+Cthick;
- I->Rmax(0) = I->GetRmin(0);
- I->Z(0) = ZFromRminpCone(F,Tc,I->GetRmin(0));
- I->Rmax(1) = I->GetRmax(0);
- I->Z(1) = ZFromRmaxpCone(F,Tc,I->GetRmax(1));
- I->Rmin(1) = RminFromZpCone(F,Tc,I->GetZ(1));
- I->Rmin(2) = RholeMin1-Cthick;
- I->Z(2) = ZFromRminpCone(F,Tc,I->GetRmin(2));
- I->Rmax(2) = RmaxFromZpCone(F,Tc,I->GetZ(2));
- I->Rmin(3) = I->GetRmin(2);
- I->Rmax(3) = I->GetRmin(3);
- I->Z(3) = ZFromRmaxpCone(F,Tc,I->GetRmax(3));
- printPcon(I);
- //
- TGeoPcon *J = new TGeoPcon("ITSsddSuportConeHoleJ",PhiHole2,dPhiHole2,4);
- J->Rmin(0) = RholeMax2;
- J->Rmax(0) = J->GetRmin(0);
- J->Z(0) = ZFromRminpCone(E,Tc,J->GetRmin(0));
- J->Rmax(1) = J->GetRmax(0);
- J->Z(1) = ZFromRmaxpCone(E,Tc,J->GetRmax(1));
- J->Rmin(1) = RminFromZpCone(E,Tc,J->GetZ(1));
- J->Rmin(2) = RholeMin2;
- J->Z(2) = ZFromRminpCone(E,Tc,J->GetRmin(2));
- J->Rmax(2) = RmaxFromZpCone(E,Tc,J->GetZ(2));
- J->Rmin(3) = J->GetRmin(2);
- J->Rmax(3) = J->GetRmin(3);
- J->Z(3) = ZFromRmaxpCone(E,Tc,J->GetRmax(3));
- printPcon(J);
- //
- x = Cthick/(0.5*(RholeMax2+RholeMin2));
- t0 = PhiHole2 - x/kRadian;
- t = dPhiHole2 + 2.0*x/kRadian;
- TGeoPcon *K = new TGeoPcon("ITSsddSuportConeHoleK",t0,t,4);
- K->Rmin(0) = RholeMax2+Cthick;
- K->Rmax(0) = K->GetRmin(0);
- K->Z(0) = ZFromRminpCone(F,Tc,K->GetRmin(0));
- K->Rmax(1) = K->GetRmax(0);
- K->Z(1) = ZFromRmaxpCone(F,Tc,K->GetRmax(1));
- K->Rmin(1) = RminFromZpCone(F,Tc,K->GetZ(1));
- K->Rmin(2) = RholeMin2-Cthick;
- K->Z(2) = ZFromRminpCone(F,Tc,K->GetRmin(2));
- K->Rmax(2) = RmaxFromZpCone(F,Tc,K->GetZ(2));
- K->Rmin(3) = K->GetRmin(2);
- K->Rmax(3) = K->GetRmin(3);
- K->Z(3) = ZFromRmaxpCone(F,Tc,K->GetRmax(3));
- printPcon(K);
- //
- TGeoCompositeShape *L,*M,*N;
- rot = new TGeoRotation("ITSsddRotZ30",0.0,0.0,30.0);
- rot->RegisterYourself();
- rot = new TGeoRotation("ITSsddRotZ60",0.0,0.0,60.0);
- rot->RegisterYourself();
- rot = new TGeoRotation("ITSsddRotZ90",0.0,0.0,90.0);
- rot->RegisterYourself();
- rot = new TGeoRotation("ITSsddRotZ120",0.0,0.0,120.0);
- rot->RegisterYourself();
- rot = new TGeoRotation("ITSsddRotZ150",0.0,0.0,150.0);
- rot->RegisterYourself();
- rot = new TGeoRotation("ITSsddRotZ180",0.0,0.0,180.0);
- rot->RegisterYourself();
- rot = new TGeoRotation("ITSsddRotZ210",0.0,0.0,210.0);
- rot->RegisterYourself();
- rot = new TGeoRotation("ITSsddRotZ240",0.0,0.0,240.0);
- rot->RegisterYourself();
- rot = new TGeoRotation("ITSsddRotZ270",0.0,0.0,270.0);
- rot->RegisterYourself();
- rot = new TGeoRotation("ITSsddRotZ300",0.0,0.0,300.0);
- rot->RegisterYourself();
- rot = new TGeoRotation("ITSsddRotZ330",0.0,0.0,330.0);
- rot->RegisterYourself();
- L = new TGeoCompositeShape("ITS SDD Suport Cone","((((((((((((((((("
- "ITSsddSuportConeCarbonFiberSurfaceE -"
- "ITSsddSuportConeHoleH) -"
- "ITSsddSuportConeHoleH:ITSsddRotZ30) -"
- "ITSsddSuportConeHoleH:ITSsddRotZ60) -"
- "ITSsddSuportConeHoleH:ITSsddRotZ90) -"
- "ITSsddSuportConeHoleH:ITSsddRotZ120) -"
- "ITSsddSuportConeHoleH:ITSsddRotZ150) -"
- "ITSsddSuportConeHoleH:ITSsddRotZ180) -"
- "ITSsddSuportConeHoleH:ITSsddRotZ210) -"
- "ITSsddSuportConeHoleH:ITSsddRotZ240) -"
- "ITSsddSuportConeHoleH:ITSsddRotZ270) -"
- "ITSsddSuportConeHoleH:ITSsddRotZ300) -"
- "ITSsddSuportConeHoleH:ITSsddRotZ330) -"
- "ITSsddSuportConeHoleJ) -"
- "ITSsddSuportConeHoleJ:ITSsddRotZ60) -"
- "ITSsddSuportConeHoleJ:ITSsddRotZ120) -"
- "ITSsddSuportConeHoleJ:ITSsddRotZ180) -"
- "ITSsddSuportConeHoleJ:ITSsddRotZ240) -"
- "ITSsddSuportConeHoleJ:ITSsddRotZ300");
- M = new TGeoCompositeShape("ITS SDD Suport Cone Inserto Stesalite",
- "((((((((((((((((("
- "ITSsddSuportConeInsertoStesaliteF -"
- "ITSsddSuportConeHoleI) -"
- "ITSsddSuportConeHoleI:ITSsddRotZ30) -"
- "ITSsddSuportConeHoleI:ITSsddRotZ60) -"
- "ITSsddSuportConeHoleI:ITSsddRotZ90) -"
- "ITSsddSuportConeHoleI:ITSsddRotZ120) -"
- "ITSsddSuportConeHoleI:ITSsddRotZ150) -"
- "ITSsddSuportConeHoleI:ITSsddRotZ180) -"
- "ITSsddSuportConeHoleI:ITSsddRotZ210) -"
- "ITSsddSuportConeHoleI:ITSsddRotZ240) -"
- "ITSsddSuportConeHoleI:ITSsddRotZ270) -"
- "ITSsddSuportConeHoleI:ITSsddRotZ300) -"
- "ITSsddSuportConeHoleI:ITSsddRotZ330) -"
- "ITSsddSuportConeHoleK) -"
- "ITSsddSuportConeHoleK:ITSsddRotZ60) -"
- "ITSsddSuportConeHoleK:ITSsddRotZ120) -"
- "ITSsddSuportConeHoleK:ITSsddRotZ180) -"
- "ITSsddSuportConeHoleK:ITSsddRotZ240) -"
- "ITSsddSuportConeHoleK:ITSsddRotZ300");
- N = new TGeoCompositeShape("ITS SDD Suport Cone Foam Core",
- "((((((((((((((((("
- "ITSsddSuportConeFoamCoreG -"
- "ITSsddSuportConeHoleI) -"
- "ITSsddSuportConeHoleI:ITSsddRotZ30) -"
- "ITSsddSuportConeHoleI:ITSsddRotZ60) -"
- "ITSsddSuportConeHoleI:ITSsddRotZ90) -"
- "ITSsddSuportConeHoleI:ITSsddRotZ120) -"
- "ITSsddSuportConeHoleI:ITSsddRotZ150) -"
- "ITSsddSuportConeHoleI:ITSsddRotZ180) -"
- "ITSsddSuportConeHoleI:ITSsddRotZ210) -"
- "ITSsddSuportConeHoleI:ITSsddRotZ240) -"
- "ITSsddSuportConeHoleI:ITSsddRotZ270) -"
- "ITSsddSuportConeHoleI:ITSsddRotZ300) -"
- "ITSsddSuportConeHoleI:ITSsddRotZ330) -"
- "ITSsddSuportConeHoleK) -"
- "ITSsddSuportConeHoleK:ITSsddRotZ60) -"
- "ITSsddSuportConeHoleK:ITSsddRotZ120) -"
- "ITSsddSuportConeHoleK:ITSsddRotZ180) -"
- "ITSsddSuportConeHoleK:ITSsddRotZ240) -"
- "ITSsddSuportConeHoleK:ITSsddRotZ300");
- //++++++++++++++++++++++++++++++++++++++++++++++++++++++++++++++++++
- TGeoVolume *Lv,*Mv,*Nv;
- Lv = new TGeoVolume("ITSsddConeL",L,SDDcf);
- Lv->SetVisibility(kTRUE);
- Lv->SetLineColor(4);
- Lv->SetLineWidth(1);
- Lv->SetFillColor(Lv->GetLineColor());
- Lv->SetFillStyle(4000); // 0% transparent
- Mv = new TGeoVolume("ITSsddConeM",M,SDDfs);
- Mv->SetVisibility(kTRUE);
- Mv->SetLineColor(2);
- Mv->SetLineWidth(1);
- Mv->SetFillColor(Mv->GetLineColor());
- Mv->SetFillStyle(4010); // 10% transparent
- Nv = new TGeoVolume("ITSsddConeN",N,SDDfo);
- Nv->SetVisibility(kTRUE);
- Nv->SetLineColor(7);
- Nv->SetLineWidth(1);
- Nv->SetFillColor(Nv->GetLineColor());
- Nv->SetFillStyle(4050); // 50% transparent
- //
- Mv->AddNode(Nv,1,0);
- Lv->AddNode(Mv,1,0);
- tran = new TGeoTranslation("",0.0,0.0,-Z0);
- Moth->AddNode(Lv,1,tran);
- rot = new TGeoRotation("",0.0,180.0*kDegree,0.0);
- rotran = new TGeoCombiTrans("",0.0,0.0,Z0,rot);
- delete rot;// rot not explicity used in AddNode functions.
- Moth->AddNode(Lv,2,rotran);
- if(GetDebug()){
- Lv->PrintNodes();
- Mv->PrintNodes();
- Nv->PrintNodes();
- } // end if
-}
-//______________________________________________________________________
-void AliITSv11::SSDCone(TGeoVolume *Moth){
- // Define the detail SSD support cone geometry.
- // Inputs:
- // none.
- // Outputs:
- // none.
- // Return:
- // none.
- //
- TGeoMedium *SSDcf = 0; // SSD support cone Carbon Fiber materal number.
- TGeoMedium *SSDfs = 0; // SSD support cone inserto stesalite 4411w.
- TGeoMedium *SSDfo = 0; // SSD support cone foam, Rohacell 50A.
- TGeoMedium *SSDss = 0; // SSD support cone screw material,Stainless steal
- TGeoMedium *SSDair = 0; // SSD support cone Air
- TGeoMedium *SSDal = 0; // SSD support cone SDD mounting bracket Al
- TGeoManager *mgr = gGeoManager;
- SSDcf = mgr->GetMedium("ITSssdCarbonFiber");
- SSDfs = mgr->GetMedium("ITSssdStaselite4411w");
- SSDfo = mgr->GetMedium("ITSssdRohacell50A");
- SSDss = mgr->GetMedium("ITSssdStainlessSteal");
- SSDair= mgr->GetMedium("ITSssdAir");
- SSDal = mgr->GetMedium("ITSssdAl");
- //
- // SSD Central cylinder/Thermal Sheald.
- const Double_t ZThCylinder = 1140.0*kmm; //
- const Double_t ZThCylFoam = 1020.0*kmm; //
- const Double_t RThCylOuter = 0.5*595.0*kmm; //
- const Double_t CthickThCyl = 0.64*kmm; //
- const Double_t FoamThickTh = 5.0*kmm; //
- const Double_t dZThCylThEnd = 6.0*kmm; //
- const Double_t RThCylInerEnd= 0.5*560.5*kmm; //
- TGeoPcon *CA,*CB;
- TGeoTube*CC;
- //
- CA = new TGeoPcon("ITS SSD Thermal Centeral CylinderA",0.0,360.0,6);
- CB = new TGeoPcon("ITS SSD Thermal Centeral CylinderB",0.0,360.0,6);
- CC = new TGeoTube("ITS SSD Thermal Centeral CylinderC",
- RThCylOuter-CthickThCyl-FoamThickTh,
- RThCylOuter-CthickThCyl,0.5*ZThCylFoam);
- CA->Z(0) = -0.5*ZThCylinder;
- CA->Rmin(0) = RThCylInerEnd;
- CA->Rmax(0) = RThCylOuter;
- CA->Z(1) = CA->GetZ(0) + dZThCylThEnd;
- CA->Rmin(1) = CA->GetRmin(0);
- CA->Rmax(1) = CA->GetRmax(0);
- CA->Z(2) = -0.5*ZThCylFoam;
- CA->Rmin(2) = RThCylOuter - 2.0*CthickThCyl-FoamThickTh;
- CA->Rmax(2) = CA->GetRmax(0);
- CA->Z(3) = -CA->GetZ(2);
- CA->Rmin(3) = CA->GetRmin(2);
- CA->Rmax(3) = CA->GetRmax(2);
- CA->Z(4) = -CA->GetZ(1);
- CA->Rmin(4) = CA->GetRmin(1);
- CA->Rmax(4) = CA->GetRmax(1);
- CA->Z(5) = -CA->GetZ(0);
- CA->Rmin(5) = CA->GetRmin(0);
- CA->Rmax(5) = CA->GetRmax(0);
- //
- CB->Z(0) = CA->GetZ(0);
- CB->Rmin(0) = CA->GetRmin(0) + CthickThCyl;
- CB->Rmax(0) = CA->GetRmax(0) - CthickThCyl;
- CB->Z(1) = CA->GetZ(1);
- CB->Rmin(1) = CA->GetRmin(1) + CthickThCyl;
- CB->Rmax(1) = CA->GetRmax(1) - CthickThCyl;
- CB->Z(2) = CA->GetZ(2);
- CB->Rmin(2) = CA->GetRmin(2) + CthickThCyl;
- CB->Rmax(2) = CA->GetRmax(2) - CthickThCyl;
- CB->Z(3) = CA->GetZ(3);
- CB->Rmin(3) = CA->GetRmin(3) + CthickThCyl;
- CB->Rmax(3) = CA->GetRmax(3) - CthickThCyl;
- CB->Z(4) = CA->GetZ(4);
- CB->Rmin(4) = CA->GetRmin(4) + CthickThCyl;
- CB->Rmax(4) = CA->GetRmax(4) - CthickThCyl;
- CB->Z(5) = CA->GetZ(5);
- CB->Rmin(5) = CA->GetRmin(5) + CthickThCyl;
- CB->Rmax(5) = CA->GetRmax(5) - CthickThCyl;
- //
- printPcon(CA);
- printPcon(CB);
- printTube(CC);
- TGeoVolume *CAv,*CBv,*CCv;
- CAv = new TGeoVolume("ITSssdCentCylCA",CA,SSDcf);
- CAv->SetVisibility(kTRUE);
- CAv->SetLineColor(4); // blue
- CAv->SetLineWidth(1);
- CAv->SetFillColor(CAv->GetLineColor());
- CAv->SetFillStyle(4010); // 10% transparent
- CBv = new TGeoVolume("ITSssdCentCylCB",CB,SSDfs);
- CBv->SetVisibility(kTRUE);
- CBv->SetLineColor(2); // red
- CBv->SetLineWidth(1);
- CBv->SetFillColor(CBv->GetLineColor());
- CBv->SetFillStyle(4010); // 10% transparent
- CCv = new TGeoVolume("ITSssdCentCylCC",CC,SSDfo);
- CCv->SetVisibility(kTRUE);
- CCv->SetLineColor(3); // green
- CCv->SetLineWidth(1);
- CCv->SetFillColor(CCv->GetLineColor());
- CCv->SetFillStyle(4010); // 10% transparent
- CBv->AddNode(CCv,1,0);
- CAv->AddNode(CBv,1,0);
- Moth->AddNode(CAv,1,0);
- if(GetDebug()){
- CAv->PrintNodes();
- CBv->PrintNodes();
- CCv->PrintNodes();
- } // end if
- //
- const Double_t Thickness = 13.0*kmm; // Thickness of Rohacell+carbon fiber
- const Double_t Cthick = 1.5*kmm; // Carbon finber thickness
- const Double_t Rcurv = 15.0*kmm; // Radius of curvature.
- const Double_t Tc = 51.0; // angle of SSD cone [degrees].
- const Double_t Sintc = TMath::Sin(Tc*TMath::DegToRad());
- const Double_t Costc = TMath::Cos(Tc*TMath::DegToRad());
- const Double_t Tantc = TMath::Tan(Tc*TMath::DegToRad());
- const Double_t ZouterMilled = (13.5-5.0)*kmm;
- const Double_t Zcylinder = 170.0*kmm;
- const Double_t Z0 = Zcylinder + 0.5*ZThCylinder;
- const Int_t Nspoaks = 12;
- const Int_t Nmounts = 4;
- const Double_t DmountAngle = 9.0; // degrees
- const Double_t RoutMax = 0.5*985.0*kmm;
- const Double_t RoutHole = 0.5*965.0*kmm;
- const Double_t RoutMin = 0.5*945.0*kmm;
- const Double_t RholeMax = 0.5*890.0*kmm;
- const Double_t RholeMin = 0.5*740.0*kmm;
- const Double_t RpostMin = 316.0*kmm;
- const Double_t ZpostMax = 196.0*kmm;
- const Int_t Nposts = 6;
- const Double_t Phi0Post = 0.0; // degree
- const Double_t dRpost = 23.0*kmm;
- const Double_t RinMax = 0.5*590.0*kmm;
- const Double_t RinCylinder = 0.5*597.0*kmm;
- const Double_t RinHole = 0.5*575.0*kmm;
- const Double_t RinMin = 0.5*562.0*kmm;
- const Double_t dZin = 15.0*kmm;
- // SSD-SDD Thermal/Mechanical cylinder mounts
- const Int_t NinScrews = 40;
- const Double_t Phi0Screws = 0.5*360.0/((const Double_t)NinScrews);//d
- const Double_t RcylinderScrews = 0.5*570.0*kmm;//from older drawing????
- const Double_t DscrewHead = 8.0*kmm;
- const Double_t DscrewShaft = 4.6*kmm;
- const Double_t ThScrewHeadHole = 8.5*kmm;
- // SDD mounting bracket, SSD part
- const Double_t NssdSupports = 3;// mounting of U and T
- const Double_t DssdsddBracketAngle = 9.0; // degrees
- const Double_t Phi0SDDsupports = 0.0; // degree
- const Double_t RsddSupportPlate = 0.5*585.0*kmm;
- const Double_t ThSDDsupportPlate = 4.0*kmm;
- const Double_t WsddSupportPlate = 70.0*kmm;
- //
- // Lets start with the upper left outer carbon fiber surface.
- // Between za[2],rmaxa[2] and za[4],rmaxa[4] there is a curved section
- // given by rmaxa = rmaxa[2]-r*Sind(t) for 0<=t<=Tc and
- // za = za[2] + r*Cosd(t) for 0<=t<=Tc. Simularly between za[1],rmina[1
- // and za[3],rmina[3] there is a curve section given by
- // rmina = rmina[1]-r*Sind(t) for 0<=t<=Tc and za = za[1]+r&Sind(t)
- // for t<=0<=Tc. These curves have been replaced by straight lines
- // between the equivelent points for simplicity.
- Double_t dza = Thickness/Sintc-(RoutMax-RoutMin)/Tantc;
- Int_t i,j;
- Double_t x,y,z[9],rn[9],rx[9],phi,dphi;
- Double_t t,t0,Z,Rmin,Rmax; // Temp variables.
- if(dza<=0){ // The number or order of the points are in error for a proper
- // call to pcons!
- Error("SSDcone","The definition of the points for a call to PCONS is"
- " in error. abort.");
- return;
- } // end if
- // Poly-cone Volume A. Top part of SSD cone Carbon Fiber.
- phi = 0.0;
- dphi = 360.0;
- z[0] = 0.0;
- rn[0] = RoutMin;
- rx[0] = RoutMax;
- z[1] = z[0]+ZouterMilled - dza; // za[2] - dza.
- rn[1] = rn[0];
- rx[1] = rx[0];
- z[2] = z[0]+ZouterMilled;//From Drawing ALR-0767 and ALR-0767/3
- rx[2] = rx[0];
- RadiusOfCurvature(Rcurv,0.,z[1],rn[1],Tc,z[3],rn[3]);
- rn[2] = RFrom2Points(rn,z,3,1,z[2]);
- RadiusOfCurvature(Rcurv,0.,z[2],rx[2],Tc,z[4],rx[4]);
- rn[4] = RminFromZpCone(rn,z,Tc,z[4]);
- rx[3] = RFrom2Points(rx,z,4,2,z[3]);
- rn[5] = RholeMax;
- z[5] = Zfrom2Points(z,rn,4,3,rn[5]);
- rx[5] = RmaxFromZpCone(rx,z,Tc,z[5]);
- rn[6] = RholeMax;
- rx[6] = rn[6];
- z[6] = ZFromRmaxpCone(rx,z,Tc,rx[6]);
- TGeoPcon *A = new TGeoPcon("ITS SSD Suport cone Carbon Fiber "
- "Surface outer left",phi,dphi,7);
- for(i=0;i<A->GetNz();i++){
- A->DefineSection(i,z[i],rn[i],rx[i]);
- } // end for i
- printPcon(A);
- //
- // Poly-cone Volume B. Stesalite inside volume A.
- // Now lets define the Inserto Stesalite 4411w material volume.
- phi = 0.0;
- dphi = 360.0;
- z[0] = A->GetZ(0);
- rn[0] = A->GetRmin(0)+Cthick;
- rx[0] = A->GetRmax(0)-Cthick;
- z[1] = A->GetZ(1);
- rn[1] = rn[0];
- rx[1] = rx[0];
- z[2] = A->GetZ(2);
- rx[2] = rx[1];
- RadiusOfCurvature(Rcurv-Cthick,0.,z[2],rx[2],Tc,z[3],rx[3]);
- RadiusOfCurvature(Rcurv+Cthick,0.,z[1],rn[1],Tc,z[4],rn[4]);
- rn[2] = RFrom2Points(rn,z,4,1,z[2]);
- rn[3] = RFrom2Points(rn,z,4,1,z[3]);
- z[5] = z[4]+(Thickness-2.0*Cthick)/Sintc;
- rn[5] = RmaxFromZpCone(A,Tc,z[5],-Cthick);
- rx[5] = rn[5];
- rx[4] = RFrom2Points(rx,z,5,3,z[4]);
- TGeoPcon *B = new TGeoPcon("ITS SSD Suport cone Inserto Stesalite "
- "left edge",phi,dphi,6);
- for(i=0;i<B->GetNz();i++){
- B->DefineSection(i,z[i],rn[i],rx[i]);
- } // end for i
- printPcon(B);
- //
- // Poly-cone Volume C. Foam inside volume A.
- // Now lets define the Rohacell foam material volume.
- phi = 0.0;
- dphi = 360.0;
- z[0] = B->GetZ(4);
- rn[0] = B->GetRmin(4);
- rx[0] = rn[0];
- z[1] = B->GetZ(5);
- rx[1] = B->GetRmin(5);
- rn[2] = A->GetRmin(5)+Cthick;//space for carbon fiber covering hole
- z[2] = ZFromRminpCone(A,Tc,rn[2],+Cthick);
- rn[1] = RFrom2Points(rn,z,2,0,z[1]);
- rx[3] = A->GetRmin(6)+Cthick;
- rn[3] = rx[3];
- z[3] = ZFromRmaxpCone(A,Tc,rx[3],-Cthick);
- rx[2] = RFrom2Points(rx,z,3,1,z[2]);
- TGeoPcon *C = new TGeoPcon("ITS SSD Suport cone Rohacell foam "
- "left edge",phi,dphi,4);
- for(i=0;i<C->GetNz();i++){
- C->DefineSection(i,z[i],rn[i],rx[i]);
- } // end for i
- printPcon(C);
- //
- // In volume SCB, th Inserto Stesalite 4411w material volume, there
- // are a number of Stainless steel screw and pin studs which will be
- // filled with screws/studs.
- rn[0] = 0.0*kmm,rx[0] = 6.0*kmm,z[0] = 0.5*10.0*kmm; // mm
- TGeoTube *D = new TGeoTube("ITS Screw+stud used to mount things to "
- "the SSD support cone",rn[0],rx[0],z[0]);
- printTube(D);
- rn[0] = 0.0*kmm;rx[0] = 6.0*kmm;z[0] = 0.5*12.0*kmm; // mm
- TGeoTube *E = new TGeoTube("ITS pin used to mount things to the "
- "SSD support cone",rn[0],rx[0],z[0]);
- printTube(E);
- //
- // Poly-cone Volume F. Foam in spoak reagion, inside volume A.
- // There is no carbon fiber between this upper left section and the
- // SSD spoaks. We remove it by replacing it with Rohacell foam.
- t = Cthick/(0.5*(RholeMax+RholeMin));// It is not posible to get
- // the carbon fiber thickness uniform in this phi direction. We can only
- // make it a fixed angular thickness.
- t *= 180.0/TMath::Pi();
- phi = 12.5+t; // degrees see drawing ALR-0767.
- dphi = 5.0 - 2.0*t; // degrees
- z[0] = C->GetZ(2);
- rn[0] = C->GetRmin(3);
- rx[0] = rn[0];
- rn[1] = A->GetRmin(5);
- rx[1] = rn[0];
- z[1] = ZFromRminpCone(A,Tc,rn[1],+Cthick);
- z[2] = C->GetZ(3);
- rn[2] = rn[1];
- rx[2] = rx[1];
- rn[3] = A->GetRmin(6);
- rx[3] = rn[3];
- z[3] = ZFromRmaxpCone(A,Tc,rx[3],-Cthick);
- TGeoPcon *F = new TGeoPcon("ITS SSD Top Suport cone Rohacell foam "
- "Spoak",phi,dphi,4);
- for(i=0;i<F->GetNz();i++){
- F->DefineSection(i,z[i],rn[i],rx[i]);
- } // end for i
- printPcon(F);
- //=================================================================
- // Poly-cone Volume G.
- // Now for the spoak part of the SSD cone.
- // It is not posible to inclue the radius of curvature between
- // the spoak part and the upper left part of the SSD cone or lowwer right
- // part. This would be discribed by the following curves.
- // R = Rmax - (5mm)*Sin(t) phi = phi0+(5mm*180/(Pi*RoutHole))*Sin(t)
- // where 0<=t<=90 For the inner curve a simular equiation holds.
- phi = 12.5; // degrees see drawing ALR-0767.
- dphi = 5.0; // degrees
- z[0] = A->GetZ(5);
- rn[0] = A->GetRmin(5);
- rx[0] = rn[0];
- z[1] = A->GetZ(6);
- rn[1] = RminFromZpCone(A,Tc,z[1]);
- rx[1] = rx[0];
- rn[2] = RholeMin;
- z[2] = ZFromRminpCone(A,Tc,rn[2]);
- rx[2] = RmaxFromZpCone(A,Tc,z[2]);
- rn[3] = rn[2];
- rx[3] = rn[3];
- z[3] = ZFromRmaxpCone(A,Tc,rx[3]);
- TGeoPcon *G = new TGeoPcon("ITS SSD spoak carbon fiber surfaces",
- phi,dphi,4);
- for(i=0;i<G->GetNz();i++){
- G->DefineSection(i,z[i],rn[i],rx[i]);
- } // end for i
- printPcon(G);
- // For the foam core.
- // Poly-cone Volume H.
- t = Cthick/(0.5*(RholeMax+RholeMin));// It is not posible to get the
- // carbon fiber thickness uniform in this phi direction. We can only
- // make it a fixed angular thickness.
- t *= 180.0/TMath::Pi();
- phi = 12.5+t; // degrees
- dphi = 5.0 - 2.0*t; // degrees see drawing ALR-0767.
- z[0] = F->GetZ(1);
- rn[0] = G->GetRmin(0);
- rx[0] = rn[0];
- z[1] = F->GetZ(3);
- rn[1] = RminFromZpCone(A,Tc,z[1],+Cthick);
- rx[1] = rx[0];
- z[2] = ZFromRminpCone(A,Tc,G->GetRmin(2),+Cthick);
- rn[2] = G->GetRmin(2);
- rx[2] = RmaxFromZpCone(A,Tc,z[2],-Cthick);
- z[3] = ZFromRmaxpCone(A,Tc,G->GetRmin(3),-Cthick);
- rn[3] = G->GetRmin(3);
- rx[3] = rn[3];
- TGeoPcon *H = new TGeoPcon("ITS SSD support cone Rohacell foam Spoak",
- phi,dphi,4);
- for(i=0;i<H->GetNz();i++){
- H->DefineSection(i,z[i],rn[i],rx[i]);
- } // end for i
- printPcon(H);
- //
- //==================================================================
- // Now for the Inner most part of the SSD cone.
- //Poly-cone Volume I.
- phi = 0.0;
- dphi = 360.0;
- z[0] = G->GetZ(2);
- rn[0] = G->GetRmin(2);
- rx[0] = rn[0];
- z[1] = G->GetZ(3);
- rn[1] = RminFromZpCone(A,Tc,z[1]);
- rx[1] = rx[0];
- rn[4] = RinMin;
- rn[5] = RinMin;
- RadiusOfCurvature(Rcurv,90.0,0.0,RinMax,90.0-Tc,Z,rx[5]); // z dummy
- z[5] = ZFromRmaxpCone(A,Tc,rx[5]);
- z[6] = Zcylinder;
- rn[6] = RinMin;
- z[7] = z[6];
- rn[7] = RinCylinder;
- rn[8] = RinCylinder;
- rx[8] = rn[8];
- Rmin = rn[5];
- RadiusOfCurvature(Rcurv,90.0-Tc,z[5],rx[5],90.0,Z,Rmax);
- Rmax = RinMax;
- z[8] = Z+(z[5]-Z)*(rx[8]-Rmax)/(rx[5]-Rmax);
- rx[6] = RFrom2Points(rx,z,8,5,z[6]);
- rx[7] = rx[6];
- z[3] = Z-dZin;
- z[4] = z[3];
- rx[3] = RmaxFromZpCone(A,Tc,z[3]);
- rx[4] = rx[3];
- //rmin dummy
- RadiusOfCurvature(Rcurv,90.,z[3],0.,90.-Tc,z[2],Rmin);
- rn[2] = RminFromZpCone(A,Tc,z[2]);
- rx[2] = RmaxFromZpCone(A,Tc,z[2]);
- // z dummy
- RadiusOfCurvature(Rcurv,90.-Tc,0.0,rn[2],90.0,Z,rn[3]);
- TGeoPcon *I = new TGeoPcon("ITS SSD lower/inner right part of SSD "
- "cone",phi,dphi,9);
- for(i=0;i<I->GetNz();i++){
- I->DefineSection(i,z[i],rn[i],rx[i]);
- } // end for i
- printPcon(I);
- // Now for Inserto volume at the inner most radius.
- // Poly-cone Volume K.
- phi = 0.0;
- dphi = 360.0;
- z[1] = I->GetZ(3)+Cthick;
- rn[1] = I->GetRmin(3);
- z[2] = z[1];
- rn[2] = I->GetRmin(4);
- rn[3] = rn[2];
- rn[4] = rn[2];
- rx[4] = I->GetRmax(5)-Cthick*Sintc;
- RadiusOfCurvature(Rcurv+Cthick,90.0,z[1],rn[1],90.0-Tc,z[0],rn[0]);
- rx[0] = rn[0];
- z[3] = z[0]+(Thickness-2.0*Cthick)*Costc;;
- rx[3] = rx[0]+(Thickness-2.0*Cthick)*Sintc;
- rx[1] = RFrom2Points(rx,z,3,0,z[1]);
- rx[2] = rx[1];
- z[4] = ZFromRmaxpCone(A,Tc,rx[4],-Cthick);
- rn[5] = rn[2];
- z[5] = I->GetZ(6);
- rx[5] = (I->GetRmax(5)-I->GetRmax(8))/(I->GetZ(5)-I->GetZ(8))*(z[5]-z[4])+
- rx[4];
- TGeoPcon *K = new TGeoPcon("ITS SSD inner most inserto material",
- phi,dphi,6);
- for(i=0;i<K->GetNz();i++){
- K->DefineSection(i,z[i],rn[i],rx[i]);
- } // end for i
- printPcon(K);
- // Now for foam core at the inner most radius.
- // Poly-cone Volume J.
- phi = 0.0;
- dphi = 360.0;
- rn[0] = I->GetRmin(0)-Cthick;
- z[0] = ZFromRminpCone(A,Tc,rn[0],+Cthick);
- rx[0] = rn[0];
- rx[1] = rx[0];
- z[1] = ZFromRmaxpCone(A,Tc,rx[1],-Cthick);
- rn[1] = RminFromZpCone(A,Tc,z[1],+Cthick);
- z[2] = K->GetZ(0);
- rn[2] = K->GetRmin(0);
- rx[2] = RmaxFromZpCone(A,Tc,z[2],-Cthick);
- z[3] = K->GetZ(3);
- rn[3] = K->GetRmax(3);
- rx[3] = rn[3];
- TGeoPcon *J = new TGeoPcon("ITS SSD inner most foam core",phi,dphi,4);
- for(i=0;i<J->GetNz();i++){
- J->DefineSection(i,z[i],rn[i],rx[i]);
- } // end for i
- printPcon(J);
- // Now for foam core at the top of the inner most radius where
- // the spoaks are.
