1 /**************************************************************************
2 * Copyright(c) 1998-1999, ALICE Experiment at CERN, All rights reserved. *
4 * Author: The ALICE Off-line Project. *
5 * Contributors are mentioned in the code where appropriate. *
7 * Permission to use, copy, modify and distribute this software and its *
8 * documentation strictly for non-commercial purposes is hereby granted *
9 * without fee, provided that the above copyright notice appears in all *
10 * copies and that both the copyright notice and this permission notice *
11 * appear in the supporting documentation. The authors make no claims *
12 * about the suitability of this software for any purpose. It is *
13 * provided "as is" without express or implied warranty. *
14 **************************************************************************/
17 //*************************************************************************
19 // SDD geometry, based on ROOT geometrical modeler
22 // This geometry has no dependence with aliroot, you can run it with root
23 // only, provided that the AliITSv11GeomCable classes are also compiled
25 // Ludovic Gaudichet gaudichet@to.infn.it
26 //*************************************************************************
32 // General Root includes
33 #include <Riostream.h>
36 // Root Geometry includes
37 #include <TGeoManager.h>
38 #include <TGeoVolume.h>
44 #include <TGeoCompositeShape.h>
45 #include <TGeoMatrix.h>
48 #include <TGeoTorus.h>
50 #include "AliITSv11GeometrySDD.h"
51 #include "AliITSv11GeomCableFlat.h"
52 #include "AliITSv11GeomCableRound.h"
54 const char* AliITSv11GeometrySDD::fgkSDDsensitiveVolName3 = "ITSsddSensitivL3";
55 const char* AliITSv11GeometrySDD::fgkSDDsensitiveVolName4 = "ITSsddSensitivL4";
56 const Double_t AliITSv11GeometrySDD::fgkSegmentLength = 37.21*2*fgkmm;
57 const Double_t AliITSv11GeometrySDD::fgkLadderWidth = 50.0*fgkmm;
58 const Double_t AliITSv11GeometrySDD::fgkLadderHeight = 30.0*fgkmm;
59 const Double_t AliITSv11GeometrySDD::fgkLadderSegBoxDW = 7.5*fgkmm;
60 const Double_t AliITSv11GeometrySDD::fgkLadderSegBoxDH = 7.1*fgkmm;
62 const Double_t AliITSv11GeometrySDD::fgkLadderBeamRadius = 0.6*fgkmm;
63 const Double_t AliITSv11GeometrySDD::fgkLadderLa = 3.*fgkmm;
64 const Double_t AliITSv11GeometrySDD::fgkLadderHa = 0.721979*fgkmm;
65 const Double_t AliITSv11GeometrySDD::fgkLadderLb = 3.7*fgkmm;
66 const Double_t AliITSv11GeometrySDD::fgkLadderHb = 0.890428*fgkmm;
67 const Double_t AliITSv11GeometrySDD::fgkLadderl = 0.25*fgkmm;
69 const Double_t AliITSv11GeometrySDD::fgkBottomBeamAngle = 56.5;
70 const Double_t AliITSv11GeometrySDD::fgkBeamSidePhi = 65;
72 const Double_t AliITSv11GeometrySDD::fgkLadWaferSep = 2*fgkmm;
73 const Double_t AliITSv11GeometrySDD::fgkPinSuppWidth = 2.5*fgkmm;
74 const Double_t AliITSv11GeometrySDD::fgkPinSuppHeight = 2.*fgkmm;
75 const Double_t AliITSv11GeometrySDD::fgkPinSuppRmax = 2.5/2.*fgkmm;
76 const Double_t AliITSv11GeometrySDD::fgkPinR = 1.5/2.*fgkmm;
77 const Double_t AliITSv11GeometrySDD::fgkPinSuppLength = 5.*fgkmm;
78 const Double_t AliITSv11GeometrySDD::fgkPinSuppThickness = 0.5*fgkmm;
79 const Double_t AliITSv11GeometrySDD::fgkPinSuppConeAngle = 4;
80 const Double_t AliITSv11GeometrySDD::fgkPinDXminOnSensor = (39./2.)*fgkmm;
81 const Double_t AliITSv11GeometrySDD::fgkPinPinDDXOnSensor = 3*fgkmm;
82 const Double_t AliITSv11GeometrySDD::fgkPinDYOnSensor = (52.5/2.)*fgkmm;
84 // parameters from ALR-0752/3
85 const Double_t AliITSv11GeometrySDD::fgkCoolPipeSuppHeight = 3.2*fgkmm;
86 const Double_t AliITSv11GeometrySDD::fgkCoolPipeSuppMaxLength = 14*fgkmm;
87 const Double_t AliITSv11GeometrySDD::fgkCoolPipeSuppWidthExt = 0.4*fgkmm;
88 const Double_t AliITSv11GeometrySDD::fgkCoolPipeSuppWidthIn = 0.65*fgkmm;
89 const Double_t AliITSv11GeometrySDD::fgkCoolPipeSuppHoleDiam = 2*fgkmm;
90 const Double_t AliITSv11GeometrySDD::fgkCoolPipeSuppFulWidth = 5.15*fgkmm;
91 const Double_t AliITSv11GeometrySDD::fgkCoolPipeSuppTongW = 0.8*fgkmm;
92 const Double_t AliITSv11GeometrySDD::fgkCoolPipeSuppAngle = 22.5;
93 const Double_t AliITSv11GeometrySDD::fgkCoolPipeSuppSlitL = 4.9*fgkmm;
94 const Double_t AliITSv11GeometrySDD::fgkCoolPipeSuppAxeDist = 3.05*fgkmm;
95 const Double_t AliITSv11GeometrySDD::fgkCoolPipeInnerDiam = 1.84*fgkmm;
96 const Double_t AliITSv11GeometrySDD::fgkCoolPipeOuterDiam = 2.*fgkmm;
98 const Double_t AliITSv11GeometrySDD::fgkBTBthick = 0.25 *fgkmm;
99 const Double_t AliITSv11GeometrySDD::fgkBTBlength = 55. *fgkmm;
100 const Double_t AliITSv11GeometrySDD::fgkBTBwidth = 18*fgkmm;
101 const Double_t AliITSv11GeometrySDD::fgkBTBaxisAtoBottom = 4*fgkmm;
102 const Double_t AliITSv11GeometrySDD::fgkBTBaxisAtoBase = 2.2*fgkmm;
103 const Double_t AliITSv11GeometrySDD::fgkRadiusAminBTB = 1. *fgkmm;
104 const Double_t AliITSv11GeometrySDD::fgkRadiusBminBTB = 0.53 *fgkmm;
105 const Double_t AliITSv11GeometrySDD::fgkBTBHoleLength = 15 *fgkmm;
106 const Double_t AliITSv11GeometrySDD::fgkBTBHolewidth = 6 *fgkmm;
107 const Double_t AliITSv11GeometrySDD::fgkBTBHoleRefX = 10 *fgkmm;
108 const Double_t AliITSv11GeometrySDD::fgkBTBHoleRefY = 6.5 *fgkmm;
110 const Double_t AliITSv11GeometrySDD::fgkLay3Rmin = 129.*fgkmm;
111 const Double_t AliITSv11GeometrySDD::fgkLay3Rmax = 205.*fgkmm;
112 const Double_t AliITSv11GeometrySDD::fgkLay3Length = (524.+0.)*fgkmm; // ladder+supporting rings (length of the virtual tube)
113 const Double_t AliITSv11GeometrySDD::fgkLay3LadderLength = 524.*fgkmm;
114 const Double_t AliITSv11GeometrySDD::fgkLay3DetShortRadius = 146.0*fgkmm;
115 const Double_t AliITSv11GeometrySDD::fgkLay3DetLongRadius = 152.0*fgkmm;
116 const Double_t AliITSv11GeometrySDD::fgkLay3LaddTopCornerEnd = 15.6*fgkmm;
117 const Int_t AliITSv11GeometrySDD::fgkLay3Ndet = 6;
118 const Int_t AliITSv11GeometrySDD::fgkLay3Nladd = 14;
119 const Double_t AliITSv11GeometrySDD::fgkLay3CoolPipeSuppH = 7.5*fgkmm;
121 const Double_t AliITSv11GeometrySDD::fgkLay4Rmin = 220.*fgkmm;
122 const Double_t AliITSv11GeometrySDD::fgkLay4Rmax = 291.*fgkmm;
123 const Double_t AliITSv11GeometrySDD::fgkLay4Length = (671.+0.)*fgkmm; // ladder+supporting rings (length of the virtual tube)
124 const Double_t AliITSv11GeometrySDD::fgkLay4LadderLength = 671.*fgkmm;
125 const Double_t AliITSv11GeometrySDD::fgkLay4DetShortRadius = 235.0*fgkmm;
126 const Double_t AliITSv11GeometrySDD::fgkLay4DetLongRadius = 240.5*fgkmm;
127 const Double_t AliITSv11GeometrySDD::fgkLay4LaddTopCornerEnd = 15.6*fgkmm;
128 const Int_t AliITSv11GeometrySDD::fgkLay4Ndet = 8;
129 const Int_t AliITSv11GeometrySDD::fgkLay4Nladd = 22;
130 const Double_t AliITSv11GeometrySDD::fgkLay4CoolPipeSuppH = 7.5*fgkmm;
132 const Double_t AliITSv11GeometrySDD::fgkEndLaddCardsShortRadiusLay3 = fgkLay3DetShortRadius;
133 const Double_t AliITSv11GeometrySDD::fgkEndLaddCardsShortRadiusLay4 = fgkLay4DetShortRadius;
134 const Double_t AliITSv11GeometrySDD::fgkDistEndLaddCardsLadd = 0.*fgkmm;
137 const Double_t AliITSv11GeometrySDD::fgkHybridAngle = 48.5; // approx !!!
138 // Origine taken at the hybrid corner :
139 const Double_t AliITSv11GeometrySDD::fgkHybridLength = 65*fgkmm;
140 const Double_t AliITSv11GeometrySDD::fgkHybridWidth = 41*fgkmm;
141 const Double_t AliITSv11GeometrySDD::fgkHybRndHoleRad = 1.05*fgkmm;
142 const Double_t AliITSv11GeometrySDD::fgkHybRndHoleZ = 2.5*fgkmm;
143 const Double_t AliITSv11GeometrySDD::fgkHybRndHoleX = fgkHybridWidth-23.599*fgkmm;
145 const Double_t AliITSv11GeometrySDD::fgkHybFLlowHoleDZ = 9.698*fgkmm;
146 const Double_t AliITSv11GeometrySDD::fgkHybFLlowHolePasDX = 10.754*fgkmm;
147 const Double_t AliITSv11GeometrySDD::fgkHybFLlowHoleAmbDX = 9.122*fgkmm;
148 // center of ships to the border
149 const Double_t AliITSv11GeometrySDD::fgkHybFLlowChipZ4 = fgkHybridLength-(4.654 )*fgkmm-fgkHybFLlowHoleDZ/2;
150 const Double_t AliITSv11GeometrySDD::fgkHybFLlowChipZ3 = fgkHybridLength-(4.654+15. )*fgkmm-fgkHybFLlowHoleDZ/2;
151 const Double_t AliITSv11GeometrySDD::fgkHybFLlowChipZ2 = fgkHybridLength-(4.654+15.*2)*fgkmm-fgkHybFLlowHoleDZ/2;
152 const Double_t AliITSv11GeometrySDD::fgkHybFLlowChipZ1 = fgkHybridLength-(4.654+15.*3)*fgkmm-fgkHybFLlowHoleDZ/2;
153 const Double_t AliITSv11GeometrySDD::fgkHybFLlowPasX = fgkHybridWidth-32.775*fgkmm;
154 const Double_t AliITSv11GeometrySDD::fgkHybFLlowAmbX = fgkHybridWidth-20.791*fgkmm;
155 const Double_t AliITSv11GeometrySDD::fgkHybChipsDZ = 9.221*fgkmm;
156 const Double_t AliITSv11GeometrySDD::fgkHybPascalDX = 10.245*fgkmm;
157 const Double_t AliITSv11GeometrySDD::fgkHybAmbraDX = 8.51*fgkmm;
158 const Double_t AliITSv11GeometrySDD::fgkHybFLUpperWidth = 15.012*fgkmm;
159 const Double_t AliITSv11GeometrySDD::fgkHybFLUpperLength = 59.878*fgkmm;
160 const Double_t AliITSv11GeometrySDD::fgkHybFLUpperAlDZ = 11.183*fgkmm;
161 const Double_t AliITSv11GeometrySDD::fgkHybFLUpperAldx = 2.307*fgkmm;
163 const Double_t AliITSv11GeometrySDD::fgkHybCC2SensorLen = 9.500*fgkmm;
164 const Double_t AliITSv11GeometrySDD::fgkHybCC2SensorWid = 1.490*fgkcm; //???
165 const Double_t AliITSv11GeometrySDD::fgkHybCC2SensorAng = 15.0;
167 const Double_t AliITSv11GeometrySDD::fgkmu = 1*fgkmicron; // 1*fgkmicron; // can be increase for checking thin objects
168 const Double_t AliITSv11GeometrySDD::fgkHybridThBridgeThick = 0.25*fgkmm; // ???
169 const Double_t AliITSv11GeometrySDD::fgkHybAlThick = 30*fgkmu;
170 const Double_t AliITSv11GeometrySDD::fgkHybUpThick = 20*fgkmu;
171 const Double_t AliITSv11GeometrySDD::fgkHybGlueScrnThick = 50*fgkmu; // ??? ?????
172 const Double_t AliITSv11GeometrySDD::fgkHybGlueLowThick = 90*fgkmu;
173 const Double_t AliITSv11GeometrySDD::fgkHybGlueUpThick = 90*fgkmu; // sur ?????
174 const Double_t AliITSv11GeometrySDD::fgkHybAlCCThick = 12*fgkmu;
175 const Double_t AliITSv11GeometrySDD::fgkHybUpCCThick = 12*fgkmu;
176 const Double_t AliITSv11GeometrySDD::fgkHybChipThick = 150*fgkmu;
177 const Double_t AliITSv11GeometrySDD::fgkHybGlueAgThick = 50*fgkmu; // ??? ????
178 const Double_t AliITSv11GeometrySDD::fgkHybUnderNiThick = 20*fgkmu; // ??? ????
179 const Int_t AliITSv11GeometrySDD::fgkNHybSMD = 25;
180 const Double_t AliITSv11GeometrySDD::fgkHybSMDposX[fgkNHybSMD] =
181 {2.92*fgkmm,6.5*fgkmm,10.13*fgkmm,13.59*fgkmm,21.40*fgkmm,
182 2.92*fgkmm,6.5*fgkmm,10.13*fgkmm,13.59*fgkmm,19.91*fgkmm,
183 2.92*fgkmm,6.5*fgkmm,10.13*fgkmm,13.59*fgkmm,17.09*fgkmm,21.40*fgkmm,
184 2.92*fgkmm,6.5*fgkmm,10.13*fgkmm,13.59*fgkmm,19.91*fgkmm,
185 1.63*fgkmm,5.22*fgkmm,13.59*fgkmm,21.40*fgkmm};
186 const Double_t AliITSv11GeometrySDD::fgkHybSMDposZ[fgkNHybSMD] =
187 { 2.3 *fgkmm, 2.3 *fgkmm, 2.3 *fgkmm, 2.3 *fgkmm, 2.3 *fgkmm,
188 17.315*fgkmm,17.315*fgkmm,17.315*fgkmm,17.315*fgkmm,17.315*fgkmm,
189 32.31*fgkmm,32.31*fgkmm,32.31*fgkmm,32.31*fgkmm,32.31*fgkmm,32.31*fgkmm,
190 47.38*fgkmm,47.38*fgkmm,47.38*fgkmm,47.38*fgkmm,47.38*fgkmm,
191 62.68*fgkmm,62.06*fgkmm,62.06*fgkmm,62.06*fgkmm};
192 const Double_t AliITSv11GeometrySDD::fgkHybSMDmiddleW = 0.954*fgkmm;
193 const Double_t AliITSv11GeometrySDD::fgkHybSMDmiddleL = 0.47 *fgkmm;
194 const Double_t AliITSv11GeometrySDD::fgkHybSMDendW = 1.132*fgkmm;
195 const Double_t AliITSv11GeometrySDD::fgkHybSMDendL = 0.925*fgkmm;
196 const Double_t AliITSv11GeometrySDD::fgkHybSMDheight = 400.*fgkmu; // ??? ????!!!!!!!
198 const Double_t AliITSv11GeometrySDD::fgkWaferThickness = 300.*fgkmu;
199 const Double_t AliITSv11GeometrySDD::fgkWaferWidth = 72.5 *fgkmm;
200 const Double_t AliITSv11GeometrySDD::fgkWaferLength = 87.6 *fgkmm;
201 const Double_t AliITSv11GeometrySDD::fgkWaferThickSens = 299.8*fgkmu;
202 const Double_t AliITSv11GeometrySDD::fgkWaferWidthSens = 70.17*fgkmm;
203 // 256 anodes times 294 microns of pitch
204 const Double_t AliITSv11GeometrySDD::fgkWaferLengthSens = 256*294*fgkmicron;
206 const Double_t AliITSv11GeometrySDD::fgkDigitCablWidth = 18.4*fgkmm;
207 const Double_t AliITSv11GeometrySDD::fgkDigitCablAlThick = (30+30*8./10.)*fgkmicron; // will probably change
208 const Double_t AliITSv11GeometrySDD::fgkDigitCablPolyThick = (20+12)*fgkmicron; // will probably change
210 const Double_t AliITSv11GeometrySDD::fgkWaHVcableAlThick = 30*2./10.*fgkmu; // will probably change // Al ratio is random !!!
211 const Double_t AliITSv11GeometrySDD::fgkWaHVcablePolyThick = 175*fgkmu; // will probably change
212 const Double_t AliITSv11GeometrySDD::fgkWaHVcableLength = 67.08*fgkmm;
213 const Double_t AliITSv11GeometrySDD::fgkWaHVcableWitdh = 17.4*fgkmm; // check !!!
214 const Double_t AliITSv11GeometrySDD::fgkWaHVcableDW = 5.24*fgkmm; //5.24*fgkmm;// check !!!
216 const Double_t AliITSv11GeometrySDD::fgkSensorGlassLX = 5. *fgkmm;
217 const Double_t AliITSv11GeometrySDD::fgkSensorGlassLZ = 5. *fgkmm;
218 const Double_t AliITSv11GeometrySDD::fgkSensorGlassLY = 150. *fgkmu;
219 const Double_t AliITSv11GeometrySDD::fgkGlassDXOnSensor = 26.28*fgkmm; // check !!!
220 const Double_t AliITSv11GeometrySDD::fgkGlassDZOnSensor = 22.50*fgkmm; // check !!!
222 const Double_t AliITSv11GeometrySDD::fgkTransitHVAlThick = 30*2./10.*fgkmu; // check // will probably change //Al ratio is random
223 const Double_t AliITSv11GeometrySDD::fgkTransitHVPolyThick = 100*fgkmu; // check // will probably change
224 const Double_t AliITSv11GeometrySDD::fgkTransitHVHeadLX = 71.46*fgkmm; // check !!!
225 const Double_t AliITSv11GeometrySDD::fgkTransitHVHeadLZ = 21.3*fgkmm;
226 const Double_t AliITSv11GeometrySDD::fgkTransitHVBondingLZ = 3.6*fgkmm;
227 const Double_t AliITSv11GeometrySDD::fgkTransitHVtailLength = 27*fgkmm; // ???, not yet fixed ...
228 const Double_t AliITSv11GeometrySDD::fgkTransitHVtailWidth = 26*fgkmm;
229 const Double_t AliITSv11GeometrySDD::fgkTransitHVtailXpos = 8*fgkmm; //8*fgkmm // ???, a mesurer !!!
230 const Double_t AliITSv11GeometrySDD::fgkTransitHVsideLZ = 10.34*fgkmm;
231 const Double_t AliITSv11GeometrySDD::fgkTransitHVsideLeftZ = 4.11*fgkmm;
232 const Double_t AliITSv11GeometrySDD::fgkTransitHVsideRightZ = 3.5*fgkmm; // ???, a mesurer !!!
234 const Double_t AliITSv11GeometrySDD::fgkLongHVcablePolyThick= (20+30+125+30+20+30+125+30+20)*fgkmu; // check // will probably change
235 const Double_t AliITSv11GeometrySDD::fgkLongHVcableAlThick = (30+30*2/10+30)*fgkmu; // check // will probably change
236 const Double_t AliITSv11GeometrySDD::fgkLongHVcableSeparation = 600*fgkmicron;
238 const Double_t AliITSv11GeometrySDD::fgkRubyDX = 14.*fgkmm;
239 const Double_t AliITSv11GeometrySDD::fgkRubyZladd3 = 250*fgkmm;
240 const Double_t AliITSv11GeometrySDD::fgkRubyZladd4 = 325*fgkmm;
242 // the stesalite ladder foot at its end
243 const Double_t AliITSv11GeometrySDD::fgkLadFootX = 60.*fgkmm;
244 const Double_t AliITSv11GeometrySDD::fgkLadFootZ = 20.*fgkmm;
245 const Double_t AliITSv11GeometrySDD::fgkLadFootY = 8.*fgkmm;
246 const Double_t AliITSv11GeometrySDD::fgkLadFootMiddleY = 4.5*fgkmm;
247 const Double_t AliITSv11GeometrySDD::fgkLadBox1X = 23.*fgkmm;
248 const Double_t AliITSv11GeometrySDD::fgkLadFingerPrintX = 6.*fgkmm;
249 const Double_t AliITSv11GeometrySDD::fgkLadFingerPrintY = 1.*fgkmm;
250 const Double_t AliITSv11GeometrySDD::fgkLadFingerPrintBorder = 4.*fgkmm;
251 const Double_t AliITSv11GeometrySDD::fgkRubyCageHoleZ = 8.*fgkmm;
252 const Double_t AliITSv11GeometrySDD::fgkRubyCageHoleX = 9.*fgkmm;
253 const Double_t AliITSv11GeometrySDD::fgkRubyCageHoleY = 6.5*fgkmm;
254 const Double_t AliITSv11GeometrySDD::fgkRubyCageAxisShift = 0.5*fgkmm;
255 const Double_t AliITSv11GeometrySDD::fgkScrewM4diam = 4.*fgkmm;
257 const Double_t AliITSv11GeometrySDD::fgkRubyScrewShiftToCenterY = 0.1;
258 const Double_t AliITSv11GeometrySDD::fgkRubyHoleDiam = 0.5;
260 // the U cooling pipe and its heat exchanger in end-ladder cards system
261 const Double_t AliITSv11GeometrySDD::fgkEndLadPipeUlengthLay3 = 138*fgkmm;
262 const Double_t AliITSv11GeometrySDD::fgkEndLadPipeUlengthLay4 = 150*fgkmm;
263 const Double_t AliITSv11GeometrySDD::fgkEndLadPipeUwidth = 59*fgkmm;
264 const Double_t AliITSv11GeometrySDD::fgkEndLadPipeRadius = 5*fgkmm;
265 const Double_t AliITSv11GeometrySDD::fgkEndLadPipeInnerDiam = 2.8*fgkmm;
266 const Double_t AliITSv11GeometrySDD::fgkEndLadPipeOuterDiam = 3.*fgkmm;
267 //--- The al body of the cooling syst.of the heat exchanger :
268 const Double_t AliITSv11GeometrySDD::fgkEndLadPipeArmZLay3 = 112.*fgkmm; //
269 const Double_t AliITSv11GeometrySDD::fgkEndLadPipeArmZLay4 = 125.*fgkmm; //
270 const Double_t AliITSv11GeometrySDD::fgkEndLadPipeArmX = 4.75*fgkmm; // the arms of the U cooling tube
271 const Double_t AliITSv11GeometrySDD::fgkEndLadPipeArmY = 6.8*fgkmm;
272 const Double_t AliITSv11GeometrySDD::fgkEndLadPipeArmBoxDY = 1.03*fgkmm; // shift in Y of the arms from the axis
273 const Double_t AliITSv11GeometrySDD::fgkEndLadPipeArmBoxDX = 0.125*fgkmm;// shift in X of the arms from the axis
274 const Double_t AliITSv11GeometrySDD::fgkEndLadPipeArmZpos = 8.9*fgkmm; //
277 const Double_t AliITSv11GeometrySDD::fgkLVcardX = 26.525*fgkmm;
278 const Double_t AliITSv11GeometrySDD::fgkLVcardY = 44.95*fgkmm;
279 const Double_t AliITSv11GeometrySDD::fgkLVcardZ = 1.*fgkmm; // all except Cu layer //???
280 const Double_t AliITSv11GeometrySDD::fgkLVcardCuZ = 0.1*fgkmm; //???
282 const Double_t AliITSv11GeometrySDD::fgkLVChip0X = 16.525*fgkmm;
283 const Double_t AliITSv11GeometrySDD::fgkLVChip0Y = 10.8*fgkmm;
284 const Double_t AliITSv11GeometrySDD::fgkLVChip0Z = 3.5*fgkmm; // all except si layer //???
285 const Double_t AliITSv11GeometrySDD::fgkLVChip0SiZ = 0.2*fgkmm; //???????????????????????????????????????????????????
286 const Double_t AliITSv11GeometrySDD::fgkLVChip0PosX = 13.*fgkmm; //19.95*fgkmm; ???
287 const Double_t AliITSv11GeometrySDD::fgkLVChip0PosY = 10.3*fgkmm;
289 const Double_t AliITSv11GeometrySDD::fgkLVChip1X = 6.00*fgkmm;
290 const Double_t AliITSv11GeometrySDD::fgkLVChip1Y = 6.00*fgkmm;
291 const Double_t AliITSv11GeometrySDD::fgkLVChip1Z = 1*fgkmm; // ???
292 const Double_t AliITSv11GeometrySDD::fgkLVChip1SiZ = 0.2*fgkmm; // ???
293 const Double_t AliITSv11GeometrySDD::fgkLVChip1PosX = 18.*fgkmm;
294 const Double_t AliITSv11GeometrySDD::fgkLVChip1PosY = 27.6*fgkmm;
296 const Double_t AliITSv11GeometrySDD::fgkLVChip2X = 6.00*fgkmm;
297 const Double_t AliITSv11GeometrySDD::fgkLVChip2Y = 6.00*fgkmm;
298 const Double_t AliITSv11GeometrySDD::fgkLVChip2Z = 1*fgkmm; // ???
299 const Double_t AliITSv11GeometrySDD::fgkLVChip2SiZ = 0.2*fgkmm; //???
300 const Double_t AliITSv11GeometrySDD::fgkLVChip2PosX = 18.0*fgkmm;
301 const Double_t AliITSv11GeometrySDD::fgkLVChip2PosY = 39.0*fgkmm;
303 const Double_t AliITSv11GeometrySDD::fgkLVChip3X = 4.01*fgkmm;
304 const Double_t AliITSv11GeometrySDD::fgkLVChip3Y = 4.01*fgkmm;
305 const Double_t AliITSv11GeometrySDD::fgkLVChip3Z = 1*fgkmm; // ???
306 const Double_t AliITSv11GeometrySDD::fgkLVChip3SiZ = 0.2*fgkmm;
307 const Double_t AliITSv11GeometrySDD::fgkLVChip3PosX = 20.7*fgkmm;
308 const Double_t AliITSv11GeometrySDD::fgkLVChip3PosY = 21.4*fgkmm;
310 const Double_t AliITSv11GeometrySDD::fgkLVcoolX1 = 17.25*fgkmm;
311 const Double_t AliITSv11GeometrySDD::fgkLVcoolY1 = 8.7*fgkmm;
312 const Double_t AliITSv11GeometrySDD::fgkLVcoolZ1 = 1.*fgkmm;
314 const Double_t AliITSv11GeometrySDD::fgkLVcoolX2 = 3.5*fgkmm;
315 const Double_t AliITSv11GeometrySDD::fgkLVcoolY2 = 8.7*fgkmm;
316 const Double_t AliITSv11GeometrySDD::fgkLVcoolZ2 = 2.3*fgkmm;
318 const Double_t AliITSv11GeometrySDD::fgkLVcoolX3 = 4.75*fgkmm;
319 const Double_t AliITSv11GeometrySDD::fgkLVcoolY3 = 3.1*fgkmm; //+0.1=glue
320 const Double_t AliITSv11GeometrySDD::fgkLVcoolPosY = 6.5*fgkmm;
323 const Double_t AliITSv11GeometrySDD::fgkHVCardCeramX = 54.01*fgkmm;
324 const Double_t AliITSv11GeometrySDD::fgkHVCardCeramY = 40.89*fgkmm;
325 const Double_t AliITSv11GeometrySDD::fgkHVCardCeramZ = 0.7*fgkmm; // ???
327 const Double_t AliITSv11GeometrySDD::fgkHVCardCapa1X = 6.8*fgkmm;
328 const Double_t AliITSv11GeometrySDD::fgkHVCardCapa1Z = 1.*fgkmm; // ???
329 const Double_t AliITSv11GeometrySDD::fgkHVCardCapa1Ymid = 4.1*fgkmm;
330 const Double_t AliITSv11GeometrySDD::fgkHVCardCapa1Yend = 0.95*fgkmm; // doesn't take into account the soldering
331 const Double_t AliITSv11GeometrySDD::fgkHVCardCapa1PosX = 13.1*fgkmm;
332 const Double_t AliITSv11GeometrySDD::fgkHVCardCapa1PosY = 14.5*fgkmm;
334 const Double_t AliITSv11GeometrySDD::fgkHVCardCapa2X = 6.8*fgkmm;
335 const Double_t AliITSv11GeometrySDD::fgkHVCardCapa2Z = 1.*fgkmm; // ???
336 const Double_t AliITSv11GeometrySDD::fgkHVCardCapa2Ymid = 2.9*fgkmm;
337 const Double_t AliITSv11GeometrySDD::fgkHVCardCapa2Yend = 0.95*fgkmm;
338 const Double_t AliITSv11GeometrySDD::fgkHVCardCapa2PosX = -12.6*fgkmm;
339 const Double_t AliITSv11GeometrySDD::fgkHVCardCapa2PosY = 16.54*fgkmm;
341 const Double_t AliITSv11GeometrySDD::fgkHVCardCapa3Xmid = 3.0*fgkmm;
342 const Double_t AliITSv11GeometrySDD::fgkHVCardCapa3Xend = 0.91*fgkmm;
343 const Double_t AliITSv11GeometrySDD::fgkHVCardCapa3Z = 2.*fgkmm; // ???
344 const Double_t AliITSv11GeometrySDD::fgkHVCardCapa3Y = 3.43*fgkmm;
346 const Double_t AliITSv11GeometrySDD::fgkHVCardCapa3PosX1 = 14.6*fgkmm;
347 const Double_t AliITSv11GeometrySDD::fgkHVCardCapa3PosX2 = 7.2*fgkmm;
348 const Double_t AliITSv11GeometrySDD::fgkHVCardCapa3PosX3 = 2.52*fgkmm;
349 const Double_t AliITSv11GeometrySDD::fgkHVCardCapa3PosX4 = -4.96*fgkmm;
350 const Double_t AliITSv11GeometrySDD::fgkHVCardCapa3PosX5 = -13.82*fgkmm;
351 const Double_t AliITSv11GeometrySDD::fgkHVCardCapa3PosY1 = 6.27*fgkmm;
352 const Double_t AliITSv11GeometrySDD::fgkHVCardCapa3PosY2 = 0.7*fgkmm;
353 const Double_t AliITSv11GeometrySDD::fgkHVCardCapa3PosY3 = 9.1*fgkmm;
355 const Double_t AliITSv11GeometrySDD::fgkHVCardCool1X = 14.*fgkmm;
356 const Double_t AliITSv11GeometrySDD::fgkHVCardCool1Y = 9.5*fgkmm;
357 const Double_t AliITSv11GeometrySDD::fgkHVCardCool1Z = 2.*fgkmm;
358 const Double_t AliITSv11GeometrySDD::fgkHVCardCool2X = 14.25*fgkmm;
359 const Double_t AliITSv11GeometrySDD::fgkHVCardCool2Y = 3.5*fgkmm;
360 const Double_t AliITSv11GeometrySDD::fgkHVCardCool2Z = 4.5*fgkmm;
361 const Double_t AliITSv11GeometrySDD::fgkHVCardCool3X = 4.5*fgkmm;
362 const Double_t AliITSv11GeometrySDD::fgkHVCardCool3Y = 3.5*fgkmm;
363 const Double_t AliITSv11GeometrySDD::fgkHVCardCool3Z = 7.2*fgkmm;
364 const Double_t AliITSv11GeometrySDD::fgkHVCardCoolDY = 6.*fgkmm;
366 const Double_t AliITSv11GeometrySDD::fgkCarlosSuppX1 = 19.5*fgkmm;
367 const Double_t AliITSv11GeometrySDD::fgkCarlosSuppY1 = 2*fgkmm;
368 const Double_t AliITSv11GeometrySDD::fgkCarlosSuppX2 = 35.*fgkmm;
369 const Double_t AliITSv11GeometrySDD::fgkCarlosSuppY2 = 3.9*fgkmm;
370 const Double_t AliITSv11GeometrySDD::fgkCarlosSuppZ = 17.*fgkmm;
371 const Double_t AliITSv11GeometrySDD::fgkCarlosSuppAngle = 45;
372 const Double_t AliITSv11GeometrySDD::fgkCarlosSuppX3 = 4.5*fgkmm;
373 const Double_t AliITSv11GeometrySDD::fgkCarlosSuppY3 = 3.*fgkmm;
374 const Double_t AliITSv11GeometrySDD::fgkCarlosSuppZ3 = 12.*fgkmm;
375 const Double_t AliITSv11GeometrySDD::fgkCarlosSuppTopLen = 8.65*fgkmm;
377 // screws fixing boards to the end-ladder on the U tube
378 const Double_t AliITSv11GeometrySDD::fgkLittleScrewHeadR = 1.85*fgkmm;
379 const Double_t AliITSv11GeometrySDD::fgkLittleScrewHeadH = 1.5*fgkmm;
380 const Double_t AliITSv11GeometrySDD::fgkLittleScrewR = 0.7*fgkmm;
381 const Double_t AliITSv11GeometrySDD::fgkShiftLittleScrewLV = 3*fgkmm; // ???
382 const Double_t AliITSv11GeometrySDD::fgkLittleLVScrewHeadR = 1.2*fgkmm; // ???
385 const Double_t AliITSv11GeometrySDD::fgkCarlosCardX1 = (25.50+28.50)*fgkmm; // length (first part of Carlos card)
386 const Double_t AliITSv11GeometrySDD::fgkCarlosCardY1 = 1.6*fgkmm; // thickness
387 const Double_t AliITSv11GeometrySDD::fgkCarlosCardZ1 = 40.8*fgkmm; // width
388 const Double_t AliITSv11GeometrySDD::fgkCarlosCardCuY = 0.1*fgkmm; // thickness of Cu layer (strips)
389 const Double_t AliITSv11GeometrySDD::fgkCarlosCardX2 = 25.50*fgkmm; // length (2nd part of Carlos card)
390 const Double_t AliITSv11GeometrySDD::fgkCarlosCardZ2 = 8.20*fgkmm; // width
392 const Double_t AliITSv11GeometrySDD::fgkCarlosCardChipSiThick = 0.1*fgkmm; // ??? idem for all chips ???
393 const Double_t AliITSv11GeometrySDD::fgkCarlosCardShift = 9*fgkmm; // ??? shift in z w.r.t. heat bridge
395 // size and position of various chips on carlos end-ladder board
396 const Double_t AliITSv11GeometrySDD::fgkCarlosU1X = 13*fgkmm;
397 const Double_t AliITSv11GeometrySDD::fgkCarlosU1Y = 1.68*fgkmm;
398 const Double_t AliITSv11GeometrySDD::fgkCarlosU1Z = 13*fgkmm;
399 const Double_t AliITSv11GeometrySDD::fgkCarlosU1posX = 18.4*fgkmm;
400 const Double_t AliITSv11GeometrySDD::fgkCarlosU1posZ = -7.2*fgkmm;
402 const Double_t AliITSv11GeometrySDD::fgkCarlosU2X = 13.75*fgkmm;
403 const Double_t AliITSv11GeometrySDD::fgkCarlosU2Y = 1.60*fgkmm;
404 const Double_t AliITSv11GeometrySDD::fgkCarlosU2Z = 13.85*fgkmm;
405 const Double_t AliITSv11GeometrySDD::fgkCarlosU2posX = -0.375*fgkmm;
406 const Double_t AliITSv11GeometrySDD::fgkCarlosU2posZ = -9.725*fgkmm;
408 const Double_t AliITSv11GeometrySDD::fgkCarlosU3X = 5*fgkmm;
409 const Double_t AliITSv11GeometrySDD::fgkCarlosU3Y = 1.*fgkmm;
410 const Double_t AliITSv11GeometrySDD::fgkCarlosU3Z = 5*fgkmm;
411 const Double_t AliITSv11GeometrySDD::fgkCarlosU3posX = 6.4*fgkmm;
412 const Double_t AliITSv11GeometrySDD::fgkCarlosU3posZ = 9.9*fgkmm;
415 const Double_t AliITSv11GeometrySDD::fgkCarlosU4posX = -12*fgkmm;
416 const Double_t AliITSv11GeometrySDD::fgkCarlosU4posZ = 3.6*fgkmm;
418 const Double_t AliITSv11GeometrySDD::fgkCarlosU17X = 16*fgkmm;
419 const Double_t AliITSv11GeometrySDD::fgkCarlosU17Y = 3.5*fgkmm;
420 const Double_t AliITSv11GeometrySDD::fgkCarlosU17Z = 10.9*fgkmm;
421 const Double_t AliITSv11GeometrySDD::fgkCarlosU17posX = -17.84*fgkmm;
422 const Double_t AliITSv11GeometrySDD::fgkCarlosU17posZ = -10.95*fgkmm;
424 const Double_t AliITSv11GeometrySDD::fgkCarlosU35X = 4*fgkmm;
425 const Double_t AliITSv11GeometrySDD::fgkCarlosU35Y = 1.*fgkmm;
426 const Double_t AliITSv11GeometrySDD::fgkCarlosU35Z = 4*fgkmm;
427 const Double_t AliITSv11GeometrySDD::fgkCarlosU35posX = -21.6*fgkmm;
428 const Double_t AliITSv11GeometrySDD::fgkCarlosU35posZ = 2.3*fgkmm;
430 const Double_t AliITSv11GeometrySDD::fgkCarlosU36X = 6*fgkmm;
431 const Double_t AliITSv11GeometrySDD::fgkCarlosU36Y = 1.*fgkmm;
432 const Double_t AliITSv11GeometrySDD::fgkCarlosU36Z = 6*fgkmm;
433 const Double_t AliITSv11GeometrySDD::fgkCarlosU36posX = -21.6*fgkmm;
434 const Double_t AliITSv11GeometrySDD::fgkCarlosU36posZ = 9.6*fgkmm;
436 const Double_t AliITSv11GeometrySDD::fgkCarlosQZ1X = 8*fgkmm;
437 const Double_t AliITSv11GeometrySDD::fgkCarlosQZ1Y = 1.7*fgkmm; // look thicker than design number (0.7) ! ???
438 const Double_t AliITSv11GeometrySDD::fgkCarlosQZ1Z = 3.7*fgkmm;
439 const Double_t AliITSv11GeometrySDD::fgkCarlosQZ1posX = -12*fgkmm;
440 const Double_t AliITSv11GeometrySDD::fgkCarlosQZ1posZ = 10.6*fgkmm;
442 // distance from the heat bridge center to the card center :
443 const Double_t AliITSv11GeometrySDD::fgkCarlosCard2HeatBridge = fgkCarlosSuppY2/2+fgkCarlosCardY1/2+fgkCarlosU1Y+0.1*fgkmm;
445 // some pieces at the end of the carbon fiber ladder
446 const Double_t AliITSv11GeometrySDD::fgkCoolPipeLay3Len = 467.*fgkmm; // ???
447 const Double_t AliITSv11GeometrySDD::fgkCoolPipeLay4Len = 616.*fgkmm; // ???
448 const Double_t AliITSv11GeometrySDD::fgkHVguideX1 = 42.5*fgkmm;
449 const Double_t AliITSv11GeometrySDD::fgkHVguideY1 = 7.*fgkmm;
450 const Double_t AliITSv11GeometrySDD::fgkHVguideZ1 = 10.*fgkmm;
451 const Double_t AliITSv11GeometrySDD::fgkHVguideZ2 = 6.*fgkmm;
452 const Double_t AliITSv11GeometrySDD::fgkHVguideDX = -8.5*fgkmm;
453 const Double_t AliITSv11GeometrySDD::fgkHVguideSuppFullZ = 37.5*fgkmm;
455 // Cooling connector between phynox and plastic cooling water tubes
456 const Double_t AliITSv11GeometrySDD::fgkConnectorCoolTubeRmin = 1 *fgkmm;
457 const Double_t AliITSv11GeometrySDD::fgkConnectorCoolTubeR1 = 2.5*fgkmm; // ???
458 const Double_t AliITSv11GeometrySDD::fgkConnectorCoolTubeL1 = 3.*fgkmm; // ???
459 const Double_t AliITSv11GeometrySDD::fgkConnectorCoolTubeR2 = 3.5*fgkmm; // ???
460 const Double_t AliITSv11GeometrySDD::fgkConnectorCoolTubeL2 = 2.*fgkmm; // ???
461 const Double_t AliITSv11GeometrySDD::fgkConnectorCoolTubeR3 = 3.*fgkmm; // ???
462 const Double_t AliITSv11GeometrySDD::fgkConnectorCoolTubeL3 = 5 *fgkmm; // ???
465 // parameters for coding SDD cables on SDD and SSD cones
466 const Double_t AliITSv11GeometrySDD::fgkSectionCuPerMod = 3*2*0.006 + 3*2*0.0005 + 2*0.002;
467 // copper : LV + signal + HV(HV ???)
468 const Double_t AliITSv11GeometrySDD::fgkSectionPlastPerMod = (TMath::Pi()*(3*0.36*0.36/4 + 3*0.21*0.21/4 + 2*0.115*0.115/4)
469 - fgkSectionCuPerMod);
471 const Double_t AliITSv11GeometrySDD::fgkSectionGlassPerMod = 3*0.006; // ???
