BOSS 7.0.3
BESIII Offline Software System
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BesEmcConstruction Class Reference

#include <BesEmcConstruction.hh>

+ Inheritance diagram for BesEmcConstruction:

Public Member Functions

 BesEmcConstruction ()
 
 ~BesEmcConstruction ()
 
void SetVerboseLevel (G4int val)
 
void SetCrystalMaterial (G4String)
 
void SetCasingMaterial (G4String)
 
void SetCasingThickness (G4ThreeVector)
 
void SetBSCRmin (G4double)
 
void SetBSCNbPhi (G4int)
 
void SetBSCNbTheta (G4int)
 
void SetStartIDTheta (G4int)
 
void SetBSCCrystalLength (G4double)
 
void SetBSCYFront0 (G4double)
 
void SetBSCYFront (G4double)
 
void SetBSCPosition0 (G4double)
 
void SetBSCPosition1 (G4double)
 
void SetMagField (G4double)
 
void Construct (G4LogicalVolume *)
 
void UpdateGeometry ()
 
void ThreeVectorTrans (G4ThreeVector fPnt[8], double x[8], double y[8], double z[8])
 
void TransformToArb8 (const G4ThreeVector fPnt[8], G4ThreeVector newfPnt[8], G4ThreeVector &center, G4ThreeVector &rotAngle)
 
Hep3Vector RotAngleFromNewZ (Hep3Vector newZ)
 
void PrintEMCParameters ()
 
G4int GetVerboseLevel ()
 
G4double GetMagField ()
 
G4int GetStartIDTheta ()
 
G4Material * GetCrystalMaterial ()
 
G4Material * GetCasingMaterial ()
 
const G4VPhysicalVolume * GetEMC ()
 
const G4VPhysicalVolume * GetBSCPhi ()
 
const G4VPhysicalVolume * GetBSCTheta ()
 
const G4VPhysicalVolume * GetBSCCrystal ()
 
const G4VPVParameterisation * GetCrystalParam ()
 
void ConstructSPFrame (G4LogicalVolume *, BesEmcGeometry *)
 
void ConstructEndGeometry (G4LogicalVolume *)
 
void GetLogicalVolume ()
 
void SetVisAndSD ()
 
G4int ComputeEndCopyNb (G4int)
 
 BesEmcConstruction ()
 
 ~BesEmcConstruction ()
 
void SetVerboseLevel (G4int val)
 
void SetCrystalMaterial (G4String)
 
void SetCasingMaterial (G4String)
 
void SetCasingThickness (G4ThreeVector)
 
void SetBSCRmin (G4double)
 
void SetBSCNbPhi (G4int)
 
void SetBSCNbTheta (G4int)
 
void SetStartIDTheta (G4int)
 
void SetBSCCrystalLength (G4double)
 
void SetBSCYFront0 (G4double)
 
void SetBSCYFront (G4double)
 
void SetBSCPosition0 (G4double)
 
void SetBSCPosition1 (G4double)
 
void SetMagField (G4double)
 
void Construct (G4LogicalVolume *)
 
void UpdateGeometry ()
 
void ThreeVectorTrans (G4ThreeVector fPnt[8], double x[8], double y[8], double z[8])
 
void TransformToArb8 (const G4ThreeVector fPnt[8], G4ThreeVector newfPnt[8], G4ThreeVector &center, G4ThreeVector &rotAngle)
 
Hep3Vector RotAngleFromNewZ (Hep3Vector newZ)
 
void PrintEMCParameters ()
 
G4int GetVerboseLevel ()
 
G4double GetMagField ()
 
G4int GetStartIDTheta ()
 
G4Material * GetCrystalMaterial ()
 
G4Material * GetCasingMaterial ()
 
const G4VPhysicalVolume * GetEMC ()
 
const G4VPhysicalVolume * GetBSCPhi ()
 
const G4VPhysicalVolume * GetBSCTheta ()
 
const G4VPhysicalVolume * GetBSCCrystal ()
 
const G4VPVParameterisation * GetCrystalParam ()
 
void ConstructSPFrame (G4LogicalVolume *, BesEmcGeometry *)
 
void ConstructEndGeometry (G4LogicalVolume *)
 
void GetLogicalVolume ()
 
void SetVisAndSD ()
 
G4int ComputeEndCopyNb (G4int)
 
- Public Member Functions inherited from BesSubdetector
 BesSubdetector ()
 
virtual ~BesSubdetector ()
 
virtual void Construct (G4LogicalVolume *bes)=0
 
G4LogicalVolume * FindLogicalVolume (const G4String &vn)
 
 BesSubdetector ()
 
virtual ~BesSubdetector ()
 
virtual void Construct (G4LogicalVolume *bes)=0
 
G4LogicalVolume * FindLogicalVolume (const G4String &vn)
 

Static Public Member Functions

static BesEmcConstructionGetBesEmcConstruction ()
 
static BesEmcConstructionGetBesEmcConstruction ()
 

Additional Inherited Members

- Protected Attributes inherited from BesSubdetector
SAXProcessor m_sxp
 
ProcessingConfigurator m_config
 

Detailed Description

Constructor & Destructor Documentation

◆ BesEmcConstruction() [1/2]

BesEmcConstruction::BesEmcConstruction ( )

Definition at line 57 of file BesEmcConstruction.cc.

58 :verboseLevel(0),
59 solidEMC(0),logicEMC(0),physiEMC(0),logicBSCWorld(0),
60 solidBSCPhi(0),logicBSCPhi(0),physiBSCPhi(0),
61 solidBSCTheta(0),logicBSCTheta(0),physiBSCTheta(0),
62 solidBSCCrystal(0),logicBSCCrystal(0),physiBSCCrystal(0),
63 magField(0),detectorMessenger(0),besEMCSD(0),crystalParam(0),
64 logicEnd(0),logicEndPhi(0),logicEndCasing(0),logicEndCrystal(0),
65 logicRear(0),logicRearCasing(0),logicOrgGlass(0),logicPD(0),
66 logicAlPlate(0),logicPreAmpBox(0),logicAirInPABox(0),
67 logicHangingPlate(0),logicOCGirder(0),logicCable(0),logicWaterPipe(0),
68 logicSupportBar(0),logicSupportBar1(0),logicEndRing(0),logicGear(0),
69 logicTaperRing1(0),logicTaperRing2(0),logicTaperRing3(0)
70{
71 if(fBesEmcConstruction)
72 { G4Exception("BesEmcConstruction constructed twice."); }
73 fBesEmcConstruction=this;
74 //for debug
75 // G4Exception("BesEmcConstruction::BesEmcConstruction() starting........");
76 startID = 1;
77 phiNbCrystals = 0;
78 thetaNbCrystals = 0;
79 besEMCGeometry = new BesEmcGeometry();
80 emcEnd = new BesEmcEndGeometry();
81}

◆ ~BesEmcConstruction() [1/2]

BesEmcConstruction::~BesEmcConstruction ( )

Definition at line 83 of file BesEmcConstruction.cc.

84{
85 if(detectorMessenger) delete detectorMessenger;
86 if(crystalParam) delete crystalParam;
87 if(besEMCGeometry) delete besEMCGeometry;
88 if(emcEnd) delete emcEnd;
89
91}
static void Kill()

◆ BesEmcConstruction() [2/2]

BesEmcConstruction::BesEmcConstruction ( )

◆ ~BesEmcConstruction() [2/2]

BesEmcConstruction::~BesEmcConstruction ( )

Member Function Documentation

◆ ComputeEndCopyNb() [1/2]

G4int BesEmcConstruction::ComputeEndCopyNb ( G4int  num)

Definition at line 1230 of file BesEmcConstruction.cc.

1231{
1232 G4int copyNb;
1233 switch(num){
1234 case 30:
1235 copyNb = 5;
1236 break;
1237 case 31:
1238 copyNb = 6;
1239 break;
1240 case 32:
1241 copyNb = 14;
1242 break;
1243 case 33:
1244 copyNb = 15;
1245 break;
1246 case 34:
1247 copyNb = 16;
1248 break;
1249 default:
1250 copyNb = num;
1251 break;
1252 }
1253 return copyNb;
1254}

◆ ComputeEndCopyNb() [2/2]

G4int BesEmcConstruction::ComputeEndCopyNb ( G4int  )

◆ Construct() [1/2]

void BesEmcConstruction::Construct ( G4LogicalVolume *  logicBes)
virtual

Implements BesSubdetector.

Definition at line 93 of file BesEmcConstruction.cc.