- t = Cthick/(0.5*(RholeMax+RholeMin));// It is not posible to get the
- // carbon fiber thickness uniform in this phi direction. We can only
- // make it a fixed angular thickness.
- // Poly-cone Volume L.
- t *= 180.0/TMath::Pi();
- phi = 12.5+t; // degrees
- dphi = 5.0 - 2.0*t; // degrees see drawing ALR-0767.
- z[0] = H->GetZ(2);
- rn[0] = H->GetRmin(2);
- rx[0] = rn[0];
- z[1] = J->GetZ(0);
- rn[1] = J->GetRmin(0);
- rx[1] = I->GetRmax(1);
- z[2] = H->GetZ(3);
- rn[2] = rn[1];
- rx[2] = rx[1];
- z[3] = J->GetZ(1);
- rn[3] = rn[2];
- rx[3] = rn[3];
- TGeoPcon *L = new TGeoPcon("ITS SSD Bottom cone Rohacell foam Spoak",
- phi,dphi,4);
- for(i=0;i<L->GetNz();i++){
- L->DefineSection(i,z[i],rn[i],rx[i]);
- } // end for i
- printPcon(L);
- // Now for the SSD mounting posts
- // Poly-cone Volume O.
- dphi = 180.0*dRpost/(RpostMin+0.5*dRpost)/TMath::Pi(); //
- phi = Phi0Post-0.5*dphi; // degrees
- rn[0] = RpostMin+dRpost;
- rx[0] = rn[0];
- z[0] = ZFromRmaxpCone(A,Tc,rx[0]);
- rn[1] = RpostMin;
- z[1] = ZFromRmaxpCone(A,Tc,rn[1]);
- rx[1] = rx[0];
- z[2] = ZpostMax;
- rn[2] = RpostMin;
- rx[2] = rn[2]+dRpost;
- TGeoPcon *O = new TGeoPcon("ITS SSD mounting post, carbon fiber",
- phi,dphi,3);
- for(i=0;i<O->GetNz();i++){
- O->DefineSection(i,z[i],rn[i],rx[i]);
- } // end for i
- printPcon(O);
- // Now for the SSD mounting posts
- // Poly-cone Volume P.
- t = 180.0*Cthick/(RpostMin+0.5*dRpost)/TMath::Pi();
- dphi = O->GetDphi()-2.0*t; // degrees
- phi = O->GetPhi1()+t; //
- rn[0] = O->GetRmin(0)-Cthick;
- rx[0] = rn[0];
- z[0] = ZFromRmaxpCone(A,Tc,rx[0]);
- rn[1] = O->GetRmin(1)+Cthick;
- rx[1] = O->GetRmin(0)-Cthick;
- z[1] = ZFromRmaxpCone(A,Tc,rn[1]);
- rn[2] = rn[1];
- rx[2] = rx[1];
- z[2] = ZpostMax;
- TGeoPcon *P = new TGeoPcon("ITS SSD mounting post, Inserto",
- phi,dphi,3);
- for(i=0;i<P->GetNz();i++){
- P->DefineSection(i,z[i],rn[i],rx[i]);
- } // end for i
- printPcon(P);
- // This insrto continues into the SSD cone displacing the foam
- // and the carbon fiber surface at those points where the posts are.
- //Poly-cone Vol. M
- phi = P->GetPhi1();
- dphi = P->GetDphi();
- rn[0] = RpostMin+dRpost-Cthick;
- rx[0] = rn[0];
- z[0] = ZFromRminpCone(A,Tc,rn[0],+Cthick);
- rx[1] = rx[0];
- z[1] = ZFromRmaxpCone(A,Tc,rx[1],-Cthick);
- rn[1] = RminFromZpCone(A,Tc,z[1],+Cthick);
- rn[2] = RpostMin+Cthick;
- z[2] = ZFromRminpCone(A,Tc,rn[2],+Cthick);
- rx[2] = RmaxFromZpCone(A,Tc,z[2],-Cthick);
- rn[3] = rn[2];
- rx[3] = rn[3];
- z[3] = ZFromRmaxpCone(A,Tc,rx[3],-Cthick);
- TGeoPcon *M = new TGeoPcon("ITS SSD mounting post foam substitute, "
- "Inserto",phi,dphi,4);
- for(i=0;i<M->GetNz();i++){
- M->DefineSection(i,z[i],rn[i],rx[i]);
- } // end for i
- printPcon(M);
- //
- //Poly-cone Vol. N
- phi = P->GetPhi1();
- dphi = P->GetDphi();
- z[0] = M->GetZ(1);
- rn[0] = M->GetRmax(1);
- rx[0] = rn[0];
- rx[1] = rx[0];
- z[1] = ZFromRmaxpCone(A,Tc,rx[1]);
- rn[1] = RmaxFromZpCone(A,Tc,z[1],-Cthick);
- z[2] = M->GetZ(3);
- rn[2] = M->GetRmin(3);
- rx[2] = RmaxFromZpCone(A,Tc,z[2]);
- rn[3] = rn[2];
- rx[3] = rn[3];
- z[3] = ZFromRmaxpCone(A,Tc,rx[3]);
- TGeoPcon *N = new TGeoPcon("ITS SSD mounting post CF subsititute, "
- "Inserto",phi,dphi,4);
- for(i=0;i<N->GetNz();i++){
- N->DefineSection(i,z[i],rn[i],rx[i]);
- } // end for i
- printPcon(N);
- // Bolt heads holding the SSD-SDD tube to the SSD cone.
- // Bolt -- PolyCone
- //Poly-cone Volume Q.
- phi = 0.0;
- dphi = 360.0;
- z[0] = I->GetZ(4)+ThSDDsupportPlate;
- rn[0] = 0.0;
- rx[0] = 0.5*DscrewHead;
- z[1] = I->GetZ(4)+ThScrewHeadHole;
- rn[1] = 0.0;
- rx[1] = 0.5*DscrewHead;
- z[2] = z[1];
- rn[2] = 0.0;
- rx[2] = 0.5*DscrewShaft;
- z[3] = I->GetZ(6);
- rn[3] = 0.0;
- rx[3] = rx[2];
- TGeoPcon *Q = new TGeoPcon("ITS SSD Thermal sheal stainless steel "
- "bolts",phi,dphi,4);
- for(i=0;i<Q->GetNz();i++){
- Q->DefineSection(i,z[i],rn[i],rx[i]);
- } // end for i
- printPcon(Q);
- // air infront of bolt (stasolit Volume K) -- Tube
- z[0] = 0.5*(ThSDDsupportPlate-Cthick);
- rn[0] = 0.0*kmm;
- rx[0] = 0.5*DscrewHead;
- TGeoTube *R = new TGeoTube("ITS Air in front of bolt (in stasolit)",
- rn[0],rx[0],z[0]);
- // air infront of bolt (carbon fiber volume I) -- Tube
- z[0] = 0.5*Cthick;
- rn[0] = 0.0*kmm;
- rx[0] = R->GetRmax();
- TGeoTube *S = new TGeoTube("ITS Air in front of Stainless Steal "
- "Screw end, N6",rn[0],rx[0],z[0]);
- printTube(S);
- // SDD support plate, SSD side.
- //Poly-cone Volume T.
- dphi = TMath::RadToDeg()*TMath::ATan2(0.5*WsddSupportPlate,
- RsddSupportPlate);
- phi = Phi0SDDsupports-0.5*dphi;
- z[0] = K->GetZ(2);
- rn[0] = I->GetRmin(4);
- rx[0] = RsddSupportPlate;
- z[1] = I->GetZ(4) - ThSDDsupportPlate;
- rn[1] = rn[0];
- rx[1] = rx[0];
- TGeoPcon *T = new TGeoPcon("ITS SSD-SDD mounting bracket Inserto->Al.",
- phi,dphi,2);
- for(i=0;i<T->GetNz();i++){
- T->DefineSection(i,z[i],rn[i],rx[i]);
- } // end for i
- printPcon(T);
- //
- // Poly-cone Volume U.
- TGeoPcon *U;
- if(I->GetRmin(3)<T->GetRmax(0)){
- dphi = T->GetDphi();
- phi = T->GetPhi1();
- z[2] = I->GetZ(4);
- rn[2] = T->GetRmin(0);
- rx[2] = T->GetRmax(0);
- z[3] = K->GetZ(2);
- rn[3] = rn[2];
- rx[3] = rx[2];
- z[1] = z[2];
- rn[1] = I->GetRmin(3);
- rx[1] = rx[3];
- rx[0] = T->GetRmax(0);
- rn[0] = rx[0];
- z[0] = Zfrom2MinPoints(I,2,3,rn[0]);
- U = new TGeoPcon("ITS SSD-SDD mounting bracket CF->Al.",phi,dphi,4);
- }else{
- dphi = T->GetDphi();
- phi = T->GetPhi1();
- z[0] = I->GetZ(4);
- rn[0] = T->GetRmin(0);
- rx[0] = T->GetRmax(0);
- z[1] = K->GetZ(2);
- rn[1] = rn[0];
- rx[1] = rx[0];
- U = new TGeoPcon("ITS SSD-SDD mounting bracket CF->Al.",phi,dphi,2);
- }// end if
- for(i=0;i<U->GetNz();i++){
- U->DefineSection(i,z[i],rn[i],rx[i]);
- } // end for i
- printPcon(U);
- //
- TGeoVolume *Av,*Bv,*Cv,*Dv,*Ev,*Fv,*Gv,*Hv,*Iv,*Jv,*Kv,*Lv,*Mv,*Nv,
- *Ov,*Pv,*Qv,*Rv,*Sv,*Tv,*Uv;
- Av = new TGeoVolume("ITSssdConeA",A,SSDcf);
- Av->SetVisibility(kTRUE);
- Av->SetLineColor(4); // blue
- Av->SetLineWidth(1);
- Av->SetFillColor(Av->GetLineColor());
- Av->SetFillStyle(4010); // 10% transparent
- Bv = new TGeoVolume("ITSssdConeB",B,SSDfs);
- Bv->SetVisibility(kTRUE);
- Bv->SetLineColor(2); // red
- Bv->SetLineWidth(1);
- Bv->SetFillColor(Bv->GetLineColor());
- Bv->SetFillStyle(4010); // 10% transparent
- Cv = new TGeoVolume("ITSssdConeC",C,SSDfo);
- Cv->SetVisibility(kTRUE);
- Cv->SetLineColor(3); // green
- Cv->SetLineWidth(1);
- Cv->SetFillColor(Cv->GetLineColor());
- Cv->SetFillStyle(4010); // 10% transparent
- Dv = new TGeoVolume("ITSssdConeD",D,SSDss);
- Dv->SetVisibility(kTRUE);
- Dv->SetLineColor(1); // black
- Dv->SetLineWidth(1);
- Dv->SetFillColor(Dv->GetLineColor());
- Dv->SetFillStyle(4010); // 10% transparent
- Ev = new TGeoVolume("ITSssdConeE",E,SSDss);
- Ev->SetVisibility(kTRUE);
- Ev->SetLineColor(1); // black
- Ev->SetLineWidth(1);
- Ev->SetFillColor(Ev->GetLineColor());
- Ev->SetFillStyle(4010); // 10% transparent
- Fv = new TGeoVolume("ITSssdConeF",F,SSDfo);
- Fv->SetVisibility(kTRUE);
- Fv->SetLineColor(3); // green
- Fv->SetLineWidth(1);
- Fv->SetFillColor(Fv->GetLineColor());
- Fv->SetFillStyle(4010); // 10% transparent
- Gv = new TGeoVolume("ITSssdConeG",G,SSDcf);
- Gv->SetVisibility(kTRUE);
- Gv->SetLineColor(4); // blue
- Gv->SetLineWidth(2);
- Gv->SetFillColor(Gv->GetLineColor());
- Gv->SetFillStyle(4010); // 10% transparent
- Hv = new TGeoVolume("ITSssdConeH",H,SSDfo);
- Hv->SetVisibility(kTRUE);
- Hv->SetLineColor(3); // green
- Hv->SetLineWidth(1);
- Hv->SetFillColor(Hv->GetLineColor());
- Hv->SetFillStyle(4010); // 10% transparent
- Iv = new TGeoVolume("ITSssdConeI",I,SSDcf);
- Iv->SetVisibility(kTRUE);
- Iv->SetLineColor(4); // blue
- Iv->SetLineWidth(1);
- Iv->SetFillColor(Iv->GetLineColor());
- Iv->SetFillStyle(4010); // 10% transparent
- Jv = new TGeoVolume("ITSssdConeJ",J,SSDfo);
- Jv->SetVisibility(kTRUE);
- Jv->SetLineColor(3); // green
- Jv->SetLineWidth(3);
- Jv->SetFillColor(Jv->GetLineColor());
- Jv->SetFillStyle(4010); // 10% transparent
- Kv = new TGeoVolume("ITSssdConeK",K,SSDfs);
- Kv->SetVisibility(kTRUE);
- Kv->SetLineColor(2); // red
- Kv->SetLineWidth(1);
- Kv->SetFillColor(Kv->GetLineColor());
- Kv->SetFillStyle(4010); // 10% transparent
- Lv = new TGeoVolume("ITSssdConeL",L,SSDfo);
- Lv->SetVisibility(kTRUE);
- Lv->SetLineColor(3); // green
- Lv->SetLineWidth(3);
- Lv->SetFillColor(Lv->GetLineColor());
- Lv->SetFillStyle(4010); // 10% transparent
- Mv = new TGeoVolume("ITSssdConeM",M,SSDfs);
- Mv->SetVisibility(kTRUE);
- Mv->SetLineColor(2); // red
- Mv->SetLineWidth(1);
- Mv->SetFillColor(Mv->GetLineColor());
- Mv->SetFillStyle(4010); // 10% transparent
- Nv = new TGeoVolume("ITSssdConeN",N,SSDfs);
- Nv->SetVisibility(kTRUE);
- Nv->SetLineColor(2); // red
- Nv->SetLineWidth(1);
- Nv->SetFillColor(Nv->GetLineColor());
- Nv->SetFillStyle(4010); // 10% transparent
- Ov = new TGeoVolume("ITSssdConeO",O,SSDcf);
- Ov->SetVisibility(kTRUE);
- Ov->SetLineColor(4); // blue
- Ov->SetLineWidth(1);
- Ov->SetFillColor(Iv->GetLineColor());
- Ov->SetFillStyle(4010); // 10% transparent
- Pv = new TGeoVolume("ITSssdConeP",P,SSDfs);
- Pv->SetVisibility(kTRUE);
- Pv->SetLineColor(2); // red
- Pv->SetLineWidth(1);
- Pv->SetFillColor(Pv->GetLineColor());
- Pv->SetFillStyle(4010); // 10% transparent
- Qv = new TGeoVolume("ITSssdConeQ",Q,SSDss);
- Qv->SetVisibility(kTRUE);
- Qv->SetLineColor(1); // black
- Qv->SetLineWidth(1);
- Qv->SetFillColor(Qv->GetLineColor());
- Qv->SetFillStyle(4010); // 10% transparent
- Rv = new TGeoVolume("ITSssdConeR",R,SSDair);
- Rv->SetVisibility(kTRUE);
- Rv->SetLineColor(5); // yellow
- Rv->SetLineWidth(1);
- Rv->SetFillColor(Rv->GetLineColor());
- Rv->SetFillStyle(4010); // 10% transparent
- Sv = new TGeoVolume("ITSssdConeS",S,SSDair);
- Sv->SetVisibility(kTRUE);
- Sv->SetLineColor(5); // yellow
- Sv->SetLineWidth(1);
- Sv->SetFillColor(Sv->GetLineColor());
- Sv->SetFillStyle(4010); // 10% transparent
- Tv = new TGeoVolume("ITSssdConeT",T,SSDal);
- Tv->SetVisibility(kTRUE);
- Tv->SetLineColor(17); // gray
- Tv->SetLineWidth(1);
- Tv->SetFillColor(Tv->GetLineColor());
- Tv->SetFillStyle(4010); // 10% transparent
- Uv = new TGeoVolume("ITSssdConeU",U,SSDal);
- Uv->SetVisibility(kTRUE);
- Uv->SetLineColor(17); // gray
- Uv->SetLineWidth(1);
- Uv->SetFillColor(Uv->GetLineColor());
- Uv->SetFillStyle(4010); // 10% transparent
- //
- TGeoTranslation *tran = new TGeoTranslation("ITSssdConeTrans",0.0,0.0,-Z0);
- TGeoRotation *rot180 = new TGeoRotation("",0.0,180.0,0.0);
- TGeoCombiTrans *flip = new TGeoCombiTrans("ITSssdConeFlip",0.0,0.0,Z0,rot180);
- delete rot180;// rot not explicity used in AddNode functions.
- TGeoTranslation *tranR,*tranS;
- TGeoCombiTrans *fliptran,*rottran;
- TGeoRotation *rot,*zspoaks,*zspoaks180;
- Int_t NcD=1,NcE=1,NcQ=1,NcR=1,NcS=1,NcT=1,NcU=1;
- Av->AddNode(Bv,1,0);
- Av->AddNode(Cv,1,0);
- Moth->AddNode(Av,1,tran); // RB24 side
- Moth->AddNode(Av,2,flip); // RB26 side (Absorber)
- Moth->AddNode(Iv,1,tran); // RB24 side
- Moth->AddNode(Iv,2,flip); // RB26 side (Absorber)
- Gv->AddNode(Hv,1,0);
- for(i=0;i<Nspoaks;i++){ // SSD Cone Spoaks
- zspoaks = new TGeoRotation("",0.0,0.0,
- ((Double_t)i*360.)/((Double_t)Nspoaks));
- rottran = new TGeoCombiTrans("",0.0,0.0,-Z0,zspoaks);
- Moth->AddNode(Gv,i+1,rottran); // RB24 side
- Av->AddNode(Fv,i+1,zspoaks);
- Iv->AddNode(Lv,i+1,zspoaks);
- zspoaks180 = new TGeoRotation("",0.0,180.0,
- ((Double_t)i*360.)/((Double_t)Nspoaks));
- fliptran = new TGeoCombiTrans("",0.0,0.0,Z0,zspoaks180);
- delete zspoaks180;// rot not explicity used in AddNode functions.
- Moth->AddNode(Gv,Nspoaks+i+1,fliptran); // RB26 side
- } // end for i
- Iv->AddNode(Jv,1,0);
- Iv->AddNode(Kv,1,0);
- Ov->AddNode(Pv,1,0);
- t0 = (P->GetPhi1()+0.5*P->GetDphi())*kRadian;
- t = (0.25* P->GetDphi())*kRadian;
- z[0] = 0.5*(P->GetRmin(2)+P->GetRmax(2))+
- 0.25*(P->GetRmax(2)-P->GetRmin(2));
- x = z[0]*TMath::Cos(t0+t);
- y = z[0]*TMath::Sin(t0+t);
- tran = new TGeoTranslation("",x,y,P->GetZ(2)-Q->GetZ(3));
- Pv->AddNode(Qv,NcQ++,tran); // Screw head
- z[0] = 0.5*(P->GetRmin(2)+P->GetRmax(2))-
- 0.25*(P->GetRmax(2)-P->GetRmin(2));
- x = z[0]*TMath::Cos(t0-t);
- y = z[0]*TMath::Sin(t0-t);
- tran = new TGeoTranslation("",x,y,P->GetZ(2)-Q->GetZ(3));
- Pv->AddNode(Qv,NcQ++,tran); // Screw head
- //Pv->AddNode(Vv,1,?); // Air hole in Posts
- //Pv->AddNode(Vv,2,?); // Air hole in Posts
- //Mv->AddNode(Wv,1,?); // Air hole in Posts
- //Mv->AddNode(Wv,2,?); // Air hole in Posts
- //Nv->AddNode(Xv,1,?); // Air hole in Posts
- //Nv->AddNode(Xv,2,?); // Air hole in Posts
- TGeoRotation *zposts,*zposts180;
- for(i=0;i<Nposts;i++){ // SSD Cone mounting posts
- zposts = new TGeoRotation("",0.0,0.0,
- ((Double_t)i*360.)/((Double_t)Nposts));
- rottran = new TGeoCombiTrans("",0.0,0.0,-Z0,zposts);
- Moth->AddNode(Ov,i+1,rottran); // RB24 side
- Jv->AddNode(Mv,i+1,zposts);
- Iv->AddNode(Nv,i+1,zposts);
- //Jv->AddNode(Xv,2*i+3,?); // Air hole in Posts
- //Jv->AddNode(Xv,2*i+4,?); // Air hole in Posts
- zposts180 = new TGeoRotation("",0.0,180.0,
- ((Double_t)i*360.)/((Double_t)Nposts));
- fliptran = new TGeoCombiTrans("",0.0,0.0,Z0,zposts180);
- delete zposts180;// rot not explicity used in AddNode functions.
- Moth->AddNode(Ov,Nposts+i+1,fliptran); // RB26 side
- } // end for i
- //
- for(i=0;i<NinScrews;i++){
- t = (Phi0Screws+360.*((Double_t)i)/((Double_t)NinScrews))*kRadian;
- tran= new TGeoTranslation("",RcylinderScrews*TMath::Cos(t),
- RcylinderScrews*TMath::Sin(t),0.0);
- Kv->AddNode(Qv,NcQ++,tran);
- tran = new TGeoTranslation("",RcylinderScrews*TMath::Cos(t),
- RcylinderScrews*TMath::Sin(t),
- CB->GetZ(0)+D->GetDz());
- CBv->AddNode(Dv,NcD++,tran);
- tran = new TGeoTranslation("",RcylinderScrews*TMath::Cos(t),
- RcylinderScrews*TMath::Sin(t),
- CB->GetZ(5)-D->GetDz());
- CBv->AddNode(Dv,NcD++,tran);
- if(/*not where volumes U and T are*/kTRUE){
- tranR = new TGeoTranslation("",RcylinderScrews*TMath::Cos(t),
- RcylinderScrews*TMath::Sin(t),
- K->GetZ(2)+R->GetDz());
- tranS = new TGeoTranslation("",RcylinderScrews*TMath::Cos(t),
- RcylinderScrews*TMath::Sin(t),
- I->GetZ(4)+S->GetDz());
- Kv->AddNode(Rv,NcR++,tranR);
- Iv->AddNode(Sv,NcS++,tranS);
- } // end if
- } // end for i
- const Int_t Nbscrew=2,Nbpins=3,Nrailsc=4,Nrailp=2;
- Double_t da[] = {-3.5,-1.5,1.5,3.5};
- for(i=0;i<2;i++){ // Mounting for ITS-TPC bracket or ITS-Rails
- t0 = 180.*((Double_t)i)*kRadian;
- for(j=-Nbscrew/2;j<=Nbscrew/2;j++)if(j!=0){//screws per ITS-TPC bracket
- t = t0 + 5.0*((Double_t)j)*kRadian;
- tran = new TGeoTranslation("",RoutHole*TMath::Cos(t),
- RoutHole*TMath::Sin(t),
- B->GetZ(0)+D->GetDz());
- Bv->AddNode(Dv,NcD++,tran);
- } // end or j
- for(j=-Nbpins/2;j<=Nbpins/2;j++){ // pins per ITS-TPC bracket
- t = t0 + 3.0*((Double_t)j)*kRadian;
- tran = new TGeoTranslation("",RoutHole*TMath::Cos(t),
- RoutHole*TMath::Sin(t),
- B->GetZ(0)+D->GetDz());
- Bv->AddNode(Ev,NcE++,tran);
- } // end or j
- t0 = (96.5+187.*((Double_t)i))*kRadian;
- for(j=0;j<Nrailsc;j++){ // screws per ITS-rail bracket
- t = t0+da[j]*kRadian;
- tran = new TGeoTranslation("",RoutHole*TMath::Cos(t),
- RoutHole*TMath::Sin(t),
- B->GetZ(0)+D->GetDz());
- Bv->AddNode(Dv,NcD++,tran);
- } // end or j
- t0 = (91.5+184.*((Double_t)i))*kRadian;
- for(j=-Nrailp/2;j<=Nrailp/2;j++)if(j!=0){ // pins per ITS-rail bracket
- t = t0+(7.0*((Double_t)j))*kRadian;
- tran = new TGeoTranslation("",RoutHole*TMath::Cos(t),
- RoutHole*TMath::Sin(t),
- B->GetZ(0)+D->GetDz());
- Bv->AddNode(Ev,NcE++,tran);
- } // end or j
- } // end for i
- for(i=0;i<Nmounts;i++){ // mounting points for SPD-cone+Beam-pipe support
- t0 = (45.0+((Double_t)i)*360./((Double_t)Nmounts))*kRadian;
- for(j=-1;j<=1;j++)if(j!=0){ // 2 screws per bracket
- t = t0+((Double_t)j)*0.5*DmountAngle*kRadian;
- tran = new TGeoTranslation("",RoutHole*TMath::Cos(t),
- RoutHole*TMath::Sin(t),
- B->GetZ(0)+D->GetDz());
- Bv->AddNode(Dv,NcD++,tran);
- } // end for j
- for(j=0;j<1;j++){ // 1 pin per bracket
- t = t0;
- tran = new TGeoTranslation("",RoutHole*TMath::Cos(t),
- RoutHole*TMath::Sin(t),
- B->GetZ(0)+D->GetDz());
- Bv->AddNode(Ev,NcE++,tran);
- } // end for j
- } // end for i
- t = (T->GetPhi1()+0.5*T->GetDphi())*kRadian;
- tran = new TGeoTranslation("",RinHole*TMath::Cos(t),RinHole*TMath::Sin(t),
- T->GetZ(T->GetNz()-1)+R->GetDz());
- Tv->AddNode(Rv,NcR++,tran);
- t = (U->GetPhi1()+0.5*U->GetDphi())*kRadian;
- tran = new TGeoTranslation("",RinHole*TMath::Cos(t),RinHole*TMath::Sin(t),
- U->GetZ(U->GetNz()-1)+S->GetDz());
- Uv->AddNode(Sv,NcS++,tran);
- for(i=0;i<NssdSupports;i++){ // mounting braclets for SSD/SDD
- t0 = ((Double_t)i*360./((Double_t)NssdSupports));
- rot = new TGeoRotation("",0.0,0.0,t0);
- Kv->AddNode(Tv,NcT++,rot);
- Iv->AddNode(Uv,NcU++,rot);
- for(j=0;j<2;j++)if(j!=0){ // 2 pin per bracket
- t = t0 + ((Double_t)j)*0.5*DssdsddBracketAngle;
- tran = new TGeoTranslation("",RinHole*TMath::Cos(t),
- RinHole*TMath::Sin(t),
- T->GetZ(T->GetNz()-1)-E->GetDz());
- Kv->AddNode(Ev,NcE++,tran);
- } // end for j
- } // end for i
- if(GetDebug()){
- Av->PrintNodes();
- Bv->PrintNodes();
- Cv->PrintNodes();
- Dv->PrintNodes();
- Ev->PrintNodes();
- Fv->PrintNodes();
- Gv->PrintNodes();
- Hv->PrintNodes();
- Iv->PrintNodes();
- Jv->PrintNodes();
- Kv->PrintNodes();
- Lv->PrintNodes();
- Mv->PrintNodes();
- Nv->PrintNodes();
- Ov->PrintNodes();
- Pv->PrintNodes();
- Qv->PrintNodes();
- Rv->PrintNodes();
- Sv->PrintNodes();
- Tv->PrintNodes();
- Uv->PrintNodes();
- } // end if
+ AliITSv11GeometrySupport *sup = new AliITSv11GeometrySupport(GetDebug());
+ //sup->SPDCone(ITSV);
+ //sup->SDDCone(ITSV);
+ sup->SSDCone(ITSV);
+ //sup->ServicesCableSupport(ITSV);
}
//______________________________________________________________________
void AliITSv11::CreateMaterials(){
new TGeoMedium("ITSssdAl",6,Al,SSDcone);
}
//______________________________________________________________________
-void AliITSv11::ServicesCableSupport(TGeoVolume *Moth){
- // Define the detail ITS cable support trays on both the RB24 and
- // RB26 sides..
- // Inputs:
- // none.
- // Outputs:
- // none.
- // Return:
- // none.
- // Based on the Drawings SSup_201A.jpg unless otherwise stated,
- // Volumes A...,
- TGeoMedium *SUPcf = 0; // SUP support cone Carbon Fiber materal number.
- TGeoMedium *SUPfs = 0; // SUP support cone inserto stesalite 4411w.
- TGeoMedium *SUPfo = 0; // SUP support cone foam, Rohacell 50A.
- TGeoMedium *SUPss = 0; // SUP support cone screw material,Stainless
- TGeoMedium *SUPair = 0; // SUP support cone Air
- TGeoMedium *SUPal = 0; // SUP support cone SDD mounting bracket Al
- TGeoMedium *SUPwater = 0; // SUP support cone Water
- TGeoManager *mgr = gGeoManager;
- SUPcf = mgr->GetMedium("ITSssdCarbonFiber");
- SUPfs = mgr->GetMedium("ITSssdStaselite4411w");
- SUPfo = mgr->GetMedium("ITSssdRohacell50A");
- SUPss = mgr->GetMedium("ITSssdStainlessSteal");
- SUPair = mgr->GetMedium("ITSssdAir");
- SUPal = mgr->GetMedium("ITSssdAl");
- SUPwater = mgr->GetMedium("ITSssdWater");
- //
- Int_t i,j;
- Double_t x,y,z,t,t0,dt,di,r;
-
- // RB 24 side
- const Double_t Z024 = 900*kmm;//SSup_203A.jpg
- const Double_t ThssFrame24 = 5.0*kmm;
- const Double_t RssFrame24 = 444.5*kmm-ThssFrame24; // SSup_204A.jpg
- const Double_t WidthFrame24 = 10.0*kmm;
- const Double_t HightFrame24 = 10.0*kmm;
- const Double_t Phi0Frame24 = 15.2*kDegree; // SSup_602A.jpg
- const Double_t Phi1Frame24 = (90.0-7.6)*kDegree; // SSup_802A.jpg
- const Double_t ZssFrameSection24 = (415.0-10.0)*kmm;
- const Int_t NZsections24 = 4;
- const Int_t NPhiSections24 = 4;
- const Int_t NFramesPhi24 = 4;
- TGeoTubeSeg *A24,*M24; // Cylinderial support structure
- TGeoBBox *B24; // Cylinderial support structure
-
- M24 = new TGeoTubeSeg("ITS sup Cable tray support frame mother volume M24",
- RssFrame24,RssFrame24+ThssFrame24,
- 0.5*(4.*ZssFrameSection24+5*WidthFrame24),
- Phi0Frame24,Phi1Frame24);
- A24 = new TGeoTubeSeg("ITS sup Cable tray support frame radial section A24",
- RssFrame24,RssFrame24+ThssFrame24,0.5*WidthFrame24,
- Phi0Frame24,Phi1Frame24);
- B24 = new TGeoBBox("ITS sup Cable tray support frame Z section B24",
- 0.5*ThssFrame24,0.5*HightFrame24,0.5*ZssFrameSection24);
- printTubeSeg(A24);
- printTubeSeg(M24);
- printBBox(B24);
- TGeoVolume *A24v,*B24v,*M24v;
- TGeoTranslation *tran;
- TGeoRotation *rot;
- TGeoCombiTrans *tranrot;
- //
- A24v = new TGeoVolume("ITSsupFrameA24",A24,SUPss);
- A24v->SetVisibility(kTRUE);
- A24v->SetLineColor(1); // black
- A24v->SetLineWidth(1);
- A24v->SetFillColor(A24v->GetLineColor());
- A24v->SetFillStyle(4000); // 0% transparent
- B24v = new TGeoVolume("ITSsupFrameB24",B24,SUPss);
- B24v->SetVisibility(kTRUE);
- B24v->SetLineColor(1); // black
- B24v->SetLineWidth(1);
- B24v->SetFillColor(B24v->GetLineColor());
- B24v->SetFillStyle(4000); // 0% transparent
- M24v = new TGeoVolume("ITSsupFrameM24",M24,SUPair);
- M24v->SetVisibility(kTRUE);
- M24v->SetLineColor(7); // light blue
- M24v->SetLineWidth(1);
- M24v->SetFillColor(M24v->GetLineColor());
- M24v->SetFillStyle(4090); // 90% transparent
- //
- Int_t NcA24=1,NcB24=1;
- t0 = Phi0Frame24;
- dt = (Phi1Frame24-Phi0Frame24)/((Double_t)NPhiSections24);
- for(i=0;i<=NZsections24;i++){
- di = (Double_t) i;
- z = -M24->GetDz()+A24->GetDz() + di*(ZssFrameSection24+WidthFrame24);
- tran = new TGeoTranslation("",0.0,0.0,z);
- M24v->AddNode(A24v,NcA24++,tran);
- r = RssFrame24+B24->GetDX();
- z = z + A24->GetDz()+B24->GetDZ();
- if(i<NZsections24) for(j=0;j<=NPhiSections24;j++){
- t = t0 + ((Double_t)j)*dt;
- rot = new TGeoRotation("",0.0,0.0,t);
- y = r*TMath::Sin(t*kRadian);
- x = r*TMath::Cos(t*kRadian);
- tranrot = new TGeoCombiTrans("",x,y,z,rot);
- delete rot;// rot not explicity used in AddNode functions.
- M24v->AddNode(B24v,NcB24++,tranrot);
- } // end for j
- } // end for i
- tran = new TGeoTranslation("",0.0,0.0,Z024+M24->GetDz());
- Moth->AddNode(M24v,1,tran);
- for(i=1;i<NFramesPhi24;i++){
- di = (Double_t) i;
- rot = new TGeoRotation("",0.0,0.0,90.0*di);
- tranrot = new TGeoCombiTrans("",0.0,0.0,Z024+M24->GetDz(),rot);
- delete rot;// rot not explicity used in AddNode functions.
