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 **************************************************************************/
16 // This class Defines the Geometry for the ITS services and support cones
17 // outside of the ceneteral volume (except for the Ceneteral support
18 // cylinders. Other classes define the rest of the ITS. Specificaly the ITS
19 // The SSD support cone,SSD Support centeral cylinder, SDD support cone,
20 // The SDD cupport centeral cylinder, the SPD Thermal Sheald, The supports
21 // and cable trays on both the RB26 (muon dump) and RB24 sides, and all of
22 // the cabling from the ladders/stave ends out past the TPC.
24 // General Root includes
25 #include <Riostream.h>
29 #include <TPolyLine.h>
30 // Root Geometry includes
31 #include <TGeoVolume.h>
34 #include <TGeoTube.h> // contaings TGeoTubeSeg
38 #include <TGeoCompositeShape.h>
39 #include <TGeoMatrix.h>
40 #include <TGeoMaterial.h>
41 #include <TGeoMedium.h>
44 //#include <TGeoRotation.h>
45 //#include <TGeoCombiTrans.h>
46 //#include <TGeoTranslation.h>
47 #include "AliITSv11GeometrySPD.h"
49 ClassImp(AliITSv11GeometrySPD)
53 //______________________________________________________________________
54 Int_t AliITSv11GeometrySPD::CreateSPDCenteralMaterials(Int_t &medOffset,
56 // Define the specific materials used for the ITS SPD centeral
57 // detectors. Note, These are the same old names. By the ALICE
58 // naming convension, these should start out at ITS SPD ....
59 // This data has been taken from AliITSvPPRasymmFMD::CreateMaterials().
61 // Int_t &medOffset The starting number of the list of media
62 // Int_t &matOffset The starting number of the list of Materials
64 // Int_t &medOffset The ending number of the list of media
65 // Int_t &matOffset The ending number of the list of Materials
67 // the last material number used +1 (the next avaiable material number).
70 <img src="http://alice.pd.infn.it/latestdr/all-sections-module.ps"
71 title="SPD Sector drawing with all cross sections defined">
72 <p>The SPD Sector definition.
73 <img src="http://alice.pd.infn.it/latestdr/assembly-10-modules.ps"
74 titile="SPD All Sectors end view with thermal sheald">
75 <p>The SPD all sector end view with thermal sheald.
76 <img src="http://alice.pd.infn.it/latestdr/assembly.ps"
77 title="SPD side view cross section">
78 <p>SPD side view cross section with condes and thermal shealds.
79 <img src="http://alice.pd.infn.it/latestdr/SECTION-A_A.jpg"
80 title="Cross setion A-A"><p>Cross section A-A
81 <img src="http://alice.pd.infn.it/latestdr/SECTION-B_B.jpg"
82 title="Cross section B-B"><p>Cross section B-B
83 <img src="http://alice.pd.infn.it/latestdr/SECTION-C_C.jpg"
84 title-"Cross section C-C"><p>Cross section C-C
85 <img src="http://alice.pd.infn.it/latestdr/SECTION-D_D.jpg"
86 title="Cross section D-D"><p>Cross section D-D
87 <img src="http://alice.pd.infn.it/latestdr/SECTION-F_F.jpg"
88 title="Cross section F-F"><p>Cross section F-F
89 <img src="http://alice.pd.infn.it/latestdr/SECTION-G_G.jpg"
90 title="Cross section G-G"><p>Cross section G-G
93 const Double_t ktmaxfd = 0.1*fgkDegree; // Degree
94 const Double_t kstemax = 1.0*fgkcm; // cm
95 const Double_t kdeemax = 0.1; // Fraction of particle's energy 0<deemax<=1
96 const Double_t kepsil = 1.0E-4; //
97 const Double_t kstmin = 0.0*fgkcm; // cm "Default value used"
98 const Double_t ktmaxfdAir = 0.1*fgkDegree; // Degree
99 const Double_t kstemaxAir = 1.0000E+00*fgkcm; // cm
100 const Double_t kdeemaxAir = 0.1; // Fraction of particle's energy 0<deemax<=1
101 const Double_t kepsilAir = 1.0E-4;//
102 const Double_t kstminAir = 0.0*fgkcm; // cm "Default value used"
103 const Double_t ktmaxfdSi = 0.1*fgkDegree; // .10000E+01; // Degree
104 const Double_t kstemaxSi = 0.0075*fgkcm; // .10000E+01; // cm
105 const Double_t kdeemaxSi = 0.1; // Fraction of particle's energy 0<deemax<=1
106 const Double_t kepsilSi = 1.0E-4;//
107 const Double_t kstminSi = 0.0*fgkcm; // cm "Default value used"
109 Int_t matindex=matOffset;
110 Int_t medindex=medOffset;
111 Double_t params[8]={8*0.0};
116 Int_t ifield = (gAlice->Field()->Integ());
117 Double_t fieldm = (gAlice->Field()->Max());
118 params[1] = (Double_t) ifield;
120 params[3] = ktmaxfdSi;
121 params[4] = kstemaxSi;
122 params[5] = kdeemaxSi;
123 params[6] = kepsilSi;
124 params[7] = kstminSi;
126 mat = new TGeoMaterial("SI",28.086,14.0,2.33*fgkgcm3,
127 TGeoMaterial::kMatStateSolid,25.0*fgkCelsius,
129 mat->SetIndex(matindex);
130 med = new TGeoMedium("SI",medindex++,mat,params);
131 //med = new TGeoMedium("SI",medindex++,matindex++,0,ifield,
132 // fieldm,ktmaxfdSi,kstemaxSi,kdeemaxSi,kepsilSi,kstminSi);
134 mat = new TGeoMaterial("SPD SI CHIP",28.086,14.0,2.33*fgkgcm3,
135 TGeoMaterial::kMatStateSolid,25.0*fgkCelsius,
137 mat->SetIndex(matindex);
138 med = new TGeoMedium("SPD SI CHIP",medindex++,mat,params);
139 //med = new TGeoMedium("SPD SI CHIP",medindex++,matindex++,0,ifield,
140 // fieldm,ktmaxfdSi,kstemaxSi,kdeemaxSi,kepsilSi,kstminSi);
142 mat = new TGeoMaterial("SPD SI BUS",28.086,14.0,2.33*fgkgcm3,
143 TGeoMaterial::kMatStateSolid,25.0*fgkCelsius,
145 mat->SetIndex(matindex);
146 med = new TGeoMedium("SPD SI BUS",medindex++,mat,params);
147 //med = new TGeoMedium("SPD SI BUS",medindex++,matindex++,0,ifield,
148 // fieldm,ktmaxfdSi,kstemaxSi,kdeemaxSi,kepsilSi,kstminSi);
150 mix = new TGeoMixture("C (M55J)",4,1.9866*fgkgcm3);// Carbon fiber by fractional weight "C (M55J)"
151 mix->SetIndex(matindex);
152 mix->DefineElement(0,12.0107,6.0,0.908508078); // Carbon by fractional weight
153 mix->DefineElement(1,14.0067,7.0,0.010387573); // Nitrogen by fractional weight
154 mix->DefineElement(2,15.9994,8.0,0.055957585); // Oxigen by fractional weight
155 mix->DefineElement(3,1.00794,1.0,0.025146765); // Hydrogen by fractional weight
156 mix->SetPressure(0.0*fgkPascal);
157 mix->SetTemperature(25.0*fgkCelsius);
158 mix->SetState(TGeoMaterial::kMatStateSolid);
164 med = new TGeoMedium("ITSspdCarbonFiber",medindex++,mix,params);
165 //med = new TGeoMedium("ITSspdCarbonFiber",medindex++,matindex++,0,ifield,
166 // fieldm,ktmaxfd,kstemax,kdeemax,kepsil,kstmin);
