/************************************************************************** * 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. * **************************************************************************/ // $Id$ //************************************************************************* // Class for flat cables // // Ludovic Gaudichet gaudichet@to.infn.it //************************************************************************* // General Root includes //#include #include #include // Root Geometry includes #include #include #include #include #include #include #include "AliITSv11GeomCableFlat.h" ClassImp(AliITSv11GeomCableFlat) //________________________________________________________________________ AliITSv11GeomCableFlat::AliITSv11GeomCableFlat(): AliITSv11GeomCable(), fWidth(0), fThick(0), fNlayer(0) { // constructor for (Int_t i=0; iGetElements()); #else CopyFrom(coord, coordVector->GetMatrixArray()); #endif return kTRUE; } else { return kFALSE; }; } //________________________________________________________________________ Int_t AliITSv11GeomCableFlat::GetVect( Int_t iCheckPt, Double_t *coord) const { // Get the correct vect corresponding to point #iCheckPt TVectorD *coordVector =(TVectorD *)fPointArray.At(2*iCheckPt+1); if (coordVector) { #if ROOT_VERSION_CODE < ROOT_VERSION(4,0,0) CopyFrom(coord, coordVector->GetElements()); #else CopyFrom(coord, coordVector->GetMatrixArray()); #endif return kTRUE; } else { return kFALSE; }; } //________________________________________________________________________ void AliITSv11GeomCableFlat::AddCheckPoint( TGeoVolume *vol, Int_t iCheckPt, Double_t *coord, Double_t *orthVect) { // // Add a check point. In the fPointArray, the point is at i and its vector // is at i+1. // // if (iCheckPt>=fVolumeArray.GetEntriesFast()) { // fVolumeArray.AddLast(vol); // TVectorD *point = new TVectorD(3,coord); // TVectorD *vect = new TVectorD(3,orthVect); // fPointArray.AddLast(point); // fPointArray.AddLast(vect); // } else if ((iCheckPt >= 0)&&(iCheckPt < fVolumeArray.GetEntriesFast())) { // fVolumeArray.AddAt(vol, iCheckPt); // TVectorD *point = new TVectorD(3,coord); // TVectorD *vect = new TVectorD(3,orthVect); // fPointArray.AddAt(point, iCheckPt*2 ); // fPointArray.AddAt(vect, iCheckPt*2+1); // }; fVolumeArray.AddAtAndExpand(vol, iCheckPt); TVectorD *point = new TVectorD(3,coord); TVectorD *vect = new TVectorD(3,orthVect); fPointArray.AddAtAndExpand(point, iCheckPt*2 ); fPointArray.AddAtAndExpand(vect, iCheckPt*2+1); } //________________________________________________________________________ void AliITSv11GeomCableFlat::PrintCheckPoints() const { // print all check points of the cable printf(" ---\n Printing all check points of the flat cable\n"); for (Int_t i = 0; iGetListOfNodes(); if (nodes->GetEntriesFast()==0) return 0; mainNode = (TGeoNode *) nodes->UncheckedAt(0); } else { mainNode = fInitialNode; }; Int_t p1 = p2 - 1; TGeoVolume *p2Vol = GetVolume(p2); TGeoVolume *p1Vol = GetVolume(p1); ResetCheckDaughter(); fCurrentVol = p1Vol; if (! CheckDaughter(mainNode)) { printf("Error::volume containing point is not visible in node tree!\n"); return 0; }; Double_t coord1[3], coord2[3], vect1[3], vect2[3]; //================================================= // Get p1 position in the systeme of p2 if (p1Vol!