- Moth->AddNode(M24v,i+1,tranrot);
- } // end for i
- if(GetDebug()){
- A24v->PrintNodes();
- B24v->PrintNodes();
- M24v->PrintNodes();
- } // end if
- // Cable support tray
- // Material is Aluminum
- const Double_t RS24in = TMath::Max(RssFrame24,444.5*kmm);
- // SSup_204A & SSup_206A
- const Double_t RS24Airout = 459.5*kmm; // SSup_204A & SSup_206A
- const Double_t RS24out = 494.5*kmm; // SSup_206A & SSup_204A
- const Double_t RS24PPout = 550.0*kmm; // SSup_206A
- const Double_t LS24PP = 350.0*kmm; // SSup_202A
- const Double_t LS24 = (2693.0-900.0)*kmm; //SSup_205A & SSup_207A
- const Double_t ThS24wall = 1.0*kmm; // SSup_209A & SSup_210A
- const Double_t WbS24 = 42.0*kmm; // SSup_209A & SSup_210A
- const Double_t WtS24 = 46.9*kmm; // SSup_209A & SSup_210A
- const Double_t WcapS24 = 50.0*kmm; // SSup_209A & SSup_210A
- const Double_t WdS24 = 41.0*kmm; // SSup_209A ? should be 41.46938776
- const Double_t HS24 = 50.0*kmm; // SSup_209A & SSup_210A
- const Double_t OutDcoolTub= 12.0*kmm; // SSup_209A
- const Double_t InDcoolTub = 10.0*kmm; // SSup_209A
- const Double_t BlkNozInDS24= 6.0*kmm; // SSup_209A
- // The following are deduced or guessed at
- const Double_t LtopLipS24 = 6.0*kmm; // Guessed at.
- const Double_t LdLipS24 = 6.0*kmm; // Guessed at.
- const Double_t HdS24 = OutDcoolTub; //
- const Double_t BlkNozZS24 = 6.0*kmm; // Guessed at.
- // Simplifided exterior shape. The side wall size is 2.5*thicker than
- // it should be (due to simplification).
- TGeoArb8 *C24 = new TGeoArb8("ITS Sup Cable Tray Element C24",0.5*LS24);
- C24->SetVertex(0,-0.5*WcapS24,HS24+ThS24wall);
- C24->SetVertex(1,+0.5*WcapS24,HS24+ThS24wall);
- C24->SetVertex(2,+0.5*WbS24,0.0);
- C24->SetVertex(3,-0.5*WbS24,0.0);
- C24->SetVertex(4,-0.5*WcapS24,HS24+ThS24wall);
- C24->SetVertex(5,+0.5*WcapS24,HS24+ThS24wall);
- C24->SetVertex(6,+0.5*WbS24,0.0);
- C24->SetVertex(7,-0.5*WbS24,0.0);
- TGeoArb8 *D24 = new TGeoArb8("ITS Sup Cable Tray lower Element D24",
- 0.5*LS24);
- // Because of question about the value of WdS24, compute what it
- // should be assuming cooling tube fixes hight of volume.
- x = OutDcoolTub*(0.5*WcapS24-0.5*WbS24-ThS24wall)/(HS24-ThS24wall);
- D24->SetVertex(0,-x,OutDcoolTub+ThS24wall);
- D24->SetVertex(1,+x,OutDcoolTub+ThS24wall);
- D24->SetVertex(2,+0.5*WbS24-ThS24wall,ThS24wall);
- D24->SetVertex(3,-0.5*WbS24+ThS24wall,ThS24wall);
- D24->SetVertex(4,-x,OutDcoolTub+ThS24wall);
- D24->SetVertex(5,+x,OutDcoolTub+ThS24wall);
- D24->SetVertex(6,+0.5*WbS24-ThS24wall,ThS24wall);
- D24->SetVertex(7,-0.5*WbS24+ThS24wall,ThS24wall);
- TGeoTube *E24 = new TGeoTube("ITS Sup Cooling Tube E24",0.5*InDcoolTub,
- 0.5*OutDcoolTub,0.5*LS24-BlkNozZS24);
- TGeoArb8 *F24 = new TGeoArb8("ITS Sup Cable Tray lower Element block F24",
- 0.5*BlkNozZS24);
- for(i=0;i<8;i++) F24->SetVertex(i,D24->GetVertices()[i*2+0],
- D24->GetVertices()[i*2+1]); //
- TGeoTube *G24 = new TGeoTube("ITS Sup Cooling Tube hole in block G24",
- 0.0,0.5*BlkNozInDS24,0.5*BlkNozZS24);
- TGeoArb8 *H24 = new TGeoArb8("ITS Sup Cable Tray upper Element H24",
- 0.5*(LS24- LS24PP));
- H24->SetVertex(0,C24->GetVertices()[0*2+0]+2.*ThS24wall,
- C24->GetVertices()[0*2+1]-ThS24wall);
- H24->SetVertex(1,C24->GetVertices()[1*2+0]-2.*ThS24wall,
- C24->GetVertices()[1*2+1]-ThS24wall);
- H24->SetVertex(2,D24->GetVertices()[1*2+0]-ThS24wall,
- D24->GetVertices()[1*2+1]+ThS24wall);
- H24->SetVertex(3,D24->GetVertices()[0*2+0]+ThS24wall,
- D24->GetVertices()[0*2+1]+ThS24wall);
- for(i=4;i<8;i++) H24->SetVertex(i,H24->GetVertices()[(i-4)*2+0],
- H24->GetVertices()[(i-4)*2+1]); //
- printArb8(C24);
- printArb8(D24);
- printTube(E24);
- printArb8(F24);
- printTube(G24);
- printArb8(H24);
- TGeoVolume *C24v,*D24v,*E24v,*F24v,*Ga24v,*Gw24v,*Gf24v,*H24v;
- //
- C24v = new TGeoVolume("ITSsupCableTrayC24",C24,SUPal);
- C24v->SetVisibility(kTRUE);
- C24v->SetLineColor(6); //
- C24v->SetLineWidth(1);
- C24v->SetFillColor(C24v->GetLineColor());
- C24v->SetFillStyle(4000); // 0% transparent
- D24v = new TGeoVolume("ITSsupCableTrayLowerD24",D24,SUPair);
- D24v->SetVisibility(kTRUE);
- D24v->SetLineColor(6); //
- D24v->SetLineWidth(1);
- D24v->SetFillColor(D24v->GetLineColor());
- D24v->SetFillStyle(4000); // 0% transparent
- E24v = new TGeoVolume("ITSsupCableTrayCoolTubeE24",E24,SUPss);
- E24v->SetVisibility(kTRUE);
- E24v->SetLineColor(6); //
- E24v->SetLineWidth(1);
- E24v->SetFillColor(E24v->GetLineColor());
- E24v->SetFillStyle(4000); // 0% transparent
- F24v = new TGeoVolume("ITSsupCableTrayBlockF24",F24,SUPal);
- F24v->SetVisibility(kTRUE);
- F24v->SetLineColor(6); //
- F24v->SetLineWidth(1);
- F24v->SetFillColor(F24v->GetLineColor());
- F24v->SetFillStyle(4000); // 0% transparent
- Gw24v = new TGeoVolume("ITSsupCableTrayCoolantWaterG24",G24,SUPwater);
- Gw24v->SetVisibility(kTRUE);
- Gw24v->SetLineColor(6); //
- Gw24v->SetLineWidth(1);
- Gw24v->SetFillColor(Gw24v->GetLineColor());
- Gw24v->SetFillStyle(4000); // 0% transparent
- Ga24v = new TGeoVolume("ITSsupCableTrayCoolantAirG24",G24,SUPair);
- Ga24v->SetVisibility(kTRUE);
- Ga24v->SetLineColor(6); //
- Ga24v->SetLineWidth(1);
- Ga24v->SetFillColor(Ga24v->GetLineColor());
- Ga24v->SetFillStyle(4000); // 0% transparent
- H24v = new TGeoVolume("ITSsupCableTrayUpperC24",H24,SUPair);
- H24v->SetVisibility(kTRUE);
- H24v->SetLineColor(6); //
- H24v->SetLineWidth(1);
- H24v->SetFillColor(H24v->GetLineColor());
- H24v->SetFillStyle(4000); // 0% transparent
- //
- tran = new TGeoTranslation("",-OutDcoolTub,OutDcoolTub+ThS24wall,0.0);
- F24v->AddNode(Gw24v,1,tran);
- D24v->AddNode(E24v,1,tran);
- tran = new TGeoTranslation("",0.0,OutDcoolTub+ThS24wall,0.0);
- F24v->AddNode(Gw24v,2,tran);
- D24v->AddNode(E24v,2,tran);
- tran = new TGeoTranslation("",+OutDcoolTub,OutDcoolTub+ThS24wall,0.0);
- F24v->AddNode(Gw24v,3,tran);
- D24v->AddNode(E24v,3,tran);
- tran = new TGeoTranslation("",0.0,0.0,0.5*LS24-0.5*BlkNozZS24);
- D24v->AddNode(F24v,1,tran);
- tran = new TGeoTranslation("",0.0,0.0,-(0.5*LS24-0.5*BlkNozZS24));
- D24v->AddNode(F24v,2,tran);
- C24v->AddNode(D24v,1,0);
- C24v->AddNode(H24v,1,0);
- //==================================================================
- //
- // RB 26 side
- const Double_t Z026 = -900*kmm;//SSup_203A.jpg
- const Double_t ThssFrame26 = 5.0*kmm;
- const Double_t R0ssFrame26 = 444.5*kmm-ThssFrame26; // SSup_204A.jpg
- const Double_t R1ssFrame26 = 601.6*kmm-ThssFrame26; // SSup_208A.jpg
- const Double_t WidthFrame26 = 10.0*kmm;
- //const Double_t HightFrame26 = 10.0*kmm;
- const Double_t Phi0Frame26 = 15.2*kDegree; // SSup_602A.jpg
- const Double_t Phi1Frame26 = (90.0-7.6)*kDegree; // SSup_802A.jpg
- const Double_t ZssFrameSection26 = (415.0-10.0)*kmm;
- const Int_t NZsections26 = 4;
- const Int_t NPhiSections26 = 4;
- const Int_t NFramesPhi26 = 4;
- TGeoConeSeg *A26[NZsections26+1],*M26; // Cylinderial support structure
- TGeoArb8 *B26; // Cylinderial support structure
- Char_t name[100];
- Double_t r1,r2,m;
-
- M26 = new TGeoConeSeg("ITS sup Cable tray support frame mother volume M26",
- 0.5*(4.*ZssFrameSection26+5*WidthFrame26),
- R1ssFrame26,R1ssFrame26+ThssFrame26,
- R0ssFrame26,R0ssFrame26+ThssFrame26,
- Phi0Frame26,Phi1Frame26);
- m = -((R1ssFrame26-R0ssFrame26)/
- (((Double_t)NZsections26)*(ZssFrameSection26+WidthFrame26)));
- for(i=0;i<NZsections26+1;i++){
- di = ((Double_t) i)*(ZssFrameSection26+WidthFrame26);
- sprintf(name,
- "ITS sup Cable tray support frame radial section A26[%d]",i);
- r1 = R1ssFrame26+m*di;
- r2 = R1ssFrame26+m*(di+WidthFrame26);
- A26[i] = new TGeoConeSeg(name,0.5*WidthFrame26,r2,r2+ThssFrame26,
- r1,r1+ThssFrame26,Phi0Frame26,Phi1Frame26);
- } // end for i
- B26 = new TGeoArb8("ITS sup Cable tray support frame Z section B26",
- 0.5*ZssFrameSection26);
- r = 0.25*(A26[0]->GetRmax1()+A26[0]->GetRmin1()+
- A26[1]->GetRmax2()+A26[1]->GetRmin2());
- B26->SetVertex(0,A26[0]->GetRmax2()-r,+0.5*WidthFrame26);
- B26->SetVertex(1,A26[0]->GetRmax2()-r,-0.5*WidthFrame26);
- B26->SetVertex(2,A26[0]->GetRmin2()-r,-0.5*WidthFrame26);
- B26->SetVertex(3,A26[0]->GetRmin2()-r,+0.5*WidthFrame26);
- B26->SetVertex(4,A26[1]->GetRmax1()-r,+0.5*WidthFrame26);
- B26->SetVertex(5,A26[1]->GetRmax1()-r,-0.5*WidthFrame26);
- B26->SetVertex(6,A26[1]->GetRmin1()-r,-0.5*WidthFrame26);
- B26->SetVertex(7,A26[1]->GetRmin1()-r,+0.5*WidthFrame26);
- for(i=0;i<NZsections26+1;i++) printConeSeg(A26[i]);
- printConeSeg(M26);
- printArb8(B26);
- TGeoVolume *A26v[NZsections26+1],*B26v,*M26v;
- //
- for(i=0;i<NZsections26+1;i++){
- sprintf(name,"ITSsupFrameA26[%d]",i);
- A26v[i] = new TGeoVolume(name,A26[i],SUPss);
- A26v[i]->SetVisibility(kTRUE);
- A26v[i]->SetLineColor(1); // black
- A26v[i]->SetLineWidth(1);
- A26v[i]->SetFillColor(A26v[i]->GetLineColor());
- A26v[i]->SetFillStyle(4000); // 0% transparent
- } // end for i
- B26v = new TGeoVolume("ITSsupFrameB26",B26,SUPss);
- B26v->SetVisibility(kTRUE);
- B26v->SetLineColor(1); // black
- B26v->SetLineWidth(1);
- B26v->SetFillColor(B26v->GetLineColor());
- B26v->SetFillStyle(4000); // 0% transparent
- M26v = new TGeoVolume("ITSsupFrameM26",M26,SUPair);
- M26v->SetVisibility(kTRUE);
- M26v->SetLineColor(7); // light blue
- M26v->SetLineWidth(1);
- M26v->SetFillColor(M26v->GetLineColor());
- M26v->SetFillStyle(4090); // 90% transparent
- //
- Int_t NcB26=1;
- t0 = Phi0Frame26;
- dt = (Phi1Frame26-Phi0Frame26)/((Double_t)NPhiSections26);
- for(i=0;i<=NZsections26;i++){
- di = ((Double_t) i)*(ZssFrameSection26+WidthFrame26);
- z = -M26->GetDz()+A26[i]->GetDz() + di;
- tran = new TGeoTranslation("",0.0,0.0,z);
- M26v->AddNode(A26v[i],1,tran);
- z = z+B26->GetDz();
- if(i<NZsections26)for(j=0;j<=NPhiSections26;j++){
- r = 0.25*(A26[i]->GetRmax1()+A26[i]->GetRmin1()+
- A26[i+1]->GetRmax2()+A26[i+1]->GetRmin2());
- t = t0 + ((Double_t)j)*dt;
- rot = new TGeoRotation("",0.0,0.0,t);
- y = r*TMath::Sin(t*kRadian);
- x = r*TMath::Cos(t*kRadian);
- tranrot = new TGeoCombiTrans("",x,y,z,rot);
- delete rot; // rot not explicity used in AddNode functions.
- M26v->AddNode(B26v,NcB26++,tranrot);
- } // end for j
- } // end for i
- tran = new TGeoTranslation("",0.0,0.0,Z026-M26->GetDz());
- Moth->AddNode(M26v,1,tran);
- for(i=1;i<NFramesPhi26;i++){
- rot = new TGeoRotation("",0.0,0.0,90.0*((Double_t)i));
- tranrot = new TGeoCombiTrans(*tran,*rot);
- delete rot; // rot not explicity used in AddNode functions.
- Moth->AddNode(M26v,i+1,tranrot);
- } // end for i
- if(GetDebug()){
- for(i=0;i<NZsections26+1;i++) A26v[i]->PrintNodes();
- B26v->PrintNodes();
- M26v->PrintNodes();
- } // end if
-}
-//______________________________________________________________________
void AliITSv11::InitAliITSgeom(){
// Based on the geometry tree defined in Geant 3.21, this
// routine initilizes the Class AliITSgeom from the Geant 3.21 ITS
virtual void SetDefaults();
virtual void DrawModule();
virtual void StepManager();
- virtual void SetWriteDet(Bool_t det=kTRUE){ // set .det write
- fGeomDetOut = det;}
- virtual void SetWriteDet(const char *f){ // set write file
- strncpy(fWrite,f,60);fGeomDetOut = kTRUE;}
- virtual void SetReadDet(Bool_t det=kTRUE){ //set .det read
- fGeomDetIn = det;}
- virtual void SetReadDet(const char *f){ // set read file
- strncpy(fRead,f,60);fGeomDetIn = kTRUE;}
- virtual void SetEUCLID(Bool_t euclid=kTRUE){ // set write Euclid file
- fEuclidOut = euclid;}
- virtual void SetEUCLIDFileName(const char *f){ // set write file
- fEuclidGeometry=f;fEuclidOut = kTRUE;}
- virtual void SetMinorVersion(Int_t v=00){ // Set minor version
- fMinorVersion = v;}
- virtual void SetThicknessDet1(Float_t v=200.){
- // Set detector thickness in layer 1
- fDet1 = v;}
- virtual void SetThicknessDet2(Float_t v=200.){
- // Set detector thickness in layer 2
- fDet2 = v;}
- virtual void SetThicknessChip1(Float_t v=300.){
- // Set chip thickness in layer 1
- fChip1 = v;}
- virtual void SetThicknessChip2(Float_t v=200.){
- // Set chip thickness in layer 2
- fChip2 = v;}
- virtual void SetRails(Int_t v=1){
- // Set flag for rails
- fRails = v;}
- virtual void SetCoolingFluid(Int_t v=1){
- // Set flag for cooling fluid
- fFluid = v;}
- virtual Bool_t GetEUCLID(){return fEuclidOut;}// returns value Euclid flag
- virtual const char *GetEULIIDFileName() const{ // return .euc file name
- return fEuclidGeometry.Data();}
- virtual Bool_t GetWriteDet() { // returns value GeomDetOut flag.
- return fGeomDetOut;}
- virtual Bool_t GetReadDet() { // returns value GeomDetIn flag.
- return fGeomDetIn;}
- virtual char *GetReadDetFileName(){ // return .det read file name
- if(fRead[0]!='\0') return fRead; else return fEuclidGeomDet;}
- virtual char *GetWriteDetFileName(){ // return .det write file name
- if(fWrite[0]!='\0') return fWrite; else return fEuclidGeomDet;}
- virtual Int_t GetMajorVersion(){// return Major Version Number
- return fMajorVersion;}
- virtual Int_t GetMinorVersion(){// return Major Version Number
- return fMinorVersion;}
- virtual Float_t GetThicknessDet1(){
- // Get detector thickness in layer 1
- return fDet1;}
- virtual Float_t GetThicknessDet2(){
- // Get detector thickness in layer 2
- return fDet2;}
- virtual Float_t GetThicknessChip1(){
- // Get chip thickness in layer 1
- return fChip1;}
- virtual Float_t GetThicknessChip2(){
- // Get chip thickness in layer 2
- return fChip2;}
- virtual Int_t GetRails(){
- // Get flag for rails
- return fRails;}
- virtual Int_t GetCoolingFluid(){
- // Get flag for cooling fluid
- return fFluid;}
-
- private:
+ private:
void InitAliITSgeom();
- virtual void SPDCone(TGeoVolume *Moth);
- virtual void SPDThermalSheald(TGeoVolume *Moth);
- virtual void SDDCone(TGeoVolume *Moth);
- virtual void SSDCone(TGeoVolume *Moth);
- virtual void ServicesCableSupport(TGeoVolume *Moth);
- Double_t RmaxFrom2Points(TGeoPcon *p,Int_t i1,Int_t i2,Double_t z);
- Double_t RminFrom2Points(TGeoPcon *p,Int_t i1,Int_t i2,Double_t z);
- Double_t RFrom2Points(Double_t *p,Double_t *Z,Int_t i1,Int_t i2,
- Double_t z);
- Double_t Zfrom2MinPoints(TGeoPcon *p,Int_t i1,Int_t i2,Double_t r);
- Double_t Zfrom2MaxPoints(TGeoPcon *p,Int_t i1,Int_t i2,Double_t r);
- Double_t Zfrom2Points(Double_t *Z,Double_t *p,Int_t i1,Int_t i2,
- Double_t r);
- Double_t RmaxFromZpCone(TGeoPcon *p,Double_t tc,Double_t z,
- Double_t th=0.0);
- Double_t RmaxFromZpCone(Double_t *Rmax,Double_t *Z,Double_t tc,
- Double_t z,Double_t th=0.0);
- Double_t RminFromZpCone(TGeoPcon *p,Double_t tc,Double_t z,
- Double_t th=0.0);
- Double_t RminFromZpCone(Double_t *Rmin,Double_t *Z,Double_t tc,
- Double_t z,Double_t th=0.0);
- Double_t ZFromRmaxpCone(TGeoPcon *p,Double_t tc,Double_t r,
- Double_t th=0.0);
- Double_t ZFromRmaxpCone(Double_t *GetRmax,Double_t *GetZ,Double_t tc,
- Double_t r,Double_t th=0.0);
- Double_t ZFromRminpCone(TGeoPcon *p,Double_t tc,Double_t r,
- Double_t th=0.0);
- void RadiusOfCurvature(Double_t rc,Double_t theta0,Double_t z0,
- Double_t r0,Double_t theta1,Double_t &z1,
- Double_t &r1);
// TString fEuclidGeomtery,fEuclidMaterial defined in AliModule.
Bool_t fEuclidOut; // Flag to write geometry in euclid format
--- /dev/null
+/**************************************************************************
+ * 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. *
+ **************************************************************************/
+
+/* $Id$ */
+#include <stdio.h>
+#include <stdlib.h>
+// General Root includes
+#include <Riostream.h>
+#include <TMath.h>
+#include <float.h>
+#include <TFile.h> // only required for Tracking function?
+#include <TObjArray.h>
+#include <TClonesArray.h>
+#include <TLorentzVector.h>
+#include <TObjString.h>
+// Root Geometry includes
+#include <TGeoManager.h>
+#include <TGeoVolume.h>
+#include <TGeoPcon.h>
+#include <TGeoCone.h>
+#include <TGeoTube.h> // contaings TGeoTubeSeg
+#include <TGeoArb8.h>
+#include <TGeoCompositeShape.h>
+#include <TGeoMatrix.h>
+#include <TGeoNode.h>
+#include <TGeoMaterial.h>
+#include <TGeoMedium.h>
+#include "AliITSBaseGeometry.h"
+#include "AliITSv11Geometry.h"
+
+ClassImp(AliITSv11Geometry)
+//______________________________________________________________________
+Double_t AliITSv11Geometry::RmaxFrom2Points(TGeoPcon *p,Int_t i1,Int_t i2,Double_t z){
+ // functions Require at parts of Volume A to be already defined.
+ // Retruns the value of Rmax corresponding to point z alone the line
+ // defined by the two points p.Rmax(i1),p-GetZ(i1) and p->GetRmax(i2),
+ // p->GetZ(i2).
+ Double_t d0,d1,d2,r;
+
+ d0 = p->GetRmax(i1)-p->GetRmax(i2);// cout <<"L263: d0="<<d0<<endl;
+ d1 = z-p->GetZ(i2);// cout <<"L264: d1="<<d1<<endl;
+ d2 = p->GetZ(i1)-p->GetZ(i2);// cout <<"L265: d2="<<d2<<endl;
+ r = p->GetRmax(i2) + d1*d0/d2;// cout <<"L266: r="<<r<<endl;
+ return r;
+}
+//______________________________________________________________________
+Double_t AliITSv11Geometry::RminFrom2Points(TGeoPcon *p,Int_t i1,Int_t i2,Double_t z){
+ // Retruns the value of Rmin corresponding to point z alone the line
+ // defined by the two points p->GetRmin(i1),p->GetZ(i1) and
+ // p->GetRmin(i2), p->GetZ(i2).
+
+ return p->GetRmin(i2)+(p->GetRmin(i1)-p->GetRmin(i2))*(z-p->GetZ(i2))/
+ (p->GetZ(i1)-p->GetZ(i2));
+}
+//______________________________________________________________________
+Double_t AliITSv11Geometry::RFrom2Points(Double_t *p,Double_t *Z,Int_t i1,
+ Int_t i2,Double_t z){
+ // Retruns the value of Rmin corresponding to point z alone the line
+ // defined by the two points p->GetRmin(i1),p->GetZ(i1) and
+ // p->GetRmin(i2), p->GetZ(i2).
+
+ return p[i2]+(p[i1]-p[i2])*(z-Z[i2])/(Z[i1]-Z[i2]);
+}
+//______________________________________________________________________
+Double_t AliITSv11Geometry::Zfrom2MinPoints(TGeoPcon *p,Int_t i1,Int_t i2,Double_t r){
+ // Retruns the value of Z corresponding to point R alone the line
+ // defined by the two points p->GetRmin(i1),p->GetZ(i1) and
+ // p->GetRmin(i2),p->GetZ(i2)
+
+ return p->GetZ(i2)+(p->GetZ(i1)-p->GetZ(i2))*(r-p->GetRmin(i2))/
+ (p->GetRmin(i1)-p->GetRmin(i2));
+}
+//______________________________________________________________________
+Double_t AliITSv11Geometry::Zfrom2MaxPoints(TGeoPcon *p,Int_t i1,Int_t i2,Double_t r){
+ // Retruns the value of Z corresponding to point R alone the line
+ // defined by the two points p->GetRmax(i1),p->GetZ(i1) and
+ // p->GetRmax(i2),p->GetZ(i2)
+
+ return p->GetZ(i2)+(p->GetZ(i1)-p->GetZ(i2))*(r-p->GetRmax(i2))/
+ (p->GetRmax(i1)-p->GetRmax(i2));
+}
+//______________________________________________________________________
+Double_t AliITSv11Geometry::Zfrom2Points(Double_t *Z,Double_t *p,Int_t i1,
+ Int_t i2,Double_t r){
+ // Retruns the value of Z corresponding to point R alone the line
+ // defined by the two points p->GetRmax(i1),p->GetZ(i1) and
+ // p->GetRmax(i2),p->GetZ(i2)
+
+ return Z[i2]+(Z[i1]-Z[i2])*(r-p[i2])/(p[i1]-p[i2]);
+}
+//______________________________________________________________________
+Double_t AliITSv11Geometry::RmaxFromZpCone(TGeoPcon *p,int ip,Double_t tc,Double_t z,
+ Double_t th){
+ // General SSD Outer Cone surface equation Rmax.
+ Double_t tantc = TMath::Tan(tc*TMath::DegToRad());
+ Double_t costc = TMath::Cos(tc*TMath::DegToRad());
+
+ return -tantc*(z-p->GetZ(ip))+p->GetRmax(ip)+th/costc;
+}
+//______________________________________________________________________
+Double_t AliITSv11Geometry::RFromZpCone(Double_t *GetRmax,Double_t *GetZ,int ip,
+ Double_t tc,Double_t z,Double_t th){
+ // General SSD Outer Cone surface equation Rmax.
+ Double_t tantc = TMath::Tan(tc*TMath::DegToRad());
+ Double_t costc = TMath::Cos(tc*TMath::DegToRad());
+
+ return -tantc*(z-GetZ[ip])+GetRmax[ip]+th/costc;
+}
+//______________________________________________________________________
+Double_t AliITSv11Geometry::RminFromZpCone(TGeoPcon *p,Int_t ip,Double_t tc,Double_t z,
+ Double_t th){
+ // General SSD Inner Cone surface equation Rmin.
+ Double_t tantc = TMath::Tan(tc*TMath::DegToRad());
+ Double_t costc = TMath::Cos(tc*TMath::DegToRad());
+
+ return -tantc*(z-p->GetZ(ip))+p->GetRmin(ip)+th/costc;
+}
+//______________________________________________________________________
+Double_t AliITSv11Geometry::ZFromRmaxpCone(TGeoPcon *p,int ip,Double_t tc,Double_t r,
+ Double_t th){
+ // General SSD Outer cone Surface equation for z.
+ Double_t tantc = TMath::Tan(tc*TMath::DegToRad());
+ Double_t costc = TMath::Cos(tc*TMath::DegToRad());
+
+ return p->GetZ(ip)+(p->GetRmax(ip)+th/costc-r)/tantc;
+}
+//______________________________________________________________________
+Double_t AliITSv11Geometry::ZFromRmaxpCone(Double_t *GetRmax,Double_t *GetZ,int ip,
+ Double_t tc,Double_t r,Double_t th){
+ // General SSD Outer cone Surface equation for z.
+ Double_t tantc = TMath::Tan(tc*TMath::DegToRad());
+ Double_t costc = TMath::Cos(tc*TMath::DegToRad());
+
+ return GetZ[ip]+(GetRmax[ip]+th/costc-r)/tantc;
+}
+//______________________________________________________________________
+Double_t AliITSv11Geometry::ZFromRminpCone(TGeoPcon *p,int ip,Double_t tc,Double_t r,
+ Double_t th){
+ // General SSD Inner cone Surface equation for z.
+ Double_t tantc = TMath::Tan(tc*TMath::DegToRad());
+ Double_t costc = TMath::Cos(tc*TMath::DegToRad());
+
+ return p->GetZ(ip)+(p->GetRmin(ip)+th/costc-r)/tantc;
+}
+//______________________________________________________________________
+void AliITSv11Geometry::RadiusOfCurvature(Double_t rc,Double_t theta0,Double_t z0,
+ Double_t r0,Double_t theta1,Double_t &z1,
+ Double_t &r1){
+ // Given a initial point z0,r0, the initial angle theta0, and the radius
+ // of curvature, returns the point z1, r1 at the angle theta1. Theta
+ // measured from the r axis in the clock wise direction [degrees].
+ Double_t sin0 = TMath::Sin(theta0*TMath::DegToRad());
+ Double_t cos0 = TMath::Cos(theta0*TMath::DegToRad());
+ Double_t sin1 = TMath::Sin(theta1*TMath::DegToRad());
+ Double_t cos1 = TMath::Cos(theta1*TMath::DegToRad());
+
+ z1 = rc*(sin1-sin0)+z0;
+ r1 = rc*(cos1-cos0)+r0;
+ return;
+}
+//______________________________________________________________________
+void AliITSv11Geometry::InsidePoint(TGeoPcon *p,Int_t i1,Int_t i2,Int_t i3,
+ Double_t c,TGeoPcon *q,Int_t j1,Bool_t max){
+ // Given two lines defined by the points i1, i2,i3 in the TGeoPcon
+ // class p that intersect at point p->GetZ(i2) return the point z,r
+ // that is Cthick away in the TGeoPcon class q. If points i1=i2
+ // and max == kTRUE, then p->GetRmin(i1) and p->GetRmax(i2) are used.
+ // if points i2=i3 and max=kTRUE then points p->GetRmax(i2) and
+ // p->GetRmin(i3) are used. If i2=i3 and max=kFALSE, then p->GetRmin(i2)
+ // and p->GetRmax(i3) are used.
+ // Inputs:
+ // TGeoPcon *p Class where points i1, i2, and i3 are taken from
+ // Int_t i1 First point in class p
+ // Int_t i2 Second point in class p
+ // Int_t i3 Third point in class p
+ // Double_t c Distance inside the outer surface/inner suface
+ // that the point j1 is to be computed for.
+ // TGeoPcon *q Pointer to class for results to be put into.
+ // Int_t j1 Point in class q where data is to be stored.
+ // Bool_t max if kTRUE, then a Rmax value is computed,
+ // else a Rmin valule is computed.
+ // Output:
+ // TGeoPcon *q Pointer to class for results to be put into.
+ // Return:
+ // none.
+ Double_t x0,y0,x1,y1,x2,y2,x,y;
+
+ if(max){
+ c = -c; //cout <<"L394 c="<<c<<endl;
+ y0 = p->GetRmax(i1);
+ if(i1==i2) y0 = p->GetRmin(i1); //cout <<"L396 y0="<<y0<<endl;
+ y1 = p->GetRmax(i2); //cout <<"L397 y1="<<y1<<endl;
+ y2 = p->GetRmax(i3); //cout <<"L398 y2="<<y2<<endl;
+ if(i2==i3) y2 = p->GetRmin(i3); //cout <<"L399 y2="<<y2<<endl;
+ }else{ // min
+ y0 = p->GetRmin(i1); //cout <<"L401 y0="<<y0<<endl;
+ y1 = p->GetRmin(i2); //cout <<"L402 y1="<<y1<<endl;
+ y2 = p->GetRmin(i3);
+ if(i2==i3) y2 = p->GetRmax(i3); //cout <<"L404 y2="<<y2<<endl;
+ } // end if
+ x0 = p->GetZ(i1); //cout <<"L406 x0="<<x0<<endl;
+ x1 = p->GetZ(i2); //cout <<"L407 x1="<<x1<<endl;
+ x2 = p->GetZ(i3); //cout <<"L408 x2="<<x2<<endl;
+ //
+ InsidePoint(x0,y0,x1,y1,x2,y2,c,x,y);
+ q->Z(j1) = x;
+ if(max) q->Rmax(j1) = y;
+ else q->Rmin(j1) = y;
+ return;
+}
+//----------------------------------------------------------------------
+void AliITSv11Geometry::InsidePoint(Double_t x0,Double_t y0,Double_t x1,Double_t y1,
+ Double_t x2,Double_t y2,Double_t c,
+ Double_t &x,Double_t &y){
+ // Given two intersecting lines defined by the points (x0,y0), (x1,y1) and
+ // (x1,y1), (x1,y2) {intersecting at (x1,y1)} the point (x,y) a distance
+ // c away is returned such that two lines a distance c away from the
+ // lines defined above intersect at (x,y).
+ // Inputs:
+ // Double_t x0 X point on the first intersecting sets of lines
+ // Double_t y0 Y point on the first intersecting sets of lines
+ // Double_t x1 X point on the first/second intersecting sets of lines
+ // Double_t y1 Y point on the first/second intersecting sets of lines
+ // Double_t x2 X point on the second intersecting sets of lines
+ // Double_t y2 Y point on the second intersecting sets of lines
+ // Double_t c Distance the two sets of lines are from each other
+ // Output:
+ // Double_t x X point for the intersecting sets of parellel lines
+ // Double_t y Y point for the intersecting sets of parellel lines
+ // Return:
+ // none.
