/************************************************************************** * 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. * **************************************************************************/ /* $Id$ */ //------------------------------------------------------------------------- // MUON shielding class // Default version // Author: A.Morsch //------------------------------------------------------------------------- #include #include #include #include #include #include #include #include #include #include #include "AliSHILv2.h" #include "AliConst.h" #include "AliLog.h" ClassImp(AliSHILv2) //_____________________________________________________________________________ AliSHILv2::AliSHILv2(): fPbCone(kTRUE), fWriteGeometry(kFALSE) { // // Default constructor for muon shield // } //_____________________________________________________________________________ AliSHILv2::AliSHILv2(const char *name, const char *title) : AliSHIL(name,title), fPbCone(kTRUE), fWriteGeometry(kFALSE) { // // Standard constructor for muon shield // // Pb cone not yet compatible with muon chamber inner radii // Switched off by default } //_____________________________________________________________________________ void AliSHILv2::CreateGeometry() { // // Build muon shield geometry // // //Begin_Html /* */ //End_Html //Begin_Html /* */ //End_Html Float_t cpar[5], cpar0[5], tpar[3], par1[100], pars1[100], par2[100], par3[100], par4[24], par0[100]; Float_t dz, dZ; Int_t *idtmed = fIdtmed->GetArray()-1699; Int_t idrotm[1799]; #include "ABSOSHILConst.h" #include "SHILConst2.h" enum {kC=1705, kAl=1708, kFe=1709, kCu=1710, kW=1711, kPb=1712, kNiCuW=1720, kVacuum=1715, kAir=1714, kConcrete=1716, kPolyCH2=1717, kSteel=1718, kInsulation=1713, kAirMuon = 1774}; Int_t i; // // Material of the rear part of the shield Int_t iHeavy = kNiCuW; if (fPbCone) iHeavy=kPb; // // Mother volume // Float_t dRear1=kDRear; Float_t zstart=kZRear-dRear1; par0[0] = 0.; par0[1] = 360.; par0[2] = 28.; Float_t dl=(kZvac12-zstart)/2.; const Float_t kzLength = dl; dz=zstart+dl; // // start par0[3] = -dl; par0[4] = 0.; par0[5] = zstart * TMath::Tan(kAccMin); // recess station 1 par0[6] = -dl - zstart + kZch11; par0[7] = 0.; par0[8] = 18.2; par0[9] = par0[6]; par0[10] = 0.; par0[11] = kR11; par0[12] = -dl - zstart + kZch12; par0[13] = 0.; par0[14] = kR11; par0[15] = par0[12]; par0[16] = 0.; par0[17] = 19.5; // recess station 2 par0[18] = -dz+kZch21; par0[19] = 0.; par0[20] = kZch21 * TMath::Tan(kAccMin); par0[21] = -dz+kZch21; par0[22] = 0.; par0[23] = kR21; par0[24] = -dz+kZch22; par0[25] = 0.; par0[26] = kR21; par0[27] = -dz+kZch22; par0[28] = 0.; par0[29] = kZch22 * TMath::Tan(kAccMin); // par0[30] = -dz+kZvac6; par0[31] = 0.; par0[32] = kZvac6 * TMath::Tan(kAccMin); // end of 2 deg cone par0[33] = -dz+kZConeE; par0[34] = 0.; par0[35] = 30.; par0[36] = -dz+kZch31; par0[37] = 0.; par0[38] = 30.; par0[39] = -dz+kZch31; par0[40] = 0.; par0[41] = 28.8; par0[42] = -dz+kZch32; par0[43] = 0.; par0[44] = 28.8; // start of 1.6 deg cone par0[45] = -dz+kZch32; par0[46] = 0.; par0[47] = 30.+(kZch32-kZConeE)*TMath::Tan(kThetaOpenPbO); // recess station 4 par0[48] = -dz+kZch41; par0[49] = 0.; par0[50] = 30.+(kZch41-kZConeE)*TMath::Tan(kThetaOpenPbO); par0[51] = -dz+kZch41; par0[52] = 0.; par0[53] = 36.9; par0[54] = -dz+kZch42; par0[55] = 0.; par0[56] = 36.9; par0[57] = -dz+kZch42; par0[58] = 0.; par0[59] = 30.+(kZch42-kZConeE)*TMath::Tan(kThetaOpenPbO); // recess station 5 par0[60] = -dz+kZch51; par0[61] = 0.; par0[62] = 30.+(kZch51-kZConeE)*TMath::Tan(kThetaOpenPbO); par0[63] = -dz+kZch51; par0[64] = 0.; par0[65] = 36.9; par0[66] = -dz+kZch52; par0[67] = 0.; par0[68] = 36.9; par0[69] = -dz+kZch52; par0[70] = 0.; par0[71] = 30.+(kZch52+4.-kZConeE)*TMath::Tan(kThetaOpenPbO); // end of cone par0[72] = -dz+kZvac10; par0[73] = 0.; par0[74] = par0[71]; par0[75] = -dz+kZvac10; par0[76] = 0.; par0[77] = kR42; par0[78] = -dz+kZvac11; par0[79] = 0.; par0[80] = kR42; par0[81] = -dz+kZvac11; par0[82] = 0.; par0[83] = kR43; par0[84] = -dz+kZvac12; par0[85] = 0.; par0[86] = kR43; gMC->Gsvolu("YMOT", "PCON", idtmed[kVacuum], par0, 87); dz=zstart+dl; AliMatrix(idrotm[1705], 270., 0., 90., 90., 180., 0.); dZ=-dl; // // Dimuon arm mother volumes (YOUT1, YOUT2) // // Dipole parameters Float_t z01 = -724.45; // Float_t z02 = -814.30; Float_t z05 = -1235.55; // Before dipole // Float_t zpos = -zstart - kzLength; Float_t shift_after_absorber = 35; Float_t delta = 1e-06; Float_t rst1 = 120; Float_t rst2 = 150; Float_t rst3 = 252; Float_t rst4 = 252; Float_t rst5 = 304; //Float_t rst6 = 430.; Float_t rst7 = 460.; // Float_t zstart2 = zpos + zstart; par0[0] = 0.; par0[1] = 360.; par0[2] = 11.; // // start // par0[3] = zpos - ( -dl ); // start only after absorber // z = -503.00 par0[3] = zpos - ( -dl + shift_after_absorber ) + delta; par0[4] = ( zstart + shift_after_absorber ) * TMath::Tan(kAccMin) + delta; par0[5] = rst1; // recess station 1 // z = -517.70 par0[6] = zpos - ( -dl - zstart + kZch11 + delta ); par0[7] = 18.2 + delta; par0[8] = rst1; // z = -517.70 par0[9] = par0[6]; par0[10] = kR11 + delta; par0[11] = rst1; // z = -553.70 par0[12] = zpos - ( -dl - zstart + kZch12 - delta ); par0[13] = kR11 + delta; par0[14] = rst1; // z = -553.70 par0[15] = par0[12]; par0[16] = 19.5 + delta; par0[17] = rst1; // recess station 2 // z = -661.30 par0[18] = zpos - ( -dz+kZch21 + delta ); par0[19] = kZch21 * TMath::Tan(kAccMin) + delta; par0[20] = rst2; // z = -661.30 par0[21] = par0[18]; par0[22] = kR21 + delta; par0[23] = rst2; // z = -709.90 par0[24] = zpos - ( -dz+kZch22 - delta ); par0[25] = kR21 + delta; par0[26] = rst2; // z = -709.90 par0[27] = par0[24]; par0[28] = kZch22 * TMath::Tan(kAccMin) + delta; par0[29] = rst2; // // z = -711.00 par0[30] = zpos - ( -dz+kZvac6 ); par0[31] = kZvac6 * TMath::Tan(kAccMin) + delta; par0[32] = rst2; Float_t nextZ = zpos - ( -dz+kZConeE ); Float_t nextRin = 30. + delta; Float_t nextRout = rst3; Float_t tgin = ( nextRin - par0[31]) / (nextZ - par0[30]); Float_t tgout = ( nextRout - par0[32])/ (nextZ - par0[30]); // z = -724.45 par0[33] = z01; par0[34] = par0[31] + (z01 - par0[30]) * tgin; par0[35] = par0[32] + (z01 - par0[30]) * tgout; gMC->Gsvolu("YOUT1", "PCON", idtmed[kAirMuon], par0, 36); gMC->Gspos("YOUT1", 1, "ALIC", 0., 0., 0., 0, "ONLY"); // // After dipole // par0[0] = 0.; par0[1] = 360.; par0[2] = 14.; // z = -1235.55 par0[3] = z05; par0[4] = nextRin - (z05 - nextZ) * TMath::Tan(kThetaOpenPbO) + delta ; par0[5] = rst4; // recess station 4 // z = -1259.90 par0[6] = zpos - ( -dz+kZch41 + delta ); par0[7] = 30.+(kZch41-kZConeE)*TMath::Tan(kThetaOpenPbO) + delta; par0[8] = rst4; // z = -1259.90 par0[9] = par0[6]; par0[10] = 36.9 + delta; par0[11] = rst4; // z = -1324.10 par0[12] = zpos - ( -dz+kZch42 - delta ); par0[13] = 36.9 + delta; par0[14] = rst4; // z = -1324.10 par0[15] = par0[12]; par0[16] = 30.+(kZch42-kZConeE)*TMath::Tan(kThetaOpenPbO) + delta; par0[17] = rst5; // recess station 5 // z = -1390.00 par0[18] = zpos - ( -dz+kZch51 + delta ); par0[19] = 30.+(kZch51-kZConeE)*TMath::Tan(kThetaOpenPbO) + delta; par0[20] = rst5; // z = -1390.00 par0[21] = par0[18]; par0[22] = 36.9 + delta; par0[23] = rst5; // z = -1454.20 par0[24] = zpos - ( -dz+kZch52 - delta ); par0[25] = 36.9 + delta; par0[26] = rst5; // z = -1454.20 par0[27] = par0[24]; par0[28] = 30.+(kZch52+4.-kZConeE)*TMath::Tan(kThetaOpenPbO) + delta; par0[29] = rst5; // end of cone // z = -1466.00 par0[30] = zpos - ( -dz+kZvac10 - delta ); par0[31] = par0[28]; par0[32] = rst7; // z = -1466.00 par0[33] = par0[30]; par0[34] = kR42 + delta; par0[35] = rst7; // z = -1800.00 par0[36] = zpos - ( -dz+kZvac11 - delta ); par0[37] = kR42 + delta; par0[38] = rst7; // z = -1800.00 par0[39] = par0[36]; par0[40] = kR43 + delta; par0[41] = rst7; // z = -1900.00 par0[42] = zpos - ( -dz+kZvac12 ); par0[43] = kR43 + delta; par0[44] = rst7; gMC->Gsvolu("YOUT2", "PCON", idtmed[kAirMuon], par0, 45); gMC->Gspos("YOUT2", 1, "ALIC", 0., 0., 0., 0, "ONLY"); // // First section: bellows below and behind front absorber // // par1[ 0] = 0.; par1[ 1] = 360.; par1[ 2] = 15.; dl=(kZvac4-zstart)/2.; par1[ 3] = -dl; par1[ 4] = kRAbs+(zstart-kZOpen) * TMath::Tan(kThetaOpen1); par1[ 5] = zstart * TMath::Tan(kAccMin); par1[ 6] = -dl-zstart+kZch11; par1[ 7] = par1[4] + (dRear1 + 19.) * TMath::Tan(kThetaOpen1); par1[ 8] = 18.2; par1[ 9] = par1[6]; par1[10] = par1[7]; par1[11] = kR11; par1[12] = -dl-zstart+kZch12; par1[13] = par1[10] + 36. * TMath::Tan(kThetaOpen1); par1[14] = kR11; par1[15] = -dl+dRear1 + 50.7; par1[16] = par1[13]; par1[17] = 19.5; par1[18] = -dl+kZvac1-zstart; par1[19] = par1[16] + (par1[18] - par1[15]) * TMath::Tan(kThetaOpen1); par1[20] = (par1[18] +dl +zstart) * TMath::Tan(kAccMin); par1[21] = -dl+kZvac1-zstart; par1[22] = kRAbs+ (kZvac1-kZOpen) * TMath::Tan(kThetaOpen1); par1[23] = (par1[21] +dl +zstart) * TMath::Tan(kAccMin); par1[24] = par1[21]+kDr11/10.; par1[25] = par1[22]+kDr11; par1[26] = (par1[24] +dl +zstart) * TMath::Tan(kAccMin); par1[27] = -dl+(kZvac1+kDr11/10.+kDB1-zstart); par1[28] = par1[25]; par1[29] = (par1[27] +dl +zstart) * TMath::Tan(kAccMin); par1[30] = par1[27]+kDr12; par1[31] = par1[28]+kDr12; par1[32] = (par1[30] +dl +zstart) * TMath::Tan(kAccMin); par1[33] = par1[30]+kDF1; par1[34] = par1[31]; par1[35] = (par1[33] +dl +zstart) * TMath::Tan(kAccMin); par1[36] = par1[33]+kDr12; par1[37] = par1[34]-kDr12; par1[38] = (par1[36] +dl +zstart) * TMath::Tan(kAccMin); par1[39] = par1[36]+kDB1; par1[40] = par1[37]; par1[41] = (par1[39] +dl +zstart) * TMath::Tan(kAccMin); par1[42] = par1[39]+kDr13; par1[43] = par1[40]-kDr13; par1[44] = (par1[42] +dl +zstart) * TMath::Tan(kAccMin); par1[45] = -dl+kZvac4-zstart; par1[46] = par1[43]; par1[47] = (par1[45] +dl +zstart) * TMath::Tan(kAccMin); Float_t r2 = par1[46]; Float_t rBox= par1[46]-0.1; gMC->Gsvolu("YGO1", "PCON", idtmed[kNiCuW+40], par1, 48); for (i=0; i<48; i++) pars1[i] = par1[i]; for (i=4; i<47; i+=3) pars1[i] = 0.; gMC->Gsvolu("YMO1", "PCON", idtmed[kVacuum+40], pars1, 48); gMC->Gspos("YGO1", 1, "YMO1", 0., 0., 0., 0, "ONLY"); dZ+=dl; gMC->Gspos("YMO1", 1, "YMOT", 0., 0., dZ, 0, "ONLY"); dZ+=dl; tpar[0]=kR21-0.6; tpar[1]=kR21; tpar[2]=(kZvac4-kZvac41)/2.; gMC->Gsvolu("YSE1", "TUBE", idtmed[kSteel], tpar, 3); dz=dl-tpar[2]; gMC->Gspos("YSE1", 1, "YGO1", 0., 0., dz, 0, "ONLY"); tpar[0]=kR11-0.6; tpar[1]=kR11; tpar[2]=(kZvac41-zstart-dRear1)/2.; gMC->Gsvolu("YSE2", "TUBE", idtmed[kSteel], tpar, 3); dz=dl-tpar[2]-(kZvac4-kZvac41); gMC->Gspos("YSE2", 1, "YGO1", 0., 0., dz, 0, "ONLY"); // // 1st section: vacuum system // // // Bellow 1 // tpar[0]=kRB1; tpar[1]=kRB1+kHB1; tpar[2]=kEB1/2.; gMC->Gsvolu("YB11", "TUBE", idtmed[kSteel+40], tpar, 3); Float_t dl1=tpar[2]; tpar[0]=kRB1+kHB1-kEB1; tpar[1]=kRB1+kHB1; tpar[2]=(kLB1/2.