472 const Double_t AliITSv11GeometrySDD::fgkSectionCoolPolyuEL = 0.4672;
473 const Double_t AliITSv11GeometrySDD::fgkSectionCoolWaterEL = 0.3496;
474 const Double_t AliITSv11GeometrySDD::fgkEndLadderEarthCableR = 0.5*fgkmm;
475 // (sections are given in cm square)
476 const Double_t AliITSv11GeometrySDD::fgkCableBendRatio = 1.3; // ??? this factor account for the bending of cables
477 const Double_t AliITSv11GeometrySDD::fgkHybridAlFoilThick = 0.1*fgkmm; // Thickness of Al foil on hybrid side - TO BE CHECKED
478 const Double_t AliITSv11GeometrySDD::fgkHybridAlFoilWide = 4.2*fgkmm; // Width of Al foil on hybrid side - from digitCableA
479 const Double_t AliITSv11GeometrySDD::fgkHybridAlFoilSide = 2.0*fgkmm; // Side length of Al foil on hybrid side
481 const Double_t AliITSv11GeometrySDD::fgkConeSDDr1 = 11.87574*fgkcm;
482 const Double_t AliITSv11GeometrySDD::fgkConeSDDr2 = 26.07574*fgkcm;
483 const Double_t AliITSv11GeometrySDD::fgkConeSDDz1 = 3.36066*fgkcm + 186.0*fgkmm + 0.5*790.0*fgkmm - 19.18934*fgkcm - 1.6;
484 const Double_t AliITSv11GeometrySDD::fgkConeSDDz2 = 17.56066*fgkcm + 186.0*fgkmm + 0.5*790.0*fgkmm - 19.18934*fgkcm - 1.6;
485 // These last parameters come from cone's code and define the slope
486 // and position of the SDD cone end. For some unknown reason, this doesn't
487 // allow to stick on the SDD cone. This has to be checked when a correct
488 // version of the cone is available ... For now 'm applying some approximative
491 const Double_t AliITSv11GeometrySDD::fgkSDDCableR1 = 16*fgkcm; // ??? // part 1 of "cable cone"
492 const Double_t AliITSv11GeometrySDD::fgkSDDCableR2 = 23*fgkcm; // ??? // part 1/2 of "cable cone"
493 const Double_t AliITSv11GeometrySDD::fgkSDDCableR3 = 26*fgkcm; // ??? // part 2 of "cable cone"
495 const Double_t AliITSv11GeometrySDD::fgkSDDCableDZint = 3.5*fgkcm;
496 const Double_t AliITSv11GeometrySDD::fgkSDDCableR5 = 37*fgkcm; // third part of "cable cone"
497 const Double_t AliITSv11GeometrySDD::fgkSDDCableZ5 = 65*fgkcm; // third part of "cable cone"
505 ClassImp(AliITSv11GeometrySDD)
507 //________________________________________________________________________
508 AliITSv11GeometrySDD::AliITSv11GeometrySDD():
511 fCoolPipeSupportL(0),
512 fCoolPipeSupportR(0),
515 fBaseThermalBridge(0),
532 fAddCoolingSyst(kTRUE),
534 fAddOnlyLadder3min(-1),
535 fAddOnlyLadder3max(-1),
536 fAddOnlyLadder4min(-1),
537 fAddOnlyLadder4max(-1),
538 fColorCarbonFiber(4),
548 fLay3LadderUnderSegDH(0),
549 fLay4LadderUnderSegDH(0),
550 fLay3LaddShortRadius(0),
551 fLay3LaddLongRadius(0),
552 fLay4LaddShortRadius(0),
553 fLay4LaddLongRadius(0)
556 // Standard constructor
558 fCommonVol[0] = NULL;
559 fCommonVol[1] = NULL;
562 for (Int_t i=0; i<fgkNladdSegCommonVol; i++){
563 fLaddSegCommonVol[i] = NULL;
564 fLaddSegCommonTr[i] = NULL;
570 //________________________________________________________________________
571 AliITSv11GeometrySDD::AliITSv11GeometrySDD(Int_t debug) :
572 AliITSv11Geometry(debug),
574 fCoolPipeSupportL(0),
575 fCoolPipeSupportR(0),
578 fBaseThermalBridge(0),
595 fAddCoolingSyst(kTRUE),
597 fAddOnlyLadder3min(-1),
598 fAddOnlyLadder3max(-1),
599 fAddOnlyLadder4min(-1),
600 fAddOnlyLadder4max(-1),
601 fColorCarbonFiber(4),
611 fLay3LadderUnderSegDH(0),
612 fLay4LadderUnderSegDH(0),
613 fLay3LaddShortRadius(0),
614 fLay3LaddLongRadius(0),
615 fLay4LaddShortRadius(0),
616 fLay4LaddLongRadius(0)
619 // Constructor setting debugging level
621 fCommonVol[0] = NULL;
622 fCommonVol[1] = NULL;
625 for (Int_t i=0; i<fgkNladdSegCommonVol; i++){
626 fLaddSegCommonVol[i] = NULL;
627 fLaddSegCommonTr[i] = NULL;
632 //________________________________________________________________________
633 AliITSv11GeometrySDD::AliITSv11GeometrySDD(const AliITSv11GeometrySDD &s) :
634 AliITSv11Geometry(s.GetDebug()),
635 fPinSupport(s.fPinSupport),
636 fCoolPipeSupportL(s.fCoolPipeSupportL),
637 fCoolPipeSupportR(s.fCoolPipeSupportR),
638 fSDDsensor3(s.fSDDsensor3),
639 fSDDsensor4(s.fSDDsensor4),
640 fBaseThermalBridge(s.fBaseThermalBridge),
642 fLadderFoot(s.fLadderFoot),
643 fCardLVR(s.fCardLVR),
644 fCardLVL(s.fCardLVL),
646 fCardCarlos(s.fCardCarlos),
647 fRaccordoL(s.fRaccordoL),
648 fDigitCableLay3A(s.fDigitCableLay3A),
649 fDigitCableLay3B(s.fDigitCableLay3B),
650 fDigitCableLay4A(s.fDigitCableLay4A),
651 fDigitCableLay4B(s.fDigitCableLay4B),
652 fMotherVol(s.fMotherVol),
653 fAddHybrids(s.fAddHybrids),
654 fAddSensors(s.fAddSensors),
655 fAddHVcables(s.fAddHVcables),
656 fAddCables(s.fAddCables),
657 fAddCoolingSyst(s.fAddCoolingSyst),
658 fCoolingOn(s.fCoolingOn),
659 fAddOnlyLadder3min(s.fAddOnlyLadder3min),
660 fAddOnlyLadder3max(s.fAddOnlyLadder3max),
661 fAddOnlyLadder4min(s.fAddOnlyLadder4min),
662 fAddOnlyLadder4max(s.fAddOnlyLadder4max),
663 fColorCarbonFiber(s.fColorCarbonFiber),
664 fColorRyton(s.fColorRyton),
665 fColorPhynox(s.fColorPhynox),
666 fColorSilicon(s.fColorSilicon),
667 fColorAl(s.fColorAl),
668 fColorPolyhamide(s.fColorPolyhamide),
669 fColorGlass(s.fColorGlass),
670 fColorSMD(s.fColorSMD),
671 fColorSMDweld(s.fColorSMDweld),
672 fColorStesalite(s.fColorStesalite),
673 fLay3LadderUnderSegDH(s.fLay3LadderUnderSegDH),
674 fLay4LadderUnderSegDH(s.fLay4LadderUnderSegDH),
675 fLay3LaddShortRadius(s.fLay3LaddShortRadius),
676 fLay3LaddLongRadius(s.fLay3LaddLongRadius),
677 fLay4LaddShortRadius(s.fLay4LaddShortRadius),
678 fLay4LaddLongRadius(s.fLay4LaddLongRadius)
681 // do only a "shallow copy" ...
682 fCommonVol[0] = s.fCommonVol[0];
683 fCommonVol[1] = s.fCommonVol[1];
684 fCommonTr[0] = s.fCommonTr[0];
685 fCommonTr[1] = s.fCommonTr[1];
686 for (Int_t i=0; i<fgkNladdSegCommonVol; i++){
687 fLaddSegCommonVol[i] = s.fLaddSegCommonVol[i];
688 fLaddSegCommonTr[i] = s.fLaddSegCommonTr[i];
693 //________________________________________________________________________
694 AliITSv11GeometrySDD& AliITSv11GeometrySDD::
695 operator=(const AliITSv11GeometrySDD &s) {
696 // Assignment operator
697 if(&s == this) return *this;
698 fMotherVol = s.fMotherVol;
699 fAddHybrids = s.fAddHybrids;
700 fAddSensors = s.fAddSensors;
701 fAddHVcables = s.fAddHVcables;
702 fAddCables = s.fAddCables;
703 fAddCoolingSyst = s.fAddCoolingSyst;
704 fCoolingOn = s.fCoolingOn;
705 fAddOnlyLadder3min = s.fAddOnlyLadder3min;
706 fAddOnlyLadder3max = s.fAddOnlyLadder3max;
707 fAddOnlyLadder4min = s.fAddOnlyLadder4min;
708 fAddOnlyLadder4max = s.fAddOnlyLadder4max;
712 //________________________________________________________________________
713 AliITSv11GeometrySDD::~AliITSv11GeometrySDD() {
714 // Look like a destructor
715 // Smell like a destructor
716 // And actually is the destructor
717 if (fDigitCableLay3A) delete [] fDigitCableLay3A;
718 if (fDigitCableLay3B) delete [] fDigitCableLay3B;
719 if (fDigitCableLay4A) delete [] fDigitCableLay4A;
720 if (fDigitCableLay4B) delete [] fDigitCableLay4B;
723 //________________________________________________________________________
724 void AliITSv11GeometrySDD::SetParameters() {
726 // Define display colors and the non constant geometry parameters
729 Double_t detLadderDist = 8.4*fgkmm;
731 fLay3LadderUnderSegDH = detLadderDist - (fgkWaHVcableAlThick+fgkWaHVcablePolyThick);
732 fLay4LadderUnderSegDH = detLadderDist - (fgkWaHVcableAlThick+fgkWaHVcablePolyThick);
734 // radius from the center to the CF ladder :
735 fLay3LaddShortRadius = (fgkLay3DetShortRadius
736 + fgkLadWaferSep+2*fgkWaferThickness
738 fLay3LaddLongRadius = (fgkLay3DetLongRadius
739 + fgkLadWaferSep+2*fgkWaferThickness
741 fLay4LaddShortRadius = (fgkLay4DetShortRadius
742 + fgkLadWaferSep+2*fgkWaferThickness
744 fLay4LaddLongRadius = (fgkLay4DetLongRadius
745 + fgkLadWaferSep+2*fgkWaferThickness
748 fLay3sensorZPos[0]= ( 35.8+72.4+75.8 )*fgkmm;
749 fLay3sensorZPos[1]= ( 35.8+72.4 )*fgkmm;
750 fLay3sensorZPos[2]= ( 35.8 )*fgkmm;
751 fLay3sensorZPos[3]= ( -37.9 )*fgkmm;
752 fLay3sensorZPos[4]= ( -37.9-74.9 )*fgkmm;
753 fLay3sensorZPos[5]= ( -37.9-74.9-71.1 )*fgkmm;
755 fLay4sensorZPos[0] = ( 38.5+73.2+75.4+71.6 )*fgkmm;
756 fLay4sensorZPos[1] = ( 38.5+73.2+75.4 )*fgkmm;
757 fLay4sensorZPos[2] = ( 38.5+73.2 )*fgkmm;
758 fLay4sensorZPos[3] = ( 38.5 )*fgkmm;
759 fLay4sensorZPos[4] = ( -35.6 )*fgkmm;
760 fLay4sensorZPos[5] = ( -35.6-74.8 )*fgkmm;
761 fLay4sensorZPos[6] = ( -35.6-74.8-72.4 )*fgkmm;
762 fLay4sensorZPos[7] = ( -35.6-74.8-72.4-76. )*fgkmm;
766 //________________________________________________________________________
767 TGeoMedium* AliITSv11GeometrySDD::GetMedium(const char* mediumName) {
769 // Called to get a medium, checks that it exists.
770 // If not, prints an error and returns 0
774 snprintf(ch, 30, "ITS_%s",mediumName);
775 TGeoMedium* medium = gGeoManager->GetMedium(ch);
777 printf("Error(AliITSv11GeometrySDD)::medium %s not found !\n", mediumName);
782 //________________________________________________________________________
783 Int_t AliITSv11GeometrySDD::GetLay3NLadders() const{
784 // Get the actual number of ladder in layer 3
785 if ( (fAddOnlyLadder3min<0) ||
786 (fAddOnlyLadder3min >= fgkLay3Nladd) ||
787 (fAddOnlyLadder3max<0) ||
788 (fAddOnlyLadder3max >= fgkLay3Nladd) )
790 else return (fAddOnlyLadder3max-fAddOnlyLadder3min+1);
794 //________________________________________________________________________
795 Int_t AliITSv11GeometrySDD::GetLay4NLadders() const{
796 // Get the actual number of ladder in layer 4
797 if ( (fAddOnlyLadder4min<0) ||
798 (fAddOnlyLadder4min >= fgkLay4Nladd) ||
799 (fAddOnlyLadder4max<0) ||
800 (fAddOnlyLadder4max >= fgkLay4Nladd) )
802 else return (fAddOnlyLadder4max-fAddOnlyLadder4min+1);
806 //________________________________________________________________________
807 void AliITSv11GeometrySDD::CreateBasicObjects() {
809 // Create basics objets which will be assembled together
810 // in Layer3 and Layer4 functions
814 fDigitCableLay3A = new AliITSv11GeomCableFlat[fgkLay3Ndet];
815 fDigitCableLay3B = new AliITSv11GeomCableFlat[fgkLay3Ndet];
816 fDigitCableLay4A = new AliITSv11GeomCableFlat[fgkLay4Ndet];
817 fDigitCableLay4B = new AliITSv11GeomCableFlat[fgkLay4Ndet];
819 fPinSupport = CreatePinSupport();
820 fCoolPipeSupportL = CreateCoolPipeSupportL();
821 fCoolPipeSupportR = CreateCoolPipeSupportR();
823 fBaseThermalBridge = CreateBaseThermalBridge();
824 fHybrid = CreateHybrid(0);
826 TGeoMedium *carbonFiberLadderStruct = GetMedium("SDD C AL (M55J)$"); //ITSsddCarbonM55J
827 TGeoMedium *polyhamideSDD = GetMedium("SDDKAPTON (POLYCH2)$");//ITSsddKAPTON_POLYCH2
828 TGeoMedium *alSDD = GetMedium("AL$"); //ITSal
829 TGeoMedium *stainless = GetMedium("AISI304L$"); // for screws
830 TGeoMedium *coolerMediumSDD = GetMedium("WATER$");
831 TGeoMedium *raccordMedium = GetMedium("INOX$"); // same as AISI 316-L
833 //********************************************************************
834 // pieces of the carbon fiber structure
835 //********************************************************************
836 Double_t dy = fgkLadderSegBoxDH/2;
837 Double_t triangleHeight = fgkLadderHeight - fgkLadderBeamRadius;
838 Double_t halfTheta = TMath::ATan( 0.5*fgkLadderWidth/triangleHeight );
839 Double_t alpha = TMath::Pi()*3./4. - halfTheta/2.;
840 Double_t beta = (TMath::Pi() - 2.*halfTheta)/4.;
841 Double_t dYTranslation = (fgkLadderHeight/2.
842 -0.5*fgkLadderWidth*TMath::Tan(beta)
843 -fgkLadderBeamRadius);
844 Double_t distCenterSideDown = 0.5*fgkLadderWidth/TMath::Cos(beta);
846 //--- the top V of the Carbon Fiber Ladder (segment)
847 TGeoArb8 *cfLaddTop1 = CreateLadderSide( "CFladdTopCornerVol1shape",
848 fgkSegmentLength/2., halfTheta,
849 -1, fgkLadderLa, fgkLadderHa, fgkLadderl);
850 TGeoVolume *cfLaddTopVol1 = new TGeoVolume("ITSsddCFladdTopCornerVol1",
851 cfLaddTop1,carbonFiberLadderStruct);
852 TGeoArb8 *cfLaddTop2 = CreateLadderSide( "CFladdTopCornerVol2shape",
853 fgkSegmentLength/2., halfTheta,
854 1, fgkLadderLa, fgkLadderHa, fgkLadderl);
855 TGeoVolume *cfLaddTopVol2 = new TGeoVolume("ITSsddCFladdTopCornerVol2",
856 cfLaddTop2, carbonFiberLadderStruct);
857 cfLaddTopVol1->SetLineColor(fColorCarbonFiber);
858 cfLaddTopVol2->SetLineColor(fColorCarbonFiber);
859 TGeoTranslation *trTop1 = new TGeoTranslation(0, fgkLadderHeight/2-dy, 0);
862 TGeoArb8 *cfLaddSide1 = CreateLadderSide( "CFladdSideCornerVol1shape",
863 fgkSegmentLength/2., beta, -1,
864 fgkLadderLb, fgkLadderHb, fgkLadderl);
865 TGeoVolume *cfLaddSideVol1 = new TGeoVolume( "ITSsddCFladdSideCornerVol1",
866 cfLaddSide1,carbonFiberLadderStruct);
867 TGeoArb8 *cfLaddSide2 = CreateLadderSide( "CFladdSideCornerVol2shape",
868 fgkSegmentLength/2., beta, 1,
869 fgkLadderLb, fgkLadderHb, fgkLadderl);
870 TGeoVolume *cfLaddSideVol2 = new TGeoVolume( "ITSsddCFladdSideCornerVol2",
871 cfLaddSide2,carbonFiberLadderStruct);
872 cfLaddSideVol1->SetLineColor(fColorCarbonFiber);
873 cfLaddSideVol2->SetLineColor(fColorCarbonFiber);
874 TGeoCombiTrans *ctSideR = CreateCombiTrans("", distCenterSideDown, 0,
875 alpha*TMath::RadToDeg());
876 AddTranslationToCombiTrans(ctSideR, 0, -dYTranslation-dy, 0);
877 TGeoCombiTrans *ctSideL = CreateCombiTrans("", distCenterSideDown,0,
878 -alpha*TMath::RadToDeg());
879 AddTranslationToCombiTrans(ctSideL, 0, -dYTranslation-dy, 0);
882 // Beams on the sides
883 Double_t beamPhiPrime = TMath::ASin(1./TMath::Sqrt( (1+TMath::Sin(2*beta)*
884 TMath::Sin(2*beta)/(TanD(fgkBeamSidePhi)*TanD(fgkBeamSidePhi))) ));
885 //cout<<"Phi prime = "<<beamPhiPrime*TMath::RadToDeg()<<endl;
886 Double_t beamLength = TMath::Sqrt( fgkLadderHeight*fgkLadderHeight/
887 ( TMath::Sin(beamPhiPrime)*TMath::Sin(beamPhiPrime))
888 + fgkLadderWidth*fgkLadderWidth/4.)-fgkLadderLa/2-fgkLadderLb/2;
889 TGeoTubeSeg *sideBeamS = new TGeoTubeSeg(0, fgkLadderBeamRadius,beamLength/2.,
891 TGeoVolume *sideBeam = new TGeoVolume("ITSsddCFSideBeamVol", sideBeamS,
892 carbonFiberLadderStruct);
893 sideBeam->SetLineColor(fColorCarbonFiber);
895 //Euler rotation : about Z, then new X, then new Z
896 TGeoRotation *beamRot1 = new TGeoRotation("", 90-2.*beta*TMath::RadToDeg(),
897 -beamPhiPrime*TMath::RadToDeg(),-90);
898 TGeoRotation *beamRot2 = new TGeoRotation("", 90-2.*beta*TMath::RadToDeg(),
899 beamPhiPrime*TMath::RadToDeg(), -90);
900 TGeoRotation *beamRot3 = new TGeoRotation("", 90+2.*beta*TMath::RadToDeg(),
901 beamPhiPrime*TMath::RadToDeg(), -90);
902 TGeoRotation *beamRot4 = new TGeoRotation("", 90+2.*beta*TMath::RadToDeg(),
903 -beamPhiPrime*TMath::RadToDeg(),-90);
905 TGeoCombiTrans *beamTransf[8];
906 beamTransf[0] = new TGeoCombiTrans( 0.5*triangleHeight*
907 TMath::Tan(halfTheta),
908 fgkLadderBeamRadius/2. - dy,
909 -3*fgkSegmentLength/8, beamRot1);
911 beamTransf[1] = new TGeoCombiTrans( 0.5*triangleHeight*
912 TMath::Tan(halfTheta),
913 fgkLadderBeamRadius/2. - dy,
914 -3*fgkSegmentLength/8, beamRot1);
915 AddTranslationToCombiTrans(beamTransf[1], 0, 0, fgkSegmentLength/2);
917 beamTransf[2] = new TGeoCombiTrans(0.5*triangleHeight*
918 TMath::Tan(halfTheta),
919 fgkLadderBeamRadius/2. - dy,
920 -fgkSegmentLength/8, beamRot2);
922 beamTransf[3] = new TGeoCombiTrans(0.5*triangleHeight*
923 TMath::Tan(halfTheta),
924 fgkLadderBeamRadius/2. - dy,
925 -fgkSegmentLength/8, beamRot2);
926 AddTranslationToCombiTrans(beamTransf[3], 0, 0, fgkSegmentLength/2);
928 beamTransf[4] = new TGeoCombiTrans(-0.5*triangleHeight*
929 TMath::Tan(halfTheta),
930 fgkLadderBeamRadius/2. - dy,
931 -3*fgkSegmentLength/8, beamRot3);
933 beamTransf[5] = new TGeoCombiTrans(-0.5*triangleHeight*
934 TMath::Tan(halfTheta),
935 fgkLadderBeamRadius/2. - dy,
936 -3*fgkSegmentLength/8, beamRot3);
937 AddTranslationToCombiTrans(beamTransf[5], 0, 0, fgkSegmentLength/2);
939 beamTransf[6] = new TGeoCombiTrans(-0.5*triangleHeight*
940 TMath::Tan(halfTheta),fgkLadderBeamRadius/2.-dy, -fgkSegmentLength/8,beamRot4);
941 beamTransf[7] = new TGeoCombiTrans(-0.5*triangleHeight*
942 TMath::Tan(halfTheta),fgkLadderBeamRadius/2.-dy,3*fgkSegmentLength/8,beamRot4);
944 //--- Beams of the bottom
945 TGeoTubeSeg *bottomBeam1 = new TGeoTubeSeg(0, fgkLadderBeamRadius,
946 fgkLadderWidth/2.-fgkLadderLb/3, 0, 180);
947 TGeoVolume *bottomBeam1Vol = new TGeoVolume("ITSsddBottomBeam1Vol",
948 bottomBeam1, carbonFiberLadderStruct);
949 bottomBeam1Vol->SetLineColor(fColorCarbonFiber);
950 TGeoTubeSeg *bottomBeam2 = new TGeoTubeSeg(0, fgkLadderBeamRadius,
951 fgkLadderWidth/2.-fgkLadderLb/3, 0, 90);
952 TGeoVolume *bottomBeam2Vol = new TGeoVolume("ITSsddBottomBeam2Vol",
953 bottomBeam2, carbonFiberLadderStruct);
954 bottomBeam2Vol->SetLineColor(fColorCarbonFiber);
955 TGeoTubeSeg *bottomBeam3 = new TGeoTubeSeg(0, fgkLadderBeamRadius,
956 0.5*fgkLadderWidth/SinD(fgkBottomBeamAngle)
957 - fgkLadderLb/3, 0, 180);
958 TGeoVolume *bottomBeam3Vol = new TGeoVolume("ITSsddBottomBeam3Vol",
959 bottomBeam3, carbonFiberLadderStruct);
960 bottomBeam3Vol->SetLineColor(fColorCarbonFiber);
961 //bottomBeam3Vol->SetLineColor(2);
962 TGeoRotation *bottomBeamRot1 = new TGeoRotation("", 90, 90, 90);
963 TGeoRotation *bottomBeamRot2 = new TGeoRotation("",-90, 90, -90);
965 TGeoCombiTrans *bottomBeamTransf1 = new TGeoCombiTrans
966 (0,-(fgkLadderHeight/2-fgkLadderBeamRadius)-dy,0, bottomBeamRot1);
967 TGeoCombiTrans *bottomBeamTransf2 = new TGeoCombiTrans(0,
968 -(fgkLadderHeight/2-fgkLadderBeamRadius)-dy,
969 -fgkSegmentLength/2, bottomBeamRot1);
970 TGeoCombiTrans *bottomBeamTransf3 = new TGeoCombiTrans(0,
971 -(fgkLadderHeight/2 - fgkLadderBeamRadius)
972 - dy, fgkSegmentLength/2, bottomBeamRot2);
973 // be careful for beams #3: when "reading" from -z to +z and
974 // from the bottom of the ladder, it should draw a Lambda, and not a V
975 TGeoRotation *bottomBeamRot4 = new TGeoRotation("", -90, fgkBottomBeamAngle, -90);
976 TGeoRotation *bottomBeamRot5 = new TGeoRotation("" ,-90,-fgkBottomBeamAngle, -90);
977 TGeoCombiTrans *bottomBeamTransf4 = new TGeoCombiTrans
978 (0,-(fgkLadderHeight/2-fgkLadderBeamRadius)-dy,-fgkSegmentLength/4,bottomBeamRot4);
979 TGeoCombiTrans *bottomBeamTransf5 = new TGeoCombiTrans
980 (0,-(fgkLadderHeight/2-fgkLadderBeamRadius)-dy,fgkSegmentLength/4, bottomBeamRot5);
982 fLaddSegCommonVol[0] = cfLaddTopVol1; fLaddSegCommonTr[0] = trTop1;
983 fLaddSegCommonVol[1] = cfLaddTopVol2; fLaddSegCommonTr[1] = trTop1;
984 fLaddSegCommonVol[2] = cfLaddSideVol1; fLaddSegCommonTr[2] = ctSideR;
985 fLaddSegCommonVol[3] = cfLaddSideVol1; fLaddSegCommonTr[3] = ctSideL;
986 fLaddSegCommonVol[4] = cfLaddSideVol2; fLaddSegCommonTr[4] = ctSideR;
987 fLaddSegCommonVol[5] = cfLaddSideVol2; fLaddSegCommonTr[5] = ctSideL;
988 fLaddSegCommonVol[6] = sideBeam; fLaddSegCommonTr[6] = beamTransf[0];
989 fLaddSegCommonVol[7] = sideBeam; fLaddSegCommonTr[7] = beamTransf[1];
990 fLaddSegCommonVol[8] = sideBeam; fLaddSegCommonTr[8] = beamTransf[2];
991 fLaddSegCommonVol[9] = sideBeam; fLaddSegCommonTr[9] = beamTransf[3];
992 fLaddSegCommonVol[10]= sideBeam; fLaddSegCommonTr[10]= beamTransf[4];
993 fLaddSegCommonVol[11]= sideBeam; fLaddSegCommonTr[11]= beamTransf[5];
994 fLaddSegCommonVol[12]= sideBeam; fLaddSegCommonTr[12]= beamTransf[6];
995 fLaddSegCommonVol[13]= sideBeam; fLaddSegCommonTr[13]= beamTransf[7];
996 fLaddSegCommonVol[14]= bottomBeam1Vol; fLaddSegCommonTr[14]= bottomBeamTransf1;
997 fLaddSegCommonVol[15]= bottomBeam2Vol; fLaddSegCommonTr[15]= bottomBeamTransf2;
998 fLaddSegCommonVol[16]= bottomBeam2Vol; fLaddSegCommonTr[16]= bottomBeamTransf3;
999 fLaddSegCommonVol[17]= bottomBeam3Vol; fLaddSegCommonTr[17]= bottomBeamTransf4;
1000 fLaddSegCommonVol[18]= bottomBeam3Vol; fLaddSegCommonTr[18]= bottomBeamTransf5;
1003 //********************************************************************
1005 //********************************************************************
1007 for (Int_t i=0; i<fgkLay3Ndet; i++) {
1008 snprintf(cableName, 30, "digitCableLay3A_%i",i);
1009 fDigitCableLay3A[i].SetName(cableName);
1010 fDigitCableLay3A[i].SetWidth(fgkDigitCablWidth);
1011 fDigitCableLay3A[i].SetThickness(fgkDigitCablPolyThick+fgkDigitCablAlThick);
1012 fDigitCableLay3A[i].SetNLayers(2);
1013 fDigitCableLay3A[i].SetLayer( 0, fgkDigitCablPolyThick, polyhamideSDD,
1015 fDigitCableLay3A[i].SetLayer(1, fgkDigitCablAlThick, alSDD, fColorAl);
1016 snprintf(cableName, 30, "digitCableLay3B_%i",i);
1017 fDigitCableLay3B[i].SetName(cableName);
1018 fDigitCableLay3B[i].SetWidth(fgkDigitCablWidth);
1019 fDigitCableLay3B[i].SetThickness(fgkDigitCablPolyThick+fgkDigitCablAlThick);
1020 fDigitCableLay3B[i].SetNLayers(2);
1021 fDigitCableLay3B[i].SetLayer( 0, fgkDigitCablPolyThick, polyhamideSDD,
1023 fDigitCableLay3B[i].SetLayer(1, fgkDigitCablAlThick, alSDD, fColorAl);
1025 for (Int_t i=0; i<fgkLay4Ndet; i++) {
1026 snprintf(cableName, 30, "digitCableLay4A_%i",i);
1027 fDigitCableLay4A[i].SetName(cableName);
1028 fDigitCableLay4A[i].SetWidth(fgkDigitCablWidth);
1029 fDigitCableLay4A[i].SetThickness(fgkDigitCablPolyThick+fgkDigitCablAlThick);
1030 fDigitCableLay4A[i].SetNLayers(2);
1031 fDigitCableLay4A[i].SetLayer( 0, fgkDigitCablPolyThick, polyhamideSDD,
1033 fDigitCableLay4A[i].SetLayer(1, fgkDigitCablAlThick, alSDD, fColorAl);
1034 snprintf(cableName, 30, "digitCableLay4B_%i",i);
1035 fDigitCableLay4B[i].SetName(cableName);
1036 fDigitCableLay4B[i].SetWidth(fgkDigitCablWidth);
1037 fDigitCableLay4B[i].SetThickness(fgkDigitCablPolyThick+fgkDigitCablAlThick);
1038 fDigitCableLay4B[i].SetNLayers(2);
1039 fDigitCableLay4B[i].SetLayer( 0, fgkDigitCablPolyThick, polyhamideSDD,
1041 fDigitCableLay4B[i].SetLayer(1, fgkDigitCablAlThick, alSDD, fColorAl);
1043 // Well, those digit cables could also include the analog cables
1044 // which have the same width and the same path, at least in the ladder.
1045 // It will gain some computing ressources (less volumes) and some
1046 // coding efforts ... !!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!
1047 // The only thing to do is to change the names and put the correct total
1050 // some transformations and volumes used in several places
1051 fCommonTr[0] = new TGeoRotation("CarlosSuppRotN",
1052 0, -fgkCarlosSuppAngle, 0);
1054 TGeoTube *littleScrewHead = new TGeoTube("littleScrewHead", 0, fgkLittleScrewHeadR,
1055 fgkLittleScrewHeadH/2);
1056 fCommonVol[0] = new TGeoVolume("vLittleScrewHead",
1057 littleScrewHead, stainless);
1058 fCommonVol[0]->SetLineColor(kGray);
1060 fLadderFoot = CreateLadderFoot();
1062 fCardHV = CreateHVCard();
1063 fCardCarlos = CreateCarlosCard(0);
1065 //==================
1066 // link beteen phynox and plastic cooling tubes
1067 //==================
1069 fRaccordoL = new TGeoVolumeAssembly("RaccordoL");
1070 Double_t fullRacLen = fgkConnectorCoolTubeL1+fgkConnectorCoolTubeL2+fgkConnectorCoolTubeL3;
1071 TGeoTube *waterRac = new TGeoTube("waterRac", 0, fgkConnectorCoolTubeRmin, fullRacLen/2);
1072 TGeoVolume * vwaterRac = new TGeoVolume("vwaterRac", waterRac, coolerMediumSDD);
1073 vwaterRac->SetLineColor(kBlue);
1075 TGeoTube *tube1Rac = new TGeoTube("tube1Rac", fgkConnectorCoolTubeRmin,
1076 fgkConnectorCoolTubeR1, fgkConnectorCoolTubeL1/2);
1077 TGeoTube *tube2Rac = new TGeoTube("tube2Rac", fgkConnectorCoolTubeRmin,
1078 fgkConnectorCoolTubeR2, fgkConnectorCoolTubeL2/2);
1079 TGeoTube *tube3Rac = new TGeoTube("tube3Rac", fgkConnectorCoolTubeRmin,
1080 fgkConnectorCoolTubeR3, fgkConnectorCoolTubeL3/2);
1081 TGeoVolume * vtube1Rac = new TGeoVolume("vtube1Rac", tube1Rac, raccordMedium);
1082 TGeoVolume * vtube2Rac = new TGeoVolume("vtube2Rac", tube2Rac, raccordMedium);
1083 TGeoVolume * vtube3Rac = new TGeoVolume("vtube3Rac", tube3Rac, raccordMedium);
1084 vtube1Rac->SetLineColor(kGray);
1085 vtube2Rac->SetLineColor(kGray);
1086 vtube3Rac->SetLineColor(kGray);
1088 TGeoTranslation *trTube1Rac = new TGeoTranslation("trTube1Rac",0,0,
1089 -fullRacLen/2+fgkConnectorCoolTubeL1/2);
1090 TGeoTranslation *trTube2Rac = new TGeoTranslation("trTube2Rac",0,0,
1091 (-fullRacLen/2+fgkConnectorCoolTubeL1+fgkConnectorCoolTubeL2/2));
1092 TGeoTranslation *trTube3Rac = new TGeoTranslation("trTube3Rac",0,0,
1093 (-fullRacLen/2+fgkConnectorCoolTubeL1+
1094 fgkConnectorCoolTubeL2+fgkConnectorCoolTubeL3/2));
1095 fRaccordoL->AddNode(vwaterRac, 1,0);
1096 fRaccordoL->AddNode(vtube1Rac, 1,trTube1Rac);
1097 fRaccordoL->AddNode(vtube2Rac, 1,trTube2Rac);
1098 fRaccordoL->AddNode(vtube3Rac, 1,trTube3Rac);
1102 //________________________________________________________________________
1103 void AliITSv11GeometrySDD::CheckOverlaps(Double_t precision){
1105 // a debugging function for checking some possible overlaps
1107 if (fSDDsensor3) fSDDsensor3->CheckOverlaps(precision);
1108 if (fSDDsensor4) fSDDsensor4->CheckOverlaps(precision);
1109 if (fHybrid) fHybrid->CheckOverlaps(precision);
1113 //________________________________________________________________________
1114 TGeoCombiTrans *AliITSv11GeometrySDD::
1115 CreateCombiTrans(const char *name, Double_t dy, Double_t dz, Double_t dphi,
1118 // return the TGeoCombiTrans which make a translation in y and z
1119 // and a rotation in phi in the global coord system
1120 // If planeSym = true, the rotation places the object symetrically
1121 // (with respect to the transverse plane) to its position in the
1122 // case planeSym = false
1125 TGeoTranslation t1(dy*CosD(90.+dphi),dy*SinD(90.+dphi), dz);
1126 TGeoRotation r1("",0.,0.,dphi);
1127 TGeoRotation r2("",90, 180, -90-dphi);
1129 TGeoCombiTrans *combiTrans1 = new TGeoCombiTrans(name);
1130 combiTrans1->SetTranslation(t1);
1131 if (planeSym) combiTrans1->SetRotation(r1);
1132 else combiTrans1->SetRotation(r2);
1137 //________________________________________________________________________
1138 void AliITSv11GeometrySDD::AddTranslationToCombiTrans(TGeoCombiTrans* ct,
1142 // Add a dx,dy,dz translation to the initial TGeoCombiTrans
1143 const Double_t *vect = ct->GetTranslation();
1144 Double_t newVect[3] = {vect[0]+dx, vect[1]+dy, vect[2]+dz};
1145 ct->SetTranslation(newVect);
1149 //________________________________________________________________________
1150 void AliITSv11GeometrySDD::ShowOnePiece(TGeoVolume *moth) {
1151 // for code developpment and debugging purposes
1153 if (! fSDDsensor3) CreateBasicObjects();
1155 // moth->AddNode(fPinSupport, 1, 0);
1156 // moth->AddNode(fCoolPipeSupportL, 1, 0);
1157 // moth->AddNode(fSDDsensor3, 1, 0);
1158 // moth->AddNode(fSDDsensor4, 1, 0);
1159 // moth->AddNode(fBaseThermalBridge, 1, 0);
1160 // moth->AddNode(fHybrid,100,0);
1161 // moth->AddNode(fLadderFoot,1,0);
1162 //moth->AddNode(fCardLVL,1,0);
1163 //moth->AddNode(fCardLVR,1,0);
1165 TGeoVolume* seg = CreateLadderSegment( 3, 0);
1166 moth->AddNode(seg, 1, 0);
1168 // TGeoVolumeAssembly *lay3Ladder = CreateLadder(3);
1169 // moth->AddNode(lay3Ladder, 1, 0);
1171 // TGeoVolumeAssembly *lay3Detectors = CreateDetectorsAssembly(3);
1172 // moth->AddNode(lay3Detectors, 1, 0);
1174 // TGeoVolumeAssembly *lay3Detectors = CreateDetectorsAssembly(3);
1175 // moth->AddNode(lay3Detectors, 1, 0);
1178 // TGeoVolumeAssembly *endLadder = CreateEndLadder( 4 );
1179 // moth->AddNode(endLadder, 1, 0);
1181 // TGeoVolumeAssembly *highVCard = CreateHVCard( 4 );
1182 // moth->AddNode(highVCard, 1, 0);
1184 // TGeoVolumeAssembly *supportRing = CreateSupportRing();
1185 // moth->AddNode(supportRing, 1, 0);
1187 // TGeoVolume *endLadderCards = CreateEndLadderCardsV( 4 );
1188 // moth->AddNode(endLadderCards, 1, 0);
1190 // TGeoVolumeAssembly *carlosCard = CreateCarlosCard( 4 );
1191 // moth->AddNode(carlosCard, 1, 0);
1196 //==================================
1197 //--- test of flat cable curvature
1198 //==================================
1201 AliITSv11GeomCableFlat cable("test", 3, 0.3);
1202 cable.SetNLayers(1);
1203 cable.SetNLayers(2);
1204 cable.SetLayer(0, 0.2, coolerMediumSDD, 2);
1205 cable.SetLayer(1, 0.1, coolerMediumSDD, 3);
1206 cable.SetInitialNode(endLadderCards);
1208 Double_t p1[3], p2[3], vX[3] = {1,0,0},vY[3] = {0,5,0};
1217 cable.AddCheckPoint(endLadderCards, 0, p1, vX);
1218 cable.AddCheckPoint(endLadderCards, 1, p2, vX);
1219 cable.CreateAndInsertBoxCableSegment(1,angle);
1221 Double_t p3[3], p4[3];
1226 cable.AddCheckPoint(endLadderCards, 2, p3, vY);
1227 cable.CreateAndInsertCableCylSegment(2,angle);
1232 cable.AddCheckPoint(endLadderCards, 3, p4, vY);
1233 cable.CreateAndInsertCableSegment(3,angle);
1238 //________________________________________________________________________
1239 void AliITSv11GeometrySDD::Layer3(TGeoVolume *moth) {
1241 // Insert the layer 3 in the mother volume. This is a virtual volume
1242 // containing ladders of layer 3 and the supporting rings
1246 printf("Error::AliITSv11GeometrySDD: Can't insert layer3, mother is null!\n");
1250 TGeoMedium *airSDD = GetMedium("SDD AIR$");
1253 if (! fSDDsensor3) CreateBasicObjects();
1255 //====================================
1256 // First we create the central barrel
1257 //====================================
1259 TGeoVolumeAssembly *lay3Ladder = CreateLadder(3);
1260 TGeoVolumeAssembly *lay3Detectors = CreateDetectorsAssembly(3);
1261 TGeoVolumeAssembly *lay3Ladd2Det = CreateDetectorsAssemblyLadd2();
1262 //TGeoVolume *lay3Detectors = CreateDetectors(3);
1263 TGeoTube *virtualLayer3Shape = new TGeoTube("ITSsddLayer3Shape",
1264 fgkLay3Rmin,fgkLay3Rmax,fgkLay3Length*0.5);
1265 TGeoVolume *virtualLayer3 = new TGeoVolume("ITSsddLayer3",
1266 virtualLayer3Shape, airSDD);
1268 Double_t dPhi = 360./fgkLay3Nladd;
1269 Double_t detectorsThick = fgkLadWaferSep + 2*fgkWaferThickness;
1270 // Placing virtual ladder and detectors volumes following
1271 // ladder ordering convention
1274 Int_t iLaddMax = fgkLay3Nladd;
1275 if ((fAddOnlyLadder3min>=0)&&(fAddOnlyLadder3max<fgkLay3Nladd)) {
1276 iLaddMin = fAddOnlyLadder3min;
1277 iLaddMax = fAddOnlyLadder3max+1;
1280 for (Int_t iLadd = iLaddMin; iLadd < iLaddMax; iLadd++) {
1282 Double_t ladderPhi = -3*dPhi+iLadd*dPhi;
1283 snprintf(rotName, 30, "ITSsddLay3Ladd%i",iLadd);
1284 Double_t minRadiusLadBox = fLay3LaddShortRadius-fLay3LadderUnderSegDH;
1286 minRadiusLadBox = fLay3LaddLongRadius-fLay3LadderUnderSegDH;
1287 minRadiusLadBox += ((TGeoBBox*)lay3Ladder->GetShape())->GetDY();
1288 TGeoCombiTrans *ctLadd;
1289 //=============================================================
1291 // Special modification for ladder 2 of layer 3:
1292 // It has been inverted (pi rotation around y axis)
1294 //=============================================================
1296 ctLadd = CreateCombiTrans(rotName,minRadiusLadBox,
1297 0, ladderPhi, kTRUE);
1299 ctLadd = CreateCombiTrans(rotName,minRadiusLadBox,
1300 0, ladderPhi, kFALSE);
1301 virtualLayer3->AddNode(lay3Ladder, iLadd, ctLadd);
1302 ///////////////////////////////////////////////////
1303 snprintf(rotName, 30, "ITSsddLay3DetBox%i",iLadd);
1304 Double_t minRadiusDetBox = fgkLay3DetShortRadius;
1305 if (iLadd%2 != 0) minRadiusDetBox = fgkLay3DetLongRadius;
1306 minRadiusDetBox += detectorsThick/2;
1307 TGeoCombiTrans *ctDet;
1308 ctDet = CreateCombiTrans(rotName, minRadiusDetBox,
1309 0, ladderPhi, kTRUE);
1312 virtualLayer3->AddNode(lay3Detectors, iLadd, ctDet);
1314 virtualLayer3->AddNode(lay3Ladd2Det , iLadd, ctDet);
1316 ///////////////////////////////////////////////////
1320 //====================================
1321 // Then the forward rapidity pieces
1322 // (cooling, Carlos, LV, HV ...)
1323 //====================================
1325 Double_t fgkForwardLay3Length = fgkEndLadPipeUlengthLay3+10*fgkmm; // this has to be tune
1326 Double_t fgkForwardLay3Rmin = fgkLay3Rmin-7*fgkmm;
1327 Double_t fgkForwardLay3Rmax = fgkLay3Rmax-5*fgkmm;
1329 TGeoVolumeAssembly* lay3EndLadder = CreateEndLadderCards(3);
1330 TGeoTube *virtualForward3Shape = new TGeoTube("virtualForward3Shape",
1331 fgkForwardLay3Rmin, fgkForwardLay3Rmax,
1332 fgkForwardLay3Length/2.);
1334 // TGeoPcon *virtualForward3Shape = new TGeoPcon("virtualForward3Shape",0,360,2);
1335 // // virtualForward3Shape->DefineSection(Int_t snum, Double_t z, Double_t rmin, Double_t rmax);
1336 // virtualForward3Shape->DefineSection(0, Double_t z, Double_t rmin, Double_t rmax);
1339 TGeoVolume *virtualForward3Pos = new TGeoVolume("ITSsddForward3Pos",
1340 virtualForward3Shape, airSDD);
1341 TGeoVolume *virtualForward3Neg = new TGeoVolume("ITSsddForward3Neg",
1342 virtualForward3Shape, airSDD);
1343 // TGeoVolume *virtualForward3Neg = new TGeoVolumeAssembly("ITSsddForward3Neg");
1344 // TGeoVolume *virtualForward3Pos = new TGeoVolumeAssembly("ITSsddForward3Pos");
1346 TGeoTranslation *virtualForward3TrPos = new TGeoTranslation("virtualForward3TrPos",0,0,
1347 fgkLay3Length/2+fgkForwardLay3Length/2);
1348 TGeoTranslation *virtualForward3TrNeg = new TGeoTranslation("virtualForward3TrNeg",0,0,
1349 -fgkLay3Length/2-fgkForwardLay3Length/2);
1351 for (Int_t iLadd = iLaddMin; iLadd < iLaddMax; iLadd++) {
1353 Double_t ladderPhi = -3*dPhi+iLadd*dPhi;
1354 Double_t minRadiusDetBox = fgkLay3DetShortRadius;
1355 if (iLadd%2 != 0) minRadiusDetBox = fgkLay3DetLongRadius;
1356 minRadiusDetBox += detectorsThick/2;
1358 sprintf(rotName, "ITSsddLay3EndLadd%i",iLadd);
1360 TGeoCombiTrans *ctEndLaddPos = CreateCombiTrans(rotName, minRadiusDetBox-0.1,
1361 -fgkForwardLay3Length/2, ladderPhi, kTRUE);
1362 TGeoCombiTrans *ctEndLaddNeg = CreateCombiTrans(rotName, minRadiusDetBox-0.1,
1363 fgkForwardLay3Length/2, ladderPhi, kFALSE);
1365 virtualForward3Pos->AddNode(lay3EndLadder, iLadd*2, ctEndLaddPos);
1366 virtualForward3Neg->AddNode(lay3EndLadder, iLadd*2, ctEndLaddNeg);
1373 virtualLayer3->CheckOverlaps(0.01);
1374 //virtualForward3Pos->CheckOverlaps(0.01);
1375 //virtualForward3Neg->CheckOverlaps(0.01);
1378 virtualLayer3->SetVisibility(kFALSE);
1379 //virtualForward3Pos->SetVisibility(kFALSE);
1380 //virtualForward3Neg->SetVisibility(kFALSE);
1383 moth->AddNode(virtualLayer3, 1, 0);
1384 //moth->AddNode(virtualForward3Pos, 1, virtualForward3TrPos);
1385 //moth->AddNode(virtualForward3Neg, 1, virtualForward3TrNeg);
1389 // //________________________________________________________________________
1390 // void AliITSv11GeometrySDD::ForwardLayer3(TGeoVolume *moth) {
1392 // // Insert the forward pieces of layer 3 in the mother volume.
1393 // // (cooling, Carlos, LV, HV ...)