+ Double_t dx01,dx12,dy01,dy12,R01,R12,m;
+ dx01 = x0-x1; //cout <<"L410 dx01="<<dx01<<endl;
+ dx12 = x1-x2; //cout <<"L411 dx12="<<dx12<<endl;
+ dy01 = y0-y1; //cout <<"L412 dy01="<<dy01<<endl;
+ dy12 = y1-y2; //cout <<"L413 dy12="<<dy12<<endl;
+ R01 = TMath::Sqrt(dy01*dy01+dx01*dx01); //cout <<"L414 R01="<<R01<<endl;
+ R12 = TMath::Sqrt(dy12*dy12+dx12*dx12); //cout <<"L415 R12="<<R12<<endl;
+ m = dx12*dy01-dy12*dx01;
+ if(m*m<DBL_EPSILON){ // m == n
+ if(dy01==0.0){ // line are =
+ x = x1+c; //cout <<"L419 x="<<x<<endl;
+ y = y1; //cout <<"L420 y="<<y<<endl;
+ return;
+ }else if(dx01==0.0){
+ x = x1;
+ y = y1+c;
+ return;
+ }else{ // dx01!=0 and dy01 !=0.
+ x = x1-0.5*c*R01/dy01; //cout <<"L434 x="<<x<<endl;
+ y = y1+0.5*c*R01/dx01; //cout <<"L435 y="<<y<<endl;
+ } // end if
+ return;
+ } //
+ x = x1-c*(dx12*R01-dx01*R12)/m; //cout <<"L442 x="<<x<<endl;
+ y = y1-c*(dy12*R01-dy01*R12)/m; //cout <<"L443 y="<<y<<endl;
+ //cout <<"=============================================="<<endl;
+ return;
+}
+//----------------------------------------------------------------------
+void AliITSv11Geometry:: printArb8(TGeoArb8 *A){
+ if(GetDebug()){
+ cout << A->GetName() << ":";
+ for(Int_t iii=0;iii<8;iii+=2){
+ cout <<"("<<A->GetVertices()[iii]<<","
+ <<A->GetVertices()[iii+1]<<","<<-A->GetDz()<<")";
+ } // end for iii
+ for(Int_t iii=8;iii<16;iii+=2){
+ cout <<"("<<A->GetVertices()[iii]<<","
+ <<A->GetVertices()[iii+1]<<","<<A->GetDz()<<")";
+ } // end for iii
+ cout << endl;
+ } // end if
+}
+//----------------------------------------------------------------------
+void AliITSv11Geometry:: printPcon(TGeoPcon *A){
+ if(GetDebug()) return;
+ cout << A->GetName() << ": N=" << A->GetNz() << " Phi1=" << A->GetPhi1()
+ << ", Dphi=" << A->GetDphi() << endl;
+ cout << "i\t Z \t Rmin \t Rmax" << endl;
+ for(Int_t iii=0;iii<A->GetNz();iii++){
+ cout << iii << "\t" << A->GetZ(iii) << "\t" << A->GetRmin(iii)
+ << "\t" << A->GetRmax(iii) << endl;
+ } // end for iii
+}
+//----------------------------------------------------------------------
+void AliITSv11Geometry::printTube(TGeoTube *A){
+ if(GetDebug()) return;
+ cout << A->GetName() <<": Rmin="<<A->GetRmin()
+ <<" Rmax=" <<A->GetRmax()<<" Dz="<<A->GetDz()<<endl;
+}
+//----------------------------------------------------------------------
+void AliITSv11Geometry::printTubeSeg(TGeoTubeSeg *A){
+ if(GetDebug()) return;
+ cout << A->GetName() <<": Phi1="<<A->GetPhi1()<<
+ " Phi2="<<A->GetPhi2()<<" Rmin="<<A->GetRmin()
+ <<" Rmax=" <<A->GetRmax()<<" Dz="<<A->GetDz()<<endl;
+}
+//----------------------------------------------------------------------
+void AliITSv11Geometry::printConeSeg(TGeoConeSeg *A){
+ if(GetDebug()) return;
+ cout << A->GetName() <<": Phi1="<<A->GetPhi1()<<
+ " Phi2="<<A->GetPhi2()<<" Rmin1="<<A->GetRmin1()
+ <<" Rmax1=" <<A->GetRmax1()<<" Rmin2="<<A->GetRmin2()
+ <<" Rmax2=" <<A->GetRmax2()<<" Dz="<<A->GetDz()<<endl;
+}
+//----------------------------------------------------------------------
+void AliITSv11Geometry::printBBox(TGeoBBox *A){
+ if(GetDebug()) return;
+ cout << A->GetName() <<": Dx="<<A->GetDX()<<
+ " Dy="<<A->GetDY()<<" Dz="<<A->GetDZ() <<endl;
+}
+
--- /dev/null
+#ifndef ALIITSV11GEOMETRY_H
+#define ALIITSV11GEOMETRY_H
+/* Copyright(c) 1998-1999, ALICE Experiment at CERN, All rights reserved. *
+ * See cxx source for full Copyright notice */
+
+/*
+ $Id$
+ */
+#include <TObject.h>
+class TGeoArb8;
+class TGeoPcon;
+class TGeoTube;
+class TGeoTubeSeg;
+class TGeoConeSeg;
+class TGeoBBox;
+
+class AliITSv11Geometry : public TObject {
+ public:
+ AliITSv11Geometry(){fDebug=kTRUE;};
+ AliITSv11Geometry(Bool_t debug){fDebug=debug;};
+ virtual ~AliITSv11Geometry(){};
+ //
+ void SetDebug(){fDebug=kTRUE;}
+ void SetNoDebug(){fDebug=kFALSE;}
+ static Double_t RmaxFrom2Points(TGeoPcon *p,Int_t i1,Int_t i2,Double_t z);
+ static Double_t RminFrom2Points(TGeoPcon *p,Int_t i1,Int_t i2,Double_t z);
+ static Double_t RFrom2Points(Double_t *p,Double_t *Z,Int_t i1,Int_t i2,
+ Double_t z);
+ static Double_t Zfrom2MinPoints(TGeoPcon *p,Int_t i1,Int_t i2,Double_t r);
+ static Double_t Zfrom2MaxPoints(TGeoPcon *p,Int_t i1,Int_t i2,Double_t r);
+ static Double_t Zfrom2Points(Double_t *Z,Double_t *p,Int_t i1,Int_t i2,
+ Double_t r);
+ static Double_t RmaxFromZpCone(TGeoPcon *p,int ip,Double_t tc,Double_t z,
+ Double_t th=0.0);
+ static Double_t RmaxFromZpCone(TGeoPcon *p,Double_t tc,Double_t z,
+ Double_t th=0.0){
+ return RmaxFromZpCone(p,4,tc,z,th);};
+ static Double_t RFromZpCone(Double_t *Rmax,Double_t *Z,int ip,Double_t tc,
+ Double_t z,Double_t th=0.0);
+ static Double_t RmaxFromZpCone(Double_t *Rmax,Double_t *Z,Double_t tc,
+ Double_t z,Double_t th=0.0){
+ return RFromZpCone(Rmax,Z,4,tc,z,th);};
+ static Double_t RminFromZpCone(TGeoPcon *p,Int_t ip,Double_t tc,Double_t z,
+ Double_t th=0.0);
+ static Double_t RminFromZpCone(TGeoPcon *p,Double_t tc,Double_t z,
+ Double_t th=0.0){
+ return RminFromZpCone(p,3,tc,z,th);};
+ static Double_t RminFromZpCone(Double_t *Rmin,Double_t *Z,Double_t tc,
+ Double_t z,Double_t th=0.0){
+ return RFromZpCone(Rmin,Z,3,tc,z,th);};
+ static Double_t ZFromRmaxpCone(TGeoPcon *p,int ip,Double_t tc,Double_t r,
+ Double_t th=0.0);
+ static Double_t ZFromRmaxpCone(TGeoPcon *p,Double_t tc,Double_t r,
+ Double_t th=0.0)
+ {return ZFromRmaxpCone(p,4,tc,r,th);};
+ static Double_t ZFromRmaxpCone(Double_t *GetRmax,Double_t *GetZ,Int_t ip,
+ Double_t tc,Double_t r,Double_t th=0.0);
+ static Double_t ZFromRmaxpCone(Double_t *GetRmax,Double_t *GetZ,
+ Double_t tc,Double_t r,Double_t th=0.0){
+ return ZFromRmaxpCone(GetRmax,GetZ,4,tc,r,th);};
+ static Double_t ZFromRminpCone(TGeoPcon *p,int ip,Double_t tc,Double_t r,
+ Double_t th=0.0);
+ static Double_t ZFromRminpCone(TGeoPcon *p,Double_t tc,Double_t r,
+ Double_t th=0.0)
+ {return ZFromRminpCone(p,3,tc,r,th);};
+ static void InsidePoint(TGeoPcon *p,Int_t i1,Int_t i2,Int_t i3,
+ Double_t Cthick,TGeoPcon *q,Int_t j1,Bool_t max);
+ static void InsidePoint(Double_t x0,Double_t y0,Double_t x1,Double_t y1,
+ Double_t x2,Double_t y2,Double_t c,
+ Double_t &x,Double_t &y);
+ static void RadiusOfCurvature(Double_t rc,Double_t theta0,Double_t z0,
+ Double_t r0,Double_t theta1,Double_t &z1,
+ Double_t &r1);
+ void printArb8(TGeoArb8 *A);
+ void printPcon(TGeoPcon *A);
+ void printTube(TGeoTube *A);
+ void printTubeSeg(TGeoTubeSeg *A);
+ void printConeSeg(TGeoConeSeg *A);
+ void printBBox(TGeoBBox *A);
+ Bool_t GetDebug(){return fDebug;}
+
+ private:
+ Bool_t fDebug; //! Debug flag
+ ClassDef(AliITSv11Geometry,1) // Base class for ITS v11 geometry
+};
+
+
+// Units, Convert from k?? to cm,degree,GeV,seconds,
+const Double_t kmm = 0.10; // Convert mm to TGeom's cm.
+const Double_t kcm = 1.00; // Convert cv to TGeom's cm.
+const Double_t kDegree = 1.0; // Convert degrees to TGeom's degrees
+const Double_t kRadian = TMath::DegToRad(); // conver to Radians
+
+#endif
--- /dev/null
+/**************************************************************************
+ * 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. *
+ **************************************************************************/
+
+/* $Id$ */
+#include <stdio.h>
+#include <stdlib.h>
+// General Root includes
+#include <Riostream.h>
+#include <TMath.h>
+#include <float.h>
+#include <TFile.h> // only required for Tracking function?
+#include <TObjArray.h>
+#include <TClonesArray.h>
+#include <TLorentzVector.h>
+#include <TObjString.h>
+// Root Geometry includes
+#include <TGeoManager.h>
+#include <TGeoVolume.h>
+#include <TGeoPcon.h>
+#include <TGeoCone.h>
+#include <TGeoTube.h> // contaings TGeoTubeSeg
+#include <TGeoArb8.h>
+#include <TGeoCompositeShape.h>
+#include <TGeoMatrix.h>
+#include <TGeoNode.h>
+#include <TGeoMaterial.h>
+#include <TGeoMedium.h>
+#include "AliITSBaseGeometry.h"
+#include "AliITSv11GeometrySupport.h"
+
+ClassImp(AliITSv11GeometrySupport)
+
+#define SQ(A) (A)*(A)
+
+//______________________________________________________________________
+void AliITSv11GeometrySupport::SPDCone(TGeoVolume *Moth){
+ // Define the detail SPD support cone geometry.
+ // Inputs:
+ // none.
+ // Outputs:
+ // none.
+ // Return:
+ // none.
+
+ SPDThermalSheald(Moth);
+}
+//______________________________________________________________________
+void AliITSv11GeometrySupport::SPDThermalSheald(TGeoVolume *Moth){
+ // Define the detail SPD Thermal Sheld geometry.
+ // Inputs:
+ // none.
+ // Outputs:
+ // none.
+ // Return:
+ // none.
+ // From ALICE-Thermal Screen (SPD) "Cylinder" file thermal-screen2_a3.ps
+ // Volumes A1,A2,A2,Ah1,Ah2,Ah3, and B1,B2,B3,Bh1,Bh2,Bh3;
+ // "CONE TRANSITION" file thermal-screen1_a3.ps Volumes C1,C2,C3,Ch1,Ch2,
+ // Ch3; "FLANGE" file thermal-screen4_a3.ps Volumes D,Ds,Dw,Dws; and
+ // "HALF ASSEMBLY" file thermal-screen3_a3.ps. This object, both halfs,
+ // are incased inside of a single minimum sized mother volume called M,
+ // which is a union of two parts M1 and 4 copies of M2.
+ const Double_t TSCarbonFiberThA = 0.03*kmm; //
+ //const Double_t TSCarbonFiberThB = 0.10*kmm; //
+ const Double_t TSCLengthB = 50.0*kmm; //
+ const Double_t TSCLengthA = 900.0*kmm-2.0*TSCLengthB; //
+ const Double_t TSCLengthC = 290.0*kmm; //
+ const Double_t TSCLengthD = 15.0*kmm; //
+ const Double_t TSCAngle = 36.0*kDegree;//Rep. angle of cent. accordin
+ const Double_t TSCRoutA = 99.255*kmm; // Outer radii
+ const Double_t TSCRinA = 81.475*kmm; // Iner radii
+ const Double_t TSCRoutB = 99.955*kmm; // Outer radii
+ const Double_t TSCRinB = 80.775*kmm; // Iner radii
+ const Double_t TSCRoutCp = 390.0*kmm; // Outer radii
+ const Double_t TSCRinCp = 373.0*kmm; // Iner radii
+ Double_t TSCRoutC,TSCRinC; // values need to be calculated
+ const Double_t TSCRwingD = 492.5*kmm; // Outer radii
+ const Double_t TSCRoutD = 0.5*840.*kmm;// Outer radii
+ const Double_t TSCRinD = 373.0*kmm; // Iner radii
+ const Double_t TSCAngleDD = 60.*kmm/TSCRwingD/kRadian;// angular wing
+ // width of fill material
+ const Double_t TSCAngleDDs = (60.*kmm-2.*TSCarbonFiberThA)/
+ TSCRwingD/kRadian;
+ const Double_t TSCAngleD0 = 45.*kDegree;//Strting angle of wing
+ const Double_t TSCoutSA = 24.372*kmm; // The other one Calculated
+ const Double_t TSCinLA = 31.674*kmm; // The ohter one Calculated
+ const Double_t TSCoutSB = 24.596*kmm; // The other one Calculated
+ const Double_t TSCinLB = 31.453*kmm; // The ohter one Calculated
+ const Double_t TSCoutSC = 148.831*kmm;// The other one Calculated
+ const Double_t TSCinLC = 90.915*kmm; // The ohter one Calculated
+ Int_t i,k;
+ Double_t th;
+ Double_t xo[7],yo[7],xi[7],yi[7];
+ Double_t xbo[7],ybo[7],xbi[7],ybi[7];
+ Double_t xco[7],yco[7],xci[7],yci[7];
+ TGeoArb8 *A1,*A2,*A3,*Ah1,*Ah2,*Ah3,*B1,*B2,*B3,*Bh1,*Bh2,*Bh3;
+ TGeoArb8 *C1,*C2,*C3,*Ch1,*Ch2,*Ch3;
+ TGeoTube *D,*Ds;
+ TGeoTubeSeg *Dw,*Dws;
+ TGeoCompositeShape *M;
+ TGeoRotation *rot;
+ TGeoTranslation *tranb,*tranbm,*tranc;
+ TGeoTranslation *tranITSspdShealdVVt0;
+ TGeoCombiTrans *rotITSspdShealdVVt1,*rotITSspdShealdVVt2;
+ TGeoCombiTrans *rotITSspdShealdVVt3;
+ TGeoMedium *SPDcf = 0; // SPD support cone Carbon Fiber materal number.
+ TGeoMedium *SPDfs = 0; // SPD support cone inserto stesalite 4411w.
+ TGeoMedium *SPDfo = 0; // SPD support cone foam, Rohacell 50A.
+ TGeoMedium *SPDss = 0; // SPD support cone screw material,Stainless steal
+ TGeoMedium *SPDair = 0; // SPD support cone Air
+ //TGeoMedium *SPDal = 0; // SPD support cone SDD mounting bracket Al
+
+ TSCRoutC = TMath::Sqrt(TSCRoutCp*TSCRoutCp-0.25*TSCoutSC*TSCoutSC);
+ TSCRinC = TMath::Sqrt(TSCRinCp *TSCRinCp -0.25*TSCinLC *TSCinLC );
+ A1 = new TGeoArb8("ITS SPD Therm Screen Clyinder A1",0.5*TSCLengthA);
+ A2 = new TGeoArb8("ITS SPD Therm Screen Clyinder A2",0.5*TSCLengthA);
+ A3 = new TGeoArb8("ITS SPD Therm Screen Clyinder A3",0.5*TSCLengthA);
+ Ah1 = new TGeoArb8("ITS SPD Therm Screen Cylinder Ah1",0.5*TSCLengthA);
+ Ah2 = new TGeoArb8("ITS SPD Therm Screen Cylinder Ah2",0.5*TSCLengthA);
+ Ah3 = new TGeoArb8("ITS SPD Therm Screen Cylinder Ah3",0.5*TSCLengthA);
+ B1 = new TGeoArb8("ITS SPD Therm Screen Clyinder B1",0.5*TSCLengthB);
+ B2 = new TGeoArb8("ITS SPD Therm Screen Clyinder B2",0.5*TSCLengthB);
+ B3 = new TGeoArb8("ITS SPD Therm Screen Clyinder B3",0.5*TSCLengthB);
+ Bh1 = new TGeoArb8("ITS SPD Therm Screen Cylinder Bh1",0.5*TSCLengthB);
+ Bh2 = new TGeoArb8("ITS SPD Therm Screen Cylinder Bh2",0.5*TSCLengthB);
+ Bh3 = new TGeoArb8("ITS SPD Therm Screen Cylinder Bh3",0.5*TSCLengthB);
+ C1 = new TGeoArb8("ITS SPD Therm Screen Clyinder C1",0.5*TSCLengthC);
+ C2 = new TGeoArb8("ITS SPD Therm Screen Clyinder C2",0.5*TSCLengthC);
+ C3 = new TGeoArb8("ITS SPD Therm Screen Clyinder C3",0.5*TSCLengthC);
+ Ch1 = new TGeoArb8("ITS SPD Therm Screen Cylinder Ch1",0.5*TSCLengthC);
+ Ch2 = new TGeoArb8("ITS SPD Therm Screen Cylinder Ch2",0.5*TSCLengthC);
+ Ch3 = new TGeoArb8("ITS SPD Therm Screen Cylinder Ch3",0.5*TSCLengthC);
+ D = new TGeoTube("ITS SPD Therm Screen Flange D",TSCRinD,TSCRoutD,
+ 0.5*TSCLengthD);
+ Ds = new TGeoTube("ITS SPD Therm Screen Flange fill Ds",
+ TSCRinD+TSCarbonFiberThA,TSCRoutD-TSCarbonFiberThA,
+ 0.5*TSCLengthD);
+ printTube(D);
+ printTube(Ds);
+ Dw = new TGeoTubeSeg("ITS SPD Therm Screen Flange Wing Dw",
+ TSCRoutD,TSCRwingD ,0.5*TSCLengthD,
+ TSCAngleD0-0.5*TSCAngleDD,TSCAngleD0+0.5*TSCAngleDD);
+ Dws = new TGeoTubeSeg("ITS SPD Therm Screen Flange Wing Fill Ds",
+ TSCRoutD,TSCRwingD-TSCarbonFiberThA,
+ 0.5*TSCLengthD,TSCAngleD0-0.5*TSCAngleDDs,
+ TSCAngleD0+0.5*TSCAngleDDs);
+ printTubeSeg(Dw);
+ printTubeSeg(Dws);
+ k = 0;
+ for(i=-1;i<2;i++){
+ th = ((Double_t)(i+1))*TSCAngle*kRadian;
+ xo[k] = TSCRoutA*TMath::Sin(th) - 0.5*TSCoutSA*TMath::Cos(th);
+ yo[k] = TSCRoutA*TMath::Cos(th) + 0.5*TSCoutSA*TMath::Sin(th);
+ xi[k] = TSCRinA *TMath::Sin(th) - 0.5*TSCinLA *TMath::Cos(th);
+ yi[k] = TSCRinA *TMath::Cos(th) + 0.5*TSCinLA *TMath::Sin(th);
+ xbo[k] = TSCRoutB*TMath::Sin(th) - 0.5*TSCoutSB*TMath::Cos(th);
+ ybo[k] = TSCRoutB*TMath::Cos(th) + 0.5*TSCoutSB*TMath::Sin(th);
+ xbi[k] = TSCRinB *TMath::Sin(th) - 0.5*TSCinLB *TMath::Cos(th);
+ ybi[k] = TSCRinB *TMath::Cos(th) + 0.5*TSCinLB *TMath::Sin(th);
+ xco[k] = TSCRoutC*TMath::Sin(th) - 0.5*TSCoutSC*TMath::Cos(th);
+ yco[k] = TSCRoutC*TMath::Cos(th) + 0.5*TSCoutSC*TMath::Sin(th);
+ xci[k] = TSCRinC *TMath::Sin(th) - 0.5*TSCinLC *TMath::Cos(th);
+ yci[k] = TSCRinC *TMath::Cos(th) + 0.5*TSCinLC *TMath::Sin(th);
+ k++;
+ xo[k] = TSCRoutA*TMath::Sin(th) + 0.5*TSCoutSA*TMath::Cos(th);
+ yo[k] = TSCRoutA*TMath::Cos(th) - 0.5*TSCoutSA*TMath::Sin(th);
+ xi[k] = TSCRinA *TMath::Sin(th) + 0.5*TSCinLA *TMath::Cos(th);
+ yi[k] = TSCRinA *TMath::Cos(th) - 0.5*TSCinLA *TMath::Sin(th);
+ xbo[k] = TSCRoutB*TMath::Sin(th) + 0.5*TSCoutSB*TMath::Cos(th);
+ ybo[k] = TSCRoutB*TMath::Cos(th) - 0.5*TSCoutSB*TMath::Sin(th);
+ xbi[k] = TSCRinB *TMath::Sin(th) + 0.5*TSCinLB *TMath::Cos(th);
+ ybi[k] = TSCRinB *TMath::Cos(th) - 0.5*TSCinLB *TMath::Sin(th);
+ xco[k] = TSCRoutC*TMath::Sin(th) + 0.5*TSCoutSC*TMath::Cos(th);
+ yco[k] = TSCRoutC*TMath::Cos(th) - 0.5*TSCoutSC*TMath::Sin(th);
+ xci[k] = TSCRinC *TMath::Sin(th) + 0.5*TSCinLC *TMath::Cos(th);
+ yci[k] = TSCRinC *TMath::Cos(th) - 0.5*TSCinLC *TMath::Sin(th);
+ k++;
+ } // end for i
+ xo[6] = xo[5];
+ yo[6] = 0.0;
+ xi[6] = xi[5];
+ yi[6] = 0.0;
+ xbo[6] = xbo[5];
+ ybo[6] = 0.0;
+ xbi[6] = xbi[5];
+ ybi[6] = 0.0;
+ xco[6] = xco[5];
+ yco[6] = 0.0;
+ xci[6] = xci[5];
+ yci[6] = 0.0;
+ if(GetDebug()){
+ cout.precision(4);
+ cout.width(7);
+ cout <<"i \t xo yo \t xi yi \t xbo ybo \t xbi ybi "
+ "\t xco yco \t xci yxi"<<endl;
+ for(i=0;i<7;i++){
+ cout << i <<"\t"<<xo[i]<<","<<yo[i];
+ cout <<"\t"<<xi[i]<<","<<yi[i];
+ cout <<"\t"<<xbo[i]<<","<<ybo[i];
+ cout <<"\t"<<xbi[i]<<","<<ybi[i];
+ cout <<"\t"<<xco[i]<<","<<yco[i];
+ cout <<"\t"<<xci[i]<<","<<yci[i];
+ cout<<endl;}
+ } // end if GetDebug()
+ //+++++++++++++++++++++++++
+ A1->SetVertex(0,xo[0],yo[0]);
+ A1->SetVertex(1,xo[1],yo[1]);
+ A1->SetVertex(2,xi[1],yi[1]);
+ A1->SetVertex(3,xi[0],yi[0]);
+ //
+ A2->SetVertex(0,xo[1],yo[1]);
+ A2->SetVertex(1,xo[2],yo[2]);
+ A2->SetVertex(2,xi[2],yi[2]);
+ A2->SetVertex(3,xi[1],yi[1]);
+ //
+ A3->SetVertex(0,xo[5],yo[5]);
+ A3->SetVertex(1,xo[6],yo[6]);
+ A3->SetVertex(2,xi[6],yi[6]);
+ A3->SetVertex(3,xi[5],yi[5]);
+ //--------------------------
+ B1->SetVertex(0,xbo[0],ybo[0]);
+ B1->SetVertex(1,xbo[1],ybo[1]);
+ B1->SetVertex(2,xbi[1],ybi[1]);
+ B1->SetVertex(3,xbi[0],ybi[0]);
+ //
+ B2->SetVertex(0,xbo[1],ybo[1]);
+ B2->SetVertex(1,xbo[2],ybo[2]);
+ B2->SetVertex(2,xbi[2],ybi[2]);
+ B2->SetVertex(3,xbi[1],ybi[1]);
+ //
+ B3->SetVertex(0,xbo[5],ybo[5]);
+ B3->SetVertex(1,xbo[6],ybo[6]);
+ B3->SetVertex(2,xbi[6],ybi[6]);
+ B3->SetVertex(3,xbi[5],ybi[5]);
+ //--------------------------
+ C1->SetVertex(0,xco[0],yco[0]);
+ C1->SetVertex(1,xco[1],yco[1]);
+ C1->SetVertex(2,xci[1],yci[1]);
+ C1->SetVertex(3,xci[0],yci[0]);
+ //
+ C2->SetVertex(0,xco[1],yco[1]);
+ C2->SetVertex(1,xco[2],yco[2]);
+ C2->SetVertex(2,xci[2],yci[2]);
+ C2->SetVertex(3,xci[1],yci[1]);
+ //
+ C3->SetVertex(0,xco[5],yco[5]);
+ C3->SetVertex(1,xco[6],yco[6]);
+ C3->SetVertex(2,xci[6],yci[6]);
+ C3->SetVertex(3,xci[5],yci[5]);
+ // Defining the hole, filled with air
+ Double_t p1,c1,x,y,x7[3],y7[3];
+ p1 = (xo[0]-xi[0])/(yo[0]-yi[0]);
+ c1 = xo[0]+0.5*TSCarbonFiberThA*TMath::Sqrt(SQ(xo[0]-xi[0])+
+ SQ(yo[0]-yi[0]))/(xo[0]-xi[0]);
+ y = TSCRoutA-2.*TSCarbonFiberThA;
+ x = p1*(y-yo[0])+c1;
+ Ah1->SetVertex(0,x,y);
+ Bh1->SetVertex(0,x,y);
+ Ch1->SetVertex(4,x,y);
+ y = TSCRinA+TSCarbonFiberThA;
+ x = p1*(y-yo[0])+c1;
+ Ah1->SetVertex(3,x,y);
+ Bh1->SetVertex(3,x,y);
+ x7[0] = x; y7[0] = y; // vortexing done after last point
+ //Ch1->SetVertex(7,x,y);
+ p1 = (xo[1]-xi[1])/(yo[1]-yi[1]);
+ c1 = xo[1]-0.5*TSCarbonFiberThA*TMath::Sqrt(SQ(xo[1]-xi[1])+
+ SQ(yo[1]-yi[1]))/(xo[1]-xi[1]);
+ y = TSCRoutA-2.*TSCarbonFiberThA;
+ x = p1*(y-yo[1])+c1;
+ Ah1->SetVertex(1,x,y);
+ Bh1->SetVertex(1,x,y);
+ Ch1->SetVertex(5,x,y);
+ y = TSCRinA+TSCarbonFiberThA;
+ x = p1*(y-yo[1])+c1;
+ Ah1->SetVertex(2,x,y);
+ Bh1->SetVertex(2,x,y);
+ Ch1->SetVertex(6,x,y);
+ //
+ // The easist way to get the points for the hole in volume A2 is to
+ // rotate it to the Y axis where the y coordinates are easier to know
+ // and then rotate it back.
+ Double_t xp,yp,xa,ya,xb,yb;
+ th = 0.5*TSCAngle*kRadian;
+ xa = TMath::Cos(th)*xo[1]-TMath::Sin(th)*yo[1];
+ ya = TMath::Sin(th)*xo[1]+TMath::Cos(th)*yo[1];
+ xb = TMath::Cos(th)*xi[1]-TMath::Sin(th)*yi[1];
+ yb = TMath::Sin(th)*xi[1]+TMath::Cos(th)*yi[1];
+ p1 = (xa-xb)/(ya-yb);
+ c1 = xa+0.5*TSCarbonFiberThA*TMath::Sqrt(SQ(xa-xb)+SQ(ya-yb))/(xa-xb);
+ y = ya-TSCarbonFiberThA;
+ x = p1*(y-ya)+c1;
+ xp = TMath::Cos(-th)*x-TMath::Sin(-th)*y;
+ yp = TMath::Sin(-th)*x+TMath::Cos(-th)*y;
+ Ah2->SetVertex(0,xp,yp);
+ Bh2->SetVertex(0,xp,yp);
+ Ch2->SetVertex(4,xp,yp);
+ y = yb+2.0*TSCarbonFiberThA;
+ x = p1*(y-ya)+c1;
+ xp = TMath::Cos(-th)*x-TMath::Sin(-th)*y;
+ yp = TMath::Sin(-th)*x+TMath::Cos(-th)*y;
+ Ah2->SetVertex(3,xp,yp);
+ Bh2->SetVertex(3,xp,yp);
+ x7[1] = x; y7[1] = y; // vortexing done after last point
+ //Ch2->SetVertex(7,xp,yp);
+ xa = TMath::Cos(th)*xo[2]-TMath::Sin(th)*yo[2];
+ ya = TMath::Sin(th)*xo[2]+TMath::Cos(th)*yo[2];
+ xb = TMath::Cos(th)*xi[2]-TMath::Sin(th)*yi[2];
+ yb = TMath::Sin(th)*xi[2]+TMath::Cos(th)*yi[2];
+ p1 = (xa-xb)/(ya-yb);
+ c1 = xa-0.5*TSCarbonFiberThA*TMath::Sqrt(SQ(xa-xb)+SQ(ya-yb))/(xa-xb);
+ y = ya-TSCarbonFiberThA;
+ x = p1*(y-ya)+c1;
+ xp = TMath::Cos(-th)*x-TMath::Sin(-th)*y;
+ yp = TMath::Sin(-th)*x+TMath::Cos(-th)*y;
+ Ah2->SetVertex(1,xp,yp);
+ Bh2->SetVertex(1,xp,yp);
+ Ch2->SetVertex(5,xp,yp);
+ y = yb+2.0*TSCarbonFiberThA;
+ x = p1*(y-ya)+c1;
+ xp = TMath::Cos(-th)*x-TMath::Sin(-th)*y;
+ yp = TMath::Sin(-th)*x+TMath::Cos(-th)*y;
+ Ah2->SetVertex(2,xp,yp);
+ Bh2->SetVertex(2,xp,yp);
+ Ch2->SetVertex(6,xp,yp);
+ //
+ p1 = (yo[5]-yi[5])/(xo[5]-xi[5]);
+ c1 = yo[5]+0.5*TSCarbonFiberThA*TMath::Sqrt(SQ(yo[5]-yi[5])+
+ SQ(xo[5]-xi[5]))/(yo[5]-yi[5]);
+ x = xo[5]-TSCarbonFiberThA;
+ y = p1*(x-xo[5])+c1;
+ Ah3->SetVertex(0,x,y);
+ Bh3->SetVertex(0,x,y);
+ Ch3->SetVertex(4,x,y);
+ x = xi[5]+2.0*TSCarbonFiberThA;
+ y = p1*(x-xo[5])+c1;
+ Ah3->SetVertex(3,x,y);
+ Bh3->SetVertex(3,x,y);
+ x7[2] = x; y7[2] = y; // vortexing done after last point
+ //Ch3->SetVertex(7,x,y);
+ y = 2.0*TSCarbonFiberThA;
+ x = xo[5]-TSCarbonFiberThA;
+ Ah3->SetVertex(1,x,y);
+ Bh3->SetVertex(1,x,y);
+ Ch3->SetVertex(5,x,y);
+ y = 2.0*TSCarbonFiberThA;
+ x = xi[5]+2.0*TSCarbonFiberThA;
+ Ah3->SetVertex(2,x,y);
+ Bh3->SetVertex(2,x,y);
+ Ch3->SetVertex(6,x,y);
+ //
+ for(i=0;i<4;i++){ // define points at +dz
+ A1->SetVertex(i+4,(A1->GetVertices())[2*i],(A1->GetVertices())[1+2*i]);
+ A2->SetVertex(i+4,(A2->GetVertices())[2*i],(A2->GetVertices())[1+2*i]);
+ A3->SetVertex(i+4,(A3->GetVertices())[2*i],(A3->GetVertices())[1+2*i]);
+ //
+ B1->SetVertex(i+4,(B1->GetVertices())[2*i],(B1->GetVertices())[1+2*i]);
+ B2->SetVertex(i+4,(B2->GetVertices())[2*i],(B2->GetVertices())[1+2*i]);
+ B3->SetVertex(i+4,(B3->GetVertices())[2*i],(B3->GetVertices())[1+2*i]);
+ // C's are a cone which must match up with B's.