94{
95 besEMCGeometry->ComputeEMCParameters();
96 detectorMessenger = new BesEmcDetectorMessenger(this,besEMCGeometry);
97 emcEnd->ComputeParameters();
98
99 G4SDManager* SDman = G4SDManager::GetSDMpointer();
100 if (!besEMCSD) {
101 besEMCSD = new BesEmcSD("CalorSD",this,besEMCGeometry);
102 SDman->AddNewDetector( besEMCSD );
103 }
104
105 // Construction
106 G4cout<<"--------ReadBoostRoot::GetEmc()="<<ReadBoostRoot::GetEmc()<<G4endl;
107 if(ReadBoostRoot::GetEmc()==2)
108 {
109 logicEMC = EmcG4Geo::Instance()->GetTopVolume();
110
111 if(logicEMC){
112 physiEMC = new G4PVPlacement(0,
113 G4ThreeVector(0.0 ,0.0 ,0.0),
114 logicEMC, "physicalEMC",logicBes, false, 0);
115 G4cout<<"logicEmc: === "<<logicEMC<<" physiEmc "<<physiEMC<<G4endl;
116
118 SetVisAndSD();
119 }
120 }
121 else {
122 //for debug
123 // G4Exception("BesEmcConstruction::Construct() starting............");
124 //
125 DefineMaterials();
126 phiNbCrystals = (*besEMCGeometry).BSCNbPhi;
127 thetaNbCrystals = (*besEMCGeometry).BSCNbTheta*2;
128
129 G4double da=0.001*deg; //delta angle to avoid overlap
130
131 //
132 //BSC
133 //
134 solidBSC = new G4Tubs("solidBSC",
135 (*besEMCGeometry).TaperRingRmin1,
136 (*besEMCGeometry).BSCRmax+(*besEMCGeometry).SPBarThickness+(*besEMCGeometry).SPBarThickness1+2.1*mm, //radius from 942mm to 940 mm
137 (*besEMCGeometry).BSCDz+(*besEMCGeometry).TaperRingThickness3+(*besEMCGeometry).EndRingDz,
138 0.*deg,
139 360.*deg);
140
141 solidESC = new G4Cons("solidESC",(*emcEnd).WorldRmin1,(*emcEnd).WorldRmax1,
142 (*emcEnd).WorldRmin2,(*emcEnd).WorldRmax2,
143 (*emcEnd).WorldDz/2,0.*deg,360.*deg);
144
145 solidEMC = new G4UnionSolid("solidEMC0",
146 solidBSC,
147 solidESC,
148 0,
149 G4ThreeVector(0,0,(*emcEnd).WorldZPosition));
150
151 G4RotationMatrix *rotateESC = new G4RotationMatrix();
152 rotateESC->rotateY(180.*deg);
153
154 solidEMC = new G4UnionSolid("solidEMC",
155 solidEMC,
156 solidESC,
157 rotateESC,
158 G4ThreeVector(0,0,-(*emcEnd).WorldZPosition));
159
160 logicEMC = new G4LogicalVolume(solidEMC,
161 G4Material::GetMaterial("Air"),
162 "logicalEMC");
163
164 physiEMC = new G4PVPlacement(0,
165 0,
166 logicEMC,
167 "physicalEMC",
168 logicBes,
169 false,
170 0);
171
172 solidBSCWorld = new G4SubtractionSolid("solidBSCWorld0",
173 solidBSC,
174 solidESC,
175 0,
176 G4ThreeVector(0,0,(*emcEnd).WorldZPosition));
177
178 solidBSCWorld = new G4SubtractionSolid("solidBSCWorld",
179 solidBSCWorld,
180 solidESC,
181 rotateESC,
182 G4ThreeVector(0,0,-(*emcEnd).WorldZPosition));
183
184 logicBSCWorld = new G4LogicalVolume(solidBSCWorld,
185 G4Material::GetMaterial("Air"),
186 "logicalBSCWorld");
187
188 G4RotationMatrix *rotBSC = new G4RotationMatrix();
189 rotBSC->rotateY(180.*deg);
190 physiBSCWorld = new G4PVPlacement(rotBSC,
191 0,
192 logicBSCWorld,
193 "physicalBSCWorld",
194 logicEMC,
195 false,
196 0);
197
198 G4RotationMatrix *rotateMatrix[200];
199 G4double oOp,ox,oy,oz;
200 G4double delta = 0*deg;
201 G4ThreeVector axis = G4ThreeVector(0,0,0);
202 oOp=(*besEMCGeometry).BSCRmin/sin(0.5*(*besEMCGeometry).BSCPhiDphi+90*deg)
203 *sin((*besEMCGeometry).BSCAngleRotat);
204 G4double ll=(*besEMCGeometry).BSCCryLength;
205 G4double rr=(*besEMCGeometry).BSCRmin;
206 G4double oj=sqrt(ll*ll+rr*rr-2*ll*rr*cos(180.*deg-(*besEMCGeometry).BSCAngleRotat));
207 G4double oij=90.*deg-(*besEMCGeometry).BSCPhiDphi/2.-(*besEMCGeometry).BSCAngleRotat;
208 G4double doj=asin(sin(180.*deg-(*besEMCGeometry).BSCAngleRotat)/oj*ll);
209 G4double ioj=(*besEMCGeometry).BSCPhiDphi/2.+doj;
210 G4double ij=oj/sin(oij)*sin(ioj);
211 G4double dOp=rr/sin(90.*deg-(*besEMCGeometry).BSCPhiDphi/2.)
212 *sin(90.*deg+(*besEMCGeometry).BSCPhiDphi/2.-(*besEMCGeometry).BSCAngleRotat);
213 G4double cOp=rr/sin(90.*deg+(*besEMCGeometry).BSCPhiDphi/2.)
214 *sin(90.*deg-(*besEMCGeometry).BSCPhiDphi/2.-(*besEMCGeometry).BSCAngleRotat);
215 G4double ch=(dOp+ll)/cos((*besEMCGeometry).BSCPhiDphi)-cOp;
216 G4double hi=(dOp+ll)*tan((*besEMCGeometry).BSCPhiDphi)-ij;
217 G4double oh=sqrt(ch*ch+rr*rr-2*ch*rr*cos(180*deg-(*besEMCGeometry).BSCAngleRotat));
218 G4double hoi=asin(sin(180*deg-oij)/oh*hi);
219 G4double dok=asin(sin(180*deg-(*besEMCGeometry).BSCAngleRotat)/oh*ch);
220 if(verboseLevel>3)
221 G4cout << "oj=" <<oj/cm<<G4endl
222 << "oij="<<oij/deg<<G4endl
223 << "doj="<<doj/deg<<G4endl
224 << "ioj="<<ioj/deg<<G4endl
225 << "ij="<<ij/cm<<G4endl
226 << "dOp="<<dOp/cm<<G4endl
227 << "cOp="<<cOp/cm<<G4endl
228 << "ch="<<ch/cm<<G4endl
229 << "hi="<<hi/cm<<G4endl
230 << "oh="<<oh/cm<<G4endl
231 << "hoi="<<hoi/deg<<G4endl
232 << "dok="<<dok/deg<<G4endl;
233
234 // Phi Cell
235 solidBSCPhiTub = new G4Tubs(
236 "solidBSCPhiTub",
237 dOp,
238 (*besEMCGeometry).BSCPhiRmax,
239 (*besEMCGeometry).BSCDz,
240 360.*deg-(*besEMCGeometry).BSCPhiDphi,
241 (*besEMCGeometry).BSCPhiDphi);
242 solidConsPhi = new G4Cons("consPhi1",
243 (*besEMCGeometry).BSCRmin1,
244 (*besEMCGeometry).BSCRmax1,
245 (*besEMCGeometry).BSCRmin2,
246 (*besEMCGeometry).BSCRmax2,
247 (*besEMCGeometry).BSCDz1/2,
248 0.*deg,
249 360.*deg);
250 solidBSCPhi1 = new G4SubtractionSolid("solidBSCPhi1",
251 solidBSCPhiTub,
252 solidConsPhi,
253 0,
254 G4ThreeVector(0,0,(*besEMCGeometry).BSCDz-(*besEMCGeometry).BSCDz1/2));
255 solidConsPhi = new G4Cons("consPhi2",
256 (*besEMCGeometry).BSCRmin2,
257 (*besEMCGeometry).BSCRmax2,
258 (*besEMCGeometry).BSCRmin1,
259 (*besEMCGeometry).BSCRmax1,
260 (*besEMCGeometry).BSCDz1/2,
261 0.*deg,
262 360.*deg);
263 solidBSCPhi = new G4SubtractionSolid("solidBSCPhi",
264 solidBSCPhi1,
265 solidConsPhi,
266 0,
267 G4ThreeVector(0,0,(*besEMCGeometry).BSCDz1/2-(*besEMCGeometry).BSCDz));
268
269 logicBSCPhi = new G4LogicalVolume(solidBSCPhi,
270 G4Material::GetMaterial("Air"),
271 "logicalBSCPhi");
272
273 G4int i;
274 for(G4int j=0;j<(*besEMCGeometry).BSCNbPhi;j++) //=============
275 {
276 if(j<(*besEMCGeometry).BSCNbPhi/2) { //0~59
277 i=(*besEMCGeometry).BSCNbPhi/2-j-1;
278 } else { //60~119
279 i=(*besEMCGeometry).BSCNbPhi*3/2-j-1;
280 }
281 rotateMatrix[i] = new G4RotationMatrix();
282 rotateMatrix[i]->rotateZ(-i*(*besEMCGeometry).BSCPhiDphi
283 -(*besEMCGeometry).BSCAngleRotat
284 -(*besEMCGeometry).BSCPhiDphi/2.
285 -hoi);
286 rotateMatrix[i]->getAngleAxis(delta, axis);
287 //G4cout << "The axis of crystals in the world system is: "
288 // << delta/deg << "(deg)(delta) "
289 //<< axis << "(Z axis)"<< G4endl;
290 ox=oOp*cos(-90.*deg+(*besEMCGeometry).BSCAngleRotat+hoi
291 +i*(*besEMCGeometry).BSCPhiDphi);
292 oy=oOp*sin(-90.*deg+(*besEMCGeometry).BSCAngleRotat+hoi
293 +i*(*besEMCGeometry).BSCPhiDphi);
294 oz=0*cm;
295
296 ostringstream strPhi;
297 strPhi << "physicalBSCPhi" << j;
298
299 physiBSCPhi = new G4PVPlacement(rotateMatrix[i],
300 G4ThreeVector(ox,oy,oz),
301 logicBSCPhi,
302 strPhi.str(),
303 logicBSCWorld,
304 false,
305 j);
306 //G4cout << G4ThreeVector(ox/cm,oy/cm,oz/cm) <<"(cm)" << G4endl
307 // << (-(*besEMCGeometry).BSCAngleRotat+(i-1)*(*besEMCGeometry).BSCPhiDphi)/deg <<"(degree)" << G4endl;
308 }
309
310 //
311 //Crystals
312 //
313 G4double zHalfLength[50];
314 G4double thetaAxis[50];
315 G4double phiAxis[50];
316 G4double yHalfLength1[50];
317 G4double xHalfLength2[50];
318 G4double xHalfLength1[50];