1397 // printf("Error::AliITSv11GeometrySDD: Can't insert layer3, mother is null!\n");
1401 // TGeoMedium *airSDD = GetMedium("SDD AIR$");
1403 // if (! fSDDsensor3) CreateBasicObjects();
1405 // Double_t dPhi = 360./fgkLay3Nladd;
1406 // Double_t detectorsThick = fgkLadWaferSep + 2*fgkWaferThickness;
1407 // Int_t iLaddMin = 0;
1408 // Int_t iLaddMax = fgkLay3Nladd;
1409 // if ((fAddOnlyLadder3min>=0)&&(fAddOnlyLadder3max<fgkLay3Nladd)) {
1410 // iLaddMin = fAddOnlyLadder3min;
1411 // iLaddMax = fAddOnlyLadder3max+1;
1413 // char rotName[30];
1416 // //=================
1418 // Double_t fgkForwardLay3Length = fgkEndLadPipeUlengthLay3+10*fgkmm; // this has to be tune
1419 // Double_t fgkForwardLay3Rmin = fgkLay3Rmin-7*fgkmm;
1420 // Double_t fgkForwardLay3Rmax = fgkLay3Rmax-5*fgkmm;
1422 // TGeoVolumeAssembly* lay3EndLadder = CreateEndLadderCards(3);
1423 // TGeoTube *virtualForward3Shape = new TGeoTube("virtualForward3Shape",
1424 // fgkForwardLay3Rmin, fgkForwardLay3Rmax,
1425 // fgkForwardLay3Length/2.);
1427 // // TGeoPcon *virtualForward3Shape = new TGeoPcon("virtualForward3Shape",0,360,2);
1428 // // // virtualForward3Shape->DefineSection(Int_t snum, Double_t z, Double_t rmin, Double_t rmax);
1429 // // virtualForward3Shape->DefineSection(0, Double_t z, Double_t rmin, Double_t rmax);
1432 // TGeoVolume *virtualForward3Pos = new TGeoVolume("ITSsddForward3Pos",
1433 // virtualForward3Shape, airSDD);
1434 // TGeoVolume *virtualForward3Neg = new TGeoVolume("ITSsddForward3Neg",
1435 // virtualForward3Shape, airSDD);
1436 // // TGeoVolume *virtualForward3Neg = new TGeoVolumeAssembly("ITSsddForward3Neg");
1437 // // TGeoVolume *virtualForward3Pos = new TGeoVolumeAssembly("ITSsddForward3Pos");
1439 // TGeoTranslation *virtualForward3TrPos = new TGeoTranslation("virtualForward3TrPos",0,0,
1440 // fgkLay3Length/2+fgkForwardLay3Length/2);
1441 // TGeoTranslation *virtualForward3TrNeg = new TGeoTranslation("virtualForward3TrNeg",0,0,
1442 // -fgkLay3Length/2-fgkForwardLay3Length/2);
1444 // for (Int_t iLadd = iLaddMin; iLadd < iLaddMax; iLadd++) {
1446 // Double_t ladderPhi = -3*dPhi+iLadd*dPhi;
1447 // Double_t minRadiusDetBox = fgkLay3DetShortRadius;
1448 // if (iLadd%2 != 0) minRadiusDetBox = fgkLay3DetLongRadius;
1449 // minRadiusDetBox += detectorsThick/2;
1451 // sprintf(rotName, "ITSsddLay3EndLadd%i",iLadd);
1453 // TGeoCombiTrans *ctEndLaddPos = CreateCombiTrans(rotName, minRadiusDetBox-0.1,
1454 // -fgkForwardLay3Length/2, ladderPhi, kTRUE);
1455 // TGeoCombiTrans *ctEndLaddNeg = CreateCombiTrans(rotName, minRadiusDetBox-0.1,
1456 // fgkForwardLay3Length/2, ladderPhi, kFALSE);
1458 // virtualForward3Pos->AddNode(lay3EndLadder, iLadd*2, ctEndLaddPos);
1459 // virtualForward3Neg->AddNode(lay3EndLadder, iLadd*2, ctEndLaddNeg);
1462 // if(GetDebug(1)) {
1463 // virtualForward3Pos->CheckOverlaps(0.01);
1464 // virtualForward3Neg->CheckOverlaps(0.01);
1467 // virtualForward3Pos->SetVisibility(kFALSE);
1468 // virtualForward3Neg->SetVisibility(kFALSE);
1470 // moth->AddNode(virtualForward3Pos, 1, virtualForward3TrPos);
1471 // moth->AddNode(virtualForward3Neg, 1, virtualForward3TrNeg);
1476 //________________________________________________________________________
1477 void AliITSv11GeometrySDD::ForwardLayer3(TGeoVolume *moth) {
1479 // Insert the end-ladder of layer 3 in the mother volume.
1480 // (cooling, Carlos, LV, HV ...)
1484 printf("Error::AliITSv11GeometrySDD: Can't insert layer3, mother is null!\n");
1488 if (! fSDDsensor3) CreateBasicObjects();
1491 Int_t iLaddMax = fgkLay3Nladd;
1492 if ((fAddOnlyLadder3min>=0)&&(fAddOnlyLadder3max<fgkLay3Nladd)) {
1493 iLaddMin = fAddOnlyLadder3min;
1494 iLaddMax = fAddOnlyLadder3max+1;
1497 TGeoVolume *virtualForward3Neg = new TGeoVolumeAssembly("ITSsddForward3Neg");
1498 TGeoVolume *virtualForward3Pos = new TGeoVolumeAssembly("ITSsddForward3Pos");
1501 Double_t dPhi = 360./fgkLay3Nladd;
1502 TGeoVolume* lay3EndLadder = CreateEndLadderCardsV(3);
1504 for (Int_t iLadd = iLaddMin; iLadd < iLaddMax; iLadd++) {
1506 Double_t ladderPhi = -3*dPhi+iLadd*dPhi;
1508 if (iLadd%2 != 0) dR = fgkLay3DetLongRadius-fgkLay3DetShortRadius;
1510 snprintf(rotName, 30, "ITSsddLay3EndLadd%i",iLadd);
1512 TGeoCombiTrans *ctEndLaddPos = CreateCombiTrans(rotName, dR,
1513 fgkLay3Length/2, ladderPhi, kTRUE);
1514 TGeoCombiTrans *ctEndLaddNeg = CreateCombiTrans(rotName, dR,
1515 -fgkLay3Length/2, ladderPhi, kFALSE);
1517 virtualForward3Pos->AddNode(lay3EndLadder, iLadd*2, ctEndLaddPos);
1518 virtualForward3Neg->AddNode(lay3EndLadder, iLadd*2, ctEndLaddNeg);
1522 virtualForward3Pos->CheckOverlaps(0.01);
1523 virtualForward3Neg->CheckOverlaps(0.01);
1526 // 180deg Y rotation to compensate the cancellation of ITSD volume
1527 // (idortm[199] in AliITSv11Hybrid : z---> -z; x ---> -x; y ---> y)
1528 TGeoRotation *y180 = new TGeoRotation();
1529 y180->SetAngles( 90.,180., 90., 90.,180., 0.);
1530 moth->AddNode(virtualForward3Pos, 1, y180);
1531 moth->AddNode(virtualForward3Neg, 1, y180);
1534 //________________________________________________________________________
1535 void AliITSv11GeometrySDD::Layer4(TGeoVolume *moth) {
1537 // Insert the layer 4 in the mother volume. This is a virtual volume
1538 // containing ladders of layer 4 and the supporting rings
1542 printf("Error::AliITSv11GeometrySDD: Can't insert layer4, mother is null!\n");
1548 if (! fSDDsensor3) CreateBasicObjects();
1550 TGeoTube *virtualLayer4Shape =new TGeoTube("ITSsddLayer4Shape",
1551 fgkLay4Rmin,fgkLay4Rmax,fgkLay4Length*0.5);
1552 TGeoMedium *airSDD = GetMedium("SDD AIR$");
1553 TGeoVolume *virtualLayer4 = new TGeoVolume("ITSsddLayer4",
1554 virtualLayer4Shape, airSDD);
1556 //====================================
1557 // First we create the central barrel
1558 //====================================
1560 TGeoVolumeAssembly *lay4Ladder = CreateLadder(4);
1561 //TGeoVolume *lay4Detectors = CreateDetectors(4);
1562 TGeoVolumeAssembly *lay4Detectors = CreateDetectorsAssembly(4);
1564 Double_t dPhi = 360./fgkLay4Nladd;
1565 Double_t detBoxThickness = fgkLadWaferSep + 2*fgkWaferThickness;
1567 // placing virtual ladder and detectors volumes following ladder
1568 // ordering convention
1571 Int_t iLaddMax = fgkLay4Nladd;
1572 if ((fAddOnlyLadder4min >= 0)&&(fAddOnlyLadder4max < fgkLay4Nladd)) {
1573 iLaddMin = fAddOnlyLadder4min;
1574 iLaddMax = fAddOnlyLadder4max+1;
1576 for (Int_t iLadd = iLaddMin; iLadd < iLaddMax; iLadd++) {
1578 Double_t ladderPhi = -5*dPhi + iLadd*dPhi;
1579 snprintf(rotName, 30, "ITSsddLay4Ladd%i",iLadd);
1580 Double_t minRadiusLadBox = fLay4LaddShortRadius-fLay4LadderUnderSegDH;
1582 minRadiusLadBox = fLay4LaddLongRadius-fLay4LadderUnderSegDH;
1583 minRadiusLadBox += ((TGeoBBox*)lay4Ladder->GetShape())->GetDY();
1584 TGeoCombiTrans *ctLadd = CreateCombiTrans(rotName, minRadiusLadBox,
1585 0, ladderPhi, kTRUE);
1586 virtualLayer4->AddNode(lay4Ladder, iLadd, ctLadd);
1587 ///////////////////////////////////////////////////
1588 snprintf(rotName, 30, "ITSsddLay4DetBox%i",iLadd);
1589 Double_t minRadiusDetBox = fgkLay4DetShortRadius;
1591 minRadiusDetBox = fgkLay4DetLongRadius;
1592 minRadiusDetBox += detBoxThickness/2;
1593 TGeoCombiTrans *ctDet = CreateCombiTrans(rotName, minRadiusDetBox,
1594 0, ladderPhi, kTRUE);
1595 virtualLayer4->AddNode(lay4Detectors, iLadd, ctDet);
1596 ///////////////////////////////////////////////////
1600 //====================================
1601 // Then the pieces at forward rapidity
1602 // (cooling, Carlos, LV, HV ...)
1603 //====================================
1605 Double_t fgkForwardLay4Length = fgkEndLadPipeUlengthLay4+10*fgkmm; // this has to be tuned
1606 Double_t fgkForwardLay4Rmin = fgkLay4Rmin-9*fgkmm;
1607 Double_t fgkForwardLay4Rmax = fgkLay4Rmax-5*fgkmm;
1609 TGeoVolumeAssembly* lay4EndLadder = CreateEndLadderCards(4);
1610 TGeoTube *virtualForward4Shape = new TGeoTube("virtualForward3Shape",
1611 fgkForwardLay4Rmin, fgkForwardLay4Rmax,
1612 fgkForwardLay4Length/2.);
1613 TGeoVolume *virtualForward4Pos = new TGeoVolume("ITSsddForward4Pos",
1614 virtualForward4Shape, airSDD);
1615 TGeoVolume *virtualForward4Neg = new TGeoVolume("ITSsddForward4Neg",
1616 virtualForward4Shape, airSDD);
1617 // TGeoVolume *virtualForward4Pos = new TGeoVolumeAssembly("ITSsddForward4Pos");
1618 // TGeoVolume *virtualForward4Neg = new TGeoVolumeAssembly("ITSsddForward4Neg");
1620 TGeoTranslation *virtualForward4TrPos = new TGeoTranslation("virtualForward4TrPos",0,0,
1621 fgkLay4Length/2+fgkForwardLay4Length/2);
1622 TGeoTranslation *virtualForward4TrNeg = new TGeoTranslation("virtualForward4TrNeg",0,0,
1623 -fgkLay4Length/2-fgkForwardLay4Length/2);
1625 for (Int_t iLadd = iLaddMin; iLadd < iLaddMax; iLadd++) {
1627 Double_t ladderPhi = -5*dPhi + iLadd*dPhi;
1628 Double_t minRadiusDetBox = fgkLay4DetShortRadius;
1630 minRadiusDetBox = fgkLay4DetLongRadius;
1631 minRadiusDetBox += detBoxThickness/2;
1633 sprintf(rotName, "ITSsddLay4EndLadd%i",iLadd);
1635 TGeoCombiTrans *ctEndLaddPos = CreateCombiTrans(rotName, minRadiusDetBox-0.1,
1636 -fgkForwardLay4Length/2, ladderPhi, kTRUE);
1637 TGeoCombiTrans *ctEndLaddNeg = CreateCombiTrans(rotName, minRadiusDetBox-0.1,
1638 fgkForwardLay4Length/2, ladderPhi, kFALSE);
1639 virtualForward4Pos->AddNode(lay4EndLadder, iLadd*2, ctEndLaddPos);
1640 virtualForward4Neg->AddNode(lay4EndLadder, iLadd*2+1, ctEndLaddNeg);
1644 if(GetDebug(1)) virtualLayer4->CheckOverlaps(0.01);
1646 virtualLayer4->SetVisibility(kFALSE);
1647 //virtualForward4Pos->SetVisibility(kFALSE);
1648 //virtualForward4Neg->SetVisibility(kFALSE);
1650 moth->AddNode(virtualLayer4,1,0);
1651 //moth->AddNode(virtualForward4Pos, 1, virtualForward4TrPos);
1652 //moth->AddNode(virtualForward4Neg, 1, virtualForward4TrNeg);
1656 // //________________________________________________________________________
1657 // void AliITSv11GeometrySDD::ForwardLayer4(TGeoVolume *moth) {
1659 // // Insert the layer 4 in the mother volume. This is a virtual volume
1660 // // containing ladders of layer 4 and the supporting rings
1661 // // (cooling, Carlos, LV, HV ...)
1665 // printf("Error::AliITSv11GeometrySDD: Can't insert layer4, mother is null!\n");
1669 // TGeoMedium *airSDD = GetMedium("SDD AIR$");
1671 // if (! fSDDsensor3) CreateBasicObjects();
1673 // Double_t dPhi = 360./fgkLay4Nladd;
1674 // Double_t detBoxThickness = fgkLadWaferSep + 2*fgkWaferThickness;
1676 // // placing virtual ladder and detectors volumes following ladder
1677 // // ordering convention
1678 // char rotName[20];
1679 // Int_t iLaddMin = 0;
1680 // Int_t iLaddMax = fgkLay4Nladd;
1681 // if ((fAddOnlyLadder4min >= 0)&&(fAddOnlyLadder4max < fgkLay4Nladd)) {
1682 // iLaddMin = fAddOnlyLadder4min;
1683 // iLaddMax = fAddOnlyLadder4max+1;
1686 // //=================
1687 // Double_t fgkForwardLay4Length = fgkEndLadPipeUlengthLay4+10*fgkmm; // this has to be tuned
1688 // Double_t fgkForwardLay4Rmin = fgkLay4Rmin-9*fgkmm;
1689 // Double_t fgkForwardLay4Rmax = fgkLay4Rmax-5*fgkmm;
1691 // TGeoVolumeAssembly* lay4EndLadder = CreateEndLadderCards(4);
1692 // TGeoTube *virtualForward4Shape = new TGeoTube("virtualForward3Shape",
1693 // fgkForwardLay4Rmin, fgkForwardLay4Rmax,
1694 // fgkForwardLay4Length/2.);
1695 // TGeoVolume *virtualForward4Pos = new TGeoVolume("ITSsddForward4Pos",
1696 // virtualForward4Shape, airSDD);
1697 // TGeoVolume *virtualForward4Neg = new TGeoVolume("ITSsddForward4Neg",
1698 // virtualForward4Shape, airSDD);
1699 // // TGeoVolume *virtualForward4Pos = new TGeoVolumeAssembly("ITSsddForward4Pos");
1700 // // TGeoVolume *virtualForward4Neg = new TGeoVolumeAssembly("ITSsddForward4Neg");
1702 // TGeoTranslation *virtualForward4TrPos = new TGeoTranslation("virtualForward4TrPos",0,0,
1703 // fgkLay4Length/2+fgkForwardLay4Length/2);
1704 // TGeoTranslation *virtualForward4TrNeg = new TGeoTranslation("virtualForward4TrNeg",0,0,
1705 // -fgkLay4Length/2-fgkForwardLay4Length/2);
1707 // for (Int_t iLadd = iLaddMin; iLadd < iLaddMax; iLadd++) {
1709 // Double_t ladderPhi = -5*dPhi + iLadd*dPhi;
1710 // Double_t minRadiusDetBox = fgkLay4DetShortRadius;
1711 // if (iLadd%2 != 0)
1712 // minRadiusDetBox = fgkLay4DetLongRadius;
1713 // minRadiusDetBox += detBoxThickness/2;
1715 // sprintf(rotName, "ITSsddLay4EndLadd%i",iLadd);
1717 // TGeoCombiTrans *ctEndLaddPos = CreateCombiTrans(rotName, minRadiusDetBox-0.1,
1718 // -fgkForwardLay4Length/2, ladderPhi, kTRUE);
1719 // TGeoCombiTrans *ctEndLaddNeg = CreateCombiTrans(rotName, minRadiusDetBox-0.1,
1720 // fgkForwardLay4Length/2, ladderPhi, kFALSE);
1721 // virtualForward4Pos->AddNode(lay4EndLadder, iLadd*2, ctEndLaddPos);
1722 // virtualForward4Neg->AddNode(lay4EndLadder, iLadd*2+1, ctEndLaddNeg);
1725 // virtualForward4Pos->SetVisibility(kFALSE);
1726 // virtualForward4Neg->SetVisibility(kFALSE);
1728 // moth->AddNode(virtualForward4Pos, 1, virtualForward4TrPos);
1729 // moth->AddNode(virtualForward4Neg, 1, virtualForward4TrNeg);
1733 //________________________________________________________________________
1734 void AliITSv11GeometrySDD::ForwardLayer4(TGeoVolume *moth) {
1736 // Insert the end-ladder of layer 4 in the mother volume.
1737 // (cooling, Carlos, LV, HV ...)
1741 printf("Error::AliITSv11GeometrySDD: Can't insert layer4, mother is null!\n");
1745 if (! fSDDsensor3) CreateBasicObjects();
1747 // placing virtual ladder and detectors volumes following ladder
1748 // ordering convention
1750 Int_t iLaddMax = fgkLay4Nladd;
1751 if ((fAddOnlyLadder4min >= 0)&&(fAddOnlyLadder4max < fgkLay4Nladd)) {
1752 iLaddMin = fAddOnlyLadder4min;
1753 iLaddMax = fAddOnlyLadder4max+1;
1756 TGeoVolume *virtualForward4Pos = new TGeoVolumeAssembly("ITSsddForward4Pos");
1757 TGeoVolume *virtualForward4Neg = new TGeoVolumeAssembly("ITSsddForward4Neg");
1760 Double_t dPhi = 360./fgkLay4Nladd;
1761 TGeoVolume* lay4EndLadder = CreateEndLadderCardsV(4);
1763 for (Int_t iLadd = iLaddMin; iLadd < iLaddMax; iLadd++) {
1765 Double_t ladderPhi = -5*dPhi + iLadd*dPhi;
1768 dR = fgkLay4DetLongRadius-fgkLay4DetShortRadius;
1770 snprintf(rotName, 30, "ITSsddLay4EndLadd%i",iLadd);
1772 TGeoCombiTrans *ctEndLaddPos = CreateCombiTrans(rotName, dR,
1773 fgkLay4Length/2, ladderPhi, kTRUE);
1774 TGeoCombiTrans *ctEndLaddNeg = CreateCombiTrans(rotName, dR,
1775 -fgkLay4Length/2, ladderPhi, kFALSE);
1776 virtualForward4Pos->AddNode(lay4EndLadder, iLadd*2, ctEndLaddPos);
1777 virtualForward4Neg->AddNode(lay4EndLadder, iLadd*2, ctEndLaddNeg);
1780 // 180deg Y rotation to compensate the cancellation of ITSD volume
1781 // (idortm[199] in AliITSv11Hybrid : z---> -z; x ---> -x; y ---> y)
1782 TGeoRotation *y180 = new TGeoRotation();
1783 y180->SetAngles( 90.,180., 90., 90.,180., 0.);
1784 moth->AddNode(virtualForward4Pos, 1, y180);
1785 moth->AddNode(virtualForward4Neg, 1, y180);
1789 //________________________________________________________________________
1790 TGeoVolumeAssembly *AliITSv11GeometrySDD::CreateLadder(Int_t iLay) {
1792 // return an assembly volume containing the CF ladder
1795 Int_t nDetectors = fgkLay3Ndet;
1796 Double_t ladderLength = fgkLay3LadderLength;
1797 Double_t underSegDH = fLay3LadderUnderSegDH;
1798 Double_t *sensorZPos = fLay3sensorZPos;
1799 AliITSv11GeomCableFlat *digitCableA = fDigitCableLay3A;
1800 AliITSv11GeomCableFlat *digitCableB = fDigitCableLay3B;
1804 nDetectors = fgkLay4Ndet;
1805 ladderLength = fgkLay4LadderLength;
1806 digitCableA = fDigitCableLay4A;
1807 digitCableB = fDigitCableLay4B;
1808 underSegDH = fLay4LadderUnderSegDH;
1809 sensorZPos = fLay4sensorZPos;
1812 printf("AliITSv11GeometrySDD::CreateLadder : error=wrong layer\n");
1814 Double_t ladderBoxDH = fgkLadderHeight+fgkLadderSegBoxDH+underSegDH;
1815 TGeoVolumeAssembly *virtualLadder = new TGeoVolumeAssembly("ITSsddLadder");
1817 // placing virtual ladder segment following detector ordering convention
1818 //=======================================================================
1821 // adding segment this way to create cable points in the correct order ...
1822 for (Int_t iSegment = nDetectors/2-1; iSegment >= 0; iSegment-- ) {
1824 //TGeoVolumeAssembly *laddSegment = CreateLadderSegment(iLay, iSegment);
1825 TGeoVolume *laddSegment = CreateLadderSegment(iLay, iSegment);
1826 snprintf(transName, 30, "ITSsddLay%iLaddSeg%i", iLay, iSegment);
1827 Double_t segmentPos = fgkSegmentLength*(nDetectors/2-1-iSegment)
1828 + fgkSegmentLength/2;
1829 TGeoTranslation *segTr = new TGeoTranslation(transName, 0,
1830 underSegDH/2,segmentPos);
1832 virtualLadder->AddNode(laddSegment, iSegment, segTr);
1834 for (Int_t iSegment = nDetectors/2; iSegment < nDetectors; iSegment++ ) {
1836 TGeoVolume *laddSegment = CreateLadderSegment(iLay, iSegment);
1837 //TGeoVolumeAssembly *laddSegment = CreateLadderSegment(iLay, iSegment);
1838 snprintf(transName, 30, "ITSsddLay%iLaddSeg%i", iLay, iSegment);
1839 Double_t segmentPos = fgkSegmentLength*(nDetectors/2-1-iSegment)
1840 + fgkSegmentLength/2;
1841 TGeoTranslation *segTr = new TGeoTranslation(transName, 0,
1842 underSegDH/2,segmentPos);
1844 virtualLadder->AddNode(laddSegment, iSegment, segTr);
1847 // putting virtual volume corresponding to the end of ladder
1848 //=======================================================================
1849 TGeoVolumeAssembly *endLadder = CreateEndLadder( iLay );
1850 Double_t endLength = (ladderLength - nDetectors*fgkSegmentLength)/2.;
1851 TGeoTranslation *endTrZPos = new TGeoTranslation("ITSsddEndTrZPos",0,0,
1852 fgkSegmentLength*(nDetectors/2)+endLength/2.);
1853 // Euler rotation : about Z, then new X, then new Z
1854 TGeoRotation *endZNegRot = new TGeoRotation("",90, 180, -90);
1855 TGeoCombiTrans *endTrZNeg = new TGeoCombiTrans(0,0,
1856 -fgkSegmentLength*(nDetectors/2)-endLength/2.,endZNegRot);
1857 virtualLadder->AddNode(endLadder, 1, endTrZPos);
1858 virtualLadder->AddNode(endLadder, 2, endTrZNeg);
1860 // creating and inserting cable segments
1861 // (check points are placed while creating segments)
1862 //=======================================================================
1864 for (Int_t iSegment = 0; iSegment < nDetectors; iSegment++ ) {
1866 digitCableA[iSegment].SetInitialNode(virtualLadder);
1867 digitCableB[iSegment].SetInitialNode(virtualLadder);
1869 for (Int_t iPt=1; iPt<digitCableA[iSegment].GetNCheckPoints(); iPt++ ) {
1870 Double_t rotation = 0;
1872 rotation = 90-fgkHybridAngle;
1873 digitCableA[iSegment].CreateAndInsertCableSegment(iPt, rotation);
1875 digitCableA[iSegment].CreateAndInsertCableSegment(iPt);
1879 for (Int_t iPt=1; iPt<digitCableB[iSegment].GetNCheckPoints(); iPt++ ) {
1880 Double_t rotation = 0;
1882 rotation = fgkHybridAngle-90;
1883 digitCableB[iSegment].CreateAndInsertCableSegment(iPt, rotation);
1885 digitCableB[iSegment].CreateAndInsertCableSegment(iPt);
1890 //=======================================================================
1892 TGeoMedium *polyhamideSDD = GetMedium("SDDKAPTON (POLYCH2)$"); //ITSsddKAPTON_POLYCH2
1893 TGeoMedium *alSDD = GetMedium("AL$"); //ITSal
1895 AliITSv11GeomCableFlat cableHV[fgkLay4Ndet]; // temp !!!
1896 char cableHVname[30];
1897 for (Int_t iSegment = 0; iSegment<nDetectors; iSegment++) {
1898 snprintf(cableHVname,30,"ITSsddHVcable%i", iSegment);
1899 cableHV[iSegment].SetName(cableHVname);
1900 cableHV[iSegment].SetThickness(fgkLongHVcablePolyThick+fgkLongHVcableAlThick);
1901 cableHV[iSegment].SetWidth(fgkTransitHVtailWidth);
1902 cableHV[iSegment].SetNLayers(2);
1903 cableHV[iSegment].SetLayer(0, fgkLongHVcablePolyThick, polyhamideSDD,
1905 cableHV[iSegment].SetLayer(1, fgkLongHVcableAlThick, alSDD, fColorAl);
1906 cableHV[iSegment].SetInitialNode(virtualLadder);
1908 Double_t x1[3], x2[3], x3[3],
1909 vY[3] = {0,1,0}, vZ[3] = {0,0,1}, vYZ[3]={0,1,1};
1911 x1[0] = -fgkTransitHVtailXpos;
1912 x2[0] = -fgkTransitHVtailXpos;
1913 x3[0] = -fgkTransitHVtailXpos;
1914 for (Int_t iSegment = nDetectors/2-1; iSegment >= 0; iSegment-- ) {
1915 Double_t cableSeparation = TMath::Abs(iSegment - (nDetectors/2-1))
1916 *fgkLongHVcableSeparation;
1917 // adjust where HV long cable starts in Y
1918 // useful if you want to let some space for alignment
1919 x1[1] = - ladderBoxDH/2 + 2*fgkmm;
1920 x2[1] = - ladderBoxDH/2 + underSegDH - cableSeparation
1921 - (fgkLongHVcablePolyThick+fgkLongHVcableAlThick)/2;
1923 x1[2] = sensorZPos[iSegment]+fgkTransitHVtailLength-5*fgkmm;
1924 x2[2] = x1[2]+5*fgkmm;
1925 x3[2] = ladderLength/2-endLength;
1926 cableHV[iSegment].AddCheckPoint( virtualLadder, 0, x1, vY );
1927 cableHV[iSegment].AddCheckPoint( virtualLadder, 1, x2, vZ ); // vYZ
1928 cableHV[iSegment].AddCheckPoint( virtualLadder, 2, x3, vZ );
1930 //cableHV[iSegment].CreateAndInsertCableSegment(1,0);
1931 cableHV[iSegment].CreateAndInsertCableCylSegment(1, -45+180);
1932 //cableHV[iSegment].CreateAndInsertCableSegment(2,0);
1933 cableHV[iSegment].CreateAndInsertBoxCableSegment(2,0);
1937 x1[0] = fgkTransitHVtailXpos;
1938 x2[0] = fgkTransitHVtailXpos;
1939 x3[0] = fgkTransitHVtailXpos;
1941 for (Int_t iSegment = nDetectors/2; iSegment < nDetectors; iSegment++ ) {
1942 Double_t cableSeparation = TMath::Abs(iSegment - (nDetectors/2-1))
1943 *fgkLongHVcableSeparation;
1944 x1[1] = - ladderBoxDH/2 + 2*fgkmm; // adjust where HV long cable starts in Y
1945 x2[1] = - ladderBoxDH/2 + underSegDH - cableSeparation
1946 - (fgkLongHVcablePolyThick+fgkLongHVcableAlThick)/2;
1948 x1[2] = sensorZPos[iSegment]-fgkTransitHVtailLength+5*fgkmm;
1949 x2[2] = x1[2]-5*fgkmm;
1950 x3[2] = -ladderLength/2+endLength;
1951 cableHV[iSegment].AddCheckPoint( virtualLadder, 0, x1, vY );
1952 cableHV[iSegment].AddCheckPoint( virtualLadder, 1, x2, vZ ); // vYZ
1953 cableHV[iSegment].AddCheckPoint( virtualLadder, 2, x3, vZ );
1955 cableHV[iSegment].CreateAndInsertCableCylSegment(1, -45);
1956 cableHV[iSegment].CreateAndInsertBoxCableSegment(2,0);
1960 //**********************************
1961 if(GetDebug(1)) virtualLadder->CheckOverlaps(0.01);
1962 return virtualLadder;
1966 //________________________________________________________________________
1967 TGeoArb8 *AliITSv11GeometrySDD::CreateLadderSide(const char *name,
1968 Double_t dz, Double_t angle, Double_t xSign,
1969 Double_t L, Double_t H, Double_t l) {
1970 // Create one half of the V shape corner of CF ladder
1972 TGeoArb8 *cfLaddSide = new TGeoArb8(dz);
1973 cfLaddSide->SetName(name);
1975 // Points must be in clockwise order
1976 cfLaddSide->SetVertex(0, 0, 0);
1977 cfLaddSide->SetVertex(2, xSign*(L*TMath::Sin(angle)-l*TMath::Cos(angle)),
1978 -L*TMath::Cos(angle)-l*TMath::Sin(angle));
1979 cfLaddSide->SetVertex(4, 0, 0);
1980 cfLaddSide->SetVertex(6, xSign*(L*TMath::Sin(angle)-l*TMath::Cos(angle)),
1981 -L*TMath::Cos(angle)-l*TMath::Sin(angle));
1983 cfLaddSide->SetVertex(1, 0, -H);
1984 cfLaddSide->SetVertex(3, xSign*L*TMath::Sin(angle), -L*TMath::Cos(angle));
1985 cfLaddSide->SetVertex(5, 0, -H);
1986 cfLaddSide->SetVertex(7, xSign*L*TMath::Sin(angle), -L*TMath::Cos(angle));
1988 cfLaddSide->SetVertex(1, xSign*L*TMath::Sin(angle), -L*TMath::Cos(angle));
1989 cfLaddSide->SetVertex(3, 0, -H);
1990 cfLaddSide->SetVertex(5, xSign*L*TMath::Sin(angle), -L*TMath::Cos(angle));
1991 cfLaddSide->SetVertex(7, 0, -H);
1997 //________________________________________________________________________
1998 TGeoVolume* AliITSv11GeometrySDD::CreateHybrid(Int_t iLRSide) {
2000 // return a box containing the front-end hybrid
2003 Double_t roundHoleX = -fgkHybridWidth/2+fgkHybRndHoleX;
2005 Double_t screenTotalThick = fgkHybGlueScrnThick+fgkHybUpThick+fgkHybAlThick;
2006 Double_t lowFLTotalThick = fgkHybGlueLowThick+fgkHybUpThick+fgkHybAlThick;
2007 // Double_t upFLTotalThick = fgkHybGlueUpThick +fgkHybUpThick+fgkHybAlThick;
2008 Double_t chipsCCTotThick = fgkHybUnderNiThick+fgkHybGlueAgThick
2009 +fgkHybChipThick+2*(fgkHybUpCCThick+fgkHybAlCCThick);
2010 Double_t ccUpLayerTotThick = fgkHybUpCCThick+fgkHybAlCCThick+fgkHybUpCCThick;
2011 // Double_t volumeThick = (fgkHybridThBridgeThick+screenTotalThick+lowFLTotalThick
2012 // + upFLTotalThick + ccUpLayerTotThick);
2013 Double_t volumeThick = (fgkHybridThBridgeThick+screenTotalThick+lowFLTotalThick
2015 Double_t lowLayerYmin = -volumeThick/2+fgkHybridThBridgeThick
2017 Double_t flUpThick = fgkHybGlueUpThick+fgkHybUpThick;
2019 //**************************************************** media :
2020 TGeoMedium *airSDD = GetMedium("SDD AIR$");
2021 TGeoMedium *carbonFiberLadderStruct = GetMedium("SDDKAPTON (POLYCH2)$"); //ITSsddCarbonM55J
2022 TGeoMedium *alSDD = GetMedium("AL$"); //ITSal
2023 TGeoMedium *alSDD80p100 = GetMedium("AL$"); // to code !!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!
2024 TGeoMedium *alSDD50p100 = GetMedium("AL$"); // to code !!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!
2025 TGeoMedium *polyhamideSDD = GetMedium("SDDKAPTON (POLYCH2)$"); //ITSsddKAPTON_POLYCH2
2026 TGeoMedium *niSDD = GetMedium("NICKEL$");
2027 TGeoMedium *glueAG = GetMedium("SDDKAPTON (POLYCH2)$"); // to code !!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!
2028 TGeoMedium *siliconSDD = GetMedium("SDD SI CHIP$"); //ITSsddSiChip
2029 TGeoMedium *medSMD = GetMedium("SDD X7R capacitors$"); // SDDX7Rcapacitors
2030 TGeoMedium *medSMDweld = GetMedium("SDD X7R weld$");
2032 //**************************************************** main volume :
2033 // TGeoBBox *hybridBox = new TGeoBBox("",fgkHybridWidth/2, volumeThick/2,
2034 // (fgkHybridLength)/2);
2035 Double_t xhybr[6],yhybr[6];
2036 xhybr[0] = -fgkHybridWidth/2;
2037 yhybr[0] = -volumeThick/2;
2038 xhybr[1] = fgkHybridWidth/2;
2039 yhybr[1] = -volumeThick/2;
2040 xhybr[2] = fgkHybridWidth/2;
2041 yhybr[2] = volumeThick/2;
2042 xhybr[3] = -fgkHybridWidth/2;
2043 yhybr[3] = volumeThick/2;
2044 xhybr[4] = xhybr[3] - 1.05*fgkHybCC2SensorLen*SinD(fgkHybCC2SensorAng);
2045 yhybr[4] = yhybr[3] - 1.05*fgkHybCC2SensorLen*CosD(fgkHybCC2SensorAng);
2046 xhybr[5] = xhybr[4];
2047 yhybr[5] = yhybr[4] - volumeThick;
2049 TGeoXtru *hybridBox = new TGeoXtru(2);
2050 hybridBox->DefinePolygon(6, xhybr, yhybr);
2051 hybridBox->DefineSection(0,-fgkHybridLength/2);
2052 hybridBox->DefineSection(1, fgkHybridLength/2);
2054 TGeoVolume *hybrid = new TGeoVolume("ITSsddHybridVol", hybridBox,
2057 TGeoBBox *sThermalBridge = new TGeoBBox( "", fgkHybridWidth/2,
2058 fgkHybridThBridgeThick/2,
2061 //**************************************************** Thermal bridge :
2062 TGeoVolume *vThermalBridge = new TGeoVolume("ITSsddHybridThBridge",
2064 carbonFiberLadderStruct);
2065 vThermalBridge->SetLineColor(fColorCarbonFiber);
2066 TGeoTranslation *thBridgeTr = new TGeoTranslation(0, -volumeThick/2
2067 +fgkHybridThBridgeThick/2, 0);
2068 hybrid->AddNode(vThermalBridge, 1, thBridgeTr);
2070 //**************************************************** Screen layer :
2071 TGeoBBox *sAlScreenLayer = new TGeoBBox("sAlScreenLayer", fgkHybridWidth/2,
2072 fgkHybAlThick/2, fgkHybridLength/2);
2073 //here the upedex and glue layers are both assumed to be polyimide
2074 TGeoBBox *sUpGlueScreenLayer = new TGeoBBox("sUpGlueScreenLayer",
2076 (fgkHybUpThick+fgkHybGlueScrnThick)/2,
2078 TGeoTube *sRoundHole = new TGeoTube("sRoundHole", 0, fgkHybRndHoleRad,
2079 (screenTotalThick+lowFLTotalThick)/2);
2081 TGeoTranslation *upGlueScreenTr = new TGeoTranslation("upGlueScreenTr",0,
2082 -volumeThick/2+fgkHybridThBridgeThick+(fgkHybUpThick+fgkHybGlueScrnThick)/2,0);
2084 TGeoTranslation *alScreenTr = new TGeoTranslation("AlScreenTr", 0,
2085 -volumeThick/2+fgkHybridThBridgeThick+fgkHybUpThick+fgkHybGlueScrnThick
2086 +fgkHybAlThick/2, 0);
2088 TGeoTranslation hybHolePos1Tr(roundHoleX,
2089 -volumeThick/2+fgkHybridThBridgeThick+(screenTotalThick+lowFLTotalThick)/2,
2090 -fgkHybridLength/2+fgkHybRndHoleZ);
2091 TGeoTranslation hybHolePos2Tr(roundHoleX,
2092 -volumeThick/2+fgkHybridThBridgeThick+(screenTotalThick+lowFLTotalThick)/2,
2093 fgkHybridLength/2-fgkHybRndHoleZ);
2095 TGeoRotation *rotHole = new TGeoRotation("", 0, 90, 0);
2096 TGeoCombiTrans *hybHolePos1 = new TGeoCombiTrans(hybHolePos1Tr, *rotHole);
2097 hybHolePos1->SetName("hybHolePos1");
2098 TGeoCombiTrans *hybHolePos2 = new TGeoCombiTrans(hybHolePos2Tr, *rotHole);
2099 hybHolePos2->SetName("hybHolePos2");
2101 upGlueScreenTr->RegisterYourself();
2102 alScreenTr->RegisterYourself();
2103 hybHolePos1->RegisterYourself();
2104 hybHolePos2->RegisterYourself();
2107 TGeoCompositeShape *sScreenAl = new TGeoCompositeShape(
2108 "sAlScreenLayer:AlScreenTr-(sRoundHole:hybHolePos1"
2109 "+sRoundHole:hybHolePos2)");
2110 TGeoVolume *vScreenAl = new TGeoVolume("vScreenAl",sScreenAl, alSDD);
2111 vScreenAl->SetLineColor(fColorAl);
2112 TGeoCompositeShape *sScreenUpGlue = new TGeoCompositeShape(
2113 "sUpGlueScreenLayer:upGlueScreenTr-(sRoundHole:hybHolePos1"
2114 "+sRoundHole:hybHolePos2)");
2115 TGeoVolume *vScreenUpGlue = new TGeoVolume("vScreenUpGlue",
2116 sScreenUpGlue,polyhamideSDD);
2117 vScreenUpGlue->SetLineColor(fColorPolyhamide);
2119 hybrid->AddNode(vScreenUpGlue, 1, 0);
2120 hybrid->AddNode(vScreenAl, 1, 0);
2122 //**************************************************** FL low layer :
2123 Double_t sideWidth1 = fgkHybFLlowChipZ1 - fgkHybFLlowHoleDZ/2;
2124 Double_t sideWidth2 = fgkHybridLength - fgkHybFLlowChipZ4 - fgkHybFLlowHoleDZ/2;
2126 //here the upedex and glue layers are both assumed to be polyimide
2127 TGeoBBox *sUpGlueBar1 = new TGeoBBox("sUpGlueBar1", fgkHybridWidth/2,
2128 (fgkHybGlueLowThick+fgkHybUpThick)/2,
2130 TGeoBBox *sAlBar1 = new TGeoBBox("sAlBar1", fgkHybridWidth/2,
2131 fgkHybAlThick/2, sideWidth1/2);
2133 TGeoTranslation *upGlueBarTr1 = new TGeoTranslation("upGlueBarTr1", 0,
2134 lowLayerYmin+(fgkHybGlueLowThick+fgkHybUpThick)/2,
2135 -(fgkHybridLength-sideWidth1)/2);
2136 TGeoTranslation *alBarTr1 = new TGeoTranslation("alBarTr1", 0,
2137 lowLayerYmin+fgkHybGlueLowThick+fgkHybUpThick+fgkHybAlThick/2,
2138 -(fgkHybridLength-sideWidth1)/2);
2139 upGlueBarTr1->RegisterYourself();
2140 alBarTr1->RegisterYourself();
2142 TGeoCompositeShape *sLowUpGlueBar1 = new TGeoCompositeShape(
2143 "sUpGlueBar1:upGlueBarTr1-sRoundHole:hybHolePos1");
2144 TGeoCompositeShape *sLowAlBar1 = new TGeoCompositeShape(
2145 "sAlBar1:alBarTr1-sRoundHole:hybHolePos1");
2146 TGeoVolume *vLowUpGlueBar1 = new TGeoVolume("vLowUpGlueBar1",
2147 sLowUpGlueBar1, polyhamideSDD);
2148 TGeoVolume *vLowAlBar1 = new TGeoVolume("vLowAlBar1",
2150 vLowUpGlueBar1->SetLineColor(fColorPolyhamide);
2151 vLowAlBar1->SetLineColor(fColorAl);
2152 hybrid->AddNode(vLowUpGlueBar1,1,0);
2153 hybrid->AddNode(vLowAlBar1,1,0);
2156 //here the upedex and glue layers are both assumed to be polyimide
2157 TGeoBBox *sUpGlueBar2 = new TGeoBBox("sUpGlueBar2", fgkHybridWidth/2,
2158 (fgkHybGlueLowThick+fgkHybUpThick)/2,
2160 TGeoBBox *sAlBar2 = new TGeoBBox("sAlBar2", fgkHybridWidth/2,
2161 fgkHybAlThick/2, sideWidth2/2);
2163 TGeoTranslation *upGlueBarTr2 = new TGeoTranslation("upGlueBarTr2", 0,
2164 lowLayerYmin+(fgkHybGlueLowThick+fgkHybUpThick)/2,
2165 (fgkHybridLength-sideWidth2)/2);
2166 TGeoTranslation *alBarTr2 = new TGeoTranslation("alBarTr2", 0,
2167 lowLayerYmin+fgkHybGlueLowThick+fgkHybUpThick+fgkHybAlThick/2,
2168 (fgkHybridLength-sideWidth2)/2);
2169 upGlueBarTr2->RegisterYourself();
2170 alBarTr2->RegisterYourself();
2172 TGeoCompositeShape *sLowUpGlueBar2 = new TGeoCompositeShape(
2173 "sUpGlueBar2:upGlueBarTr2-sRoundHole:hybHolePos2");
2174 TGeoCompositeShape *sLowAlBar2 = new TGeoCompositeShape(
2175 "sAlBar2:alBarTr2-sRoundHole:hybHolePos2");
2176 TGeoVolume *vLowUpGlueBar2 = new TGeoVolume("vLowUpGlueBar2",sLowUpGlueBar2,
2178 TGeoVolume *vLowAlBar2 = new TGeoVolume("vLowAlBar2",sLowAlBar2,
2180 vLowUpGlueBar2->SetLineColor(fColorPolyhamide);
2181 vLowAlBar2->SetLineColor(fColorAl);
2182 hybrid->AddNode(vLowUpGlueBar2, 1, 0);
2183 hybrid->AddNode(vLowAlBar2, 1, 0);
2185 if(GetDebug(3)) { // Remove compiler warning.
2186 sAlScreenLayer->InspectShape();
2187 sUpGlueScreenLayer->InspectShape();
2188 sRoundHole->InspectShape();
2189 sUpGlueBar1->InspectShape();
2190 sUpGlueBar2->InspectShape();
2191 sAlBar1->InspectShape();
2192 sAlBar2->InspectShape();
2195 //using class AliITSv11GeomCableFlat to add 2-layer segments ...