+ C1->SetVertex(i+4,(B1->GetVertices())[2*i],(B1->GetVertices())[1+2*i]);
+ C2->SetVertex(i+4,(B2->GetVertices())[2*i],(B2->GetVertices())[1+2*i]);
+ C3->SetVertex(i+4,(B3->GetVertices())[2*i],(B3->GetVertices())[1+2*i]);
+ //
+ Ah1->SetVertex(i+4,(Ah1->GetVertices())[2*i],
+ (Ah1->GetVertices())[1+2*i]);
+ Ah2->SetVertex(i+4,(Ah2->GetVertices())[2*i],
+ (Ah2->GetVertices())[1+2*i]);
+ Ah3->SetVertex(i+4,(Ah3->GetVertices())[2*i],
+ (Ah3->GetVertices())[1+2*i]);
+ //
+ Bh1->SetVertex(i+4,(Bh1->GetVertices())[2*i],
+ (Bh1->GetVertices())[1+2*i]);
+ Bh2->SetVertex(i+4,(Bh2->GetVertices())[2*i],
+ (Bh2->GetVertices())[1+2*i]);
+ Bh3->SetVertex(i+4,(Bh3->GetVertices())[2*i],
+ (Bh3->GetVertices())[1+2*i]);
+ } // end for
+ //
+ p1 = (xco[0]-xci[0])/(yco[0]-yci[0]);
+ c1 = xco[0]+0.5*TSCarbonFiberThA*TMath::Sqrt(SQ(xco[0]-xci[0])+
+ SQ(yco[0]-yci[0]))/(xco[0]-xci[0]);
+ y = TSCRoutC-2.*TSCarbonFiberThA;
+ x = p1*(y-yco[0])+c1;
+ Ch1->SetVertex(0,x,y);
+ y = TSCRinC+TSCarbonFiberThA;
+ x = p1*(y-yci[0])+c1;
+ Ch1->SetVertex(2,x,y);
+ p1 = (xco[1]-xci[1])/(yco[1]-yci[1]);
+ c1 = xco[1]-0.5*TSCarbonFiberThA*TMath::Sqrt(SQ(xco[1]-xci[1])+
+ SQ(yco[1]-yci[1]))/(xco[1]-xci[1]);
+ y = TSCRoutC-2.*TSCarbonFiberThA;
+ x = p1*(y-yco[1])+c1;
+ Ch1->SetVertex(1,x,y);
+ y = TSCRinC+TSCarbonFiberThA;
+ x = p1*(y-yci[1])+c1;
+ Ch1->SetVertex(3,x,y);
+ //
+ th = 0.5*TSCAngle*kRadian;
+ xa = TMath::Cos(th)*xco[1]-TMath::Sin(th)*yco[1];
+ ya = TMath::Sin(th)*xco[1]+TMath::Cos(th)*yco[1];
+ xb = TMath::Cos(th)*xci[1]-TMath::Sin(th)*yci[1];
+ yb = TMath::Sin(th)*xci[1]+TMath::Cos(th)*yci[1];
+ p1 = (xa-xb)/(ya-yb);
+ c1 = xa+0.5*TSCarbonFiberThA*TMath::Sqrt(SQ(xa-xb)+SQ(ya-yb))/(xa-xb);
+ y = ya-TSCarbonFiberThA;
+ x = p1*(y-ya)+c1;
+ xp = TMath::Cos(-th)*x-TMath::Sin(-th)*y;
+ yp = TMath::Sin(-th)*x+TMath::Cos(-th)*y;
+ yp = ya-TSCarbonFiberThA;
+ xp = p1*(y-ya)+c1;
+ Ch2->SetVertex(0,xp,yp);
+ y = yb+2.0*TSCarbonFiberThA;
+ x = p1*(y-ya)+c1;
+ xp = TMath::Cos(-th)*x-TMath::Sin(-th)*y;
+ yp = TMath::Sin(-th)*x+TMath::Cos(-th)*y;
+ Ch2->SetVertex(2,xp,yp);
+ xa = TMath::Cos(th)*xco[2]-TMath::Sin(th)*yco[2];
+ ya = TMath::Sin(th)*xco[2]+TMath::Cos(th)*yco[2];
+ xb = TMath::Cos(th)*xci[2]-TMath::Sin(th)*yci[2];
+ yb = TMath::Sin(th)*xci[2]+TMath::Cos(th)*yci[2];
+ p1 = (xa-xb)/(ya-yb);
+ c1 = xa-0.5*TSCarbonFiberThA*TMath::Sqrt(SQ(xa-xb)+SQ(ya-yb))/(xa-xb);
+ y = ya-TSCarbonFiberThA;
+ x = p1*(y-ya)+c1;
+ xp = TMath::Cos(-th)*x-TMath::Sin(-th)*y;
+ yp = TMath::Sin(-th)*x+TMath::Cos(-th)*y;
+ Ch2->SetVertex(1,xp,yp);
+ y = yb+2.0*TSCarbonFiberThA;
+ x = p1*(y-ya)+c1;
+ xp = TMath::Cos(-th)*x-TMath::Sin(-th)*y;
+ yp = TMath::Sin(-th)*x+TMath::Cos(-th)*y;
+ Ch2->SetVertex(3,xp,yp);
+ //
+ p1 = (yco[5]-yci[5])/(xco[5]-xci[5]);
+ c1 = yco[5]+0.5*TSCarbonFiberThA*TMath::Sqrt(SQ(yco[5]-yci[5])+
+ SQ(xco[5]-xci[5]))/(yco[5]-yci[5]);
+ x = xco[5]-TSCarbonFiberThA;
+ y = p1*(x-xco[5])+c1;
+ Ch3->SetVertex(0,x,y);
+ x = xci[5]+2.0*TSCarbonFiberThA;
+ y = p1*(x-xci[5])+c1;
+ Ch3->SetVertex(2,x,y);
+ y = 2.0*TSCarbonFiberThA;
+ x = xco[5]-TSCarbonFiberThA;
+ Ch3->SetVertex(1,x,y);
+ y = 2.0*TSCarbonFiberThA;
+ x = xci[5]+2.0*TSCarbonFiberThA;
+ Ch3->SetVertex(3,x,y);
+ Ch1->SetVertex(7,x7[0],y7[0]); // 7th point most be done last ???
+ Ch2->SetVertex(7,x7[1],y7[1]); // 7th point most be done last ???
+ Ch3->SetVertex(7,x7[2],y7[2]); // 7th point most be done last ???
+ printArb8(A1);
+ printArb8(Ah1);
+ printArb8(A2);
+ printArb8(Ah2);
+ printArb8(A3);
+ printArb8(Ah3);
+ printArb8(B1);
+ printArb8(Bh1);
+ printArb8(B2);
+ printArb8(Bh2);
+ printArb8(B3);
+ printArb8(Bh3);
+ printArb8(C1);
+ printArb8(Ch1);
+ printArb8(C2);
+ printArb8(Ch2);
+ printArb8(C3);
+ printArb8(Ch3);
+ //
+ // Define Minimal volume to inclose this SPD Thermal Sheald.
+ TGeoPcon *M1 = new TGeoPcon("ITSspdShealdVV",0.0,360.0,9);
+ M1->Z(0) = 0.5*TSCLengthA+TSCLengthB;
+ M1->Rmin(0) = TSCRinB;
+ x = B1->GetVertices()[0]; // [0][0]
+ y = B1->GetVertices()[1]; // [0][1]
+ M1->Rmax(0) = TMath::Sqrt(x*x+y*y);
+ M1->Z(1) = M1->GetZ(0)-TSCLengthB;
+ M1->Rmin(1) = M1->GetRmin(0);
+ M1->Rmax(1) = M1->GetRmax(0);
+ M1->Z(2) = M1->GetZ(1);
+ M1->Rmin(2) = TSCRinA;
+ x = A1->GetVertices()[0]; // [0]0]
+ y = A1->GetVertices()[1]; // [0][1]
+ M1->Rmax(2) = TMath::Sqrt(x*x+y*y);
+ M1->Z(3) = -(M1->GetZ(0)-TSCLengthB);
+ M1->Rmin(3) = M1->GetRmin(2);
+ M1->Rmax(3) = M1->GetRmax(2);
+ M1->Z(4) = M1->GetZ(3);
+ M1->Rmin(4) = M1->GetRmin(1);
+ M1->Rmax(4) = M1->GetRmax(1);
+ M1->Z(5) = -(M1->GetZ(0));
+ M1->Rmin(5) = M1->GetRmin(0);
+ M1->Rmax(5) = M1->GetRmax(0);
+ M1->Z(6) = M1->GetZ(5) - TSCLengthC;
+ M1->Rmin(6) = TSCRinC;
+ x = C1->GetVertices()[0]; // [0][0]
+ y = C1->GetVertices()[1]; // [0][1]
+ M1->Rmax(6) = TMath::Sqrt(x*x+y*y);
+ M1->Z(7) = M1->GetZ(6);
+ M1->Rmin(7) = D->GetRmin();
+ M1->Rmax(7) = D->GetRmax();
+ M1->Z(8) = M1->Z(7) - TSCLengthD;
+ M1->Rmin(8) = M1->GetRmin(7);
+ M1->Rmax(8) = M1->GetRmax(7);
+ TGeoTubeSeg *M2 = new TGeoTubeSeg("ITSspdShealdWingVV",
+ M1->GetRmax(8),Dw->GetRmax(),Dw->GetDz(),Dw->GetPhi1(),Dw->GetPhi2());
+ printTubeSeg(M2);
+ //
+ x = 0.5*(M1->GetZ(8) + M1->GetZ(7));
+ tranITSspdShealdVVt0 = new TGeoTranslation("ITSspdShealdVVt0",0.0,0.0,x);
+ tranITSspdShealdVVt0->RegisterYourself();
+ TGeoRotation rotz90("",0.0,0.0,90.0); // never registered.
+ rotITSspdShealdVVt1 = new TGeoCombiTrans(*tranITSspdShealdVVt0,rotz90);
+ rotITSspdShealdVVt1->SetName("ITSspdShealdVVt1");
+ rotITSspdShealdVVt1->RegisterYourself();
+ TGeoRotation rotz180("",0.0,0.0,180.0); // never registered
+ rotITSspdShealdVVt2 = new TGeoCombiTrans(*tranITSspdShealdVVt0,rotz180);
+ rotITSspdShealdVVt2->SetName("ITSspdShealdVVt2");
+ rotITSspdShealdVVt2->RegisterYourself();
+ TGeoRotation rotz270("",0.0,0.0,270.0); // never registered
+ rotITSspdShealdVVt3 = new TGeoCombiTrans(*tranITSspdShealdVVt0,rotz270);
+ rotITSspdShealdVVt3->SetName("ITSspdShealdVVt3");
+ rotITSspdShealdVVt3->RegisterYourself();
+ M = new TGeoCompositeShape("ITS SPD Thermal sheald volume",
+ "(((ITSspdShealdVV+"
+ "ITSspdShealdWingVV:ITSspdShealdVVt0)+"
+ "ITSspdShealdWingVV:ITSspdShealdVVt1)+"
+ "ITSspdShealdWingVV:ITSspdShealdVVt2)+"
+ "ITSspdShealdWingVV:ITSspdShealdVVt3");
+ //
+ TGeoManager *mgr = gGeoManager;
+ SPDcf = mgr->GetMedium("ITSspdCarbonFiber");
+ SPDfs = mgr->GetMedium("ITSspdStaselite4411w");
+ SPDfo = mgr->GetMedium("ITSspdRohacell50A");
+ SPDss = mgr->GetMedium("ITSspdStainlessSteal");
+ SPDair= mgr->GetMedium("ITSspdAir");
+ TGeoVolume *A1v,*A2v,*A3v,*Ah1v,*Ah2v,*Ah3v;
+ TGeoVolume *B1v,*B2v,*B3v,*Bh1v,*Bh2v,*Bh3v;
+ TGeoVolume *C1v,*C2v,*C3v,*Ch1v,*Ch2v,*Ch3v;
+ TGeoVolume *Dv,*Dsv,*Dwv,*Dwsv,*Mv;
+ Mv = new TGeoVolume("ITSspdThermalSheald",M,SPDair);
+ Mv->SetVisibility(kTRUE);
+ Mv->SetLineColor(7); // light Blue
+ Mv->SetLineWidth(1);
+ Mv->SetFillColor(Mv->GetLineColor());
+ Mv->SetFillStyle(4090); // 90% transparent
+ Moth->AddNode(Mv,1,0); ///////////////////// Virtual Volume ////////
+ A1v = new TGeoVolume("ITSspdCentCylA1CF",A1,SPDcf);
+ A1v->SetVisibility(kTRUE);
+ A1v->SetLineColor(4);
+ A1v->SetLineWidth(1);
+ A2v = new TGeoVolume("ITSspdCentCylA2CF",A2,SPDcf);
+ A2v->SetVisibility(kTRUE);
+ A2v->SetLineColor(4);
+ A2v->SetLineWidth(1);
+ A3v = new TGeoVolume("ITSspdCentCylA3CF",A3,SPDcf);
+ A3v->SetVisibility(kTRUE);
+ A3v->SetLineColor(4);
+ A3v->SetLineWidth(1);
+ B1v = new TGeoVolume("ITSspdCentCylB1CF",B1,SPDcf);
+ B1v->SetVisibility(kTRUE);
+ B1v->SetLineColor(4);
+ B1v->SetLineWidth(1);
+ B2v = new TGeoVolume("ITSspdCentCylB2CF",B2,SPDcf);
+ B2v->SetVisibility(kTRUE);
+ B2v->SetLineColor(4);
+ B2v->SetLineWidth(1);
+ B3v = new TGeoVolume("ITSspdCentCylB3CF",B3,SPDcf);
+ B3v->SetVisibility(kTRUE);
+ B3v->SetLineColor(4);
+ B3v->SetLineWidth(1);
+ C1v = new TGeoVolume("ITSspdCentCylC1CF",C1,SPDcf);
+ C1v->SetVisibility(kTRUE);
+ C1v->SetLineColor(4);
+ C1v->SetLineWidth(1);
+ C2v = new TGeoVolume("ITSspdCentCylC2CF",C2,SPDcf);
+ C2v->SetVisibility(kTRUE);
+ C2v->SetLineColor(4);
+ C2v->SetLineWidth(1);
+ C3v = new TGeoVolume("ITSspdCentCylC3CF",C3,SPDcf);
+ C3v->SetVisibility(kTRUE);
+ C3v->SetLineColor(4);
+ C3v->SetLineWidth(1);
+ Ah1v = new TGeoVolume("ITSspdCentCylA1AirA",Ah1,SPDair);
+ Ah1v->SetVisibility(kTRUE);
+ Ah1v->SetLineColor(5); // Yellow
+ Ah1v->SetFillColor(Ah1v->GetLineColor());
+ Ah1v->SetFillStyle(4090); // 90% transparent
+ Ah2v = new TGeoVolume("ITSspdCentCylA2AirA",Ah2,SPDair);
+ Ah2v->SetVisibility(kTRUE);
+ Ah2v->SetLineColor(5); // Yellow
+ Ah2v->SetFillColor(Ah2v->GetLineColor());
+ Ah2v->SetFillStyle(4090); // 90% transparent
+ Ah3v = new TGeoVolume("ITSspdCentCylA3AirA",Ah3,SPDair);
+ Ah3v->SetVisibility(kTRUE);
+ Ah3v->SetLineColor(5); // Yellow
+ Ah3v->SetFillColor(Ah3v->GetLineColor());
+ Ah3v->SetFillStyle(4090); // 90% transparent
+ Bh1v = new TGeoVolume("ITSspdCentCylA1AirB",Bh1,SPDair);
+ Bh1v->SetVisibility(kTRUE);
+ Bh1v->SetLineColor(5); // Yellow
+ Bh1v->SetFillColor(Bh1v->GetLineColor());
+ Bh1v->SetFillStyle(4090); // 90% transparent
+ Bh2v = new TGeoVolume("ITSspdCentCylA2AirB",Bh2,SPDair);
+ Bh2v->SetVisibility(kTRUE);
+ Bh2v->SetLineColor(5); // Yellow
+ Bh2v->SetFillColor(Bh2v->GetLineColor());
+ Bh2v->SetFillStyle(4090); // 90% transparent
+ Bh3v = new TGeoVolume("ITSspdCentCylA3AirB",Bh3,SPDair);
+ Bh3v->SetVisibility(kTRUE);
+ Bh3v->SetLineColor(5); // Yellow
+ Bh3v->SetFillColor(Bh3v->GetLineColor());
+ Bh3v->SetFillStyle(4090); // 90% transparent
+ Ch1v = new TGeoVolume("ITSspdCentCylA1AirC",Ch1,SPDair);
+ Ch1v->SetVisibility(kTRUE);
+ Ch1v->SetLineColor(5); // Yellow
+ Ch1v->SetFillColor(Ch1v->GetLineColor());
+ Ch1v->SetFillStyle(4090); // 90% transparent
+ Ch2v = new TGeoVolume("ITSspdCentCylA2AirC",Ch2,SPDair);
+ Ch2v->SetVisibility(kTRUE);
+ Ch2v->SetLineColor(5); // Yellow
+ Ch2v->SetFillColor(Ch2v->GetLineColor());
+ Ch2v->SetFillStyle(4090); // 90% transparent
+ Ch3v = new TGeoVolume("ITSspdCentCylA3AirC",Ch3,SPDair);
+ Ch3v->SetVisibility(kTRUE);
+ Ch3v->SetLineColor(5); // Yellow
+ Ch3v->SetFillColor(Ch3v->GetLineColor());
+ Ch3v->SetFillStyle(4090); // 90% transparent
+ Dv = new TGeoVolume("ITSspdCentCylA1CD",D,SPDcf);
+ Dv->SetVisibility(kTRUE);
+ Dv->SetLineColor(4);
+ Dv->SetLineWidth(1);
+ Dwv = new TGeoVolume("ITSspdCentCylA1CDw",Dw,SPDcf);
+ Dwv->SetVisibility(kTRUE);
+ Dwv->SetLineColor(4);
+ Dwv->SetLineWidth(1);
+ Dsv = new TGeoVolume("ITSspdCentCylA1Dfill",Ds,SPDfs);
+ Dsv->SetVisibility(kTRUE);
+ Dsv->SetLineColor(3); // Green
+ Dsv->SetFillColor(Dsv->GetLineColor());
+ Dsv->SetFillStyle(4010); // 10% transparent
+ Dwsv = new TGeoVolume("ITSspdCentCylA1DwingFill",Dws,SPDfs);
+ Dwsv->SetVisibility(kTRUE);
+ Dwsv->SetLineColor(3); // Green
+ Dwsv->SetFillColor(Dwsv->GetLineColor());
+ Dwsv->SetFillStyle(4010); // 10% transparent
+ //
+ A1v->AddNode(Ah1v,1,0);
+ A2v->AddNode(Ah2v,1,0);
+ A3v->AddNode(Ah3v,1,0);
+ B1v->AddNode(Bh1v,1,0);
+ B2v->AddNode(Bh2v,1,0);
+ B3v->AddNode(Bh3v,1,0);
+ C1v->AddNode(Ch1v,1,0);
+ C2v->AddNode(Ch2v,1,0);
+ C3v->AddNode(Ch3v,1,0);
+ Dv ->AddNode(Dsv ,1,0);
+ Dwv->AddNode(Dwsv,1,0);
+ //
+ Mv->AddNode(A1v,1,0);
+ Mv->AddNode(A2v,1,0);
+ Mv->AddNode(A3v,1,0);
+ tranb = new TGeoTranslation("",0.0,0.0,0.5*(TSCLengthA+TSCLengthB));
+ tranbm = new TGeoTranslation("",0.0,0.0,0.5*(-TSCLengthA-TSCLengthB));
+ Mv->AddNode(B1v,1,tranb);
+ Mv->AddNode(B2v,1,tranb);
+ Mv->AddNode(B3v,1,tranb);
+ Mv->AddNode(B1v,2,tranbm);
+ Mv->AddNode(B2v,2,tranbm);
+ Mv->AddNode(B3v,2,tranbm);
+ // Muon side (rb26) is at -Z.
+ tranc = new TGeoTranslation("",0.0,0.0,
+ 0.5*(-TSCLengthA-TSCLengthB-TSCLengthC));
+ Mv->AddNode(C1v,1,tranc);
+ Mv->AddNode(C2v,1,tranc);
+ Mv->AddNode(C3v,1,tranc);
+ Mv->AddNode(Dv,1,tranITSspdShealdVVt0);
+ Mv->AddNode(Dwv,1,tranITSspdShealdVVt0);
+ Mv->AddNode(Dwv,2,rotITSspdShealdVVt1);
+ Mv->AddNode(Dwv,3,rotITSspdShealdVVt2);
+ Mv->AddNode(Dwv,4,rotITSspdShealdVVt3);
+ k=2;
+ for(i=1;i<10;i++) {
+ th = ((Double_t)i)*TSCAngle*kDegree;
+ rot = new TGeoRotation("",0.0,0.0,th);
+ Mv->AddNode(A1v,i+1,rot);
+ Mv->AddNode(B1v,i+2,new TGeoCombiTrans(*tranb,*rot));
+ Mv->AddNode(B1v,i+12,new TGeoCombiTrans(*tranbm,*rot));
+ Mv->AddNode(C1v,i+1,new TGeoCombiTrans(*tranc,*rot));
+ if(i!=0||i!=2||i!=7){
+ Mv->AddNode(A2v,k++,rot);
+ Mv->AddNode(B2v,k++,new TGeoCombiTrans(*tranb,*rot));
+ Mv->AddNode(B2v,k++,new TGeoCombiTrans(*tranbm,*rot));
+ Mv->AddNode(C2v,k++,new TGeoCombiTrans(*tranc,*rot));
+ } // end if
+ if(i==5) {
+ Mv->AddNode(A3v,2,rot);
+ Mv->AddNode(B3v,3,new TGeoCombiTrans(*tranb,*rot));
+ Mv->AddNode(B3v,4,new TGeoCombiTrans(*tranbm,*rot));
+ Mv->AddNode(C3v,2,new TGeoCombiTrans(*tranc,*rot));
+ } // end if
+ } // end for i
+ rot = new TGeoRotation("",180.,0.0,0.0);
+ Mv->AddNode(A3v,3,rot);
+ Mv->AddNode(B3v,5,new TGeoCombiTrans(*tranb,*rot));
+ Mv->AddNode(B3v,6,new TGeoCombiTrans(*tranbm,*rot));
+ Mv->AddNode(C3v,3,new TGeoCombiTrans(*tranc,*rot));
+ rot = new TGeoRotation("",180.,0.0,180.0);
+ Mv->AddNode(A3v,4,rot);
+ Mv->AddNode(B3v,7,new TGeoCombiTrans(*tranb,*rot));
+ Mv->AddNode(B3v,8,new TGeoCombiTrans(*tranbm,*rot));
+ Mv->AddNode(C3v,4,new TGeoCombiTrans(*tranc,*rot));
+ if(GetDebug()){
+ A1v->PrintNodes();
+ Ah1v->PrintNodes();
+ A2v->PrintNodes();
+ Ah2v->PrintNodes();
+ A3v->PrintNodes();
+ Ah3v->PrintNodes();
+ B1v->PrintNodes();
+ Bh1v->PrintNodes();
+ B2v->PrintNodes();
+ Bh2v->PrintNodes();
+ B3v->PrintNodes();
+ Bh3v->PrintNodes();
+ C1v->PrintNodes();
+ Ch1v->PrintNodes();
+ C2v->PrintNodes();
+ Ch2v->PrintNodes();
+ C3v->PrintNodes();
+ Ch3v->PrintNodes();
+ Dv->PrintNodes();
+ Dsv->PrintNodes();
+ Dwv->PrintNodes();
+ Dwsv->PrintNodes();
+ //Mv->PrintNodes();
+ } // end if
+}
+//______________________________________________________________________
+void AliITSv11GeometrySupport::SDDCone(TGeoVolume *Moth){
+ // Define the detail SDD support cone geometry.
+ // Inputs:
+ // none.
+ // Outputs:
+ // none.
+ // Return:
+ // none.
+ //
+ // From Cilindro Centrale - Lavorazioni, ALR 0816/1 04/08/03 File
+ // name SDD/Cilindro.hpgl
+ const Double_t TSLength = 790.0*kmm; // Thermal Sheeld length
+ const Double_t TSInsertoLength= 15.0*kmm; // ????
+ const Double_t TSOuterR = 0.5*(220.+10.)*kmm; // ????
+ const Double_t TSInnerR = 0.5*(220.-10.)*kmm; // ????
+ const Double_t TSCarbonFiberth= 0.02*kmm; // ????
+ const Double_t TSBoltDiameter = 6.0*kmm; // M6 screw
+ const Double_t TSBoltDepth = 6.0*kmm; // in volume C
+ const Double_t TSBoltRadius = 0.5*220.*kmm; // Radius in volume C
+ const Double_t TSBoltAngle0 = 0.0*kDegree; // Angle in volume C
+ const Double_t TSBoltdAngle = 30.0*kDegree; // Angle in Volume C
+ Double_t x,y,z,t,t0;
+ Int_t i,n;
+ TGeoTube *A,*B,*C,*D;
+ TGeoTranslation *tran;
+ TGeoRotation *rot;
+ TGeoCombiTrans *rotran;
+ TGeoMedium *SDDcf,*SDDfs,*SDDfo,*SDDss;
+
+ A = new TGeoTube("ITS SDD Central Cylinder",TSInnerR,TSOuterR,
+ 0.5*TSLength);
+ B = new TGeoTube("ITS SDD CC Foam",TSInnerR+TSCarbonFiberth,
+ TSOuterR-TSCarbonFiberth,
+ 0.5*(TSLength-2.0*TSInsertoLength));
+ C = new TGeoTube("ITS SDD CC Inserto",TSInnerR+TSCarbonFiberth,
+ TSOuterR-TSCarbonFiberth,0.5*TSLength);
+ D = new TGeoTube("ITS SDD CC M6 bolt end",0.0,0.5*TSBoltDiameter,
+ 0.5*TSBoltDepth);
+ printTube(A);
+ printTube(B);
+ printTube(C);
+ printTube(D);
+ //
+ TGeoManager *mgr = gGeoManager;
+ SDDcf = mgr->GetMedium("ITSssdCarbonFiber");
+ SDDfs = mgr->GetMedium("ITSssdStaselite4411w");
+ SDDfo = mgr->GetMedium("ITSssdRohacell50A");
+ SDDss = mgr->GetMedium("ITSssdStainlessSteal");
+ TGeoVolume *Av,*Bv,*Cv,*Dv;
+ Av = new TGeoVolume("ITSsddCentCylCF",A,SDDcf);
+ Av->SetVisibility(kTRUE);
+ Av->SetLineColor(4);
+ Av->SetLineWidth(1);
+ Av->SetFillColor(Av->GetLineColor());
+ Av->SetFillStyle(4000); // 0% transparent
+ Bv = new TGeoVolume("ITSsddCentCylF",B,SDDfo);
+ Bv->SetVisibility(kTRUE);
+ Bv->SetLineColor(3);
+ Bv->SetLineWidth(1);
+ Bv->SetFillColor(Bv->GetLineColor());
+ Bv->SetFillStyle(4000); // 0% transparent
+ Cv = new TGeoVolume("ITSsddCentCylSt",C,SDDfs);
+ Cv->SetVisibility(kTRUE);
+ Cv->SetLineColor(2);
+ Cv->SetLineWidth(1);
+ Cv->SetFillColor(Cv->GetLineColor());
+ Cv->SetFillStyle(4000); // 0% transparent
+ Dv = new TGeoVolume("ITSsddCentCylSS",D,SDDss);
+ Dv->SetVisibility(kTRUE);
+ Dv->SetLineColor(1);
+ Dv->SetLineWidth(1);
+ Dv->SetFillColor(Dv->GetLineColor());
+ Dv->SetFillStyle(4000); // 0% transparent
+ //
+ Moth->AddNode(Av,1,0);
+ Av->AddNode(Cv,1,0);
+ Cv->AddNode(Bv,1,0);
+ n = (Int_t)((360.*kDegree)/TSBoltdAngle);
+ for(i=0;i<n;i++){
+ t = TSBoltAngle0+((Double_t)i)*TSBoltdAngle;
+ x = TSBoltRadius*TMath::Cos(t*kRadian);
+ y = TSBoltRadius*TMath::Sin(t*kRadian);
+ z = 0.5*(TSLength-TSBoltDepth);
+ tran = new TGeoTranslation("",x,y,z);
+ Cv->AddNode(Dv,i+1,tran);
+ tran = new TGeoTranslation("",x,y,-z);
+ Cv->AddNode(Dv,i+n+1,tran);
+ } // end for i
+ if(GetDebug()){
+ Av->PrintNodes();
+ Bv->PrintNodes();
+ Cv->PrintNodes();
+ Dv->PrintNodes();
+ } // end if
+ // SDD Suport Cone
+ //
+ //
+ const Double_t Thickness = 10.5*kmm; // Thickness of Rohacell+carbon fiber
+ const Double_t Cthick = 1.5*kmm; // Carbon finber thickness
+ const Double_t Rcurv = 15.0*kmm; // Radius of curvature.
+ const Double_t Tc = 45.0; // angle of SDD cone [degrees].
+ const Double_t Sintc = TMath::Sin(Tc*TMath::DegToRad());
+ const Double_t Costc = TMath::Cos(Tc*TMath::DegToRad());
+ const Double_t Tantc = TMath::Tan(Tc*TMath::DegToRad());
+ const Double_t ZouterMilled = 23.0*kmm;
+ const Double_t Zcylinder = 186.0*kmm;
+ const Double_t Z0 = Zcylinder + 0.5*TSLength;
+ //const Int_t Nspoaks = 12;
+ //const Int_t Nmounts = 4;
+ //const Double_t DmountAngle = 9.0; // degrees
+ const Double_t RoutMax = 0.5*560.0*kmm;
+ const Double_t RoutMin = 0.5*539.0*kmm;
+ // Holes in cone for cables
+ const Double_t PhiHole1 = 0.0*kDegree;
+ const Double_t dPhiHole1 = 25.0*kDegree;
+ const Double_t RholeMax1 = 0.5*528.*kmm;
+ const Double_t RholeMin1 = 0.5*464.*kmm;
+ const Double_t PhiHole2 = 0.0*kDegree;
+ const Double_t dPhiHole2 = 50.0*kDegree;
+ const Double_t RholeMax2 = 0.5*375.*kmm;
+ const Double_t RholeMin2 = 0.5*280.*kmm;
+ //
+ //const Int_t NpostsOut = 6;
+ //const Int_t NpostsIn = 3;
+ //const Double_t Phi0PostOut = 0.0; // degree
+ //const Double_t Phi0PostIn = 0.0; // degree
+ //const Double_t dRpostOut = 16.0*kmm;
+ //const Double_t dRpostIn = 16.0*kmm;
+ //const Double_t ZpostMaxOut = 116.0*kmm;
+ //const Double_t ZpostMaxIn = 190.0*kmm;
+ const Double_t RinMax = 0.5*216*kmm;
+ const Double_t RinCylinder = 0.5*231.0*kmm;
+ //const Double_t RinHole = 0.5*220.0*kmm;
+ const Double_t RinMin = 0.5*210.0*kmm;
+ const Double_t dZin = 15.0*kmm; // ???
+ //
+ Double_t dza = Thickness/Sintc-(RoutMax-RoutMin)/Tantc;
+ Double_t Z,Rmin,Rmax; // Temp variables.
+ if(dza<=0){ // The number or order of the points are in error for a proper
+ // call to pcons!