=p2Vol) { Int_t p1nodeInd[fgkCableMaxNodeLevel]; for (Int_t i=0; iGetDaughter(p2nodeInd[i]); }; Double_t globalCoord1[3] = {coord1[0], coord1[1], coord1[2]}; Double_t globalVect1[3] = {vect1[0], vect1[1], vect1[2]}; for (Int_t i = commonMotherLevel+1; i <= p2volLevel; i++) { pathNode[i+1]->GetMatrix()->MasterToLocal(globalCoord1, coord1); pathNode[i+1]->GetMatrix()->MasterToLocalVect(globalVect1, vect1); CopyFrom(globalCoord1, coord1); CopyFrom(globalVect1, vect1); }; } else { if (! GetCheckPoint(p1, 0, 0, coord1) ) return 0; if (! GetCheckVect(p1, 0, 0, vect1) ) return 0; }; //================================================= // Get p2 position in the systeme of p2 if (! GetCheckPoint(p2, 0, 0, coord2) ) return 0; if (! GetCheckVect(p2, 0, 0, vect2) ) return 0; Double_t cx = (coord1[0]+coord2[0])/2; Double_t cy = (coord1[1]+coord2[1])/2; Double_t cz = (coord1[2]+coord2[2])/2; Double_t dx = coord2[0]-coord1[0]; Double_t dy = coord2[1]-coord1[1]; Double_t dz = coord2[2]-coord1[2]; //================================================= // Positionning of the segment between the 2 points if (TMath::Abs(dy)<1e-231) dy = 1e-231; if (TMath::Abs(dz)<1e-231) dz = 1e-231; //Double_t angleRot1 = -TMath::ATan(dx/dy); //Double_t planDiagL = -TMath::Sqrt(dy*dy+dx*dx); //if (dy<0) planDiagL = -planDiagL; //Double_t angleRotDiag = TMath::ATan(planDiagL/dz); Double_t angleRot1 = -TMath::ATan2(dx,dy); Double_t planDiagL = TMath::Sqrt(dy*dy+dx*dx); Double_t angleRotDiag = -TMath::ATan2(planDiagL,dz); //--- (Calculate rotation of segment on the Z axis) //-- Here I'm trying to calculate the rotation to be applied in //-- order to match as closer as possible this segment and the //-- previous one. //-- It seems that some times it doesn't work ... TGeoRotation rotTemp("",angleRot1*TMath::RadToDeg(), angleRotDiag*TMath::RadToDeg(), rotation); Double_t localX[3] = {0,1,0}; Double_t globalX[3]; rotTemp.LocalToMasterVect(localX, globalX); CopyFrom(localX, globalX); GetCheckVect(localX, p2Vol, 0, fgkCableMaxNodeLevel+1, globalX); Double_t orthVect[3]; GetCheckVect(vect1, p2Vol, 0, fgkCableMaxNodeLevel+1, orthVect); // Double_t angleRotZ = 0; // if (p2>1) { // Double_t orthVectNorm2 = ScalProd(orthVect,orthVect); // Double_t alpha1 = ScalProd(fPreviousX,orthVect)/orthVectNorm2; // Double_t alpha2 = ScalProd(globalX,orthVect)/orthVectNorm2; // Double_t globalX1p[3], globalX2p[3]; // globalX1p[0] = fPreviousX[0] - alpha1*orthVect[0]; // globalX1p[1] = fPreviousX[1] - alpha1*orthVect[1]; // globalX1p[2] = fPreviousX[2] - alpha1*orthVect[2]; // globalX2p[0] = globalX[0] - alpha2*orthVect[0]; // globalX2p[1] = globalX[1] - alpha2*orthVect[1]; // globalX2p[2] = globalX[2] - alpha2*orthVect[2]; // //-- now I'm searching the 3th vect which makes an orthogonal base // //-- with orthVect and globalX1p ... // Double_t nulVect[3] = {0,0,0}; // Double_t axis3[3]; // TMath::Normal2Plane(nulVect, orthVect, globalX1p, axis3); // Double_t globalX1pNorm2 = ScalProd(globalX1p, globalX1p); // Double_t beta = ScalProd(globalX2p, globalX1p)/globalX1pNorm2; // Double_t gamma = ScalProd(globalX2p, axis3); // angleRotZ = (TMath::ATan2(1,0) - TMath::ATan2(beta, gamma)) // *TMath::RadToDeg(); // }; // cout << "!!!!!!!!!!!!!!!!!!! angle = " <AddNode(vCableSegB, p2, combiB); //=================================================; if (fDebug) { printf("---\n Cable segment points : "); printf("%f, %f, %f\n",coord1[0], coord1[1], coord1[2]); printf("%f, %f, %f\n",coord2[0], coord2[1], coord2[2]); }; // #include // TGeoMedium *airSDD = gGeoManager->GetMedium("ITS_AIR$"); // TGeoSphere *sphere = new TGeoSphere(0, 0.05); // TGeoVolume *vSphere = new TGeoVolume("", sphere, airSDD); // TGeoTranslation *trC = new TGeoTranslation("", cx, cy, cz); // TGeoTranslation *tr1 = new TGeoTranslation("",coord1[0], // coord1[1],coord1[2]); // TGeoTranslation *tr2 = new TGeoTranslation("",coord2[0], // coord2[1],coord2[2]); // p2Vol->AddNode(vSphere, p2*3-2, trC); // p2Vol->AddNode(vSphere, p2*3-1, tr1); // p2Vol->AddNode(vSphere, p2*3 , tr2); if (ct) *ct = combiB; return vCableSegB; } //________________________________________________________________________ TGeoVolume* AliITSv11GeomCableFlat::CreateAndInsertBoxCableSegment(Int_t p2, Double_t rotation, TGeoCombiTrans** ct) { // This function is to be use only when the segment has the shape // of a simple box, i.e. the normal vector to its end is perpendicular // to the segment own axis // Creates a cable segment between points p1 and p2. // Rotation is the eventual rotation of the flat cable // along its length axis // // The segment volume is created inside the volume containing point2 // Therefore this segment should be defined in this volume only. // I mean here that, if the previous point is in another volume, // it should be just at the border between the 2 volumes. Also the // orientation vector of the previous point should be orthogonal to // the surface between the 2 volumes. TGeoNode *mainNode; if (fInitialNode==0) { TObjArray *nodes = gGeoManager->GetListOfNodes(); if (nodes->GetEntriesFast()==0) return 0; mainNode = (TGeoNode *) nodes->UncheckedAt(0); } else { mainNode = fInitialNode; }; Int_t p1 = p2 - 1; TGeoVolume *p2Vol = GetVolume(p2); TGeoVolume *p1Vol = GetVolume(p1); ResetCheckDaughter(); fCurrentVol = p1Vol; if (! CheckDaughter(mainNode)) { printf("Error::volume containing point is not visible in node tree!\n"); return 0; }; Double_t coord1[3], coord2[3], vect1[3], vect2[3]; //================================================= // Get p1 position in the systeme of p2 if (p1Vol!=p2Vol) { Int_t p1nodeInd[fgkCableMaxNodeLevel]; for (Int_t i=0; iGetDaughter(p2nodeInd[i]); }; Double_t globalCoord1[3] = {coord1[0], coord1[1], coord1[2]}; Double_t globalVect1[3] = {vect1[0], vect1[1], vect1[2]}; for (Int_t i = commonMotherLevel+1; i <= p2volLevel; i++) { pathNode[i+1]->GetMatrix()->MasterToLocal(globalCoord1, coord1); pathNode[i+1]->GetMatrix()->MasterToLocalVect(globalVect1, vect1); CopyFrom(globalCoord1, coord1); CopyFrom(globalVect1, vect1); }; } else { if (! GetCheckPoint(p1, 0, 0, coord1) ) return 0; if (! GetCheckVect(p1, 0, 0, vect1) ) return 0; }; //================================================= // Get p2 position in the systeme of p2 if (! GetCheckPoint(p2, 0, 0, coord2) ) return 0; if (! GetCheckVect(p2, 0, 0, vect2) ) return 0; Double_t cx = (coord1[0]+coord2[0])/2; Double_t cy = (coord1[1]+coord2[1])/2; Double_t cz = (coord1[2]+coord2[2])/2; Double_t dx = coord2[0]-coord1[0]; Double_t dy = coord2[1]-coord1[1]; Double_t dz = coord2[2]-coord1[2]; //================================================= // Positionning of the segment between the 2 points if (TMath::Abs(dy)<1e-231) dy = 1e-231; if (TMath::Abs(dz)<1e-231) dz = 1e-231; //Double_t angleRot1 = -TMath::ATan(dx/dy); //Double_t planDiagL = -TMath::Sqrt(dy*dy+dx*dx); //if (dy<0) planDiagL = -planDiagL; //Double_t angleRotDiag = TMath::ATan(planDiagL/dz); Double_t angleRot1 = -TMath::ATan2(dx,dy); Double_t planDiagL = TMath::Sqrt(dy*dy+dx*dx); Double_t angleRotDiag = -TMath::ATan2(planDiagL,dz); //--- (Calculate rotation of segment on the Z axis) //-- Here I'm trying to calculate the rotation to be applied in //-- order to match as closer as possible this segment and the //-- previous one. //-- It seems that some times it doesn't work ... TGeoRotation rotTemp("",angleRot1*TMath::RadToDeg(), angleRotDiag*TMath::RadToDeg(), rotation); Double_t localX[3] = {0,1,0}; Double_t globalX[3]; rotTemp.LocalToMasterVect(localX, globalX); CopyFrom(localX, globalX); GetCheckVect(localX, p2Vol, 0, fgkCableMaxNodeLevel+1, globalX); Double_t orthVect[3]; GetCheckVect(vect1, p2Vol, 0, fgkCableMaxNodeLevel+1, orthVect); // Double_t angleRotZ = 0; // if (p2>1) { // Double_t orthVectNorm2 = ScalProd(orthVect,orthVect); // Double_t alpha1 = ScalProd(fPreviousX,orthVect)/orthVectNorm2; // Double_t alpha2 = ScalProd(globalX,orthVect)/orthVectNorm2; // Double_t globalX1p[3], globalX2p[3]; // globalX1p[0] = fPreviousX[0] - alpha1*orthVect[0]; // globalX1p[1] = fPreviousX[1] - alpha1*orthVect[1]; // globalX1p[2] = fPreviousX[2] - alpha1*orthVect[2]; // globalX2p[0] = globalX[0] - alpha2*orthVect[0]; // globalX2p[1] = globalX[1] - alpha2*orthVect[1]; // globalX2p[2] = globalX[2] - alpha2*orthVect[2]; // //-- now I'm searching the 3th vect which makes an orthogonal base // //-- with orthVect and globalX1p ... // Double_t nulVect[3] = {0,0,0}; // Double_t axis3[3]; // TMath::Normal2Plane(nulVect, orthVect, globalX1p, axis3); // Double_t globalX1pNorm2 = ScalProd(globalX1p, globalX1p); // Double_t beta = ScalProd(globalX2p, globalX1p)/globalX1pNorm2; // Double_t gamma = ScalProd(globalX2p, axis3); // angleRotZ = (TMath::ATan2(1,0) - TMath::ATan2(beta, gamma)) // *TMath::RadToDeg(); // }; CopyFrom(fPreviousX, globalX); //--- Double_t localVect1[3], localVect2[3]; TGeoRotation rot("",angleRot1*TMath::RadToDeg(), angleRotDiag*TMath::RadToDeg(), rotation); // rotation-angleRotZ); // since angleRotZ doesn't always work, I won't use it ... rot.MasterToLocalVect(vect1, localVect1); rot.MasterToLocalVect(vect2, localVect2); //================================================= // Create the segment and add it to the mother volume TGeoVolume *vCableSegB = CreateBoxSegment(coord1, coord2); TGeoRotation rotArbSeg("", 0, 90, 0); rotArbSeg.MultiplyBy(&rot, kFALSE); TGeoTranslation trans("",cx, cy, cz); TGeoCombiTrans *combiB = new TGeoCombiTrans(trans, rotArbSeg); p2Vol->AddNode(vCableSegB, p2, combiB); //=================================================; if (fDebug) { printf("---\n Cable segment points : "); printf("%f, %f, %f\n",coord1[0], coord1[1], coord1[2]); printf("%f, %f, %f\n",coord2[0], coord2[1], coord2[2]); }; if (ct) *ct = combiB; return vCableSegB; } //________________________________________________________________________ TGeoVolume* AliITSv11GeomCableFlat::CreateAndInsertCableCylSegment(Int_t p2, Double_t rotation, TGeoCombiTrans** ct) { // Create a flat cable segment with a curvature between points p1 and p2. // The radius and position of the curve is defined by the // perpendicular vector of point p2 (the orientation of this vector // and the position of the 2 check points are enough to completely // define the curve) // Rotation