2196 Double_t piece1width = fgkHybFLlowPasX-fgkHybFLlowHolePasDX/2;
2197 AliITSv11GeomCableFlat lowFLpiece("lowFLpiece1",piece1width,
2199 lowFLpiece.SetNLayers(2);
2200 lowFLpiece.SetLayer(0, fgkHybGlueLowThick+fgkHybUpThick, polyhamideSDD,
2202 lowFLpiece.SetLayer(1, fgkHybAlThick, alSDD80p100, fColorAl);
2203 // alSDD at 80% : mostly to take into account strips of piece 3
2205 Double_t x1[3] = { -fgkHybridWidth/2 + piece1width/2,
2206 lowLayerYmin + lowFLTotalThick/2,
2207 -fgkHybridLength/2 + sideWidth1 };
2208 Double_t x2[3] ={ x1[0], x1[1], fgkHybridLength/2 - sideWidth2 };
2209 Double_t vZ[3] = {0,0,1};
2210 lowFLpiece.AddCheckPoint( hybrid, 0, x2, vZ );
2211 lowFLpiece.AddCheckPoint( hybrid, 1, x1, vZ );
2212 lowFLpiece.SetInitialNode(hybrid);
2213 lowFLpiece.CreateAndInsertBoxCableSegment(1);
2214 lowFLpiece.ResetPoints();
2216 Double_t piece2width = fgkHybFLlowAmbX-fgkHybFLlowPasX
2217 -fgkHybFLlowHolePasDX/2-fgkHybFLlowHoleAmbDX/2;
2219 lowFLpiece.SetWidth(piece2width);
2220 lowFLpiece.SetName("lowFLpiece2");
2221 x1[0] = piece2width/2+fgkHybFLlowPasX+fgkHybFLlowHolePasDX/2-fgkHybridWidth/2;
2223 lowFLpiece.AddCheckPoint( hybrid, 0, x2, vZ );
2224 lowFLpiece.AddCheckPoint( hybrid, 1, x1, vZ );
2225 lowFLpiece.CreateAndInsertBoxCableSegment(1);
2226 lowFLpiece.ResetPoints();
2228 Double_t piece3width = fgkHybridWidth - fgkHybFLlowAmbX
2229 - fgkHybFLlowHoleAmbDX/2;
2231 lowFLpiece.SetWidth(piece3width);
2232 lowFLpiece.SetName("lowFLpiece3");
2233 x1[0] = fgkHybridWidth/2-piece3width/2;
2235 lowFLpiece.AddCheckPoint( hybrid, 0, x2, vZ );
2236 lowFLpiece.AddCheckPoint( hybrid, 1, x1, vZ );
2237 lowFLpiece.CreateAndInsertBoxCableSegment(1);
2239 Double_t zChips[4] = {fgkHybFLlowChipZ1,fgkHybFLlowChipZ2,
2240 fgkHybFLlowChipZ3,fgkHybFLlowChipZ4};
2241 Double_t vX[3] = {1,0,0};
2242 for (Int_t i=0; i<3; i++) {
2244 snprintf(ch, 20, "lowFLpieceA%i", i+4);
2245 lowFLpiece.SetName(ch);
2246 lowFLpiece.SetWidth(zChips[i+1]-zChips[i]-fgkHybFLlowHoleDZ);
2248 lowFLpiece.SetLayer(1, fgkHybAlThick, alSDD, fColorAl);
2249 x1[0] = -fgkHybridWidth/2 + piece1width;
2250 x2[0] = x1[0] + fgkHybFLlowHolePasDX;
2251 Double_t zPiece = (zChips[i+1]+zChips[i])/2 - fgkHybridLength/2;
2252 x1[2] = zPiece; x2[2] = zPiece;
2253 lowFLpiece.AddCheckPoint( hybrid, 0, x2, vX );
2254 lowFLpiece.AddCheckPoint( hybrid, 1, x1, vX );
2255 lowFLpiece.CreateAndInsertBoxCableSegment(1,90);
2256 lowFLpiece.ResetPoints();
2258 snprintf(ch, 20, "lowFLpieceB%i", i+4);
2259 lowFLpiece.SetName(ch);
2260 x1[0] = fgkHybridWidth/2 - piece3width;
2261 x2[0] = x1[0] - fgkHybFLlowHoleAmbDX;
2262 lowFLpiece.AddCheckPoint( hybrid, 0, x1, vX );
2263 lowFLpiece.AddCheckPoint( hybrid, 1, x2, vX );
2264 lowFLpiece.CreateAndInsertBoxCableSegment(1,90);
2267 //**************************************************** chips+CC:
2268 AliITSv11GeomCableFlat chip("", fgkHybChipsDZ, chipsCCTotThick);
2269 chip.SetInitialNode(hybrid);
2271 chip.SetLayer(0, fgkHybUnderNiThick, niSDD, 2);
2272 chip.SetLayer(1, fgkHybGlueAgThick, glueAG, 4);
2273 chip.SetLayer(2, fgkHybChipThick, siliconSDD, fColorSilicon);
2274 chip.SetLayer(3, fgkHybUpCCThick+fgkHybUpCCThick, polyhamideSDD,
2276 chip.SetLayer(4, fgkHybAlCCThick+fgkHybAlCCThick, alSDD80p100, fColorAl);
2277 // Here the tho CC (low+up) are merged
2278 // In fact, the last layer has a smaller surface of Al -> I put 80%
2280 x1[1] = lowLayerYmin + chipsCCTotThick/2;
2284 for (Int_t i=0; i<4; i++) {
2285 snprintf(ch, 20, "pascalCC%i", i);
2287 x1[0] = fgkHybFLlowPasX - fgkHybridWidth/2 - fgkHybPascalDX/2;
2288 x2[0] = x1[0] + fgkHybPascalDX;
2289 x1[2] = zChips[i] - fgkHybridLength/2;
2291 chip.AddCheckPoint( hybrid, 0, x1, vX );
2292 chip.AddCheckPoint( hybrid, 1, x2, vX );
2293 chip.CreateAndInsertBoxCableSegment(1,-90);
2296 snprintf(ch, 20, "ambraCC%i", i);
2298 x1[0] = fgkHybFLlowAmbX - fgkHybridWidth/2 - fgkHybAmbraDX/2;
2299 x2[0] = x1[0] + fgkHybAmbraDX;
2300 chip.AddCheckPoint( hybrid, 0, x1, vX );
2301 chip.AddCheckPoint( hybrid, 1, x2, vX );
2302 chip.CreateAndInsertBoxCableSegment(1,-90);
2306 //**************************************************** CC outside chips:
2307 // I don't think there is a second aluminium layer here ...
2308 for (Int_t i = 0; i<4; i++) {
2309 snprintf(ch, 20, "ccLayerA%i", i);
2311 AliITSv11GeomCableFlat ccLayer1(ch, 6.6*fgkmm, ccUpLayerTotThick);
2312 ccLayer1.SetInitialNode(hybrid);
2313 ccLayer1.SetNLayers(2);
2314 ccLayer1.SetLayer(0, 2*fgkHybUpCCThick, polyhamideSDD, fColorPolyhamide);
2315 ccLayer1.SetLayer(1, fgkHybAlCCThick, alSDD50p100, fColorAl);
2318 x1[0] = -fgkHybridWidth/2;
2319 x2[0] = fgkHybFLlowPasX - fgkHybridWidth/2 - fgkHybPascalDX/2;
2320 x1[1] = lowLayerYmin + fgkHybUnderNiThick + fgkHybGlueAgThick
2321 + fgkHybChipThick + ccUpLayerTotThick/2;
2323 x1[2] = zChips[i] - fgkHybridLength/2;
2325 ccLayer1.AddCheckPoint( hybrid, 0, x1, vX );
2326 ccLayer1.AddCheckPoint( hybrid, 1, x2, vX );
2327 ccLayer1.CreateAndInsertBoxCableSegment(1,-90);
2329 snprintf(ch, 20, "ccLayerB%i", i);
2330 AliITSv11GeomCableFlat ccLayer2(ch, fgkHybChipsDZ, ccUpLayerTotThick);
2331 ccLayer2.SetInitialNode(hybrid);
2332 ccLayer2.SetNLayers(2);
2333 ccLayer2.SetLayer(0, 2*fgkHybUpCCThick, polyhamideSDD, fColorPolyhamide);
2334 ccLayer2.SetLayer(1, fgkHybAlCCThick, alSDD50p100, fColorAl);
2337 x1[0] = -fgkHybridWidth/2 + fgkHybFLlowPasX + fgkHybPascalDX/2;
2338 x2[0] = -fgkHybridWidth/2 + fgkHybFLlowAmbX - fgkHybAmbraDX/2;
2339 ccLayer2.AddCheckPoint( hybrid, 0, x1, vX );
2340 ccLayer2.AddCheckPoint( hybrid, 1, x2, vX );
2341 ccLayer2.CreateAndInsertBoxCableSegment(1,-90);
2342 ccLayer2.ResetPoints();
2343 snprintf(ch, 20, "ccLayerC%i", i);
2344 ccLayer2.SetName(ch);
2345 x1[0] = -fgkHybridWidth/2 + fgkHybFLlowAmbX + fgkHybAmbraDX/2;
2346 x2[0] = fgkHybridWidth/2 - fgkHybFLUpperWidth + 3*fgkmm;
2347 x1[1] = lowLayerYmin + lowFLTotalThick + flUpThick + fgkHybAlThick
2348 + ccUpLayerTotThick/2;
2351 ccLayer2.AddCheckPoint( hybrid, 0, x1, vX );
2352 ccLayer2.AddCheckPoint( hybrid, 1, x2, vX );
2353 ccLayer2.CreateAndInsertBoxCableSegment(1,-90);
2355 //**************************************************** CC to sensors:
2356 // (alas, we cannot use GeomCableFlat here because section is not constant)
2357 Double_t xcc[8],ycc[8];
2358 xcc[0] = -0.5*ccLayer1.GetWidth();
2360 xcc[1] = 0.5*ccLayer1.GetWidth();
2363 ycc[2] = -fgkHybCC2SensorLen*0.8;
2364 xcc[3] = xcc[2] + 0.1*fgkHybCC2SensorWid;
2367 ycc[4] = -fgkHybCC2SensorLen;
2368 xcc[5] = xcc[4] - fgkHybCC2SensorWid;
2371 ycc[6] = 0.8*ycc[5];
2373 ycc[7] = 0.2*ycc[5];
2375 TGeoXtru* ccToSensPoliSh = new TGeoXtru(2);
2376 ccToSensPoliSh->DefinePolygon(8, xcc, ycc);
2377 ccToSensPoliSh->DefineSection(0, 0.);
2378 ccToSensPoliSh->DefineSection(1, ccLayer1.GetThickness());
2380 snprintf(ch, 20, "ccToSens%i", i);
2381 TGeoVolume* ccToSensPoliVol = new TGeoVolume(ch, ccToSensPoliSh, polyhamideSDD);
2382 ccToSensPoliVol->SetLineColor(fColorPolyhamide);
2384 TGeoXtru* ccToSensAlSh = new TGeoXtru(2);
2387 ccToSensAlSh->DefinePolygon(8, xcc, ycc);
2388 ccToSensAlSh->DefineSection(0, 0.);
2389 ccToSensAlSh->DefineSection(1, fgkHybAlCCThick);
2391 snprintf(ch, 20, "ccToSensAl%i", i);
2392 TGeoVolume* ccToSensAlVol = new TGeoVolume(ch, ccToSensAlSh, alSDD50p100);
2393 ccToSensAlVol->SetLineColor(fColorAl);
2395 ccToSensPoliVol->AddNode(ccToSensAlVol, 1, 0);
2398 ccLayer1.GetPoint(0,coord);
2399 hybrid->AddNode(ccToSensPoliVol, i+1,
2400 new TGeoCombiTrans(coord[0], coord[1], coord[2],
2401 new TGeoRotation("",-90-fgkHybCC2SensorAng, 90, 90)));
2404 //**************************************************** FL UP:
2405 // (last Al layer will be a special triangular shape)
2406 TGeoBBox *sFLupPolyhamide = new TGeoBBox("sFLupPolyhamide",
2407 fgkHybFLUpperWidth/2, flUpThick/2,
2408 fgkHybFLUpperLength/2);
2409 TGeoVolume *vFLupPolyhamide = new TGeoVolume("vFLupPolyhamide",
2410 sFLupPolyhamide, polyhamideSDD);
2411 vFLupPolyhamide->SetLineColor(fColorPolyhamide);
2412 TGeoTranslation *trFLupPolyhamide =
2413 new TGeoTranslation(fgkHybridWidth/2-fgkHybFLUpperWidth/2,
2414 lowLayerYmin+lowFLTotalThick+flUpThick/2,0);
2416 hybrid->AddNode(vFLupPolyhamide, 1, trFLupPolyhamide);
2418 TGeoArb8 *aluStrip = new TGeoArb8(fgkHybAlThick/2);
2419 aluStrip->SetVertex( 0,-fgkHybFLUpperAlDZ/2, fgkHybFLUpperWidth);
2420 aluStrip->SetVertex( 1, fgkHybFLUpperAlDZ/2, fgkHybFLUpperWidth);
2421 aluStrip->SetVertex( 2, fgkHybFLUpperAlDZ/2, fgkHybFLUpperWidth-fgkHybFLUpperAldx);
2422 aluStrip->SetVertex( 3,-fgkHybFLUpperAlDZ/2, 0);
2423 aluStrip->SetVertex( 4,-fgkHybFLUpperAlDZ/2, fgkHybFLUpperWidth);
2424 aluStrip->SetVertex( 5, fgkHybFLUpperAlDZ/2, fgkHybFLUpperWidth);
2425 aluStrip->SetVertex( 6, fgkHybFLUpperAlDZ/2, fgkHybFLUpperWidth-fgkHybFLUpperAldx);
2426 aluStrip->SetVertex( 7,-fgkHybFLUpperAlDZ/2, 0);
2427 TGeoVolume *vAluStrip = new TGeoVolume("vAluStrip",aluStrip, alSDD50p100);
2430 vAluStrip->SetLineColor(fColorAl);
2431 //TGeoRotation rotAluStrip("rotAluStrip",0, -90, 90);
2432 TGeoRotation *rotAluStrip = new TGeoRotation("rotAluStrip",0, -90, 90);
2434 Double_t yRotAluStrip = lowLayerYmin+lowFLTotalThick
2435 +flUpThick+fgkHybAlThick/2;
2436 TGeoCombiTrans *aluStripTr1 = new TGeoCombiTrans(
2437 fgkHybridWidth/2,yRotAluStrip,
2438 fgkHybridLength/2-fgkHybFLlowChipZ1+1*fgkmm, rotAluStrip);
2439 TGeoCombiTrans *aluStripTr2 = new TGeoCombiTrans(*aluStripTr1);
2440 AddTranslationToCombiTrans(aluStripTr2,0,0,
2441 fgkHybFLlowChipZ1-fgkHybFLlowChipZ2);
2442 TGeoCombiTrans *aluStripTr3 = new TGeoCombiTrans(*aluStripTr2);
2443 AddTranslationToCombiTrans(aluStripTr3,0,0,
2444 fgkHybFLlowChipZ2-fgkHybFLlowChipZ3);
2445 TGeoCombiTrans *aluStripTr4 = new TGeoCombiTrans(*aluStripTr3);
2446 AddTranslationToCombiTrans(aluStripTr4,0,0,
2447 fgkHybFLlowChipZ3-fgkHybFLlowChipZ4);
2449 hybrid->AddNode(vAluStrip, 1, aluStripTr1);
2450 hybrid->AddNode(vAluStrip, 2, aluStripTr2);
2451 hybrid->AddNode(vAluStrip, 3, aluStripTr3);
2452 hybrid->AddNode(vAluStrip, 4, aluStripTr4);
2453 //**************************************************** SMD:
2454 TGeoBBox *hybSMD = new TGeoBBox("ITSsddSMDshape",
2455 fgkHybSMDmiddleL/2+fgkHybSMDendL,
2456 fgkHybSMDheight/2,fgkHybSMDendW/2);
2457 TGeoVolume *vHybSMD = new TGeoVolume("ITSsddSMD",hybSMD,airSDD);
2459 TGeoBBox *hybSMDmiddle = new TGeoBBox("ITSsddSMDmiddleShape",
2460 fgkHybSMDmiddleL/2,fgkHybSMDheight/2,
2461 fgkHybSMDmiddleW/2);
2462 TGeoVolume *vHybSMDmiddle = new TGeoVolume("ITSsddSMDmiddle",
2463 hybSMDmiddle,medSMD);
2464 vHybSMDmiddle->SetLineColor(fColorSMD);
2465 TGeoBBox *hybSMDend = new TGeoBBox("ITSsddSMDendShape",
2466 fgkHybSMDendL/2,fgkHybSMDheight/2,fgkHybSMDendW/2);
2467 TGeoVolume *vHybSMDend = new TGeoVolume("ITSsddSMDend",
2468 hybSMDend,medSMDweld);
2469 vHybSMDend->SetLineColor(fColorSMDweld);
2470 TGeoTranslation *vHybSMDendTr1 = new TGeoTranslation("",
2471 (fgkHybSMDmiddleL+fgkHybSMDendL)/2,0,0);
2472 TGeoTranslation *vHybSMDendTr2 = new TGeoTranslation("",
2473 -(fgkHybSMDmiddleL+fgkHybSMDendL)/2,0,0);
2474 vHybSMD->AddNode(vHybSMDmiddle,1,0);
2475 vHybSMD->AddNode(vHybSMDend,1,vHybSMDendTr1);
2476 vHybSMD->AddNode(vHybSMDend,2,vHybSMDendTr2);
2477 for (Int_t i=0; i<fgkNHybSMD; i++) {
2478 TGeoTranslation *vHybSMDtr = new TGeoTranslation("",
2479 -fgkHybridWidth/2+fgkHybSMDposX[i],
2480 lowLayerYmin+lowFLTotalThick+fgkHybSMDheight/2,
2481 -fgkHybridLength/2+fgkHybSMDposZ[i]);
2482 hybrid->AddNode(vHybSMD, i+1, vHybSMDtr);
2488 if(GetDebug(1)) hybrid->CheckOverlaps(0.01);
2489 hybrid->SetVisibility(kFALSE);
2493 //________________________________________________________________________
2494 TGeoVolume* AliITSv11GeometrySDD::CreateLadderSegment(Int_t iLay, Int_t iSeg) {
2496 // Return a TGeoVolume* containing a segment of a ladder.
2499 TGeoMedium *phynoxSDD = GetMedium("INOX$");
2500 TGeoMedium *coolerMediumSDD = GetMedium("WATER$");
2501 TGeoMedium *airSDD = GetMedium("SDD AIR$");
2502 TGeoMedium *alSDD = GetMedium("AL$");
2504 Double_t tDY = fgkLadderSegBoxDH/2; //space left on top of the ladder
2505 Double_t segmentLength = fgkSegmentLength;
2506 Double_t spaceBetweenCables = 500*fgkmicron;
2508 //*****************************************
2509 // Set parameters according to (iLay,iSeg):
2510 //*****************************************
2511 Int_t nDetectors = fgkLay3Ndet;
2512 Double_t coolPipeSuppH = fgkLay3CoolPipeSuppH;
2513 Double_t sensorCenterZPos = fLay3sensorZPos[iSeg]-
2514 (fgkSegmentLength*fgkLay3Ndet/2. -
2515 fgkSegmentLength/2-(iSeg)*fgkSegmentLength);
2516 // sensorCenterZPos = z in segment local coord syst.
2518 AliITSv11GeomCableFlat *digitCableA = fDigitCableLay3A;
2519 AliITSv11GeomCableFlat *digitCableB = fDigitCableLay3B;
2522 } else if (iLay==4) {
2523 nDetectors = fgkLay4Ndet;
2524 coolPipeSuppH = fgkLay4CoolPipeSuppH;
2525 sensorCenterZPos = fLay4sensorZPos[iSeg]-
2526 (fgkSegmentLength*fgkLay4Ndet/2. -
2527 fgkSegmentLength/2-(iSeg)*fgkSegmentLength);
2528 digitCableA = fDigitCableLay4A;
2529 digitCableB = fDigitCableLay4B;
2531 printf("AliITSv11GeometrySDD::CreateLadderSegment Wrong layer index !");
2534 Double_t cableSideSign = -1;
2535 if (iSeg<nDetectors/2) cableSideSign = 1;
2536 Double_t spaceForCables = spaceBetweenCables*
2537 (nDetectors-TMath::Abs(nDetectors-2*iSeg-1)-1)/2
2539 // gives [0-1-2-2-1-0]*spaceBetweenCables
2540 // or [0-1-2-3-3-2-1-0]*spaceBetweenCables
2541 Int_t iUpdateCableMin;
2542 Int_t iUpdateCableMax;
2543 if (cableSideSign==-1) {
2544 iUpdateCableMin = nDetectors/2;
2545 iUpdateCableMax = iSeg-1;
2547 iUpdateCableMin = iSeg+1;
2548 iUpdateCableMax = nDetectors/2-1;
2552 cout << "Segment ("<< iLay <<',' << iSeg
2553 << ") : sensor z shift in local segment coord.="
2554 << sensorCenterZPos << endl;
2557 //****************************
2558 // The segment volume
2559 //****************************
2561 // Use of TGeoVolumeAssembly increases the calculation time of overlaps and very
2562 // likely slows down the transport of particles through the geometry
2564 //TGeoVolumeAssembly *virtualSeg = new TGeoVolumeAssembly("ITSsddSegment");
2566 // TGeoBBox *segBox = new TGeoBBox("ITSsddSegBox",
2567 // fgkLadderWidth/2+fgkPinSuppWidth+fgkLadderSegBoxDW,
2568 // fgkLadderHeight/2+fgkLadderSegBoxDH/2,
2569 // segmentLength/2);
2570 // A shaped Xtru instead of a simple BBox to avoid overlaps and extrusions
2571 TGeoXtru *segBox = new TGeoXtru(2);
2572 segBox->SetName("ITSsddSegBox");
2574 Double_t xseg[12],yseg[12];
2575 xseg[ 0] = -(fgkLadderWidth/2+fgkPinSuppWidth+fgkLadderSegBoxDW);
2576 yseg[ 0] = fgkLadderHeight/2+fgkLadderSegBoxDH/2;
2578 yseg[ 1] = -yseg[0];
2579 xseg[ 2] = 0.87*xseg[1];
2581 xseg[ 3] = 0.77*xseg[1];
2582 yseg[ 3] = -yseg[0] - 0.62*fgkHybCC2SensorLen;
2583 xseg[ 4] = 0.72*xseg[1];
2585 xseg[ 5] = 0.83*xseg[1];
2588 for (Int_t j=0; j<6; j++) {
2589 xseg[6+j] = -xseg[5-j];
2590 yseg[6+j] = yseg[5-j];
2593 segBox->DefinePolygon(12, xseg, yseg);
2594 segBox->DefineSection(0,-segmentLength/2);
2595 segBox->DefineSection(1, segmentLength/2);
2597 TGeoVolume *virtualSeg = new TGeoVolume("ITSsddSegment",
2599 virtualSeg->SetVisibility(kFALSE);
2601 //******************************
2602 // Carbon fiber structure :
2603 //******************************
2605 virtualSeg->AddNode(fLaddSegCommonVol[0], 1, fLaddSegCommonTr[0]);
2606 Int_t volumeIndex = 1;
2607 for (Int_t i = 1; i<fgkNladdSegCommonVol;i++ ) {
2608 if (fLaddSegCommonVol[i]==fLaddSegCommonVol[i-1])
2612 virtualSeg->AddNode(fLaddSegCommonVol[i], volumeIndex,
2613 fLaddSegCommonTr[i]);
2616 //**********************************
2617 // Pine support of the sensors :
2618 //**********************************
2619 TGeoRotation *rotPS1 = new TGeoRotation("",0,-90,90);
2620 TGeoRotation *rotPS2 = new TGeoRotation("",0,-90,-90);
2622 // The use of the following constructor type allow to use rotPS1 and rotPS2
2623 // (and not copy them) therefore we gain some memory
2624 TGeoCombiTrans *transPS1 = new TGeoCombiTrans( fgkPinDYOnSensor,
2625 - fgkLadderHeight/2.-tDY
2626 + fgkPinSuppHeight/2.,
2627 sensorCenterZPos+fgkPinDXminOnSensor,rotPS1);
2629 TGeoCombiTrans *transPS2 = new TGeoCombiTrans( fgkPinDYOnSensor,
2630 - fgkLadderHeight/2.-tDY
2631 + fgkPinSuppHeight/2.,
2632 sensorCenterZPos+fgkPinDXminOnSensor,rotPS1);
2633 AddTranslationToCombiTrans(transPS2, 0, 0, fgkPinPinDDXOnSensor);
2635 TGeoCombiTrans *transPS3 = new TGeoCombiTrans( fgkPinDYOnSensor,
2636 - fgkLadderHeight/2.-tDY
2637 + fgkPinSuppHeight/2.,
2638 sensorCenterZPos+fgkPinDXminOnSensor,rotPS1);
2639 AddTranslationToCombiTrans(transPS3, 0, 0, -2*fgkPinDXminOnSensor);
2641 TGeoCombiTrans *transPS4 = new TGeoCombiTrans( fgkPinDYOnSensor,
2642 - fgkLadderHeight/2.-tDY
2643 + fgkPinSuppHeight/2.,
2644 sensorCenterZPos+fgkPinDXminOnSensor,rotPS1);
2645 AddTranslationToCombiTrans(transPS4, 0, 0, -2*fgkPinDXminOnSensor-fgkPinPinDDXOnSensor);
2647 TGeoCombiTrans *transPS5 = new TGeoCombiTrans( -fgkPinDYOnSensor,
2648 - fgkLadderHeight/2. - tDY
2649 + fgkPinSuppHeight/2.,
2650 sensorCenterZPos+fgkPinDXminOnSensor,rotPS2);
2652 TGeoCombiTrans *transPS6 = new TGeoCombiTrans( -fgkPinDYOnSensor,
2653 - fgkLadderHeight/2. - tDY
2654 + fgkPinSuppHeight/2.,
2655 sensorCenterZPos+fgkPinDXminOnSensor,rotPS2);
2656 AddTranslationToCombiTrans(transPS6, 0, 0, fgkPinPinDDXOnSensor);
2658 TGeoCombiTrans *transPS7 = new TGeoCombiTrans( -fgkPinDYOnSensor,
2659 - fgkLadderHeight/2. - tDY
2660 + fgkPinSuppHeight/2.,
2661 sensorCenterZPos+fgkPinDXminOnSensor,rotPS2);
2662 AddTranslationToCombiTrans(transPS7, 0, 0, -2*fgkPinDXminOnSensor);
2664 TGeoCombiTrans *transPS8 = new TGeoCombiTrans( -fgkPinDYOnSensor,
2665 - fgkLadderHeight/2. - tDY
2666 + fgkPinSuppHeight/2.,
2667 sensorCenterZPos+fgkPinDXminOnSensor,rotPS2);
2668 AddTranslationToCombiTrans(transPS8, 0, 0, -2*fgkPinDXminOnSensor-fgkPinPinDDXOnSensor);
2670 virtualSeg->AddNode(fPinSupport, 1, transPS1);
2671 virtualSeg->AddNode(fPinSupport, 2, transPS2);
2672 virtualSeg->AddNode(fPinSupport, 3, transPS3);
2673 virtualSeg->AddNode(fPinSupport, 4, transPS4);
2674 virtualSeg->AddNode(fPinSupport, 5, transPS5);
2675 virtualSeg->AddNode(fPinSupport, 6, transPS6);
2676 virtualSeg->AddNode(fPinSupport, 7, transPS7);
2677 virtualSeg->AddNode(fPinSupport, 8, transPS8);
2679 TGeoMedium *pinMed = GetMedium("RYTON$");
2680 Double_t fgkPinHeight = 4.5*fgkmm;
2681 TGeoTube *pineS = new TGeoTube("ITSsddPin",0,fgkPinR,
2683 TGeoVolume *pineV = new TGeoVolume("ITSsddPinVol", pineS, pinMed);
2685 TGeoCombiTrans *transPS2b = new TGeoCombiTrans( fgkPinDYOnSensor,
2686 - fgkLadderHeight/2.-tDY
2688 sensorCenterZPos+fgkPinDXminOnSensor,rotPS1);
2689 AddTranslationToCombiTrans(transPS2b, 0, 0, fgkPinPinDDXOnSensor);
2690 virtualSeg->AddNode(pineV, 1, transPS2b);
2692 TGeoCombiTrans *transPS6b = new TGeoCombiTrans( -fgkPinDYOnSensor,
2693 - fgkLadderHeight/2. - tDY
2695 sensorCenterZPos+fgkPinDXminOnSensor,rotPS2);
2696 AddTranslationToCombiTrans(transPS6b, 0, 0, fgkPinPinDDXOnSensor);
2697 virtualSeg->AddNode(pineV, 2, transPS6b);
2700 TGeoCombiTrans *transPS4b = new TGeoCombiTrans( fgkPinDYOnSensor,
2701 - fgkLadderHeight/2.-tDY
2703 sensorCenterZPos+fgkPinDXminOnSensor,rotPS1);
2704 AddTranslationToCombiTrans(transPS4b, 0, 0, -2*fgkPinDXminOnSensor-fgkPinPinDDXOnSensor);
2705 virtualSeg->AddNode(pineV, 3, transPS4b);
2707 TGeoCombiTrans *transPS8b = new TGeoCombiTrans( -fgkPinDYOnSensor,
2708 - fgkLadderHeight/2. - tDY
2710 sensorCenterZPos+fgkPinDXminOnSensor,rotPS2);
2711 AddTranslationToCombiTrans(transPS8b, 0, 0, -2*fgkPinDXminOnSensor-fgkPinPinDDXOnSensor);
2712 virtualSeg->AddNode(pineV, 4, transPS8b);
2715 //******************************
2716 // Cooling pipe supports :
2717 //******************************
2718 Double_t triangleHeight = fgkLadderHeight - fgkLadderBeamRadius;
2719 Double_t halfTheta = TMath::ATan( 0.5*fgkLadderWidth/triangleHeight );
2720 Double_t triangleCPaxeDist = fgkCoolPipeSuppAxeDist-fgkCoolPipeSuppWidthExt-
2721 fgkCoolPipeSuppWidthIn+fgkLadderBeamRadius;
2723 Double_t coolPipeSuppL = TMath::Tan(halfTheta)*
2724 (triangleHeight+triangleCPaxeDist/
2725 TMath::Sin(halfTheta)-coolPipeSuppH);
2726 if (fAddCoolingSyst) {
2727 TGeoRotation *rotCPS2 = new TGeoRotation("", -halfTheta*TMath::RadToDeg(), -90, 90);
2728 TGeoRotation *rotCPS1 = new TGeoRotation("", halfTheta*TMath::RadToDeg(), -90, -90);
2729 TGeoCombiTrans *transCPS1 = new TGeoCombiTrans(coolPipeSuppL,
2730 -fgkLadderHeight/2. - tDY
2731 +coolPipeSuppH+fgkLadderBeamRadius,
2732 -segmentLength/2., rotCPS1);
2734 TGeoCombiTrans *transCPS3 = new TGeoCombiTrans(coolPipeSuppL,
2735 -fgkLadderHeight/2. - tDY
2736 +coolPipeSuppH+fgkLadderBeamRadius,
2737 -segmentLength/2., rotCPS1);
2738 AddTranslationToCombiTrans(transCPS3, 0, 0, segmentLength);
2740 TGeoCombiTrans *transCPS2 = new TGeoCombiTrans(-coolPipeSuppL,
2741 -fgkLadderHeight/2.- tDY
2742 +coolPipeSuppH+fgkLadderBeamRadius,
2743 segmentLength/2., rotCPS2);
2745 TGeoCombiTrans *transCPS4 = new TGeoCombiTrans(-coolPipeSuppL,
2746 -fgkLadderHeight/2.- tDY
2747 +coolPipeSuppH+fgkLadderBeamRadius,
2748 segmentLength/2., rotCPS2);
2749 AddTranslationToCombiTrans(transCPS4, 0, 0, -segmentLength);
2751 virtualSeg->AddNode(fCoolPipeSupportL, 1, transCPS1);
2752 virtualSeg->AddNode(fCoolPipeSupportL, 2, transCPS2);
2753 virtualSeg->AddNode(fCoolPipeSupportR, 1, transCPS3);
2754 virtualSeg->AddNode(fCoolPipeSupportR, 2, transCPS4);
2757 //************************
2759 //************************
2760 TGeoTranslation *pipeTr1 = new TGeoTranslation(coolPipeSuppL,
2761 -fgkLadderHeight/2. - tDY +
2762 fgkLadderBeamRadius+coolPipeSuppH, 0);
2763 TGeoTranslation *pipeTr2 = new TGeoTranslation(-coolPipeSuppL,
2764 -fgkLadderHeight/2.- tDY +
2765 fgkLadderBeamRadius+coolPipeSuppH, 0);
2767 if (fAddCoolingSyst) {
2768 TGeoTube *coolingPipeShape = new TGeoTube( fgkCoolPipeInnerDiam/2,
2769 fgkCoolPipeOuterDiam/2,
2771 TGeoTube *coolerShape = new TGeoTube( 0, fgkCoolPipeInnerDiam/2,
2774 TGeoVolume *coolingPipe = new TGeoVolume("ITSsddCoolingPipe",
2775 coolingPipeShape, phynoxSDD );
2776 coolingPipe->SetLineColor(fColorPhynox);
2777 TGeoVolume *cooler = new TGeoVolume("ITSsddCoolingLiquid",coolerShape,
2781 virtualSeg->AddNode(coolingPipe, 1, pipeTr1);
2782 virtualSeg->AddNode(coolingPipe, 2, pipeTr2);
2784 virtualSeg->AddNode(cooler, 1, pipeTr1);
2785 virtualSeg->AddNode(cooler, 2, pipeTr2);
2789 //**********************************
2790 // Bases of hybrid thermal bridges
2791 //**********************************
2792 Double_t shiftHyb = 1.05; // shift between thermal Bridge base and thermal bridge
2793 // approx !!! not clear on 0752/14-A
2794 if (fAddCoolingSyst) {
2795 TGeoRotation rotHybrid1("", 0, 0, -90 - fgkHybridAngle);
2796 TGeoRotation rotHybrid2("", 0 ,180, 90 - fgkHybridAngle);
2797 TGeoCombiTrans *baseTr1 = new TGeoCombiTrans(*pipeTr2, rotHybrid1);
2798 TGeoCombiTrans *baseTr2 = new TGeoCombiTrans(*pipeTr1, rotHybrid2);
2800 virtualSeg->AddNode(fBaseThermalBridge, 1, baseTr1);
2801 virtualSeg->AddNode(fBaseThermalBridge, 2, baseTr2);
2804 //*************************
2806 //*************************
2807 Double_t hybDy = ((TGeoXtru*)fHybrid->GetShape())->GetY(2);
2808 Double_t distAxeToHybridCenter = fgkBTBaxisAtoBase+hybDy;
2810 Double_t hybrVolX = ( distAxeToHybridCenter*CosD(fgkHybridAngle)
2811 - shiftHyb*SinD(fgkHybridAngle) );
2812 Double_t hybrVolY = ( distAxeToHybridCenter*SinD(fgkHybridAngle)
2813 + shiftHyb*CosD(fgkHybridAngle) );
2815 TGeoRotation rotHybrid3("", 0, 0, 90. - fgkHybridAngle);
2816 TGeoRotation rotHybrid4("", 0 ,180, -90. - fgkHybridAngle);
2817 TGeoCombiTrans *hybTr1 = new TGeoCombiTrans(*pipeTr2, rotHybrid3);
2818 TGeoCombiTrans *hybTr2 = new TGeoCombiTrans(*pipeTr1, rotHybrid4);
2819 AddTranslationToCombiTrans( hybTr1, -hybrVolX, hybrVolY, 0);
2820 AddTranslationToCombiTrans( hybTr2, hybrVolX, hybrVolY, 0);
2822 virtualSeg->AddNode(fHybrid, 1, hybTr1);
2823 virtualSeg->AddNode(fHybrid, 2, hybTr2);
2830 // Starting from this segment
2831 Double_t hybDz = ((TGeoXtru*)fHybrid->GetShape())->GetZ(1);
2832 Double_t hybDx = ((TGeoXtru*)fHybrid->GetShape())->GetX(1);
2833 Double_t posDigitCableAlongHyb = shiftHyb+ hybDx
2834 - digitCableA->GetWidth()/2;
2835 Double_t distAxeToDigitCableCenter = distAxeToHybridCenter+hybDy
2836 - digitCableA->GetThickness()/2;
2838 Double_t digitCableX = ( coolPipeSuppL
2839 + distAxeToDigitCableCenter*CosD(fgkHybridAngle)
2840 - posDigitCableAlongHyb*SinD(fgkHybridAngle) );
2841 Double_t digitCableY = ( - fgkLadderHeight/2.-TMath::Abs(tDY)
2842 + fgkLadderBeamRadius+coolPipeSuppH
2843 + distAxeToDigitCableCenter*SinD(fgkHybridAngle)
2844 + posDigitCableAlongHyb*CosD(fgkHybridAngle) );
2847 Double_t digitCableCenterA0[3]={ -cableSideSign*digitCableX,
2848 digitCableY, cableSideSign*hybDz };
2849 Double_t digitCableCenterA1[3] = {
2850 -cableSideSign*(digitCableX+spaceForCables*CosD(fgkHybridAngle)),
2851 digitCableY+spaceForCables*SinD(fgkHybridAngle),
2852 cableSideSign*segmentLength/2 };
2854 Double_t digitCableCenterB0[3]={ cableSideSign*digitCableX,
2855 digitCableY,cableSideSign*hybDz};
2856 Double_t digitCableCenterB1[3]={
2857 cableSideSign*(digitCableX+spaceForCables*CosD(fgkHybridAngle)),
2858 digitCableY+spaceForCables*SinD(fgkHybridAngle),
2859 cableSideSign*segmentLength/2 };
2861 Double_t vZ[3] = {0,0,1};
2862 digitCableA[iSeg].AddCheckPoint( virtualSeg, 0, digitCableCenterA0, vZ);
2863 digitCableA[iSeg].AddCheckPoint( virtualSeg, 1, digitCableCenterA1, vZ);
2864 digitCableB[iSeg].AddCheckPoint( virtualSeg, 0, digitCableCenterB0, vZ);
2865 digitCableB[iSeg].AddCheckPoint( virtualSeg, 1, digitCableCenterB1, vZ);
2867 // Updating the other cables
2868 for (Int_t iCable=iUpdateCableMin; iCable<=iUpdateCableMax; iCable++) {
2870 Int_t iPoint = TMath::Abs(iCable-iSeg)+1;
2872 digitCableA[iCable].GetPoint( 1, coord);
2873 digitCableA[iCable].AddCheckPoint( virtualSeg, iPoint, coord, vZ);
2874 digitCableB[iCable].GetPoint( 1, coord);
2875 digitCableB[iCable].AddCheckPoint( virtualSeg, iPoint, coord, vZ);
2878 // Now the small Al foil on the same hybrid side
2879 Double_t xfoil[5],yfoil[5];
2881 xfoil[0] = -fgkHybridAlFoilWide/2;
2883 xfoil[1] = fgkHybridAlFoilWide/2;
2884 yfoil[1] = yfoil[0];
2885 xfoil[2] = xfoil[1];
2886 yfoil[2] = -hybDx + (fgkHybridAlFoilWide - fgkHybridAlFoilSide);
2887 xfoil[3] = xfoil[0] + fgkHybridAlFoilSide;
2889 xfoil[4] = xfoil[0];
2890 yfoil[4] = yfoil[3];
2892 TGeoXtru* alFoilSh = new TGeoXtru(2);
2893 alFoilSh->DefinePolygon(5, xfoil, yfoil);
2894 alFoilSh->DefineSection(0,-fgkHybridAlFoilThick/2);
2895 alFoilSh->DefineSection(1, fgkHybridAlFoilThick/2);
2897 TGeoVolume* alFoilVol = new TGeoVolume("ITSsddAlFoilHybSide", alFoilSh, alSDD);
2898 alFoilVol->SetLineColor(fColorAl);
2900 Double_t zFoilTrans = cableSideSign*(hybDz + alFoilSh->GetX(1));
2901 TGeoRotation rotFoil3;
2902 TGeoRotation rotFoil4;
2903 if (cableSideSign > 0) {
2904 rotFoil3 = TGeoRotation("", 90-fgkHybridAngle, -90, -90);
2905 rotFoil4 = TGeoRotation("",-90+fgkHybridAngle, 90, 90);
2907 rotFoil3 = TGeoRotation("", 90-fgkHybridAngle, 90, -90);
2908 rotFoil4 = TGeoRotation("",-90+fgkHybridAngle, -90, 90);
2910 TGeoCombiTrans *foiTr1 = new TGeoCombiTrans(*pipeTr2, rotFoil3);
2911 TGeoCombiTrans *foiTr2 = new TGeoCombiTrans(*pipeTr1, rotFoil4);
2912 AddTranslationToCombiTrans( foiTr1, -hybrVolX, hybrVolY, zFoilTrans);
2913 AddTranslationToCombiTrans( foiTr2, hybrVolX, hybrVolY, zFoilTrans);
2915 virtualSeg->AddNode(alFoilVol, 1, foiTr1);
2916 virtualSeg->AddNode(alFoilVol, 2, foiTr2);
2919 //**********************************
2920 if(GetDebug(1)) virtualSeg->CheckOverlaps(0.01);
2925 //________________________________________________________________________
2926 TGeoVolume* AliITSv11GeometrySDD::CreatePinSupport() {
2928 // Create a pine support and its pine
2929 // axis of rotation is the cone axis, center in its middle
2931 TGeoMedium *rytonSDD = GetMedium("RYTON$");
2933 TGeoCone *cone = new TGeoCone("ITSsddPinSuppCone",fgkPinSuppHeight/2.,
2934 0,fgkPinSuppRmax,0,fgkPinSuppRmax-
2935 fgkPinSuppHeight*TanD(fgkPinSuppConeAngle) );
2936 TGeoBBox *tong = new TGeoBBox("ITSsddPinSuppTong",fgkPinSuppRmax,
2937 fgkPinSuppLength/2.,fgkPinSuppThickness/2.);
2938 TGeoTube *hole = new TGeoTube("ITSsddPinSuppHole",0,fgkPinR,
2939 fgkPinSuppHeight/2.+0.00001);
2940 // 0.00001 is for seing the actual hole (avoid viewer artefact)
2942 if(GetDebug(3)){// Remove compiler warning.
2943 cone->InspectShape();
2944 tong->InspectShape();
2945 hole->InspectShape();
2948 TGeoTranslation *tongTrans = new TGeoTranslation("ITSsddPinSuppTongTr",0,
2949 fgkPinSuppLength/2.,-fgkPinSuppHeight/2.+fgkPinSuppThickness/2.);
2950 tongTrans->RegisterYourself();
2951 TGeoCompositeShape *pinSupportShape = new TGeoCompositeShape(
2952 "ITSsddPinSupportShape","(ITSsddPinSuppCone+"
2953 "ITSsddPinSuppTong:ITSsddPinSuppTongTr)-ITSsddPinSuppHole");
2955 TGeoVolume *pinSupport = new TGeoVolume("ITSsddPinSupport", pinSupportShape,
2957 pinSupport->SetLineColor(fColorRyton);
2963 //________________________________________________________________________
2964 TGeoVolume* AliITSv11GeometrySDD::CreateCoolPipeSupportL() {
2966 // Create half of the cooling pipe support (ALR-0752/3)
2969 Double_t diffX = fgkCoolPipeSuppHeight*TanD(fgkCoolPipeSuppAngle);
2971 TGeoArb8 *side1 = new TGeoArb8(fgkCoolPipeSuppHeight/2.);
2972 side1->SetName("ITSsddCPSside1");
2973 side1->SetVertex( 0, 0, -fgkCoolPipeSuppWidthExt/2.);
2974 side1->SetVertex( 1, 0, fgkCoolPipeSuppWidthExt/2.);
2975 side1->SetVertex( 2, fgkCoolPipeSuppMaxLength/2.-diffX,
2976 fgkCoolPipeSuppWidthExt/2.);
2977 side1->SetVertex( 3, fgkCoolPipeSuppMaxLength/2.-diffX,
2978 -fgkCoolPipeSuppWidthExt/2.);
2979 side1->SetVertex( 4, 0, -fgkCoolPipeSuppWidthExt/2.);
2980 side1->SetVertex( 5, 0, fgkCoolPipeSuppWidthExt/2.);
2981 side1->SetVertex( 6, fgkCoolPipeSuppMaxLength/2.,
2982 fgkCoolPipeSuppWidthExt/2.);
2983 side1->SetVertex( 7, fgkCoolPipeSuppMaxLength/2.,
2984 -fgkCoolPipeSuppWidthExt/2.);
2986 TGeoTranslation *side1Tr = new TGeoTranslation("ITSsddCPStr1",0,
2987 - fgkCoolPipeSuppAxeDist
2988 + fgkCoolPipeSuppWidthExt/2., 0);
2989 side1Tr->RegisterYourself();
2990 TGeoTranslation *side2Tr = new TGeoTranslation("ITSsddCPStr2",0,
2991 - fgkCoolPipeSuppAxeDist
2992 + fgkCoolPipeSuppWidthExt*3/2.