319 G4double tanAlpha1[50];
320 G4double yHalfLength2[50];
321 G4double xHalfLength4[50];
322 G4double xHalfLength3[50];
323 G4double tanAlpha2[50];
324 G4double xPosition[50];
325 G4double yPosition[50];
326 G4double zPosition[50];
327 G4double thetaPosition[50];
328 for(i=0;i<(*besEMCGeometry).BSCNbTheta;i++)
329 {
330 zHalfLength[i] = (*besEMCGeometry).zHalfLength[i];
331 thetaAxis[i] = (*besEMCGeometry).thetaAxis[i];
332 phiAxis[i] = (*besEMCGeometry).phiAxis[i];
333 yHalfLength1[i] = (*besEMCGeometry).yHalfLength1[i];
334 xHalfLength2[i] = (*besEMCGeometry).xHalfLength2[i];
335 xHalfLength1[i] = (*besEMCGeometry).xHalfLength1[i];
336 tanAlpha1[i] = (*besEMCGeometry).tanAlpha1[i];
337 yHalfLength2[i] = (*besEMCGeometry).yHalfLength2[i];
338 xHalfLength4[i] = (*besEMCGeometry).xHalfLength4[i];
339 xHalfLength3[i] = (*besEMCGeometry).xHalfLength3[i];
340 tanAlpha2[i] = (*besEMCGeometry).tanAlpha2[i];
341 xPosition[i] = (*besEMCGeometry).xPosition[i];
342 yPosition[i] = (*besEMCGeometry).yPosition[i];
343 zPosition[i] = (*besEMCGeometry).zPosition[i];
344 thetaPosition[i]= (*besEMCGeometry).thetaPosition[i];
345 if(verboseLevel>4)
346 G4cout << "The sizes of the "<<i+1<<" crystal are:" << G4endl
347 <<"zHalfLength ="<<zHalfLength[i]/cm<< "(cm)," << G4endl
348 << "thetaAxis ="<<thetaAxis[i]/deg << "(deg),"<< G4endl
349 << "phiAxis ="<< phiAxis[i]/deg << "(deg),"<< G4endl
350 << "yHalfLength1="<<yHalfLength1[i]/cm<<"(cm),"<< G4endl
351 << "xHalfLength1="<<xHalfLength1[i]/cm<<"(cm),"<< G4endl
352 << "xHalfLength2="<<xHalfLength2[i]/cm<<"(cm),"<< G4endl
353 << "tanAlpha1 ="<< tanAlpha1[i] << G4endl
354 << "yHalfLength2="<<yHalfLength2[i]/cm<<"(cm),"<< G4endl
355 << "xHalfLength3="<<xHalfLength3[i]/cm<<"(cm),"<< G4endl
356 << "xHalfLength4="<<xHalfLength4[i]/cm<<"(cm),"<< G4endl
357 << "tanAlpha2 =" << tanAlpha2[i] << "." << G4endl;
358 }
359 besEMCGeometry->ModifyForCasing();
360
361 solidBSCCrystal = new G4Trap("solidCrystal",
362 100*cm, 100*deg, 100*deg,
363 100*cm, 100*cm, 100*cm, 100*deg,
364 100*cm, 100*cm, 100*cm, 100*deg);
365
366 logicBSCCrystal = new G4LogicalVolume(solidBSCCrystal,
367 fCrystalMaterial,
368 "logicalCrystal");
369
370 crystalParam = new BesCrystalParameterisation
371 (startID,
372 thetaNbCrystals,
373 (*besEMCGeometry).BSCNbTheta*2,
374 besEMCGeometry,
375 verboseLevel);
376
377 //---------------------------------------------------------------------------------
378 //rear substance
379 solidRear = new G4Box("solidRearBox",
380 (*besEMCGeometry).rearBoxLength/2,
381 (*besEMCGeometry).rearBoxLength/2,
382 (*besEMCGeometry).rearBoxDz/2);
383
384 logicRear = new G4LogicalVolume(solidRear,
385 G4Material::GetMaterial("Air"),
386 "logicalRearBox");
387
388 //organic glass
389 solidOrgGlass = new G4Box("solidOrganicGlass",
390 (*besEMCGeometry).orgGlassLengthX/2,
391 (*besEMCGeometry).orgGlassLengthY/2,
392 (*besEMCGeometry).orgGlassLengthZ/2);
393
394 logicOrgGlass = new G4LogicalVolume(solidOrgGlass,
395 organicGlass,
396 "logicalOrganicGlass");
397
398 physiOrgGlass = new G4PVPlacement(0,
399 G4ThreeVector(0,0,-((*besEMCGeometry).rearBoxDz-(*besEMCGeometry).orgGlassLengthZ)/2),
400 logicOrgGlass,
401 "physicalOrganicGlass",
402 logicRear,
403 false,
404 0);
405
406 //casing
407 solidCasingBox = new G4Box("solidCasingBox",
408 (*besEMCGeometry).rearBoxLength/2,
409 (*besEMCGeometry).rearBoxLength/2,
410 (*besEMCGeometry).rearCasingThickness/2);
411
412 solidAirHole = new G4Box("solidAirHole",
413 (*besEMCGeometry).orgGlassLengthX/2,
414 (*besEMCGeometry).orgGlassLengthY/2,
415 (*besEMCGeometry).rearBoxDz/2); //any value more than casing thickness
416
417 solidRearCasing = new G4SubtractionSolid("solidRearCasing",
418 solidCasingBox,
419 solidAirHole,
420 0,
421 0);
422
423 logicRearCasing = new G4LogicalVolume(solidRearCasing,
424 rearCasingMaterial,
425 "logicalRearCasing");
426
427 physiRearCasing = new G4PVPlacement(0,
428 G4ThreeVector(0,0,-((*besEMCGeometry).rearBoxDz-(*besEMCGeometry).rearCasingThickness)/2),
429 logicRearCasing,
430 "physicalRearCasing",
431 logicRear,
432 false,
433 0);
434
435 //Al Plate
436 solidAlBox = new G4Box("solidAlBox",
437 (*besEMCGeometry).rearBoxLength/2,
438 (*besEMCGeometry).rearBoxLength/2,
439 (*besEMCGeometry).AlPlateDz/2);
440
441 solidAlPlate = new G4SubtractionSolid("solidAlPlate",
442 solidAlBox,
443 solidAirHole,
444 0,
445 0);
446
447 logicAlPlate = new G4LogicalVolume(solidAlPlate,
448 G4Material::GetMaterial("Aluminium"),
449 "logicalAlPlate");
450
451 physiAlPlate = new G4PVPlacement(0,
452 G4ThreeVector(0,0,-((*besEMCGeometry).rearBoxDz/2
453 -(*besEMCGeometry).rearCasingThickness
454 -(*besEMCGeometry).AlPlateDz/2)),
455 logicAlPlate,
456 "physicalAlPlate",
457 logicRear,
458 false,
459 0);
460
461 //photodiode
462 solidPD = new G4Box("solidPD",
463 (*besEMCGeometry).PDLengthX, //two PD
464 (*besEMCGeometry).PDLengthY/2,
465 (*besEMCGeometry).PDLengthZ/2);
466
467 logicPD = new G4LogicalVolume(solidPD,
468 G4Material::GetMaterial("M_Silicon"),
469 "logicalPD");
470
471 physiPD = new G4PVPlacement(0,
472 G4ThreeVector(0,0,-((*besEMCGeometry).rearBoxDz/2
473 -(*besEMCGeometry).orgGlassLengthZ
474 -(*besEMCGeometry).PDLengthZ/2)),
475 logicPD,
476 "physicalPD",
477 logicRear,
478 false,
479 0);
480
481 //preamplifier box
482 solidPreAmpBox = new G4Box("solidPreAmpBox",
483 (*besEMCGeometry).rearBoxLength/2,
484 (*besEMCGeometry).rearBoxLength/2,
485 (*besEMCGeometry).PABoxDz/2);
486
487 logicPreAmpBox = new G4LogicalVolume(solidPreAmpBox,
488 G4Material::GetMaterial("Aluminium"),
489 "logicalPreAmpBox");
490
491 physiPreAmpBox = new G4PVPlacement(0,
492 G4ThreeVector(0,0,-((*besEMCGeometry).rearBoxDz/2
493 -(*besEMCGeometry).rearCasingThickness
494 -(*besEMCGeometry).AlPlateDz
495 -(*besEMCGeometry).PABoxDz/2)),
496 logicPreAmpBox,
497 "physicalPreAmpBox",
498 logicRear,
499 false,
500 0);
501
502 //air in preamplifier box
503 solidAirInPABox = new G4Box("solidAirInPABox",
504 (*besEMCGeometry).rearBoxLength/2-(*besEMCGeometry).PABoxThickness,
505 (*besEMCGeometry).rearBoxLength/2-(*besEMCGeometry).PABoxThickness,
506 (*besEMCGeometry).PABoxDz/2-(*besEMCGeometry).PABoxThickness);
507
508 logicAirInPABox = new G4LogicalVolume(solidAirInPABox,
509 G4Material::GetMaterial("Air"),
510 "logicalAirInPABox");
511
512 physiAirInPABox = new G4PVPlacement(0,
513 0,
514 logicAirInPABox,
515 "physicalAirInPABox",
516 logicPreAmpBox,
517 false,
518 0);
519
520 //stainless steel for hanging the crystal
521 solidHangingPlate = new G4Box("solidHangingPlate",
522 (*besEMCGeometry).rearBoxLength/2,
523 (*besEMCGeometry).rearBoxLength/2,
524 (*besEMCGeometry).HangingPlateDz/2);
525
526 logicHangingPlate = new G4LogicalVolume(solidHangingPlate,stainlessSteel,"logicalHangingPlate");
527
528 physiHangingPlate = new G4PVPlacement(0,
529 G4ThreeVector(0,0,-((*besEMCGeometry).rearBoxDz/2
530 -(*besEMCGeometry).rearCasingThickness
531 -(*besEMCGeometry).AlPlateDz
532 -(*besEMCGeometry).PABoxDz
533 -(*besEMCGeometry).HangingPlateDz/2)),
534 logicHangingPlate,
535 "physicalHangingPlate",
536 logicRear,
537 false,
538 0);
539
540 //water pipe
541 solidWaterPipe = new G4Tubs("solidWaterPipe",
542 0,