168 mix = new TGeoMixture("Air",4,1.20479E-3*fgkgcm3);// Carbon fiber by fractional weight
169 mix->SetIndex(matindex);
170 mix->DefineElement(0,12.0107,6.0,0.000124); // Carbon by fractional weight
171 mix->DefineElement(1,14.0067,7.0,0.755267); // Nitrogen by fractional weight
172 mix->DefineElement(2,15.9994,8.0,0.231781); // Oxigen by fractional weight
173 mix->DefineElement(3,39.948,18.0,0.012827); // Argon by fractional weight
174 mix->SetPressure(101325.0*fgkPascal); // 1 atmosphere
175 mix->SetTemperature(25.0*fgkCelsius);
176 mix->SetState(TGeoMaterial::kMatStateGas);
177 params[3] = ktmaxfdAir;
178 params[4] = kstemaxAir;
179 params[5] = kdeemaxAir;
180 params[6] = kepsilAir;
181 params[7] = kstminAir;
182 med = new TGeoMedium("ITSspdAir",medindex++,mix,params);
183 //med = new TGeoMedium("ITSspdAir",medindex++,matindex++,0,ifield,
184 // fieldm,ktmaxfdAir,kstemaxAir,kdeemaxAir,kepsilAir,kstminAir);
186 mix = new TGeoMixture("INOX",9,8.03*fgkgcm3);// Carbon fiber by fractional weight
187 mix->SetIndex(matindex);
188 mix->DefineElement(0,12.0107, 6.0,0.0003); // Carbon by fractional weight
189 mix->DefineElement(1,54.9380,25.0,0.02); // Iron by fractional weight
190 mix->DefineElement(2,28.0855,14.0,0.01); // Sodium by fractional weight
191 mix->DefineElement(3,30.9738,15.0,0.00045); // by fractional weight
192 mix->DefineElement(4,32.066 ,16.0,0.0003); // by fractional weight
193 mix->DefineElement(5,58.6928,28.0,0.12); // Nickel by fractional weight
194 mix->DefineElement(6,55.9961,24.0,0.17); // by fractional weight
195 mix->DefineElement(7,95.84 ,42.0,0.025); // by fractional weight
196 mix->DefineElement(8,55.845 ,26.0,0.654); // by fractional weight
197 mix->SetPressure(0.0*fgkPascal); //
198 mix->SetTemperature(25.0*fgkCelsius);
199 mix->SetState(TGeoMaterial::kMatStateSolid);
200 params[3] = ktmaxfdAir;
201 params[4] = kstemaxAir;
202 params[5] = kdeemaxAir;
203 params[6] = kepsilAir;
204 params[7] = kstminAir;
205 med = new TGeoMedium("ITSspdStainlessSteel",medindex++,mix,params);
206 //med = new TGeoMedium("ITSspdStainlessSteel",medindex++,matindex++,0,ifield,
207 // fieldm,ktmaxfdAir,kstemaxAir,kdeemaxAir,kepsilAir,kstminAir);
209 mix = new TGeoMixture("Freon",2,1.63*fgkgcm3);// Carbon fiber by fractional weight
210 mix->SetIndex(matindex);
211 mix->DefineElement(0,12.0107,6.0,4); // Carbon by fractional weight
212 mix->DefineElement(1,18.9984032,9.0,10); // Florine by fractional weight
213 mix->SetPressure(101325.0*fgkPascal); // 1 atmosphere
214 mix->SetTemperature(25.0*fgkCelsius);
215 mix->SetState(TGeoMaterial::kMatStateLiquid);
216 params[3] = ktmaxfdAir;
217 params[4] = kstemaxAir;
218 params[5] = kdeemaxAir;
219 params[6] = kepsilAir;
220 params[7] = kstminAir;
221 med = new TGeoMedium("ITSspdCoolingFluid",medindex++,mix,params);
222 //med = new TGeoMedium("ITSspdCoolingFluid",medindex++,matindex++,0,ifield,
223 // fieldm,ktmaxfdAir,kstemaxAir,kdeemaxAir,kepsilAir,kstminAir);
225 medOffset = medindex;
226 matOffset = matindex;
229 //______________________________________________________________________
230 void AliITSv11GeometrySPD::InitSPDCenteral(Int_t offset,TVirtualMC *vmc){
231 // Do any SPD Centeral detector related initilizations, setting
232 // transport cuts for example.
233 // Some GEANT3 Physics switches
235 // Multiple scattering. The variable IMULS controls this process. For
236 // more information see [PHYS320 or 325 or 328].
237 // 0 - No multiple scattering.
238 // 1 - Multiple scattering according to Molière theory. Default setting.
239 // 2 - Same as 1. Kept for backward compatibility.
240 // 3 - Pure Gaussian scattering according to the Rossi formula.
242 // delta ray production. The variable IDRAY controls this process. See [PHYS430]
243 // 0 - No delta rays production.
244 // 1 - delta rays production with generation of . Default setting.
245 // 2 - delta rays production without generation of .
247 // Continuous energy loss. The variable ILOSS controls this process.
248 // 0 - No continuous energy loss, IDRAY is set to 0.
249 // 1 - Continuous energy loss with generation of delta rays above
250 // DCUTE (common/GCUTS/) and restricted Landau fluctuations below DCUTE.
251 // 2 - Continuous energy loss without generation of delta rays and full
252 // Landau-Vavilov-Gauss fluctuations. In this case the variable IDRAY
253 // is forced to 0 to avoid double counting of fluctuations. Default setting.
254 // 3 - Same as 1, kept for backward compatibility.
255 // 4 - Energy loss without fluctuation. The value obtained from the tables is
258 // Int_t offset The material/medium index offset.
259 // TVirturalMC *vmc The pointer to the virtual Monte Carlo default gMC.
267 vmc->Gstpar(i+offset,"CUTGAM",30.0*fgkKeV);
268 vmc->Gstpar(i+offset,"CUTELE",30.0*fgkKeV);
269 vmc->Gstpar(i+offset,"CUTNEU",30.0*fgkKeV);
270 vmc->Gstpar(i+offset,"CUTHAD",30.0*fgkKeV);
271 vmc->Gstpar(i+offset,"CUTMUO",30.0*fgkKeV);
272 vmc->Gstpar(i+offset,"BCUTE",30.0*fgkKeV);
273 vmc->Gstpar(i+offset,"BCUTM",30.0*fgkKeV);
274 vmc->Gstpar(i+offset,"DCUTE",30.0*fgkKeV);
275 vmc->Gstpar(i+offset,"DCUTM",30.0*fgkKeV);
276 //vmc->Gstpar(i+offset,"PPCUTM",);
277 //vmc->Gstpar(i+offset,"PAIR",);
278 //vmc->Gstpar(i+offset,"COMPT",);
279 //vmc->Gstpar(i+offset,"PHOT",);
280 //vmc->Gstpar(i+offset,"PFIS",);
281 vmc->Gstpar(i+offset,"DRAY",1);
282 //vmc->Gstpar(i+offset,"ANNI",);
283 //vmc->Gstpar(i+offset,"BREM",);
284 //vmc->Gstpar(i+offset,"HADR",);
285 //vmc->Gstpar(i+offset,"MUNU",);
286 //vmc->Gstpar(i+offset,"DCAY",);
287 vmc->Gstpar(i+offset,"LOSS",1);
288 //vmc->Gstpar(i+offset,"MULS",);
289 //vmc->Gstpar(i+offset,"GHCOR1",);
290 //vmc->Gstpar(i+offset,"BIRK1",);
291 //vmc->Gstpar(i+offset,"BRIK2",);
292 //vmc->Gstpar(i+offset,"BRIK3",);
293 //vmc->Gstpar(i+offset,"LABS",);
294 //vmc->Gstpar(i+offset,"SYNC",);
295 //vmc->Gstpar(i+offset,"STRA",);
298 //______________________________________________________________________
299 void AliITSv11GeometrySPD::SPDSector(TGeoVolume *moth,TGeoManager *mgr){
300 // Position of the Carbon Fiber Assembly based on distance
301 // of closest point of SPD stave to beam pipe figures
302 // all-sections-modules.ps of 7.22mm at section A-A.