-2.*kEB1)/2.; gMC->Gsvolu("YB12", "TUBE", idtmed[kSteel+40], tpar, 3); Float_t dl2=tpar[2]; tpar[0]=kRB1-kEB1; tpar[1]=kRB1; tpar[2]=kLB1/8.; gMC->Gsvolu("YB13", "TUBE", idtmed[kSteel+40], tpar, 3); Float_t dl3=tpar[2]; tpar[0]=0; tpar[1]=kRB1+kHB1; tpar[2]=kLB1/2.; gMC->Gsvolu("YBU1", "TUBE", idtmed[kVacuum+40], tpar, 3); dz=-tpar[2]+dl3; gMC->Gspos("YB13", 1, "YBU1", 0., 0., dz, 0, "ONLY"); dz+=dl3; dz+=dl1; gMC->Gspos("YB11", 1, "YBU1", 0., 0., dz, 0, "ONLY"); dz+=dl1; dz+=dl2; gMC->Gspos("YB12", 1, "YBU1", 0., 0., dz, 0, "ONLY"); dz+=dl2; dz+=dl1; gMC->Gspos("YB11", 2, "YBU1", 0., 0., dz, 0, "ONLY"); dz+=dl1; dz+=dl3; gMC->Gspos("YB13", 2, "YBU1", 0., 0., dz, 0, "ONLY"); tpar[0]=0; tpar[1]=kRB1+kHB1+0.5; tpar[2]=12.*kLB1/2.; gMC->Gsvolu("YBM1", "TUBE", idtmed[kVacuum+40], tpar, 3); Float_t bsize = tpar[2]; tpar[0]=kRB1+kHB1; gMC->Gsvolu("YBI1", "TUBE", idtmed[kInsulation+40], tpar, 3); gMC->Gspos("YBI1", 2, "YBM1", 0., 0., 0., 0, "ONLY"); dz=-bsize+kLB1/2.; for (i=0; i<12; i++) { gMC->Gspos("YBU1", i+1 , "YBM1", 0., 0., dz, 0, "ONLY"); dz+=kLB1; } dz=-dl+(kZvac1-zstart)+kDr11/10.+bsize; gMC->Gspos("YBM1", 1, "YMO1", 0., 0., dz, 0, "ONLY"); // // Flange tpar[0]=0; tpar[1]=kRF1+0.6; tpar[2]=kDF1/2.; gMC->Gsvolu("YFM1", "TUBE", idtmed[kVacuum+40], tpar, 3); // Steel tpar[0]=kRB1; tpar[1]=kRF1+0.6; tpar[2]=kDF1/2.; gMC->Gsvolu("YF11", "TUBE", idtmed[kSteel+40], tpar, 3); // Insulation tpar[0]=kRF1; tpar[1]=kRF1+0.5; tpar[2]=kDF1/2.; gMC->Gsvolu("YF12", "TUBE", idtmed[kInsulation+40], tpar, 3); gMC->Gspos("YF11", 1, "YFM1", 0., 0., 0., 0, "ONLY"); gMC->Gspos("YF12", 1, "YFM1", 0., 0., 0., 0, "ONLY"); dz=-dl+(kZvac3-zstart)-2.*kDr13-tpar[2]; gMC->Gspos("YFM1", 2, "YMO1", 0., 0., dz, 0, "ONLY"); // // pipe between flange and bellows // // Steel tpar[0] = kRB1-dTubeS; tpar[1] = kRB1+0.6; tpar[2] = (kZvac3-kZvac1-2.*kDr13-kDr11/10.-kDF1-2.*bsize)/2.; gMC->Gsvolu("YPF1", "TUBE", idtmed[kSteel+40], tpar, 3); // Insulation tpar[0]=kRB1; tpar[1]=kRB1+0.5; gMC->Gsvolu("YPS1", "TUBE", idtmed[kInsulation+40], tpar, 3); gMC->Gspos("YPS1", 1, "YPF1", 0., 0., 0., 0, "ONLY"); dz=-dl+(kZvac1-zstart)+kDr11/10.+2.*bsize+tpar[2]; gMC->Gspos("YPF1", 1, "YMO1", 0., 0., dz, 0, "ONLY"); // Pipe+Heating 1.5 mm // Heating Jacket 5.0 mm // Protection 1.0 mm // ======================== // 7.5 mm // pipe and heating jackets outside bellows // // left side cpar0[0]=(kZvac1+kDr11/10.-zstart)/2; cpar0[1]=kRVacu-0.05 +(zstart-kZOpen)*TMath::Tan(kThetaOpen1); cpar0[2]=kRVacu+0.7 +(zstart-kZOpen)*TMath::Tan(kThetaOpen1); cpar0[3]=cpar0[1]+2.*cpar0[0]*TMath::Tan(kThetaOpen1); cpar0[4]=cpar0[2]+2.*cpar0[0]*TMath::Tan(kThetaOpen1); gMC->Gsvolu("YV11", "CONE", idtmed[kSteel+40], cpar0, 5); // // insulation dTubeS=0.15; cpar[0]=cpar0[0]; cpar[1]=cpar0[1]+0.15; cpar[2]=cpar0[1]+0.65; cpar[3]=cpar0[3]+0.15; cpar[4]=cpar0[3]+0.65; gMC->Gsvolu("YI11", "CONE", idtmed[kInsulation+40], cpar, 5); gMC->Gspos("YI11", 1, "YV11", 0., 0., 0., 0, "ONLY"); dz=-dl+cpar0[0]; gMC->Gspos("YV11", 1, "YMO1", 0., 0., dz, 0, "ONLY"); // right side dTubeS = 0.35; dVacuS += 0.25; cpar0[0] = (kZvac4-kZvac3+2.*kDr13)/2; cpar0[1] = kRB1; cpar0[2] = cpar0[1]+dVacuS; cpar0[3] = cpar0[1]+2.*cpar0[0]*TMath::Tan(kThetaOpenB); cpar0[4] = cpar0[2]+2.*cpar0[0]*TMath::Tan(kThetaOpenB); gMC->Gsvolu("YV12", "CONE", idtmed[kSteel], cpar0, 5); Float_t r2V=cpar0[3]; // // insulation cpar[0] = cpar0[0]; cpar[1] = cpar0[1]+dTubeS; cpar[2] = cpar0[1]+dTubeS+kDInsuS; cpar[3] = cpar0[3]+dTubeS; cpar[4] = cpar0[3]+dTubeS+kDInsuS; gMC->Gsvolu("YI12", "CONE", idtmed[kInsulation], cpar, 5); gMC->Gspos("YI12", 1, "YV12", 0., 0., 0., 0, "ONLY"); dz=dl-cpar0[0]; gMC->Gspos("YV12", 1, "YMO1", 0., 0., dz, 0, "ONLY"); // // Second Section // Between first and second bellow section // par2[0] = 0.; par2[1] = 360.; par2[2] = 11.; dl=(kZvac7-kZvac4)/2.; // recess station 2 par2[3] = -dl; par2[4] = r2; par2[5] = kR21; par2[6] = -dl+.1; par2[7] = r2; par2[8] = kR21; par2[9] = -dl+(kZvac6-kZvac4); par2[10] = r2+(kZvac6-kZvac4-10.) * TMath::Tan(kThetaOpen2); par2[11] = kR21; par2[12] = -dl+(kZvac6-kZvac4); par2[13] = par2[10]; par2[14] = kZvac6*TMath::Tan(kAccMin); // Start of Pb section par2[15] = -dl+(kZPb-kZvac4); par2[16] = r2+(kZPb-kZvac4-10.) * TMath::Tan(kThetaOpen2); par2[17] = kZPb*TMath::Tan(kAccMin); // // end of cone following 2 deg line par2[18] = -dl+(kZConeE-kZvac4); par2[19] = r2+(kZConeE-kZvac4-10.) * TMath::Tan(kThetaOpen2); par2[20] = 30.; // recess station 3 par2[21] = -dl+(kZch31-kZvac4); par2[22] = r2+(kZch31-kZvac4-10.) * TMath::Tan(kThetaOpen2); par2[23] = 