543 (*besEMCGeometry).waterPipeDr,
544 (*besEMCGeometry).BSCDz,
545 0.*deg,
546 360.*deg);
547
548 logicWaterPipe = new G4LogicalVolume(solidWaterPipe,waterPipe,"logicalWaterPipe");
549
550 physiWaterPipe = new G4PVPlacement(0,
551 G4ThreeVector((*besEMCGeometry).cablePosX[0]-2*(*besEMCGeometry).cableDr,
552 (*besEMCGeometry).cablePosY[0]-(*besEMCGeometry).cableDr-(*besEMCGeometry).waterPipeDr,
553 0),
554 logicWaterPipe,
555 "physicalWaterPipe",
556 logicBSCPhi,
557 false,
558 0);
559 //---------------------------------------------------------------------------------
560
561
562 //
563 //Theta Cell
564 //
565 G4String nameCrystalAndCasing="CrystalAndCasing";
566
567 G4int id=0; //ID of crystals after distinguishing left and right
568 for(i=startID;i<=thetaNbCrystals;i++) //================
569 {
570 ostringstream strSolidCasing;
571 strSolidCasing << "solidBSCCasing" << i-1;
572 ostringstream strVolumeCasing;
573 strVolumeCasing << "logicalBSCCasing" << i-1;
574 ostringstream strPhysiCasing;
575 strPhysiCasing << "physicalBSCCasing" << i-1;
576
577 if(i>(*besEMCGeometry).BSCNbTheta)
578 {
579 id=i-(*besEMCGeometry).BSCNbTheta-1;
580 solidBSCTheta = new G4Trap(strSolidCasing.str(),
581 zHalfLength[id],
582 thetaAxis[id],
583 -phiAxis[id],
584 yHalfLength1[id],
585 xHalfLength2[id],
586 xHalfLength1[id],
587 -tanAlpha1[id],
588 yHalfLength2[id],
589 xHalfLength4[id],
590 xHalfLength3[id],
591 -tanAlpha2[id]);
592
593 //G4cout<<"in EmcConstr1: "<<strSolidCasing.str()<<" x1="<<xHalfLength1[id]<<" y1="<<yHalfLength1[id]<<" theta="<<thetaAxis[id]
594 //<<" phi="<<-phiAxis[id]<<" a1="<<-tanAlpha1[id]<<G4endl;
595
596 logicBSCTheta = new G4LogicalVolume(solidBSCTheta,
597 fCasingMaterial,
598 strVolumeCasing.str());
599
600 rotateMatrix[(*besEMCGeometry).BSCNbPhi+i-1] = new G4RotationMatrix();
601 rotateMatrix[(*besEMCGeometry).BSCNbPhi+i-1]->rotateZ(-90*deg);
602 rotateMatrix[(*besEMCGeometry).BSCNbPhi+i-1]
603 ->rotateX(-thetaPosition[id]);
604
605
606 physiBSCTheta =
607 new G4PVPlacement(rotateMatrix[(*besEMCGeometry).BSCNbPhi+i-1],
608 G4ThreeVector(xPosition[id],
609 yPosition[id],
610 zPosition[id]),
611 strPhysiCasing.str(),
612 logicBSCTheta,
613 physiBSCPhi,
614 false,
615 i-1);
616
617 if(logicBSCTheta)
618 {
619 G4VisAttributes* rightVisAtt= new G4VisAttributes(G4Colour(1.0,0.,0.));
620 rightVisAtt->SetVisibility(true);
621 logicBSCTheta->SetVisAttributes(rightVisAtt);
622 logicBSCTheta->SetVisAttributes(G4VisAttributes::Invisible);
623 }
624
625 ostringstream strRear;
626 strRear << "physicalRearBox_1_" << i-1;
627
628 physiRear = new G4PVPlacement(rotateMatrix[(*besEMCGeometry).BSCNbPhi+i-1],
629 G4ThreeVector((*besEMCGeometry).rearBoxPosX[id],
630 (*besEMCGeometry).rearBoxPosY[id],
631 (*besEMCGeometry).rearBoxPosZ[id]),
632 strRear.str(),
633 logicRear,
634 physiBSCPhi,
635 false,
636 i-1);
637
638 ostringstream strGirder;
639 strGirder << "solidOpenningCutGirder_1_" << i-1;
640 solidOCGirder = new G4Cons(strGirder.str(),
641 (*besEMCGeometry).OCGirderRmin1[id],
642 (*besEMCGeometry).BSCPhiRmax,
643 (*besEMCGeometry).OCGirderRmin2[id],
644 (*besEMCGeometry).BSCPhiRmax,
645 (*besEMCGeometry).OCGirderDz[id]/2,
646 360.*deg-(*besEMCGeometry).OCGirderAngle/2,
647 (*besEMCGeometry).OCGirderAngle/2-da);
648
649 ostringstream strVGirder;
650 strVGirder << "logicalOpenningCutGirder_1_" << i-1;
651 logicOCGirder = new G4LogicalVolume(solidOCGirder,stainlessSteel,strVGirder.str());
652 logicOCGirder->SetVisAttributes(G4VisAttributes::Invisible);
653
654 ostringstream strPGirder;
655 strPGirder << "physicalOpenningCutGirder_1_" << i-1;
656 physiOCGirder = new G4PVPlacement(0,
657 G4ThreeVector(0,0,(*besEMCGeometry).OCGirderPosZ[id]),
658 logicOCGirder,
659 strPGirder.str(),
660 logicBSCPhi,
661 false,
662 0);
663
664 if(id<(*besEMCGeometry).BSCNbTheta-1)
665 {
666 G4double zLength = (*besEMCGeometry).OCGirderPosZ[id+1]
667 -(*besEMCGeometry).OCGirderPosZ[id]
668 -(*besEMCGeometry).OCGirderDz[id+1]/2-(*besEMCGeometry).OCGirderDz[id]/2;
669 G4double zPosition = (*besEMCGeometry).OCGirderPosZ[id+1]
670 -(*besEMCGeometry).OCGirderDz[id+1]/2-zLength/2;
671
672 ostringstream strGirder2;
673 strGirder2 << "solidOpenningCutGirder_2_" << i-1;
674 solidOCGirder = new G4Cons(strGirder2.str(),
675 (*besEMCGeometry).OCGirderRmin2[id],
676 (*besEMCGeometry).BSCPhiRmax,
677 (*besEMCGeometry).OCGirderRmin1[id+1],
678 (*besEMCGeometry).BSCPhiRmax,
679 zLength/2,
680 360.*deg-(*besEMCGeometry).OCGirderAngle/2,
681 (*besEMCGeometry).OCGirderAngle/2-da);
682
683 ostringstream strVGirder2;
684 strVGirder2 << "logicalOpenningCutGirder_2_" << i-1;
685 logicOCGirder = new G4LogicalVolume(solidOCGirder,stainlessSteel,strVGirder2.str());
686 logicOCGirder->SetVisAttributes(G4VisAttributes::Invisible);
687
688 ostringstream strPGirder2;
689 strPGirder2 << "physicalOpenningCutGirder_2_" << i-1;
690 physiOCGirder = new G4PVPlacement(0,
691 G4ThreeVector(0,0,zPosition),
692 logicOCGirder,
693 strPGirder2.str(),
694 logicBSCPhi,
695 false,
696 0);
697 }
698
699 ostringstream strBSCCable;
700 strBSCCable << "solidBSCCable_1_" << i-1;
701 solidCable = new G4Tubs(strBSCCable.str(),
702 0,
703 (*besEMCGeometry).cableDr,
704 (*besEMCGeometry).cableLength[id]/2,
705 0.*deg,
706 360.*deg);
707
708 ostringstream strVBSCCable;
709 strVBSCCable << "logicalBSCCable_1_" << i-1;
710 logicCable = new G4LogicalVolume(solidCable,cable,strVBSCCable.str());
711
712 ostringstream strPBSCCable;
713 strPBSCCable << "physicalBSCCable_1_" << i-1;
714 physiCable = new G4PVPlacement(0,
715 G4ThreeVector((*besEMCGeometry).cablePosX[id],
716 (*besEMCGeometry).cablePosY[id],
717 (*besEMCGeometry).cablePosZ[id]),
718 logicCable,
719 strPBSCCable.str(),
720 logicBSCPhi,
721 false,
722 0);
723 logicCable->SetVisAttributes(G4VisAttributes::Invisible);
724 }
725 else
726 {
727 id=(*besEMCGeometry).BSCNbTheta-i;
728 solidBSCTheta = new G4Trap(strSolidCasing.str(),
729 zHalfLength[id],
730 thetaAxis[id],
731 phiAxis[id],
732 yHalfLength1[id],
733 xHalfLength1[id],
734 xHalfLength2[id],
735 tanAlpha1[id],
736 yHalfLength2[id],
737 xHalfLength3[id],
738 xHalfLength4[id],
739 tanAlpha2[id]);
740
741 // G4cout<<"in EmcConstr2: "<<strSolidCasing.str()<<" x1="<<xHalfLength1[id]<<" y1="<<yHalfLength1[id]<<" theta="<<thetaAxis[id]
742 // <<" phi="<<phiAxis[id]<<" a1="<<tanAlpha1[id]<<G4endl;
743
744 logicBSCTheta = new G4LogicalVolume(solidBSCTheta,
745 fCasingMaterial,
746 strVolumeCasing.str());
747
748 rotateMatrix[(*besEMCGeometry).BSCNbPhi+i-1] = new G4RotationMatrix();
749 rotateMatrix[(*besEMCGeometry).BSCNbPhi+i-1]->rotateZ(-90*deg);
750 rotateMatrix[(*besEMCGeometry).BSCNbPhi+i-1]
751 ->rotateX(-180*deg+thetaPosition[id]);
752 physiBSCTheta =
753 new G4PVPlacement(rotateMatrix[(*besEMCGeometry).BSCNbPhi+i-1],
754 G4ThreeVector(xPosition[id],
755 yPosition[id],
756 -zPosition[id]),
757 strPhysiCasing.str(),
758 logicBSCTheta,
759 physiBSCPhi,
760 false,
761 i-1);
762 if(logicBSCTheta)
763 {
764 G4VisAttributes* rightVisAtt= new G4VisAttributes(G4Colour(1.0,0.,0.));
765 rightVisAtt->SetVisibility(true);
766 logicBSCTheta->SetVisAttributes(rightVisAtt);
767 logicBSCTheta->SetVisAttributes(G4VisAttributes::Invisible);