304 // TGeoVolume *moth the mother volume which this
305 // object/volume is to be placed in.
310 const Double_t kSPDclossesStaveAA = 7.22*fgkmm;
311 const Double_t kSectorStartingAngle = -72.0*fgkDegree;
312 const Double_t kNSectorsTotal = 10.; // number
313 const Double_t kSectorRelativeAngle = 360./kNSectorsTotal*fgkDegree;
314 const Double_t kBeamPipeRadius = 0.5*60.0*fgkmm;
317 Double_t angle,radiusSector,xAAtubeCenter0,yAAtubeCenter0;
318 Double_t staveThicknessAA=1.03*fgkmm; // get from stave geometry.
319 TGeoCombiTrans *secRot=new TGeoCombiTrans();
320 TGeoVolume *vCarbonFiberSector;
321 TGeoMedium *medSPDcf;
323 medSPDcf = mgr->GetMedium("ITSspdCarbonFiber");
324 vCarbonFiberSector = new TGeoVolumeAssembly("ITSSPDCarbonFiberSectorV");
325 vCarbonFiberSector->SetMedium(medSPDcf);
326 CarbonFiberSector(vCarbonFiberSector,xAAtubeCenter0,yAAtubeCenter0);
327 vCarbonFiberSector->SetVisibility(kFALSE); // logical volume
328 // Compute the radial shift out of the sectors.
329 radiusSector = kBeamPipeRadius+kSPDclossesStaveAA+staveThicknessAA;
330 radiusSector *= radiusSector; // squaring;
331 radiusSector -= xAAtubeCenter0*xAAtubeCenter0;
332 radiusSector = -yAAtubeCenter0+TMath::Sqrt(radiusSector);
333 angle = kSectorStartingAngle;
334 secRot->RotateZ(angle);
335 for(i=0;i<(Int_t)kNSectorsTotal;i++){
336 secRot->SetDx(-radiusSector*TMath::Sin(angle/fgkRadian));
337 secRot->SetDy(radiusSector*TMath::Cos(angle/fgkRadian));
338 //secRot->RegisterYourself();
339 moth->AddNode(vCarbonFiberSector,i+1,new TGeoCombiTrans(*secRot));
340 printf("i=%d angle=%g angle[rad]=%g radiusSector=%g x=%g y=%g \n",
341 i,angle,angle/fgkRadian,radiusSector,
342 -radiusSector*TMath::Sin(angle/fgkRadian),
343 radiusSector*TMath::Cos(angle/fgkRadian));
344 angle += kSectorRelativeAngle;
345 secRot->RotateZ(kSectorRelativeAngle);
349 } // end if GetDebug().
352 //______________________________________________________________________
353 void AliITSv11GeometrySPD::CarbonFiberSector(TGeoVolume *moth,
354 Double_t &xAAtubeCenter0,
355 Double_t &yAAtubeCenter0,
357 // Define the detail SPD Carbon fiber support Sector geometry.
358 // Based on the drawings ALICE-Pixel "Construzione Profilo Modulo"
359 // March 25 2004 and ALICE-SUPPORTO "construzione Profilo Modulo"
360 // Define Outside radii as negitive, Outside in the sence that the
361 // center of the arc is outside of the object.
364 // TGeoVolume *moth The mother volume to put this object
366 // Double_t &xAAtubeCenter0 The x location of the outer surface
367 // of the cooling tube center for tube 0.
368 // This location helps determine where
369 // this sector is to be located (information
370 // used for this is the distance the
371 // center of the #0 detector is from the
372 // beam pipe. Measurements taken at
373 // cross section A-A.
374 // Double_t &yAAtubeCenter0 The y location of the outer surface
375 // of the cooling tube center for tube 0
376 // This location helps determine where
377 // this sector is to be located (information
378 // used for this is the distance the
379 // center of the #0 detector is from the
380 // beam pipe. Measurements taken at
381 // cross section A-A.
382 // TGeoManager *mgr The TGeoManager as needed, default is
386 TGeoMedium *medSPDcf = 0; // SPD support cone Carbon Fiber materal number.
387 //TGeoMedium *medSPDfs = 0; // SPD support cone inserto stesalite 4411w.
388 //TGeoMedium *medSPDfo = 0; // SPD support cone foam, Rohacell 50A.
389 TGeoMedium *medSPDss = 0; // SPD support cone screw material,Stainless
390 TGeoMedium *medSPDair = 0; // SPD support cone Air
391 //TGeoMedium *medSPDal = 0; // SPD support cone SDD mounting bracket Al
392 TGeoMedium *medSPDcoolfl = 0; // SPD cooling fluid, Freeon
393 medSPDcf = mgr->GetMedium("ITSspdCarbonFiber");
394 //medSPDfs = mgr->GetMedium("ITSspdStaselite4411w");
395 //medSPDfo = mgr->GetMedium("ITSspdRohacell50A");
396 medSPDss = mgr->GetMedium("ITSspdStainlessSteel");
397 medSPDair= mgr->GetMedium("ITSspdAir");
398 medSPDcoolfl= mgr->GetMedium("ITSspdCoolingFluid");
400 const Double_t ksecDz = 0.5*500.0*fgkmm;
401 const Double_t ksecLen = 30.0*fgkmm;
402 const Double_t ksecCthick = 0.20*fgkmm;
403 const Double_t ksecDipLength = 3.2*fgkmm;
404 const Double_t ksecDipRadii = 0.4*fgkmm;
405 //const Double_t ksecCoolingTubeExtraDepth = 0.86*fgkmm;
406 // These positions, ksecX*,ksecY* are the center of curvatures
407 // for the different point around the SPD sector. The radii,
408 // inner and outer, are the radous of curvature about the centers
409 // ksecX* and ksecY*. To draw this SPD sector, first plot all of
410 // the ksecX and ksecY points and draw circles of the specified
411 // radius about these points. Connect the circles, such that the
412 // lines are tangent to the circles, in accordance with the
413 // radii being "Inside" or "Outside". These lines and the
414 // corresponding arc's are the surface of this SPD sector.