2993 + fgkCoolPipeSuppWidthIn,0);
2994 side2Tr->RegisterYourself();
2996 TGeoBBox *middle = new TGeoBBox("ITSsddCPSmiddle",
2997 (fgkCoolPipeSuppMaxLength/2.-fgkCoolPipeSuppSlitL)/2.,
2998 fgkCoolPipeSuppWidthIn/2., fgkCoolPipeSuppHeight/2.);
2999 TGeoTranslation *middleTr =
3000 new TGeoTranslation("ITSsddCPStr3",
3001 (fgkCoolPipeSuppMaxLength/2.-fgkCoolPipeSuppSlitL)/2.,
3002 -fgkCoolPipeSuppAxeDist+fgkCoolPipeSuppWidthExt
3003 +fgkCoolPipeSuppWidthIn/2., 0);
3004 middleTr->RegisterYourself();
3006 TGeoBBox *axeBox = new TGeoBBox("ITSsddCPSaxeBox",
3007 fgkCoolPipeSuppTongW/4.,
3008 (fgkCoolPipeSuppFulWidth
3009 - 2*fgkCoolPipeSuppWidthExt
3010 - fgkCoolPipeSuppWidthIn)/2,
3011 fgkCoolPipeSuppHeight/2.);
3013 TGeoTranslation *axeBoxTr = new TGeoTranslation("ITSsddCPSAxBoxTr",
3014 fgkCoolPipeSuppTongW/4.,
3015 - fgkCoolPipeSuppAxeDist
3016 + fgkCoolPipeSuppFulWidth
3017 - axeBox->GetDY(), 0);
3018 axeBoxTr->RegisterYourself();
3020 TGeoTube *axe = new TGeoTube("ITSsddCPSaxe",0,fgkCoolPipeSuppHoleDiam/2.,
3021 fgkCoolPipeSuppTongW/4.);
3023 TGeoRotation *axeRot = new TGeoRotation("ITSsddCPSaxeRot",90,90,0);
3024 TGeoCombiTrans *axeTrans = new TGeoCombiTrans("ITSsddCPSaxeTr",
3025 fgkCoolPipeSuppTongW/4.,0,0,axeRot);
3026 axeTrans->RegisterYourself();
3027 //delete axeRot; // make the code crash, no idea of why !!!
3030 middle->InspectShape();
3031 axe->InspectShape();
3034 TGeoMedium *rytonSDD = GetMedium("RYTON$");
3036 TGeoCompositeShape *coolPipeSuppShape = new TGeoCompositeShape(
3037 "ITSsddCoolPipeSuppShapeL",
3038 "ITSsddCPSmiddle:ITSsddCPStr3"
3039 "+ITSsddCPSside1:ITSsddCPStr1"
3040 "+ITSsddCPSside1:ITSsddCPStr2"
3041 "+ITSsddCPSaxeBox:ITSsddCPSAxBoxTr"
3042 "-ITSsddCPSaxe:ITSsddCPSaxeTr");
3043 TGeoVolume *coolPipeSupp = new TGeoVolume("ITSsddCoolPipeSupportL",
3044 coolPipeSuppShape, rytonSDD);
3046 coolPipeSupp->SetLineColor(fColorRyton);
3048 return coolPipeSupp;
3052 //________________________________________________________________________
3053 TGeoVolume* AliITSv11GeometrySDD::CreateCoolPipeSupportR() {
3055 //Create half of the cooling pipe support (ALR-0752/3)
3058 Double_t diffX = fgkCoolPipeSuppHeight*TanD(fgkCoolPipeSuppAngle);
3060 TGeoArb8 *side1 = new TGeoArb8(fgkCoolPipeSuppHeight/2.);
3061 side1->SetName("ITSsddCPSside1R");
3062 side1->SetVertex( 0, 0, -fgkCoolPipeSuppWidthExt/2.);
3063 side1->SetVertex( 1, -(fgkCoolPipeSuppMaxLength/2.-diffX),
3064 -fgkCoolPipeSuppWidthExt/2.);
3065 side1->SetVertex( 2, -(fgkCoolPipeSuppMaxLength/2.-diffX),
3066 fgkCoolPipeSuppWidthExt/2.);
3067 side1->SetVertex( 3, 0, fgkCoolPipeSuppWidthExt/2.);
3068 side1->SetVertex( 4, 0, -fgkCoolPipeSuppWidthExt/2.);
3069 side1->SetVertex( 5, -fgkCoolPipeSuppMaxLength/2.,
3070 -fgkCoolPipeSuppWidthExt/2.);
3071 side1->SetVertex( 6, -fgkCoolPipeSuppMaxLength/2.,
3072 fgkCoolPipeSuppWidthExt/2.);
3073 side1->SetVertex( 7, 0, fgkCoolPipeSuppWidthExt/2.);
3075 TGeoTranslation *side1Tr = new TGeoTranslation("ITSsddCPStr1R",0,
3076 - fgkCoolPipeSuppAxeDist
3077 + fgkCoolPipeSuppWidthExt/2., 0);
3078 side1Tr->RegisterYourself();
3079 TGeoTranslation *side2Tr = new TGeoTranslation("ITSsddCPStr2R",0,
3080 - fgkCoolPipeSuppAxeDist
3081 + fgkCoolPipeSuppWidthExt*3/2.
3082 + fgkCoolPipeSuppWidthIn, 0);
3083 side2Tr->RegisterYourself();
3085 TGeoBBox *middle = new TGeoBBox("ITSsddCPSmiddleR",
3086 (fgkCoolPipeSuppMaxLength/2.
3087 - fgkCoolPipeSuppSlitL)/2.,
3088 fgkCoolPipeSuppWidthIn/2.,
3089 fgkCoolPipeSuppHeight/2.);
3090 TGeoTranslation *middleTr =
3091 new TGeoTranslation("ITSsddCPStr3R",
3092 -( fgkCoolPipeSuppMaxLength/2.
3093 -fgkCoolPipeSuppSlitL)/2.,
3094 -fgkCoolPipeSuppAxeDist + fgkCoolPipeSuppWidthExt
3095 + fgkCoolPipeSuppWidthIn/2.,0);
3096 middleTr->RegisterYourself();
3098 TGeoBBox *axeBox = new TGeoBBox("ITSsddCPSaxeBoxR",
3099 fgkCoolPipeSuppTongW/4.,
3100 (fgkCoolPipeSuppFulWidth
3101 - 2*fgkCoolPipeSuppWidthExt
3102 - fgkCoolPipeSuppWidthIn)/2,
3103 fgkCoolPipeSuppHeight/2.);
3105 TGeoTranslation *axeBoxTr = new TGeoTranslation("ITSsddCPSAxBoxTrR",
3106 - fgkCoolPipeSuppTongW/4.,
3107 - fgkCoolPipeSuppAxeDist
3108 + fgkCoolPipeSuppFulWidth
3109 - axeBox->GetDY(),0);
3110 axeBoxTr->RegisterYourself();
3112 TGeoTube *axe = new TGeoTube("ITSsddCPSaxeR",0,fgkCoolPipeSuppHoleDiam/2.,
3113 fgkCoolPipeSuppTongW/4.);
3115 TGeoRotation *axeRot = new TGeoRotation("ITSsddCPSaxeRotR",90,90,0);
3116 TGeoCombiTrans *axeTrans = new TGeoCombiTrans("ITSsddCPSaxeTrR",
3117 -fgkCoolPipeSuppTongW/4.,0,0,axeRot);
3118 axeTrans->RegisterYourself();
3122 middle->InspectShape();
3123 axe->InspectShape();
3126 TGeoCompositeShape *coolPipeSuppShape = new TGeoCompositeShape(
3127 "ITSsddCoolPipeSuppShapeR",
3128 "ITSsddCPSmiddleR:ITSsddCPStr3R"
3129 "+ITSsddCPSside1R:ITSsddCPStr1R"
3130 "+ITSsddCPSside1R:ITSsddCPStr2R"
3131 "+ITSsddCPSaxeBoxR:ITSsddCPSAxBoxTrR"
3132 "-ITSsddCPSaxeR:ITSsddCPSaxeTrR");
3134 TGeoMedium *rytonSDD = GetMedium("RYTON$");
3135 TGeoVolume *coolPipeSupp = new TGeoVolume( "ITSsddCoolPipeSupportR",
3136 coolPipeSuppShape, rytonSDD);
3137 coolPipeSupp->SetLineColor(fColorRyton);
3139 return coolPipeSupp;
3142 //________________________________________________________________________
3143 TGeoVolume* AliITSv11GeometrySDD::CreateBaseThermalBridge() {
3145 // based on ALR 0752/8
3148 Double_t dy = fgkBTBaxisAtoBase - fgkRadiusBminBTB - fgkBTBthick;
3150 Double_t base1width = fgkBTBwidth - fgkBTBaxisAtoBottom - fgkRadiusBminBTB
3151 - (fgkRadiusAminBTB+fgkBTBthick);
3152 TGeoBBox *base1 = new TGeoBBox( "ITSsddBTBbase1", base1width/2.,
3153 fgkBTBthick/2., fgkBTBlength/2.);
3154 TGeoTranslation *base1Tr = new TGeoTranslation("ITSsddBTBtr1",
3155 fgkBTBaxisAtoBottom-fgkBTBwidth+base1width/2.,
3156 -(fgkBTBaxisAtoBase-fgkBTBthick/2.), 0);
3157 base1Tr->RegisterYourself();
3159 Double_t base2width = fgkBTBaxisAtoBottom - fgkRadiusAminBTB - fgkBTBthick
3161 TGeoBBox *base2 = new TGeoBBox( "ITSsddBTBbase2", base2width/2.,
3162 fgkBTBthick/2., fgkBTBlength/2.);
3163 TGeoTranslation *base2Tr = new TGeoTranslation("ITSsddBTBtr2",
3164 fgkBTBaxisAtoBottom - base2width/2.,
3165 -(fgkBTBaxisAtoBase-fgkBTBthick/2.), 0);
3166 base2Tr->RegisterYourself();
3168 TGeoBBox *side = new TGeoBBox( "ITSsddBTBside",
3169 fgkBTBthick/2., dy/2., fgkBTBlength/2.);
3170 TGeoTranslation *sideTr1 = new TGeoTranslation("ITSsddBTBsideTr1",
3171 -fgkRadiusAminBTB-fgkBTBthick/2., -dy/2., 0);
3172 TGeoTranslation *sideTr2 = new TGeoTranslation("ITSsddBTBsideTr2",
3173 fgkRadiusAminBTB+fgkBTBthick/2., -dy/2., 0);
3174 sideTr1->RegisterYourself();
3175 sideTr2->RegisterYourself();
3177 TGeoBBox *hole = new TGeoBBox( "ITSsddBTBhole", fgkBTBHolewidth/2.,
3178 fgkBTBthick/2., fgkBTBHoleLength/2.);
3179 TGeoTranslation *holeTr1 = new TGeoTranslation("ITSsddBTBholeTr1",
3180 - fgkBTBHoleRefX + fgkBTBHolewidth/2.,
3181 - (fgkBTBaxisAtoBase-fgkBTBthick/2.),
3182 fgkBTBHoleRefY+(fgkBTBHoleLength-fgkBTBlength)/2.);
3183 TGeoTranslation *holeTr2 = new TGeoTranslation("ITSsddBTBholeTr2",
3184 - fgkBTBHoleRefX + fgkBTBHolewidth/2.,
3185 - (fgkBTBaxisAtoBase-fgkBTBthick/2.),
3186 - fgkBTBHoleRefY-(fgkBTBHoleLength-fgkBTBlength)/2.);
3187 holeTr1->RegisterYourself();
3188 holeTr2->RegisterYourself();
3190 Double_t radiusAmaxBTB = fgkRadiusAminBTB + fgkBTBthick;
3191 TGeoTubeSeg *mainAxis = new TGeoTubeSeg( "ITSsddBTBmainAxis",
3192 fgkRadiusAminBTB, radiusAmaxBTB,
3193 fgkBTBlength/2., 0., 180.);
3194 TGeoTubeSeg *round1 = new TGeoTubeSeg( "ITSsddBTBround1",
3195 fgkRadiusBminBTB, fgkRadiusBminBTB+fgkBTBthick,
3196 fgkBTBlength/2., 270., 360.);
3197 TGeoTranslation *roundTr1 = new TGeoTranslation("ITSsddBTBround1Tr",
3198 -(fgkRadiusAminBTB+fgkBTBthick+fgkRadiusBminBTB),
3200 roundTr1->RegisterYourself();
3202 TGeoTubeSeg *round2 = new TGeoTubeSeg( "ITSsddBTBround2",
3203 fgkRadiusBminBTB, fgkRadiusBminBTB+fgkBTBthick,
3204 fgkBTBlength/2., 180., 270.);
3205 TGeoTranslation *roundTr2 = new TGeoTranslation("ITSsddBTBround2Tr",
3206 (fgkRadiusAminBTB+fgkBTBthick+fgkRadiusBminBTB),
3208 roundTr2->RegisterYourself();
3210 TGeoCompositeShape *sBaseThermalBridge = new TGeoCompositeShape(
3211 "ITSsddBaseThermalBridgeShape",
3212 "ITSsddBTBbase1:ITSsddBTBtr1"
3213 "+ ITSsddBTBbase2:ITSsddBTBtr2"
3214 "+ ITSsddBTBround1:ITSsddBTBround1Tr"
3215 "+ ITSsddBTBround2:ITSsddBTBround2Tr"
3216 "+ ITSsddBTBside:ITSsddBTBsideTr1"
3217 "+ ITSsddBTBside:ITSsddBTBsideTr2"
3218 "- ITSsddBTBhole:ITSsddBTBholeTr1"
3219 "- ITSsddBTBhole:ITSsddBTBholeTr2"
3220 "+ ITSsddBTBmainAxis");
3222 if(GetDebug(3)){// Remove compiler warning.
3223 base1->InspectShape();
3224 base2->InspectShape();
3225 side->InspectShape();
3226 hole->InspectShape();
3227 mainAxis->InspectShape();
3228 round1->InspectShape();
3229 round2->InspectShape();
3232 TGeoMedium *carbonFiberLadderStruct = GetMedium("SDD C AL (M55J)$");
3233 TGeoVolume *vBaseThermalBridge = new TGeoVolume( "ITSsddBaseThermalBridge",
3235 carbonFiberLadderStruct);
3237 vBaseThermalBridge->SetLineColor(fColorCarbonFiber);
3238 return vBaseThermalBridge;
3242 //________________________________________________________________________
3243 TGeoVolumeAssembly* AliITSv11GeometrySDD::CreateEndLadder(Int_t iLay) {
3245 // Return an assembly containing a end of a CF ladder.
3248 TGeoMedium *carbonFiberLadderStruct = GetMedium("SDD C AL (M55J)$"); // ITSsddCarbonM55J
3249 TGeoMedium *stesalite = GetMedium("G10FR4$");
3250 TGeoMedium *phynoxSDD = GetMedium("INOX$");
3251 TGeoMedium *coolerMediumSDD = GetMedium("WATER$");
3253 Double_t length = (fgkLay3LadderLength-fgkLay3Ndet*fgkSegmentLength)/2.;
3254 Double_t coolPipeSuppH = fgkLay3CoolPipeSuppH;
3255 Double_t underSegDH = fLay3LadderUnderSegDH;
3256 Double_t footDZ = fgkRubyZladd3 - fgkLay3Ndet*fgkSegmentLength/2 - length/2;
3257 // footDZ is also where to place the ruby's center in local Z
3258 Double_t coolPipeEndLen = (fgkCoolPipeLay3Len-fgkSegmentLength*fgkLay3Ndet)/2;
3261 } else if (iLay==4) {
3262 length = (fgkLay4LadderLength-fgkLay4Ndet*fgkSegmentLength)/2.;
3263 coolPipeSuppH = fgkLay4CoolPipeSuppH;
3264 underSegDH = fLay4LadderUnderSegDH;
3265 footDZ = fgkRubyZladd4 - fgkLay4Ndet*fgkSegmentLength/2 - length/2;
3266 coolPipeEndLen = (fgkCoolPipeLay4Len-fgkSegmentLength*fgkLay4Ndet)/2;
3268 printf("error in AliITSv11GeometrySDD::CreateEndLadder: Wrong layer");
3272 Double_t tDY = (- fgkLadderSegBoxDH/2 //space left on top of the ladder
3273 + underSegDH/2); //space under ladder segment
3274 // here tDY is not the same as for the segment because the end ladder
3275 // does not have a space under it, inside the general ladder volume.
3276 Double_t segmentLength = fgkSegmentLength;
3277 Double_t topCornerLength = fgkSegmentLength/2.-fgkLay4LaddTopCornerEnd;
3279 TGeoVolumeAssembly *virtualEnd = new TGeoVolumeAssembly("ITSsddEnd");
3281 //**********************************
3282 // coding real matter :
3283 //**********************************
3284 Double_t triangleHeight = fgkLadderHeight - fgkLadderBeamRadius;
3285 Double_t halfTheta = TMath::ATan( 0.5*fgkLadderWidth/triangleHeight );
3286 Double_t beta = (TMath::Pi()-2.*halfTheta)/4.;
3287 Double_t alpha = TMath::Pi()*3./4. - halfTheta/2.;
3289 //--- The 3 V shape corners of the Carbon Fiber Ladder
3291 TGeoArb8 *cfLaddTop1 = CreateLadderSide("CFladdTopCornerV1shape",
3292 topCornerLength/2., halfTheta, -1,
3293 fgkLadderLa, fgkLadderHa, fgkLadderl);
3294 TGeoVolume *cfLaddTopVol1 = new TGeoVolume("ITSsddCFladdTopCornerV1",
3295 cfLaddTop1,carbonFiberLadderStruct);
3296 cfLaddTopVol1->SetLineColor(fColorCarbonFiber);
3297 TGeoArb8 *cfLaddTop2 = CreateLadderSide( "CFladdTopCornerV2shape",
3298 topCornerLength/2., halfTheta, 1,
3299 fgkLadderLa, fgkLadderHa, fgkLadderl);
3300 TGeoVolume *cfLaddTopVol2 = new TGeoVolume("ITSsddCFladdTopCornerV2",
3301 cfLaddTop2,carbonFiberLadderStruct);
3302 cfLaddTopVol2->SetLineColor(fColorCarbonFiber);
3303 TGeoTranslation *trTop1 = new TGeoTranslation(0, fgkLadderHeight/2+tDY,
3304 -(length-topCornerLength)/2.);
3305 virtualEnd->AddNode(cfLaddTopVol1, 1, trTop1);
3306 virtualEnd->AddNode(cfLaddTopVol2, 1, trTop1);
3309 TGeoArb8 *cfLaddSide1 = CreateLadderSide( "CFladdSideCornerV1shape",
3310 length/2., beta, -1,
3311 fgkLadderLb, fgkLadderHb, fgkLadderl);
3312 TGeoVolume *cfLaddSideVol1 = new TGeoVolume("ITSsddCFladdSideCornerV1",
3313 cfLaddSide1,carbonFiberLadderStruct);
3314 cfLaddSideVol1->SetLineColor(fColorCarbonFiber);
3315 TGeoArb8 *cfLaddSide2 = CreateLadderSide( "CFladdSideCornerV2shape",
3317 fgkLadderLb, fgkLadderHb, fgkLadderl);
3318 TGeoVolume *cfLaddSideVol2 = new TGeoVolume("ITSsddCFladdSideCornerV2",
3319 cfLaddSide2,carbonFiberLadderStruct);
3320 cfLaddSideVol2->SetLineColor(fColorCarbonFiber);
3321 Double_t dYTranslation = ( fgkLadderHeight/2. - 0.5*fgkLadderWidth*
3322 TMath::Tan(beta) - fgkLadderBeamRadius );
3324 // because center of the triangle doesn't correspond to virtual vol. center
3325 Double_t distCenterSideDown = 0.5*fgkLadderWidth/TMath::Cos(beta);
3326 TGeoCombiTrans *ctSideR = CreateCombiTrans("", distCenterSideDown, 0,
3327 alpha*TMath::RadToDeg());
3328 AddTranslationToCombiTrans(ctSideR, 0, -dYTranslation+tDY, 0);
3329 TGeoCombiTrans *ctSideL = CreateCombiTrans("", distCenterSideDown, 0,
3330 -alpha*TMath::RadToDeg());
3331 AddTranslationToCombiTrans(ctSideL, 0, -dYTranslation+tDY, 0);
3332 virtualEnd->AddNode(cfLaddSideVol1, 1, ctSideR);
3333 virtualEnd->AddNode(cfLaddSideVol2, 1, ctSideR);
3334 virtualEnd->AddNode(cfLaddSideVol1, 2, ctSideL);
3335 virtualEnd->AddNode(cfLaddSideVol2, 2, ctSideL);
3338 // Beams on the sides
3339 Double_t beamPhiPrime = TMath::ASin(1./TMath::Sqrt( (1+TMath::Sin(2*beta)*
3340 TMath::Sin(2*beta)/(TanD(fgkBeamSidePhi)*TanD(fgkBeamSidePhi))) ));
3342 //Euler rotation : about Z, then new X, then new Z
3343 TGeoRotation *beamRot1 = new TGeoRotation("", 90-2.*beta*TMath::RadToDeg(),
3344 -beamPhiPrime*TMath::RadToDeg(), -90);
3345 TGeoRotation *beamRot2 = new TGeoRotation("", 90-2.*beta*TMath::RadToDeg(),
3346 beamPhiPrime*TMath::RadToDeg(), -90);
3347 TGeoRotation *beamRot3 = new TGeoRotation("", 90+2.*beta*TMath::RadToDeg(),
3348 beamPhiPrime*TMath::RadToDeg(), -90);
3349 TGeoRotation *beamRot4 = new TGeoRotation("", 90+2.*beta*TMath::RadToDeg(),
3350 -beamPhiPrime*TMath::RadToDeg(), -90);
3351 TGeoCombiTrans *beamTransf1 = new TGeoCombiTrans(0.5*triangleHeight*
3352 TMath::Tan(halfTheta),
3353 fgkLadderBeamRadius/2. + tDY,
3354 -length/2 + segmentLength/8, beamRot1);
3355 TGeoCombiTrans *beamTransf3 = new TGeoCombiTrans( 0.5*triangleHeight*
3356 TMath::Tan(halfTheta),
3357 fgkLadderBeamRadius/2.+tDY,
3358 -length/2 + 3*segmentLength/8, beamRot2);
3359 TGeoCombiTrans *beamTransf5 = new TGeoCombiTrans(-0.5*triangleHeight*
3360 TMath::Tan(halfTheta),
3361 fgkLadderBeamRadius/2.+tDY,
3362 -length/2 + segmentLength/8, beamRot3);
3363 TGeoCombiTrans *beamTransf7 = new TGeoCombiTrans(-0.5*triangleHeight*
3364 TMath::Tan(halfTheta),
3365 fgkLadderBeamRadius/2. + tDY,
3366 -length/2+3*segmentLength/8, beamRot4);
3368 virtualEnd->AddNode(fLaddSegCommonVol[6], 1, beamTransf1);
3369 virtualEnd->AddNode(fLaddSegCommonVol[6], 2, beamTransf3);
3370 virtualEnd->AddNode(fLaddSegCommonVol[6], 3, beamTransf5);
3371 virtualEnd->AddNode(fLaddSegCommonVol[6], 4, beamTransf7);
3373 //--- Beams of the bottom
3374 TGeoRotation *bottomBeamRot1 = new TGeoRotation("",90, 90, 90);
3376 /* Not there actually
3377 TGeoTubeSeg *bottomBeam1 = new TGeoTubeSeg(0, fgkLadderBeamRadius,
3378 fgkLadderWidth/2.-fgkLadderLb/3, 0, 180);
3379 TGeoVolume *bottomBeam1Vol = new TGeoVolume("ITSsddBottomBeam1Vol",
3380 bottomBeam1, carbonFiberLadderStruct);
3381 bottomBeam1Vol->SetLineColor(fColorCarbonFiber);
3383 TGeoCombiTrans *bottomBeamTransf1 = new TGeoCombiTrans(0,
3384 -(fgkLadderHeight/2-fgkLadderBeamRadius)+tDY,
3385 -length/2+fgkSegmentLength/2, bottomBeamRot1);
3386 virtualEnd->AddNode(bottomBeam1Vol, 1, bottomBeamTransf1);
3388 TGeoTubeSeg *bottomBeam2 = new TGeoTubeSeg(0, fgkLadderBeamRadius,
3389 fgkLadderWidth/2.-fgkLadderLb/3, 0, 90);
3390 TGeoVolume *bottomBeam2Vol = new TGeoVolume("ITSsddBottomBeam2Vol",
3391 bottomBeam2, carbonFiberLadderStruct);
3392 bottomBeam2Vol->SetLineColor(fColorCarbonFiber);
3393 TGeoCombiTrans *bottomBeamTransf2 = new TGeoCombiTrans(0,
3394 -(fgkLadderHeight/2-fgkLadderBeamRadius)+tDY,-length/2,bottomBeamRot1);
3395 virtualEnd->AddNode(bottomBeam2Vol, 1, bottomBeamTransf2);
3397 //**********************************
3398 //the cooling pipe supports
3399 Double_t triangleCPaxeDist = fgkCoolPipeSuppAxeDist-fgkCoolPipeSuppWidthExt-
3400 fgkCoolPipeSuppWidthIn+fgkLadderBeamRadius;
3402 Double_t coolPipeSuppL = TMath::Tan(halfTheta)*
3403 (triangleHeight+triangleCPaxeDist/
3404 TMath::Sin(halfTheta)-coolPipeSuppH);
3406 if (fAddCoolingSyst) {
3407 TGeoRotation *rotCPS2 = new TGeoRotation("",-halfTheta*TMath::RadToDeg(),-90, 90);
3408 TGeoRotation *rotCPS1 = new TGeoRotation("", halfTheta*TMath::RadToDeg(),-90,-90);
3409 TGeoCombiTrans *transCPS1 = new TGeoCombiTrans(coolPipeSuppL,
3410 -fgkLadderHeight/2.+ tDY +
3411 coolPipeSuppH+fgkLadderBeamRadius,
3412 -length/2., rotCPS1);
3413 TGeoCombiTrans *transCPS4 = new TGeoCombiTrans(-coolPipeSuppL,
3414 -fgkLadderHeight/2.+ tDY +
3415 coolPipeSuppH+fgkLadderBeamRadius,
3416 -length/2., rotCPS2);
3418 virtualEnd->AddNode(fCoolPipeSupportL, 1, transCPS1);
3419 virtualEnd->AddNode(fCoolPipeSupportR, 1, transCPS4);
3422 //**********************************
3423 //--- The stesalite foot of the ladder
3425 Double_t footDY = -(fgkLadderHeight/2-fgkLadderBeamRadius)+tDY
3426 - fgkLadFootY/2+fgkLadFingerPrintY;
3428 TGeoTranslation *footTr = new TGeoTranslation("SDDfootTr",0,footDY,footDZ);
3429 virtualEnd->AddNode(fLadderFoot, 1, footTr);
3431 //=====================================
3434 if (fAddCoolingSyst) {
3436 TGeoTranslation *pipeTr1 = new TGeoTranslation(coolPipeSuppL,
3437 -fgkLadderHeight/2.+ tDY +
3438 coolPipeSuppH + fgkLadderBeamRadius,
3439 -length/2.+coolPipeEndLen/2.);
3440 TGeoTranslation *pipeTr2 = new TGeoTranslation(-coolPipeSuppL,
3441 -fgkLadderHeight/2. + tDY +
3442 fgkLadderBeamRadius + coolPipeSuppH,
3443 -length/2.+coolPipeEndLen/2.);
3445 TGeoTube *coolingPipeShape = new TGeoTube( fgkCoolPipeInnerDiam/2,
3446 fgkCoolPipeOuterDiam/2,
3448 TGeoTube *coolerShape = new TGeoTube( 0, fgkCoolPipeInnerDiam/2,
3451 TGeoVolume *coolingPipe = new TGeoVolume("ITSsddCoolingPipeEnd",
3452 coolingPipeShape, phynoxSDD );
3453 coolingPipe->SetLineColor(fColorPhynox);
3454 TGeoVolume *cooler = new TGeoVolume("ITSsddCoolingEndLiquid",coolerShape,
3457 virtualEnd->AddNode(coolingPipe, 1, pipeTr1);
3458 virtualEnd->AddNode(coolingPipe, 2, pipeTr2);
3460 virtualEnd->AddNode(cooler, 1, pipeTr1);
3461 virtualEnd->AddNode(cooler, 2, pipeTr2);
3465 //=====================================
3466 //--- HV cable guide
3469 TGeoBBox* guideHVbox = new TGeoBBox("guideHVbox",fgkHVguideX1/2,
3470 fgkHVguideY1/2,fgkHVguideZ1/2);
3471 TGeoVolume *guideHV = new TGeoVolume("guideHV",guideHVbox,stesalite);
3473 TGeoTranslation* guideHVtr = new TGeoTranslation(fgkHVguideDX,
3474 -(fgkLadderHeight/2-fgkLadderBeamRadius)+tDY-fgkHVguideY1/2,
3475 footDZ+fgkLadFootZ/2+fgkHVguideZ1/2-(fgkHVguideSuppFullZ-fgkHVguideZ2));
3476 virtualEnd->AddNode(guideHV, 1, guideHVtr);
3478 //=====================================
3480 Double_t raccordFullLen = fgkConnectorCoolTubeL1+fgkConnectorCoolTubeL2+fgkConnectorCoolTubeL3;
3481 TGeoTranslation *trRaccordo1 = new TGeoTranslation("trRaccordo1",-coolPipeSuppL,
3482 -fgkLadderHeight/2.+ tDY +
3483 coolPipeSuppH+fgkLadderBeamRadius,
3484 -length/2.+coolPipeEndLen+raccordFullLen/2);
3485 TGeoTranslation *trRaccordo2 = new TGeoTranslation("trRaccordo2", coolPipeSuppL,
3486 -fgkLadderHeight/2.+ tDY +
3487 coolPipeSuppH+fgkLadderBeamRadius,
3488 -length/2.+coolPipeEndLen+raccordFullLen/2);
3490 virtualEnd->AddNode(fRaccordoL, 1, trRaccordo1);
3491 virtualEnd->AddNode(fRaccordoL, 2, trRaccordo2);
3493 if(GetDebug(1)) virtualEnd->CheckOverlaps(0.01);
3498 //________________________________________________________________________
3499 TGeoVolumeAssembly* AliITSv11GeometrySDD::CreateLadderFoot() {
3501 //--- The stesalite foot of the ladder
3503 // The 2 screw holes on the left part
3504 // the small holes at each corner of the ruby cage (diam 2mm)
3505 // the really small level difference of 0.3mm on the bottom
3508 TGeoMedium *stesalite = GetMedium("G10FR4$");
3510 TGeoVolumeAssembly *virtualFoot = new TGeoVolumeAssembly("ITSsddFoot");
3512 Double_t epsilon = 2e-10;
3513 TGeoBBox *ladFootBox1 = new TGeoBBox("ladFootBox1",fgkLadBox1X/2, fgkLadFootY/2,
3515 TGeoTranslation *ladFootBox1Tr = new TGeoTranslation("ladFootBox1Tr",
3516 fgkLadFootX/2-fgkLadBox1X/2,0,0);
3517 TGeoBBox *ladFingerPrint = new TGeoBBox("ladFingerPrint",fgkLadFingerPrintX/2,
3518 fgkLadFingerPrintY/2+epsilon, fgkLadFootZ/2+epsilon);
3520 TGeoTranslation *ladFingerPrintTr = new TGeoTranslation("ladFingerPrintTr",
3521 fgkLadFootX/2-fgkLadFingerPrintBorder-fgkLadFingerPrintX/2,
3522 fgkLadFootY/2-fgkLadFingerPrintY/2+epsilon,
3525 TGeoBBox *rubyCageHole = new TGeoBBox("rubyCageHole",fgkRubyCageHoleX/2,
3526 fgkRubyCageHoleY/2+epsilon, fgkRubyCageHoleZ/2);
3528 TGeoTranslation *rubyCageHoleTr = new TGeoTranslation("rubyCageHoleTr",
3529 fgkLadFootX/2-(fgkLadFootX/2-fgkRubyDX)+fgkRubyCageAxisShift,
3530 fgkLadFootY/2-fgkRubyCageHoleY/2,0);
3532 double rubyScrewHoleLen = fgkLadFootX/2-fgkRubyDX;
3533 TGeoTube *rubyScrewHole = new TGeoTube("rubyScrewHole", 0,fgkScrewM4diam/2,
3534 rubyScrewHoleLen/2);
3536 TGeoRotation *rot9090 = new TGeoRotation("",90,90,0);
3537 TGeoCombiTrans *rubyScrewHoleTr = new TGeoCombiTrans("rubyScrewHoleTr",
3538 fgkLadFootX/2-rubyScrewHoleLen/2,
3539 -fgkRubyScrewShiftToCenterY, 0, rot9090);
3541 Double_t rubyHoleLen = fgkLadFootY-fgkRubyCageHoleY;
3542 TGeoTube *rubyHole = new TGeoTube("rubyHole", 0,fgkRubyHoleDiam/2,
3545 TGeoRotation *rot90 = new TGeoRotation("",0,90,0);
3546 TGeoCombiTrans *rubyHoleTr = new TGeoCombiTrans("rubyHoleTr", fgkRubyDX,
3547 -(fgkLadFootY-rubyHoleLen)/2, 0, rot90);
3549 ladFootBox1Tr->RegisterYourself();
3550 ladFingerPrintTr->RegisterYourself();
3551 rubyCageHoleTr->RegisterYourself();
3552 rubyScrewHoleTr->RegisterYourself();
3553 rubyHoleTr->RegisterYourself();
3555 TGeoCompositeShape *footRightPart = new TGeoCompositeShape(
3556 "ladFootBox1:ladFootBox1Tr-(ladFingerPrint:ladFingerPrintTr"
3557 "+rubyCageHole:rubyCageHoleTr+rubyScrewHole:rubyScrewHoleTr"
3558 "+rubyHole:rubyHoleTr)");
3559 TGeoVolume *vFootRightPart = new TGeoVolume("vFootRightPart",
3560 footRightPart,stesalite);
3561 vFootRightPart->SetLineColor(fColorStesalite);
3563 virtualFoot->AddNode(vFootRightPart, 1, 0);
3566 //--- This was the right part of the foot, now let's do the middle
3567 //--- and the right parts
3569 Double_t middleX = fgkLadFootX-fgkLadBox1X-fgkLadFingerPrintX-fgkLadFingerPrintBorder;
3570 TGeoBBox *footMiddle = new TGeoBBox("footMiddle", middleX/2, fgkLadFootMiddleY/2,
3572 TGeoTranslation *middleXTr = new TGeoTranslation("middleXTr",
3573 fgkLadFootX/2-fgkLadBox1X-middleX/2,
3574 fgkLadFootY/2-fgkLadFootMiddleY/2, 0);
3576 TGeoVolume *vFootMiddle = new TGeoVolume("vFootMiddle", footMiddle,stesalite);
3577 vFootMiddle->SetLineColor(fColorStesalite);
3578 virtualFoot->AddNode(vFootMiddle, 1, middleXTr);
3581 TGeoBBox *footLeftLadFinger = new TGeoBBox("footLeftLadFinger", fgkLadFingerPrintX/2,
3582 (fgkLadFootY-fgkLadFingerPrintY)/2,
3584 TGeoTranslation *footLeftLadFingerTr = new TGeoTranslation("footLeftLadFingerTr",
3585 -fgkLadFootX/2+fgkLadFingerPrintBorder+fgkLadFingerPrintX/2,
3586 -fgkLadFingerPrintY/2, 0);
3587 TGeoVolume *vFootLeftLadFinger = new TGeoVolume("vFootLeftLadFinger",footLeftLadFinger,
3589 vFootLeftLadFinger->SetLineColor(fColorStesalite);
3590 virtualFoot->AddNode(vFootLeftLadFinger, 1, footLeftLadFingerTr);
3593 TGeoBBox *footLeft = new TGeoBBox("footLeft", fgkLadFingerPrintBorder/2,
3596 TGeoTranslation *footLeftTr = new TGeoTranslation("footLeftTr",
3597 -fgkLadFootX/2+fgkLadFingerPrintBorder/2,
3599 TGeoVolume *vFootLeft = new TGeoVolume("vFootLeft",footLeft,stesalite);
3600 vFootLeft->SetLineColor(fColorStesalite);
3601 virtualFoot->AddNode(vFootLeft, 1, footLeftTr);
3603 if(GetDebug(3)){ // Remove compiler warning.
3604 ladFingerPrint->InspectShape();
3605 ladFootBox1->InspectShape();
3606 rubyCageHole->InspectShape();
3607 rubyScrewHole->InspectShape();
3608 rubyHole->InspectShape();
3614 //________________________________________________________________________
3615 TGeoVolumeAssembly* AliITSv11GeometrySDD::CreateCarlosCard(Int_t iLay) {
3617 // return an assembly containing the CARLOS end-ladder board
3618 // and the heat bridge
3622 TGeoMedium *glassFiber = GetMedium("GLASS FIBER$");// glassFiber
3623 TGeoMedium *siliconChip = GetMedium("SDD SI CHIP$");// ITSsddSiChip
3624 TGeoMedium *plastiChip = GetMedium("SDDKAPTON (POLYCH2)$"); // ITSsddKAPTON_POLYCH2
3625 TGeoMedium *copper = GetMedium("COPPER$");
3626 TGeoMedium *alCu12SDD = GetMedium("ALCU12$"); // ITSsddAlCu12
3627 TGeoMedium *stainless = GetMedium("AISI304L$"); // for screws
3629 //=========================================
3630 // cooling support of the Carlos card (HeatBridge):
3631 TGeoVolumeAssembly *assemblySupCarlos = new TGeoVolumeAssembly("assemblySupCarlos");
3633 TGeoBBox *supCarlosBoard1 = new TGeoBBox("",fgkCarlosSuppX1/2,fgkCarlosSuppY1/2,
3635 TGeoBBox *supCarlosBoard2 = new TGeoBBox("",fgkCarlosSuppX2/2,fgkCarlosSuppY2/2,
3637 TGeoVolume *vSupCarlosBoard1 = new TGeoVolume("vSupCarlosBoard1",
3638 supCarlosBoard1, alCu12SDD);
3639 TGeoVolume *vSupCarlosBoard2 = new TGeoVolume("vSupCarlosBoard2",
3640 supCarlosBoard2, alCu12SDD);
3641 vSupCarlosBoard1->SetLineColor(4);
3642 vSupCarlosBoard2->SetLineColor(4);
3645 Double_t shiftGlob = -fgkCarlosSuppZ/2+fgkCarlosSuppTopLen;
3646 // shift of the main planes in the direction of their width
3647 // the center is fixed at the center of the 2 small fixing arms on each sides.
3650 shiftGlob+= 0.5*fgkCarlosSuppY3/cos((90-fgkCarlosSuppAngle)*TMath::DegToRad());
3651 shiftGlob-= 0.5*fgkCarlosSuppY2*tan((90-fgkCarlosSuppAngle)*TMath::DegToRad());
3652 Double_t shiftGlobY = shiftGlob*sin(fgkCarlosSuppAngle*TMath::DegToRad());
3653 Double_t shiftGlobZ = shiftGlob*cos(fgkCarlosSuppAngle*TMath::DegToRad());
3655 TGeoTranslation *carlosSupTr1 = new TGeoTranslation( -fgkCarlosSuppX2/2,
3656 (-fgkCarlosSuppY1+fgkCarlosSuppY2)/2+shiftGlobY,
3659 TGeoTranslation *carlosSupTr2 = new TGeoTranslation( fgkCarlosSuppX1/2,
3663 assemblySupCarlos->AddNode(vSupCarlosBoard1, 0, carlosSupTr1);
3664 assemblySupCarlos->AddNode(vSupCarlosBoard2, 0, carlosSupTr2);
3666 //=========================================
3667 // fixing arm of the cooling support :
3668 TGeoBBox *supCarlosBoard3 = new TGeoBBox("",fgkCarlosSuppX3/2,fgkCarlosSuppY3/2,
3670 TGeoVolume *vSupCarlosBoard3 = new TGeoVolume("vSupCarlosBoard3",
3671 supCarlosBoard3, alCu12SDD);
3672 vSupCarlosBoard3->SetLineColor(4);
3675 TGeoTube *littleScrew = new TGeoTube("littleScrew", 0, fgkLittleScrewR,
3677 TGeoVolume *vLittleScrew = new TGeoVolume("vLittleScrew",
3678 littleScrew, stainless);
3679 TGeoRotation *rotScrew = new TGeoRotation("",0,90,0);
3680 TGeoCombiTrans *cbScrew1 = new TGeoCombiTrans(0, 0, fgkCarlosSuppZ3/2 -
3681 fgkLittleScrewHeadR-0.07, rotScrew);
3682 TGeoCombiTrans *cbScrew2 = new TGeoCombiTrans(0, 0, -fgkCarlosSuppZ3/2 +
3683 fgkLittleScrewHeadR+0.07, rotScrew);
3684 vSupCarlosBoard3->AddNode(vLittleScrew,1, cbScrew1);
3685 vSupCarlosBoard3->AddNode(vLittleScrew,2, cbScrew2);
3687 TGeoRotation *carlosSupRot = new TGeoRotation("carlosSuppInvertAngle",
3688 0, fgkCarlosSuppAngle, 0);
3689 TGeoCombiTrans *carlosSupTr3 = new TGeoCombiTrans((fgkCarlosSuppX1+
3690 fgkCarlosSuppX2+fgkCarlosSuppX3)/2,0,0, carlosSupRot);
3691 TGeoCombiTrans *carlosSupTr4 = new TGeoCombiTrans(-(fgkCarlosSuppX1+
3692 fgkCarlosSuppX2+fgkCarlosSuppX3)/2,0,0, carlosSupRot);
3693 assemblySupCarlos->AddNode(vSupCarlosBoard3, 0, carlosSupTr3);
3694 assemblySupCarlos->AddNode(vSupCarlosBoard3, 1, carlosSupTr4);
3697 //=========================================
3698 // screws fixing the board on the U tube
3699 Double_t aaa = fgkCarlosSuppY3; // ???
3700 //Double_t aaa = fgkCarlosSuppY3/2 + fgkLittleScrewHeadH/2;
3701 Double_t bbb = fgkCarlosSuppZ3/2 - fgkLittleScrewHeadR;
3702 Double_t screw1y = ( aaa*cos(TMath::DegToRad()*fgkCarlosSuppAngle) -
3703 bbb*sin(TMath::DegToRad()*fgkCarlosSuppAngle) );
3704 Double_t screw1z = ( aaa*sin(TMath::DegToRad()*fgkCarlosSuppAngle) +
3705 bbb*cos(TMath::DegToRad()*fgkCarlosSuppAngle) )-0.07;
3707 TGeoRotation *carlosSuppRot = (TGeoRotation *)fCommonTr[0];
3709 TGeoCombiTrans* lScrewTr1 = new TGeoCombiTrans((fgkCarlosSuppX1+
3710 fgkCarlosSuppX2+fgkCarlosSuppX3)/2,
3711 screw1y,screw1z, carlosSuppRot);
3713 TGeoCombiTrans* lScrewTr2 = new TGeoCombiTrans((fgkCarlosSuppX1+
3714 fgkCarlosSuppX2+fgkCarlosSuppX3)/2,
3715 screw1z,screw1y, carlosSuppRot);
3717 TGeoCombiTrans *lScrewTr3 = new TGeoCombiTrans(-(fgkCarlosSuppX1+
3718 fgkCarlosSuppX2+fgkCarlosSuppX3)/2,
3719 screw1y,screw1z, carlosSuppRot);
3721 TGeoCombiTrans *lScrewTr4 = new TGeoCombiTrans(-(fgkCarlosSuppX1+
3722 fgkCarlosSuppX2+fgkCarlosSuppX3)/2,
3723 screw1z,screw1y, carlosSuppRot);
3725 assemblySupCarlos->AddNode(fCommonVol[0], 1, lScrewTr1);
3726 assemblySupCarlos->AddNode(fCommonVol[0], 2, lScrewTr2);
3727 assemblySupCarlos->AddNode(fCommonVol[0], 3, lScrewTr3);
3728 assemblySupCarlos->AddNode(fCommonVol[0], 4, lScrewTr4);
3730 //=========================================
3732 Double_t p1[3], p2[3], vX[3] = {1,0,0};
3733 AliITSv11GeomCableFlat card1("cardCarlos1", fgkCarlosCardZ1, fgkCarlosCardY1); // name, width, thickness
3734 card1.SetNLayers(2);
3735 card1.SetLayer(0, fgkCarlosCardCuY, copper, kOrange); // index, thickness, material, color
3736 card1.SetLayer(1, fgkCarlosCardY1-fgkCarlosCardCuY, glassFiber, 30);
3737 card1.SetInitialNode( (TGeoVolume *) assemblySupCarlos);
3738 p1[0] = -fgkCarlosCardX1/2;
3739 p1[1] = shiftGlobY - fgkCarlosCard2HeatBridge;
3740 p1[2] = fgkCarlosCardShift;
3741 p2[0] = fgkCarlosCardX1/2;
3742 p2[1] = shiftGlobY - fgkCarlosCard2HeatBridge;
3743 p2[2] = fgkCarlosCardShift;
3744 card1.AddCheckPoint( (TGeoVolume *) assemblySupCarlos, 0, p1, vX);
3745 card1.AddCheckPoint( (TGeoVolume *) assemblySupCarlos, 1, p2, vX);
3746 card1.CreateAndInsertBoxCableSegment(1,90);
3748 AliITSv11GeomCableFlat card2("cardCarlos2", fgkCarlosCardZ2, fgkCarlosCardY1); // name, width, thickness
3749 card2.SetNLayers(2);
3750 card2.SetLayer(0, fgkCarlosCardCuY, copper, kOrange); // index, thickness, material, color
3751 card2.SetLayer(1, fgkCarlosCardY1-fgkCarlosCardCuY, glassFiber, 30);
3752 card2.SetInitialNode( (TGeoVolume *) assemblySupCarlos);
3754 p1[0] = -fgkCarlosCardX1/2;
3755 p1[1] = shiftGlobY - fgkCarlosCard2HeatBridge;
3756 p1[2] = fgkCarlosCardShift + fgkCarlosCardZ1/2 + fgkCarlosCardZ2/2;
3758 p2[0] = -fgkCarlosCardX1/2 + fgkCarlosCardX2;
3759 p2[1] = shiftGlobY - fgkCarlosCard2HeatBridge;
3760 p2[2] = fgkCarlosCardShift + fgkCarlosCardZ1/2 + fgkCarlosCardZ2/2;
3761 card2.AddCheckPoint( (TGeoVolume *) assemblySupCarlos, 0, p1, vX);
3762 card2.AddCheckPoint( (TGeoVolume *) assemblySupCarlos, 1, p2, vX);
3763 card2.CreateAndInsertBoxCableSegment(1,90);
3765 //=========================================
3766 // some chips on the board
3768 AliITSv11GeomCableFlat u1("carlosCardU1", fgkCarlosU1Z, fgkCarlosU1Y); // name, width, thickness
3770 u1.SetLayer(0, fgkCarlosCardChipSiThick, siliconChip, kGreen); // index, thickness, material, color
3771 u1.SetLayer(1, fgkCarlosU1Y - fgkCarlosCardChipSiThick, plastiChip, kGray+3);
3772 u1.SetInitialNode( (TGeoVolume *) assemblySupCarlos);
3774 p1[0] = fgkCarlosU1posX - fgkCarlosU1X/2;
3775 p1[1] = shiftGlobY - fgkCarlosCard2HeatBridge + fgkCarlosCardY1/2 + fgkCarlosU1Y/2;
3776 p1[2] = fgkCarlosCardShift + fgkCarlosU1posZ;
3778 p2[0] = fgkCarlosU1posX + fgkCarlosU1X/2;
3779 p2[1] = shiftGlobY - fgkCarlosCard2HeatBridge + fgkCarlosCardY1/2 + fgkCarlosU1Y/2;
3780 p2[2] = fgkCarlosCardShift + fgkCarlosU1posZ;
3781 u1.AddCheckPoint( (TGeoVolume *) assemblySupCarlos, 0, p1, vX);
3782 u1.AddCheckPoint( (TGeoVolume *) assemblySupCarlos, 1, p2, vX);
3783 u1.CreateAndInsertBoxCableSegment(1,90);
3786 AliITSv11GeomCableFlat u2("carlosCardU2", fgkCarlosU2Z, fgkCarlosU2Y); // name, width, thickness
3788 u2.SetLayer(0, fgkCarlosCardChipSiThick, siliconChip, kGreen); // index, thickness, material, color
3789 u2.SetLayer(1, fgkCarlosU2Y - fgkCarlosCardChipSiThick, plastiChip, kGray+3);
3790 u2.SetInitialNode( (TGeoVolume *) assemblySupCarlos);
3792 p1[0] = fgkCarlosU2posX - fgkCarlosU2X/2;
3793 p1[1] = shiftGlobY - fgkCarlosCard2HeatBridge + fgkCarlosCardY1/2 + fgkCarlosU2Y/2;
3794 p1[2] = fgkCarlosCardShift + fgkCarlosU2posZ;
3796 p2[0] = fgkCarlosU2posX + fgkCarlosU2X/2;
3797 p2[1] = shiftGlobY - fgkCarlosCard2HeatBridge + fgkCarlosCardY1/2 + fgkCarlosU2Y/2;
3798 p2[2] = fgkCarlosCardShift + fgkCarlosU2posZ;
3799 u2.AddCheckPoint( (TGeoVolume *) assemblySupCarlos, 0, p1, vX);
3800 u2.AddCheckPoint( (TGeoVolume *) assemblySupCarlos, 1, p2, vX);
3801 u2.CreateAndInsertBoxCableSegment(1,90);
3804 AliITSv11GeomCableFlat u3("carlosCardU3", fgkCarlosU3Z, fgkCarlosU3Y); // name, width, thickness
3806 u3.SetLayer(0, fgkCarlosCardChipSiThick, siliconChip, kGreen); // index, thickness, material, color
3807 u3.SetLayer(1, fgkCarlosU3Y - fgkCarlosCardChipSiThick, plastiChip, kGray+3);
3808 u3.SetInitialNode( (TGeoVolume *) assemblySupCarlos);
3810 Double_t u3Y = shiftGlobY - fgkCarlosCard2HeatBridge + fgkCarlosCardY1/2 + fgkCarlosU3Y/2;
3811 p1[0] = fgkCarlosU3posX - fgkCarlosU3X/2;
3813 p1[2] = fgkCarlosCardShift + fgkCarlosU3posZ;
3815 p2[0] = fgkCarlosU3posX + fgkCarlosU3X/2;
3817 p2[2] = fgkCarlosCardShift + fgkCarlosU3posZ;
3818 u3.AddCheckPoint( (TGeoVolume *) assemblySupCarlos, 0, p1, vX);
3819 u3.AddCheckPoint( (TGeoVolume *) assemblySupCarlos, 1, p2, vX);
3820 TGeoVolume *u3Vol = u3.CreateAndInsertBoxCableSegment(1,90);
3822 //--- U4 is like U3 (?)