768 }
769
770 ostringstream strRear;
771 strRear << "physicalRearBox_2_" << i-1;
772
773 physiRear = new G4PVPlacement(rotateMatrix[(*besEMCGeometry).BSCNbPhi+i-1],
774 G4ThreeVector((*besEMCGeometry).rearBoxPosX[id],
775 (*besEMCGeometry).rearBoxPosY[id],
776 -(*besEMCGeometry).rearBoxPosZ[id]),
777 strRear.str(),
778 logicRear,
779 physiBSCPhi,
780 false,
781 i-1);
782
783 ostringstream strGirder;
784 strGirder << "solidOpenningCutGirder_3_" << i-1;
785 solidOCGirder = new G4Cons(strGirder.str(),
786 (*besEMCGeometry).OCGirderRmin2[id],
787 (*besEMCGeometry).BSCPhiRmax,
788 (*besEMCGeometry).OCGirderRmin1[id],
789 (*besEMCGeometry).BSCPhiRmax,
790 (*besEMCGeometry).OCGirderDz[id]/2,
791 360.*deg-(*besEMCGeometry).OCGirderAngle/2,
792 (*besEMCGeometry).OCGirderAngle/2-da);
793
794 ostringstream strVGirder;
795 strVGirder << "logicalOpenningCutGirder_3_" << i-1;
796 logicOCGirder = new G4LogicalVolume(solidOCGirder,stainlessSteel,strVGirder.str());
797 logicOCGirder->SetVisAttributes(G4VisAttributes::Invisible);
798
799 ostringstream strPGirder;
800 strPGirder << "physicalOpenningCutGirder_3_" << i-1;
801 physiOCGirder = new G4PVPlacement(0,
802 G4ThreeVector(0,0,-(*besEMCGeometry).OCGirderPosZ[id]),
803 logicOCGirder,
804 strPGirder.str(),
805 logicBSCPhi,
806 false,
807 0);
808
809 if(id<(*besEMCGeometry).BSCNbTheta-1)
810 {
811 G4double zLength = (*besEMCGeometry).OCGirderPosZ[id+1]-(*besEMCGeometry).OCGirderPosZ[id]
812 -(*besEMCGeometry).OCGirderDz[id+1]/2-(*besEMCGeometry).OCGirderDz[id]/2;
813 G4double zPosition = (*besEMCGeometry).OCGirderPosZ[id+1]-(*besEMCGeometry).OCGirderDz[id+1]/2-zLength/2;
814
815 ostringstream strGirder2;
816 strGirder2 << "solidOpenningCutGirder_4_" << i-1;
817 solidOCGirder = new G4Cons(strGirder2.str(),
818 (*besEMCGeometry).OCGirderRmin1[id+1],
819 (*besEMCGeometry).BSCPhiRmax,
820 (*besEMCGeometry).OCGirderRmin2[id],
821 (*besEMCGeometry).BSCPhiRmax,
822 zLength/2,
823 360.*deg-(*besEMCGeometry).OCGirderAngle/2,
824 (*besEMCGeometry).OCGirderAngle/2-da);
825
826 ostringstream strVGirder2;
827 strVGirder2 << "logicalOpenningCutGirder_4_" << i-1;
828 logicOCGirder
829 = new G4LogicalVolume(solidOCGirder,stainlessSteel,strVGirder2.str());
830 logicOCGirder->SetVisAttributes(G4VisAttributes::Invisible);
831
832 ostringstream strPGirder2;
833 strPGirder2 << "physicalOpenningCutGirder_4_" << i-1;
834 physiOCGirder = new G4PVPlacement(0,
835 G4ThreeVector(0,0,-zPosition),
836 logicOCGirder,
837 strPGirder2.str(),
838 logicBSCPhi,
839 false,
840 0);
841 }
842
843 ostringstream strBSCCable;
844 strBSCCable << "solidBSCCable_2_" << i-1;
845 solidCable = new G4Tubs(strBSCCable.str(),
846 0,
847 (*besEMCGeometry).cableDr,
848 (*besEMCGeometry).cableLength[id]/2,
849 0.*deg,
850 360.*deg);
851
852 ostringstream strVBSCCable;
853 strVBSCCable << "logicalBSCCable_2_" << i-1;
854 logicCable = new G4LogicalVolume(solidCable,cable,strVBSCCable.str());
855
856 ostringstream strPBSCCable;
857 strPBSCCable << "physicalBSCCable_2_" << i-1;
858 physiCable = new G4PVPlacement(0,
859 G4ThreeVector((*besEMCGeometry).cablePosX[id],
860 (*besEMCGeometry).cablePosY[id],
861 -(*besEMCGeometry).cablePosZ[id]),
862 logicCable,
863 strPBSCCable.str(),
864 logicBSCPhi,
865 false,
866 0);
867 logicCable->SetVisAttributes(G4VisAttributes::Invisible);
868
869 }
870
871 ostringstream strCrystal;
872 strCrystal << "physicalCrystal" << i-1;
873 physiBSCCrystal = new G4PVParameterised(
874 strCrystal.str(),
875 logicBSCCrystal,
876 physiBSCTheta,
877 kZAxis,
878 1,//for this method,it must be 1.
879 crystalParam);
880 (*besEMCGeometry).physiBSCCrystal[i]=physiBSCCrystal;
881 //G4cout << (*besEMCGeometry).physiBSCCrystal[i] << G4endl;
882 physiBSCCrystal->SetCopyNo(i);
883
884
885 if(verboseLevel>4)
886 G4cout << "BesEmcConstruction*****************************"<< G4endl
887 << "point of crystal =" <<physiBSCCrystal << G4endl
888 // << "point of mother =" <<physiBSCCrystal->GetMotherPhysical() << G4endl
889 << "point of excepted=" <<physiBSCTheta << G4endl;
890 //G4Exception("BesEMCConstruction::Construct() starting............");
891 }
892
893 //
894 //always return the physical World
895 //
896 if(verboseLevel>0)PrintEMCParameters();
897 // return physiBSC;
898
899 ConstructSPFrame(logicBSCWorld,besEMCGeometry);
900 ConstructEndGeometry(logicEMC);
901 }
902
903 //Set vis attributes and sensitive detector
904 SetVisAndSD();
905
906 //list geo tree
907 if(logicEMC&&physiEMC&&verboseLevel>4){
908 G4cout<<"logicEmc "<<logicEMC<<" physiEmc "<<physiEMC<<G4endl;
909 G4cout<<"list geo tree"<<G4endl;
910
911 int NdaughterofEMC = logicEMC->GetNoDaughters();
912
913 for(int i = 0; i < NdaughterofEMC; i++)
914 {
915 G4LogicalVolume *daughterofEmc = logicEMC->GetDaughter(i)->GetLogicalVolume();
916 G4cout<<i<<"/"<<NdaughterofEMC<<" name: "<<daughterofEmc->GetName()<<" "<<daughterofEmc<<" shape: "<<daughterofEmc->GetSolid()->GetName()<<G4endl;
917 int NdaughterofEmc_2 = daughterofEmc->GetNoDaughters();
918 for(int j = 0; j < NdaughterofEmc_2; j++)
919 {
920 G4LogicalVolume *daughterofEmc_2 = daughterofEmc->GetDaughter(j)->GetLogicalVolume();
921 G4cout<<" --> "<<j<<"/"<<NdaughterofEmc_2<<" name: "<<daughterofEmc_2->GetName()<<" "<<daughterofEmc_2<<" shape: "<<daughterofEmc_2->GetSolid()->GetName()<<G4endl;
922 int NdaughterofEmc_3 = daughterofEmc_2->GetNoDaughters();
923 for(int k = 0; k < NdaughterofEmc_3; k++)
924 {
925 G4LogicalVolume *daughterofEmc_3 = daughterofEmc_2->GetDaughter(k)->GetLogicalVolume();
926 G4cout<<" --> "<<k<<"/"<<NdaughterofEmc_3<<" name: "<<daughterofEmc_3->GetName()<<" "<<daughterofEmc_3<<" shape: "<<daughterofEmc_3->GetSolid()->GetName()<<G4endl;
927 int NdaughterofEmc_4 = daughterofEmc_3->GetNoDaughters();
928 for(int m = 0; m < NdaughterofEmc_4; m++)
929 {
930 G4LogicalVolume *daughterofEmc_4 = daughterofEmc_3->GetDaughter(m)->GetLogicalVolume();
931 G4cout<<" --> "<<m<<"/"<<NdaughterofEmc_4<<" name: "<<daughterofEmc_4->GetName()<<" "<<daughterofEmc_4<<" shape: "<<daughterofEmc_4->GetSolid()->GetName()<<G4endl;
932 if(daughterofEmc_3->GetSolid()->GetName().contains("solidBSCCasing"))
933 {
934 G4Trap *Crystal = (G4Trap *)daughterofEmc_3->GetSolid();
935 double hz = Crystal->GetZHalfLength();
936 double hx1 = Crystal->GetXHalfLength1();
937 double hx2 = Crystal->GetXHalfLength2();
938 double hx3 = Crystal->GetXHalfLength3();
939 double hx4 = Crystal->GetXHalfLength4();
940 double hy1 = Crystal->GetYHalfLength1();
941 double hy2 = Crystal->GetYHalfLength2();
942 double tanalpha1 = Crystal->GetTanAlpha1();
943 double tanalpha2 = Crystal->GetTanAlpha2();
944 G4cout<<" --> "<<hx1<<" "<<hx2<<" "<<hx3<<" "<<hx4<<" "<<hy1<<" "<<hy2<<" "<<hz<<" "<<tanalpha1<<" "<<tanalpha2<<G4endl;
945
946 }//if(SolidCrystal)
947 }//4
948 }//3
949 }//2
950 }//1
951 }
952
953
954}
double tan(const BesAngle a)
double sin(const BesAngle a)
double cos(const BesAngle a)
void ConstructSPFrame(G4LogicalVolume *, BesEmcGeometry *)
void ConstructEndGeometry(G4LogicalVolume *)
void ComputeEMCParameters()
static EmcG4Geo * Instance()
Get a pointer to the single instance of EmcG4Geo.
Definition: EmcG4Geo.cxx:52
G4LogicalVolume * GetTopVolume()
Get the top(world) volume;.