415 const Double_t ksecX0 = -10.725*fgkmm;
416 const Double_t ksecY0 = -14.853*fgkmm;
417 const Double_t ksecR0 = -0.8*fgkmm; // Outside
418 const Double_t ksecX1 = -13.187*fgkmm;
419 const Double_t ksecY1 = -19.964*fgkmm;
420 const Double_t ksecR1 = +0.6*fgkmm; // Inside
421 //const Double_t ksecDip0 = 5.9*fgkmm;
423 const Double_t ksecX2 = -3.883*fgkmm;
424 const Double_t ksecY2 = -17.805*fgkmm;
425 const Double_t ksecR2 = +0.80*fgkmm; // Inside Guess.
426 const Double_t ksecX3 = -3.123*fgkmm;
427 const Double_t ksecY3 = -14.618*fgkmm;
428 const Double_t ksecR3 = -0.6*fgkmm; // Outside
429 //const Double_t ksecDip1 = 8.035*fgkmm;
431 const Double_t ksecX4 = +11.280*fgkmm;
432 const Double_t ksecY4 = -14.473*fgkmm;
433 const Double_t ksecR4 = +0.8*fgkmm; // Inside
434 const Double_t ksecX5 = +19.544*fgkmm;
435 const Double_t ksecY5 = +10.961*fgkmm;
436 const Double_t ksecR5 = +0.8*fgkmm; // Inside
437 //const Double_t ksecDip2 = 4.553*fgkmm;
439 const Double_t ksecX6 = +10.830*fgkmm;
440 const Double_t ksecY6 = +16.858*fgkmm;
441 const Double_t ksecR6 = +0.6*fgkmm; // Inside
442 const Double_t ksecX7 = +11.581*fgkmm;
443 const Double_t ksecY7 = +13.317*fgkmm;
444 const Double_t ksecR7 = -0.6*fgkmm; // Outside
445 //const Double_t ksecDip3 = 6.978*fgkmm;
447 const Double_t ksecX8 = -0.733*fgkmm;
448 const Double_t ksecY8 = +17.486*fgkmm;
449 const Double_t ksecR8 = +0.6*fgkmm; // Inside
450 const Double_t ksecX9 = +0.562*fgkmm;
451 const Double_t ksecY9 = +14.486*fgkmm;
452 const Double_t ksecR9 = -0.6*fgkmm; // Outside
453 //const Double_t ksecDip4 = 6.978*fgkmm;
455 const Double_t ksecX10 = -12.252*fgkmm;
456 const Double_t ksecY10 = +16.298*fgkmm;
457 const Double_t ksecR10 = +0.6*fgkmm; // Inside
458 const Double_t ksecX11 = -10.445*fgkmm;
459 const Double_t ksecY11 = +13.162*fgkmm;
460 const Double_t ksecR11 = -0.6*fgkmm; // Outside
461 //const Double_t ksecDip5 = 6.978*fgkmm;
463 const Double_t ksecX12 = -22.276*fgkmm;
464 const Double_t ksecY12 = +12.948*fgkmm;
465 const Double_t ksecR12 = +0.85*fgkmm; // Inside
466 //const Double_t ksecX13 = *fgkmm;
467 //const Double_t ksecY13 = *fgkmm;
468 const Double_t ksecR13 = -0.8*fgkmm; // Outside
469 const Double_t ksecAngleSide13 = 36.0*fgkDegree;
471 const Int_t ksecNRadii = 20;
472 const Int_t ksecNPointsPerRadii = 4;
473 const Int_t ksecNCoolingTubeDips = 6;
474 // Since the Rounded parts are aproximated by a regular polygon and
475 // a cooling tube of the propper diameter must fit, a scaling factor
476 // increases the size of the polygon for the tube to fit.
477 //const Double_t ksecRCoolScale = 1./TMath::Cos(TMath::Pi()/
478 // (Double_t)ksecNPointsPerRadii);
479 const Double_t ksecZEndLen = 30.00*fgkmm;
480 //const Double_t ksecZFlangLen= 45.00*fgkmm;
481 const Double_t ksecTl = 0.860*fgkmm;
482 const Double_t ksecCthick2 = 0.600*fgkmm;
483 //const Double_t ksecCthick3 = 1.800*fgkmm;
484 //const Double_t ksecSidelen = 22.00*fgkmm;
485 //const Double_t ksecSideD5 = 3.679*fgkmm;
486 //const Double_t ksecSideD12 = 7.066*fgkmm;
487 const Double_t ksecRCoolOut = 2.400*fgkmm;
488 const Double_t ksecRCoolIn = 2.000*fgkmm;
489 const Double_t ksecDl1 = 5.900*fgkmm;
490 const Double_t ksecDl2 = 8.035*fgkmm;
491 const Double_t ksecDl3 = 4.553*fgkmm;
492 const Double_t ksecDl4 = 6.978*fgkmm;
493 const Double_t ksecDl5 = 6.978*fgkmm;
494 const Double_t ksecDl6 = 6.978*fgkmm;
495 const Double_t ksecCoolTubeThick = 0.04*fgkmm;
496 const Double_t ksecCoolTubeROuter = 2.6*fgkmm;
497 const Double_t ksecCoolTubeFlatX = 3.696*fgkmm;
498 const Double_t ksecCoolTubeFlatY = 0.68*fgkmm;
499 //const Double_t ksecBeamX0 = 0.0*fgkmm; // guess
500 //const Double_t ksecBeamY0 = (15.223+40.)*fgkmm; // guess
502 const Int_t ksecNPoints = (ksecNPointsPerRadii+1)*ksecNRadii + 8;
503 Double_t secX[ksecNRadii] = {ksecX0,ksecX1,-1000.0,ksecX2 ,ksecX3 ,-1000.0,
504 ksecX4,ksecX5,-1000.0,ksecX6 ,ksecX7 ,-1000.0,
505 ksecX8,ksecX9,-1000.0,ksecX10,ksecX11,-1000.0,
507 Double_t secY[ksecNRadii] = {ksecY0,ksecY1,-1000.0,ksecY2 ,ksecY3 ,-1000.0,
508 ksecY4,ksecY5,-1000.0,ksecY6 ,ksecY7 ,-1000.0,
509 ksecY8,ksecY9,-1000.0,ksecY10,ksecY11,-1000.0,
511 Double_t secR[ksecNRadii] ={ksecR0 ,ksecR1 ,-.5*ksecDipLength-ksecDipRadii,
512 ksecR2 ,ksecR3 ,-.5*ksecDipLength-ksecDipRadii,
513 ksecR4 ,ksecR5 ,-.5*ksecDipLength-ksecDipRadii,
514 ksecR6 ,ksecR7 ,-.5*ksecDipLength-ksecDipRadii,
515 ksecR8 ,ksecR9 ,-.5*ksecDipLength-ksecDipRadii,
516 ksecR10,ksecR11,-.5*ksecDipLength-ksecDipRadii,
518 Double_t secDip[ksecNRadii]={0.0,0.0,ksecDip0,0.0,0.0,ksecDip1,
519 0.0,0.0,ksecDip2,0.0,0.0,ksecDip3,
520 0.0,0.0,ksecDip4,0.0,0.0,ksecDip5,
522 Double_t secX2[ksecNRadii];
523 Double_t secY2[ksecNRadii];
524 Double_t secR2[ksecNRadii] = {
525 ksecR0,ksecR1,ksecRCoolOut,ksecR2,ksecR3,ksecRCoolOut,ksecR4,ksecR5,