3823 TGeoCombiTrans *u4Trans = new TGeoCombiTrans;
3824 u4Trans->RotateX(90);
3825 u4Trans->SetTranslation(fgkCarlosU4posX, u3Y,
3826 fgkCarlosCardShift + fgkCarlosU4posZ);
3827 assemblySupCarlos->AddNode(u3Vol, 2, u4Trans);
3830 AliITSv11GeomCableFlat u17("carlosCardU17", fgkCarlosU17Z, fgkCarlosU17Y); // name, width, thickness
3832 u17.SetLayer(0, fgkCarlosCardChipSiThick, siliconChip, kGreen); // index, thickness, material, color
3833 u17.SetLayer(1, fgkCarlosU17Y - fgkCarlosCardChipSiThick, plastiChip, kGray+3);
3834 u17.SetInitialNode( (TGeoVolume *) assemblySupCarlos);
3836 p1[0] = fgkCarlosU17posX - fgkCarlosU17X/2;
3837 p1[1] = shiftGlobY - fgkCarlosCard2HeatBridge + fgkCarlosCardY1/2 + fgkCarlosU17Y/2;
3838 p1[2] = fgkCarlosCardShift + fgkCarlosU17posZ;
3840 p2[0] = fgkCarlosU17posX + fgkCarlosU17X/2;
3841 p2[1] = shiftGlobY - fgkCarlosCard2HeatBridge + fgkCarlosCardY1/2 + fgkCarlosU17Y/2;
3842 p2[2] = fgkCarlosCardShift + fgkCarlosU17posZ;
3843 u17.AddCheckPoint( (TGeoVolume *) assemblySupCarlos, 0, p1, vX);
3844 u17.AddCheckPoint( (TGeoVolume *) assemblySupCarlos, 1, p2, vX);
3845 u17.CreateAndInsertBoxCableSegment(1,90);
3848 AliITSv11GeomCableFlat u35("carlosCardU35", fgkCarlosU35Z, fgkCarlosU35Y); // name, width, thickness
3850 u35.SetLayer(0, fgkCarlosCardChipSiThick, siliconChip, kGreen); // index, thickness, material, color
3851 u35.SetLayer(1, fgkCarlosU35Y - fgkCarlosCardChipSiThick, plastiChip, kGray+3);
3852 u35.SetInitialNode( (TGeoVolume *) assemblySupCarlos);
3854 p1[0] = fgkCarlosU35posX - fgkCarlosU35X/2;
3855 p1[1] = shiftGlobY - fgkCarlosCard2HeatBridge + fgkCarlosCardY1/2 + fgkCarlosU35Y/2;
3856 p1[2] = fgkCarlosCardShift + fgkCarlosU35posZ;
3858 p2[0] = fgkCarlosU35posX + fgkCarlosU35X/2;
3859 p2[1] = shiftGlobY - fgkCarlosCard2HeatBridge + fgkCarlosCardY1/2 + fgkCarlosU35Y/2;
3860 p2[2] = fgkCarlosCardShift + fgkCarlosU35posZ;
3861 u35.AddCheckPoint( (TGeoVolume *) assemblySupCarlos, 0, p1, vX);
3862 u35.AddCheckPoint( (TGeoVolume *) assemblySupCarlos, 1, p2, vX);
3863 u35.CreateAndInsertBoxCableSegment(1,90);
3866 AliITSv11GeomCableFlat u36("carlosCardU36", fgkCarlosU36Z, fgkCarlosU36Y); // name, width, thickness
3868 u36.SetLayer(0, fgkCarlosCardChipSiThick, siliconChip, kGreen); // index, thickness, material, color
3869 u36.SetLayer(1, fgkCarlosU36Y - fgkCarlosCardChipSiThick, plastiChip, kGray+3);
3870 u36.SetInitialNode( (TGeoVolume *) assemblySupCarlos);
3872 p1[0] = fgkCarlosU36posX - fgkCarlosU36X/2;
3873 p1[1] = shiftGlobY - fgkCarlosCard2HeatBridge + fgkCarlosCardY1/2 + fgkCarlosU36Y/2;
3874 p1[2] = fgkCarlosCardShift + fgkCarlosU36posZ;
3876 p2[0] = fgkCarlosU36posX + fgkCarlosU36X/2;
3877 p2[1] = shiftGlobY - fgkCarlosCard2HeatBridge + fgkCarlosCardY1/2 + fgkCarlosU36Y/2;
3878 p2[2] = fgkCarlosCardShift + fgkCarlosU36posZ;
3879 u36.AddCheckPoint( (TGeoVolume *) assemblySupCarlos, 0, p1, vX);
3880 u36.AddCheckPoint( (TGeoVolume *) assemblySupCarlos, 1, p2, vX);
3881 u36.CreateAndInsertBoxCableSegment(1,90);
3884 AliITSv11GeomCableFlat qz1("carlosCardQZ1", fgkCarlosQZ1Z, fgkCarlosQZ1Y); // name, width, thickness
3886 qz1.SetLayer(0, fgkCarlosCardChipSiThick, siliconChip, kGreen); // index, thickness, material, color
3887 qz1.SetLayer(1, fgkCarlosQZ1Y - fgkCarlosCardChipSiThick, plastiChip, kGray+3);
3888 qz1.SetInitialNode( (TGeoVolume *) assemblySupCarlos);
3890 p1[0] = fgkCarlosQZ1posX - fgkCarlosQZ1X/2;
3891 p1[1] = shiftGlobY - fgkCarlosCard2HeatBridge + fgkCarlosCardY1/2 + fgkCarlosQZ1Y/2;
3892 p1[2] = fgkCarlosCardShift + fgkCarlosQZ1posZ;
3894 p2[0] = fgkCarlosQZ1posX + fgkCarlosQZ1X/2;
3895 p2[1] = shiftGlobY - fgkCarlosCard2HeatBridge + fgkCarlosCardY1/2 + fgkCarlosQZ1Y/2;
3896 p2[2] = fgkCarlosCardShift + fgkCarlosQZ1posZ;
3897 qz1.AddCheckPoint( (TGeoVolume *) assemblySupCarlos, 0, p1, vX);
3898 qz1.AddCheckPoint( (TGeoVolume *) assemblySupCarlos, 1, p2, vX);
3899 qz1.CreateAndInsertBoxCableSegment(1,90);
3901 return assemblySupCarlos;
3904 //________________________________________________________________________
3905 Int_t AliITSv11GeometrySDD::CreateLVCard() {
3907 // Creates the assemblies containing the LV cards (left and right)
3910 TGeoMedium *glassFiber = GetMedium("GLASS FIBER$");// glassFiber
3911 TGeoMedium *siliconChip = GetMedium("SDD SI CHIP$");// ITSsddSiChip
3912 TGeoMedium *plastiChip = GetMedium("SDDKAPTON (POLYCH2)$"); // ITSsddKAPTON_POLYCH2
3913 TGeoMedium *copper = GetMedium("COPPER$");
3914 TGeoMedium *alCu12SDD = GetMedium("ALCU12$"); // ITSsddAlCu12
3915 TGeoMedium *stainless = GetMedium("AISI304L$"); // for screws
3917 fCardLVL = new TGeoVolumeAssembly("ITSsddLVCardLeft");
3918 fCardLVR = new TGeoVolumeAssembly("ITSsddLVCardRight");
3920 // we are going to use flat cable class to create multilayer box,
3921 // then we can use the pointers to created volumes to place them elsewhere
3922 Double_t p1[3], p2[3], vX[3] = {1,0,0};
3924 Double_t carLVfullThick = fgkLVcardZ+fgkLVcardCuZ;
3925 AliITSv11GeomCableFlat cardLV("cardLV", fgkLVcardY, carLVfullThick); // name, width, thickness
3926 cardLV.SetNLayers(2);
3927 cardLV.SetLayer(0, fgkLVcardCuZ, copper, 30); // index, thickness, material, color
3928 cardLV.SetLayer(1, fgkLVcardZ, glassFiber, 30);
3929 cardLV.SetInitialNode( (TGeoVolume *) fCardLVL);
3931 p1[1] = fgkLVcardY/2;
3934 p2[1] = fgkLVcardY/2;
3936 cardLV.AddCheckPoint( (TGeoVolume *) fCardLVL, 0, p1, vX);
3937 cardLV.AddCheckPoint( (TGeoVolume *) fCardLVL, 1, p2, vX);
3938 TGeoVolume* boxVol = cardLV.CreateAndInsertBoxCableSegment(1);
3939 TGeoRotation *rotAdd = new TGeoRotation("",90,0,0);
3940 TGeoCombiTrans *trCard = new TGeoCombiTrans(-fgkLVcardX/2,fgkLVcardY/2,0,rotAdd);
3941 fCardLVR->AddNode(boxVol, 1, trCard);
3943 Double_t chip0fullThick = fgkLVChip0Z + fgkLVChip0SiZ;
3944 AliITSv11GeomCableFlat chipO("chipO", fgkLVChip0Y, chip0fullThick); // name, width, thickness
3945 chipO.SetNLayers(2);
3946 chipO.SetLayer(0, fgkLVChip0SiZ, siliconChip, 8); // index, thickness, material, color
3947 chipO.SetLayer(1, fgkLVChip0Z, plastiChip, 12);
3948 chipO.SetInitialNode( (TGeoVolume *) fCardLVL);
3949 p1[0] = (fgkLVChip0PosX - fgkLVChip0X/2);
3950 p1[1] = fgkLVChip0PosY;
3951 p1[2] = carLVfullThick/2 + chip0fullThick/2;
3953 p2[0] = (fgkLVChip0PosX + fgkLVChip0X/2);
3954 p2[1] = fgkLVChip0PosY;
3955 p2[2] = carLVfullThick/2 + chip0fullThick/2;
3956 chipO.AddCheckPoint( (TGeoVolume *) fCardLVL, 0, p1, vX);
3957 chipO.AddCheckPoint( (TGeoVolume *) fCardLVL, 1, p2, vX);
3958 boxVol = chipO.CreateAndInsertBoxCableSegment(1);
3959 trCard = new TGeoCombiTrans( -fgkLVChip0PosX,
3961 carLVfullThick/2+chip0fullThick/2, rotAdd);
3962 fCardLVR->AddNode(boxVol, 1, trCard);
3964 // put also this chip on the other side of the card
3965 trCard = new TGeoCombiTrans( fgkLVChip0PosX,
3967 -carLVfullThick/2-chip0fullThick/2, rotAdd);
3968 fCardLVL->AddNode(boxVol, 2, trCard);
3969 trCard = new TGeoCombiTrans( -fgkLVChip0PosX,
3971 -carLVfullThick/2-chip0fullThick/2, rotAdd);
3972 fCardLVR->AddNode(boxVol, 2, trCard);
3974 Double_t chip1fullThick = fgkLVChip1Z + fgkLVChip1SiZ;
3975 AliITSv11GeomCableFlat chip1("chip1", fgkLVChip1Y, chip1fullThick);
3976 chip1.SetNLayers(2);
3977 chip1.SetLayer(0, fgkLVChip1SiZ, siliconChip, 8);
3978 chip1.SetLayer(1, fgkLVChip1Z, plastiChip, 12);
3979 chip1.SetInitialNode( (TGeoVolume *) fCardLVL);
3980 p1[0] = (fgkLVChip1PosX-fgkLVChip1X/2);
3981 p1[1] = fgkLVChip1PosY;
3982 p1[2] = carLVfullThick/2 + chip1fullThick/2;
3984 p2[0] = (fgkLVChip1PosX+fgkLVChip1X/2);
3985 p2[1] = fgkLVChip1PosY;
3986 p2[2] = carLVfullThick/2 + chip1fullThick/2;
3987 chip1.AddCheckPoint( (TGeoVolume *) fCardLVL, 0, p1, vX);
3988 chip1.AddCheckPoint( (TGeoVolume *) fCardLVL, 1, p2, vX);
3989 boxVol = chip1.CreateAndInsertBoxCableSegment(1);
3990 trCard = new TGeoCombiTrans( -fgkLVChip1PosX,
3992 carLVfullThick/2 + chip1fullThick/2, rotAdd);
3993 fCardLVR->AddNode(boxVol, 1, trCard);
3995 Double_t chip2fullThick = fgkLVChip2Z + fgkLVChip2SiZ;
3996 AliITSv11GeomCableFlat chip2("chip2", fgkLVChip2Y, chip2fullThick);
3997 chip2.SetNLayers(2);
3998 chip2.SetLayer(0, fgkLVChip2SiZ, siliconChip, 8);
3999 chip2.SetLayer(1, fgkLVChip2Z, plastiChip, 12);
4000 chip2.SetInitialNode( (TGeoVolume *) fCardLVL);
4001 p1[0] = (fgkLVChip2PosX-fgkLVChip2X/2);
4002 p1[1] = fgkLVChip2PosY;
4003 p1[2] = carLVfullThick/2 + chip2fullThick/2;
4004 p2[0] = (fgkLVChip2PosX+fgkLVChip2X/2);
4005 p2[1] = fgkLVChip2PosY;
4006 p2[2] = carLVfullThick/2 + chip2fullThick/2;
4007 chip2.AddCheckPoint( (TGeoVolume *) fCardLVL, 0, p1, vX);
4008 chip2.AddCheckPoint( (TGeoVolume *) fCardLVL, 1, p2, vX);
4009 boxVol = chip2.CreateAndInsertBoxCableSegment(1);
4010 trCard = new TGeoCombiTrans( -fgkLVChip2PosX,
4012 carLVfullThick/2 + chip2fullThick/2, rotAdd);
4013 fCardLVR->AddNode(boxVol, 1, trCard);
4015 Double_t chip3fullThick = fgkLVChip3Z + fgkLVChip3SiZ;
4016 AliITSv11GeomCableFlat chip3("chip3", fgkLVChip3Y, chip3fullThick);
4017 chip3.SetNLayers(2);
4018 chip3.SetLayer(0, fgkLVChip3Z, plastiChip, 12);
4019 chip3.SetLayer(1, fgkLVChip3SiZ, siliconChip, 8);
4020 chip3.SetInitialNode( (TGeoVolume *) fCardLVL);
4021 p1[0] = (fgkLVChip3PosX-fgkLVChip3X/2);
4022 p1[1] = fgkLVChip3PosY;
4023 p1[2] = -carLVfullThick/2 - chip3fullThick/2;
4024 p2[0] = (fgkLVChip3PosX+fgkLVChip3X/2);
4025 p2[1] = fgkLVChip3PosY;
4026 p2[2] = -carLVfullThick/2 - chip3fullThick/2;
4027 chip3.AddCheckPoint( (TGeoVolume *) fCardLVL, 0, p1, vX);
4028 chip3.AddCheckPoint( (TGeoVolume *) fCardLVL, 1, p2, vX);
4029 boxVol = chip3.CreateAndInsertBoxCableSegment(1);
4030 trCard = new TGeoCombiTrans( -fgkLVChip3PosX,
4032 -carLVfullThick/2 - chip3fullThick/2, rotAdd);
4033 fCardLVR->AddNode(boxVol, 1, trCard);
4035 // the Al pieces for heat exchange :
4036 TGeoBBox *alLVcooling1 = new TGeoBBox("alLVcooling1" ,
4037 fgkLVcoolX1/2, fgkLVcoolY1/2, fgkLVcoolZ1/2);
4039 TGeoTranslation *alLVcooling1Tr = new TGeoTranslation("alLVcooling1Tr",
4040 (fgkLVcoolX1/2+fgkLVcoolX2),
4041 fgkLVcoolPosY+fgkLVcoolY1/2,
4042 carLVfullThick/2+chip0fullThick+fgkLVcoolZ1/2);
4043 TGeoTranslation *alLVcooling1TrB = new TGeoTranslation("alLVcooling1TrB",
4044 (fgkLVcoolX1/2+fgkLVcoolX2),
4045 fgkLVcoolPosY+fgkLVcoolY1/2,
4046 -(carLVfullThick/2+chip0fullThick+fgkLVcoolZ1/2));
4048 TGeoVolume *vAlLVcooling1 = new TGeoVolume("vAlLVcooling1",alLVcooling1,
4050 vAlLVcooling1->SetLineColor(2);
4053 TGeoBBox * alLVcooling2 = new TGeoBBox("lLVcooling2" ,
4054 fgkLVcoolX2/2, fgkLVcoolY2/2, fgkLVcoolZ2/2);
4055 TGeoTranslation *alLVcooling2Tr = new TGeoTranslation("alLVcooling2Tr",
4057 fgkLVcoolPosY+fgkLVcoolY1/2,
4058 carLVfullThick/2+chip0fullThick+fgkLVcoolZ1-fgkLVcoolZ2/2);
4059 TGeoTranslation *alLVcooling2TrB = new TGeoTranslation("alLVcooling2TrB",
4061 fgkLVcoolPosY+fgkLVcoolY1/2,
4062 -(carLVfullThick/2+chip0fullThick+fgkLVcoolZ1-fgkLVcoolZ2/2));
4064 TGeoVolume *vAlLVcooling2 = new TGeoVolume("vAlLVcooling2",alLVcooling2,
4066 vAlLVcooling2->SetLineColor(2);
4069 Double_t alLVcoolZ3 = (fgkLVcardCuZ+fgkLVcardZ+2.*(fgkLVChip0SiZ+fgkLVChip0Z)
4071 TGeoBBox * alLVcooling3 = new TGeoBBox("lLVcooling3" ,
4072 fgkLVcoolX3/2, fgkLVcoolY3/2, alLVcoolZ3/2);
4073 TGeoTranslation *alLVcooling3Tr = new TGeoTranslation("alLVcooling3Tr",
4075 fgkLVcoolPosY+fgkLVcoolY1-fgkLVcoolY3/2,
4077 TGeoVolume *vAlLVcooling3 = new TGeoVolume("vAlLVcooling3",alLVcooling3,alCu12SDD);
4078 vAlLVcooling3->SetLineColor(2);
4080 //=== screw fixing th LV card to the U cooling tube :
4081 TGeoTube *littleScrew = new TGeoTube("littleScrewLV", 0, fgkLittleScrewR,
4083 TGeoVolume *vLittleScrew = new TGeoVolume("vLittleScrewLV",
4084 littleScrew, stainless);
4085 TGeoRotation *rotScrew = new TGeoRotation("",0,90,0);
4087 TGeoCombiTrans *cbScrew = new TGeoCombiTrans(0,0,fgkShiftLittleScrewLV,
4089 vAlLVcooling3->AddNode(vLittleScrew, 1, cbScrew);
4091 TGeoTube *littleScrewHead = new TGeoTube("littleScrewLVhead",
4092 0, fgkLittleLVScrewHeadR,
4093 fgkLittleScrewHeadH/2);
4094 TGeoVolume *vLittleScrewHead = new TGeoVolume("vLittleScrewLVhead",
4095 littleScrewHead, stainless);
4096 vLittleScrewHead->SetLineColor(kGray);
4097 TGeoCombiTrans *cbScrewHeadL = new TGeoCombiTrans( -fgkLVcoolX3/2,
4098 fgkLVcoolPosY+fgkLVcoolY1 + fgkLittleScrewHeadH/2,
4099 fgkShiftLittleScrewLV,
4101 fCardLVL->AddNode(vLittleScrewHead, 1, cbScrewHeadL);
4103 TGeoCombiTrans *cbScrewHeadR = new TGeoCombiTrans( fgkLVcoolX3/2,
4104 fgkLVcoolPosY+fgkLVcoolY1 + fgkLittleScrewHeadH/2,
4105 fgkShiftLittleScrewLV,
4107 fCardLVR->AddNode(vLittleScrewHead, 1, cbScrewHeadR);
4109 // adding the cooling pieces to the left card
4110 fCardLVL->AddNode(vAlLVcooling1, 1,alLVcooling1Tr);
4111 fCardLVL->AddNode(vAlLVcooling1, 2,alLVcooling1TrB);
4112 fCardLVL->AddNode(vAlLVcooling2, 1,alLVcooling2Tr);
4113 fCardLVL->AddNode(vAlLVcooling2, 2,alLVcooling2TrB);
4114 fCardLVL->AddNode(vAlLVcooling3, 1,alLVcooling3Tr);
4116 TGeoTranslation *alLVcooling1TrR = new TGeoTranslation("alLVcooling1TrR",
4117 -(fgkLVcoolX1/2+fgkLVcoolX2),
4118 fgkLVcoolPosY+fgkLVcoolY1/2,
4119 carLVfullThick/2+chip0fullThick+fgkLVcoolZ1/2);
4120 TGeoTranslation *alLVcooling1TrBR = new TGeoTranslation("alLVcooling1TrBR",
4121 -(fgkLVcoolX1/2+fgkLVcoolX2),
4122 fgkLVcoolPosY+fgkLVcoolY1/2,
4123 -(carLVfullThick/2+chip0fullThick+fgkLVcoolZ1/2));
4124 TGeoTranslation *alLVcooling2TrR = new TGeoTranslation("alLVcooling2TrR",
4126 fgkLVcoolPosY+fgkLVcoolY1/2,
4127 carLVfullThick/2+chip0fullThick+fgkLVcoolZ1-fgkLVcoolZ2/2);
4128 TGeoTranslation *alLVcooling2TrBR = new TGeoTranslation("alLVcooling2TrBR",
4130 fgkLVcoolPosY+fgkLVcoolY1/2,
4131 -(carLVfullThick/2+chip0fullThick+fgkLVcoolZ1-fgkLVcoolZ2/2));
4133 TGeoTranslation *alLVcooling3TrR = new TGeoTranslation("alLVcooling3TrR",
4135 fgkLVcoolPosY+fgkLVcoolY1-fgkLVcoolY3/2,
4137 // and to the right card
4138 fCardLVR->AddNode(vAlLVcooling1, 1,alLVcooling1TrR);
4139 fCardLVR->AddNode(vAlLVcooling1, 2,alLVcooling1TrBR);
4140 fCardLVR->AddNode(vAlLVcooling2, 1,alLVcooling2TrR);
4141 fCardLVR->AddNode(vAlLVcooling2, 2,alLVcooling2TrBR);
4142 fCardLVR->AddNode(vAlLVcooling3, 1,alLVcooling3TrR);
4147 //________________________________________________________________________
4148 TGeoVolumeAssembly* AliITSv11GeometrySDD::CreateHVCard(){
4150 // return an assembly containing the HV card
4153 TGeoMedium *ceramic = GetMedium("CERAMICS$"); // ceramicHVcard
4154 TGeoMedium *medSMDcapaMiddle = GetMedium("SDD X7R capacitors$"); // check if different
4155 TGeoMedium *medSMDcapaEnd = GetMedium("SDD X7R capacitors$"); // check if different
4156 TGeoMedium *stainless = GetMedium("INOX$"); // ITSspdStainlesSteal ???????????
4157 TGeoMedium *plastic = GetMedium("SDDKAPTON (POLYCH2)$"); // ITS_ITSsddKAPTON_POLYCH2 ???????????
4158 TGeoMedium *alCu12SDD = GetMedium("ALCU12$"); // ITSsddAlCu12
4160 TGeoVolumeAssembly *highVCard = new TGeoVolumeAssembly("ITSsddHVCard");
4162 //====================================
4163 //--- the card itself
4164 TGeoBBox *ceramicCard = new TGeoBBox("ceramCard", fgkHVCardCeramX/2,
4165 fgkHVCardCeramY/2, fgkHVCardCeramZ/2);
4166 TGeoVolume *vCeramicCard = new TGeoVolume("vCeramCard", ceramicCard, ceramic);
4167 vCeramicCard->SetLineColor(38);// or 9 blue slightly dark
4169 highVCard->AddNode(vCeramicCard, 1, 0);
4172 //====================================
4176 TGeoBBox *capa1Middle = new TGeoBBox("cardHVCapa1Middle", fgkHVCardCapa1X/2,
4177 fgkHVCardCapa1Ymid/2, fgkHVCardCapa1Z/2);
4178 TGeoVolume *vCapa1Middle = new TGeoVolume("vCardHVCapa1Middle",capa1Middle,
4181 TGeoBBox *capa1End = new TGeoBBox("cardHVCapa1End", fgkHVCardCapa1X/2,
4182 fgkHVCardCapa1Yend/2, fgkHVCardCapa1Z/2);
4183 TGeoVolume *vCapa1End = new TGeoVolume("vCardHVCapa1End",capa1End,
4185 vCapa1End->SetLineColor(18);// grey silver
4186 TGeoTranslation *capa1EndTr1 = new TGeoTranslation("cardHVcapa1EndTr1", 0,
4187 (fgkHVCardCapa1Ymid+fgkHVCardCapa1Yend)/2,0);
4188 TGeoTranslation *capa1EndTr2 = new TGeoTranslation("cardHVcapa1EndTr2", 0,
4189 -(fgkHVCardCapa1Ymid+fgkHVCardCapa1Yend)/2,0);
4191 TGeoTranslation *capa1PosTr = new TGeoTranslation("cardHVcapa1PosTr",
4192 fgkHVCardCapa1PosX, fgkHVCardCapa1PosY,
4193 -fgkHVCardCeramZ/2-fgkHVCardCapa1Z/2);
4195 TGeoVolumeAssembly *capa1 = new TGeoVolumeAssembly("cardHVCapa1");
4196 capa1->AddNode(vCapa1Middle, 1,0);
4197 capa1->AddNode(vCapa1End, 1, capa1EndTr1);
4198 capa1->AddNode(vCapa1End, 2, capa1EndTr2);
4200 highVCard->AddNode(capa1, 1, capa1PosTr);
4203 TGeoBBox *capa2Middle = new TGeoBBox("cardHVCapa2Middle", fgkHVCardCapa2X/2,
4204 fgkHVCardCapa2Ymid/2, fgkHVCardCapa2Z/2);
4205 TGeoVolume *vCapa2Middle = new TGeoVolume("vCardHVCapa2Middle",capa2Middle,
4208 TGeoBBox *capa2End = new TGeoBBox("cardHVCapa2End", fgkHVCardCapa2X/2,
4209 fgkHVCardCapa2Yend/2, fgkHVCardCapa2Z/2);
4210 TGeoVolume *vCapa2End = new TGeoVolume("vCardHVCapa2End",capa2End,
4212 vCapa2End->SetLineColor(18);// grey silver
4213 TGeoTranslation *capa2EndTr1 = new TGeoTranslation("cardHVcapa2EndTr1", 0,
4214 (fgkHVCardCapa2Ymid+fgkHVCardCapa2Yend)/2,0);
4215 TGeoTranslation *capa2EndTr2 = new TGeoTranslation("cardHVcapa2EndTr2", 0,
4216 -(fgkHVCardCapa2Ymid+fgkHVCardCapa2Yend)/2,0);
4218 TGeoTranslation *capa2PosTr = new TGeoTranslation("cardHVcapa2PosTr",
4219 fgkHVCardCapa2PosX, fgkHVCardCapa2PosY,
4220 -fgkHVCardCeramZ/2-fgkHVCardCapa2Z/2);
4222 TGeoVolumeAssembly *capa2 = new TGeoVolumeAssembly("cardHVCapa2");
4223 capa2->AddNode(vCapa2Middle, 1,0);
4224 capa2->AddNode(vCapa2End, 1, capa2EndTr1);
4225 capa2->AddNode(vCapa2End, 2, capa2EndTr2);
4227 highVCard->AddNode(capa2, 1, capa2PosTr);
4230 TGeoBBox *capa3Middle = new TGeoBBox("cardHVCapa3Middle", fgkHVCardCapa3Xmid/2,
4231 fgkHVCardCapa3Y/2, fgkHVCardCapa3Z/2);
4232 TGeoVolume *vCapa3Middle = new TGeoVolume("vCardHVCapa3Middle",capa3Middle,
4235 TGeoBBox *capa3End = new TGeoBBox("cardHVCapa3End", fgkHVCardCapa3Xend/2,
4236 fgkHVCardCapa3Y/2, fgkHVCardCapa3Z/2);
4237 TGeoVolume *vCapa3End = new TGeoVolume("vCardHVCapa3End",capa3End,
4239 vCapa3End->SetLineColor(18);// grey silver
4241 TGeoTranslation *capa3EndTr1 = new TGeoTranslation("cardHVcapa3EndTr1",
4242 (fgkHVCardCapa3Xmid+fgkHVCardCapa3Xend)/2, 0, 0);
4243 TGeoTranslation *capa3EndTr2 = new TGeoTranslation("cardHVcapa2EndTr2",
4244 -(fgkHVCardCapa3Xmid+fgkHVCardCapa3Xend)/2, 0, 0);
4246 TGeoVolumeAssembly *capa3 = new TGeoVolumeAssembly("cardHVCapa3");
4247 capa3->AddNode(vCapa3Middle, 1,0);
4248 capa3->AddNode(vCapa3End, 1, capa3EndTr1);
4249 capa3->AddNode(vCapa3End, 2, capa3EndTr2);
4251 TGeoTranslation *capa3PosTr1 = new TGeoTranslation("cardHVcapa3PosTr1",
4252 fgkHVCardCapa3PosX1, fgkHVCardCapa3PosY1,
4253 -fgkHVCardCeramZ/2-fgkHVCardCapa3Z/2);
4255 TGeoTranslation *capa3PosTr2 = new TGeoTranslation("cardHVcapa3PosTr2",
4256 fgkHVCardCapa3PosX2, fgkHVCardCapa3PosY1,
4257 -fgkHVCardCeramZ/2-fgkHVCardCapa3Z/2);
4259 TGeoTranslation *capa3PosTr3 = new TGeoTranslation("cardHVcapa3PosTr3",
4260 fgkHVCardCapa3PosX3, fgkHVCardCapa3PosY2,
4261 -fgkHVCardCeramZ/2-fgkHVCardCapa3Z/2);
4263 TGeoTranslation *capa3PosTr4 = new TGeoTranslation("cardHVcapa3PosTr4",
4264 fgkHVCardCapa3PosX4, fgkHVCardCapa3PosY2,
4265 -fgkHVCardCeramZ/2-fgkHVCardCapa3Z/2);
4267 TGeoTranslation *capa3PosTr5 = new TGeoTranslation("cardHVcapa3PosTr5",
4268 fgkHVCardCapa3PosX5, fgkHVCardCapa3PosY3,
4269 -fgkHVCardCeramZ/2-fgkHVCardCapa3Z/2);
4271 highVCard->AddNode(capa3, 1, capa3PosTr1);
4272 highVCard->AddNode(capa3, 2, capa3PosTr2);
4273 highVCard->AddNode(capa3, 3, capa3PosTr3);
4274 highVCard->AddNode(capa3, 4, capa3PosTr4);
4275 highVCard->AddNode(capa3, 5, capa3PosTr5);
4277 //====================================
4278 //--- connexions to LV card
4280 Double_t fgkConnexLVHVdiam1 = 0.8*fgkmm;
4281 Double_t fgkConnexLVHVdiam2 = 2*fgkmm;
4282 Double_t fgkConnexLVHVlen = 6.2*fgkmm;
4283 Double_t fgkConnexLVHVx = 3*fgkmm;
4284 Double_t fgkConnexLVHVy1 = 8*fgkmm;
4285 Double_t fgkConnexLVHVdy = 2.5*fgkmm;
4287 TGeoTube *connexLVHVmetal = new TGeoTube("connexLVHVmetal",0,
4288 fgkConnexLVHVdiam1/2,fgkConnexLVHVlen/2);
4289 TGeoTube *connexLVHVplastic = new TGeoTube("connexLVHVplastic",
4290 fgkConnexLVHVdiam1/2,
4291 fgkConnexLVHVdiam2/2,
4292 fgkConnexLVHVlen/2);
4293 TGeoVolume *vConnexLVHVmetal = new TGeoVolume("ITSsddConnexLVHVmetal",
4294 connexLVHVmetal, stainless);
4295 TGeoVolume *vConnexLVHVplast = new TGeoVolume("ITSsddConnexLVHVplast",
4296 connexLVHVplastic, plastic);
4297 vConnexLVHVmetal->SetLineColor(10);// white
4298 vConnexLVHVplast->SetLineColor(12); // dark grey
4300 TGeoVolumeAssembly *connexion = new TGeoVolumeAssembly("ITSsddConnexLVHV");
4301 connexion->AddNode(vConnexLVHVmetal, 1, 0);
4302 connexion->AddNode(vConnexLVHVplast, 1, 0);
4304 TGeoTranslation *trConnexion1 = new TGeoTranslation(-fgkConnexLVHVx,fgkConnexLVHVy1,
4305 -fgkHVCardCeramZ/2-fgkConnexLVHVlen/2 );
4306 TGeoTranslation *trConnexion2 = new TGeoTranslation( fgkConnexLVHVx,fgkConnexLVHVy1,
4307 -fgkHVCardCeramZ/2-fgkConnexLVHVlen/2 );
4309 TGeoTranslation *trConnexion3 = new TGeoTranslation(-fgkConnexLVHVx,
4310 fgkConnexLVHVy1+fgkConnexLVHVdy,
4311 -fgkHVCardCeramZ/2-fgkConnexLVHVlen/2 );
4312 TGeoTranslation *trConnexion4 = new TGeoTranslation( fgkConnexLVHVx,
4313 fgkConnexLVHVy1+fgkConnexLVHVdy,
4314 -fgkHVCardCeramZ/2-fgkConnexLVHVlen/2 );
4316 TGeoTranslation *trConnexion5 = new TGeoTranslation(-fgkConnexLVHVx,
4317 fgkConnexLVHVy1+2*fgkConnexLVHVdy,
4318 -fgkHVCardCeramZ/2-fgkConnexLVHVlen/2 );
4319 TGeoTranslation *trConnexion6 = new TGeoTranslation( fgkConnexLVHVx,
4320 fgkConnexLVHVy1+2*fgkConnexLVHVdy,
4321 -fgkHVCardCeramZ/2-fgkConnexLVHVlen/2 );
4323 TGeoTranslation *trConnexion7 = new TGeoTranslation(-fgkConnexLVHVx,
4324 fgkConnexLVHVy1+3*fgkConnexLVHVdy,
4325 -fgkHVCardCeramZ/2-fgkConnexLVHVlen/2 );
4326 TGeoTranslation *trConnexion8 = new TGeoTranslation( fgkConnexLVHVx,
4327 fgkConnexLVHVy1+3*fgkConnexLVHVdy,
4328 -fgkHVCardCeramZ/2-fgkConnexLVHVlen/2 );
4330 highVCard->AddNode(connexion, 1, trConnexion1);
4331 highVCard->AddNode(connexion, 2, trConnexion2);
4332 highVCard->AddNode(connexion, 3, trConnexion3);
4333 highVCard->AddNode(connexion, 4, trConnexion4);
4334 highVCard->AddNode(connexion, 5, trConnexion5);
4335 highVCard->AddNode(connexion, 6, trConnexion6);
4336 highVCard->AddNode(connexion, 7, trConnexion7);
4337 highVCard->AddNode(connexion, 8, trConnexion8);
4339 //====================================
4340 //--- cooling pieces
4342 TGeoBBox *cardHVcool1 = new TGeoBBox("cardHVcool1",fgkHVCardCool1X/2,
4343 fgkHVCardCool1Y/2, fgkHVCardCool1Z/2);
4346 TGeoBBox *cardHVcool2 = new TGeoBBox("cardHVcool2",fgkHVCardCool2X/2,
4347 fgkHVCardCool2Y/2, fgkHVCardCool2Z/2);
4349 TGeoBBox *cardHVcool3 = new TGeoBBox("cardHVcool3",fgkHVCardCool3X/2,
4350 fgkHVCardCool3Y/2, fgkHVCardCool3Z/2);
4352 TGeoVolume *vCardHVcool1 = new TGeoVolume("vCardHVcool1",cardHVcool1,
4354 TGeoVolume *vCardHVcool2 = new TGeoVolume("vCardHVcool2",cardHVcool2,
4356 TGeoVolume *vCardHVcool3 = new TGeoVolume("vCardHVcool3",cardHVcool3,
4358 // This last volume contains the screw used for fixing
4359 // the card to the cooling tube ...