30.; par2[24] = -dl+(kZch31-kZvac4); par2[25] = r2+(kZch31-kZvac4-10.) * TMath::Tan(kThetaOpen2); par2[26] = 28.8; par2[27] = -dl+(kZch32-kZvac4); par2[28] = r2+(kZch32-kZvac4-10.) * TMath::Tan(kThetaOpen2); par2[29] = 28.8; par2[30] = -dl+(kZch32-kZvac4); par2[31] = r2+(kZch32-kZvac4-10.) * TMath::Tan(kThetaOpen2); par2[32] = 30.; par2[33] = -dl+(kZvac7-kZvac4); par2[34] = r2+(kZvac7-kZvac4-10.) * TMath::Tan(kThetaOpen2); par2[35] = 30.; gMC->Gsvolu("YGO2", "PCON", idtmed[kSteel+40], par2, 36); // // Lead cone // Float_t parPb[18]; parPb[ 0] = 0.; parPb[ 1] = 360.; parPb[ 2] = 5.; Float_t dlPb=(kZvac7-kZPb)/2.; parPb[ 3] = -dlPb; parPb[ 4] = r2+(kZPb-kZvac4-10.) * TMath::Tan(kThetaOpen2); parPb[ 5] = kZPb*TMath::Tan(kAccMin)-kDRSteel2; parPb[ 6] = -dlPb+(kZConeE-kZPb); parPb[ 7] = r2+(kZConeE-kZvac4-10.) * TMath::Tan(kThetaOpen2); parPb[ 8] = 26.; parPb[ 9] = -dlPb+(kZch32+4.-kZPb); parPb[10] = r2+(kZch32+4.-kZvac4-10.) * TMath::Tan(kThetaOpen2); parPb[11] = 26.; parPb[12] = -dlPb+(kZch32+4.-kZPb); parPb[13] = r2+(kZch32+4.-kZvac4-10.) * TMath::Tan(kThetaOpen2); parPb[14] = 30.; parPb[15] = dlPb; parPb[16] = r2+(kZvac7-kZvac4-10.) * TMath::Tan(kThetaOpen2); parPb[17] = 30.; gMC->Gsvolu("YXO2", "PCON", idtmed[kPb+40], parPb, 18); gMC->Gspos("YXO2", 1, "YGO2", 0., 0., (kZPb-kZvac4)/2., 0, "ONLY"); // // Concrete replacing Pb // Float_t parCC[9]; Float_t zCC1 = 1066.; Float_t zCC2 = 1188.; parCC[ 0] = 0.; parCC[ 1] = 360.; parCC[ 2] = 2.; Float_t dlCC=(zCC2-zCC1)/2.; parCC[ 3] = -dlCC; parCC[ 4] = r2+(zCC1-kZvac4-10.) * TMath::Tan(kThetaOpen2); parCC[ 5] = 30.; parCC[ 6] = dlCC; parCC[ 7] = r2+(zCC2-kZvac4-10.) * TMath::Tan(kThetaOpen2); parCC[ 8] = 30.; gMC->Gsvolu("YCO2", "PCON", idtmed[kSteel], parCC, 9); // gMC->Gspos("YCO2", 1, "YXO2", 0., 0., dlPb-dlCC-(kZvac7-zCC2), 0, "ONLY"); zCC1 = 751.75; zCC2 = kZConeE; dlCC=(zCC2-zCC1)/2.; parCC[ 3] = -dlCC; parCC[ 4] = r2+(zCC1-kZvac4-10.) * TMath::Tan(kThetaOpen2); parCC[ 5] = zCC1*TMath::Tan(kAccMin)-kDRSteel2; parCC[ 6] = dlCC; parCC[ 7] = r2+(zCC2-kZvac4-10.) * TMath::Tan(kThetaOpen2); parCC[ 8] = 26.; gMC->Gsvolu("YCO1", "PCON", idtmed[kSteel], parCC, 9); // gMC->Gspos("YCO1", 1, "YXO2", 0., 0., dlPb-dlCC-(kZvac7-zCC2), 0, "ONLY"); // // W cone // Float_t parW[15]; parW[0] = 0.; parW[1] = 360.; parW[2] = 4.; Float_t dlW=(kZPb-kZvac4)/2.; parW[3] = -dlW; parW[4] = r2; parW[5] = kR21-kDRSteel2; parW[6] = -dlW+(kZvac6-kZvac4)+kDRSteel2; parW[7] = r2+(kZvac6-kZvac4+kDRSteel2) * TMath::Tan(kThetaOpen2); parW[8] = kR21-kDRSteel2; parW[9] = -dlW+(kZvac6-kZvac4)+kDRSteel2; parW[10] = r2+(kZvac6-kZvac4+kDRSteel2) * TMath::Tan(kThetaOpen2); parW[11] = (kZvac6+kDRSteel2)*TMath::Tan(kAccMin)-kDRSteel2; parW[12] = dlW; parW[13] = r2+(kZPb-kZvac4) * TMath::Tan(kThetaOpen2); parW[14] = kZPb*TMath::Tan(kAccMin)-kDRSteel2; gMC->Gsvolu("YYO2", "PCON", idtmed[kNiCuW+40], parW, 15); gMC->Gspos("YYO2", 1, "YGO2", 0., 0., -(kZvac7-kZPb)/2., 0, "ONLY"); for (i=4; i<35; i+=3) par2[i] = 0; gMC->Gsvolu("YMO2", "PCON", idtmed[kVacuum+40], par2, 36); gMC->Gspos("YGO2", 1, "YMO2", 0., 0., 0., 0, "ONLY"); dZ+=dl; gMC->Gspos("YMO2", 1, "YMOT", 0., 0., dZ, 0, "ONLY"); dZ+=dl; // // // 2nd section: vacuum system // cpar0[0]=(kZvac7-kZvac4)/2; cpar0[1]=r2V; cpar0[2]=r2V+dVacuS; cpar0[3]=cpar0[1]+2.*cpar0[0]*TMath::Tan(kThetaOpenB); cpar0[4]=cpar0[2]+2.*cpar0[0]*TMath::Tan(kThetaOpenB); gMC->Gsvolu("YV21", "CONE", idtmed[kSteel+40], cpar0, 5); // // insulation cpar[0]=cpar0[0]; cpar[1]=cpar0[1]+dTubeS; cpar[2]=cpar0[1]+dTubeS+kDInsuS; cpar[3]=cpar0[3]+dTubeS; cpar[4]=cpar0[3]+dTubeS+kDInsuS; gMC->Gsvolu("YI21", "CONE", idtmed[kInsulation+40], cpar, 5); gMC->Gspos("YI21", 1, "YV21", 0., 0., 0., 0, "ONLY"); gMC->Gspos("YV21", 1, "YMO2", 0., 0., 0., 0, "ONLY"); // // Third Section: Bellows and Flange // par3[0] = 0.; par3[1] = 360.; par3[2] = 8.; dl=(kZvac9-kZvac7)/2.; par3[3] = -dl; par3[4] = r2+(kZvac7-kZvac3) * TMath::Tan(kThetaOpen2); par3[5] = 30.; par3[6] = -dl+kDr21; par3[7] = par3[4]+kDr21; par3[8] = 30.; par3[9] = par3[6]+kDB2; par3[10] = par3[7]; par3[11] = 30.; par3[12] = par3[9]+kDr22; par3[13] = par3[10]+kDr22; par3[14] = 30.; par3[15] = par3[12]+kDF2; par3[16] = par3[13]; par3[17] = 30.; par3[18] = par3[15]+kDr22; par3[19] = par3[16]-kDr22; par3[20] = 30.; par3[21] = par3[18]+kDB2; par3[22] = par3[19]; par3[23] = 30.; par3[24] = par3[21]+kDr23; par3[25] = par3[22]; par3[26] = 30.; // rBox=par3[22]-0.1; Float_t r3=par3[25]; gMC->Gsvolu("YGO3", "PCON", idtmed[iHeavy+40], par3, 27); for (i=4; i<26; i+=3) par3[i] = 0; gMC->Gsvolu("YMO3", "PCON", idtmed[kVacuum+40], par3, 27); gMC->Gspos("YGO3", 1, "YMO3", 0., 0., 0., 0, "ONLY"); // // Steel envelope // tpar[0]=26; // tpar[1]=30; // tpar[2]=dl; // gMC->Gsvolu("YS31", "TUBE", idtmed[kSteel], tpar, 3); // gMC->Gspos("YS31", 1, "YGO3", 0., 0., 0., 0, "ONLY"); dZ+=dl; gMC->Gspos("YMO3", 1, "YMOT", 0., 0., dZ, 0, "ONLY"); dZ+=dl; // // 3rd section: vacuum system // // // Bellow2 // tpar[0]=kRB2; tpar[1]=kRB2+kHB2; tpar[2]=kEB2/2.; gMC->Gsvolu("YB21", "TUBE", idtmed[kSteel+40], tpar, 3); dl1=tpar[2]; tpar[0]=kRB2+kHB2-kEB2; tpar[1]=kRB2+kHB2; tpar[2]=(kLB2/2.-2.