526 ksecRCoolOut,ksecR6,ksecR7,ksecRCoolOut,ksecR8,ksecR9,ksecRCoolOut,
527 ksecR10,ksecR11,ksecRCoolOut,ksecR12,ksecR13};
528 Double_t secDip2[ksecNCoolingTubeDips]={ksecDl1,ksecDl2,ksecDl3,
529 ksecDl4,ksecDl5,ksecDl6};
530 Double_t secX3[ksecNRadii];
531 Double_t secY3[ksecNRadii];
532 const Int_t ksecDipIndex[ksecNCoolingTubeDips] = {2,5,8,11,14,17};
533 Double_t secAngleStart[ksecNRadii];
534 Double_t secAngleEnd[ksecNRadii];
535 Double_t secAngleStart2[ksecNRadii];
536 Double_t secAngleEnd2[ksecNRadii];
537 Double_t secAngleTurbo[ksecNCoolingTubeDips] = {0.0,0.0,0.0,0.0,0.0,0.0};
538 //Double_t secAngleStart3[ksecNRadii];
539 //Double_t secAngleEnd3[ksecNRadii];
540 Double_t xpp[ksecNPoints],ypp[ksecNPoints];
541 Double_t xpp2[ksecNPoints],ypp2[ksecNPoints];
542 Double_t *xp[ksecNRadii],*xp2[ksecNRadii];
543 Double_t *yp[ksecNRadii],*yp2[ksecNRadii];
544 TGeoXtru *sA0,*sA1,*sB0,*sB1;
545 TGeoEltu *sTA0,*sTA1;
546 TGeoTube *sTB0,*sTB1,*sM0;
548 TGeoTranslation *trans;
549 TGeoCombiTrans *rotrans;
550 Double_t t,t0,t1,a,b,x0,y0,x1,y1;
555 Error("CarbonFiberSector","moth=%p",moth);
559 for(i=0;i<ksecNRadii;i++){
560 xp[i] = &(xpp[i*(ksecNPointsPerRadii+1)]);
561 yp[i] = &(ypp[i*(ksecNPointsPerRadii+1)]);
562 xp2[i] = &(xpp2[i*(ksecNPointsPerRadii+1)]);
563 yp2[i] = &(ypp2[i*(ksecNPointsPerRadii+1)]);
570 // Find starting and ending angles for all but cooling tube sections
571 secAngleStart[0] = 0.5*ksecAngleSide13;
572 for(i=0;i<ksecNRadii-2;i++){
574 for(j=0;j<ksecNCoolingTubeDips;j++) tst = tst||i==ksecDipIndex[j];
577 for(j=0;j<ksecNCoolingTubeDips;j++) tst = tst||(i+1)==ksecDipIndex[j];
580 AnglesForRoundedCorners(secX[i],secY[i],secR[i],
581 secX[j],secY[j],secR[j],t0,t1);
583 secAngleStart[j] = t1;
584 if(secR[i]>0.0&&secR[j]>0.0)if(secAngleStart[i]>secAngleEnd[i])
585 secAngleEnd[i] += 360.0;
586 secAngleStart2[i] = secAngleStart[i];
587 secAngleEnd2[i] = secAngleEnd[i];
589 secAngleEnd[ksecNRadii-2] = secAngleStart[ksecNRadii-2] +
590 (secAngleEnd[ksecNRadii-5]-
591 secAngleStart[ksecNRadii-5]);
592 if(secAngleEnd[ksecNRadii-2]<0.0) secAngleEnd[ksecNRadii-2] += 360.0;
593 secAngleStart[ksecNRadii-1] = secAngleEnd[ksecNRadii-2] - 180.0;
594 secAngleEnd[ksecNRadii-1] = secAngleStart[0];
595 secAngleStart2[ksecNRadii-2] = secAngleStart[ksecNRadii-2];
596 secAngleEnd2[ksecNRadii-2] = secAngleEnd[ksecNRadii-2];
597 secAngleStart2[ksecNRadii-1] = secAngleStart[ksecNRadii-1];
598 secAngleEnd2[ksecNRadii-1] = secAngleEnd[ksecNRadii-1];
599 // Find location of circle last rounded corner.
602 t0 = TanD(secAngleStart[i]-90.);
603 t1 = TanD(secAngleEnd[j]-90.);
604 t = secY[i] - secY[j];
605 // Note, secR[i=0] <0; secR[j=18]>0; and secR[j+1=19] <0
606 t += (-secR[i]+secR[j+1])*SinD(secAngleStart[i]);
607 t -= (secR[j]-secR[j+1])*SinD(secAngleEnd[j]);
608 t += t1*secX[j] - t0*secX[i];
609 t += t1*(secR[j]-secR[j+1])*CosD(secAngleEnd[j]);
610 t -= t0*(-secR[i]+secR[j+1])*CosD(secAngleStart[i]);
611 secX[ksecNRadii-1] = t/(t1-t0);
612 secY[ksecNRadii-1] = TanD(90.+0.5*ksecAngleSide13)*
613 (secX[ksecNRadii-1]-secX[0]) + secY[0];
614 secX2[ksecNRadii-1] = secX[ksecNRadii-1];
615 secY2[ksecNRadii-1] = secY[ksecNRadii-1];
616 secX3[ksecNRadii-1] = secX[ksecNRadii-1];
617 secY3[ksecNRadii-1] = secY[ksecNRadii-1];
618 // find location of cooling tube centers
619 for(i=0;i<ksecNCoolingTubeDips;i++){
621 x0 = secX[j-1] + TMath::Abs(secR[j-1])*CosD(secAngleEnd[j-1]);
622 y0 = secY[j-1] + TMath::Abs(secR[j-1])*SinD(secAngleEnd[j-1]);
623 x1 = secX[j+1] + TMath::Abs(secR[j+1])*CosD(secAngleStart[j+1]);
624 y1 = secY[j+1] + TMath::Abs(secR[j+1])*SinD(secAngleStart[j+1]);
625 t0 = TMath::Sqrt((x0-x1)*(x0-x1)+(y0-y1)*(y0-y1));
629 if(i==0){ // get location of tube center->Surface for locating
630 // this sector around the beam pipe. This needs to be
631 // double checked, but I need my notes for that, Bjorn Nilsen
632 xAAtubeCenter0 = x0+(x1-x0)*t*0.5;
633 yAAtubeCenter0 = y0+(y1-y0)*t*0.5;
635 if(a+b*(a-x0)/(b-y0)>0.0){
636 secX[j] = a + TMath::Abs(y1-y0)*2.0*ksecDipRadii/t0;
637 secY[j] = b - TMath::Sign(2.0*ksecDipRadii,y1-y0)*(x1-x0)/t0;
638 secX2[j] = a + TMath::Abs(y1-y0)*ksecTl/t0;
639 secY2[j] = b - TMath::Sign(ksecTl,y1-y0)*(x1-x0)/t0;
640 secX3[j] = a + TMath::Abs(y1-y0)*(2.0*ksecDipRadii-
641 0.5*ksecCoolTubeFlatY)/t0;
642 secY3[j] = b - TMath::Sign(2.0*ksecDipRadii-0.5*ksecCoolTubeFlatY,
645 secX[j] = a - TMath::Abs(y1-y0)*2.0*ksecDipRadii/t0;
646 secY[j] = b + TMath::Sign(2.0*ksecDipRadii,y1-y0)*(x1-x0)/t0;
647 secX2[j] = a - TMath::Abs(y1-y0)*ksecTl/t0;
648 secY2[j] = b + TMath::Sign(ksecTl,y1-y0)*(x1-x0)/t0;
649 secX3[j] = a - TMath::Abs(y1-y0)*(2.0*ksecDipRadii-
650 0.5*ksecCoolTubeFlatY)/t0;
651 secY3[j] = b + TMath::Sign(2.0*ksecDipRadii-0.5*ksecCoolTubeFlatY,
654 // Set up Start and End angles to correspond to start/end of dips.