is the eventual rotation of the flat cable // along its length axis // TGeoNode *mainNode; if (fInitialNode==0) { TObjArray *nodes = gGeoManager->GetListOfNodes(); if (nodes->GetEntriesFast()==0) return 0; mainNode = (TGeoNode *) nodes->UncheckedAt(0); } else { mainNode = fInitialNode; }; Int_t p1 = p2 - 1; TGeoVolume *p1Vol = GetVolume(p1); TGeoVolume *p2Vol = GetVolume(p2); ResetCheckDaughter(); fCurrentVol = p1Vol; if (! CheckDaughter(mainNode)) { printf("Error::volume containing point is not visible in node tree!\n"); return 0; }; Double_t coord1[3], coord2[3], vect1[3], vect2[3]; //================================================= // Get p1 position in the systeme of p2 if (p1Vol!=p2Vol) { Int_t p1nodeInd[fgkCableMaxNodeLevel]; for (Int_t i=0; iGetDaughter(p2nodeInd[i]); }; Double_t globalCoord1[3] = {coord1[0], coord1[1], coord1[2]}; Double_t globalVect1[3] = {vect1[0], vect1[1], vect1[2]}; for (Int_t i = commonMotherLevel+1; i<=p2volLevel; i++) { pathNode[i+1]->GetMatrix()->MasterToLocal(globalCoord1, coord1); pathNode[i+1]->GetMatrix()->MasterToLocalVect(globalVect1, vect1); CopyFrom(globalCoord1, coord1); CopyFrom(globalVect1, vect1); }; } else { GetCheckPoint(p1, 0, 0, coord1); GetCheckVect(p1, 0, 0, vect1); }; //================================================= // Get p2 position in the systeme of p2 GetCheckPoint(p2, 0, 0, coord2); GetCheckVect(p2, 0, 0, vect2); Double_t cx = (coord1[0]+coord2[0])/2; Double_t cy = (coord1[1]+coord2[1])/2; Double_t cz = (coord1[2]+coord2[2])/2; Double_t dx = coord2[0]-coord1[0]; Double_t dy = coord2[1]-coord1[1]; Double_t dz = coord2[2]-coord1[2]; Double_t length = TMath::Sqrt(dx*dx+dy*dy+dz*dz); //================================================= // Positionning of the segment between the 2 points if ((dy<1e-31)&&(dy>0)) dy = 1e-31; if ((dz<1e-31)&&(dz>0)) dz = 1e-31; if ((dy>-1e-31)&&(dy<0)) dy = -1e-31; if ((dz>-1e-31)&&(dz<0)) dz = -1e-31; Double_t angleRot1 = -TMath::ATan2(dx,dy); Double_t planDiagL = TMath::Sqrt(dy*dy+dx*dx); Double_t angleRotDiag = -TMath::ATan2(planDiagL,dz); TGeoRotation rotTorusTemp("",angleRot1*TMath::RadToDeg(), angleRotDiag*TMath::RadToDeg(),0); TGeoRotation rotTorusToZ("",0,90,0); rotTorusTemp.MultiplyBy(&rotTorusToZ, kTRUE); Double_t localVect2[3]; rotTorusTemp.MasterToLocalVect(vect2, localVect2); if (localVect2[1]<0) { localVect2[0] = -localVect2[0]; localVect2[1] = -localVect2[1]; localVect2[2] = -localVect2[2]; }; Double_t normVect2 = TMath::Sqrt(localVect2[0]*localVect2[0]+ localVect2[1]*localVect2[1]+ localVect2[2]*localVect2[2]); Double_t axisX[3] = {1,0,0}; Double_t cosangleTorusSeg = (localVect2[0]*axisX[0]+ localVect2[1]*axisX[1]+ localVect2[2]*axisX[2])/normVect2; Double_t angleTorusSeg = TMath::ACos(cosangleTorusSeg)*TMath::RadToDeg(); TGeoRotation rotTorus("",angleRot1*TMath::RadToDeg(), angleRotDiag*TMath::RadToDeg(), 45-angleTorusSeg+rotation); //180-angleTorusSeg+rotation); rotTorus.MultiplyBy(&rotTorusToZ, kTRUE); rotTorus.MasterToLocalVect(vect2, localVect2); if (localVect2[1]<0) { localVect2[0] = -localVect2[0]; localVect2[1] = -localVect2[1]; localVect2[2] = -localVect2[2]; }; normVect2 = TMath::Sqrt(localVect2[0]*localVect2[0]+ localVect2[1]*localVect2[1]+ localVect2[2]*localVect2[2]); Double_t axisY[3] = {0,1,0}; Double_t cosPhi = (localVect2[0]*axisY[0]+localVect2[1]*axisY[1]+ localVect2[2]*axisY[2])/normVect2; Double_t