*kEB2)/2.; gMC->Gsvolu("YB22", "TUBE", idtmed[kSteel+40], tpar, 3); dl2=tpar[2]; tpar[0]=kRB2-kEB2; tpar[1]=kRB2; tpar[2]=kLB2/8.; gMC->Gsvolu("YB23", "TUBE", idtmed[kSteel+40], tpar, 3); dl3=tpar[2]; tpar[0]=0; tpar[1]=kRB2+kHB2; tpar[2]=kLB2/2.; gMC->Gsvolu("YBU2", "TUBE", idtmed[kVacuum+40], tpar, 3); dz=-tpar[2]+dl3; gMC->Gspos("YB23", 1, "YBU2", 0., 0., dz, 0, "ONLY"); dz+=dl3; dz+=dl1; gMC->Gspos("YB21", 1, "YBU2", 0., 0., dz, 0, "ONLY"); dz+=dl1; dz+=dl2; gMC->Gspos("YB22", 1, "YBU2", 0., 0., dz, 0, "ONLY"); dz+=dl2; dz+=dl1; gMC->Gspos("YB21", 2, "YBU2", 0., 0., dz, 0, "ONLY"); dz+=dl1; dz+=dl3; gMC->Gspos("YB23", 2, "YBU2", 0., 0., dz, 0, "ONLY"); tpar[0]=0; tpar[1]=kRB2+kHB2; tpar[2]=7.*kLB2/2.; gMC->Gsvolu("YBM2", "TUBE", idtmed[kVacuum+40], tpar, 3); dz=-tpar[2]+kLB2/2.; for (i=0; i<7; i++) { gMC->Gspos("YBU2", i+1 , "YBM2", 0., 0.,dz , 0, "ONLY"); dz+=kLB2; } dz=-dl+kDr21+tpar[2]; gMC->Gspos("YBM2", 1, "YMO3", 0., 0., dz, 0, "ONLY"); dz=dl-kDr23-tpar[2]; gMC->Gspos("YBM2", 2, "YMO3", 0., 0., dz, 0, "ONLY"); // // Flange tpar[0]=0; tpar[1]=kRF2; tpar[2]=kDF2/2.; gMC->Gsvolu("YFM2", "TUBE", idtmed[kVacuum+40], tpar, 3); tpar[0]=kRF2-2.; tpar[1]=kRF2; tpar[2]=kDF2/2.; gMC->Gsvolu("YF21", "TUBE", idtmed[kSteel+40], tpar, 3); gMC->Gspos("YF21", 1, "YFM2", 0., 0., 0., 0, "ONLY"); tpar[0]=kRB2; tpar[1]=kRF2-2.; tpar[2]=kDFlange/2.; gMC->Gsvolu("YF22", "TUBE", idtmed[kSteel+40], tpar, 3); dz=-kDF2/2.+tpar[2]; gMC->Gspos("YF22", 1, "YFM2", 0., 0., dz, 0, "ONLY"); dz= kDF2/2.-tpar[2]; gMC->Gspos("YF22", 2, "YFM2", 0., 0., dz, 0, "ONLY"); dz=kDr21/2.-kDr23/2.; gMC->Gspos("YFM2", 2, "YMO3", 0., 0., dz, 0, "ONLY"); // // pipe between flange and bellows tpar[0]=kRB2-dTubeS; tpar[1]=kRB2; tpar[2]=2.*(kDB2+kDr22-7.*kLB2)/4.; gMC->Gsvolu("YPF2", "TUBE", idtmed[kSteel+40], tpar, 3); dz=kDr21/2.-kDr23/2.-kDF2/2.-tpar[2]; gMC->Gspos("YPF2", 1, "YMO3", 0., 0., dz, 0, "ONLY"); dz=kDr21/2.-kDr23/2.+kDF2/2.+tpar[2]; gMC->Gspos("YPF2", 2, "YMO3", 0., 0., dz, 0, "ONLY"); Float_t dHorZ=20.; // // 4th section: rear shield and closing cone // par4[0] = 0.; par4[1] = 360.; par4[2] = 7.; dl=(kZvac12-kZvac9)/2.; par4[3] = -dl; par4[4] = r3; par4[5] = 30.; par4[6] = -dl+dHorZ; par4[7] = r3; par4[8] = 30.; par4[9] = -dl+(kZvac10-kZvac9); par4[10] = r3+(kZvac10-kZvac9-dHorZ) * TMath::Tan(kThetaOpen3); par4[11] = 30.; par4[12] = par4[9]; par4[13] = par4[10]; par4[14] = kR42; par4[15] = -dl+(kZvac11-kZvac9); par4[16] = r3+(kZvac11-kZvac9-dHorZ) * TMath::Tan(kThetaOpen3); par4[17] = kR42; par4[18] = par4[15]; par4[19] = par4[16]; par4[20] = kR43; par4[21] = -dl+(kZvac12-kZvac9); par4[22] = kRVacu+dVacuS; par4[23] = kR43; gMC->Gsvolu("YGO4", "PCON", idtmed[iHeavy+40], par4, 24); for (i=4; i<23; i+=3) par4[i] = 0; gMC->Gsvolu("YMO4", "PCON", idtmed[kVacuum+40], par4, 24); gMC->Gspos("YGO4", 1, "YMO4", 0., 0., 0., 0, "ONLY"); dZ+=dl; gMC->Gspos("YMO4", 1, "YMOT", 0., 0., dZ, 0, "ONLY"); dZ+=dl; // // Concrete replacing Pb // zCC1 = 1316.; zCC2 = 1349.; parCC[ 0] = 0.; parCC[ 1] = 360.; parCC[ 2] = 2.; dlCC=(zCC2-zCC1)/2.; parCC[ 3] = -dlCC; parCC[ 4] = r3+(zCC1-kZvac9-dHorZ) * TMath::Tan(kThetaOpen3); parCC[ 5] = 30.; parCC[ 6] = dlCC; parCC[ 7] = r3+(zCC2-kZvac9-dHorZ) * TMath::Tan(kThetaOpen3); parCC[ 8] = 30.; gMC->Gsvolu("YCO4", "PCON", idtmed[kSteel], parCC, 9); // gMC->Gspos("YCO4", 1, "YGO4", 0., 0., dl-dlCC-(kZvac12-zCC2), 0, "ONLY"); zCC1 = 1471.; zCC2 = 1591.; dlCC=(zCC2-zCC1)/2.; parCC[ 3] = -dlCC; parCC[ 4] = r3+(zCC1-kZvac9-dHorZ) * TMath::Tan(kThetaOpen3); parCC[ 5] = kR41-kDRSteel2; parCC[ 6] = dlCC; parCC[ 7] = r3+(zCC2-kZvac9-dHorZ) * TMath::Tan(kThetaOpen3); parCC[ 8] = kR41-kDRSteel2; gMC->Gsvolu("YCO5", "PCON", idtmed[kSteel], parCC, 9); // gMC->Gspos("YCO5", 1, "YGO4", 0., 0., dl-dlCC-(kZvac12-zCC2), 0, "ONLY"); // // Closing concrete cone // cpar[0]=(kZvac12-kZvac11)/2.; cpar[1] = r3+(kZvac11-kZvac9-dHorZ) * TMath::Tan(kThetaOpen3); cpar[2] = cpar[1]+0.001; cpar[3] = kRVacu+dVacuS; cpar[4] = cpar[2]; gMC->Gsvolu("YCC4", "CONE", idtmed[kConcrete+40], cpar, 5); dz=dl-cpar[0]; gMC->Gspos("YCC4", 1, "YGO4", 0., 0., dz, 0, "ONLY"); // // Steel envelope // dz=-dl; tpar[0]=26.; tpar[1]=30.; tpar[2]=(kZvac10-kZvac9)/2.; gMC->Gsvolu("YS41", "TUBE", idtmed[kSteel], tpar, 3); dz+=tpar[2]; // gMC->Gspos("YS41", 1, "YGO4", 0., 0., dz, 0, "ONLY"); dz+=tpar[2]; tpar[0]=kR41-kDRSteel2; tpar[1]=kR41; tpar[2]=(kZvac11-kZvac10)/2.; gMC->Gsvolu("YS43", "TUBE", idtmed[kPb+40], tpar, 3); dz+=tpar[2]; gMC->Gspos("YS43", 1, "YGO4", 0., 0., dz, 0, "ONLY"); // // rear lead shield // tpar[0]=kR41; tpar[1]=kR42; tpar[2]=(kZvac11-kZvac10)/2.; gMC->Gsvolu("YPBI", "TUBE", idtmed[kPb+40], tpar, 3); dz-=0; gMC->Gspos("YPBI", 1, "YGO4", 0., 0., dz, 0, "ONLY"); tpar[2]=(zCC2-zCC1)/2.; gMC->Gsvolu("YCO6", "TUBE", idtmed[kSteel+40], tpar, 3); // gMC->Gspos("YCO6", 1, "YPBI", 0., 0., -(kZvac11-kZvac10)/2.+tpar[2], 0, "ONLY"); tpar[0]=kR42-5; tpar[1]=kR42; tpar[2]=(kZvac11-kZvac10)/2.; gMC->Gsvolu("YPBO", "TUBE", idtmed[kPb+40], tpar, 3); gMC->Gspos("YPBO", 1, "YPBI", 0., 0., 0., 0, "ONLY"); tpar[2]=(zCC2-zCC1)/2.; gMC->Gsvolu("YCO7", "TUBE", idtmed[kSteel], tpar, 3); // gMC->Gspos("YCO7", 1, "YPBO", 0., 0., -(kZvac11-kZvac10)/2.