655 t1 = (secDip2[i]-TMath::Abs(secR[j]))/t0;
656 secAngleStart[j] = TMath::RadToDeg()*TMath::ATan2(
657 y0+(y1-y0)*t1-secY[j],x0+(x1-x0)*t1-secX[j]);
658 if(secAngleStart[j]<0.0) secAngleStart[j] += 360.0;
659 secAngleStart2[j] = secAngleStart[j];
660 t1 = (secDip2[i]+TMath::Abs(secR[j]))/t0;
661 secAngleEnd[j] = TMath::RadToDeg()*TMath::ATan2(
662 y0+(y1-y0)*t1-secY[j],x0+(x1-x0)*t1-secX[j]);
663 if(secAngleEnd[j]<0.0) secAngleEnd[j] += 360.0;
664 secAngleEnd2[j] = secAngleEnd[j];
665 if(secAngleEnd[j]>secAngleStart[j]) secAngleEnd[j] -= 360.0;
666 secR[j] = TMath::Sqrt(secR[j]*secR[j]+4.0*ksecDipRadii*ksecDipRadii);
669 secAngleStart2[8] -= 360.;
670 secAngleStart2[11] -= 360.;
672 SPDsectorShape(ksecNRadii,secX,secY,secR,secAngleStart,secAngleEnd,
673 ksecNPointsPerRadii,m,xp,yp);
674 // Fix up dips to be square.
675 for(i=0;i<ksecNCoolingTubeDips;i++){
677 t = 0.5*ksecDipLength+ksecDipRadii;
678 t0 = TMath::RadToDeg()*TMath::ATan(2.0*ksecDipRadii/t);
679 t1 = secAngleEnd[j] + t0;
680 t0 = secAngleStart[j] - t0;
681 x0 = xp[j][1] = secX[j] + t*CosD(t0);
682 y0 = yp[j][1] = secY[j] + t*SinD(t0);
683 x1 = xp[j][ksecNPointsPerRadii-1] = secX[j] + t*CosD(t1);
684 y1 = yp[j][ksecNPointsPerRadii-1] = secY[j] + t*SinD(t1);
685 t0 = 1./((Double_t)(ksecNPointsPerRadii-2));
686 for(k=2;k<ksecNPointsPerRadii-1;k++){// extra points spread them out.
687 t = ((Double_t)(k-1))*t0;
688 xp[j][k] = x0+(x1-x0)*t;
689 yp[j][k] = y0+(y1-y0)*t;
691 secAngleTurbo[i] = -TMath::RadToDeg()*TMath::ATan2(y1-y0,x1-x0);
693 cout <<"i="<<i<<" angle="<<secAngleTurbo[i]<<" x0,y0{"
694 <<x0<<","<<y0<<"} x1y1={"<<x1<<","<<y1<<"}"<<endl;
697 sA0 = new TGeoXtru(2);
698 sA0->SetName("ITS SPD Carbon fiber support Sector A0");
699 sA0->DefinePolygon(m,xpp,ypp);
700 sA0->DefineSection(0,-ksecDz);
701 sA0->DefineSection(1,ksecDz);
703 InsidePoint(xpp[m-1],ypp[m-1],xpp[0],ypp[0],xpp[1],ypp[1],
704 ksecCthick,xpp2[0],ypp2[0]);
706 j = i/(ksecNPointsPerRadii+1);
707 InsidePoint(xpp[i-1],ypp[i-1],xpp[i],ypp[i],xpp[i+1],ypp[i+1],
708 ksecCthick,xpp2[i],ypp2[i]);
710 InsidePoint(xpp[m-2],ypp[m-2],xpp[m-1],ypp[m-1],xpp[0],ypp[0],
711 ksecCthick,xpp2[m-1],ypp2[m-1]);
712 // Fix center value of cooling tube dip.
713 // find location of cooling tube centers
714 for(i=0;i<ksecNCoolingTubeDips;i++){
718 x1 = xp2[j][ksecNPointsPerRadii-1];
719 y1 = yp2[j][ksecNPointsPerRadii-1];
720 t0 = TMath::Sqrt((x0-x1)*(x0-x1)+(y0-y1)*(y0-y1));
722 for(k=2;k<ksecNPointsPerRadii-1;k++){// extra points spread them out.
723 t = ((Double_t)(k-1))*t0;
724 xp2[j][k] = x0+(x1-x0)*t;
725 yp2[j][k] = y0+(y1-y0)*t;
728 sA1 = new TGeoXtru(2);
729 sA1->SetName("ITS SPD Carbon fiber support Sector Air A1");
730 sA1->DefinePolygon(m,xpp2,ypp2);
731 sA1->DefineSection(0,-ksecDz);
732 sA1->DefineSection(1,ksecDz);
734 // Error in TGeoEltu. Semi-axis X must be < Semi-axis Y (?).