Referenced by BesDetectorConstruction::Construct().

◆ Construct() [2/2]

void BesEmcConstruction::Construct ( G4LogicalVolume *  )
virtual

Implements BesSubdetector.

◆ ConstructEndGeometry() [1/2]

void BesEmcConstruction::ConstructEndGeometry ( G4LogicalVolume *  logicEMC)

Definition at line 956 of file BesEmcConstruction.cc.

957{
958 G4Material* fCrystalMaterial = G4Material::GetMaterial("Cesiumiodide");
959 G4VisAttributes* crystalVisAtt= new G4VisAttributes(G4Colour(0.5,0,1.0));
960 crystalVisAtt->SetVisibility(false);
961 G4VisAttributes* endPhiVisAtt= new G4VisAttributes(G4Colour(0,1.0,0));
962 endPhiVisAtt->SetVisibility(false);
963 const G4double zoomConst = 0.995;
964 const G4double da=0.001*deg;
965
966 //world volume of endcap
967 //east end
968 solidEnd = new G4Cons("solidEndWorld",(*emcEnd).WorldRmin1,(*emcEnd).WorldRmax1,
969 (*emcEnd).WorldRmin2,(*emcEnd).WorldRmax2,
970 (*emcEnd).WorldDz/2,0.*deg,360.*deg);
971 logicEnd = new G4LogicalVolume(solidEnd, G4Material::GetMaterial("Aluminium"), "logicalEndWorld", 0, 0, 0);
972 physiEnd = new G4PVPlacement(0, // no rotation
973 G4ThreeVector(0,0,(*emcEnd).WorldZPosition),
974 logicEnd, // its logical volume
975 "physicalEndWorld0", // its name
976 logicEMC, // its mother volume
977 false, // no boolean operations
978 0); // no field specific to volume
979 if(logicEnd)
980 logicEnd->SetVisAttributes(G4VisAttributes::Invisible);
981
982
983 //west end
984 G4RotationMatrix *rotateEnd = new G4RotationMatrix();
985 rotateEnd->rotateY(180.*deg);
986 physiEnd = new G4PVPlacement(rotateEnd,
987 G4ThreeVector(0,0,-(*emcEnd).WorldZPosition),
988 logicEnd,
989 "physicalEndWorld2",
990 logicEMC,
991 false,
992 2);
993
994 ////////////////////////////////////////////////////////////////////////
995 // emc endcap sectors (east) //
996 //////////////////////////////////////////////////////////////////////////
997 // 20mm gap //
998 // || //
999 // \ 7 || 6 / //
1000 // - 8 \ || / 5 - //
1001 // - \ || / - //
1002 // _ 9 - \ || / - 4 _ //
1003 // - _ - \ || / - _ - //
1004 // - _ - \||/ - _ - //
1005 // 10 - -||- - 3 //
1006 // ----------------||---------------- //
1007 // 11 - -||- - 2 //
1008 // _ - - /||\ - - _ //
1009 // _ - - / || \ - - _ //
1010 // - 12 - / || \ - 1 - //
1011 // - / || \ - //
1012 // - 13 / || \ 0 - //
1013 // / 14 || 15 \ //
1014 // || //
1015 ////////////////////////////////////////////////////////////////////////
1016
1017 // 1/16 of endcap world,which has some symmetry
1018 // sector 0-6,8-14
1019 solidEndPhi = new G4Cons("solidEndPhi0",
1020 (*emcEnd).SectorRmin1,(*emcEnd).SectorRmax1,(*emcEnd).SectorRmin2,(*emcEnd).SectorRmax2,
1021 (*emcEnd).SectorDz/2,0.*deg,22.5*deg-da);
1022 logicEndPhi = new G4LogicalVolume(solidEndPhi, G4Material::GetMaterial("Air"), "logicalEndPhi0", 0, 0, 0);
1023 for(G4int i=0;i<14;i++)
1024 {
1025 if((i!=6)&&(i!=7))
1026 {
1027 G4RotationMatrix *rotatePhi = new G4RotationMatrix();
1028 rotatePhi->rotateZ(-i*22.5*deg+67.5*deg);
1029 ostringstream strEndPhi;
1030 strEndPhi << "physicalEndPhi" << i;
1031 physiEndPhi = new G4PVPlacement(rotatePhi,//0,logicEndPhi,strEndPhi.str(),logicEnd,false,i);
1032 G4ThreeVector(0,0,(*emcEnd).SectorZPosition),logicEndPhi,strEndPhi.str(),logicEnd,false,i);
1033 }
1034 }
1035 if(logicEndPhi)
1036 logicEndPhi->SetVisAttributes(endPhiVisAtt);
1037
1038 for(G4int i=0;i<35;i++)
1039 {
1040 ostringstream strEndCasing;
1041 strEndCasing << "solidEndCasing_0_" << i;
1042
1043 //-************tranform to new coodinate! liangyt 2007.5.7 *******
1044 G4ThreeVector newfPnt[8];
1045 G4ThreeVector center(0.0, 0.0, 0.0);
1046 G4ThreeVector rotAngle(0.0, 0.0, 0.0);
1047
1048 TransformToArb8( (*emcEnd).fPnt[i], newfPnt, center, rotAngle );
1049
1050 emcEnd->Zoom(newfPnt,zoomConst); //change emcEnd.fPnt[i] to newfPnt
1051
1052 G4RotationMatrix *rotatePhiIrregBox = new G4RotationMatrix();
1053 rotatePhiIrregBox->rotateX(rotAngle.x());
1054 rotatePhiIrregBox->rotateY(rotAngle.y());
1055 rotatePhiIrregBox->rotateZ(rotAngle.z());
1056 //-*******************************************************************
1057
1058 solidEndCasing = new G4IrregBox(strEndCasing.str(),(*emcEnd).zoomPoint); //liangyt
1059
1060 ostringstream strVEndCasing;
1061 strVEndCasing << "logicalEndCasing_0_" << i;
1062 logicEndCasing = new G4LogicalVolume(solidEndCasing,fCasingMaterial,strVEndCasing.str());
1063
1064 ostringstream strPEndCasing;
1065 strPEndCasing << "physicalEndCasing_0_" << i;
1066 physiEndCasing = new G4PVPlacement(rotatePhiIrregBox,center,
1067 logicEndCasing,strPEndCasing.str(),logicEndPhi,false,i); //change with rot and pos now!
1068
1069 ostringstream strEndCrystal;
1070 strEndCrystal << "solidEndCrystal_0_" << i;
1071
1072 emcEnd->ModifyForCasing((*emcEnd).zoomPoint,i);
1073 solidEndCrystal = new G4IrregBox(strEndCrystal.str(),(*emcEnd).cryPoint);
1074
1075 ostringstream strVEndCrystal;
1076 strVEndCrystal << "logicalEndCrystal_0_" << i;
1077 logicEndCrystal = new G4LogicalVolume(solidEndCrystal,fCrystalMaterial,strVEndCrystal.str());
1078
1079 ostringstream strPEndCrystal;
1080 strPEndCrystal << "physicalEndCrystal_0_" << i;
1081 physiEndCrystal = new G4PVPlacement(0,0,logicEndCrystal,strPEndCrystal.str(),logicEndCasing,false,i);
1082
1083 logicEndCasing->SetVisAttributes(G4VisAttributes::Invisible);
1084 logicEndCrystal->SetVisAttributes(crystalVisAtt);
1085 logicEndCrystal->SetSensitiveDetector(besEMCSD);
1086 }
1087
1088 // the top area which has 20 mm gap
1089 // sector 6,14
1090 solidEndPhi = new G4Cons("solidEndPhi1",
1091 (*emcEnd).WorldRmin1,(*emcEnd).WorldRmax1,(*emcEnd).WorldRmin2,(*emcEnd).WorldRmax2,
1092 (*emcEnd).WorldDz/2,67.5*deg,22.5*deg-da);
1093 logicEndPhi = new G4LogicalVolume(solidEndPhi, G4Material::GetMaterial("Air"), "logicalEndPhi1", 0, 0, 0);
1094 for(G4int i=0;i<2;i++)
1095 {
1096 G4RotationMatrix *rotatePhi = new G4RotationMatrix();
1097 rotatePhi->rotateZ(-i*180.*deg);
1098 ostringstream strEndPhi;
1099 strEndPhi << "physicalEndPhi" << i*8+6;
1100 physiEndPhi = new G4PVPlacement(rotatePhi,G4ThreeVector(0,0,(*emcEnd).SectorZPosition),
1101 logicEndPhi,strEndPhi.str(),logicEnd,false,i*8+6);
1102 }
1103 if(logicEndPhi)
1104 logicEndPhi->SetVisAttributes(endPhiVisAtt);
1105
1106 for(G4int i=0;i<35;i++)
1107 {
1108 ostringstream strEndCasing;
1109 strEndCasing << "solidEndCasing_1_" << i;
1110
1111 //-************tranform to new coodinate! liangyt 2007.5.7 *******
1112 G4ThreeVector newfPnt[8];
1113 G4ThreeVector center(0.0, 0.0, 0.0);
1114 G4ThreeVector rotAngle(0.0, 0.0, 0.0);
1115
1116 TransformToArb8( (*emcEnd).fPnt1[i], newfPnt, center, rotAngle );
1117
1118 emcEnd->Zoom(newfPnt,zoomConst); //change emcEnd.fPnt[i] to newfPnt
1119
1120 G4RotationMatrix *rotatePhiIrregBox = new G4RotationMatrix();
1121 rotatePhiIrregBox->rotateX(rotAngle.x());
1122 rotatePhiIrregBox->rotateY(rotAngle.y());
1123 rotatePhiIrregBox->rotateZ(rotAngle.z());
1124 //-*******************************************************************
1125
1126 solidEndCasing = new G4IrregBox(strEndCasing.str(),(*emcEnd).zoomPoint);
1127
1128 ostringstream strVEndCasing;
1129 strVEndCasing << "logicalEndCasing_1_" << i;
1130 logicEndCasing = new G4LogicalVolume(solidEndCasing,fCasingMaterial,strVEndCasing.str());
1131
1132 ostringstream strPEndCasing;
1133 strPEndCasing << "physicalEndCasing_1_" << i;
1134 physiEndCasing = new G4PVPlacement(rotatePhiIrregBox,center,
1135 logicEndCasing,strPEndCasing.str(),logicEndPhi,false,i); //change with rot and pos now!
1136
1137 ostringstream strEndCrystal;
1138 strEndCrystal << "solidEndCrystal_1_" << i;
1139
1140 emcEnd->ModifyForCasing((*emcEnd).zoomPoint,i);
1141 solidEndCrystal = new G4IrregBox(strEndCrystal.str(),(*emcEnd).cryPoint);
1142
1143 ostringstream strVEndCrystal;
1144 strVEndCrystal << "logicalEndCrystal_1_" << i;
1145 logicEndCrystal = new G4LogicalVolume(solidEndCrystal,fCrystalMaterial,strVEndCrystal.str());
1146
1147 ostringstream strPEndCrystal;
1148 strPEndCrystal << "physicalEndCrystal_1_" << i;
1149 physiEndCrystal = new G4PVPlacement(0,0,logicEndCrystal,strPEndCrystal.str(),logicEndCasing,false,i);
1150
1151 logicEndCasing->SetVisAttributes(G4VisAttributes::Invisible);
1152 logicEndCrystal->SetVisAttributes(crystalVisAtt);
1153 logicEndCrystal->SetSensitiveDetector(besEMCSD);
1154 }
1155
1156 (*emcEnd).ReflectX();
1157
1158 // sector 7,15
1159 for(G4int i=0;i<35;i++)
1160 for (G4int j=0;j<8;j++)
1161 (*emcEnd).fPnt1[i][j].rotateZ(-90.*deg);
1162
1163 solidEndPhi = new G4Cons("solidEndPhi2",
1164 (*emcEnd).WorldRmin1,(*emcEnd).WorldRmax1,(*emcEnd).WorldRmin2,(*emcEnd).WorldRmax2,
1165 (*emcEnd).WorldDz/2,0*deg,22.5*deg-da);
1166 logicEndPhi = new G4LogicalVolume(solidEndPhi, G4Material::GetMaterial("Air"), "logicalEndPhi2", 0, 0, 0);
1167 for(G4int i=0;i<2;i++)
1168 {
1169 G4RotationMatrix *rotatePhi = new G4RotationMatrix();
1170 rotatePhi->rotateZ(-i*180.*deg-90.*deg);
1171 ostringstream strEndPhi;
1172 strEndPhi << "physicalEndPhi" << i*8+7;
1173 physiEndPhi = new G4PVPlacement(rotatePhi,G4ThreeVector(0,0,(*emcEnd).SectorZPosition),
1174 logicEndPhi,strEndPhi.str(),logicEnd,false,i*8+7);
1175 }
1176 if(logicEndPhi)
1177 logicEndPhi->SetVisAttributes(endPhiVisAtt);
1178
1179 for(G4int i=0;i<35;i++)
1180 {
1181 ostringstream strEndCasing;
1182 strEndCasing << "solidEndCasing_2_" << i;
1183
1184 //-************tranform to new coodinate! liangyt 2007.5.7 *******
1185 G4ThreeVector newfPnt[8];
1186 G4ThreeVector center(0.0, 0.0, 0.0);
1187 G4ThreeVector rotAngle(0.0, 0.0, 0.0);
1188
1189 TransformToArb8( (*emcEnd).fPnt1[i], newfPnt, center, rotAngle );
1190
1191 emcEnd->Zoom(newfPnt,zoomConst); //change emcEnd.fPnt[i] to newfPnt
1192
1193 G4RotationMatrix *rotatePhiIrregBox = new G4RotationMatrix();
1194 rotatePhiIrregBox->rotateX(rotAngle.x());
1195 rotatePhiIrregBox->rotateY(rotAngle.y());
1196 rotatePhiIrregBox->rotateZ(rotAngle.z());
1197 //-*******************************************************************
1198
1199 solidEndCasing = new G4IrregBox(strEndCasing.str(),(*emcEnd).zoomPoint);
1200
1201 ostringstream strVEndCasing;
1202 strVEndCasing << "logicalEndCasing_2_" << i;
1203 logicEndCasing = new G4LogicalVolume(solidEndCasing,fCasingMaterial,strVEndCasing.str());
1204
1205 ostringstream strPEndCasing;
1206 strPEndCasing << "physicalEndCasing_2_" << i;
1207 physiEndCasing = new G4PVPlacement(rotatePhiIrregBox,center,
1208 logicEndCasing,strPEndCasing.str(),logicEndPhi,false,i); //change with rot and pos now!
1209
1210 ostringstream strEndCrystal;
1211 strEndCrystal << "solidEndCrystal_2_" << i;
1212
1213 emcEnd->ModifyForCasing((*emcEnd).zoomPoint,i);
1214 solidEndCrystal = new G4IrregBox(strEndCrystal.str(),(*emcEnd).cryPoint);
1215
1216 ostringstream strVEndCrystal;
1217 strVEndCrystal << "logicalEndCrystal_2_" << i;
1218 logicEndCrystal = new G4LogicalVolume(solidEndCrystal,fCrystalMaterial,strVEndCrystal.str());
1219
1220 ostringstream strPEndCrystal;
1221 strPEndCrystal << "physicalEndCrystal_2_" << i;
1222 physiEndCrystal = new G4PVPlacement(0,0,logicEndCrystal,strPEndCrystal.str(),logicEndCasing,false,i);
1223
1224 logicEndCasing->SetVisAttributes(G4VisAttributes::Invisible);
1225 logicEndCrystal->SetVisAttributes(crystalVisAtt);
1226 logicEndCrystal->SetSensitiveDetector(besEMCSD);
1227 }
1228}
void TransformToArb8(const G4ThreeVector fPnt[8], G4ThreeVector newfPnt[8], G4ThreeVector &center, G4ThreeVector &rotAngle)
void ModifyForCasing(G4ThreeVector pos[8], G4int CryNb)
void Zoom(const G4ThreeVector pos[8], const G4double factor)

Referenced by Construct().

◆ ConstructEndGeometry() [2/2]

void BesEmcConstruction::ConstructEndGeometry ( G4LogicalVolume *  )

◆ ConstructSPFrame() [1/2]

void BesEmcConstruction::ConstructSPFrame ( G4LogicalVolume *  logicEMC,
BesEmcGeometry besEMCGeometry 
)

Definition at line 1256 of file BesEmcConstruction.cc.