+tpar[2], 0, "ONLY"); // // rear Fe shield // tpar[0]=31.; tpar[1]=kR43; tpar[2]=(kZvac12-kZvac11)/2.; gMC->Gsvolu("YFEI", "TUBE", idtmed[kSteel+40], tpar, 3); dz=dl-tpar[2]; gMC->Gspos("YFEI", 1, "YGO4", 0., 0., dz, 0, "ONLY"); tpar[0]=31.; tpar[1]=kR43; tpar[2]=2.5; gMC->Gsvolu("YFEO", "TUBE", idtmed[kSteel], tpar, 3); dz=-(kZvac12-kZvac11)/2.+tpar[2]; gMC->Gspos("YFEO", 1, "YFEI", 0., 0., dz, 0, "ONLY"); // // // 4th section: vacuum system // // up to closing cone Float_t r3V=r3-kDr23+dVacuS-1.6; cpar0[0]=(kZvac11-kZvac9)/2; cpar0[1]=r3V-dVacuS; cpar0[2]=r3V; cpar0[3]=cpar0[1]+2.*cpar0[0]*TMath::Tan(kThetaOpen3); cpar0[4]=cpar0[2]+2.*cpar0[0]*TMath::Tan(kThetaOpen3); gMC->Gsvolu("YV31", "CONE", idtmed[kSteel+40], cpar0, 5); // // insulation cpar[0]=cpar0[0]; cpar[1]=cpar0[1]+dTubeS; cpar[2]=cpar0[1]+dTubeS+kDInsuS; cpar[3]=cpar0[3]+dTubeS; cpar[4]=cpar0[3]+dTubeS+kDInsuS; gMC->Gsvolu("YI31", "CONE", idtmed[kInsulation+40], cpar, 5); gMC->Gspos("YI31", 1, "YV31", 0., 0., 0., 0, "ONLY"); dz=-dl+cpar[0]; gMC->Gspos("YV31", 1, "YMO4", 0., 0., dz, 0, "ONLY"); // // closing cone cpar0[0]=(kZvac12-kZvac11)/2; cpar0[1]=r3V-dVacuS+(kZvac11-kZvac9)*TMath::Tan(kThetaOpen3); cpar0[2]=r3V +(kZvac11-kZvac9)*TMath::Tan(kThetaOpen3); cpar0[3]=kRVacu; cpar0[4]=kRVacu+dTubeS+kDInsuS+kDProtS+kDFreeS; gMC->Gsvolu("YV32", "CONE", idtmed[kSteel+40], cpar0, 5); // // insulation cpar[0]=cpar0[0]; cpar[1]=cpar0[1]+dTubeS; cpar[2]=cpar0[1]+dTubeS+kDInsuS; cpar[3]=cpar0[3]+dTubeS; cpar[4]=cpar0[3]+dTubeS+kDInsuS; gMC->Gsvolu("YI32", "CONE", idtmed[kInsulation+40], cpar, 5); gMC->Gspos("YI32", 1, "YV32", 0., 0., 0., 0, "ONLY"); dz=dl-cpar[0]; gMC->Gspos("YV32", 1, "YMO4", 0., 0., dz, 0, "ONLY"); /////////////////////////////////// // Muon Filter // // Drawing ALIP2A__0105 // /////////////////////////////////// TGeoBBox* shMuonFilterO1 = new TGeoBBox(550./2., 620./2., 120./2.); shMuonFilterO1->SetName("FilterO1"); TGeoTube* shMuonFilterI1 = new TGeoTube(0., 50., 121./2.); shMuonFilterI1->SetName("FilterI1"); TGeoCompositeShape* shMuonFilterM = new TGeoCompositeShape("YMuonFilterM", "FilterO1-FilterI1"); TGeoVolume* voMuonFilterM = new TGeoVolume("YMuonFilterM", shMuonFilterM, gGeoManager->GetMedium("SHIL_ST_C0")); TGeoBBox* shMuonFilterO2 = new TGeoBBox(550./2., 620./2., 110./2.); shMuonFilterO2->SetName("FilterO2"); TGeoTube* shMuonFilterI2 = new TGeoTube(0., 50., 111./2.); shMuonFilterI2->SetName("FilterI2"); TGeoCompositeShape* shMuonFilterI = new TGeoCompositeShape("YMuonFilterI", "FilterO2-FilterI2"); TGeoVolume* voMuonFilterI = new TGeoVolume("YMuonFilterI", shMuonFilterI, gGeoManager->GetMedium("SHIL_ST_C3")); voMuonFilterI->SetName("YMuonFilterI"); voMuonFilterM->AddNode(voMuonFilterI, 1, new TGeoTranslation(0., 0., 0.)); dz = (kZFilterIn + kZFilterOut) / 2.; gMC->Gspos("YMuonFilterM", 1, "YOUT2", 0., 0., - dz, 0, "ONLY"); // // Outer Pb Cone // if (fPbCone) { dl = (kZvac10-kZch32)/2.; dz = dl+kZch32; par0[0] = 0.; par0[1] = 360.; par0[2] = 10.; par0[ 3] = -dl; par0[ 4] = 30.; par0[ 5] = 30.+(kZch32-kZConeE)*TMath::Tan(kThetaOpenPbO); // 4th station par0[ 6] = -dz + kZch41; par0[ 7] = 30.; par0[ 8] = 30.+(kZch41-kZConeE)*TMath::Tan(kThetaOpenPbO); par0[ 9] = -dz + kZch41; par0[10] = 30.; par0[11] = 36.9; // recess erice2000 par0[12] = -dz + kZch42; par0[13] = 30.; par0[14] = par0[11]; par0[15] = -dz + kZch42; par0[16] = 30.; par0[17] = 30.+(kZch42-kZConeE)*TMath::Tan(kThetaOpenPbO); // 5th station par0[18] = -dz + kZch51; par0[19] = 30.; par0[20] = 30.+(kZch51-kZConeE)*TMath::Tan(kThetaOpenPbO); par0[21] = -dz + kZch51; par0[22] = 30.; par0[23] = 36.9; // recess erice2000 par0[24] = -dz + kZch52; par0[25] = 30.; par0[26] = par0[23]; par0[27] = -dz + kZch52; par0[28] = 30.; par0[29] = 30.+(kZch52+4.-kZConeE)*TMath::Tan(kThetaOpenPbO); // end of cone par0[30] = +dl; par0[31] = 30.; par0[32] = par0[29]; // gMC->Gsvolu("YOPB", "PCON", idtmed[kPb+40], par0, 33); Float_t dzs = -kzLength + (kZch32-zstart) + dl; gMC->Gspos("YOPB", 1, "YMOT", 0., 0., dzs, 0, "ONLY"); // // Steel envelope // par0[ 0] = 0.; par0[ 1] = 360.; par0[ 2] = 11.; par0[ 3] = -dl; par0[ 5] = 30.+(kZch32-kZConeE)*TMath::Tan(kThetaOpenPbO); par0[ 4] = par0[ 5] - 4.; // 4th station par0[ 6] = -dz + kZch41 - 4.; par0[ 8] = 30.+(kZch41-4.-kZConeE)*TMath::Tan(kThetaOpenPbO); par0[ 7] = par0[ 8] -4.; par0[ 9] = -dz + kZch41 - 4.; par0[11] = par0[8]; par0[10] = 33.5; par0[12] = -dz + kZch41; par0[14] = 30.+(kZch41-kZConeE)*TMath::Tan(kThetaOpenPbO); par0[13] = 33.5; par0[15] = -dz + kZch41; par0[17] = 36.9; par0[16] = 32.9; // 5th station par0[18] = -dz + kZch51; par0[20] = 36.9; par0[19] = 32.9; par0[21] = -dz + kZch52; par0[23] = 36.9; par0[22] = 32.9; par0[24] = -dz + kZch52; par0[26] = 30.+(kZch52-kZConeE)*TMath::Tan(kThetaOpenPbO); par0[25] = 33.5; par0[27] = -dz + kZch52 + 4.; par0[29] = 30.+(kZch52+4.-kZConeE)*TMath::Tan(kThetaOpenPbO); par0[28] = 33.5; par0[30] = -dz + kZch52 + 4.; par0[32] = 30.+(kZch52+4.