+ Error("SDDcone","The definition of the points for a call to PCONS is"
+ " in error. abort.");
+ return;
+ } // end if
+ TGeoPcon *E = new TGeoPcon("ITSsddSuportConeCarbonFiberSurfaceE",
+ 0.0,360.0,12);
+ E->Z(0) = 0.0;
+ E->Rmin(0) = RoutMin;
+ E->Rmax(0) = RoutMax;
+ E->Z(1) = ZouterMilled - dza;
+ E->Rmin(1) = E->GetRmin(0);
+ E->Rmax(1) = E->GetRmax(0);
+ E->Z(2) = ZouterMilled;
+ E->Rmax(2) = E->GetRmax(0);
+ RadiusOfCurvature(Rcurv,0.,E->GetZ(1),E->GetRmin(1),Tc,Z,Rmin);
+ E->Z(3) = Z;
+ E->Rmin(3) = Rmin;
+ E->Rmin(2) = RminFrom2Points(E,3,1,E->GetZ(2));
+ RadiusOfCurvature(Rcurv,0.,E->GetZ(2),E->GetRmax(2),Tc,Z,Rmax);
+ E->Z(4) = Z;
+ E->Rmax(4) = Rmax;
+ E->Rmin(4) = RminFromZpCone(E,Tc,E->GetZ(4),0.0);
+ E->Rmax(3) = RmaxFrom2Points(E,4,2,E->GetZ(3));
+ E->Rmin(7) = RinMin;
+ E->Rmin(8) = RinMin;
+ RadiusOfCurvature(Rcurv,90.0,0.0,RinMax,90.0-Tc,Z,Rmax);
+ E->Rmax(8) = Rmax;
+ E->Z(8) = ZFromRmaxpCone(E,Tc,E->GetRmax(8));
+ E->Z(9) = Zcylinder;
+ E->Rmin(9) = RinMin;
+ E->Z(10) = E->GetZ(9);
+ E->Rmin(10) = RinCylinder;
+ E->Rmin(11) = RinCylinder;
+ E->Rmax(11) = E->GetRmin(11);
+ Rmin = E->GetRmin(8);
+ RadiusOfCurvature(Rcurv,90.0-Tc,E->GetZ(8),E->GetRmax(8),90.0,Z,Rmax);
+ Rmax = RinMax;
+ E->Z(11) = Z+(E->GetZ(8)-Z)*(E->GetRmax(11)-Rmax)/(E->GetRmax(8)-Rmax);
+ E->Rmax(9) = RmaxFrom2Points(E,11,8,E->GetZ(9));
+ E->Rmax(10) = E->GetRmax(9);
+ E->Z(6) = Z-dZin;
+ E->Z(7) = E->GetZ(6);
+ E->Rmax(6) = RmaxFromZpCone(E,Tc,E->GetZ(6));
+ E->Rmax(7) = E->GetRmax(6);
+ RadiusOfCurvature(Rcurv,90.,E->GetZ(6),0.0,90.0-Tc,Z,Rmin);
+ E->Z(5) = Z;
+ E->Rmin(5) = RminFromZpCone(E,Tc,Z);
+ E->Rmax(5) = RmaxFromZpCone(E,Tc,Z);
+ RadiusOfCurvature(Rcurv,90.-Tc,0.0,E->Rmin(5),90.0,Z,Rmin);
+ E->Rmin(6) = Rmin;
+ printPcon(E);
+ // Inner Core, Inserto material
+ TGeoPcon *F = new TGeoPcon("ITSsddSuportConeInsertoStesaliteF",
+ 0.,360.0,9);
+ F->Z(0) = E->GetZ(0);
+ F->Rmin(0) = E->GetRmin(0)+Cthick;
+ F->Rmax(0) = E->GetRmax(0)-Cthick;
+ F->Z(1) = E->GetZ(1);
+ F->Rmin(1) = F->GetRmin(0);
+ F->Rmax(1) = F->GetRmax(0);
+ F->Z(2) = E->GetZ(2);
+ F->Rmax(2) = F->GetRmax(1);
+ RadiusOfCurvature(Rcurv-Cthick,0.,F->GetZ(1),F->GetRmax(1),Tc,Z,Rmin);
+ F->Z(3) = Z;
+ F->Rmin(3) = Rmin;
+ F->Rmin(2) = RminFrom2Points(F,3,1,F->GetZ(2));
+ RadiusOfCurvature(Rcurv+Cthick,0.,F->GetZ(2),F->GetRmax(2),Tc,Z,Rmax);
+ F->Z(4) = Z;
+ F->Rmax(4) = Rmax;
+ F->Rmin(4) = RmaxFromZpCone(E,Tc,F->GetZ(4),-Cthick);
+ F->Rmax(3) = RmaxFrom2Points(F,4,2,F->GetZ(3));
+ F->Rmin(7) = E->GetRmin(7);
+ F->Rmin(8) = E->GetRmin(8);
+ F->Z(6) = E->GetZ(6)+Cthick;
+ F->Rmin(6) = E->GetRmin(6);
+ F->Z(7) = F->GetZ(6);
+ F->Rmax(8) = E->GetRmax(8)-Cthick*Sintc;
+ RadiusOfCurvature(Rcurv+Cthick,90.0,F->GetZ(6),F->GetRmin(6),90.0-Tc,
+ Z,Rmin);
+ F->Z(5) = Z;
+ F->Rmin(5) = Rmin;
+ F->Rmax(5) = RmaxFromZpCone(F,Tc,Z);
+ F->Rmax(6) = RmaxFromZpCone(F,Tc,F->GetZ(6));
+ F->Rmax(7) = F->GetRmax(6);
+ F->Z(8) = ZFromRmaxpCone(F,Tc,F->GetRmax(8),-Cthick);
+ printPcon(F);
+ // Inner Core, Inserto material
+ TGeoPcon *G = new TGeoPcon("ITSsddSuportConeFoamCoreG",0.0,360.0,4);
+ RadiusOfCurvature(Rcurv+Cthick,0.0,F->GetZ(1),F->GetRmin(1),Tc,Z,Rmin);
+ G->Z(0) = Z;
+ G->Rmin(0) = Rmin;
+ G->Rmax(0) = G->GetRmin(0);
+ G->Z(1) = G->GetZ(0)+(Thickness-2.0*Cthick)/Sintc;;
+ G->Rmin(1) = RminFromZpCone(F,Tc,G->GetZ(1));
+ G->Rmax(1) = RmaxFromZpCone(F,Tc,G->GetZ(1));
+ G->Z(2) = E->GetZ(5)-Cthick;
+ G->Rmin(2) = RminFromZpCone(F,Tc,G->GetZ(2));
+ G->Rmax(2) = RmaxFromZpCone(F,Tc,G->GetZ(2));
+ G->Z(3) = F->GetZ(5)+(Thickness-2.0*Cthick)*Costc;
+ G->Rmax(3) = RmaxFromZpCone(F,Tc,G->GetZ(3));
+ G->Rmin(3) = G->GetRmax(3);
+ printPcon(G);
+ //
+ TGeoPcon *H = new TGeoPcon("ITSsddSuportConeHoleH",PhiHole1,dPhiHole1,4);
+ H->Rmin(0) = RholeMax1;
+ H->Rmax(0) = H->GetRmin(0);
+ H->Z(0) = ZFromRminpCone(E,Tc,H->GetRmin(0));
+ H->Rmax(1) = H->GetRmax(0);
+ H->Z(1) = ZFromRmaxpCone(E,Tc,H->GetRmax(1));
+ H->Rmin(1) = RminFromZpCone(E,Tc,H->GetZ(1));
+ H->Rmin(2) = RholeMin1;
+ H->Z(2) = ZFromRminpCone(E,Tc,H->GetRmin(2));
+ H->Rmax(2) = RmaxFromZpCone(E,Tc,H->GetZ(2));
+ H->Rmin(3) = H->GetRmin(2);
+ H->Rmax(3) = H->GetRmin(3);
+ H->Z(3) = ZFromRminpCone(E,Tc,H->GetRmin(3));
+ printPcon(H);
+ //
+ x = Cthick/(0.5*(RholeMax1+RholeMin1));
+ t0 = PhiHole1 - x/kRadian;
+ t = dPhiHole1 + 2.0*x/kRadian;
+ TGeoPcon *I = new TGeoPcon("ITSsddSuportConeHoleI",t0,t,4);
+ I->Rmin(0) = RholeMax1+Cthick;
+ I->Rmax(0) = I->GetRmin(0);
+ I->Z(0) = ZFromRminpCone(F,Tc,I->GetRmin(0));
+ I->Rmax(1) = I->GetRmax(0);
+ I->Z(1) = ZFromRmaxpCone(F,Tc,I->GetRmax(1));
+ I->Rmin(1) = RminFromZpCone(F,Tc,I->GetZ(1));
+ I->Rmin(2) = RholeMin1-Cthick;
+ I->Z(2) = ZFromRminpCone(F,Tc,I->GetRmin(2));
+ I->Rmax(2) = RmaxFromZpCone(F,Tc,I->GetZ(2));
+ I->Rmin(3) = I->GetRmin(2);
+ I->Rmax(3) = I->GetRmin(3);
+ I->Z(3) = ZFromRmaxpCone(F,Tc,I->GetRmax(3));
+ printPcon(I);
+ //
+ TGeoPcon *J = new TGeoPcon("ITSsddSuportConeHoleJ",PhiHole2,dPhiHole2,4);
+ J->Rmin(0) = RholeMax2;
+ J->Rmax(0) = J->GetRmin(0);
+ J->Z(0) = ZFromRminpCone(E,Tc,J->GetRmin(0));
+ J->Rmax(1) = J->GetRmax(0);
+ J->Z(1) = ZFromRmaxpCone(E,Tc,J->GetRmax(1));
+ J->Rmin(1) = RminFromZpCone(E,Tc,J->GetZ(1));
+ J->Rmin(2) = RholeMin2;
+ J->Z(2) = ZFromRminpCone(E,Tc,J->GetRmin(2));
+ J->Rmax(2) = RmaxFromZpCone(E,Tc,J->GetZ(2));
+ J->Rmin(3) = J->GetRmin(2);
+ J->Rmax(3) = J->GetRmin(3);
+ J->Z(3) = ZFromRmaxpCone(E,Tc,J->GetRmax(3));
+ printPcon(J);
+ //
+ x = Cthick/(0.5*(RholeMax2+RholeMin2));
+ t0 = PhiHole2 - x/kRadian;
+ t = dPhiHole2 + 2.0*x/kRadian;
+ TGeoPcon *K = new TGeoPcon("ITSsddSuportConeHoleK",t0,t,4);
+ K->Rmin(0) = RholeMax2+Cthick;
+ K->Rmax(0) = K->GetRmin(0);
+ K->Z(0) = ZFromRminpCone(F,Tc,K->GetRmin(0));
+ K->Rmax(1) = K->GetRmax(0);
+ K->Z(1) = ZFromRmaxpCone(F,Tc,K->GetRmax(1));
+ K->Rmin(1) = RminFromZpCone(F,Tc,K->GetZ(1));
+ K->Rmin(2) = RholeMin2-Cthick;
+ K->Z(2) = ZFromRminpCone(F,Tc,K->GetRmin(2));
+ K->Rmax(2) = RmaxFromZpCone(F,Tc,K->GetZ(2));
+ K->Rmin(3) = K->GetRmin(2);
+ K->Rmax(3) = K->GetRmin(3);
+ K->Z(3) = ZFromRmaxpCone(F,Tc,K->GetRmax(3));
+ printPcon(K);
+ //
+ TGeoCompositeShape *L,*M,*N;
+ rot = new TGeoRotation("ITSsddRotZ30",0.0,0.0,30.0);
+ rot->RegisterYourself();
+ rot = new TGeoRotation("ITSsddRotZ60",0.0,0.0,60.0);
+ rot->RegisterYourself();
+ rot = new TGeoRotation("ITSsddRotZ90",0.0,0.0,90.0);
+ rot->RegisterYourself();
+ rot = new TGeoRotation("ITSsddRotZ120",0.0,0.0,120.0);
+ rot->RegisterYourself();
+ rot = new TGeoRotation("ITSsddRotZ150",0.0,0.0,150.0);
+ rot->RegisterYourself();
+ rot = new TGeoRotation("ITSsddRotZ180",0.0,0.0,180.0);
+ rot->RegisterYourself();
+ rot = new TGeoRotation("ITSsddRotZ210",0.0,0.0,210.0);
+ rot->RegisterYourself();
+ rot = new TGeoRotation("ITSsddRotZ240",0.0,0.0,240.0);
+ rot->RegisterYourself();
+ rot = new TGeoRotation("ITSsddRotZ270",0.0,0.0,270.0);
+ rot->RegisterYourself();
+ rot = new TGeoRotation("ITSsddRotZ300",0.0,0.0,300.0);
+ rot->RegisterYourself();
+ rot = new TGeoRotation("ITSsddRotZ330",0.0,0.0,330.0);
+ rot->RegisterYourself();
+ L = new TGeoCompositeShape("ITS SDD Suport Cone","((((((((((((((((("
+ "ITSsddSuportConeCarbonFiberSurfaceE -"
+ "ITSsddSuportConeHoleH) -"
+ "ITSsddSuportConeHoleH:ITSsddRotZ30) -"
+ "ITSsddSuportConeHoleH:ITSsddRotZ60) -"
+ "ITSsddSuportConeHoleH:ITSsddRotZ90) -"
+ "ITSsddSuportConeHoleH:ITSsddRotZ120) -"
+ "ITSsddSuportConeHoleH:ITSsddRotZ150) -"
+ "ITSsddSuportConeHoleH:ITSsddRotZ180) -"
+ "ITSsddSuportConeHoleH:ITSsddRotZ210) -"
+ "ITSsddSuportConeHoleH:ITSsddRotZ240) -"
+ "ITSsddSuportConeHoleH:ITSsddRotZ270) -"
+ "ITSsddSuportConeHoleH:ITSsddRotZ300) -"
+ "ITSsddSuportConeHoleH:ITSsddRotZ330) -"
+ "ITSsddSuportConeHoleJ) -"
+ "ITSsddSuportConeHoleJ:ITSsddRotZ60) -"
+ "ITSsddSuportConeHoleJ:ITSsddRotZ120) -"
+ "ITSsddSuportConeHoleJ:ITSsddRotZ180) -"
+ "ITSsddSuportConeHoleJ:ITSsddRotZ240) -"
+ "ITSsddSuportConeHoleJ:ITSsddRotZ300");
+ M = new TGeoCompositeShape("ITS SDD Suport Cone Inserto Stesalite",
+ "((((((((((((((((("
+ "ITSsddSuportConeInsertoStesaliteF -"
+ "ITSsddSuportConeHoleI) -"
+ "ITSsddSuportConeHoleI:ITSsddRotZ30) -"
+ "ITSsddSuportConeHoleI:ITSsddRotZ60) -"
+ "ITSsddSuportConeHoleI:ITSsddRotZ90) -"
+ "ITSsddSuportConeHoleI:ITSsddRotZ120) -"
+ "ITSsddSuportConeHoleI:ITSsddRotZ150) -"
+ "ITSsddSuportConeHoleI:ITSsddRotZ180) -"
+ "ITSsddSuportConeHoleI:ITSsddRotZ210) -"
+ "ITSsddSuportConeHoleI:ITSsddRotZ240) -"
+ "ITSsddSuportConeHoleI:ITSsddRotZ270) -"
+ "ITSsddSuportConeHoleI:ITSsddRotZ300) -"
+ "ITSsddSuportConeHoleI:ITSsddRotZ330) -"
+ "ITSsddSuportConeHoleK) -"
+ "ITSsddSuportConeHoleK:ITSsddRotZ60) -"
+ "ITSsddSuportConeHoleK:ITSsddRotZ120) -"
+ "ITSsddSuportConeHoleK:ITSsddRotZ180) -"
+ "ITSsddSuportConeHoleK:ITSsddRotZ240) -"
+ "ITSsddSuportConeHoleK:ITSsddRotZ300");
+ N = new TGeoCompositeShape("ITS SDD Suport Cone Foam Core",
+ "((((((((((((((((("
+ "ITSsddSuportConeFoamCoreG -"
+ "ITSsddSuportConeHoleI) -"
+ "ITSsddSuportConeHoleI:ITSsddRotZ30) -"
+ "ITSsddSuportConeHoleI:ITSsddRotZ60) -"
+ "ITSsddSuportConeHoleI:ITSsddRotZ90) -"
+ "ITSsddSuportConeHoleI:ITSsddRotZ120) -"
+ "ITSsddSuportConeHoleI:ITSsddRotZ150) -"
+ "ITSsddSuportConeHoleI:ITSsddRotZ180) -"
+ "ITSsddSuportConeHoleI:ITSsddRotZ210) -"
+ "ITSsddSuportConeHoleI:ITSsddRotZ240) -"
+ "ITSsddSuportConeHoleI:ITSsddRotZ270) -"
+ "ITSsddSuportConeHoleI:ITSsddRotZ300) -"
+ "ITSsddSuportConeHoleI:ITSsddRotZ330) -"
+ "ITSsddSuportConeHoleK) -"
+ "ITSsddSuportConeHoleK:ITSsddRotZ60) -"
+ "ITSsddSuportConeHoleK:ITSsddRotZ120) -"
+ "ITSsddSuportConeHoleK:ITSsddRotZ180) -"
+ "ITSsddSuportConeHoleK:ITSsddRotZ240) -"
+ "ITSsddSuportConeHoleK:ITSsddRotZ300");
+ //++++++++++++++++++++++++++++++++++++++++++++++++++++++++++++++++++
+ TGeoVolume *Lv,*Mv,*Nv;
+ Lv = new TGeoVolume("ITSsddConeL",L,SDDcf);
+ Lv->SetVisibility(kTRUE);
+ Lv->SetLineColor(4);
+ Lv->SetLineWidth(1);
+ Lv->SetFillColor(Lv->GetLineColor());
+ Lv->SetFillStyle(4000); // 0% transparent
+ Mv = new TGeoVolume("ITSsddConeM",M,SDDfs);
+ Mv->SetVisibility(kTRUE);
+ Mv->SetLineColor(2);
+ Mv->SetLineWidth(1);
+ Mv->SetFillColor(Mv->GetLineColor());
+ Mv->SetFillStyle(4010); // 10% transparent
+ Nv = new TGeoVolume("ITSsddConeN",N,SDDfo);
+ Nv->SetVisibility(kTRUE);
+ Nv->SetLineColor(7);
+ Nv->SetLineWidth(1);
+ Nv->SetFillColor(Nv->GetLineColor());
+ Nv->SetFillStyle(4050); // 50% transparent
+ //
+ Mv->AddNode(Nv,1,0);
+ Lv->AddNode(Mv,1,0);
+ tran = new TGeoTranslation("",0.0,0.0,-Z0);
+ Moth->AddNode(Lv,1,tran);
+ rot = new TGeoRotation("",0.0,180.0*kDegree,0.0);
+ rotran = new TGeoCombiTrans("",0.0,0.0,Z0,rot);
+ delete rot;// rot not explicity used in AddNode functions.
+ Moth->AddNode(Lv,2,rotran);
+ if(GetDebug()){
+ Lv->PrintNodes();
+ Mv->PrintNodes();
+ Nv->PrintNodes();
+ } // end if
+}
+//______________________________________________________________________
+void AliITSv11GeometrySupport::SSDCone(TGeoVolume *Moth){
+ // Define the detail SSD support cone geometry.
+ // Inputs:
+ // none.
+ // Outputs:
+ // none.
+ // Return:
+ // none.
+ //
+ Int_t i,j;
+ Double_t t,t0,dt,x,y,z,vl[3],vg[3],x0,y0;
+ TGeoMedium *SSDcf = 0; // SSD support cone Carbon Fiber materal number.
+ TGeoMedium *SSDfs = 0; // SSD support cone inserto stesalite 4411w.
+ TGeoMedium *SSDfo = 0; // SSD support cone foam, Rohacell 50A.
+ TGeoMedium *SSDss = 0; // SSD support cone screw material,Stainless steal
+ TGeoMedium *SSDair = 0; // SSD support cone Air
+ TGeoMedium *SSDal = 0; // SSD support cone SDD mounting bracket Al
+ TGeoManager *mgr = gGeoManager;
+ SSDcf = mgr->GetMedium("ITSssdCarbonFiber");
+ SSDfs = mgr->GetMedium("ITSssdStaselite4411w");
+ SSDfo = mgr->GetMedium("ITSssdRohacell50A");
+ SSDss = mgr->GetMedium("ITSssdStainlessSteal");
+ SSDair= mgr->GetMedium("ITSssdAir");
+ SSDal = mgr->GetMedium("ITSssdAl");
+ //
+ // SSD Central cylinder/Thermal Sheald.
+ const Double_t CylZlength = 1140.0*kmm; //
+ const Double_t CylZFoamlength = 1020.0*kmm; //
+ const Double_t CylROuter = 0.5*595.0*kmm; //
+ const Double_t CylRInner = 0.5*560.5*kmm; //
+ const Double_t CylCthick = 0.64*kmm; //
+ const Double_t CylFoamThick = 5.0*kmm; //
+ const Double_t CylRholes = 0.5*575.0*kmm;
+ const Double_t CylZM6 = 6.0*kmm; //
+ const Double_t CylRM6 = 0.5*6.0*kmm;
+ const Double_t CylPhi0M6 = 0.0*kDegree;
+ const Int_t CylNM6 = 40;
+ const Double_t CylZPin = 10.0*kmm;
+ const Double_t CylRPin = 0.5*4.0*kmm;
+ const Double_t CylPhi0Pin = (90.0+4.5)*kDegree;
+ const Int_t CylNPin = 2;
+ //
+ //Begin_Html
+ /*
+ <img src="picts/ITS/file_name.gif">
+ <P>
+ <FONT FACE'"TIMES">
+ ITS SSD centreal support and thermal sheal cylinder.
+ </FONT>
+ </P>
+ */
+ //End_Html
+ TGeoPcon *CA = new TGeoPcon("ITS SSD Thermal Centeral Carbon Fiber "
+ "CylinderCA",0.0,360.0,6);
+ TGeoPcon *CB = new TGeoPcon("ITS SSD Thermal Centeral Stesalite "
+ "CylinderCB",0.0,360.0,6);
+ TGeoTube *CC = new TGeoTube("ITS SSD Thermal Centeral Rohacell "
+ "CylinderCC",
+ CylROuter-CylCthick-CylFoamThick,
+ CylROuter-CylCthick,0.5*CylZFoamlength);
+ CA->Z(0) = -0.5*CylZlength;
+ CA->Rmin(0) = CylRInner;
+ CA->Rmax(0) = CylROuter;
+ CA->Z(1) = CA->GetZ(0) + CylZM6;
+ CA->Rmin(1) = CA->GetRmin(0);
+ CA->Rmax(1) = CA->GetRmax(0);
+ CA->Z(2) = -0.5*CylZFoamlength;
+ CA->Rmin(2) = CylROuter - 2.0*CylCthick-CylFoamThick;
+ CA->Rmax(2) = CA->GetRmax(0);
+ CA->Z(3) = -CA->GetZ(2);
+ CA->Rmin(3) = CA->GetRmin(2);
+ CA->Rmax(3) = CA->GetRmax(2);
+ CA->Z(4) = -CA->GetZ(1);
+ CA->Rmin(4) = CA->GetRmin(1);
+ CA->Rmax(4) = CA->GetRmax(1);
+ CA->Z(5) = -CA->GetZ(0);
+ CA->Rmin(5) = CA->GetRmin(0);
+ CA->Rmax(5) = CA->GetRmax(0);
+ //
+ CB->Z(0) = CA->GetZ(0);
+ CB->Rmin(0) = CA->GetRmin(0) + CylCthick;
+ CB->Rmax(0) = CA->GetRmax(0) - CylCthick;
+ CB->Z(1) = CA->GetZ(1);
+ CB->Rmin(1) = CA->GetRmin(1) + CylCthick;
+ CB->Rmax(1) = CA->GetRmax(1) - CylCthick;
+ CB->Z(2) = CA->GetZ(2);
+ CB->Rmin(2) = CA->GetRmin(2) + CylCthick;
+ CB->Rmax(2) = CA->GetRmax(2) - CylCthick;
+ CB->Z(3) = CA->GetZ(3);
+ CB->Rmin(3) = CA->GetRmin(3) + CylCthick;
+ CB->Rmax(3) = CA->GetRmax(3) - CylCthick;
+ CB->Z(4) = CA->GetZ(4);
+ CB->Rmin(4) = CA->GetRmin(4) + CylCthick;
+ CB->Rmax(4) = CA->GetRmax(4) - CylCthick;
+ CB->Z(5) = CA->GetZ(5);
+ CB->Rmin(5) = CA->GetRmin(5) + CylCthick;
+ CB->Rmax(5) = CA->GetRmax(5) - CylCthick;
+ //
+ printPcon(CA);
+ printPcon(CB);
+ printTube(CC);
+ //
+ TGeoTube *CD = new TGeoTube("ITS SSD Thermal Centeral Cylinder M6 screwCD",
+ 0.0,CylRM6,0.5*CylZM6);
+ TGeoTube *CE = new TGeoTube("ITS SSD Thermal Centeral Cylinder PinCE",
+ 0.0,CylRPin,0.5*CylZPin);
+ //
+ TGeoVolume *CAv,*CBv,*CCv,*CDv,*CEv;
+ CAv = new TGeoVolume("ITSssdCentCylCA",CA,SSDcf);
+ CAv->SetVisibility(kTRUE);
+ CAv->SetLineColor(4); // blue
+ CAv->SetLineWidth(1);
+ CAv->SetFillColor(CAv->GetLineColor());
+ CAv->SetFillStyle(4000); // 0% transparent
+ CBv = new TGeoVolume("ITSssdCentCylCB",CB,SSDfs);
+ CBv->SetVisibility(kTRUE);
+ CBv->SetLineColor(2); // red
+ CBv->SetLineWidth(1);
+ CBv->SetFillColor(CBv->GetLineColor());
+ CBv->SetFillStyle(4050); // 50% transparent
+ CCv = new TGeoVolume("ITSssdCentCylCC",CC,SSDfo);
+ CCv->SetVisibility(kTRUE);
+ CCv->SetLineColor(3); // green
+ CCv->SetLineWidth(1);
+ CCv->SetFillColor(CCv->GetLineColor());
+ CCv->SetFillStyle(4050); // 50% transparent
+ CDv = new TGeoVolume("ITSssdCentCylCD",CD,SSDss);
+ CDv->SetVisibility(kTRUE);
+ CDv->SetLineColor(1); // black
+ CDv->SetLineWidth(1);
+ CDv->SetFillColor(CDv->GetLineColor());
+ CDv->SetFillStyle(4000); // 0% transparent
+ CEv = new TGeoVolume("ITSssdCentCylCE",CE,SSDss);
+ CEv->SetVisibility(kTRUE);
+ CEv->SetLineColor(1); // black
+ CEv->SetLineWidth(1);
+ CEv->SetFillColor(CEv->GetLineColor());
+ CEv->SetFillStyle(4000); // 0% transparent
+ // Insert Bolt and Pins in both the Cone and Cylinder at the same time.
+ CBv->AddNode(CCv,1,0);
+ CAv->AddNode(CBv,1,0);
+ Moth->AddNode(CAv,1,0);
+ if(GetDebug()){
+ CAv->PrintNodes();
+ CBv->PrintNodes();
+ CCv->PrintNodes();
+ } // end if
+ //
+ // SSD Cone
+ // Data from Drawings ALR 0743/2E "Supporto Globale Settore SSD" and
+ // ALR 0743/2A "Supporto Generale Settore SSD".
+ //
+ const Double_t ConThick = 13.0*kmm; // Thickness of Cone.
+ const Double_t ConCthick = 0.75*kmm; // Carbon finber thickness
+ const Double_t ConRCurv = 10.0*kmm; // Radius of curvature.
+ const Double_t ConT = 39.0*kDegree; // angle of SSD cone.
+ const Double_t ConZOuterRing = 47.0*kmm;
+ const Double_t ConZOuterRingMill = ConZOuterRing-5.0*kmm;
+ const Double_t ConZToCylinder = 170.0*kmm;
+ const Double_t ConZLength = 176.5*kmm-
+ (ConZOuterRing-ConZOuterRingMill);
+ const Double_t ConZInnerRing = 161.5*kmm-
+ (ConZOuterRing-ConZOuterRingMill);
+ const Double_t ConZOuterRingInside = 30.25*kmm-
+ (ConZOuterRing-ConZOuterRingMill);
+ const Double_t ConZDisplacement = ConZToCylinder + 0.5*CylZlength;
+ const Double_t ConROuterMax = 0.5*985.0*kmm;
+ const Double_t ConROuterMin = 0.5*945.0*kmm;
+ const Double_t ConRCylOuterMill = 0.5*597.0*kmm;
+ const Double_t ConRInnerMin = 0.5*564.0*kmm;
+ const Double_t ConRCentCurv0 = 0.5*927.0*kmm;
+ const Double_t ConRCentCurv1 = 0.5*593.0*kmm;
+ //const Double_t ConRCentCurv2 = 0.5*578.0*kmm;
+ // Foam core.
+ const Double_t ConRohacellL0 = 112.3*kmm;
+ const Double_t ConRohacellL1 = 58.4*kmm;
+ // Screws and pins in outer SSD cone ring
+ const Double_t ConROutHoles = 0.5*965.0*kmm;
+ const Double_t ConRScrewM5by12 = 0.5*5.0*kmm;
+ const Double_t ConLScrewM5by12 = 0.5*12.0*kmm;
+ const Int_t ConNScrewM5by12 = 2;
+ const Double_t ConRPinO6 = 0.5*6.0*kmm;
+ const Double_t ConLPinO6 = 0.5*10.0*kmm;
+ const Int_t ConNPinO6 = 3;
+ const Int_t ConNRailScrews = 4;
+ const Int_t ConNRailPins = 2;
+ const Int_t ConNmounts = 4;
+ const Double_t ConMountPhi0 = 9.0*kDegree; // degrees
+ // Holes in SSD cone, Ch* Cable Hole, Th* Tubing hole, and
+ // Mh* mounting-post holes
+ const Double_t ConCableHoleROut = 0.5*920.0*kmm;
+ const Double_t ConCableHoleRinner = 0.5*800.0*kmm;
+ const Double_t ConCableHoleWidth = 200.0*kmm;
+ const Double_t ConCableHoleAngle = 42.0*kDegree;
+ //const Double_t ConCableHolePhi0 = 90.0/4.0*kDegree;
+ //const Int_t ConNCableHoles = 8;
+ const Double_t ConCoolHoleWidth = 40.0*kmm;
+ const Double_t ConCoolHoleHight = 30.0*kmm;
+ const Double_t ConCoolHoleRmin = 350.0*kmm;
+ //const Double_t ConCoolHolephi0 = 90.0/4.0*kDegree;
+ //const Int_t ConNCoolHoles = 8;
+ const Double_t ConMountHoleWidth = 20.0*kmm;
+ const Double_t ConMountHoleHight = 20.0*kmm;
+ const Double_t ConMountHoleRmin = 317.5*kmm;
+ //const Double_t ConMountHolephi0 = 0.0*kDegree;
+ //const Int_t ConNMountHoles = 6;
+ // SSD cone Wings with holes.
+ const Double_t ConWingRmax = 527.5*kmm;
+ const Double_t ConWingWidth = 70.0*kmm;
+ const Double_t ConWingThick = 10.0*kmm;
+ const Double_t ConWingPhi0 = 45.0*kDegree;
+ //const Int_t ConNWings = 4;
+ // SSD-SDD Thermal/Mechanical cylinder mounts
+ const Double_t ConRM6Head = 8.0*kmm;
+ const Double_t ConZM6Head = 8.5*kmm;
+ //
+ // SSD-SDD Mounting bracket
+ const Double_t SupPRmin = 0.5*539.0*kmm;// see SDD RoutMin
+ const Double_t SupPRmax = 0.5*585.0*kmm;
+ const Double_t SupPZ = 3.5*kmm;
+ const Double_t SupPPhi1 = -0.5*70.0*kmm/SupPRmax*kRadian;
+ const Double_t SupPPhi2 = -SupPPhi1;
+ //
+ const Double_t Sintc = TMath::Sin(ConT*kRadian);
+ const Double_t Costc = TMath::Cos(ConT*kRadian);
+ //
+ // Lets start with the upper left outer carbon fiber surface.
+ // Between za[2],rmaxa[2] and za[4],rmaxa[4] there is a curved section
+ // given by rmaxa = rmaxa[2]-r*Sind(t) for 0<=t<=ConT and
+ // za = za[2] + r*Cosd(t) for 0<=t<=ConT. Simularly between za[1],rmina[1
+ // and za[3],rmina[3] there is a curve section given by
+ // rmina = rmina[1]-r*Sind(t) for 0<=t<=ConT and za = za[1]+r&Sind(t)
+ // for t<=0<=ConT. These curves have been replaced by straight lines
+ // between the equivelent points for simplicity.
+ // Poly-cone Volume A0. Top part of SSD cone Carbon Fiber.
+ TGeoPcon *A0 = new TGeoPcon("ITSssdSuportConeCarbonFiberSurfaceA0",
+ 0.0,360.0,15);
+ A0->Z(0) = 0.0;
+ A0->Rmin(0) = ConROuterMin;
+ A0->Rmax(0) = ConROuterMax;
+ A0->Z(1) = ConZOuterRingInside-ConRCurv;
+ A0->Rmin(1) = A0->GetRmin(0);
+ A0->Rmax(1) = A0->GetRmax(0);
+ A0->Z(2) = ConZOuterRingInside;
+ A0->Rmin(2) = ConROuterMin-ConRCurv;
+ A0->Rmax(2) = A0->GetRmax(0);
+ A0->Z(3) = A0->GetZ(2);
+ A0->Rmin(3) = -1000; // See Below
+ A0->Rmax(3) = A0->GetRmax(0);
+ A0->Z(4) = ConZOuterRingMill-ConRCurv;
+ A0->Rmin(4) = -1000; // See Below
+ A0->Rmax(4) = A0->GetRmax(0);
+ A0->Z(5) = ConZOuterRingMill;
+ A0->Rmin(5) = -1000; // See Below
+ A0->Rmax(5) = A0->GetRmax(0) - ConRCurv;
+ A0->Z(6) = A0->GetZ(5);
+ A0->Rmin(6) = -1000; // See Below
+ A0->Rmax(6) = ConRCentCurv0;
+ A0->Z(7) = ConZOuterRingMill+ConRCurv*Sintc;
+ A0->Rmin(7) = -1000; // See Below
+ A0->Rmax(7) = ConRCentCurv0-ConRCurv*Costc;
+ A0->Z(8) = -1000; // See Below
+ A0->Rmin(8) = ConRInnerMin;
+ A0->Rmax(8) = -1000; // See Below
+ A0->Z(9) = ConZInnerRing;
+ A0->Rmin(9) = -1000; // See Below
+ A0->Rmax(9) = -1000; // See Below
+ A0->Z(10) = ConZInnerRing;
+ A0->Rmin(10)= ConRInnerMin;
+ A0->Rmax(10)= -1000; // See Below
+ A0->Z(11) = ConZLength-ConRCurv+ConRCurv*Costc;
+ A0->Rmin(11)= ConRInnerMin;
+ A0->Rmax(11)= ConRCentCurv1+ConRCurv*Sintc;
+ A0->Z(12) = ConZToCylinder;
+ A0->Rmin(12)= ConRInnerMin;
+ A0->Rmax(12)= -1000; // See Below
+ A0->Z(13) = ConZToCylinder;
+ A0->Rmin(13)= ConRCylOuterMill;
+ A0->Rmax(13)= -1000; // See Below
+ A0->Z(14) = -1000; // See Below
+ A0->Rmin(14)= ConRCylOuterMill;
+ A0->Rmax(14)= ConRCylOuterMill;
+ // Compute values undefined above.