1257{
1258 G4double rmax=(*besEMCGeometry).BSCRmax+2.*mm; //radius from 942mm to 940mm
1259 solidSupportBar = new G4Tubs("solidSupportBar0",
1260 rmax+(*besEMCGeometry).SPBarThickness1,
1261 rmax+(*besEMCGeometry).SPBarThickness+(*besEMCGeometry).SPBarThickness1,
1262 (*besEMCGeometry).BSCDz
1263 +(*besEMCGeometry).TaperRingThickness3+(*besEMCGeometry).EndRingDz,
1264 0.*deg,
1265 360.*deg);
1266
1267 logicSupportBar = new G4LogicalVolume(solidSupportBar,stainlessSteel,"logicalSupportBar0");
1268
1269 physiSupportBar = new G4PVPlacement(0,0,logicSupportBar,"physicalSupportBar0",logicEMC,false,0);
1270
1271 solidSupportBar1 = new G4Tubs("solidSupportBar1",
1272 rmax,
1273 rmax+(*besEMCGeometry).SPBarThickness1,
1274 (*besEMCGeometry).BSCDz+(*besEMCGeometry).TaperRingThickness3,
1275 (*besEMCGeometry).BSCPhiDphi-(*besEMCGeometry).SPBarDphi/2,
1276 (*besEMCGeometry).SPBarDphi);
1277
1278 logicSupportBar1 = new G4LogicalVolume(solidSupportBar1,stainlessSteel,"logicalSupportBar1");
1279
1280 for(G4int i=0;i<(*besEMCGeometry).BSCNbPhi/2;i++)
1281 {
1282 G4RotationMatrix *rotateSPBar = new G4RotationMatrix();
1283 rotateSPBar->rotateZ((*besEMCGeometry).BSCPhiDphi-i*2*(*besEMCGeometry).BSCPhiDphi);
1284 ostringstream strSupportBar1;
1285 strSupportBar1 << "physicalSupportBar1_" << i;
1286 physiSupportBar1 = new G4PVPlacement(rotateSPBar,0,
1287 logicSupportBar1,strSupportBar1.str(),logicEMC,false,0);
1288 }
1289
1290 //end ring
1291 solidEndRing = new G4Tubs("solidEndRing",
1292 (*besEMCGeometry).EndRingRmin,
1293 (*besEMCGeometry).EndRingRmin+(*besEMCGeometry).EndRingDr/2,
1294 (*besEMCGeometry).EndRingDz/2,
1295 0.*deg,
1296 360.*deg);
1297
1298 solidGear = new G4Tubs("solidGear",
1299 (*besEMCGeometry).EndRingRmin+(*besEMCGeometry).EndRingDr/2,
1300 (*besEMCGeometry).EndRingRmin+(*besEMCGeometry).EndRingDr,
1301 (*besEMCGeometry).EndRingDz/2,
1302 0.*deg,
1303 (*besEMCGeometry).BSCPhiDphi);
1304
1305 //taper ring
1306 solidTaperRing1 = new G4Tubs("solidTaperRing1",
1307 (*besEMCGeometry).TaperRingRmin1,
1308 (*besEMCGeometry).TaperRingRmin1+(*besEMCGeometry).TaperRingThickness1,
1309 (*besEMCGeometry).TaperRingInnerLength/2,
1310 0.*deg,
1311 360.*deg);
1312
1313 solidTaperRing2 = new G4Cons("solidTaperRing2",
1314 (*besEMCGeometry).TaperRingRmin1,
1315 (*besEMCGeometry).TaperRingRmin1+(*besEMCGeometry).TaperRingDr,
1316 (*besEMCGeometry).TaperRingRmin2,
1317 (*besEMCGeometry).TaperRingRmin2+(*besEMCGeometry).TaperRingDr,
1318 (*besEMCGeometry).TaperRingDz/2,
1319 0.*deg,
1320 360.*deg);
1321
1322 solidTaperRing3 = new G4Cons("solidTaperRing3",
1323 (*besEMCGeometry).BSCRmax2,
1324 (*besEMCGeometry).BSCRmax2+(*besEMCGeometry).TaperRingOuterLength1,
1325 (*besEMCGeometry).TaperRingRmin2+(*besEMCGeometry).TaperRingDr,
1326 (*besEMCGeometry).TaperRingRmin2+(*besEMCGeometry).TaperRingDr+(*besEMCGeometry).TaperRingOuterLength,
1327 (*besEMCGeometry).TaperRingThickness3/2,
1328 0.*deg,
1329 360.*deg);
1330
1331 logicEndRing = new G4LogicalVolume(solidEndRing,stainlessSteel,"logicalEndRing");
1332 logicGear = new G4LogicalVolume(solidGear,stainlessSteel,"logicalGear");
1333 logicTaperRing1 = new G4LogicalVolume(solidTaperRing1,stainlessSteel,"logicalTaperRing1");
1334 logicTaperRing2 = new G4LogicalVolume(solidTaperRing2,stainlessSteel,"logicalTaperRing2");
1335 logicTaperRing3 = new G4LogicalVolume(solidTaperRing3,stainlessSteel,"logicalTaperRing3");
1336
1337 for(G4int i=0;i<2;i++)
1338 {
1339 G4RotationMatrix *rotateSPRing = new G4RotationMatrix();
1340 G4double zEndRing,z1,z2,z3;
1341 if(i==0)
1342 {
1343 zEndRing = (*besEMCGeometry).BSCDz+(*besEMCGeometry).TaperRingThickness3+(*besEMCGeometry).EndRingDz/2;
1344 z1 = (*besEMCGeometry).BSCDz+(*besEMCGeometry).TaperRingThickness3
1345 -(*besEMCGeometry).TaperRingDz-(*besEMCGeometry).TaperRingInnerLength/2;
1346 z2 = (*besEMCGeometry).BSCDz+(*besEMCGeometry).TaperRingThickness3-(*besEMCGeometry).TaperRingDz/2;
1347 z3 = (*besEMCGeometry).BSCDz+(*besEMCGeometry).TaperRingThickness3/2;
1348 }
1349 else
1350 {
1351 rotateSPRing->rotateY(180.*deg);
1352 zEndRing = -((*besEMCGeometry).BSCDz+(*besEMCGeometry).TaperRingThickness3+(*besEMCGeometry).EndRingDz/2);
1353 z1 = -((*besEMCGeometry).BSCDz+(*besEMCGeometry).TaperRingThickness3
1354 -(*besEMCGeometry).TaperRingDz-(*besEMCGeometry).TaperRingInnerLength/2);
1355 z2 = -((*besEMCGeometry).BSCDz+(*besEMCGeometry).TaperRingThickness3-(*besEMCGeometry).TaperRingDz/2);
1356 z3 = -((*besEMCGeometry).BSCDz+(*besEMCGeometry).TaperRingThickness3/2);
1357 }
1358
1359 ostringstream strEndRing;
1360 strEndRing << "physicalEndRing_" << i;
1361 physiEndRing = new G4PVPlacement(rotateSPRing,G4ThreeVector(0,0,zEndRing),
1362 logicEndRing,strEndRing.str(),logicEMC,false,0);
1363
1364 for(G4int j=0;j<(*besEMCGeometry).BSCNbPhi/2;j++)
1365 {
1366 G4RotationMatrix *rotateGear = new G4RotationMatrix();
1367 rotateGear->rotateZ((*besEMCGeometry).BSCPhiDphi/2-j*2*(*besEMCGeometry).BSCPhiDphi);
1368
1369 ostringstream strGear;
1370 strGear << "physicalGear_" << i << "_" <<j;
1371 physiGear = new G4PVPlacement(rotateGear,G4ThreeVector(0,0,zEndRing),
1372 logicGear,strGear.str(),logicEMC,false,0);
1373 }
1374
1375 ostringstream strTaperRing1;
1376 strTaperRing1 << "physicalTaperRing1_" << i;
1377 physiTaperRing1 = new G4PVPlacement(rotateSPRing,G4ThreeVector(0,0,z1),
1378 logicTaperRing1,strTaperRing1.str(),logicEMC,false,0);
1379
1380 ostringstream strTaperRing2;
1381 strTaperRing2 << "physicalTaperRing2_" << i;
1382 physiTaperRing2 = new G4PVPlacement(rotateSPRing,G4ThreeVector(0,0,z2),
1383 logicTaperRing2,strTaperRing2.str(),logicEMC,false,0);
1384
1385 ostringstream strTaperRing3;
1386 strTaperRing3 << "physicalTaperRing3_" << i;
1387 physiTaperRing3 = new G4PVPlacement(rotateSPRing,G4ThreeVector(0,0,z3),
1388 logicTaperRing3,strTaperRing3.str(),logicEMC,false,0);
1389 }
1390}

Referenced by Construct().

◆ ConstructSPFrame() [2/2]

void BesEmcConstruction::ConstructSPFrame ( G4LogicalVolume *  ,
BesEmcGeometry  
)

◆ GetBesEmcConstruction() [1/2]

BesEmcConstruction * BesEmcConstruction::GetBesEmcConstruction ( )
static

Definition at line 54 of file BesEmcConstruction.cc.

55{ return fBesEmcConstruction;}

Referenced by BesCrystalParameterisation::ComputeIDAndSide(), and BesCrystalParameterisation::ComputeMaterial().

◆ GetBesEmcConstruction() [2/2]

static BesEmcConstruction * BesEmcConstruction::GetBesEmcConstruction ( )
static

◆ GetBSCCrystal() [1/2]

const G4VPhysicalVolume * BesEmcConstruction::GetBSCCrystal ( )
inline

Definition at line 113 of file InstallArea/include/EmcSim/EmcSim/BesEmcConstruction.hh.

113{return physiBSCCrystal;};

◆ GetBSCCrystal() [2/2]

const G4VPhysicalVolume * BesEmcConstruction::GetBSCCrystal ( )
inline

Definition at line 113 of file Simulation/BOOST/EmcSim/EmcSim-00-00-46/EmcSim/BesEmcConstruction.hh.

113{return physiBSCCrystal;};

◆ GetBSCPhi() [1/2]

const G4VPhysicalVolume * BesEmcConstruction::GetBSCPhi ( )
inline

Definition at line 111 of file InstallArea/include/EmcSim/EmcSim/BesEmcConstruction.hh.

111{return physiBSCPhi;};

◆ GetBSCPhi() [2/2]

const G4VPhysicalVolume * BesEmcConstruction::GetBSCPhi ( )
inline

Definition at line 111 of file Simulation/BOOST/EmcSim/EmcSim-00-00-46/EmcSim/BesEmcConstruction.hh.

111{return physiBSCPhi;};

◆ GetBSCTheta() [1/2]

const G4VPhysicalVolume * BesEmcConstruction::GetBSCTheta ( )
inline

Definition at line 112 of file InstallArea/include/EmcSim/EmcSim/BesEmcConstruction.hh.

112{return physiBSCTheta;};

◆ GetBSCTheta() [2/2]

const G4VPhysicalVolume * BesEmcConstruction::GetBSCTheta ( )
inline

Definition at line 112 of file Simulation/BOOST/EmcSim/EmcSim-00-00-46/EmcSim/BesEmcConstruction.hh.

112{return physiBSCTheta;};

◆ GetCasingMaterial() [1/2]

G4Material * BesEmcConstruction::GetCasingMaterial ( )
inline

◆ GetCasingMaterial() [2/2]

G4Material * BesEmcConstruction::GetCasingMaterial ( )
inline

Definition at line 107 of file Simulation/BOOST/EmcSim/EmcSim-00-00-46/EmcSim/BesEmcConstruction.hh.

107{return fCasingMaterial;};

◆ GetCrystalMaterial() [1/2]

G4Material * BesEmcConstruction::GetCrystalMaterial ( )
inline

◆ GetCrystalMaterial() [2/2]

G4Material * BesEmcConstruction::GetCrystalMaterial ( )
inline

Definition at line 106 of file Simulation/BOOST/EmcSim/EmcSim-00-00-46/EmcSim/BesEmcConstruction.hh.

106{return fCrystalMaterial;};

◆ GetCrystalParam() [1/2]

const G4VPVParameterisation * BesEmcConstruction::GetCrystalParam ( )
inline

Definition at line 114 of file InstallArea/include/EmcSim/EmcSim/BesEmcConstruction.hh.