735 sTA0 = new TGeoEltu("ITS SPD Cooling Tube TA0",
736 0.5* ksecCoolTubeFlatY, 0.5* ksecCoolTubeFlatX,ksecDz);
737 sTA1 = new TGeoEltu("ITS SPD Cooling Tube coolant TA1",
738 sTA0->GetA()-ksecCoolTubeThick,
739 sTA0->GetB()-ksecCoolTubeThick,ksecDz);
741 SPDsectorShape(ksecNRadii,secX2,secY2,secR2,secAngleStart2,secAngleEnd2,
742 ksecNPointsPerRadii,m,xp,yp);
744 sB0 = new TGeoXtru(2);
745 sB0->SetName("ITS SPD Carbon fiber support Sector End B0");
746 sB0->DefinePolygon(m,xpp,ypp);
747 sB0->DefineSection(0,ksecDz);
748 sB0->DefineSection(1,ksecDz+ksecZEndLen);
750 InsidePoint(xpp[m-1],ypp[m-1],xpp[0],ypp[0],xpp[1],ypp[1],
751 ksecCthick2,xpp2[0],ypp2[0]);
754 for(k=0;k<ksecNCoolingTubeDips;k++)
755 if((i/(ksecNPointsPerRadii+1))==ksecDipIndex[k])
756 if(!(ksecDipIndex[k]*(ksecNPointsPerRadii+1)==i ||
757 ksecDipIndex[k]*(ksecNPointsPerRadii+1)+
758 ksecNPointsPerRadii==i ))
759 t = ksecRCoolOut-ksecRCoolIn;
760 InsidePoint(xpp[i-1],ypp[i-1],xpp[i],ypp[i],xpp[i+1],ypp[i+1],
763 InsidePoint(xpp[m-2],ypp[m-2],xpp[m-1],ypp[m-1],xpp[0],ypp[0],
764 ksecCthick2,xpp2[m-1],ypp2[m-1]);
765 sB1 = new TGeoXtru(2);
766 sB1->SetName("ITS SPD Carbon fiber support Sector Air End B1");
767 sB1->DefinePolygon(m,xpp2,ypp2);
768 sB1->DefineSection(0,ksecDz);
769 sB1->DefineSection(1,ksecDz+ksecLen);
770 sTB0 = new TGeoTube("ITS SPD Cooling Tube End TB0",0.0,
771 0.5*ksecCoolTubeROuter,0.5*ksecLen);
772 sTB1 = new TGeoTube("ITS SPD Cooling Tube End coolant TB0",0.0,
773 sTB0->GetRmax()-ksecCoolTubeThick,0.5*ksecLen);
775 sM0 = new TGeoTube("ITS SPD Sensitive Virutual Volume M0",0.0,8.0,
776 sA0->GetZ(1)+sB0->GetZ(1));
779 cout<<"medSPDcf= "<<medSPDcf<<endl;
780 // printf("medSPDcf=%x\n",medSPDcf);
781 if(medSPDcf) medSPDcf->Dump();
782 cout<<"medSPDss= "<<medSPDss<<endl;
783 // printf("medSPDss=%x\n",medSPDss);
784 if(medSPDss) medSPDss->Dump();
785 cout<<"medSPDair= "<<medSPDair<<endl;
786 // printf("medSPDair=%x\n",medSPDair);
787 if(medSPDair) medSPDair->Dump();
788 cout<<"medSPDcoolfl= "<<medSPDcoolfl<<endl;
789 // printf("medSPDcoolfl=%x\n",medSPDcoolfl);
790 if(medSPDcoolfl) medSPDcoolfl->Dump();
798 TGeoVolume *vM0,*vA0,*vA1,*vTA0,*vTA1,*vB0,*vB1,*vTB0,*vTB1;
799 vM0 = new TGeoVolume("ITSSPDSensitiveVirtualvolumeM0",sM0,medSPDair);
800 vM0->SetVisibility(kTRUE);
801 vM0->SetLineColor(7); // light Blue
802 vM0->SetLineWidth(1);
803 vM0->SetFillColor(vM0->GetLineColor());
804 vM0->SetFillStyle(4090); // 90% transparent
805 vA0 = new TGeoVolume("ITSSPDCarbonFiberSupportSectorA0",sA0,medSPDcf);
806 vA0->SetVisibility(kTRUE);
807 vA0->SetLineColor(4); // Blue
808 vA0->SetLineWidth(1);
809 vA0->SetFillColor(vA0->GetLineColor());
810 vA0->SetFillStyle(4010); // 10% transparent
811 vA1 = new TGeoVolume("ITSSPDCarbonFiberSupportSectorAirA1",sA1,medSPDair);
812 vA1->SetVisibility(kTRUE);
813 vA1->SetLineColor(7); // light Blue
814 vA1->SetLineWidth(1);
815 vA1->SetFillColor(vA1->GetLineColor());
816 vA1->SetFillStyle(4090); // 90% transparent
817 vTA0 = new TGeoVolume("ITSSPDCoolingTubeTA0",sTA0,medSPDss);
818 vTA0->SetVisibility(kTRUE);
819 vTA0->SetLineColor(1); // Black
820 vTA0->SetLineWidth(1);
821 vTA0->SetFillColor(vTA0->GetLineColor());
822 vTA0->SetFillStyle(4000); // 0% transparent
823 vTA1 = new TGeoVolume("ITSSPDCoolingTubeFluidTA1",sTA1,medSPDcoolfl);
824 vTA1->SetVisibility(kTRUE);
825 vTA1->SetLineColor(6); // Purple
826 vTA1->SetLineWidth(1);
827 vTA1->SetFillColor(vTA1->GetLineColor());
828 vTA1->SetFillStyle(4000); // 0% transparent
829 vB0 = new TGeoVolume("ITSSPDCarbonFiberSupportSectorEndB0",sB0,medSPDcf);
830 vB0->SetVisibility(kTRUE);
831 vB0->SetLineColor(4); // Blue
832 vB0->SetLineWidth(1);
833 vB0->SetFillColor(vB0->GetLineColor());
834 vB0->SetFillStyle(4010); // 10% transparent
835 vB1 = new TGeoVolume("ITSSPDCarbonFiberSupportSectorEndAirB1",
837 vB1->SetVisibility(kTRUE);
838 vB1->SetLineColor(7); // light Blue
839 vB1->SetLineWidth(1);
840 vB1->SetFillColor(vB1->GetLineColor());
841 vB1->SetFillStyle(4090); // 90% transparent
842 vTB0 = new TGeoVolume("ITSSPDCoolingTubeEndTB0",sTB0,medSPDss);
843 vTB0->SetVisibility(kTRUE);
844 vTB0->SetLineColor(1); // Black
845 vTB0->SetLineWidth(1);
846 vTB0->SetFillColor(vTB0->GetLineColor());
847 vTB0->SetFillStyle(4000); // 0% transparent
848 vTB1 = new TGeoVolume("ITSSPDCoolingTubeEndFluidTB1",sTB1,medSPDcoolfl);
849 vTB1->SetVisibility(kTRUE);
850 vTB1->SetLineColor(6); // Purple
851 vTB1->SetLineWidth(1);
852 vTB1->SetFillColor(vTB1->GetLineColor());
853 vTB1->SetFillStyle(4000); // 0% transparent
855 moth->AddNode(vM0,1,0); // Add virtual volume to mother
856 vA0->AddNode(vA1,1,0); // Put air inside carbon fiber.
857 vB0->AddNode(vB1,1,0); // Put air inside carbon fiber.
858 vTA0->AddNode(vTA1,1,0); // Put air inside carbon fiber.
859 vTB0->AddNode(vTB1,1,0); // Put air inside carbon fiber.
860 for(i=0;i<ksecNCoolingTubeDips;i++){
861 x0 = secX3[ksecDipIndex[i]];
862 y0 = secY3[ksecDipIndex[i]];
863 t = 90.0-secAngleTurbo[i];
864 trans = new TGeoTranslation("",x0,y0,0.5*(sB1->GetZ(0)+sB1->GetZ(1)));
865 vB1->AddNode(vTB0,i+1,trans);
866 rot = new TGeoRotation("",0.0,0.0,t);
867 rotrans = new TGeoCombiTrans("",x0,y0,0.0,rot);
868 vM0->AddNode(vTA0,i+1,rotrans);
869 //delete rot; // rot owned by AliITSv11GeometerySPD::CarbonFiberSector
871 vM0->AddNode(vA0,1,0);
872 vM0->AddNode(vB0,1,0);
874 vM0->AddNode(vB0,2,new TGeoRotation("",90.,0.,90.,90.,180.,0.));
888 //----------------------------------------------------------------------
889 void AliITSv11GeometrySPD::SPDsectorShape(Int_t n,const Double_t *xc,
890 const Double_t *yc,const Double_t *r,const Double_t *ths,const Double_t *the,
891 Int_t npr,Int_t &m,Double_t **xp,Double_t **yp){
892 // Code to compute the points that make up the shape of the SPD
893 // Carbon fiber support sections
895 // Int_t n Size of arrays xc,yc, and r.
896 // Double_t *xc Array of x values for radii centers.
897 // Double_t *yc Array of y values for radii centers.
898 // Double_t *r Array of signed radii values.
899 // Double_t *ths Array of starting angles [degrees].
900 // Double_t *the Array of ending angles [degrees].
901 // Int_t npr The number of lines segments to aproximate the arc.
903 // Int_t m The number of enetries in the arrays *xp[npr+1]
905 // Double_t **xp Array of x coordinate values of the line segments
906 // which make up the SPD support sector shape.