+ RadiusOfCurvature(ConRCurv,0.0,A0->GetZ(9),A0->GetRmin(9),ConT,A0->Z(8),x);
+ A0->Rmin(3) = RminFromZpCone(A0,8,90.-ConT,A0->GetZ(3),0.0);
+ A0->Rmin(4) = RminFromZpCone(A0,3,90.-ConT,A0->GetZ(4),0.0);
+ A0->Rmin(5) = RminFromZpCone(A0,3,90.-ConT,A0->GetZ(5),0.0);
+ A0->Rmin(6) = A0->GetRmin(5);
+ A0->Rmin(7) = RminFromZpCone(A0,3,90.-ConT,A0->GetZ(7),0.0);
+ A0->Rmax(8) = RmaxFromZpCone(A0,4,90.-ConT,A0->GetZ(8),0.0);
+ A0->Rmin(9) = RminFromZpCone(A0,3,90.-ConT,A0->GetZ(9),0.0);
+ A0->Rmax(9) = RmaxFromZpCone(A0,4,90.-ConT,A0->GetZ(9),0.0);
+ A0->Rmax(10)= RmaxFromZpCone(A0,4,90.-ConT,A0->GetZ(10),0.0);
+ t = TMath::Tan((270.+ConT)*TMath::DegToRad());
+ A0->Z(14) = (ConRCylOuterMill-A0->GetRmax(4)+t*A0->GetZ(4))/t;
+ A0->Rmax(12)= RmaxFrom2Points(A0,11,14,A0->GetZ(12));
+ A0->Rmax(13)= RmaxFrom2Points(A0,11,14,A0->GetZ(13));
+ printPcon(A0);
+ //
+ // Poly-cone Volume B. Stesalite inside volume A0.
+ // Now lets define the Inserto Stesalite 4411w material volume.
+ // Poly-cone Volume A0. Top part of SSD cone Carbon Fiber.
+ TGeoPcon *B0 = new TGeoPcon("ITSssdSuportConeStaseliteB0",
+ 0.0,360.0,15);
+ //
+ B0->Z(0) = A0->GetZ(0);
+ B0->Rmin(0) = A0->GetRmin(0) + ConCthick;
+ B0->Rmax(0) = A0->GetRmax(0) - ConCthick;
+ InsidePoint(A0,0,1,2,ConCthick,B0,1,kFALSE); // Rmin
+ B0->Rmax(1) = B0->Rmax(0);
+ InsidePoint(A0,1,2,3,ConCthick,B0,2,kFALSE); // Rmin
+ B0->Rmax(2) = B0->Rmax(0);
+ InsidePoint(A0,2,3,9,ConCthick,B0,3,kFALSE);
+ B0->Rmax(3) = B0->Rmax(0);
+ InsidePoint(A0,0,4,5,ConCthick,B0,4,kTRUE); // Rmax
+ B0->Rmin(4) = -1000.; // see Bellow
+ InsidePoint(A0,4,5,6,ConCthick,B0,5,kTRUE); // Rmax
+ B0->Rmin(5) = -1000.; // see Bellow
+ InsidePoint(A0,5,6,7,ConCthick,B0,6,kTRUE); // Rmax
+ B0->Rmin(6) = -1000.; // see Bellow
+ InsidePoint(A0,6,7,11,ConCthick,B0,7,kTRUE); // Rmax
+ B0->Rmin(7) = -1000.; // see Bellow
+ InsidePoint(A0,3,8,9,ConCthick,B0,8,kFALSE); // Rmin
+ B0->Rmax(8) = -1000.; // see Bellow
+ InsidePoint(A0,8,9,10,ConCthick,B0,9,kFALSE); // Rmin
+ B0->Rmax(9) = -1000.; // see Bellow
+ B0->Z(10) = A0->GetZ(10) + ConCthick;
+ B0->Rmin(10)= A0->GetRmin(10);
+ B0->Rmax(10)= -1000.; // see Bellow
+ InsidePoint(A0,7,11,14,ConCthick,B0,11,kTRUE); // Rmax
+ B0->Rmin(11)= A0->GetRmin(10);
+ B0->Z(2) = A0->GetZ(12);
+ B0->Rmin(12)= A0->GetRmin(12);
+ B0->Rmax(12)= -1000.; // see Bellow
+ B0->Z(13) = A0->GetZ(13);
+ B0->Rmin(13)= A0->GetRmin(13);
+ B0->Rmax(13)= -1000.; // see Bellow
+ B0->Z(14) = A0->GetZ(14) - ConCthick;
+ B0->Rmin(14)= A0->GetRmin(14);
+ B0->Rmax(14)= B0->Rmin(14); // Close?
+ B0->Rmin(4) = RminFrom2Points(B0,3,8,B0->GetZ(4));
+ B0->Rmin(5) = RminFrom2Points(B0,3,8,B0->GetZ(5));
+ B0->Rmin(6) = B0->GetRmin(5);
+ B0->Rmin(7) = RminFrom2Points(B0,3,8,B0->GetZ(7));
+ B0->Rmax(8) = RmaxFrom2Points(B0,7,11,B0->GetZ(8));
+ B0->Rmax(9) = RmaxFrom2Points(B0,7,11,B0->GetZ(9));
+ B0->Rmax(10)= B0->GetRmax(9);
+ B0->Rmax(12)= RmaxFrom2Points(B0,11,14,B0->GetZ(12));
+ B0->Rmax(13)= RmaxFrom2Points(B0,11,14,B0->GetZ(13));
+ printPcon(B0);
+ //
+ // Poly-cone Volume C0. Foam inside volume A0.
+ // Now lets define the Rohacell foam material volume.
+ TGeoPcon *C0 = new TGeoPcon("ITSssdSuportConeRohacellC0",
+ 0.0,360.0,4);
+ C0->Z(1) = B0->GetZ(7);
+ C0->Rmax(1) = B0->GetRmax(7);
+ C0->Rmin(1) = RminFrom2Points(B0,3,8,C0->GetZ(1));
+ C0->Rmin(0) = C0->GetRmax(1);
+ C0->Rmax(0) = C0->GetRmin(0);
+ C0->Z(0) = Zfrom2MinPoints(B0,3,8,C0->Rmin(0));
+ C0->Z(3) = C0->GetZ(0)+(ConThick-2.0*ConCthick+ConRohacellL0)*Costc;
+ C0->Rmin(3) = C0->GetRmin(0)+(ConThick-2.0*ConCthick-ConRohacellL0)*Sintc;
+ C0->Rmax(3) = C0->GetRmin(3);
+ C0->Rmin(2) = C0->GetRmin(3);
+ C0->Z(2) = Zfrom2MinPoints(B0,3,8,C0->GetRmin(2));
+ C0->Rmax(2) = RmaxFrom2Points(B0,4,11,C0->GetZ(2));
+ printPcon(C0);
+ //
+ // Poly-cone Volume F. Second Foam inside volume A0.
+ // Now lets define the Rohacell foam material volume.
+ TGeoPcon *F0 = new TGeoPcon("ITSssdSuportConeRohacellCF0",
+ 0.0,360.0,4);
+ F0->Z(2) = B0->GetZ(8);
+ F0->Rmin(2) = B0->GetRmin(8);
+ F0->Rmax(2) = B0->GetRmax(8);
+ F0->Z(0) = F0->GetZ(2)-ConRohacellL1*Sintc;
+ F0->Rmin(0) = F0->GetRmin(2)+ConRohacellL1*Costc;
+ F0->Rmax(0) = F0->GetRmin(0);
+ F0->Z(1) = Zfrom2MaxPoints(B0,4,11,F0->GetRmax(0));
+ F0->Rmax(1) = F0->GetRmax(0);
+ F0->Rmin(1) = RminFrom2Points(B0,3,8,F0->GetZ(1));
+ F0->Rmin(3) = F0->GetRmin(2)+(ConThick-2.0*ConCthick)*Costc;
+ F0->Z(3) = F0->GetZ(2)+(ConThick-2.0*ConCthick)*Sintc;
+ F0->Rmax(3) = F0->GetRmin(3);
+ printPcon(F0);
+ // Holes for Cables to pass Through is created by the intersection
+ // between a cone segment and an Arb8, One for the volume A0 and a
+ // larger one for the volumes B0 and C0, so that the surface is covered
+ // in carbon figer (volume A0).
+ TGeoConeSeg *Ah1 = new TGeoConeSeg("ITSssdCableHoleAh1",
+ 0.5*ConZLength,ConCableHoleRinner,
+ ConCableHoleROut,ConCableHoleRinner,
+ ConCableHoleROut,
+ 90.-0.5*ConCableHoleWidth/
+ ConCableHoleROut/kRadian,
+ 90.+0.5*ConCableHoleWidth/
+ ConCableHoleROut/kRadian);
+ TGeoConeSeg *Bh1 = new TGeoConeSeg("ITSssdCableHoleBh1",0.5*ConZLength,
+ ConCableHoleRinner-ConCthick,
+ ConCableHoleROut+ConCthick,
+ ConCableHoleRinner-ConCthick,
+ ConCableHoleROut+ConCthick,
+ 90.+((-0.5*ConCableHoleWidth-ConCthick)/
+ (ConCableHoleROut-ConCthick))/kRadian,
+ 90.+((+0.5*ConCableHoleWidth-ConCthick)/
+ (ConCableHoleROut-ConCthick))/kRadian);
+ x0 = Ah1->GetRmax1()*TMath::Cos(Ah1->GetPhi2()*kRadian);
+ y0 = Ah1->GetRmax1()*TMath::Sin(Ah1->GetPhi2()*kRadian);
+ TGeoArb8 *Ah2 = new TGeoArb8("ITSssdCableHoleAh2",0.5*ConZLength);
+ y = Ah1->GetRmax1();
+ x = x0+(y-y0)/TMath::Tan((90.0+ConCableHoleAngle)*kRadian);
+ Ah2->SetVertex(0,x,y);
+ y = Ah1->GetRmin1()*TMath::Sin(Ah1->GetPhi2()*kRadian);
+ x = x0+(y-y0)/TMath::Tan((90.0+ConCableHoleAngle)*kRadian);
+ Ah2->SetVertex(3,x,y);
+ x0 = Ah1->GetRmax1()*TMath::Cos(Ah1->GetPhi1()*kRadian);
+ y0 = Ah1->GetRmax1()*TMath::Sin(Ah1->GetPhi1()*kRadian);
+ y = Ah1->GetRmax1();
+ x = x0+(y-y0)/TMath::Tan((90.0-ConCableHoleAngle)*kRadian);
+ Ah2->SetVertex(1,x,y);
+ y = Ah1->GetRmin1()*TMath::Sin(Ah1->GetPhi1()*kRadian);
+ x = x0+(y-y0)/TMath::Tan((90.0-ConCableHoleAngle)*kRadian);
+ Ah2->SetVertex(2,x,y);
+ //
+ x0 = Bh1->GetRmax1()*TMath::Cos(Bh1->GetPhi2()*kRadian);
+ y0 = Bh1->GetRmax1()*TMath::Sin(Bh1->GetPhi2()*kRadian);
+ TGeoArb8 *Bh2 = new TGeoArb8("ITSssdCableHoleBh2",0.5*ConZLength);
+ y = Bh1->GetRmax1();
+ x = x0+(y-y0)/TMath::Tan((90.0+ConCableHoleAngle)*kRadian);
+ Bh2->SetVertex(0,x,y);
+ y = Bh1->GetRmin1()*TMath::Sin(Bh1->GetPhi2()*kRadian);
+ x = x0+(y-y0)/TMath::Tan((90.0+ConCableHoleAngle)*kRadian);
+ Bh2->SetVertex(3,x,y);
+ x0 = Bh1->GetRmax1()*TMath::Cos(Bh1->GetPhi1()*kRadian);
+ y0 = Bh1->GetRmax1()*TMath::Sin(Bh1->GetPhi1()*kRadian);
+ y = Bh1->GetRmax1();
+ x = x0+(y-y0)/TMath::Tan((90.0-ConCableHoleAngle)*kRadian);
+ Bh2->SetVertex(1,x,y);
+ y = Bh1->GetRmin1()*TMath::Sin(Bh1->GetPhi1()*kRadian);
+ x = x0+(y-y0)/TMath::Tan((90.0-ConCableHoleAngle)*kRadian);
+ Bh2->SetVertex(2,x,y);
+ for(i=0;i<4;i++){ // define points at +dz
+ Ah2->SetVertex(i+4,(Ah2->GetVertices())[2*i],
+ (Ah2->GetVertices())[1+2*i]);
+ Bh2->SetVertex(i+4,(Bh2->GetVertices())[2*i],
+ (Bh2->GetVertices())[1+2*i]);
+ } // end for i
+ TGeoBBox *Ah3 = new TGeoBBox("ITSssdCoolingHoleAh3",0.5*ConCoolHoleWidth,
+ 0.5*ConCoolHoleHight,0.5*ConZLength);
+ TGeoBBox *Bh3 = new TGeoBBox("ITSssdCoolingHoleBh3",
+ 0.5*ConCoolHoleWidth+ConCthick,
+ 0.5*ConCoolHoleHight+ConCthick,
+ 0.5*ConZLength);
+ TGeoBBox *Ah4 = new TGeoBBox("ITSssdMountingPostHoleAh4",
+ 0.5*ConMountHoleWidth,
+ 0.5*ConMountHoleHight,0.5*ConZLength);
+ TGeoBBox *Bh4 = new TGeoBBox("ITSssdMountingPostHoleBh4",
+ 0.5*ConMountHoleWidth+ConCthick,
+ 0.5*ConMountHoleHight+ConCthick,
+ 0.5*ConZLength);
+ printConeSeg(Ah1);
+ printConeSeg(Bh1);
+ printArb8(Ah2);
+ printArb8(Bh2);
+ printBBox(Ah3);
+ printBBox(Bh3);
+ printBBox(Ah4);
+ printBBox(Bh4);
+ // SSD Cone Wings
+ TGeoConeSeg *G = new TGeoConeSeg("ITSssdWingCarbonFiberSurfaceG",
+ 0.5*ConWingThick,ConROuterMax-ConCthick,
+ ConWingRmax,
+ ConROuterMax-ConCthick,ConWingRmax,
+ ConWingPhi0-0.5*ConWingWidth/ConWingRmax*kRadian,
+ ConWingPhi0+0.5*ConWingWidth/ConWingRmax*kRadian);
+ TGeoConeSeg *H = new TGeoConeSeg("ITSssdWingStaseliteH",
+ 0.5*ConWingThick-ConCthick,ConROuterMax-ConCthick,
+ ConWingRmax-ConCthick,
+ ConROuterMax-ConCthick,
+ ConWingRmax-ConCthick,
+ ConWingPhi0-((0.5*ConWingWidth-ConCthick)/
+ (ConWingRmax-ConCthick))*kRadian,
+ ConWingPhi0+((0.5*ConWingWidth-ConCthick)/
+ (ConWingRmax-ConCthick))*kRadian);
+ printConeSeg(G);
+ printConeSeg(H);
+ // SDD support plate, SSD side.
+ //Poly-cone Volume T.
+ TGeoTubeSeg *T = new TGeoTubeSeg("ITSssdsddMountingBracketT",
+ SupPRmin,SupPRmax,
+ SupPZ,SupPPhi1,
+ SupPPhi2);
+ printTubeSeg(T);
+ //
+ TGeoRotation *rotZ225 =new TGeoRotation("ITSssdConeZ225", 0.0,0.0, 22.5);
+ rotZ225->RegisterYourself();
+ TGeoRotation *rotZ675 =new TGeoRotation("ITSssdConeZ675", 0.0,0.0, 67.5);
+ rotZ675->RegisterYourself();
+ TGeoRotation *rotZ90 =new TGeoRotation("ITSssdConeZ90", 0.0,0.0, 90.0);
+ rotZ90->RegisterYourself();
+ TGeoRotation *rotZ1125=new TGeoRotation("ITSssdConeZ1125",0.0,0.0,112.5);
+ rotZ1125->RegisterYourself();
+ TGeoRotation *rotZ1575=new TGeoRotation("ITSssdConeZ1575",0.0,0.0,157.5);
+ rotZ1575->RegisterYourself();
+ TGeoRotation *rotZ180 =new TGeoRotation("ITSssdConeZ180", 0.0,0.0,180.0);
+ rotZ180->RegisterYourself();
+ TGeoRotation *rotZ2025=new TGeoRotation("ITSssdConeZ2025",0.0,0.0,202.5);
+ rotZ2025->RegisterYourself();
+ TGeoRotation *rotZ2475=new TGeoRotation("ITSssdConeZ2475",0.0,0.0,247.5);
+ rotZ2475->RegisterYourself();
+ TGeoRotation *rotZ270 =new TGeoRotation("ITSssdConeZ270", 0.0,0.0,270.0);
+ rotZ270->RegisterYourself();
+ TGeoRotation *rotZ2925=new TGeoRotation("ITSssdConeZ2925",0.0,0.0,292.5);
+ rotZ2925->RegisterYourself();
+ TGeoRotation *rotZ3375=new TGeoRotation("ITSssdConeZ3375",0.0,0.0,337.5);
+ rotZ3375->RegisterYourself();
+ //
+ vl[0] = 0.0;vl[1] = ConCoolHoleRmin+0.5*ConCoolHoleHight;vl[2] = 0.0;
+ rotZ225->LocalToMaster(vl,vg);
+ TGeoCombiTrans *rotranA225 = new TGeoCombiTrans("ITSssdConeTZ225",vg[0],
+ vg[1],vg[2],rotZ225);
+ rotranA225->RegisterYourself();
+ rotZ675->LocalToMaster(vl,vg);
+ TGeoCombiTrans *rotranA675 = new TGeoCombiTrans("ITSssdConeTZ675", vg[0],
+ vg[1],vg[2],rotZ675);
+ rotranA675->RegisterYourself();
+ rotZ1125->LocalToMaster(vl,vg);
+ TGeoCombiTrans *rotranA1125 = new TGeoCombiTrans("ITSssdConeTZ1125",vg[0],
+ vg[1],vg[2],rotZ1125);
+ rotranA1125->RegisterYourself();
+ rotZ1575->LocalToMaster(vl,vg);
+ TGeoCombiTrans *rotranA1575 = new TGeoCombiTrans("ITSssdConeTZ1575",vg[0],
+ vg[1],vg[2],rotZ1575);
+ rotranA1575->RegisterYourself();
+ rotZ2025->LocalToMaster(vl,vg);
+ TGeoCombiTrans *rotranA2025 = new TGeoCombiTrans("ITSssdConeTZ2025",vg[0],
+ vg[1],vg[2],rotZ2025);
+ rotranA2025->RegisterYourself();
+ rotZ2475->LocalToMaster(vl,vg);
+ TGeoCombiTrans *rotranA2475 = new TGeoCombiTrans("ITSssdConeTZ2475",vg[0],
+ vg[1],vg[2],rotZ2475);
+ rotranA2475->RegisterYourself();
+ rotZ2925->LocalToMaster(vl,vg);
+ TGeoCombiTrans *rotranA2925 = new TGeoCombiTrans("ITSssdConeTZ2925",vg[0],
+ vg[1],vg[2],rotZ2925);
+ rotranA2925->RegisterYourself();
+ rotZ3375->LocalToMaster(vl,vg);
+ TGeoCombiTrans *rotranA3375 = new TGeoCombiTrans("ITSssdConeTZ3375",vg[0],
+ vg[1],vg[2],rotZ3375);
+ rotranA3375->RegisterYourself();
+ TGeoRotation *rotZ30 = new TGeoRotation("ITSssdConeZ30", 0.0,0.0, 30.0);
+ TGeoRotation *rotZ60 = new TGeoRotation("ITSssdConeZ60", 0.0,0.0, 60.0);
+ //TGeoRotation *rotZ120 = new TGeoRotation("ITSssdConeZ120",0.0,0.0,120.0);
+ TGeoRotation *rotZ150 = new TGeoRotation("ITSssdConeZ150",0.0,0.0,150.0);
+ TGeoRotation *rotZ210 = new TGeoRotation("ITSssdConeZ210",0.0,0.0,210.0);
+ //TGeoRotation *rotZ240 = new TGeoRotation("ITSssdConeZ240",0.0,0.0,240.0);
+ TGeoRotation *rotZ300 = new TGeoRotation("ITSssdConeZ300",0.0,0.0,300.0);
+ TGeoRotation *rotZ330 = new TGeoRotation("ITSssdConeZ330",0.0,0.0,330.0);
+ vl[0] = ConMountHoleRmin+0.5*ConMountHoleHight; vl[1] = 0.0; vl[2] = 0.0;
+ rotZ30->LocalToMaster(vl,vg);
+ TGeoCombiTrans *rotranA30 = new TGeoCombiTrans("ITSssdConeTZ30",vl[0],
+ vl[1],vl[2],rotZ30);
+ rotranA30->RegisterYourself();
+ rotZ90->LocalToMaster(vl,vg);
+ TGeoCombiTrans *rotranA90 = new TGeoCombiTrans("ITSssdConeTZ90", vg[0],
+ vg[1],vg[2],rotZ90);
+ rotranA90->RegisterYourself();
+ rotZ150->LocalToMaster(vl,vg);
+ TGeoCombiTrans *rotranA150 = new TGeoCombiTrans("ITSssdConeTZ150",vg[0],
+ vg[1],vg[2],rotZ150);
+ rotranA150->RegisterYourself();
+ rotZ210->LocalToMaster(vl,vg);
+ TGeoCombiTrans *rotranA210 = new TGeoCombiTrans("ITSssdConeTZ210",vg[0],
+ vg[1],vg[2],rotZ210);
+ rotranA210->RegisterYourself();
+ rotZ270->LocalToMaster(vl,vg);
+ TGeoCombiTrans *rotranA270 = new TGeoCombiTrans("ITSssdConeTZ270",vg[0],
+ vg[1],vg[2],rotZ270);
+ rotranA270->RegisterYourself();
+ rotZ330->LocalToMaster(vl,vg);
+ TGeoCombiTrans *rotranA330 = new TGeoCombiTrans("ITSssdConeTZ330",vg[0],
+ vg[1],vg[2],rotZ330);
+ rotranA330->RegisterYourself();
+ vl[0] = 0.0; vl[1] = 0.0; vl[2] = A0->GetZ(10)+T->GetDz();
+ rotZ60->LocalToMaster(vl,vg);
+ TGeoCombiTrans *rotranBrTZ60 = new TGeoCombiTrans("ITSssdConeBrTZ60",
+ vg[0],vg[1],vg[2],rotZ60);
+ rotranBrTZ60->RegisterYourself();
+ TGeoCombiTrans *rotranBrTZ180 = new TGeoCombiTrans("ITSssdConeBrTZ180",
+ vg[0],vg[1],vg[2],rotZ180);
+ rotranBrTZ180->RegisterYourself();
+ TGeoCombiTrans *rotranBrTZ300 = new TGeoCombiTrans("ITSssdConeBrTZ300",
+ vg[0],vg[1],vg[2],rotZ300);
+ rotranBrTZ300->RegisterYourself();
+ TGeoCompositeShape *A = new TGeoCompositeShape(
+ "ITSssdSuportConeCarbonFiberSurfaceA","(((((((((((((((((((((((((((("
+ "ITSssdSuportConeCarbonFiberSurfaceA0 +"
+ "ITSssdWingCarbonFiberSurfaceG) +"
+ "ITSssdWingCarbonFiberSurfaceG:ITSssdConeZ90) +"
+ "ITSssdWingCarbonFiberSurfaceG:ITSssdConeZ180) +"
+ "ITSssdWingCarbonFiberSurfaceG:ITSssdConeZ270) -"
+ "(ITSssdCableHoleAh1*ITSssdCableHoleAh2):ITSssdConeZ225) -"
+ "(ITSssdCableHoleAh1*ITSssdCableHoleAh2):ITSssdConeZ675) -"
+ "(ITSssdCableHoleAh1*ITSssdCableHoleAh2):ITSssdConeZ1125) -"
+ "(ITSssdCableHoleAh1*ITSssdCableHoleAh2):ITSssdConeZ1575) -"
+ "(ITSssdCableHoleAh1*ITSssdCableHoleAh2):ITSssdConeZ2025) -"
+ "(ITSssdCableHoleAh1*ITSssdCableHoleAh2):ITSssdConeZ2475) -"
+ "(ITSssdCableHoleAh1*ITSssdCableHoleAh2):ITSssdConeZ2925) -"
+ "(ITSssdCableHoleAh1*ITSssdCableHoleAh2):ITSssdConeZ3375) -"
+ "ITSssdCoolingHoleAh3:ITSssdConeTZ225) -"
+ "ITSssdCoolingHoleAh3:ITSssdConeTZ675) -"
+ "ITSssdCoolingHoleAh3:ITSssdConeTZ1125) -"
+ "ITSssdCoolingHoleAh3:ITSssdConeTZ1575) -"
+ "ITSssdCoolingHoleAh3:ITSssdConeTZ2025) -"
+ "ITSssdCoolingHoleAh3:ITSssdConeTZ2475) -"
+ "ITSssdCoolingHoleAh3:ITSssdConeTZ2925) -"
+ "ITSssdCoolingHoleAh3:ITSssdConeTZ3375) -"
+ "ITSssdMountingPostHoleAh4:ITSssdConeTZ30) -"
+ "ITSssdMountingPostHoleAh4:ITSssdConeTZ90) -"
+ "ITSssdMountingPostHoleAh4:ITSssdConeTZ150) -"
+ "ITSssdMountingPostHoleAh4:ITSssdConeTZ210) -"
+ "ITSssdMountingPostHoleAh4:ITSssdConeTZ270) -"
+ "ITSssdMountingPostHoleAh4:ITSssdConeTZ330) -"
+ "ITSssdsddMountingBracketT:ITSssdConeBrTZ60) -"
+ "ITSssdsddMountingBracketT:ITSssdConeBrTZ180) -"
+ "ITSssdsddMountingBracketT:ITSssdConeBrTZ300"
+ );
+ TGeoCompositeShape *B = new TGeoCompositeShape(
+ "ITSssdSuportConeStaseliteB","(((((((((((((((((((((((((((("
+ "ITSssdSuportConeStaseliteB0 +"
+ "ITSssdWingStaseliteH) +"
+ "ITSssdWingStaseliteH:ITSssdConeZ90) +"
+ "ITSssdWingStaseliteH:ITSssdConeZ180) +"
+ "ITSssdWingStaseliteH:ITSssdConeZ270) -"
+ "(ITSssdCableHoleBh1*ITSssdCableHoleBh2):ITSssdConeZ225) -"
+ "(ITSssdCableHoleBh1*ITSssdCableHoleBh2):ITSssdConeZ675) -"
+ "(ITSssdCableHoleBh1*ITSssdCableHoleBh2):ITSssdConeZ1125) -"
+ "(ITSssdCableHoleBh1*ITSssdCableHoleBh2):ITSssdConeZ1575) -"
+ "(ITSssdCableHoleBh1*ITSssdCableHoleBh2):ITSssdConeZ2025) -"
+ "(ITSssdCableHoleBh1*ITSssdCableHoleBh2):ITSssdConeZ2475) -"
+ "(ITSssdCableHoleBh1*ITSssdCableHoleBh2):ITSssdConeZ2925) -"
+ "(ITSssdCableHoleBh1*ITSssdCableHoleBh2):ITSssdConeZ3375) -"
+ "ITSssdCoolingHoleBh3:ITSssdConeTZ225) -"
+ "ITSssdCoolingHoleBh3:ITSssdConeTZ675) -"
+ "ITSssdCoolingHoleBh3:ITSssdConeTZ1125) -"
+ "ITSssdCoolingHoleBh3:ITSssdConeTZ1575) -"
+ "ITSssdCoolingHoleBh3:ITSssdConeTZ2025) -"
+ "ITSssdCoolingHoleBh3:ITSssdConeTZ2475) -"
+ "ITSssdCoolingHoleBh3:ITSssdConeTZ2925) -"
+ "ITSssdCoolingHoleBh3:ITSssdConeTZ3375) -"
+ "ITSssdMountingPostHoleBh4:ITSssdConeTZ30) -"
+ "ITSssdMountingPostHoleBh4:ITSssdConeTZ90) -"
+ "ITSssdMountingPostHoleBh4:ITSssdConeTZ150) -"
+ "ITSssdMountingPostHoleBh4:ITSssdConeTZ210) -"
+ "ITSssdMountingPostHoleBh4:ITSssdConeTZ270) -"
+ "ITSssdMountingPostHoleBh4:ITSssdConeTZ330) -"
+ "ITSssdsddMountingBracketT:ITSssdConeBrTZ60) -"
+ "ITSssdsddMountingBracketT:ITSssdConeBrTZ180) -"
+ "ITSssdsddMountingBracketT:ITSssdConeBrTZ300"
+ );
+ TGeoCompositeShape *C = new TGeoCompositeShape(
+ "ITSssdSuportConeRohacellC","("
+ "ITSssdSuportConeRohacellC0 -((((((("
+ "ITSssdCableHoleBh1:ITSssdConeZ225*ITSssdCableHoleBh2:ITSssdConeZ225)-"
+ "ITSssdCableHoleBh1:ITSssdConeZ675*ITSssdCableHoleBh2:ITSssdConeZ675)-"
+ "ITSssdCableHoleBh1:ITSssdConeZ1125*ITSssdCableHoleBh2:ITSssdConeZ1125)-"
+ "ITSssdCableHoleBh1:ITSssdConeZ1575*ITSssdCableHoleBh2:ITSssdConeZ1575)-"
+ "ITSssdCableHoleBh1:ITSssdConeZ2025*ITSssdCableHoleBh2:ITSssdConeZ2025)-"
+ "ITSssdCableHoleBh1:ITSssdConeZ2475*ITSssdCableHoleBh2:ITSssdConeZ2475)-"
+ "ITSssdCableHoleBh1:ITSssdConeZ2925*ITSssdCableHoleBh2:ITSssdConeZ2925))"
+ );
+ TGeoCompositeShape *F = new TGeoCompositeShape(
+ "ITSssdSuportConeRohacellCF","((((("
+ "ITSssdSuportConeRohacellCF0 -("
+ "ITSssdMountingPostHoleBh4:ITSssdConeTZ30) -"
+ "ITSssdMountingPostHoleBh4:ITSssdConeTZ90) -"
+ "ITSssdMountingPostHoleBh4:ITSssdConeTZ150) -"
+ "ITSssdMountingPostHoleBh4:ITSssdConeTZ210) -"
+ "ITSssdMountingPostHoleBh4:ITSssdConeTZ270) -"
+ "ITSssdMountingPostHoleBh4:ITSssdConeTZ330)"
+ );
+ //
+ // In volume SCB, th Inserto Stesalite 4411w material volume, there
+ // are a number of Stainless steel screw and pin studs which will be
+ // filled with screws/studs.
+ TGeoTube *D = new TGeoTube("ITS Screw+stud used to mount things to "
+ "the SSD support cone",
+ 0.0,ConRScrewM5by12,ConLScrewM5by12);
+ printTube(D);
+ TGeoTube *E = new TGeoTube("ITS pin used to mount things to the "
+ "SSD support cone",0.0,ConRPinO6,ConLPinO6);
+ printTube(E);
+ // Bolt heads holding the SSD-SDD tube to the SSD cone.
+ // Bolt -- PolyCone
+ //Poly-cone Volume Q.
+ TGeoPcon *Q = new TGeoPcon("ITS SSD Thermal sheal M6 screw headQ",
+ 0.0,360.0,4);
+ Q->Z(0) = A0->GetZ(12);
+ Q->Rmin(0) = 0.0;
+ Q->Rmax(0) = CylRM6;
+ Q->Z(1) = Q->GetZ(0) + ConZM6Head;
+ Q->Rmin(1) = 0.0;
+ Q->Rmax(1) = CylRM6;
+ Q->Z(2) = Q->GetZ(1);
+ Q->Rmin(2) = 0.0;
+ Q->Rmax(2) = ConRM6Head;
+ Q->Z(3) = Q->GetZ(0)-SupPZ;
+ Q->Rmin(3) = 0.0;
+ Q->Rmax(3) = 0.5*ConRM6Head;
+ printPcon(Q);
+ // air infront of bolt (stasolit Volume K) -- Tube
+ TGeoTube *R = new TGeoTube("ITS Air in front of bolt (in stasolit)R",
+ Q->GetRmin(3),Q->GetRmax(3),
+ 0.5*(SupPZ-ConCthick));
+ // air infront of bolt (carbon fiber volume I) -- Tube
+ TGeoTube *S = new TGeoTube("ITS Air in front of Stainless Steal Screw "
+ "end, M6S",Q->GetRmin(3),Q->GetRmax(3),
+ 0.5*ConCthick);
+ printTube(S);
+ //
+ TGeoVolume *Av,*Bv,*Cv,*Dv,*Ev,*Fv,*Qv,*Rv,*Sv,*Tv;
+ //
+ Av = new TGeoVolume("ITSssdConeA",A,SSDcf); // Carbon Fiber
+ Av->SetVisibility(kTRUE);
+ Av->SetLineColor(4); // blue
+ Av->SetLineWidth(1);
+ Av->SetFillColor(Av->GetLineColor());
+ Av->SetFillStyle(4000); // 0% transparent
+ Bv = new TGeoVolume("ITSssdConeB",B,SSDfs); // Staselite
+ Bv->SetVisibility(kTRUE);
+ Bv->SetLineColor(2); // red
+ Bv->SetLineWidth(1);
+ Bv->SetFillColor(Bv->GetLineColor());
+ Bv->SetFillStyle(4010); // 10% transparent
+ Cv = new TGeoVolume("ITSssdConeC",C,SSDfo); // Rohacell
+ Cv->SetVisibility(kTRUE);
+ Cv->SetLineColor(3); // green
+ Cv->SetLineWidth(1);
+ Cv->SetFillColor(Cv->GetLineColor());
+ Cv->SetFillStyle(4050); // 50% transparent
+ Fv = new TGeoVolume("ITSssdConeF",F,SSDfo); // Rohacell;
+ Fv->SetVisibility(kTRUE);
+ Fv->SetLineColor(3); // green
+ Fv->SetLineWidth(1);
+ Fv->SetFillColor(Fv->GetLineColor());
+ Fv->SetFillStyle(4050); // 50% transparent
+ Dv = new TGeoVolume("ITSssdConeD",D,SSDss);
+ Dv->SetVisibility(kTRUE);
+ Dv->SetLineColor(1); // black
+ Dv->SetLineWidth(1);
+ Dv->SetFillColor(Dv->GetLineColor());
+ Dv->SetFillStyle(4000); // 0% transparent
+ Ev = new TGeoVolume("ITSssdConeE",E,SSDss);
+ Ev->SetVisibility(kTRUE);
+ Ev->SetLineColor(1); // black
+ Ev->SetLineWidth(1);
+ Ev->SetFillColor(Ev->GetLineColor());
+ Ev->SetFillStyle(4000); // 0% transparent
+ Qv = new TGeoVolume("ITSssdConeQ",Q,SSDss);
+ Qv->SetVisibility(kTRUE);
+ Qv->SetLineColor(1); // black
+ Qv->SetLineWidth(1);
+ Qv->SetFillColor(Qv->GetLineColor());
+ Qv->SetFillStyle(4000); // 00% transparent
+ Rv = new TGeoVolume("ITSssdConeR",R,SSDair);
+ Rv->SetVisibility(kTRUE);
+ Rv->SetLineColor(5); // yellow
+ Rv->SetLineWidth(1);
+ Rv->SetFillColor(Rv->GetLineColor());
+ Rv->SetFillStyle(4090); // 90% transparent
+ Sv = new TGeoVolume("ITSssdConeS",S,SSDair);
+ Sv->SetVisibility(kTRUE);
+ Sv->SetLineColor(5); // yellow
+ Sv->SetLineWidth(1);
+ Sv->SetFillColor(Sv->GetLineColor());
+ Sv->SetFillStyle(4090); // 90% transparent
+ Tv = new TGeoVolume("ITSssdsddMountingBracket",S,SSDal);
+ Tv->SetVisibility(kTRUE);
+ Tv->SetLineColor(5); // yellow
+ Tv->SetLineWidth(1);
+ Tv->SetFillColor(Tv->GetLineColor());
+ Tv->SetFillStyle(4000); // 0% transparent
+ //
+ TGeoCombiTrans *rotran;
+ TGeoTranslation *tran;
+ tran = new TGeoTranslation("ITSssdConeTrans",0.0,0.0,-ConZDisplacement);
+ TGeoRotation *rotY180 = new TGeoRotation("",0.0,180.0,0.0);
+ TGeoCombiTrans *flip = new TGeoCombiTrans("ITSssdConeFlip",
+ 0.0,0.0,ConZDisplacement,rotY180);
+ delete rotY180;// rot not explicity used in AddNode functions.