torusPhi1 = TMath::ACos(cosPhi); Double_t torusR = (length/2)/TMath::Sin(torusPhi1); torusPhi1 = torusPhi1*TMath::RadToDeg(); Double_t perpLength = TMath::Sqrt(torusR*torusR-length*length/4); Double_t localTransT[3] = {-perpLength,0,0}; Double_t globalTransT[3]; rotTorus.LocalToMasterVect(localTransT, globalTransT); TGeoTranslation transTorus("",cx+globalTransT[0],cy+globalTransT[1], cz+globalTransT[2]); TGeoCombiTrans *combiTorus = new TGeoCombiTrans(transTorus, rotTorus); //================================================= // Create the segment and add it to the mother volume TGeoVolume *vCableSegT = CreateCylSegment(torusPhi1, torusR); p2Vol->AddNode(vCableSegT, p2, combiTorus); if (fDebug) { printf("---\n Cable segment points : "); printf("%f, %f, %f\n",coord1[0], coord1[1], coord1[2]); printf("%f, %f, %f\n",coord2[0], coord2[1], coord2[2]); }; if (ct) *ct = combiTorus; return vCableSegT; } //________________________________________________________________________ TGeoVolume *AliITSv11GeomCableFlat::CreateSegment( Double_t *coord1, Double_t *coord2, Double_t *localVect1, Double_t *localVect2 ) { // Create a segment with arbitrary vertices (general case) //================================================= // Calculate segment "deformation" Double_t dx = coord2[0]-coord1[0]; Double_t dy = coord2[1]-coord1[1]; Double_t dz = coord2[2]-coord1[2]; Double_t length = TMath::Sqrt(dx*dx+dy*dy+dz*dz); Double_t cosTheta1 = -1./TMath::Sqrt( 1 + localVect1[0]*localVect1[0] /localVect1[2]/localVect1[2] ); Double_t cosTheta2 = 1./TMath::Sqrt( 1 + localVect2[0]*localVect2[0] /localVect2[2]/localVect2[2] ); if (localVect1[2]<0) cosTheta1 = -cosTheta1; if (localVect2[2]<0) cosTheta2 = -cosTheta2; Double_t dL1 = 0.5*fWidth*TMath::Tan(TMath::ACos(cosTheta1)); Double_t dL2 = 0.5*fWidth*TMath::Tan(TMath::ACos(cosTheta2)); if (localVect1[0]<0) dL1 = - dL1; if (localVect2[0]<0) dL2 = - dL2; //--- Double_t cosPhi1 = -1./TMath::Sqrt( 1 + localVect1[1]*localVect1[1] /localVect1[2]/localVect1[2] ); Double_t cosPhi2 = 1./TMath::Sqrt( 1 + localVect2[1]*localVect2[1] /localVect2[2]/localVect2[2] ); if (localVect1[2]<0) cosPhi1 = -cosPhi1; if (localVect2[2]<0) cosPhi2 = -cosPhi2; Double_t tanACosCosPhi1 = TMath::Tan(TMath::ACos(cosPhi1)); Double_t tanACosCosPhi2 = TMath::Tan(TMath::ACos(cosPhi2)); if (localVect1[1]<0) tanACosCosPhi1 = -tanACosCosPhi1; if (localVect2[1]<0) tanACosCosPhi2 = -tanACosCosPhi2; Double_t dl1 = 0.5*fThick*tanACosCosPhi1*0.99999999999999; Double_t dl2 = 0.5*fThick*tanACosCosPhi2*0.99999999999999; // 0.9999999999999 is for correcting problems in TGeo... //================================================= // Create the segment TGeoArb8 *cableSeg = new TGeoArb8(fThick/2); cableSeg->SetVertex( 0, -fWidth/2, -length/2 - dL1 + dl1); cableSeg->SetVertex( 1, -fWidth/2, length/2 + dL2 - dl2); cableSeg->SetVertex( 2, fWidth/2, length/2 - dL2 - dl2); cableSeg->SetVertex( 3, fWidth/2, -length/2 + dL1 + dl1); cableSeg->SetVertex( 4, -fWidth/2, -length/2 - dL1 - dl1); cableSeg->SetVertex( 5, -fWidth/2, length/2 + dL2 + dl2); cableSeg->SetVertex( 6, fWidth/2, length/2 - dL2 + dl2); cableSeg->SetVertex( 7, fWidth/2, -length/2 + dL1 - dl1); TGeoVolume *vCableSeg = new TGeoVolume(GetName(), cableSeg, fLayMedia[fNlayer-1]); vCableSeg->SetLineColor(fLayColor[fNlayer-1]); // add all cable layers but the last for (Int_t iLay=0; iLaySetVertex( 