-kZConeE)*TMath::Tan(kThetaOpenPbO); par0[31] = par0[32] - 4.; par0[33] = +dl; par0[35] = par0[32]; par0[34] = par0[31]; gMC->Gsvolu("YOSE", "PCON", idtmed[kSteel], par0, 36); gMC->Gspos ("YOSE", 1, "YOPB", 0., 0., 0., 0, "ONLY"); // // Extra Tungsten shield close to stations 1 and 2 // TGeoRotation* rot000 = new TGeoRotation("rot000", 90., 0., 90., 90., 0., 0.); TGeoRotation* rot090 = new TGeoRotation("rot090", 90., 90., 90., 180., 0., 0.); TGeoRotation* rot180 = new TGeoRotation("rot180", 90., 180., 90., 270., 0., 0.); TGeoRotation* rot270 = new TGeoRotation("rot270", 90., 270., 90., 0., 0., 0.); TGeoVolume* mother = gGeoManager->GetVolume("YMOT"); TGeoVolumeAssembly* assembly = new TGeoVolumeAssembly("YASS"); assembly->AddNode(mother, 1, new TGeoTranslation(0., 0., 0.)); TGeoVolumeAssembly* extraShield1 = new TGeoVolumeAssembly("YCRE"); TGeoVolumeAssembly* extraShield2 = new TGeoVolumeAssembly("YCRF"); /////////////////////////////////// // // // Recess Station 1 // // // /////////////////////////////////// /////////////////////////////////// // FA W-Ring 2 // // Drawing ALIP2A__0220 // /////////////////////////////////// Float_t faWring2Rinner = 15.40; Float_t faWring2Router = 18.40; Float_t faWring2HWidth = 3.75; Float_t faWring2Cutoffx = 3.35; Float_t faWring2Cutoffy = 3.35; TGeoTubeSeg* shFaWring2a = new TGeoTubeSeg(faWring2Rinner, faWring2Router, faWring2HWidth, 0., 90.); shFaWring2a->SetName("shFaWring2a"); TGeoBBox* shFaWring2b = new TGeoBBox(faWring2Router / 2., faWring2Router / 2., faWring2HWidth); shFaWring2b->SetName("shFaWring2b"); TGeoTranslation* trFaWring2b = new TGeoTranslation("trFaWring2b", faWring2Router / 2. + faWring2Cutoffx, faWring2Router / 2. + faWring2Cutoffy, 0.); trFaWring2b->RegisterYourself(); TGeoCompositeShape* shFaWring2 = new TGeoCompositeShape("shFaWring2", "(shFaWring2a)*(shFaWring2b:trFaWring2b)"); TGeoVolume* voFaWring2 = new TGeoVolume("FA_WRING2", shFaWring2, gGeoManager->GetMedium("SHIL_Ni/W3")); /////////////////////////////////// // FA W-Ring 3 // // Drawing ALIP2A__0219 // /////////////////////////////////// Float_t faWring3Rinner = 15.40; Float_t faWring3Router = 18.40; Float_t faWring3HWidth = 3.75; Float_t faWring3Cutoffx = 3.35; Float_t faWring3Cutoffy = 3.35; TGeoTubeSeg* shFaWring3a = new TGeoTubeSeg(faWring3Rinner, faWring3Router, faWring3HWidth, 0., 90.); shFaWring3a->SetName("shFaWring3a"); TGeoBBox* shFaWring3b = new TGeoBBox(faWring3Router / 2., faWring3Router / 2., faWring3HWidth); shFaWring3b->SetName("shFaWring3b"); TGeoTranslation* trFaWring3b = new TGeoTranslation("trFaWring3b", faWring3Router / 2. + faWring3Cutoffx, faWring3Router / 2. + faWring3Cutoffy, 0.); trFaWring3b->RegisterYourself(); TGeoCompositeShape* shFaWring3 = new TGeoCompositeShape("shFaWring3", "(shFaWring3a)*(shFaWring3b:trFaWring3b)"); TGeoVolume* voFaWring3 = new TGeoVolume("FA_WRING3", shFaWring3, gGeoManager->GetMedium("SHIL_Ni/W3")); /////////////////////////////////// // FA W-Ring 5 // // Drawing ALIP2A__0221 // /////////////////////////////////// Float_t faWring5Rinner = 15.40; Float_t faWring5Router = 18.67; Float_t faWring5HWidth = 1.08; TGeoVolume* voFaWring5 = new TGeoVolume("FA_WRING5", new TGeoTube(faWring5Rinner, faWring5Router, faWring5HWidth), gGeoManager->GetMedium("SHIL_Ni/W3")); // // Position the rings in the assembly // // Distance between rings Float_t faDWrings = 1.92; // dz = - (4. * faWring2HWidth + 4. * faWring3HWidth + 2. * faWring5HWidth + 2. * faDWrings) / 2.; dz += faWring2HWidth; extraShield1->AddNode(voFaWring2, 1, new TGeoCombiTrans(0., 0., dz, rot090)); extraShield1->AddNode(voFaWring2, 2, new TGeoCombiTrans(0., 0., dz, rot270)); dz += faWring2HWidth; dz += faDWrings; dz += faWring3HWidth; extraShield1->AddNode(voFaWring3, 1, new TGeoCombiTrans(0., 0., dz, rot000)); extraShield1->AddNode(voFaWring3, 2, new TGeoCombiTrans(0., 0., dz, rot180)); dz += faWring3HWidth; dz += faWring5HWidth; extraShield1->AddNode(voFaWring5, 1, new TGeoTranslation(0., 0., dz)); dz += faWring5HWidth; dz += faWring3HWidth; extraShield1->AddNode(voFaWring3, 3, new TGeoCombiTrans(0., 0., dz, rot090)); extraShield1->AddNode(voFaWring3, 4, new TGeoCombiTrans(0., 0., dz, rot270)); dz += faWring3HWidth; dz += faDWrings; dz += faWring2HWidth; extraShield1->AddNode(voFaWring2, 3, new TGeoCombiTrans(0., 0., dz, rot000)); extraShield1->AddNode(voFaWring2, 4, new TGeoCombiTrans(0., 0., dz, rot180)); dz += faWring2HWidth; // assembly->AddNode(extraShield1, 1, new TGeoTranslation(0., 0., -kzLength + 49.7 + dz)); Float_t dzKeep = dz; /////////////////////////////////// // // // Recess Station 2 // // // /////////////////////////////////// /////////////////////////////////// // SAA1 W-Ring 1 // // Drawing ALIP2A__0217 // /////////////////////////////////// Float_t saa1Wring1Width = 5.85; TGeoPcon* shSaa1Wring1 = new TGeoPcon(0., 360., 2); shSaa1Wring1->DefineSection(0, 0.00 , 20.30, 23.175); shSaa1Wring1->DefineSection(1, saa1Wring1Width, 20.30, 23.400); TGeoVolume* voSaa1Wring1 = new TGeoVolume("SAA1_WRING1", shSaa1Wring1, gGeoManager->GetMedium("SHIL_Ni/W3")); /////////////////////////////////// // SAA1 W-Ring 2 // // Drawing ALIP2A__0055 // /////////////////////////////////// Float_t saa1Wring2Rinner = 20.30; Float_t saa1Wring2Router = 23.40; Float_t saa1Wring2HWidth = 3.75; Float_t