+ //
+ //
+ //
+ //
+ Av->AddNode(Bv,1,0);
+ Bv->AddNode(Cv,1,0);
+ Bv->AddNode(Fv,1,0);
+ Moth->AddNode(Av,1,tran); // RB24 side
+ Moth->AddNode(Av,2,flip); // RB26 side (Absorber)
+ //
+ //
+ //
+ // Insert Bolt and Pins in both the Cone and Cylinder at the same time.
+ Int_t NcopyCDv=0,NcopyCEv=0,NcopyQv=0,NcopyRv=0,NcopySv=0,NcopyTv=0;
+ Int_t NcopyDv=0,NcopyEv=0;
+ z = CB->GetZ(0)-0.5*CylZPin;
+ dt = (360.0/((Double_t)CylNPin));
+ for(i=0;i<CylNPin;i++){
+ t = ((Double_t)i)*dt;
+ x = CylRholes*TMath::Cos((t+CylPhi0Pin)*kRadian);
+ y = CylRholes*TMath::Sin((t+CylPhi0Pin)*kRadian);
+ tran = new TGeoTranslation("",x,y,z);
+ CBv->AddNode(CDv,++NcopyCDv,tran);
+ tran = new TGeoTranslation("",x,y,-z);
+ CBv->AddNode(CDv,++NcopyCDv,tran);
+ } // end for i
+ dt = (360.0/((Double_t)CylNM6));
+ for(i=0;i<CylNM6;i++){
+ t = ((Double_t)i)*dt;
+ x = CylRholes*TMath::Cos((t+CylPhi0M6)*kRadian);
+ y = CylRholes*TMath::Sin((t+CylPhi0M6)*kRadian);
+ z = CB->GetZ(0)-0.5*CylZM6;
+ tran = new TGeoTranslation("",x,y,z);
+ CBv->AddNode(CEv,++NcopyCEv,tran);
+ tran = new TGeoTranslation("",x,y,-z);
+ CBv->AddNode(CEv,++NcopyCEv,tran);
+ tran = new TGeoTranslation("",x,y,0.0);
+ Bv->AddNode(Qv,++NcopyQv,tran);
+ if(!((t<rotranBrTZ60->GetRotation()->GetPhiRotation()+T->GetPhi2()&&
+ t>rotranBrTZ60->GetRotation()->GetPhiRotation()-T->GetPhi1())||
+ (t<rotranBrTZ180->GetRotation()->GetPhiRotation()+T->GetPhi2()&&
+ t>rotranBrTZ180->GetRotation()->GetPhiRotation()-T->GetPhi1())||
+ (t<rotranBrTZ300->GetRotation()->GetPhiRotation()+T->GetPhi2()&&
+ t>rotranBrTZ300->GetRotation()->GetPhiRotation()-T->GetPhi1()))){
+ // If not at an angle where the bracket T is located.
+ tran = new TGeoTranslation("",x,y,B0->GetZ(10)-R->GetDz());
+ Bv->AddNode(Rv,++NcopyRv,tran);
+ tran = new TGeoTranslation("",x,y,A0->GetZ(10)-S->GetDz());
+ Av->AddNode(Sv,++NcopySv,tran);
+ } // end if
+ } // end for i
+ // Add the mounting brackets to the RB24 side only.
+ vl[0] = 0.0; vl[1] = 0.0, vl[2] = A0->GetZ(10)+ConZDisplacement-T->GetDz();
+ rotZ60->LocalToMaster(vl,vg);
+ rotran = new TGeoCombiTrans("",vg[0],vg[1],vg[2],rotZ60);
+ Moth->AddNode(Tv,++NcopyTv,rotran);
+ rotZ180->LocalToMaster(vl,vg);
+ rotran = new TGeoCombiTrans("",vg[0],vg[1],vg[2],rotZ180);
+ Moth->AddNode(Tv,++NcopyTv,rotran);
+ rotZ300->LocalToMaster(vl,vg);
+ rotran = new TGeoCombiTrans("",vg[0],vg[1],vg[2],rotZ300);
+ Moth->AddNode(Tv,++NcopyTv,rotran);
+ //
+ Double_t da[] = {-3.5,-1.5,1.5,3.5};
+ for(i=0;i<2;i++){ // Mounting for ITS-TPC bracket or ITS-Rails
+ t0 = 180.*((Double_t)i)*kRadian;
+ for(j=-ConNScrewM5by12/2;j<=ConNScrewM5by12/2;j++)if(j!=0){
+ //screws per ITS-TPC brkt
+ t = t0 + 5.0*((Double_t)j)*kRadian;
+ tran = new TGeoTranslation("",ConROutHoles*TMath::Cos(t),
+ ConROutHoles*TMath::Sin(t),
+ B0->GetZ(0)+D->GetDz());
+ Bv->AddNode(Dv,++NcopyDv,tran);
+ } // end or j
+ for(j=-ConNPinO6/2;j<=ConNPinO6/2;j++){ // pins per ITS-TPC bracket
+ t = t0 + 3.0*((Double_t)j)*kRadian;
+ tran = new TGeoTranslation("",ConROutHoles*TMath::Cos(t),
+ ConROutHoles*TMath::Sin(t),
+ B0->GetZ(0)+D->GetDz());
+ Bv->AddNode(Ev,++NcopyEv,tran);
+ } // end or j
+ t0 = (96.5+187.*((Double_t)i))*kRadian;
+ for(j=0;j<ConNRailScrews;j++){ // screws per ITS-rail bracket
+ t = t0+da[j]*kRadian;
+ tran = new TGeoTranslation("",ConROutHoles*TMath::Cos(t),
+ ConROutHoles*TMath::Sin(t),
+ B0->GetZ(0)+D->GetDz());
+ Bv->AddNode(Dv,++NcopyDv,tran);
+ } // end or j
+ t0 = (91.5+184.*((Double_t)i))*kRadian;
+ for(j=-ConNRailPins/2;j<=ConNRailPins/2;j++)if(j!=0){
+ // pins per ITS-rail bracket
+ t = t0+(7.0*((Double_t)j))*kRadian;
+ tran = new TGeoTranslation("",ConROutHoles*TMath::Cos(t),
+ ConROutHoles*TMath::Sin(t),
+ B0->GetZ(0)+D->GetDz());
+ Bv->AddNode(Ev,++NcopyEv,tran);
+ } // end or j
+ } // end for i
+ for(i=0;i<ConNmounts;i++){
+ // mounting points for SPD-cone+Beam-pipe support
+ t0 = (45.0+((Double_t)i)*360./((Double_t)ConNmounts))*kRadian;
+ for(j=-1;j<=1;j++)if(j!=0){ // 2 screws per bracket
+ t = t0+((Double_t)j)*0.5*ConMountPhi0*kRadian;
+ tran = new TGeoTranslation("",ConROutHoles*TMath::Cos(t),
+ ConROutHoles*TMath::Sin(t),
+ B0->GetZ(0)+D->GetDz());
+ Bv->AddNode(Dv,++NcopyDv,tran);
+ } // end for j
+ for(j=0;j<1;j++){ // 1 pin per bracket
+ t = t0;
+ tran = new TGeoTranslation("",ConROutHoles*TMath::Cos(t),
+ ConROutHoles*TMath::Sin(t),
+ B0->GetZ(0)+D->GetDz());
+ Bv->AddNode(Ev,++NcopyEv,tran);
+ } // end for j
+ } // end for i
+ if(GetDebug()){
+ Av->PrintNodes();
+ Bv->PrintNodes();
+ Cv->PrintNodes();
+ Dv->PrintNodes();
+ Ev->PrintNodes();
+ Fv->PrintNodes();
+ Qv->PrintNodes();
+ Rv->PrintNodes();
+ Sv->PrintNodes();
+ Tv->PrintNodes();
+ } // end if
+}
+
+//______________________________________________________________________
+void AliITSv11GeometrySupport::ServicesCableSupport(TGeoVolume *Moth){
+ // Define the detail ITS cable support trays on both the RB24 and
+ // RB26 sides..
+ // Inputs:
+ // none.
+ // Outputs:
+ // none.
+ // Return:
+ // none.
+ // Based on the Drawings SSup_201A.jpg unless otherwise stated,
+ // Volumes A...,
+ TGeoMedium *SUPcf = 0; // SUP support cone Carbon Fiber materal number.
+ TGeoMedium *SUPfs = 0; // SUP support cone inserto stesalite 4411w.
+ TGeoMedium *SUPfo = 0; // SUP support cone foam, Rohacell 50A.
+ TGeoMedium *SUPss = 0; // SUP support cone screw material,Stainless
+ TGeoMedium *SUPair = 0; // SUP support cone Air
+ TGeoMedium *SUPal = 0; // SUP support cone SDD mounting bracket Al
+ TGeoMedium *SUPwater = 0; // SUP support cone Water
+ TGeoManager *mgr = gGeoManager;
+ SUPcf = mgr->GetMedium("ITSssdCarbonFiber");
+ SUPfs = mgr->GetMedium("ITSssdStaselite4411w");
+ SUPfo = mgr->GetMedium("ITSssdRohacell50A");
+ SUPss = mgr->GetMedium("ITSssdStainlessSteal");
+ SUPair = mgr->GetMedium("ITSssdAir");
+ SUPal = mgr->GetMedium("ITSssdAl");
+ SUPwater = mgr->GetMedium("ITSssdWater");
+ //
+ Int_t i,j;
+ Double_t x,y,z,t,t0,dt,di,r;
+
+ // RB 24 side
+ const Double_t Z024 = 900*kmm;//SSup_203A.jpg
+ const Double_t ThssFrame24 = 5.0*kmm;
+ const Double_t RssFrame24 = 444.5*kmm-ThssFrame24; // SSup_204A.jpg
+ const Double_t WidthFrame24 = 10.0*kmm;
+ const Double_t HightFrame24 = 10.0*kmm;
+ const Double_t Phi0Frame24 = 15.2*kDegree; // SSup_602A.jpg
+ const Double_t Phi1Frame24 = (90.0-7.6)*kDegree; // SSup_802A.jpg
+ const Double_t ZssFrameSection24 = (415.0-10.0)*kmm;
+ const Int_t NZsections24 = 4;
+ const Int_t NPhiSections24 = 4;
+ const Int_t NFramesPhi24 = 4;
+ //
+ TGeoTubeSeg *M24 = new TGeoTubeSeg("ITS sup Cable tray support frame "
+ "mother volume M24",
+ RssFrame24,RssFrame24+ThssFrame24,
+ 0.5*(4.*ZssFrameSection24+5*WidthFrame24),
+ Phi0Frame24,Phi1Frame24);
+ TGeoTubeSeg *A24 = new TGeoTubeSeg("ITS sup Cable tray support frame "
+ "radial section A24",
+ RssFrame24,RssFrame24+ThssFrame24,0.5*WidthFrame24,
+ Phi0Frame24,Phi1Frame24);
+ TGeoBBox *B24 = new TGeoBBox("ITS sup Cable tray support frame Z section "
+ "B24",
+ 0.5*ThssFrame24,0.5*HightFrame24,0.5*ZssFrameSection24);
+ printTubeSeg(A24);
+ printTubeSeg(M24);
+ printBBox(B24);
+ TGeoVolume *A24v,*B24v,*M24v;
+ TGeoTranslation *tran;
+ TGeoRotation *rot;
+ TGeoCombiTrans *tranrot;
+ //
+ A24v = new TGeoVolume("ITSsupFrameA24",A24,SUPss);
+ A24v->SetVisibility(kTRUE);
+ A24v->SetLineColor(1); // black
+ A24v->SetLineWidth(1);
+ A24v->SetFillColor(A24v->GetLineColor());
+ A24v->SetFillStyle(4000); // 0% transparent
+ B24v = new TGeoVolume("ITSsupFrameB24",B24,SUPss);
+ B24v->SetVisibility(kTRUE);
+ B24v->SetLineColor(1); // black
+ B24v->SetLineWidth(1);
+ B24v->SetFillColor(B24v->GetLineColor());
+ B24v->SetFillStyle(4000); // 0% transparent
+ M24v = new TGeoVolume("ITSsupFrameM24",M24,SUPair);
+ M24v->SetVisibility(kTRUE);
+ M24v->SetLineColor(7); // light blue
+ M24v->SetLineWidth(1);
+ M24v->SetFillColor(M24v->GetLineColor());
+ M24v->SetFillStyle(4090); // 90% transparent
+ //
+ Int_t NcA24=1,NcB24=1;
+ t0 = Phi0Frame24;
+ dt = (Phi1Frame24-Phi0Frame24)/((Double_t)NPhiSections24);
+ for(i=0;i<=NZsections24;i++){
+ di = (Double_t) i;
+ z = -M24->GetDz()+A24->GetDz() + di*(ZssFrameSection24+WidthFrame24);
+ tran = new TGeoTranslation("",0.0,0.0,z);
+ M24v->AddNode(A24v,NcA24++,tran);
+ r = RssFrame24+B24->GetDX();
+ z = z + A24->GetDz()+B24->GetDZ();
+ if(i<NZsections24) for(j=0;j<=NPhiSections24;j++){
+ t = t0 + ((Double_t)j)*dt;
+ rot = new TGeoRotation("",0.0,0.0,t);
+ y = r*TMath::Sin(t*kRadian);
+ x = r*TMath::Cos(t*kRadian);
+ tranrot = new TGeoCombiTrans("",x,y,z,rot);
+ delete rot;// rot not explicity used in AddNode functions.
+ M24v->AddNode(B24v,NcB24++,tranrot);
+ } // end for j
+ } // end for i
+ tran = new TGeoTranslation("",0.0,0.0,Z024+M24->GetDz());
+ Moth->AddNode(M24v,1,tran);
+ for(i=1;i<NFramesPhi24;i++){
+ di = (Double_t) i;
+ rot = new TGeoRotation("",0.0,0.0,90.0*di);
+ tranrot = new TGeoCombiTrans("",0.0,0.0,Z024+M24->GetDz(),rot);
+ delete rot;// rot not explicity used in AddNode functions.
+ Moth->AddNode(M24v,i+1,tranrot);
+ } // end for i
+ if(GetDebug()){
+ A24v->PrintNodes();
+ B24v->PrintNodes();
+ M24v->PrintNodes();
+ } // end if
+ // Cable support tray
+ // Material is Aluminum
+ //const Double_t RS24in = TMath::Max(RssFrame24,444.5*kmm);
+ // SSup_204A & SSup_206A
+ //const Double_t RS24Airout = 459.5*kmm; // SSup_204A & SSup_206A
+ //const Double_t RS24out = 494.5*kmm; // SSup_206A & SSup_204A
+ //const Double_t RS24PPout = 550.0*kmm; // SSup_206A
+ const Double_t LS24PP = 350.0*kmm; // SSup_202A
+ const Double_t LS24 = (2693.0-900.0)*kmm; //SSup_205A & SSup_207A
+ const Double_t ThS24wall = 1.0*kmm; // SSup_209A & SSup_210A
+ const Double_t WbS24 = 42.0*kmm; // SSup_209A & SSup_210A
+ //const Double_t WtS24 = 46.9*kmm; // SSup_209A & SSup_210A
+ const Double_t WcapS24 = 50.0*kmm; // SSup_209A & SSup_210A
+ //const Double_t WdS24 = 41.0*kmm; //SSup_209A ? should be 41.46938776
+ const Double_t HS24 = 50.0*kmm; // SSup_209A & SSup_210A
+ const Double_t OutDcoolTub= 12.0*kmm; // SSup_209A
+ const Double_t InDcoolTub = 10.0*kmm; // SSup_209A
+ const Double_t BlkNozInDS24= 6.0*kmm; // SSup_209A
+ // The following are deduced or guessed at
+ //const Double_t LtopLipS24 = 6.0*kmm; // Guessed at.
+ //const Double_t LdLipS24 = 6.0*kmm; // Guessed at.
+ //const Double_t HdS24 = OutDcoolTub; //
+ const Double_t BlkNozZS24 = 6.0*kmm; // Guessed at.
+ // Simplifided exterior shape. The side wall size is 2.5*thicker than
+ // it should be (due to simplification).
+ TGeoArb8 *C24 = new TGeoArb8("ITS Sup Cable Tray Element C24",0.5*LS24);
+ C24->SetVertex(0,-0.5*WcapS24,HS24+ThS24wall);
+ C24->SetVertex(1,+0.5*WcapS24,HS24+ThS24wall);
+ C24->SetVertex(2,+0.5*WbS24,0.0);
+ C24->SetVertex(3,-0.5*WbS24,0.0);
+ C24->SetVertex(4,-0.5*WcapS24,HS24+ThS24wall);
+ C24->SetVertex(5,+0.5*WcapS24,HS24+ThS24wall);
+ C24->SetVertex(6,+0.5*WbS24,0.0);
+ C24->SetVertex(7,-0.5*WbS24,0.0);
+ TGeoArb8 *D24 = new TGeoArb8("ITS Sup Cable Tray lower Element D24",
+ 0.5*LS24);
+ // Because of question about the value of WdS24, compute what it
+ // should be assuming cooling tube fixes hight of volume.
+ x = OutDcoolTub*(0.5*WcapS24-0.5*WbS24-ThS24wall)/(HS24-ThS24wall);
+ D24->SetVertex(0,-x,OutDcoolTub+ThS24wall);
+ D24->SetVertex(1,+x,OutDcoolTub+ThS24wall);
+ D24->SetVertex(2,+0.5*WbS24-ThS24wall,ThS24wall);
+ D24->SetVertex(3,-0.5*WbS24+ThS24wall,ThS24wall);
+ D24->SetVertex(4,-x,OutDcoolTub+ThS24wall);
+ D24->SetVertex(5,+x,OutDcoolTub+ThS24wall);
+ D24->SetVertex(6,+0.5*WbS24-ThS24wall,ThS24wall);
+ D24->SetVertex(7,-0.5*WbS24+ThS24wall,ThS24wall);
+ TGeoTube *E24 = new TGeoTube("ITS Sup Cooling Tube E24",0.5*InDcoolTub,
+ 0.5*OutDcoolTub,0.5*LS24-BlkNozZS24);
+ TGeoArb8 *F24 = new TGeoArb8("ITS Sup Cable Tray lower Element block F24",
+ 0.5*BlkNozZS24);
+ for(i=0;i<8;i++) F24->SetVertex(i,D24->GetVertices()[i*2+0],
+ D24->GetVertices()[i*2+1]); //
+ TGeoTube *G24 = new TGeoTube("ITS Sup Cooling Tube hole in block G24",
+ 0.0,0.5*BlkNozInDS24,0.5*BlkNozZS24);
+ TGeoArb8 *H24 = new TGeoArb8("ITS Sup Cable Tray upper Element H24",
+ 0.5*(LS24- LS24PP));
+ H24->SetVertex(0,C24->GetVertices()[0*2+0]+2.*ThS24wall,
+ C24->GetVertices()[0*2+1]-ThS24wall);
+ H24->SetVertex(1,C24->GetVertices()[1*2+0]-2.*ThS24wall,
+ C24->GetVertices()[1*2+1]-ThS24wall);
+ H24->SetVertex(2,D24->GetVertices()[1*2+0]-ThS24wall,
+ D24->GetVertices()[1*2+1]+ThS24wall);
+ H24->SetVertex(3,D24->GetVertices()[0*2+0]+ThS24wall,
+ D24->GetVertices()[0*2+1]+ThS24wall);
+ for(i=4;i<8;i++) H24->SetVertex(i,H24->GetVertices()[(i-4)*2+0],
+ H24->GetVertices()[(i-4)*2+1]); //
+ printArb8(C24);
+ printArb8(D24);
+ printTube(E24);
+ printArb8(F24);
+ printTube(G24);
+ printArb8(H24);
+ TGeoVolume *C24v,*D24v,*E24v,*F24v,*Ga24v,*Gw24v,*H24v;
+ //
+ C24v = new TGeoVolume("ITSsupCableTrayC24",C24,SUPal);
+ C24v->SetVisibility(kTRUE);
+ C24v->SetLineColor(6); //
+ C24v->SetLineWidth(1);
+ C24v->SetFillColor(C24v->GetLineColor());
+ C24v->SetFillStyle(4000); // 0% transparent
+ D24v = new TGeoVolume("ITSsupCableTrayLowerD24",D24,SUPair);
+ D24v->SetVisibility(kTRUE);
+ D24v->SetLineColor(6); //
+ D24v->SetLineWidth(1);
+ D24v->SetFillColor(D24v->GetLineColor());
+ D24v->SetFillStyle(4000); // 0% transparent
+ E24v = new TGeoVolume("ITSsupCableTrayCoolTubeE24",E24,SUPss);
+ E24v->SetVisibility(kTRUE);
+ E24v->SetLineColor(6); //
+ E24v->SetLineWidth(1);
+ E24v->SetFillColor(E24v->GetLineColor());
+ E24v->SetFillStyle(4000); // 0% transparent
+ F24v = new TGeoVolume("ITSsupCableTrayBlockF24",F24,SUPal);
+ F24v->SetVisibility(kTRUE);
+ F24v->SetLineColor(6); //
+ F24v->SetLineWidth(1);
+ F24v->SetFillColor(F24v->GetLineColor());
+ F24v->SetFillStyle(4000); // 0% transparent
+ Gw24v = new TGeoVolume("ITSsupCableTrayCoolantWaterG24",G24,SUPwater);
+ Gw24v->SetVisibility(kTRUE);
+ Gw24v->SetLineColor(6); //
+ Gw24v->SetLineWidth(1);
+ Gw24v->SetFillColor(Gw24v->GetLineColor());
+ Gw24v->SetFillStyle(4000); // 0% transparent
+ Ga24v = new TGeoVolume("ITSsupCableTrayCoolantAirG24",G24,SUPair);
+ Ga24v->SetVisibility(kTRUE);
+ Ga24v->SetLineColor(6); //
+ Ga24v->SetLineWidth(1);
+ Ga24v->SetFillColor(Ga24v->GetLineColor());
+ Ga24v->SetFillStyle(4000); // 0% transparent
+ H24v = new TGeoVolume("ITSsupCableTrayUpperC24",H24,SUPair);
+ H24v->SetVisibility(kTRUE);
+ H24v->SetLineColor(6); //
+ H24v->SetLineWidth(1);
+ H24v->SetFillColor(H24v->GetLineColor());
+ H24v->SetFillStyle(4000); // 0% transparent
+ //
+ tran = new TGeoTranslation("",-OutDcoolTub,OutDcoolTub+ThS24wall,0.0);
+ F24v->AddNode(Gw24v,1,tran);
+ D24v->AddNode(E24v,1,tran);
+ tran = new TGeoTranslation("",0.0,OutDcoolTub+ThS24wall,0.0);
+ F24v->AddNode(Gw24v,2,tran);
+ D24v->AddNode(E24v,2,tran);
+ tran = new TGeoTranslation("",+OutDcoolTub,OutDcoolTub+ThS24wall,0.0);
+ F24v->AddNode(Gw24v,3,tran);
+ D24v->AddNode(E24v,3,tran);
+ tran = new TGeoTranslation("",0.0,0.0,0.5*LS24-0.5*BlkNozZS24);
+ D24v->AddNode(F24v,1,tran);
+ tran = new TGeoTranslation("",0.0,0.0,-(0.5*LS24-0.5*BlkNozZS24));
+ D24v->AddNode(F24v,2,tran);
+ C24v->AddNode(D24v,1,0);
+ C24v->AddNode(H24v,1,0);
+ //==================================================================
+ //
+ // RB 26 side
+ const Double_t Z026 = -900*kmm;//SSup_203A.jpg
+ const Double_t ThssFrame26 = 5.0*kmm;
+ const Double_t R0ssFrame26 = 444.5*kmm-ThssFrame26; // SSup_204A.jpg
+ const Double_t R1ssFrame26 = 601.6*kmm-ThssFrame26; // SSup_208A.jpg
+ const Double_t WidthFrame26 = 10.0*kmm;
+ //const Double_t HightFrame26 = 10.0*kmm;
+ const Double_t Phi0Frame26 = 15.2*kDegree; // SSup_602A.jpg
+ const Double_t Phi1Frame26 = (90.0-7.6)*kDegree; // SSup_802A.jpg
+ const Double_t ZssFrameSection26 = (415.0-10.0)*kmm;
+ const Int_t NZsections26 = 4;
+ const Int_t NPhiSections26 = 4;
+ const Int_t NFramesPhi26 = 4;
+ TGeoConeSeg *A26[NZsections26+1],*M26; // Cylinderial support structure
+ TGeoArb8 *B26; // Cylinderial support structure
+ Char_t name[100];
+ Double_t r1,r2,m;
+
+ M26 = new TGeoConeSeg("ITS sup Cable tray support frame mother volume "
+ "M26",0.5*(4.*ZssFrameSection26+5*WidthFrame26),
+ R1ssFrame26,R1ssFrame26+ThssFrame26,
+ R0ssFrame26,R0ssFrame26+ThssFrame26,
+ Phi0Frame26,Phi1Frame26);
+ m = -((R1ssFrame26-R0ssFrame26)/
+ (((Double_t)NZsections26)*(ZssFrameSection26+WidthFrame26)));
+ for(i=0;i<NZsections26+1;i++){
+ di = ((Double_t) i)*(ZssFrameSection26+WidthFrame26);
+ sprintf(name,
+ "ITS sup Cable tray support frame radial section A26[%d]",i);
+ r1 = R1ssFrame26+m*di;
+ r2 = R1ssFrame26+m*(di+WidthFrame26);
+ A26[i] = new TGeoConeSeg(name,0.5*WidthFrame26,r2,r2+ThssFrame26,
+ r1,r1+ThssFrame26,Phi0Frame26,Phi1Frame26);
+ } // end for i
+ B26 = new TGeoArb8("ITS sup Cable tray support frame Z section B26",
+ 0.5*ZssFrameSection26);
+ r = 0.25*(A26[0]->GetRmax1()+A26[0]->GetRmin1()+
+ A26[1]->GetRmax2()+A26[1]->GetRmin2());
+ B26->SetVertex(0,A26[0]->GetRmax2()-r,+0.5*WidthFrame26);
+ B26->SetVertex(1,A26[0]->GetRmax2()-r,-0.5*WidthFrame26);
+ B26->SetVertex(2,A26[0]->GetRmin2()-r,-0.5*WidthFrame26);
+ B26->SetVertex(3,A26[0]->GetRmin2()-r,+0.5*WidthFrame26);
+ B26->SetVertex(4,A26[1]->GetRmax1()-r,+0.5*WidthFrame26);
+ B26->SetVertex(5,A26[1]->GetRmax1()-r,-0.5*WidthFrame26);
+ B26->SetVertex(6,A26[1]->GetRmin1()-r,-0.5*WidthFrame26);
+ B26->SetVertex(7,A26[1]->GetRmin1()-r,+0.5*WidthFrame26);
+ for(i=0;i<NZsections26+1;i++) printConeSeg(A26[i]);
+ printConeSeg(M26);
+ printArb8(B26);
+ TGeoVolume *A26v[NZsections26+1],*B26v,*M26v;
+ //
+ for(i=0;i<NZsections26+1;i++){
+ sprintf(name,"ITSsupFrameA26[%d]",i);
+ A26v[i] = new TGeoVolume(name,A26[i],SUPss);
+ A26v[i]->SetVisibility(kTRUE);
+ A26v[i]->SetLineColor(1); // black
+ A26v[i]->SetLineWidth(1);
+ A26v[i]->SetFillColor(A26v[i]->GetLineColor());
+ A26v[i]->SetFillStyle(4000); // 0% transparent
+ } // end for i
+ B26v = new TGeoVolume("ITSsupFrameB26",B26,SUPss);
+ B26v->SetVisibility(kTRUE);
+ B26v->SetLineColor(1); // black
+ B26v->SetLineWidth(1);
+ B26v->SetFillColor(B26v->GetLineColor());
+ B26v->SetFillStyle(4000); // 0% transparent
+ M26v = new TGeoVolume("ITSsupFrameM26",M26,SUPair);
+ M26v->SetVisibility(kTRUE);
+ M26v->SetLineColor(7); // light blue
+ M26v->SetLineWidth(1);
+ M26v->SetFillColor(M26v->GetLineColor());
+ M26v->SetFillStyle(4090); // 90% transparent
+ //
+ Int_t NcB26=1;
+ t0 = Phi0Frame26;
+ dt = (Phi1Frame26-Phi0Frame26)/((Double_t)NPhiSections26);
+ for(i=0;i<=NZsections26;i++){
+ di = ((Double_t) i)*(ZssFrameSection26+WidthFrame26);
+ z = -M26->GetDz()+A26[i]->GetDz() + di;
+ tran = new TGeoTranslation("",0.0,0.0,z);
+ M26v->AddNode(A26v[i],1,tran);
+ z = z+B26->GetDz();
+ if(i<NZsections26)for(j=0;j<=NPhiSections26;j++){
+ r = 0.25*(A26[i]->GetRmax1()+A26[i]->GetRmin1()+
+ A26[i+1]->GetRmax2()+A26[i+1]->GetRmin2());
+ t = t0 + ((Double_t)j)*dt;
+ rot = new TGeoRotation("",0.0,0.0,t);
+ y = r*TMath::Sin(t*kRadian);
+ x = r*TMath::Cos(t*kRadian);
+ tranrot = new TGeoCombiTrans("",x,y,z,rot);
+ delete rot; // rot not explicity used in AddNode functions.
+ M26v->AddNode(B26v,NcB26++,tranrot);
+ } // end for j
+ } // end for i
+ tran = new TGeoTranslation("",0.0,0.0,Z026-M26->GetDz());
+ Moth->AddNode(M26v,1,tran);
+ for(i=1;i<NFramesPhi26;i++){
+ rot = new TGeoRotation("",0.0,0.0,90.0*((Double_t)i));
+ tranrot = new TGeoCombiTrans(*tran,*rot);
+ delete rot; // rot not explicity used in AddNode functions.
+ Moth->AddNode(M26v,i+1,tranrot);
+ } // end for i
+ if(GetDebug()){
+ for(i=0;i<NZsections26+1;i++) A26v[i]->PrintNodes();
+ B26v->PrintNodes();
+ M26v->PrintNodes();
+ } // end if
+}
--- /dev/null
+#ifndef ALIITSV11GEOMETRYSUPPORT_H
+#define ALIITSV11GEOMETRYSUPPORT_H
+/* Copyright(c) 1998-1999, ALICE Experiment at CERN, All rights reserved. *
+ * See cxx source for full Copyright notice */
+
+/*
+ $Id$
+ */
+#include <AliITSv11Geometry.h>
+class TGeoVolume;
+
+class AliITSv11GeometrySupport : public AliITSv11Geometry {
+ public:
+ AliITSv11GeometrySupport(){};
+ AliITSv11GeometrySupport(Bool_t debug):AliITSv11Geometry(debug){};
+ virtual ~AliITSv11GeometrySupport(){};
+ //
+ virtual void SPDCone(TGeoVolume *Moth);
+ virtual void SPDThermalSheald(TGeoVolume *Moth);
+ virtual void SDDCone(TGeoVolume *Moth);
+ virtual void SSDCone(TGeoVolume *Moth);
+ virtual void ServicesCableSupport(TGeoVolume *Moth);
+
+ private:
+ ClassDef(AliITSv11GeometrySupport,1) // ITS v11 Support geometry
+};
+
+#endif