4360 TGeoTube *littleScrewHV = new TGeoTube("littleScrewHV", 0, fgkLittleScrewR,
4362 TGeoVolume *vLittleScrewHV = new TGeoVolume("vLittleScrewHV",
4363 littleScrewHV, stainless);
4365 TGeoRotation *rotScrewHead = new TGeoRotation("",0,90,0);
4366 vCardHVcool3->AddNode(vLittleScrewHV, 1,rotScrewHead);
4368 vCardHVcool1->SetLineColor(2); //red
4369 vCardHVcool2->SetLineColor(2); //red
4370 vCardHVcool3->SetLineColor(2); //red
4372 TGeoTranslation *cool1Tr1 = new TGeoTranslation("cardHVcool1Tr1",
4373 fgkHVCardCeramX/2-fgkHVCardCool1X/2,
4374 -fgkHVCardCoolDY+fgkHVCardCool1Y/2,
4375 fgkHVCardCeramZ/2+fgkHVCardCool1Z/2);
4376 TGeoTranslation *cool1Tr2 = new TGeoTranslation("cardHVcool1Tr2",
4377 -fgkHVCardCeramX/2+fgkHVCardCool1X/2,
4378 -fgkHVCardCoolDY+fgkHVCardCool1Y/2,
4379 fgkHVCardCeramZ/2+fgkHVCardCool1Z/2);
4381 highVCard->AddNode(vCardHVcool1, 1, cool1Tr1);
4382 highVCard->AddNode(vCardHVcool1, 2, cool1Tr2);
4384 TGeoTranslation *cool2Tr1 = new TGeoTranslation("cardHVcool2Tr1",
4385 fgkHVCardCeramX/2-fgkHVCardCool1X+fgkHVCardCool2X/2,
4386 -fgkHVCardCoolDY-fgkHVCardCool2Y/2,
4387 fgkHVCardCeramZ/2+fgkHVCardCool2Z/2);
4389 TGeoTranslation *cool2Tr2 = new TGeoTranslation("cardHVcool2Tr2",
4390 -fgkHVCardCeramX/2+fgkHVCardCool1X-fgkHVCardCool2X/2,
4391 -fgkHVCardCoolDY-fgkHVCardCool2Y/2,
4392 fgkHVCardCeramZ/2+fgkHVCardCool2Z/2);
4394 highVCard->AddNode(vCardHVcool2, 1, cool2Tr1);
4395 highVCard->AddNode(vCardHVcool2, 2, cool2Tr2);
4397 TGeoTranslation *cool3Tr1 = new TGeoTranslation("cardHVcool2Tr1",
4398 fgkHVCardCeramX/2-fgkHVCardCool1X+fgkHVCardCool2X+fgkHVCardCool3X/2,
4399 -fgkHVCardCoolDY-fgkHVCardCool3Y/2,
4400 fgkHVCardCeramZ/2+fgkHVCardCool2Z-fgkHVCardCool3Z/2);
4402 TGeoTranslation *cool3Tr2 = new TGeoTranslation("cardHVcool2Tr2",
4403 -fgkHVCardCeramX/2+fgkHVCardCool1X-fgkHVCardCool2X-fgkHVCardCool3X/2,
4404 -fgkHVCardCoolDY-fgkHVCardCool3Y/2,
4405 fgkHVCardCeramZ/2+fgkHVCardCool2Z-fgkHVCardCool3Z/2);
4407 highVCard->AddNode(vCardHVcool3, 1, cool3Tr1);
4408 highVCard->AddNode(vCardHVcool3, 2, cool3Tr2);
4410 //====================================
4412 TGeoCombiTrans *cbScrewHead1 = new TGeoCombiTrans("cardHVscrewHeadTr1",
4413 fgkHVCardCeramX/2-fgkHVCardCool1X+fgkHVCardCool2X+fgkHVCardCool3X/2,
4414 -fgkHVCardCoolDY+fgkLittleScrewHeadH/2,
4415 fgkHVCardCeramZ/2+fgkHVCardCool2Z-fgkHVCardCool3Z/2,
4417 TGeoCombiTrans *cbScrewHead2 = new TGeoCombiTrans("cardHVscrewHeadTr2",
4418 -fgkHVCardCeramX/2+fgkHVCardCool1X-fgkHVCardCool2X-fgkHVCardCool3X/2,
4419 -fgkHVCardCoolDY+fgkLittleScrewHeadH/2,
4420 fgkHVCardCeramZ/2+fgkHVCardCool2Z-fgkHVCardCool3Z/2,
4423 highVCard->AddNode(fCommonVol[0], 1, cbScrewHead1);
4424 highVCard->AddNode(fCommonVol[0], 2, cbScrewHead2);
4429 //________________________________________________________________________
4430 TGeoVolumeAssembly* AliITSv11GeometrySDD::CreateEndLadderCards(Int_t iLay) {
4432 // return an assembly containing the LV, HV and Carlos cards of one ladder
4433 // and their cooling system
4436 TGeoMedium *alCu12SDD = GetMedium("ALCU12$"); // ITSsddAlCu12
4437 TGeoMedium *phynoxSDD = GetMedium("INOX$");
4438 TGeoMedium *coolerMediumSDD = GetMedium("WATER$");
4440 TGeoVolumeAssembly *endLadderCards = new TGeoVolumeAssembly("endLadderCards");
4442 //=*********************************
4443 //--- The rounded pipe for the end ladder card coooling
4445 Double_t endLadPipeUlength = fgkEndLadPipeUlengthLay3;
4446 Double_t endLadPipeArmZ = fgkEndLadPipeArmZLay3;
4450 endLadPipeUlength = fgkEndLadPipeUlengthLay4;
4451 endLadPipeArmZ = fgkEndLadPipeArmZLay4;
4455 AliITSv11GeomCableRound endLadderPipe("endLadderPipe", fgkEndLadPipeOuterDiam/2);
4456 endLadderPipe.SetNLayers(2);
4457 endLadderPipe.SetLayer(0, fgkEndLadPipeInnerDiam/2, coolerMediumSDD, 4);
4458 endLadderPipe.SetLayer(1, (fgkEndLadPipeOuterDiam-fgkEndLadPipeInnerDiam)/2, phynoxSDD, fColorPhynox);
4460 Double_t coolUzPos = fgkEndLadPipeOuterDiam/2+2.*fgkmm; //it is the x coord of the axis
4461 // of the U colling pipe in its center
4463 Double_t coordA[3] = { fgkEndLadPipeUwidth/2, 0, endLadPipeUlength+coolUzPos};
4464 Double_t vectA[3] = {0,0,1};
4466 Double_t coordB[3] = { fgkEndLadPipeUwidth/2,0, fgkEndLadPipeRadius+coolUzPos};
4467 Double_t vectB[3] = {0,0,1};
4469 Double_t coordC[3] = { fgkEndLadPipeUwidth/2-fgkEndLadPipeRadius, 0, coolUzPos};
4470 Double_t vectC[3] = {1,0,0};
4472 Double_t coordD[3] = {-fgkEndLadPipeUwidth/2+fgkEndLadPipeRadius, 0, coolUzPos};
4473 Double_t vectD[3] = {-1,0,0};
4475 Double_t coordE[3] = {-fgkEndLadPipeUwidth/2, 0, fgkEndLadPipeRadius+coolUzPos};
4476 Double_t vectE[3] = {0,0,-1};
4478 Double_t coordF[3] = {-fgkEndLadPipeUwidth/2,0, endLadPipeUlength+coolUzPos};
4479 Double_t vectF[3] = {0,0,-1};
4481 endLadderPipe.AddCheckPoint( (TGeoVolume *) endLadderCards, 0, coordA, vectA);
4482 endLadderPipe.AddCheckPoint( (TGeoVolume *) endLadderCards, 1, coordB, vectB);
4483 endLadderPipe.AddCheckPoint( (TGeoVolume *) endLadderCards, 2, coordC, vectC);
4484 endLadderPipe.AddCheckPoint( (TGeoVolume *) endLadderCards, 3, coordD, vectD);
4485 endLadderPipe.AddCheckPoint( (TGeoVolume *) endLadderCards, 4, coordE, vectE);
4486 endLadderPipe.AddCheckPoint( (TGeoVolume *) endLadderCards, 5, coordF, vectF);
4488 endLadderPipe.SetInitialNode((TGeoVolume *) endLadderCards); //Set the root node
4489 //endLadderPipe.CreateAndInsertCableSegment( 1);
4490 endLadderPipe.CreateAndInsertTubeSegment( 1);
4491 //endLadderPipe.CreateAndInsertCableSegment( 2);
4492 endLadderPipe.CreateAndInsertTorusSegment( 2);
4493 //endLadderPipe.CreateAndInsertCableSegment( 3);
4494 endLadderPipe.CreateAndInsertTubeSegment( 3);
4495 //endLadderPipe.CreateAndInsertCableSegment( 4);
4496 endLadderPipe.CreateAndInsertTorusSegment( 4);
4497 //endLadderPipe.CreateAndInsertCableSegment( 5);
4498 endLadderPipe.CreateAndInsertTubeSegment( 5);
4500 TGeoBBox *endLadPipeArmBox = new TGeoBBox("endLadPipeArmBox",fgkEndLadPipeArmX/2,
4501 fgkEndLadPipeArmY/2, endLadPipeArmZ/2);
4502 TGeoTube *endLadPipeArmTube = new TGeoTube("endLadPipeArmTube", 0,
4503 fgkEndLadPipeOuterDiam/2, endLadPipeArmZ/2);
4505 TGeoTranslation *endLadPipeArmBoxDY1 = new TGeoTranslation("endLadPipeArmBoxDY1",
4506 - fgkEndLadPipeArmBoxDX,
4507 fgkEndLadPipeArmBoxDY,0);
4508 TGeoTranslation *endLadPipeArmBoxDY2 = new TGeoTranslation("endLadPipeArmBoxDY2",
4509 fgkEndLadPipeArmBoxDX,
4510 fgkEndLadPipeArmBoxDY,0);
4511 endLadPipeArmBoxDY1->RegisterYourself();
4512 endLadPipeArmBoxDY2->RegisterYourself();
4514 if(GetDebug(3)) { // Remove compiler warning.
4515 endLadPipeArmBox->InspectShape();
4516 endLadPipeArmTube->InspectShape();
4519 TGeoCompositeShape *endLadPipeArm1 = new TGeoCompositeShape("ITSsddEndLadPipeArm1",
4520 "endLadPipeArmBox:endLadPipeArmBoxDY1"
4521 "- endLadPipeArmTube");
4522 TGeoCompositeShape *endLadPipeArm2 = new TGeoCompositeShape("ITSsddEndLadPipeArm2",
4523 "endLadPipeArmBox:endLadPipeArmBoxDY2"
4524 "- endLadPipeArmTube");
4526 TGeoVolume *vEndLadPipeArm1 = new TGeoVolume("ITSsddVolEndLadPipeArm1",
4527 endLadPipeArm1, alCu12SDD);
4528 TGeoVolume *vEndLadPipeArm2 = new TGeoVolume("ITSsddVolEndLadPipeArm2",
4529 endLadPipeArm2, alCu12SDD);
4530 vEndLadPipeArm1->SetLineColor(2);
4531 vEndLadPipeArm2->SetLineColor(2);
4533 Double_t armZ = (coolUzPos-fgkEndLadPipeOuterDiam/2+endLadPipeArmZ/2
4534 +fgkEndLadPipeArmZpos);
4536 TGeoTranslation *trEndLadPipeArm1 = new TGeoTranslation("trEndLadPipeArm1",
4537 -fgkEndLadPipeUwidth/2,0,armZ);
4538 TGeoTranslation *trEndLadPipeArm2 = new TGeoTranslation("trEndLadPipeArm2",
4539 fgkEndLadPipeUwidth/2,0,armZ);
4541 endLadderCards->AddNode(vEndLadPipeArm1, 1, trEndLadPipeArm1);
4542 endLadderCards->AddNode(vEndLadPipeArm2, 1, trEndLadPipeArm2);
4544 //=*********************************
4546 TGeoVolumeAssembly *cardLVassemblyR = fCardLVR;
4547 TGeoVolumeAssembly *cardLVassemblyL = fCardLVL;
4549 Double_t spaceBetweenCards = 0.2*fgkmm;
4551 Double_t cardLVxShift = (fgkEndLadPipeUwidth/2-fgkEndLadPipeArmX/2
4552 +fgkEndLadPipeArmBoxDX);
4553 Double_t cardLVyShift = (-fgkLVcoolPosY-fgkLVcoolY1+fgkLVcoolY3
4554 +fgkEndLadPipeArmY/2+fgkEndLadPipeArmBoxDY);
4556 Double_t alLVcoolZ3 = (fgkLVcardCuZ+fgkLVcardZ+2.*(fgkLVChip0SiZ+fgkLVChip0Z)
4559 Double_t firstLVCardZ = fgkEndLadPipeArmZpos-fgkEndLadPipeOuterDiam/2.+alLVcoolZ3/2
4560 +coolUzPos+1.25*fgkmm;
4561 // Position in z of the first LVB with respect to the start of the cooling
4562 // rectangular arm, coming (from inside of the ladder)
4563 // The cards are added one after the other
4565 for (Int_t iCard=0; iCard<nCards; iCard++) {
4567 Double_t cardLVzShift = firstLVCardZ +
4568 Double_t(iCard)*(alLVcoolZ3 + 2.*spaceBetweenCards+fgkHVCardCool3Z);
4570 TGeoTranslation *trCardLVassemblyR = new TGeoTranslation(cardLVxShift,
4571 cardLVyShift, cardLVzShift);
4572 TGeoTranslation *trCardLVassemblyL = new TGeoTranslation(-cardLVxShift,
4573 cardLVyShift, cardLVzShift);
4575 endLadderCards->AddNode(cardLVassemblyR, iCard+1, trCardLVassemblyR);
4576 endLadderCards->AddNode(cardLVassemblyL, iCard+1, trCardLVassemblyL);
4579 //=*********************************
4581 TGeoVolumeAssembly *cardHV = fCardHV;
4583 Double_t coolHVdy = (fgkHVCardCoolDY + fgkHVCardCool3Y
4584 + fgkEndLadPipeArmY/2 + fgkEndLadPipeArmBoxDY);
4586 Double_t coolHVCenterShift = (fgkHVCardCool3Z/2-fgkHVCardCool2Z
4587 -(fgkHVCardCeramZ)/2);
4589 for (Int_t iCard=0; iCard<nCards; iCard++) {
4591 Double_t fact = iCard*2.+1.;
4592 Double_t coolHVdz = (firstLVCardZ + alLVcoolZ3*fact/2 + spaceBetweenCards*fact
4593 + fgkHVCardCool3Z*fact/2. + coolHVCenterShift);
4594 TGeoTranslation *trCardHV = new TGeoTranslation(0,coolHVdy, coolHVdz);
4595 endLadderCards->AddNode(cardHV, iCard+1, trCardHV);
4598 //=*********************************
4601 TGeoVolumeAssembly *assemblySupCarlos = fCardCarlos;
4602 // TGeoRotation *carlosSupRot1 = new TGeoRotation("carlosSuppAngle",
4603 // 0, -fgkCarlosSuppAngle, 0);
4605 Double_t spaceBetweenCarlsoCards = 0.1*fgkmm;
4606 Double_t firstCarlosCardZ = (firstLVCardZ - alLVcoolZ3/2 + alLVcoolZ3*4 +
4607 fgkHVCardCool3Z*4 + spaceBetweenCards*7 + 2*fgkmm);
4608 // position in z of the first Carlos board, coming from inside of the ladder
4610 Double_t coolCarlosDy = (fgkCarlosSuppY3/2 + fgkEndLadPipeArmY/2 +
4611 fgkEndLadPipeArmBoxDY);
4613 for (Int_t iCard=0; iCard<nCards; iCard++) {
4615 Double_t carloszPos = ( firstCarlosCardZ + fgkCarlosSuppZ3/2 +
4616 iCard*(fgkCarlosSuppZ3+spaceBetweenCarlsoCards) );
4617 TGeoCombiTrans *carlosPos = new TGeoCombiTrans(0,coolCarlosDy,carloszPos,
4618 (TGeoRotation*) fCommonTr[0]);
4620 endLadderCards->AddNode(assemblySupCarlos, iCard, carlosPos);
4623 return endLadderCards;
4627 //________________________________________________________________________
4628 TGeoVolume* AliITSv11GeometrySDD::CreateEndLadderCardsV(Int_t iLay) {
4630 // return an Pcon containing the LV, HV and Carlos cards of one ladder
4631 // and their cooling system
4632 // This is the code actually used for the end ladder cards
4635 TGeoMedium *alCu12SDD = GetMedium("ALCU12$"); // ITSsddAlCu12
4636 TGeoMedium *phynoxSDD = GetMedium("INOX$");
4637 TGeoMedium *coolerMediumSDD = GetMedium("WATER$");
4638 TGeoMedium *copper = GetMedium("COPPER$");
4639 TGeoMedium *plastic = GetMedium("SDDKAPTON (POLYCH2)$"); // ???
4640 TGeoMedium *airSDD = GetMedium("SDD AIR$");
4641 TGeoMedium *opticalFiber = GetMedium("SDD OPTICFIB$");
4642 TGeoMedium *polyurethane = GetMedium("POLYURETHANE$");
4644 Double_t endLadPipeUlength = fgkEndLadPipeUlengthLay3;
4645 Double_t endLadPipeArmZ = fgkEndLadPipeArmZLay3;
4647 Double_t rREF = fgkEndLaddCardsShortRadiusLay3;
4648 Double_t deltaZcables = 0;
4649 // reference radius corresponding to local y=0
4652 endLadPipeUlength = fgkEndLadPipeUlengthLay4;
4653 endLadPipeArmZ = fgkEndLadPipeArmZLay4;
4655 rREF = fgkEndLaddCardsShortRadiusLay4;
4656 deltaZcables = 2.8*fgkmm;
4659 Double_t cardLVxShift = (fgkEndLadPipeUwidth/2-fgkEndLadPipeArmX/2
4660 +fgkEndLadPipeArmBoxDX);
4661 Double_t cardLVyShift = (-fgkLVcoolPosY-fgkLVcoolY1+fgkLVcoolY3
4662 +fgkEndLadPipeArmY/2+fgkEndLadPipeArmBoxDY);
4664 Double_t rMin = rREF + cardLVyShift;
4665 // (The LV card is defining rMin because it is the lower object)
4667 Double_t thickTotCable = 0.5;
4669 //==================================
4670 //--- The Pcon container
4672 // minimum angle of the Pcon :
4673 Double_t tanDPhi = ((fgkEndLadPipeUwidth/2+fgkEndLadPipeArmX/2) /
4674 (rREF-fgkEndLadPipeArmY/2) );
4675 Double_t dphi = 2*TMath::ATan(tanDPhi)*TMath::RadToDeg();
4676 Double_t phi0 = 90-dphi/2;
4677 Double_t coolUzPos = fgkEndLadPipeOuterDiam/2 + fgkDistEndLaddCardsLadd; // it is the z coord of the axis
4678 // of the U colling pipe in its center
4679 Double_t zMax = endLadPipeUlength+coolUzPos;
4680 Double_t rMax = rMin + fgkLVcardY;
4681 rMax = TMath::Sqrt(rMax*rMax + cardLVxShift*cardLVxShift);
4682 Double_t cablesRadius = rMax-0.5;
4684 TGeoPcon *containerShape = new TGeoPcon("EndLadderCcontainerShape", phi0, dphi, 10);
4685 //DefineSection(Int_t snum, Double_t z, Double_t rmin, Double_t rmax);
4686 // hard coded numbers are fine tuning to avoid overlaps with other volume in the old geometry
4687 containerShape->DefineSection(0, fgkDistEndLaddCardsLadd, rREF-fgkEndLadPipeOuterDiam/2-0.2, rMax);
4688 containerShape->DefineSection(1, fgkDistEndLaddCardsLadd+1.4, rREF-fgkEndLadPipeOuterDiam/2-0.2, rMax);
4689 containerShape->DefineSection(2, fgkDistEndLaddCardsLadd+1.4, rMin, rMax);
4690 containerShape->DefineSection(3, endLadPipeArmZ+2*fgkEndLadPipeRadius, rMin, rMax);
4691 containerShape->DefineSection(4, endLadPipeArmZ+2*fgkEndLadPipeRadius, rREF-1.*fgkmm, rMax);
4692 containerShape->DefineSection(5, zMax, rREF-1.*fgkmm, rMax);
4693 // the following is quite dirty but works for the moment ...
4694 containerShape->DefineSection(6, zMax, rREF+fgkCarlosCardZ1/2, rMax);
4695 containerShape->DefineSection(7, zMax+1, cablesRadius-thickTotCable/2, rMax);
4697 // The next parameters define the shape of the Pcon at its end and where cables
4699 Double_t cableSectionR1 = cablesRadius-thickTotCable/2;
4700 Double_t cableSectionR2 = rMax;
4701 Double_t cableSectionZ1 = zMax + 23.6*fgkmm + 3.0*fgkcm + deltaZcables;
4702 Double_t cableSectionZ2 = zMax + 23.6*fgkmm + 4.0*fgkcm + deltaZcables;
4703 // Those numbers are to be fixed to stick the maximum to the SDD cone
4704 // (hardcoded numbers are ugly, but it's easier to find where to stop)
4706 containerShape->DefineSection(8, cableSectionZ1, cableSectionR1, rMax);
4707 containerShape->DefineSection(9, cableSectionZ2, cableSectionR2, rMax);
4709 TGeoVolume *endLadderCards = new TGeoVolume("endLadderCards",containerShape,airSDD);
4710 //endLadderCards->SetVisibility(kFALSE);
4712 //=*********************************
4713 //--- The rounded pipe for the end ladder card cooling
4715 AliITSv11GeomCableRound endLadderPipe("endLadderPipe", fgkEndLadPipeOuterDiam/2);
4716 endLadderPipe.SetNLayers(2);
4717 endLadderPipe.SetLayer(0, fgkEndLadPipeInnerDiam/2, coolerMediumSDD, 4);
4718 endLadderPipe.SetLayer(1, (fgkEndLadPipeOuterDiam-fgkEndLadPipeInnerDiam)/2, phynoxSDD, fColorPhynox);
4720 Double_t coordA[3] = { fgkEndLadPipeUwidth/2, rREF, endLadPipeUlength+coolUzPos};
4721 Double_t vectA[3] = {0,0,1};
4723 Double_t coordB[3] = { fgkEndLadPipeUwidth/2,rREF, fgkEndLadPipeRadius+coolUzPos};
4724 Double_t vectB[3] = {0,0,1};
4726 Double_t coordC[3] = { fgkEndLadPipeUwidth/2-fgkEndLadPipeRadius, rREF, coolUzPos};
4727 Double_t vectC[3] = {1,0,0};
4729 Double_t coordD[3] = {-fgkEndLadPipeUwidth/2+fgkEndLadPipeRadius, rREF, coolUzPos};
4730 Double_t vectD[3] = {-1,0,0};
4732 Double_t coordE[3] = {-fgkEndLadPipeUwidth/2, rREF, fgkEndLadPipeRadius+coolUzPos};
4733 Double_t vectE[3] = {0,0,-1};
4735 Double_t coordF[3] = {-fgkEndLadPipeUwidth/2,rREF, endLadPipeUlength+coolUzPos};
4736 Double_t vectF[3] = {0,0,-1};
4738 endLadderPipe.AddCheckPoint( (TGeoVolume *) endLadderCards, 0, coordA, vectA);
4739 endLadderPipe.AddCheckPoint( (TGeoVolume *) endLadderCards, 1, coordB, vectB);
4740 endLadderPipe.AddCheckPoint( (TGeoVolume *) endLadderCards, 2, coordC, vectC);
4741 endLadderPipe.AddCheckPoint( (TGeoVolume *) endLadderCards, 3, coordD, vectD);
4742 endLadderPipe.AddCheckPoint( (TGeoVolume *) endLadderCards, 4, coordE, vectE);
4743 endLadderPipe.AddCheckPoint( (TGeoVolume *) endLadderCards, 5, coordF, vectF);
4745 endLadderPipe.SetInitialNode((TGeoVolume *) endLadderCards); //Set the root node
4746 //endLadderPipe.CreateAndInsertCableSegment( 1);
4747 endLadderPipe.CreateAndInsertTubeSegment( 1);
4748 //endLadderPipe.CreateAndInsertCableSegment( 2);
4749 endLadderPipe.CreateAndInsertTorusSegment( 2);
4750 //endLadderPipe.CreateAndInsertCableSegment( 3);
4751 endLadderPipe.CreateAndInsertTubeSegment( 3);
4752 //endLadderPipe.CreateAndInsertCableSegment( 4);
4753 endLadderPipe.CreateAndInsertTorusSegment( 4);
4754 //endLadderPipe.CreateAndInsertCableSegment( 5);
4755 endLadderPipe.CreateAndInsertTubeSegment( 5);
4757 TGeoBBox *endLadPipeArmBox = new TGeoBBox("endLadPipeArmBox",fgkEndLadPipeArmX/2,
4758 fgkEndLadPipeArmY/2, endLadPipeArmZ/2);
4759 TGeoTube *endLadPipeArmTube = new TGeoTube("endLadPipeArmTube", 0,
4760 fgkEndLadPipeOuterDiam/2, endLadPipeArmZ/2);
4762 TGeoTranslation *endLadPipeArmBoxDY1 = new TGeoTranslation("endLadPipeArmBoxDY1",
4763 - fgkEndLadPipeArmBoxDX,
4764 fgkEndLadPipeArmBoxDY,0);
4765 TGeoTranslation *endLadPipeArmBoxDY2 = new TGeoTranslation("endLadPipeArmBoxDY2",
4766 fgkEndLadPipeArmBoxDX,
4767 fgkEndLadPipeArmBoxDY,0);
4768 endLadPipeArmBoxDY1->RegisterYourself();
4769 endLadPipeArmBoxDY2->RegisterYourself();
4771 if(GetDebug(3)) { // Remove compiler warning.
4772 endLadPipeArmBox->InspectShape();
4773 endLadPipeArmTube->InspectShape();
4776 TGeoCompositeShape *endLadPipeArm1 = new TGeoCompositeShape("ITSsddEndLadPipeArm1",
4777 "endLadPipeArmBox:endLadPipeArmBoxDY1"
4778 "- endLadPipeArmTube");
4779 TGeoCompositeShape *endLadPipeArm2 = new TGeoCompositeShape("ITSsddEndLadPipeArm2",
4780 "endLadPipeArmBox:endLadPipeArmBoxDY2"
4781 "- endLadPipeArmTube");
4783 TGeoVolume *vEndLadPipeArm1 = new TGeoVolume("ITSsddVolEndLadPipeArm1",
4784 endLadPipeArm1, alCu12SDD);
4785 TGeoVolume *vEndLadPipeArm2 = new TGeoVolume("ITSsddVolEndLadPipeArm2",
4786 endLadPipeArm2, alCu12SDD);
4787 vEndLadPipeArm1->SetLineColor(2);
4788 vEndLadPipeArm2->SetLineColor(2);
4790 Double_t armZ = (coolUzPos-fgkEndLadPipeOuterDiam/2+endLadPipeArmZ/2
4791 +fgkEndLadPipeArmZpos);
4793 TGeoTranslation *trEndLadPipeArm1 = new TGeoTranslation("trEndLadPipeArm1",
4794 -fgkEndLadPipeUwidth/2,rREF,armZ);
4795 TGeoTranslation *trEndLadPipeArm2 = new TGeoTranslation("trEndLadPipeArm2",
4796 fgkEndLadPipeUwidth/2,rREF,armZ);
4798 endLadderCards->AddNode(vEndLadPipeArm1, 1, trEndLadPipeArm1);
4799 endLadderCards->AddNode(vEndLadPipeArm2, 1, trEndLadPipeArm2);
4801 //=*********************************
4803 TGeoVolumeAssembly *cardLVassemblyR = fCardLVR;
4804 TGeoVolumeAssembly *cardLVassemblyL = fCardLVL;
4806 Double_t spaceBetweenCards = 0.2*fgkmm;
4809 Double_t alLVcoolZ3 = (fgkLVcardCuZ+fgkLVcardZ+2.*(fgkLVChip0SiZ+fgkLVChip0Z)
4812 Double_t firstLVCardZ = fgkEndLadPipeArmZpos-fgkEndLadPipeOuterDiam/2.+alLVcoolZ3/2
4813 +coolUzPos+1.25*fgkmm;
4814 // Position in z of the first LVB with respect to the start of the cooling
4815 // rectangular arm, coming (from inside of the ladder)
4816 // The cards are added one after the other
4818 for (Int_t iCard=0; iCard<nCards; iCard++) {
4820 Double_t cardLVzShift = firstLVCardZ +
4821 Double_t(iCard)*(alLVcoolZ3 + 2.*spaceBetweenCards+fgkHVCardCool3Z);
4823 TGeoTranslation *trCardLVassemblyR = new TGeoTranslation(cardLVxShift,
4824 cardLVyShift+rREF, cardLVzShift);
4825 TGeoTranslation *trCardLVassemblyL = new TGeoTranslation(-cardLVxShift,
4826 cardLVyShift+rREF, cardLVzShift);
4828 endLadderCards->AddNode(cardLVassemblyR, iCard+1, trCardLVassemblyR);
4829 endLadderCards->AddNode(cardLVassemblyL, iCard+1, trCardLVassemblyL);
4832 //=*********************************
4834 TGeoVolumeAssembly *cardHV = fCardHV;
4836 Double_t coolHVdy = (fgkHVCardCoolDY + fgkHVCardCool3Y
4837 + fgkEndLadPipeArmY/2 + fgkEndLadPipeArmBoxDY);
4838 // shift of the HV card in local y w.r.t the local y=0 (center of cooling tube)
4840 Double_t coolHVCenterShift = (fgkHVCardCool3Z/2-fgkHVCardCool2Z
4841 -(fgkHVCardCeramZ)/2);
4843 for (Int_t iCard=0; iCard<nCards; iCard++) {
4845 Double_t fact = iCard*2.+1.;
4846 Double_t coolHVdz = (firstLVCardZ + alLVcoolZ3*fact/2 + spaceBetweenCards*fact
4847 + fgkHVCardCool3Z*fact/2. + coolHVCenterShift);
4848 TGeoTranslation *trCardHV = new TGeoTranslation(0,coolHVdy+rREF, coolHVdz);
4849 endLadderCards->AddNode(cardHV, iCard+1, trCardHV);
4852 //=*********************************
4855 TGeoVolumeAssembly *assemblySupCarlos = fCardCarlos;
4856 // TGeoRotation *carlosSupRot1 = new TGeoRotation("carlosSuppAngle",
4857 // 0, -fgkCarlosSuppAngle, 0);
4859 Double_t spaceBetweenCarlsoCards = 0.1*fgkmm;
4860 Double_t firstCarlosCardZ = (firstLVCardZ - alLVcoolZ3/2 + alLVcoolZ3*4 +
4861 fgkHVCardCool3Z*4 + spaceBetweenCards*7 + 2*fgkmm);
4862 // position in z of the first Carlos board, coming from inside of the ladder
4864 Double_t coolCarlosDy = (fgkCarlosSuppY3/2 + fgkEndLadPipeArmY/2 +
4865 fgkEndLadPipeArmBoxDY);
4867 for (Int_t iCard=0; iCard<nCards; iCard++) {
4869 Double_t carloszPos = ( firstCarlosCardZ + fgkCarlosSuppZ3/2 +
4870 iCard*(fgkCarlosSuppZ3+spaceBetweenCarlsoCards) );
4871 TGeoCombiTrans *carlosPos = new TGeoCombiTrans(0,coolCarlosDy+rREF,carloszPos,
4872 (TGeoRotation*) fCommonTr[0]);
4874 endLadderCards->AddNode(assemblySupCarlos, iCard, carlosPos);
4878 //=*********************************
4882 Double_t sectionV = (fgkSectionCuPerMod+fgkSectionPlastPerMod
4883 + fgkSectionGlassPerMod)*nCards
4884 + fgkSectionCoolPolyuEL + fgkSectionCoolWaterEL;
4885 // We fix thickness, then width is calculated accordingly
4886 Double_t width = sectionV/thickTotCable;
4887 Double_t thickCu = thickTotCable*fgkSectionCuPerMod
4888 / (fgkSectionCuPerMod+fgkSectionPlastPerMod+fgkSectionGlassPerMod+fgkSectionCoolPolyuEL+fgkSectionCoolWaterEL);
4889 Double_t thickPlast = thickTotCable*fgkSectionPlastPerMod
4890 / (fgkSectionCuPerMod+fgkSectionPlastPerMod+fgkSectionGlassPerMod+fgkSectionCoolPolyuEL+fgkSectionCoolWaterEL);
4891 Double_t thickGlass = thickTotCable*fgkSectionGlassPerMod
4892 / (fgkSectionCuPerMod+fgkSectionPlastPerMod+fgkSectionGlassPerMod+fgkSectionCoolPolyuEL+fgkSectionCoolWaterEL);
4894 Double_t thickCoolPolyu = thickTotCable*fgkSectionCoolPolyuEL
4895 / (fgkSectionCuPerMod+fgkSectionPlastPerMod+fgkSectionGlassPerMod+fgkSectionCoolPolyuEL+fgkSectionCoolWaterEL);
4896 Double_t thickCoolWater = thickTotCable*fgkSectionCoolWaterEL
4897 / (fgkSectionCuPerMod+fgkSectionPlastPerMod+fgkSectionGlassPerMod+fgkSectionCoolPolyuEL+fgkSectionCoolWaterEL);
4899 AliITSv11GeomCableFlat cable("SDDcableEndLadder",width,thickTotCable);
4900 cable.SetNLayers(5);
4901 cable.SetLayer(0, thickCu, copper, kRed);
4902 cable.SetLayer(1, thickPlast, plastic, kYellow);
4903 cable.SetLayer(2, thickGlass, opticalFiber, kGreen);
4904 cable.SetLayer(3, thickCoolPolyu, polyurethane, kGray);
4905 cable.SetLayer(4, thickCoolWater, coolerMediumSDD, kBlue);
4907 Double_t zVect[3]={0,0,1};
4908 Double_t xMinCable = firstCarlosCardZ+nCards*(fgkCarlosSuppZ3
4909 +spaceBetweenCarlsoCards)/2 + 2.9;
4910 // the 2.9cm is for taking into account carlos card angle...
4912 Double_t zEndCable = GetConeZ(cablesRadius-thickTotCable/2, cableSectionR1,
4913 cableSectionR2,cableSectionZ1,cableSectionZ2);
4915 Double_t pos1[3] = {0, cablesRadius, xMinCable};
4916 Double_t pos2[3] = {0, cablesRadius, zEndCable};
4917 cable.AddCheckPoint( endLadderCards, 0, pos1, zVect );
4918 cable.AddCheckPoint( endLadderCards, 1, pos2, zVect );
4919 cable.SetInitialNode(endLadderCards);
4920 cable.CreateAndInsertCableSegment(1);
4923 TGeoTorus *earthShape = new TGeoTorus(rMax-fgkEndLadderEarthCableR,
4924 0., fgkEndLadderEarthCableR,
4925 phi0, dphi); // same as containerShape
4927 TGeoVolume *earthCable = new TGeoVolume("SDDcableEndLadderEarthCable",
4928 earthShape, copper);
4930 endLadderCards->AddNode(earthCable, 1,
4931 new TGeoTranslation(0, 0, fgkDistEndLaddCardsLadd+1));
4933 return endLadderCards;
4936 //________________________________________________________________________
4937 TGeoVolumeAssembly* AliITSv11GeometrySDD::CreateSupportRing() {
4939 // return an assembly of the support rings, attaching the ladders to the cone
4944 TGeoMedium *stainless = GetMedium("INOX$"); // To code !!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!
4945 TGeoVolumeAssembly *supportRing = new TGeoVolumeAssembly("supportRing");
4948 //**********************************
4951 Double_t fgkRubyCageX = 9*fgkmm;
4952 Double_t fgkRubyCageY = 5.5*fgkmm;
4953 Double_t fgkRubyCageZ = 8*fgkmm;
4954 Double_t fgkRubyCageInternSide = 5.*fgkmm; //side of the internal square
4955 Double_t fgkRubyCageHoleDX = 2.*fgkmm;
4956 Double_t fgkRubyCageVIntern = 5.42*fgkmm;
4957 Double_t fgkRubyCageScrewHoleR = 4.5/2*fgkmm;
4958 Double_t fgkRubyCageScrewHoleY = 1.5*fgkmm;
4960 TGeoBBox *rubyCageBox = new TGeoBBox("rubyCageBox",fgkRubyCageX/2,fgkRubyCageY/2,
4963 Double_t epsilon = 1e-10; //dummy epsilon to force the gl viewer to show holes
4965 // pieces common to both square and V cages
4966 TGeoBBox *rubyCageInternBox = new TGeoBBox("rubyCageInternBox",fgkRubyCageInternSide/2,
4967 fgkRubyCageY/2+epsilon, fgkRubyCageInternSide/2);
4969 TGeoTube *screwHole = new TGeoTube("screwHole", 0, fgkRubyCageScrewHoleR,
4970 fgkRubyCageHoleDX/2+epsilon);
4972 TGeoRotation *rotV = new TGeoRotation("", 90,90,-90);
4973 TGeoCombiTrans *trScrewHole = new TGeoCombiTrans("trScrewHole",
4974 fgkRubyCageX/2-fgkRubyCageHoleDX/2,
4975 -fgkRubyCageY/2+fgkRubyCageScrewHoleY,0,rotV);
4976 trScrewHole->RegisterYourself();
4978 TGeoBBox *screwHoleFoot = new TGeoBBox("screwHoleFoot",fgkRubyCageHoleDX/2+epsilon,
4979 fgkRubyCageScrewHoleY/2+epsilon, fgkRubyCageScrewHoleR);
4980 TGeoTranslation *trScrewHoleFoot = new TGeoTranslation("trScrewHoleFoot",
4981 fgkRubyCageX/2-fgkRubyCageHoleDX/2,
4982 -fgkRubyCageY/2+fgkRubyCageScrewHoleY/2, 0);
4983 trScrewHoleFoot->RegisterYourself();
4986 // pieces which differ
4987 Double_t rubyCageVInternBoxX = fgkRubyCageVIntern - fgkRubyCageInternSide/2;
4989 TGeoBBox *rubyCageVInternBox = new TGeoBBox("rubyCageVInternBox",rubyCageVInternBoxX/2,
4990 fgkRubyCageY/2+epsilon, fgkRubyCageInternSide/2);
4992 TGeoTranslation *trRubyCageVInternBox = new TGeoTranslation("trRubyCageVInternB",
4993 fgkRubyCageX/2-fgkRubyCageHoleDX-rubyCageVInternBoxX/2,0,0);
4994 trRubyCageVInternBox->RegisterYourself();
4996 TGeoTrd1 *rubyCageVInternTriangl = new TGeoTrd1("rubyCageVInternTriangl", 0,
4997 fgkRubyCageInternSide/2, fgkRubyCageY/2+epsilon,
4998 fgkRubyCageInternSide/4);
5000 TGeoCombiTrans *trRubyCageVInternTriangl = new TGeoCombiTrans("trRubyCageVInternTriangl",
5001 fgkRubyCageX/2-fgkRubyCageHoleDX-rubyCageVInternBoxX-fgkRubyCageInternSide/4
5002 +epsilon,0,0, rotV );
5003 trRubyCageVInternTriangl->RegisterYourself();
5006 TGeoCompositeShape *rubyCageSquare = new TGeoCompositeShape("rubyCageSquare",
5007 "rubyCageBox-(rubyCageInternBox"
5008 "+screwHole:trScrewHole+screwHoleFoot:trScrewHoleFoot)");
5010 TGeoVolume *vRubyCageSquare = new TGeoVolume("vRubyCageSquare",
5011 rubyCageSquare, stainless);
5012 vRubyCageSquare->SetLineColor(10);
5014 TGeoCompositeShape *rubyCageV = new TGeoCompositeShape("rubyCageV",
5015 "rubyCageBox-(rubyCageVInternBox:trRubyCageVInternB"
5016 "+rubyCageVInternTriangl:trRubyCageVInternTriangl"
5017 "+screwHole:trScrewHole+screwHoleFoot:trScrewHoleFoot)");
5018 TGeoVolume *vRubyCageV = new TGeoVolume("vRubyCageV", rubyCageV, stainless);
5019 vRubyCageV->SetLineColor(10);
5021 if(GetDebug(3)) { // Remove compiler warning.
5022 rubyCageBox->InspectShape();
5023 rubyCageInternBox->InspectShape();
5024 screwHole->InspectShape();
5025 screwHoleFoot->InspectShape();
5026 rubyCageVInternBox->InspectShape();
5027 rubyCageVInternTriangl->InspectShape();
5030 supportRing->AddNode(vRubyCageSquare, 0, 0);
5031 //supportRing->AddNode(vRubyCageV, 0, 0);
5037 //________________________________________________________________________
5038 void AliITSv11GeometrySDD::CreateSDDsensor() {
5040 // return a box containing the SDD sensor
5043 TGeoMedium *airSDD = GetMedium("SDD AIR$");
5044 TGeoMedium *siliconSDD = GetMedium("SDD SI insensitive$"); // ITSsddSi
5045 TGeoMedium *siliconSDDsens = GetMedium("SI$"); // ITSsddSi
5046 TGeoMedium *alSDD = GetMedium("AL$"); // ITSal
5047 TGeoMedium *polyhamideSDD = GetMedium("SDDKAPTON (POLYCH2)$"); // ITSsddKAPTON_POLYCH2
5048 TGeoMedium *glassSDD = GetMedium("STDGLASS$"); // StdGlass
5051 Double_t rWraping = fgkWaferThickness/2+fgkWaHVcableAlThick+fgkWaHVcablePolyThick;
5052 Double_t witdhCableBox = (fgkWaHVcableWitdh - TMath::Pi()*rWraping)/2;
5053 // width : in the beam direction !