0, -fWidth/2, -length/2 - dL1 + dl1Lay - dl1LayS); lay->SetVertex( 1, -fWidth/2, length/2 + dL2 - dl2Lay + dl2LayS); lay->SetVertex( 2, fWidth/2, length/2 - dL2 - dl2Lay + dl2LayS); lay->SetVertex( 3, fWidth/2, -length/2 + dL1 + dl1Lay - dl1LayS); lay->SetVertex( 4, -fWidth/2, -length/2 - dL1 - dl1Lay - dl1LayS); lay->SetVertex( 5, -fWidth/2, length/2 + dL2 + dl2Lay + dl2LayS); lay->SetVertex( 6, fWidth/2, length/2 - dL2 + dl2Lay + dl2LayS); lay->SetVertex( 7, fWidth/2, -length/2 + dL1 - dl1Lay - dl1LayS); TGeoVolume *vLay = new TGeoVolume("vCableSegLay", lay, fLayMedia[iLay]); vLay->SetLineColor(fLayColor[iLay]); if (fTranslation[iLay]==0) fTranslation[iLay] = new TGeoTranslation(0, 0, ztr); vCableSeg->AddNode(vLay, iLay+1, fTranslation[iLay]); }; //vCableSeg->SetVisibility(kFALSE); return vCableSeg; } //________________________________________________________________________ TGeoVolume *AliITSv11GeomCableFlat::CreateCylSegment(Double_t &phi, Double_t &r) { // Create a segment in shape of a cylinder, allows to represent // a folded flat cable Double_t phi1 = 360-phi; Double_t phi2 = 360+phi; Double_t rMin = r-fThick/2; Double_t rMax = r+fThick/2; //================================================= // Create the segment TGeoTubeSeg *cableSeg = new TGeoTubeSeg(rMin, rMax, fWidth/2, phi1, phi2); TGeoVolume *vCableSeg = new TGeoVolume(GetName(), cableSeg, fLayMedia[fNlayer-1]); vCableSeg->SetLineColor(fLayColor[fNlayer-1]); // add all cable layers but the last for (Int_t iLay=0; iLaySetLineColor(fLayColor[iLay]); vCableSeg->AddNode(vLay, iLay+1, 0); }; //vCableSeg->SetVisibility(kFALSE); return vCableSeg; } //________________________________________________________________________ TGeoVolume *AliITSv11GeomCableFlat::CreateBoxSegment( Double_t *coord1, Double_t *coord2) { // Create a segment for the case it is a simple box //================================================= Double_t dx = coord2[0]-coord1[0]; Double_t dy = coord2[1]-coord1[1]; Double_t dz = coord2[2]-coord1[2]; Double_t length = TMath::Sqrt(dx*dx+dy*dy+dz*dz); TGeoBBox *cableSeg = new TGeoBBox(fWidth/2, length/2, fThick/2); TGeoVolume *vCableSeg = new TGeoVolume(GetName(), cableSeg, fLayMedia[fNlayer-1]); vCableSeg->SetLineColor(fLayColor[fNlayer-1]); // This volume is the cable container. It codes also the material for the // last layer // add all cable layers but the last one for (Int_t iLay=0; iLaySetLineColor(fLayColor[iLay]); if (fTranslation[iLay]==0) fTranslation[iLay] = new TGeoTranslation(0, 0, ztr); vCableSeg->AddNode(vLay, iLay+1, fTranslation[iLay]); }; //vCableSeg->SetVisibility(kFALSE); return vCableSeg; } //________________________________________________________________________ void AliITSv11GeomCableFlat::SetNLayers(Int_t nLayers) { // Set the number of layers if((nLayers>0) &&(nLayers<=fgkCableMaxLayer)) { fNlayer = nLayers; for (Int_t i=0; i=fNlayer)) { printf("Set wrong layer number of the cable\n"); return kFALSE; }; if (nLayer>0) if (fLayThickness[nLayer-1]<=0) { printf("AliITSv11GeomCableFlat::SetLayer():" " You must define cable layer %i first !",nLayer-1); return kFALSE; }; Double_t thickTot = 0; for (Int_t i=0; ifThick) { printf("Can't add this layer, cable thickness would be higher than total\n"); return kFALSE; }; fLayThickness[nLayer] = thick; fLayMedia[nLayer] = medium; fLayColor[nLayer] = color; fTranslation[nLayer] = 0; return kTRUE; }