907 // Double_t **yp Array of y coordinate values of the line segments
908 // which make up the SPD support sector shape.
916 cout <<" X \t Y \t R \t S \t E"<< m <<endl;
918 cout <<"{"<< xc[i] <<",";
921 cout << ths[i] <<",";
922 cout << the[i] <<"},"<< endl;
926 if(GetDebug(3)) cout <<"Double_t sA0 = ["<< n*(npr+1)+1<<"][";
927 if(GetDebug(4)) cout <<"3]{";
928 else if(GetDebug(3)) cout <<"2]{";
931 t1 = (the[i]-ths[i])/t0;
932 if(GetDebug(5)) cout<<"t1="<< t1<<endl;
934 t=ths[i]+((Double_t)k)*t1;
935 xp[i][k] = TMath::Abs(r[i])*CosD(t)+xc[i];
936 yp[i][k] = TMath::Abs(r[i])*SinD(t)+yc[i];
938 cout << "{"<<xp[i][k]<<","<<yp[i][k];
939 if(GetDebug(4)) cout <<","<<t;
943 if(GetDebug(3)) cout << endl;
945 if(GetDebug(3)) cout<<"{"<<xp[0][0]<<","<<yp[0][0];
946 if(GetDebug(4)) cout<<","<< ths[0];
947 if(GetDebug(3)) cout<<"}}"<<endl;
951 //______________________________________________________________________
952 void AliITSv11GeometrySPD::HalfStave(TGeoVolume *moth,Double_t &thicknessAA,
954 // Define the detail SPD Half Stave geometry.
956 // TGeoVolume *moth The mother volume to place this object.
957 // Int_t &thicknessAA Thickness of stave at section A-A
958 // TGeoManager *mgr TGeoManager default gGeoManager
964 thicknessAA = 1.03*fgkmm; // Default value
966 Error("HalfStave","moth=%p mgr=%p",moth,mgr);
970 //----------------------------------------------------------------------
971 void AliITSv11GeometrySPD::CreateFigure0(const Char_t *filepath,
974 // Creates Figure 0 for the documentation of this class. In this
975 // specific case, it creates the X,Y cross section of the SPD suport
976 // section, center and ends. The output is written to a standard
977 // file name to the path specificed.
979 // const Char_t *filepath Path where the figure is to be drawn
980 // const Char_t *type The type of file, default is gif.
981 // TGeoManager *mgr The TGeoManager default gGeoManager
986 TGeoXtru *sA0,*sA1,*sB0,*sB1;
987 //TPolyMarker *pmA,*pmB;
988 TPolyLine plA0,plA1,plB0,plB1;
991 Double_t x=0.0,y=0.0;
994 if(strcmp(filepath,"")){
995 Error("CreateFigure0","filepath=%s type=%s",filepath,type);
998 sA0 = (TGeoXtru*) mgr->GetVolume(
999 "ITSSPDCarbonFiberSupportSectorA0_1")->GetShape();
1000 sA1 = (TGeoXtru*) mgr->GetVolume(
1001 "ITSSPDCarbonFiberSupportSectorAirA1_1")->GetShape();
1002 sB0 = (TGeoXtru*) mgr->GetVolume(
1003 "ITSSPDCarbonFiberSupportSectorEndB0_1")->GetShape();
1004 sB1 = (TGeoXtru*) mgr->GetVolume(
1005 "ITSSPDCarbonFiberSupportSectorEndAirB1_1")->GetShape();
1006 //pmA = new TPolyMarker();
1007 //pmA.SetMarkerStyle(2); // +
1008 //pmA.SetMarkerColor(7); // light blue
1009 //pmB = new TPolyMarker();
1010 //pmB.SetMarkerStyle(5); // X
1011 //pmB.SetMarkerColor(6); // purple
1012 plA0.SetPolyLine(sA0->GetNvert());
1013 plA0.SetLineColor(1); // black
1014 plA0.SetLineStyle(1);
1015 plA1.SetPolyLine(sA1->GetNvert());
1016 plA1.SetLineColor(2); // red
1017 plA1.SetLineStyle(1);
1018 plB0.SetPolyLine(sB0->GetNvert());
1019 plB0.SetLineColor(3); // Green
1020 plB0.SetLineStyle(2);
1021 plB1.SetPolyLine(sB1->GetNvert());
1022 plB1.SetLineColor(4); // Blue
1023 plB1.SetLineStyle(2);
1024 //for(i=0;i<kNRadii;i++) pmA.SetPoint(i,xyB1p[i][0],xyB1p[i][1]);
1025 //for(i=0;i<kNRadii;i++) pmB.SetPoint(i,xyB1p[i][0],xyB1p[i][1]);
1026 for(i=0;i<sA0->GetNvert();i++) plA0.SetPoint(i,sA0->GetX(i),sA0->GetY(i));
1027 for(i=0;i<sA1->GetNvert();i++) plA1.SetPoint(i,sA1->GetX(i),sA1->GetY(i));
1028 for(i=0;i<sB0->GetNvert();i++) plB0.SetPoint(i,sB0->GetX(i),sB0->GetY(i));
1029 for(i=0;i<sB1->GetNvert();i++) plB1.SetPoint(i,sB1->GetX(i),sB1->GetY(i));
1030 canvas = new TCanvas("AliITSv11GeometrySPDFig0","",1000,1000);
1031 canvas->Range(-3.,-3.,3.,3.);
1032 txt.SetTextSize(0.05);
1033 txt.SetTextAlign(33);
1034 txt.SetTextColor(1);
1035 txt.DrawLatex(2.9,2.9,"Section A-A outer Carbon Fiber surface");
1036 txt.SetTextColor(2);
1037 txt.DrawLatex(2.9,2.5,"Section A-A Inner Carbon Fiber surface");
1038 txt.SetTextColor(3);
1039 txt.DrawLatex(2.9,2.1,"Section E-E outer Carbon Fiber surface");
1040 txt.SetTextColor(4);
1041 txt.DrawLatex(2.9,1.7,"Section E-E Inner Carbon Fiber surface");
1052 for(i=0;i<kNRadii;i++){
1053 sprintf(chr,"%2d",i);txt.DrawLatex(x-0.1,y,chr);
1054 sprintf(chr,"%8.4f",5.000);txt.DrawLatex(x,y,chr);
1055 sprintf(chr,"%8.4f",5.000);txt.DrawLatex(x+0.5,y,chr);
1056 sprintf(chr,"%8.4f",5.000);txt.DrawLatex(x+1.0,y,chr);
1057 sprintf(chr,"%8.4f",5.000);txt.DrawLatex(x+1.5,y,chr);
1058 sprintf(chr,"%8.4f",5.000);txt.DrawLatex(x+2.0,y,chr);
1059 if(kTRUE) txt.DrawLatex(x+2.5,y,"A-A/E-E");
1060 else txt.DrawLatex(x+2.5,y,"E-E");
1062 txt.DrawLatex(x,y,"x_{c} mm");
1063 txt.DrawLatex(x+0.5,y,"y_{c} mm");
1064 txt.DrawLatex(x+1.0,y,"R mm");
1065 txt.DrawLatex(x+1.5,y,"#theta_{start}^{#circle}");
1066 txt.DrawLatex(x+2.0,y,"#theta_{end}^{#circle}");
1067 txt.DrawLatex(x+2.5,y,"Section");