5055 Double_t sensoxBoxLength = ( fgkWaferLength +
5056 2*(rWraping+witdhCableBox-fgkWaHVcableDW) );
5057 // Makes life easier to include the space for the WA HV cable on both sides
5058 Double_t sensoxBoxThick = fgkWaferThickness +
5059 2*(fgkWaHVcableAlThick+fgkWaHVcablePolyThick);
5061 // cout << "fgkWaferLength=" << fgkWaferLength << " sensoxBoxLength="<< sensoxBoxLength <<endl;
5062 // cout << "fgkWaferThickness=" << fgkWaferThickness << " sensoxBoxThick=" << sensoxBoxThick << endl;
5064 TGeoBBox *box = new TGeoBBox("ITSsddSensorBox",
5065 fgkWaferWidth/2, sensoxBoxThick/2, sensoxBoxLength/2);
5067 fSDDsensor3 = new TGeoVolume("ITSsddSensor3", box, airSDD);
5068 fSDDsensor4 = new TGeoVolume("ITSsddSensor4", box, airSDD);
5071 //****************************
5073 //****************************
5075 // we need 2 different sensor objects, because they have to have different names
5076 // This is required for the step manager
5078 TGeoBBox *waferShape = new TGeoBBox("ITSsddWaferShape",
5079 fgkWaferWidth/2, fgkWaferThickness/2, fgkWaferLength/2);
5082 TGeoVolume *wafer3 = new TGeoVolume("ITSsddWafer3", waferShape, siliconSDD);
5083 wafer3->SetLineColor(fColorSilicon);
5084 TGeoBBox *sensBox3 = new TGeoBBox("ITSsddSensorSensBox3",
5085 fgkWaferWidthSens/2, fgkWaferThickSens/2, fgkWaferLengthSens/2);
5086 TGeoVolume *sensVol3 = new TGeoVolume(fgkSDDsensitiveVolName3,sensBox3, siliconSDDsens);
5087 sensVol3->SetLineColor(fColorSilicon+5);
5088 wafer3->AddNode(sensVol3, 1, 0);
5089 fSDDsensor3->AddNode(wafer3, 1, 0);
5091 TGeoVolume *wafer4 = new TGeoVolume("ITSsddWafer4", waferShape, siliconSDD);
5092 wafer4->SetLineColor(fColorSilicon);
5093 TGeoBBox *sensBox4 = new TGeoBBox("ITSsddSensorSensBox4",
5094 fgkWaferWidthSens/2, fgkWaferThickSens/2, fgkWaferLengthSens/2);
5095 TGeoVolume *sensVol4 = new TGeoVolume(fgkSDDsensitiveVolName4,sensBox4, siliconSDDsens);
5096 sensVol4->SetLineColor(fColorSilicon+5);
5097 wafer4->AddNode(sensVol4, 1, 0);
5098 fSDDsensor4->AddNode(wafer4, 1, 0);
5101 //****************************
5103 //****************************
5104 TGeoBBox *glass = new TGeoBBox("ITSsddGlassBox", fgkSensorGlassLX/2,
5105 fgkSensorGlassLY/2, fgkSensorGlassLZ/2);
5106 TGeoVolume *vGlass = new TGeoVolume("ITSsddGlass",glass, glassSDD);
5107 vGlass->SetLineColor(fColorGlass);
5108 TGeoTranslation *glassTr1 = new TGeoTranslation("",fgkGlassDXOnSensor,
5109 fgkWaferThickness/2+fgkSensorGlassLY/2,
5110 fgkGlassDZOnSensor);
5111 TGeoTranslation *glassTr2 = new TGeoTranslation("",-fgkGlassDXOnSensor,
5112 fgkWaferThickness/2+fgkSensorGlassLY/2,
5113 fgkGlassDZOnSensor);
5114 TGeoTranslation *glassTr3 = new TGeoTranslation("",fgkGlassDXOnSensor,
5115 fgkWaferThickness/2+fgkSensorGlassLY/2,
5116 -fgkGlassDZOnSensor);
5117 TGeoTranslation *glassTr4 = new TGeoTranslation("",-fgkGlassDXOnSensor,
5118 fgkWaferThickness/2+fgkSensorGlassLY/2,
5119 -fgkGlassDZOnSensor);
5120 fSDDsensor3->AddNode(vGlass, 1, glassTr1);
5121 fSDDsensor3->AddNode(vGlass, 2, glassTr2);
5122 fSDDsensor3->AddNode(vGlass, 3, glassTr3);
5123 fSDDsensor3->AddNode(vGlass, 4, glassTr4);
5125 fSDDsensor4->AddNode(vGlass, 1, glassTr1);
5126 fSDDsensor4->AddNode(vGlass, 2, glassTr2);
5127 fSDDsensor4->AddNode(vGlass, 3, glassTr3);
5128 fSDDsensor4->AddNode(vGlass, 4, glassTr4);
5130 //****************************
5131 // Wrap-around cable
5132 //****************************
5134 AliITSv11GeomCableFlat waHVCable("ITSsddWaHVCableU",witdhCableBox,
5135 fgkWaHVcableAlThick+fgkWaHVcablePolyThick);
5136 waHVCable.SetNLayers(2);
5137 waHVCable.SetLayer(0, fgkWaHVcablePolyThick,polyhamideSDD,fColorPolyhamide);
5138 waHVCable.SetLayer(1, fgkWaHVcableAlThick, alSDD, fColorAl);
5139 waHVCable.SetInitialNode(fSDDsensor3);
5141 Double_t x1[3], x2[3], vX[3] = {1,0,0};
5142 x1[0] = -fgkWaHVcableLength/2;
5144 x1[1] = (fgkWaferThickness + waHVCable.GetThickness())/2;
5146 x1[2] = fgkWaferLength/2+waHVCable.GetWidth()/2-fgkWaHVcableDW;
5149 waHVCable.AddCheckPoint(fSDDsensor3, 0, x1, vX);
5150 waHVCable.AddCheckPoint(fSDDsensor3, 1, x2, vX);
5151 TGeoCombiTrans *ctSegment = 0;
5152 TGeoVolume* segment = waHVCable.CreateAndInsertBoxCableSegment(1,-90, &ctSegment);
5153 fSDDsensor4->AddNode(segment, 1, ctSegment);
5157 waHVCable.SetName("ITSsddWaHVCableD");
5158 waHVCable.ResetPoints();
5159 waHVCable.AddCheckPoint(fSDDsensor3, 0, x1, vX);
5160 waHVCable.AddCheckPoint(fSDDsensor3, 1, x2, vX);
5161 segment = waHVCable.CreateAndInsertBoxCableSegment(1, 90, &ctSegment);
5162 fSDDsensor4->AddNode(segment, 1, ctSegment);
5164 AliITSv11GeomCableRound waHVCableFold("ITSsddWaHVCableFold",
5166 waHVCableFold.SetPhi(180,360);
5167 waHVCableFold.SetNLayers(2);
5168 waHVCableFold.SetLayer(0, fgkWaferThickness/2+fgkWaHVcablePolyThick,
5169 polyhamideSDD, fColorPolyhamide);
5170 waHVCableFold.SetLayer(1, fgkWaHVcableAlThick, alSDD, fColorAl);
5171 waHVCableFold.SetInitialNode(fSDDsensor3);
5174 x1[2] = fgkWaferLength/2-fgkWaHVcableDW+witdhCableBox;
5176 waHVCableFold.AddCheckPoint(fSDDsensor3, 0, x1, vX);
5177 waHVCableFold.AddCheckPoint(fSDDsensor3, 1, x2, vX);
5178 segment = waHVCableFold.CreateAndInsertCableSegment(1, &ctSegment);
5179 fSDDsensor4->AddNode(segment, 1, ctSegment);
5182 //****************************
5184 //****************************
5185 Double_t headRadius = (fgkTransitHVHeadLX*fgkTransitHVHeadLX/4.+
5186 fgkTransitHVHeadLZ*fgkTransitHVHeadLZ)
5187 /(2.*fgkTransitHVHeadLZ);
5188 Double_t theta = TMath::ATan2(fgkTransitHVHeadLX/2,
5189 headRadius-fgkTransitHVHeadLZ)
5192 TGeoTubeSeg *headPoly = new TGeoTubeSeg(0,headRadius,
5193 fgkTransitHVPolyThick/2,
5195 headPoly->SetName("headPoly");
5196 TGeoTranslation *headPolyTr = new TGeoTranslation(0,0,
5197 -fgkTransitHVPolyThick/2);
5198 headPolyTr->SetName("headPolyTr");
5199 headPolyTr->RegisterYourself();
5201 TGeoTubeSeg *headAl = new TGeoTubeSeg(0,headRadius,
5202 fgkTransitHVAlThick/2,
5204 headAl->SetName("headAl");
5205 TGeoTranslation *headAlTr = new TGeoTranslation(0,0,
5206 -fgkTransitHVPolyThick
5207 -fgkTransitHVAlThick/2);
5208 headAlTr->SetName("headAlTr");
5209 headAlTr->RegisterYourself();
5211 TGeoBBox *cache = new TGeoBBox(fgkTransitHVHeadLX/2,
5212 (headRadius-fgkTransitHVHeadLZ)/2,
5213 (fgkTransitHVPolyThick+fgkTransitHVAlThick)/2);
5214 cache->SetName("cache");
5216 TGeoTranslation *headCacheTr = new TGeoTranslation(0,
5217 (headRadius-fgkTransitHVHeadLZ)/2,
5218 -(fgkTransitHVPolyThick
5219 +fgkTransitHVAlThick)/2);
5220 headCacheTr->SetName("cacheTr");
5221 headCacheTr->RegisterYourself();
5223 TGeoCompositeShape *headPolyComp = new TGeoCompositeShape(
5224 "headPoly:headPolyTr-cache:cacheTr");
5225 TGeoVolume *vHeadPolyComp = new TGeoVolume(
5226 "ITSsddHVtransitHeadPoly",headPolyComp, polyhamideSDD);
5227 vHeadPolyComp->SetLineColor(fColorPolyhamide);
5228 TGeoCompositeShape *headAlComp = new TGeoCompositeShape(
5229 "headAl:headAlTr-cache:cacheTr");
5230 TGeoVolume *vHeadAlComp = new TGeoVolume(
5231 "ITSsddHVtransitHeadAl",headAlComp, alSDD);
5232 vHeadAlComp->SetLineColor(fColorAl);
5235 // TGeoRotation rotHead("",0,90,0);
5236 // TGeoCombiTrans *rotHeadTr = new TGeoCombiTrans(0,fgkWaferThickness/2,
5237 // -headRadius+fgkTransitHVHeadLZ+fgkTransitHVBondingLZ/2,
5239 TGeoRotation *rotHead = new TGeoRotation("",0,90,0);
5240 TGeoCombiTrans *rotHeadTr = new TGeoCombiTrans(0,fgkWaferThickness/2,
5241 -headRadius+fgkTransitHVHeadLZ+fgkTransitHVBondingLZ/2,
5244 fSDDsensor3->AddNode(vHeadPolyComp,1,rotHeadTr);
5245 fSDDsensor3->AddNode(vHeadAlComp,1,rotHeadTr);
5246 fSDDsensor4->AddNode(vHeadPolyComp,1,rotHeadTr);
5247 fSDDsensor4->AddNode(vHeadAlComp,1,rotHeadTr);
5250 AliITSv11GeomCableFlat transitHVCable("ITSsddHVtransitCenter",
5251 fgkTransitHVBondingLZ,
5252 fgkTransitHVPolyThick+fgkTransitHVAlThick);
5253 transitHVCable.SetNLayers(2);
5254 transitHVCable.SetLayer(0, fgkTransitHVPolyThick,polyhamideSDD,
5256 transitHVCable.SetLayer(1, fgkTransitHVAlThick, alSDD, fColorAl);
5257 transitHVCable.SetInitialNode(fSDDsensor3);
5259 x1[0] = -fgkTransitHVHeadLX/2;
5261 x1[1] = (fgkWaferThickness+fgkTransitHVPolyThick+fgkTransitHVAlThick)/2;
5265 transitHVCable.AddCheckPoint(fSDDsensor3, 0, x1, vX);
5266 transitHVCable.AddCheckPoint(fSDDsensor3, 1, x2, vX);
5267 segment = transitHVCable.CreateAndInsertBoxCableSegment(1,-90,&ctSegment);
5268 fSDDsensor4->AddNode(segment, 1, ctSegment);
5270 transitHVCable.ResetPoints();
5271 transitHVCable.SetName("ITSsddHVtransitTail");
5272 transitHVCable.SetWidth(fgkTransitHVtailWidth);
5273 x1[0] = fgkTransitHVtailXpos;
5274 x2[0] = fgkTransitHVtailXpos;
5275 x1[2] = -fgkTransitHVBondingLZ/2;
5276 x2[2] = -fgkTransitHVBondingLZ/2-fgkTransitHVtailLength;
5277 Double_t vZ[3] = {0,0,1};
5278 transitHVCable.AddCheckPoint(fSDDsensor3, 0, x1, vZ);
5279 transitHVCable.AddCheckPoint(fSDDsensor3, 1, x2, vZ);
5280 segment = transitHVCable.CreateAndInsertBoxCableSegment(1,0, &ctSegment);
5281 fSDDsensor4->AddNode(segment, 1, ctSegment);
5284 TGeoArb8 *sideLeft = new TGeoArb8( fgkTransitHVPolyThick/2 );
5285 sideLeft->SetVertex(0, fgkTransitHVtailXpos+fgkTransitHVtailWidth/2,0);
5286 sideLeft->SetVertex(1, fgkTransitHVtailXpos+fgkTransitHVtailWidth/2,
5287 fgkTransitHVsideLZ);
5288 sideLeft->SetVertex(2, fgkTransitHVHeadLX/2, fgkTransitHVsideLeftZ);
5289 sideLeft->SetVertex(3, fgkTransitHVHeadLX/2, 0);
5290 sideLeft->SetVertex(4, fgkTransitHVtailXpos+fgkTransitHVtailWidth/2,0);
5291 sideLeft->SetVertex(5, fgkTransitHVtailXpos+fgkTransitHVtailWidth/2,
5292 fgkTransitHVsideLZ);
5293 sideLeft->SetVertex(6, fgkTransitHVHeadLX/2, fgkTransitHVsideLeftZ);
5294 sideLeft->SetVertex(7, fgkTransitHVHeadLX/2, 0);
5296 TGeoArb8 *sideLeftAl = new TGeoArb8( fgkTransitHVAlThick/2 );
5297 sideLeftAl->SetVertex(0, fgkTransitHVtailXpos+fgkTransitHVtailWidth/2,0);
5298 sideLeftAl->SetVertex(1, fgkTransitHVtailXpos+fgkTransitHVtailWidth/2,
5299 fgkTransitHVsideLZ);
5300 sideLeftAl->SetVertex(2, fgkTransitHVHeadLX/2, fgkTransitHVsideLeftZ);
5301 sideLeftAl->SetVertex(3, fgkTransitHVHeadLX/2, 0);
5302 sideLeftAl->SetVertex(4, fgkTransitHVtailXpos+fgkTransitHVtailWidth/2,0);
5303 sideLeftAl->SetVertex(5, fgkTransitHVtailXpos+fgkTransitHVtailWidth/2,
5304 fgkTransitHVsideLZ);
5305 sideLeftAl->SetVertex(6, fgkTransitHVHeadLX/2, fgkTransitHVsideLeftZ);
5306 sideLeftAl->SetVertex(7, fgkTransitHVHeadLX/2, 0);
5308 // sideRight is not there actually
5309 // TGeoArb8 *sideRight = new TGeoArb8( fgkTransitHVPolyThick/2 );
5310 // sideRight->SetVertex(0, fgkTransitHVtailXpos-fgkTransitHVtailWidth/2,0);
5311 // sideRight->SetVertex(1, fgkTransitHVtailXpos-fgkTransitHVtailWidth/2,
5312 // fgkTransitHVsideLZ);
5313 // sideRight->SetVertex(2, -fgkTransitHVHeadLX/2, fgkTransitHVsideRightZ);
5314 // sideRight->SetVertex(3, -fgkTransitHVHeadLX/2, 0);
5315 // sideRight->SetVertex(4, fgkTransitHVtailXpos-fgkTransitHVtailWidth/2,0);
5316 // sideRight->SetVertex(5, fgkTransitHVtailXpos-fgkTransitHVtailWidth/2,
5317 // fgkTransitHVsideLZ);
5318 // sideRight->SetVertex(6, -fgkTransitHVHeadLX/2, fgkTransitHVsideRightZ);
5319 // sideRight->SetVertex(7, -fgkTransitHVHeadLX/2, 0);
5321 // TGeoRotation rotSide("",0,-90,0);
5322 // TGeoCombiTrans *sideRightTr = new TGeoCombiTrans(0,
5323 // (fgkWaferThickness+fgkTransitHVPolyThick)/2,
5324 // -fgkTransitHVBondingLZ/2,&rotSide);
5325 // TGeoCombiTrans *sideLeftTr = new TGeoCombiTrans(0,
5326 // (fgkWaferThickness+fgkTransitHVPolyThick)/2,
5327 // -fgkTransitHVBondingLZ/2, &rotSide);
5328 // TGeoCombiTrans *sideLeftAlTr = new TGeoCombiTrans(0,
5329 // fgkTransitHVPolyThick+(fgkWaferThickness+fgkTransitHVAlThick)/2,
5330 // -fgkTransitHVBondingLZ/2, &rotSide);
5331 TGeoRotation *rotSide = new TGeoRotation("",0,-90,0);
5332 // TGeoCombiTrans *sideRightTr = new TGeoCombiTrans(0,
5333 // (fgkWaferThickness+fgkTransitHVPolyThick)/2,
5334 // -fgkTransitHVBondingLZ/2,rotSide);
5335 TGeoCombiTrans *sideLeftTr = new TGeoCombiTrans(0,
5336 (fgkWaferThickness+fgkTransitHVPolyThick)/2,
5337 -fgkTransitHVBondingLZ/2, rotSide);
5338 TGeoCombiTrans *sideLeftAlTr = new TGeoCombiTrans(0,
5339 fgkTransitHVPolyThick+(fgkWaferThickness+fgkTransitHVAlThick)/2,
5340 -fgkTransitHVBondingLZ/2, rotSide);
5342 TGeoVolume *vSideLeft = new TGeoVolume("ITSsddHVtransitSideLeft",
5343 sideLeft,polyhamideSDD);
5344 vSideLeft->SetLineColor(fColorPolyhamide);
5345 TGeoVolume *vSideLeftAl = new TGeoVolume("ITSsddHVtransitSideLeftAl",
5347 vSideLeftAl->SetLineColor(fColorAl);
5349 // TGeoVolume *vSideRight = new TGeoVolume("ITSsddHVtransitSideRight",
5350 // sideRight,polyhamideSDD);
5351 // vSideRight->SetLineColor(fColorPolyhamide);
5353 fSDDsensor3->AddNode(vSideLeft, 1, sideLeftTr);
5354 fSDDsensor3->AddNode(vSideLeftAl, 1, sideLeftAlTr);
5355 // fSDDsensor3->AddNode(vSideRight, 1, sideRightTr);
5357 fSDDsensor4->AddNode(vSideLeft, 1, sideLeftTr);
5358 fSDDsensor4->AddNode(vSideLeftAl, 1, sideLeftAlTr);
5359 // fSDDsensor4->AddNode(vSideRight, 1, sideRightTr);
5362 //****************************
5364 fSDDsensor3->CheckOverlaps(0.01);
5365 fSDDsensor4->CheckOverlaps(0.01);
5368 fSDDsensor3->SetVisibility(kFALSE);
5369 fSDDsensor4->SetVisibility(kFALSE);
5373 //________________________________________________________________________
5374 TGeoVolume *AliITSv11GeometrySDD::CreateDetectors(Int_t iLay) {
5376 // return a box volume containing the detectors
5379 TGeoMedium *airSDD = GetMedium("SDD AIR$");
5381 Int_t nDetectors = fgkLay3Ndet;
5382 Double_t ladderLength = fgkLay3LadderLength;
5383 Double_t *sensorZPos = fLay3sensorZPos;
5387 nDetectors = fgkLay4Ndet;
5388 ladderLength = fgkLay4LadderLength;
5389 sensorZPos = fLay4sensorZPos;
5391 printf("AliITSv11GeometrySDD::CreateDetectors: Error : Wrong layer");
5395 Double_t volThickness = ( fgkLadWaferSep + 2*fgkWaferThickness +
5396 2*(fgkWaHVcableAlThick+fgkWaHVcablePolyThick));
5398 sprintf(name,"ITSsddDetBox%i",iLay);
5399 TGeoBBox *detBox = new TGeoBBox(name, fgkWaferWidth/2, volThickness/2,
5400 ladderLength*((nDetectors-0.5)/nDetectors)/2);
5401 TGeoVolume *virtualDet = new TGeoVolume("ITSsddLadd",detBox, airSDD);
5403 for (Int_t i=0; i<nDetectors; i++) {
5404 Double_t localZ = sensorZPos[i];
5405 Double_t localY = fgkLadWaferSep/2+fgkWaferThickness/2;
5406 if (iLay==3) if (i%2!=0) localY = -localY;
5407 if (iLay==4) if (i%2==0) localY = -localY;
5408 sprintf(name, "ITSsddLay%iSensorPos%i",iLay, i);
5410 if (i >= nDetectors/2) {
5411 TGeoTranslation *sensorPos = new TGeoTranslation(0,localY,localZ);
5412 sensorPos->SetName(name);
5413 virtualDet->AddNode(fSDDsensor, i, sensorPos);
5416 TGeoRotation *rotSensor = new TGeoRotation("",0, 180, 180);
5417 TGeoCombiTrans *sensorPos = new TGeoCombiTrans(0,localY,
5419 sensorPos->SetName(name);
5420 virtualDet->AddNode(fSDDsensor, i, sensorPos);
5424 if(GetDebug(1)) virtualDet->CheckOverlaps(0.01);
5425 virtualDet->SetVisibility(kFALSE);
5430 //________________________________________________________________________
5431 TGeoVolumeAssembly *AliITSv11GeometrySDD::CreateDetectorsAssembly(Int_t iLay) {
5433 // return a box volume containing the detectors
5436 Int_t nDetectors = fgkLay3Ndet;
5437 Double_t ladderLength = fgkLay3LadderLength;
5438 Double_t *sensorZPos = fLay3sensorZPos;
5439 TGeoVolume *sensorSDD = fSDDsensor3;
5443 nDetectors = fgkLay4Ndet;
5444 ladderLength = fgkLay4LadderLength;
5445 sensorZPos = fLay4sensorZPos;
5446 sensorSDD = fSDDsensor4;
5448 printf("AliITSv11GeometrySDD::CreateDetectorsAssembly: Error:Wrong layer");
5452 snprintf(name,30,"ITSsddDetBox%i",iLay);
5454 TGeoVolumeAssembly *virtualDet = new TGeoVolumeAssembly("ITSsddLadd");
5456 for (Int_t i=0; i<nDetectors; i++) {
5457 Double_t localZ = sensorZPos[i];
5458 Double_t localY = fgkLadWaferSep/2+fgkWaferThickness/2;
5459 if (iLay==3) if (i%2!=0) localY = -localY;
5460 if (iLay==4) if (i%2==0) localY = -localY;
5461 snprintf(name, 30, "ITSsddLay%iSensorPos%i",iLay, i);
5463 if (i >= nDetectors/2) {
5464 TGeoTranslation *sensorPos = new TGeoTranslation(0,localY,localZ);
5465 sensorPos->SetName(name);
5466 virtualDet->AddNode(sensorSDD, i, sensorPos);
5469 TGeoRotation *rotSensor = new TGeoRotation("",0, 180, 180);
5470 TGeoCombiTrans *sensorPos = new TGeoCombiTrans(0,localY,
5472 sensorPos->SetName(name);
5473 virtualDet->AddNode(sensorSDD, i, sensorPos);
5477 if(GetDebug(1)) virtualDet->CheckOverlaps(0.01);
5482 //________________________________________________________________________
5483 TGeoVolumeAssembly *AliITSv11GeometrySDD::CreateDetectorsAssemblyLadd2() {
5485 // return a box volume containing the detectors
5486 // Special case for Layer 3 Ladder 2 which is rotated (cannot simply
5487 // rotate the standard volume, because the module numbering would be wrong)
5488 // M.Sitta 25 Nov 2009
5491 Int_t nDetectors = fgkLay3Ndet;
5492 Double_t *sensorZPos = fLay3sensorZPos;
5493 TGeoVolume *sensorSDD = fSDDsensor3;
5496 snprintf(name,30,"ITSsddDetBoxLadd2");
5498 TGeoVolumeAssembly *virtualDet = new TGeoVolumeAssembly("ITSsddLadd");
5500 for (Int_t i=0; i<nDetectors; i++) {
5501 Double_t localZ = (-1.)*sensorZPos[nDetectors-1-i];
5502 Double_t localY = fgkLadWaferSep/2+fgkWaferThickness/2;
5503 if (i%2==0) localY = -localY;
5504 snprintf(name, 30, "ITSsddLayLadd2SensorPos%i", i);
5506 if (i >= nDetectors/2) {
5507 TGeoTranslation *sensorPos = new TGeoTranslation(0,localY,localZ);
5508 sensorPos->SetName(name);
5509 virtualDet->AddNode(sensorSDD, i, sensorPos);
5512 TGeoRotation *rotSensor = new TGeoRotation("",0, 180, 180);
5513 TGeoCombiTrans *sensorPos = new TGeoCombiTrans(0,localY,
5515 sensorPos->SetName(name);
5516 virtualDet->AddNode(sensorSDD, i, sensorPos);
5520 if(GetDebug(1)) virtualDet->CheckOverlaps(0.01);
5525 //________________________________________________________________________
5526 Int_t AliITSv11GeometrySDD::
5527 GetCurrentLayLaddDet(Int_t &lay, Int_t &ladd, Int_t&det) const {
5529 // Function which gives the layer, ladder and det.
5530 // index of the current volume. To be used in
5531 // AliITS::StepManager()
5534 if (gGeoManager->GetLevel()<3) return kFALSE;
5535 // Get the det index :
5536 TGeoNode *node = gGeoManager->GetMother(2);
5537 if (!node) return kFALSE;
5538 det = node->GetNumber()+1;
5540 // Get the ladder index :
5541 node = gGeoManager->GetMother(3);
5542 if (!node) return kFALSE;
5543 ladd = node->GetNumber()+1;
5545 // Get the layer index :
5546 if (node->GetNdaughters()==fgkLay3Ndet)
5554 //________________________________________________________________________
5555 TGeoPcon* AliITSv11GeometrySDD::CreateConeConstSection(Double_t r1max, Double_t z1,
5556 Double_t r2max, Double_t z2,
5557 Double_t section, Int_t nDiv)
5559 // Creates a cone along z where the section is approximately constant
5560 // with z. This is for simulation of cables, because a cone with a constant
5561 // radius difference would show a quantity of matter increasing with z...
5562 // The max radius of the created Pcon is evolving linearly, the min radius
5563 // is calculated at several steps (nDiv).
5564 // z2 > z1 (required by the Pcon)
5566 TGeoPcon *myPcon = new TGeoPcon(0, 360, 1+nDiv);
5568 Double_t dr = (r2max-r1max)/nDiv;
5569 Double_t dz = (z2-z1)/nDiv;
5570 Double_t r1minI, r2minI, r1maxI, r2maxI;
5573 Double_t lZ = TMath::Sqrt((r2max-r1max)*(r2max-r1max) + (z2-z1)*(z2-z1));
5574 Double_t cosAlpha = (z2-z1)/lZ;
5576 r1minI = TMath::Sqrt(r1max*r1max-section/(TMath::Pi()*cosAlpha));
5577 myPcon->DefineSection(0, z1, r1minI, r1max);
5579 for (Int_t i=0; i<nDiv; i++) {
5583 r1maxI = r1max + i*dr;
5584 r2maxI = r1maxI + dr;
5586 r2minI = TMath::Sqrt(r2maxI*r2maxI-section/(TMath::Pi()*cosAlpha));
5587 myPcon->DefineSection(i+1, z2I, r2minI, r2maxI);
5593 //________________________________________________________________________
5594 Double_t AliITSv11GeometrySDD::GetConeZ(Double_t r, Double_t refR1, Double_t refR2,
5595 Double_t refZ1, Double_t refZ2) const {
5596 // just a helping function
5597 return refZ1+(refZ2-refZ1)*(r-refR1)/(refR2-refR1);
5600 //________________________________________________________________________
5601 Int_t AliITSv11GeometrySDD::CreateAndInsetConeCablePart(TGeoVolume *mother, Double_t angle,
5602 Int_t nLay3, Int_t nLay4,
5603 Double_t r1, Double_t z1,
5604 Double_t r2, Double_t z2) {
5606 // Create some cables portions from SDD modules grouped
5607 // and attached at the border of the SSD cone
5609 TGeoMedium *copper = GetMedium("COPPER$");
5610 TGeoMedium *plastic = GetMedium("SDDKAPTON (POLYCH2)$");
5611 TGeoMedium *opticalFiber = GetMedium("SDD OPTICFIB$");
5613 char titleCable[30];
5614 snprintf(titleCable,30,"cableSDDport%i",(Int_t)angle);
5617 Double_t section = (fgkSectionCuPerMod+fgkSectionPlastPerMod+fgkSectionGlassPerMod)*(nLay3+nLay4);
5618 Double_t thickness = 1.; // let's fix the thickness, then calculate the width
5619 Double_t width = section/thickness;
5620 Double_t thickCu = thickness*fgkSectionCuPerMod/(fgkSectionCuPerMod+fgkSectionPlastPerMod
5621 +fgkSectionGlassPerMod);
5623 Double_t thickPlast = thickness*fgkSectionPlastPerMod/(fgkSectionCuPerMod+fgkSectionPlastPerMod
5624 +fgkSectionGlassPerMod);
5626 Double_t thickGlass = thickness*fgkSectionGlassPerMod/(fgkSectionCuPerMod+fgkSectionPlastPerMod
5627 +fgkSectionGlassPerMod);
5629 Double_t hypothenus = TMath::Sqrt( (r2-r1)*(r2-r1) + (z2-z1)*(z2-z1) );
5630 Double_t cosAlpha = (z2-z1)/hypothenus;
5631 Double_t radius1Cable = TMath::Sqrt(r1*r1 - width*width/4) - 0.5*thickness/cosAlpha;
5632 Double_t radius2Cable = TMath::Sqrt(r2*r2 - width*width/4) - 0.5*thickness/cosAlpha;
5633 angle *= TMath::DegToRad();
5634 Double_t x1 = radius1Cable*TMath::Cos(angle), y1 = radius1Cable*TMath::Sin(angle);
5635 Double_t x2 = radius2Cable*TMath::Cos(angle), y2 = radius2Cable*TMath::Sin(angle);
5636 Double_t pos1[3] = {x1,y1,z1};
5637 Double_t pos2[3] = {x2,y2,z2};
5638 Double_t zVect[3] = {0,0,1};
5640 AliITSv11GeomCableFlat cable(titleCable,width,thickness);
5641 cable.SetNLayers(3);
5642 cable.SetLayer(0, thickPlast, plastic, kYellow);
5643 cable.SetLayer(1, thickCu, copper, kRed);
5644 cable.SetLayer(2, thickGlass, opticalFiber, kGreen);
5646 cable.AddCheckPoint( mother, 0, pos1, zVect );
5647 cable.AddCheckPoint( mother, 1, pos2, zVect );
5648 cable.SetInitialNode(mother);
5649 cable.CreateAndInsertCableSegment(1);
5656 //________________________________________________________________________
5657 void AliITSv11GeometrySDD::SDDCables(TGeoVolume *moth)
5660 // Creates and inserts the SDD cables running on SDD and SSD cones
5663 // moth : the TGeoVolume owing the volume structure
5666 // Created: ??? Ludovic Gaudichet
5667 // Updated: 15 Mar 2008 Mario Sitta
5668 // Updated: 14 Apr 2008 Mario Sitta Overlap fixes
5669 // Updated: 09 May 2008 Mario Sitta SSD overlap fixes
5672 TGeoMedium *copper = GetMedium("COPPER$");
5673 TGeoMedium *plastic = GetMedium("SDDKAPTON (POLYCH2)$");
5674 TGeoMedium *opticalFiber = GetMedium("SDD OPTICFIB$");
5675 TGeoMedium *airSDD = GetMedium("SDD AIR$");
5678 //==================================
5680 //==================================
5682 Double_t nModLay3 = fgkLay3Nladd*fgkLay3Ndet;
5683 Double_t nModLay4 = fgkLay4Nladd*fgkLay4Ndet;
5685 Double_t sectionLay3Cu = fgkCableBendRatio*fgkSectionCuPerMod*nModLay3/2;
5686 Double_t sectionLay3Plastic = fgkCableBendRatio*fgkSectionPlastPerMod*nModLay3/2;
5687 Double_t sectionLay3Glass = fgkCableBendRatio*fgkSectionGlassPerMod*nModLay3/2;
5689 Double_t sectionLay4Cu = fgkCableBendRatio*fgkSectionCuPerMod*nModLay4/2;
5690 Double_t sectionLay4Plastic = fgkCableBendRatio*fgkSectionPlastPerMod*nModLay4/2;
5691 Double_t sectionLay4Glass = fgkCableBendRatio*fgkSectionGlassPerMod*nModLay4/2;
5693 // Do not use hardcoded numbers, get them from real shapes - M.S. 15/03/08
5694 TGeoVolume *sddCone = gGeoManager->GetVolume("SDDCarbonFiberCone");
5695 TGeoPcon *sddConeShape = (TGeoPcon*)sddCone->GetShape();
5697 TGeoVolume *sddCylinder = gGeoManager->GetVolume("SDDCarbonFiberCylinder");
5698 TGeoTube *sddCylinderShape = (TGeoTube*)sddCylinder->GetShape();
5700 // (were fgkConeSDDr1, fgkConeSDDr2, fgkConeSDDz1, fgkConeSDDz2 hardcoded)
5701 Double_t coneSDDr1 = sddConeShape->GetRmin(5);
5702 Double_t coneSDDr2 = sddConeShape->GetRmin(3);
5704 Double_t coneSDDz1 = sddConeShape->GetZ(9) - sddConeShape->GetZ(5) +
5705 sddCylinderShape->GetDz();
5706 Double_t coneSDDz2 = sddConeShape->GetZ(9) - sddConeShape->GetZ(3) +
5707 sddCylinderShape->GetDz();
5709 // Calculate z1, z2 thanks to R1 and R2
5710 Double_t sddCableZ1 = GetConeZ(fgkSDDCableR1, coneSDDr1, coneSDDr2,
5711 coneSDDz1, coneSDDz2);
5712 Double_t sddCableZ2 = GetConeZ(fgkSDDCableR2, coneSDDr1, coneSDDr2,
5713 coneSDDz1, coneSDDz2);
5714 Double_t sddCableZ3 = GetConeZ(fgkSDDCableR3, coneSDDr1, coneSDDr2,
5715 coneSDDz1, coneSDDz2);
5717 TGeoRotation *rotCableSDD = new TGeoRotation("rotCableSDD",0,180,0);
5719 //==================================
5720 // first set of cones : cables from layer 3
5721 //==================================
5723 TGeoPcon* pcon1all = CreateConeConstSection(fgkSDDCableR1, sddCableZ1,
5724 fgkSDDCableR2, sddCableZ2,
5725 sectionLay3Plastic+sectionLay3Cu+sectionLay3Glass, 1);
5727 TGeoPcon* pcon1container = new TGeoPcon(0,360,2);
5728 pcon1container->DefineSection(0, sddCableZ1, pcon1all->GetRmin(0),
5729 pcon1all->GetRmax(0));
5731 Double_t drMax = pcon1all->GetRmax(0)- pcon1all->GetRmin(0);
5732 pcon1container->DefineSection(1, sddCableZ2, pcon1all->GetRmax(1)-drMax,
5733 pcon1all->GetRmax(1));
5735 TGeoVolume *vpcon1container = new TGeoVolume("vpcon1container",
5736 pcon1container, airSDD);
5737 vpcon1container->SetVisibility(kFALSE);
5739 TGeoPcon* pcon1plast = CreateConeConstSection(fgkSDDCableR1, sddCableZ1,
5740 fgkSDDCableR2, sddCableZ2,
5741 sectionLay3Plastic, 3);
5743 TGeoVolume *vpcon1plast = new TGeoVolume("ITScablesSDDpcon1Plast",
5744 pcon1plast, plastic);
5745 vpcon1plast->SetLineColor(kYellow);
5746 vpcon1container->AddNode(vpcon1plast, 0);
5748 Double_t dr1a = fgkSDDCableR1 - pcon1plast->GetRmin(0);
5749 TGeoPcon* pcon1Cu = CreateConeConstSection(fgkSDDCableR1 - dr1a, sddCableZ1,
5750 fgkSDDCableR2 - dr1a, sddCableZ2,
5753 TGeoVolume *vpcon1Cu = new TGeoVolume("ITScablesSDDpcon1Cu",
5755 vpcon1Cu->SetLineColor(kRed);
5756 vpcon1container->AddNode(vpcon1Cu, 0);
5758 Double_t dr1b = pcon1Cu->GetRmax(0) - pcon1Cu->GetRmin(0);
5759 TGeoPcon* pcon1glass = CreateConeConstSection(fgkSDDCableR1-dr1a-dr1b, sddCableZ1,
5760 fgkSDDCableR2-dr1a-dr1b, sddCableZ2,
5761 sectionLay3Glass, 3);
5763 TGeoVolume *vpcon1glass = new TGeoVolume("ITScablesSDDpcon1glass",
5764 pcon1glass, opticalFiber);
5765 vpcon1glass->SetLineColor(kGreen);
5766 vpcon1container->AddNode(vpcon1glass, 0);
5768 moth->AddNode(vpcon1container, 1);
5769 moth->AddNode(vpcon1container, 2, rotCableSDD);
5771 //==================================
5772 // 2nd set of cones : cables from layer 3 and layer 4
5773 //==================================
5775 TGeoPcon* pcon2all = CreateConeConstSection(fgkSDDCableR2, sddCableZ2,
5776 fgkSDDCableR3, sddCableZ3,
5777 sectionLay3Plastic+sectionLay4Plastic+
5778 sectionLay3Cu+sectionLay4Cu+
5779 sectionLay3Glass+sectionLay4Glass, 1);
5781 TGeoPcon* pcon2container = new TGeoPcon(0,360,2);
5782 pcon2container->DefineSection(0, sddCableZ2, pcon2all->GetRmin(0),
5783 pcon2all->GetRmax(0));
5785 drMax = pcon2all->GetRmax(0)- pcon2all->GetRmin(0);
5786 pcon2container->DefineSection(1, sddCableZ3, pcon2all->GetRmax(1)-drMax,
5787 pcon2all->GetRmax(1));
5790 TGeoVolume *vpcon2container = new TGeoVolume("vpcon2container",
5791 pcon2container, airSDD);
5792 vpcon2container->SetVisibility(kFALSE);
5794 TGeoPcon* pcon2plast = CreateConeConstSection(fgkSDDCableR2, sddCableZ2,
5795 fgkSDDCableR3, sddCableZ3,
5797 sectionLay4Plastic, 3);
5799 TGeoVolume *vpcon2plast = new TGeoVolume("ITScablesSDDpcon2Plast",
5800 pcon2plast, plastic);
5801 vpcon2plast->SetLineColor(kYellow);
5802 vpcon2container->AddNode(vpcon2plast, 0);
5804 Double_t dr2a = fgkSDDCableR2 - pcon2plast->GetRmin(0);
5805 TGeoPcon* pcon2Cu = CreateConeConstSection(fgkSDDCableR2 - dr2a, sddCableZ2,
5806 fgkSDDCableR3 - dr2a, sddCableZ3,
5807 sectionLay3Cu+sectionLay4Cu, 3);
5809 TGeoVolume *vpcon2Cu = new TGeoVolume("ITScablesSDDpcon2Cu",
5811 vpcon2Cu->SetLineColor(kRed);
5812 vpcon2container->AddNode(vpcon2Cu, 0);
5814 Double_t dr2b = pcon2Cu->GetRmax(0) - pcon2Cu->GetRmin(0);
5815 TGeoPcon* pcon2glass = CreateConeConstSection(fgkSDDCableR2-dr2a-dr2b, sddCableZ2,
5816 fgkSDDCableR3-dr2a-dr2b, sddCableZ3,
5818 sectionLay4Glass, 3);
5820 TGeoVolume *vpcon2glass = new TGeoVolume("ITScablesSDDpcon2glass",
5821 pcon2glass, opticalFiber);
5822 vpcon2glass->SetLineColor(kGreen);
5823 vpcon2container->AddNode(vpcon2glass, 0);
5825 moth->AddNode(vpcon2container, 1);
5826 moth->AddNode(vpcon2container, 2, rotCableSDD);
5828 //==================================
5829 // intermediate cylinder
5830 //==================================
5832 // (was fgkSDDCableDZint hardcoded)
5833 Double_t sddCableDZint = (sddConeShape->GetZ(9) - sddConeShape->GetZ(0) +
5834 sddCylinderShape->GetDz()) - sddCableZ3;
5836 TGeoTube *interCyl = new TGeoTube("sddCableInterCyl",
5837 pcon2container->GetRmin(1),
5838 pcon2container->GetRmax(1),
5841 TGeoVolume *vInterCyl = new TGeoVolume("vSddCableInterCyl",
5843 vInterCyl->SetVisibility(kFALSE);
5845 Double_t rmaxCylPlast = pcon2container->GetRmax(1);
5846 Double_t rminCylPlast = TMath::Sqrt(rmaxCylPlast*rmaxCylPlast -
5847 (sectionLay3Plastic+sectionLay4Plastic)/TMath::Pi() );
5849 TGeoTube *interCylPlast = new TGeoTube("sddCableInterCylPlast", rminCylPlast,
5850 rmaxCylPlast, sddCableDZint/2);
5852 TGeoVolume *vInterCylPlast = new TGeoVolume("vSddCableInterCylPlast",
5853 interCylPlast, plastic);
5854 vInterCylPlast->SetLineColor(kYellow);
5855 vInterCyl->AddNode(vInterCylPlast, 0);
5857 Double_t rmaxCylCu = pcon2Cu->GetRmax(3);
5858 Double_t rminCylCu = TMath::Sqrt(rmaxCylCu*rmaxCylCu -
5859 (sectionLay3Cu+sectionLay4Cu)/TMath::Pi() );
5861 TGeoTube *interCylCu = new TGeoTube("sddCableInterCylCu", rminCylCu,
5862 rmaxCylCu, sddCableDZint/2);
5864 TGeoVolume *vInterCylCu = new TGeoVolume("vSddCableInterCylCu",
5865 interCylCu, copper);
5866 vInterCylCu->SetLineColor(kRed);
5867 vInterCyl->AddNode(vInterCylCu, 0);
5869 Double_t rmaxCylGlass = pcon2glass->GetRmax(3);
5870 Double_t rminCylGlass = TMath::Sqrt(rmaxCylGlass*rmaxCylGlass -
5871 (sectionLay3Glass+sectionLay4Glass)/TMath::Pi() );
5873 TGeoTube *interCylGlass = new TGeoTube("sddCableInterCylGlass", rminCylGlass,
5874 rmaxCylGlass, sddCableDZint/2);
5876 TGeoVolume *vInterCylGlass = new TGeoVolume("vSddCableInterCylGlass",
5877 interCylGlass,opticalFiber);
5878 vInterCylGlass->SetLineColor(kGreen);
5879 vInterCyl->AddNode(vInterCylGlass, 0);
5881 moth->AddNode(vInterCyl, 1, new TGeoTranslation(0, 0,
5882 sddCableZ3+sddCableDZint/2));
5883 moth->AddNode(vInterCyl, 2, new TGeoTranslation(0, 0,
5884 -sddCableZ3-sddCableDZint/2));
5886 //==================================
5887 // cable cone on the SSD cone
5888 //==================================
5890 Double_t sddCableR4 = rmaxCylPlast;
5891 Double_t sddCableZ4 = sddCableZ3 + sddCableDZint;
5893 TGeoPcon* pcon3all = CreateConeConstSection(sddCableR4, sddCableZ4,
5894 fgkSDDCableR5, fgkSDDCableZ5,
5897 sectionLay3Cu+sectionLay4Cu+
5898 sectionLay3Glass+sectionLay4Glass, 1);
5900 TGeoPcon* pcon3container = new TGeoPcon(0,360,2);
5901 pcon3container->DefineSection(0, sddCableZ4, pcon3all->GetRmin(0),
5902 pcon3all->GetRmax(0));
5904 drMax = pcon3all->GetRmax(0) - pcon3all->GetRmin(0);
5905 pcon3container->DefineSection(1, fgkSDDCableZ5, pcon3all->GetRmax(1)-drMax,
5906 pcon3all->GetRmax(1));
5909 TGeoVolume *vpcon3container = new TGeoVolume("vpcon3container",
5910 pcon3container, airSDD);
5911 vpcon3container->SetVisibility(kFALSE);
5913 TGeoPcon* pcon3plast = CreateConeConstSection(sddCableR4, sddCableZ4,
5914 fgkSDDCableR5, fgkSDDCableZ5,
5916 sectionLay4Plastic, 3);
5918 TGeoVolume *vpcon3plast = new TGeoVolume("ITScablesSDDpcon3Plast",
5919 pcon3plast, plastic);
5920 vpcon3plast->SetLineColor(kYellow);
5921 vpcon3container->AddNode(vpcon3plast, 0);
5923 Double_t dr3a = sddCableR4 - pcon3plast->GetRmin(0);
5924 TGeoPcon* pcon3Cu = CreateConeConstSection(sddCableR4 - dr3a, sddCableZ4,
5925 fgkSDDCableR5 - dr3a, fgkSDDCableZ5,
5926 sectionLay3Cu+sectionLay4Cu, 3);
5928 TGeoVolume *vpcon3Cu = new TGeoVolume("ITScablesSDDpcon3Cu",
5930 vpcon3Cu->SetLineColor(kRed);
5931 vpcon3container->AddNode(vpcon3Cu, 0);
5933 Double_t dr3b = pcon3Cu->GetRmax(0) - pcon3Cu->GetRmin(0);
5934 TGeoPcon* pcon3glass = CreateConeConstSection(sddCableR4-dr3a-dr3b, sddCableZ4,
5935 fgkSDDCableR5-dr3a-dr3b, fgkSDDCableZ5,
5936 sectionLay3Glass+sectionLay4Glass, 3);
5938 TGeoVolume *vpcon3glass = new TGeoVolume("ITScablesSDDpcon3glass",
5939 pcon3glass,opticalFiber);
5940 vpcon3glass->SetLineColor(kGreen);
5941 vpcon3container->AddNode(vpcon3glass, 0);
5943 moth->AddNode(vpcon3container, 1);
5944 moth->AddNode(vpcon3container, 2, rotCableSDD);
5946 //==================================
5947 // cables that are grouped at the end of SSD cones
5948 //==================================
5950 // Double_t fgkSDDCableR6 = fgkSDDCableR5+9;
5951 // Double_t fgkSDDCableZ6 = fgkSDDCableZ5+8.8;
5952 Double_t fgkSDDCableR6 = fgkSDDCableR5+8;
5953 Double_t fgkSDDCableZ6 = fgkSDDCableZ5+8;
5955 TGeoVolumeAssembly *endConeSDDCable = new TGeoVolumeAssembly("endConeSDDCable");
5957 // Add some hardcoded shifts to avoid overlaps with SSD pathc panels
5958 CreateAndInsetConeCablePart(endConeSDDCable, 20, 1*3,2*4, fgkSDDCableR5,
5959 fgkSDDCableZ5,fgkSDDCableR6-2.6,fgkSDDCableZ6-2.6);
5961 CreateAndInsetConeCablePart(endConeSDDCable, 50, 1*3,1*4, fgkSDDCableR5,
5962 fgkSDDCableZ5,fgkSDDCableR6,fgkSDDCableZ6);
5964 CreateAndInsetConeCablePart(endConeSDDCable, 85, 2*3,1*4, fgkSDDCableR5,
5965 fgkSDDCableZ5,fgkSDDCableR6,fgkSDDCableZ6);
5967 CreateAndInsetConeCablePart(endConeSDDCable, 95, 0*3,1*4, fgkSDDCableR5,
5968 fgkSDDCableZ5,fgkSDDCableR6,fgkSDDCableZ6);
5970 CreateAndInsetConeCablePart(endConeSDDCable, 105, 2*3,3*4, fgkSDDCableR5,
5971 fgkSDDCableZ5,fgkSDDCableR6-2.6,fgkSDDCableZ6-2.6);
5973 CreateAndInsetConeCablePart(endConeSDDCable, 129, 0*3,3*4, fgkSDDCableR5,
5974 fgkSDDCableZ5,fgkSDDCableR6,fgkSDDCableZ6);
5976 CreateAndInsetConeCablePart(endConeSDDCable, 176, 0*3,1*4, fgkSDDCableR5,
5977 fgkSDDCableZ5,fgkSDDCableR6,fgkSDDCableZ6);
5979 CreateAndInsetConeCablePart(endConeSDDCable, 190, 2*3,0*4, fgkSDDCableR5,
5980 fgkSDDCableZ5,fgkSDDCableR6,fgkSDDCableZ6);
5982 CreateAndInsetConeCablePart(endConeSDDCable, 210, 1*3,2*4, fgkSDDCableR5,
5983 fgkSDDCableZ5,fgkSDDCableR6-2.6,fgkSDDCableZ6-2.6);
5985 CreateAndInsetConeCablePart(endConeSDDCable, 230, 1*3,2*4, fgkSDDCableR5,
5986 fgkSDDCableZ5,fgkSDDCableR6,fgkSDDCableZ6);
5988 CreateAndInsetConeCablePart(endConeSDDCable, 277, 2*3,2*4, fgkSDDCableR5,
5989 fgkSDDCableZ5,fgkSDDCableR6,fgkSDDCableZ6);
5991 CreateAndInsetConeCablePart(endConeSDDCable, 306, 1*3,1*4, fgkSDDCableR5,
5992 fgkSDDCableZ5,fgkSDDCableR6,fgkSDDCableZ6);
5994 CreateAndInsetConeCablePart(endConeSDDCable, 353, 1*3,3*4, fgkSDDCableR5,
5995 fgkSDDCableZ5,fgkSDDCableR6,fgkSDDCableZ6);
5997 moth->AddNode(endConeSDDCable, 1, 0);
5999 TGeoRotation* reflect = new TGeoRotation("reflectEndConeSDDCable");
6000 reflect->ReflectZ(kTRUE);
6001 moth->AddNode(endConeSDDCable, 2, reflect);