saa1Wring2Cutoffx = 4.45; Float_t saa1Wring2Cutoffy = 4.45; TGeoTubeSeg* shSaa1Wring2a = new TGeoTubeSeg(saa1Wring2Rinner, saa1Wring2Router, saa1Wring2HWidth, 0., 90.); shSaa1Wring2a->SetName("shSaa1Wring2a"); TGeoBBox* shSaa1Wring2b = new TGeoBBox(saa1Wring2Router / 2., saa1Wring2Router / 2., saa1Wring2HWidth); shSaa1Wring2b->SetName("shSaa1Wring2b"); TGeoTranslation* trSaa1Wring2b = new TGeoTranslation("trSaa1Wring2b", saa1Wring2Router / 2. + saa1Wring2Cutoffx, saa1Wring2Router / 2. + saa1Wring2Cutoffy, 0.); trSaa1Wring2b->RegisterYourself(); TGeoCompositeShape* shSaa1Wring2 = new TGeoCompositeShape("shSaa1Wring2", "(shSaa1Wring2a)*(shSaa1Wring2b:trSaa1Wring2b)"); TGeoVolume* voSaa1Wring2 = new TGeoVolume("SAA1_WRING2", shSaa1Wring2, gGeoManager->GetMedium("SHIL_Ni/W3")); /////////////////////////////////// // SAA1 W-Ring 3 // // Drawing ALIP2A__0216 // /////////////////////////////////// Float_t saa1Wring3Rinner = 20.30; Float_t saa1Wring3Router = 23.40; Float_t saa1Wring3HWidth = 3.75; Float_t saa1Wring3Cutoffx = 4.50; Float_t saa1Wring3Cutoffy = 4.40; TGeoTubeSeg* shSaa1Wring3a = new TGeoTubeSeg(saa1Wring3Rinner, saa1Wring3Router, saa1Wring3HWidth, 0., 90.); shSaa1Wring3a->SetName("shSaa1Wring3a"); TGeoBBox* shSaa1Wring3b = new TGeoBBox(saa1Wring3Router / 2., saa1Wring3Router / 2., saa1Wring3HWidth); shSaa1Wring3b->SetName("shSaa1Wring3b"); TGeoTranslation* trSaa1Wring3b = new TGeoTranslation("trSaa1Wring3b", saa1Wring3Router / 2. + saa1Wring3Cutoffx, saa1Wring3Router / 2. + saa1Wring3Cutoffy, 0.); trSaa1Wring3b->RegisterYourself(); TGeoCompositeShape* shSaa1Wring3 = new TGeoCompositeShape("shSaa1Wring3", "(shSaa1Wring3a)*(shSaa1Wring3b:trSaa1Wring3b)"); TGeoVolume* voSaa1Wring3 = new TGeoVolume("SAA1_WRING3", shSaa1Wring3, gGeoManager->GetMedium("SHIL_Ni/W3")); /////////////////////////////////// // SAA1 W-Ring 4 // // Drawing ALIP2A__0215 // /////////////////////////////////// Float_t saa1Wring4Width = 5.85; TGeoPcon* shSaa1Wring4 = new TGeoPcon(0., 360., 5); shSaa1Wring4->DefineSection(0, 0.00, 20.30, 23.40); shSaa1Wring4->DefineSection(1, 1.00, 20.30, 23.40); shSaa1Wring4->DefineSection(2, 1.00, 20.30, 24.50); shSaa1Wring4->DefineSection(3, 4.85, 20.30, 24.80); shSaa1Wring4->DefineSection(4, 5.85, 24.10, 24.80); TGeoVolume* voSaa1Wring4 = new TGeoVolume("SAA1_WRING4", shSaa1Wring4, gGeoManager->GetMedium("SHIL_Ni/W3")); /////////////////////////////////// // SAA1 W-Ring 5 // // Drawing ALIP2A__0218 // /////////////////////////////////// Float_t saa1Wring5Rinner = 20.30; Float_t saa1Wring5Router = 23.40; Float_t saa1Wring5HWidth = 0.85; TGeoVolume* voSaa1Wring5 = new TGeoVolume("SAA1_WRING5", new TGeoTube(saa1Wring5Rinner, saa1Wring5Router, saa1Wring5HWidth), gGeoManager->GetMedium("SHIL_Ni/W3")); // // Position the rings in the assembly // // Distance between rings Float_t saa1DWrings = 2.6; // dz = - (saa1Wring1Width + 6. * saa1Wring2HWidth + 2. * saa1Wring3HWidth + saa1Wring4Width + 2. * saa1Wring5HWidth + 2. * saa1DWrings) / 2.; extraShield2->AddNode(voSaa1Wring1, 1, new TGeoTranslation(0., 0., dz)); dz += saa1Wring1Width; dz += saa1Wring2HWidth; extraShield2->AddNode(voSaa1Wring2, 1, new TGeoCombiTrans(0., 0., dz, rot000)); extraShield2->AddNode(voSaa1Wring2, 2, new TGeoCombiTrans(0., 0., dz, rot180)); dz += saa1Wring2HWidth; dz += saa1DWrings; dz += saa1Wring2HWidth; extraShield2->AddNode(voSaa1Wring2, 3, new TGeoCombiTrans(0., 0., dz, rot090)); extraShield2->AddNode(voSaa1Wring2, 4, new TGeoCombiTrans(0., 0., dz, rot270)); dz += saa1Wring2HWidth; dz += saa1Wring5HWidth; extraShield2->AddNode(voSaa1Wring5, 1, new TGeoTranslation(0., 0., dz)); dz += saa1Wring5HWidth; dz += saa1Wring2HWidth; extraShield2->AddNode(voSaa1Wring2, 5, new TGeoCombiTrans(0., 0., dz, rot000)); extraShield2->AddNode(voSaa1Wring2, 6, new TGeoCombiTrans(0., 0., dz, rot180)); dz += saa1Wring2HWidth; dz += saa1DWrings; dz += saa1Wring3HWidth; extraShield2->AddNode(voSaa1Wring3, 1, new TGeoCombiTrans(0., 0., dz, rot090)); extraShield2->AddNode(voSaa1Wring3, 2, new TGeoCombiTrans(0., 0., dz, rot270)); dz += saa1Wring3HWidth; extraShield2->AddNode(voSaa1Wring4, 1, new TGeoTranslation(0., 0., dz)); dz += saa1Wring4Width; //assembly->AddNode(extraShield2, 1, new TGeoTranslation(0., 0., -kzLength + (kZch21 - zstart) + dz)); TGeoRotation* rotxz = new TGeoRotation("rotxz", 90., 0., 90., 90., 180., 0.); TGeoVolume* yout1 = gGeoManager->GetVolume("YOUT1"); yout1->AddNode(extraShield1, 1, new TGeoCombiTrans(0., 0., -zstart - ( 49.7 + dzKeep), rotxz)); yout1->AddNode(extraShield2, 1, new TGeoCombiTrans(0., 0., -zstart - (kZch21 - zstart + dz ), rotxz)); TGeoVolume* top = gGeoManager->GetVolume("ALIC"); top->AddNode(assembly, 1, new TGeoCombiTrans(0., 0., -zstart - kzLength, rotxz)); } } void AliSHILv2::Init() { // // Initialise the muon shield after it has been built // Int_t i; // if(AliLog::GetGlobalDebugLevel()>0) { printf("\n%s: ",ClassName()); for(i=0;i<35;i++) printf("*"); printf(" SHILv2_INIT "); for(i=0;i<35;i++) printf("*"); printf("\n%s: ",ClassName()); // // Here the SHIL initialisation code (if any!) for(i=0;i<80;i++) printf("*"); printf("\n"); } }