114{return crystalParam;};

◆ GetCrystalParam() [2/2]

const G4VPVParameterisation * BesEmcConstruction::GetCrystalParam ( )
inline

Definition at line 114 of file Simulation/BOOST/EmcSim/EmcSim-00-00-46/EmcSim/BesEmcConstruction.hh.

114{return crystalParam;};

◆ GetEMC() [1/2]

const G4VPhysicalVolume * BesEmcConstruction::GetEMC ( )
inline

Definition at line 110 of file InstallArea/include/EmcSim/EmcSim/BesEmcConstruction.hh.

110{return physiEMC; }

◆ GetEMC() [2/2]

const G4VPhysicalVolume * BesEmcConstruction::GetEMC ( )
inline

Definition at line 110 of file Simulation/BOOST/EmcSim/EmcSim-00-00-46/EmcSim/BesEmcConstruction.hh.

110{return physiEMC; }

◆ GetLogicalVolume() [1/2]

void BesEmcConstruction::GetLogicalVolume ( )

Definition at line 1466 of file BesEmcConstruction.cc.

1467{
1468 //-------------------------------------------------------------
1469 //Barrel
1470 logicBSCWorld = FindLogicalVolume("logicalBSCWorld");
1471 logicBSCCrystal = FindLogicalVolume("logicalCrystal");
1472 logicBSCPhi = FindLogicalVolume("logicalBSCPhi");
1473 logicRear = FindLogicalVolume("logicalRearBox");
1474 logicOrgGlass = FindLogicalVolume("logicalOrganicGlass");
1475 logicRearCasing = FindLogicalVolume("logicalRearCasing");
1476 logicAlPlate = FindLogicalVolume("logicalAlPlate");
1477 logicPD = FindLogicalVolume("logicalPD");
1478 logicPreAmpBox = FindLogicalVolume("logicalPreAmpBox");
1479 logicAirInPABox = FindLogicalVolume("logicalAirInPABox");
1480 logicHangingPlate = FindLogicalVolume("logicalHangingPlate");
1481 logicWaterPipe = FindLogicalVolume("logicalWaterPipe");
1482
1483 for(int i = 0; i < 44; i++){
1484 std::ostringstream osnameBSCCasing;
1485 osnameBSCCasing << "logicalBSCCasing"<<i;
1486 logicBSCTheta = FindLogicalVolume( osnameBSCCasing.str() );
1487 if(logicBSCTheta)
1488 {
1489 G4VisAttributes* rightVisAtt= new G4VisAttributes(G4Colour(1.0, 0.0,0.0));
1490 rightVisAtt->SetVisibility(false);
1491 logicBSCTheta->SetVisAttributes(rightVisAtt);
1492 }
1493
1494 std::ostringstream osnameBSCCable1;
1495 osnameBSCCable1 << "logicalBSCCable_1_"<<i;
1496 logicCable = FindLogicalVolume( osnameBSCCable1.str() );
1497 if(logicCable)
1498 logicCable->SetVisAttributes(G4VisAttributes::Invisible);
1499
1500 std::ostringstream osnameBSCCable2;
1501 osnameBSCCable2 << "logicalBSCCable_2_"<<i;
1502 logicCable = FindLogicalVolume( osnameBSCCable2.str() );
1503 if(logicCable)
1504 logicCable->SetVisAttributes(G4VisAttributes::Invisible);
1505
1506 std::ostringstream osnameOCGirder1;
1507 osnameOCGirder1 <<"logicalOpenningCutGirder_1_"<<i;
1508 logicOCGirder = FindLogicalVolume( osnameOCGirder1.str() );
1509 if(logicOCGirder)
1510 logicOCGirder->SetVisAttributes(G4VisAttributes::Invisible);
1511
1512 std::ostringstream osnameOCGirder2;
1513 osnameOCGirder2 <<"logicalOpenningCutGirder_2_"<<i;
1514 logicOCGirder = FindLogicalVolume( osnameOCGirder2.str() );
1515 if(logicOCGirder)
1516 logicOCGirder->SetVisAttributes(G4VisAttributes::Invisible);
1517
1518 std::ostringstream osnameOCGirder3;
1519 osnameOCGirder3 <<"logicalOpenningCutGirder_3_"<<i;
1520 logicOCGirder = FindLogicalVolume( osnameOCGirder3.str() );
1521 if(logicOCGirder)
1522 logicOCGirder->SetVisAttributes(G4VisAttributes::Invisible);
1523
1524 std::ostringstream osnameOCGirder4;
1525 osnameOCGirder4 <<"logicalOpenningCutGirder_4_"<<i;
1526 logicOCGirder = FindLogicalVolume( osnameOCGirder4.str() );
1527 if(logicOCGirder)
1528 logicOCGirder->SetVisAttributes(G4VisAttributes::Invisible);
1529 }
1530
1531 //-------------------------------------------------------------
1532 //Support system
1533 logicSupportBar = FindLogicalVolume("logicalSupportBar0");
1534 logicSupportBar1 = FindLogicalVolume("logicalSupportBar1");
1535 logicEndRing = FindLogicalVolume("logicalEndRing");
1536 logicGear = FindLogicalVolume("logicalGear");
1537 logicTaperRing1 = FindLogicalVolume("logicalTaperRing1");
1538 logicTaperRing2 = FindLogicalVolume("logicalTaperRing2");
1539 logicTaperRing3 = FindLogicalVolume("logicalTaperRing3");
1540
1541 //-------------------------------------------------------------
1542 //Endcap
1543 logicEnd = FindLogicalVolume("logicalEndWorld");
1544
1545 for(G4int sector=0;sector<3;sector++) {
1546 std::ostringstream osnameEndPhi;
1547 osnameEndPhi<<"logicalEndPhi"<<sector;
1548 logicEndPhi = FindLogicalVolume(osnameEndPhi.str());
1549 if(logicEndPhi) {
1550 logicEndPhi->SetVisAttributes(G4VisAttributes::Invisible);
1551 } else {
1552 G4cout<<"Can't find logicEndPhi!"<<G4endl;
1553 }
1554
1555 for(G4int cryNb=0;cryNb<35;cryNb++) {
1556
1557 std::ostringstream osnameEndCrystal;
1558 osnameEndCrystal<<"logicalEndCrystal_"<<sector<<"_"<<cryNb;
1559 logicEndCrystal = FindLogicalVolume( osnameEndCrystal.str() );
1560 if(logicEndCrystal) {
1561 logicEndCrystal->SetSensitiveDetector(besEMCSD);
1562 G4VisAttributes* crystalVisAtt
1563 = new G4VisAttributes(G4Colour(0.5,0,1.0));
1564 crystalVisAtt->SetVisibility(false);
1565 logicEndCrystal->SetVisAttributes(crystalVisAtt);
1566 } else {
1567 G4cout<<"Can't find: "<<osnameEndCrystal.str()<<G4endl;
1568 }
1569
1570 std::ostringstream osnameEndCasing;
1571 osnameEndCasing<<"logicalEndCasing_"<<sector<<"_"<<cryNb;
1572 logicEndCasing = FindLogicalVolume( osnameEndCasing.str() );
1573 if(logicEndCasing) {
1574 logicEndCasing->SetVisAttributes(G4VisAttributes::Invisible);
1575 } else {
1576 G4cout<<"Can't find: "<<osnameEndCasing.str()<<G4endl;
1577 }
1578 }
1579 }
1580}
G4LogicalVolume * FindLogicalVolume(const G4String &vn)

Referenced by Construct().

◆ GetLogicalVolume() [2/2]

void BesEmcConstruction::GetLogicalVolume ( )

◆ GetMagField() [1/2]

G4double BesEmcConstruction::GetMagField ( )
inline

◆ GetMagField() [2/2]

G4double BesEmcConstruction::GetMagField ( )
inline

Definition at line 102 of file Simulation/BOOST/EmcSim/EmcSim-00-00-46/EmcSim/BesEmcConstruction.hh.

102{return fmagField;};

◆ GetStartIDTheta() [1/2]

G4int BesEmcConstruction::GetStartIDTheta ( )
inline

Definition at line 104 of file InstallArea/include/EmcSim/EmcSim/BesEmcConstruction.hh.

104{return startID;};

◆ GetStartIDTheta() [2/2]

G4int BesEmcConstruction::GetStartIDTheta ( )
inline

Definition at line 104 of file Simulation/BOOST/EmcSim/EmcSim-00-00-46/EmcSim/BesEmcConstruction.hh.

104{return startID;};

◆ GetVerboseLevel() [1/2]

G4int BesEmcConstruction::GetVerboseLevel ( )
inline

◆ GetVerboseLevel() [2/2]

G4int BesEmcConstruction::GetVerboseLevel ( )
inline

Definition at line 101 of file Simulation/BOOST/EmcSim/EmcSim-00-00-46/EmcSim/BesEmcConstruction.hh.

101{return verboseLevel;};

◆ PrintEMCParameters() [1/2]

void BesEmcConstruction::PrintEMCParameters ( )

Definition at line 1713 of file BesEmcConstruction.cc.

1714{
1715 G4cout << "-------------------------------------------------------"<< G4endl
1716 << "---> There are "
1717 << phiNbCrystals << "(max=" << (*besEMCGeometry).BSCNbPhi
1718 << ") crystals along phi direction and "
1719 << thetaNbCrystals << "(max=" << (*besEMCGeometry).BSCNbTheta
1720 << ") crystals along theta direction."<< G4endl
1721 << "The crystals have sizes of "
1722 << (*besEMCGeometry).BSCCryLength/cm << "cm(L) and "
1723 << (*besEMCGeometry).BSCYFront/cm << "cm(Y) with "
1724 << fCrystalMaterial->GetName() <<"."<< G4endl
1725 << "The casing is layer of "
1726 << (*besEMCGeometry).fTyvekThickness/mm << "mm tyvek,"
1727 << (*besEMCGeometry).fAlThickness/mm << "mm aluminum and"
1728 << (*besEMCGeometry).fMylarThickness/mm << "mm mylar."<< G4endl
1729 << "-------------------------------------------------------"<< G4endl;
1730 G4cout << G4Material::GetMaterial("PolyethyleneTerephthlate") << G4endl
1731 << G4Material::GetMaterial("Casing") << G4endl
1732 << G4Material::GetMaterial("Polyethylene") << G4endl
1733 << "-------------------------------------------------------"<< G4endl;
1734}

Referenced by Construct(), SetCasingMaterial(), and SetCrystalMaterial().

◆ PrintEMCParameters() [2/2]

void BesEmcConstruction::PrintEMCParameters ( )

◆ RotAngleFromNewZ() [1/2]

Hep3Vector BesEmcConstruction::RotAngleFromNewZ ( Hep3Vector  newZ)

Definition at line 1908 of file BesEmcConstruction.cc.

1909{
1910 newZ.setMag(1.0);
1911 Hep3Vector x0(1, 0, 0), y0(0, 1, 0), z0(0, 0, 1);
1912 double dx, dy, dz = 0.0;
1913
1914 Hep3Vector a(0.0, newZ.y(), newZ.z());
1915 // three rotated angles, rotate dx angles(rad) by X axis,
1916 // then rotate dy by new Y axis, then dz by new Z axis;
1917 // all rotate in left hand system;
1918
1919 // a, project of final newZ on original YZ plane, 0 <= theta < pi;
1920 if(a.mag() != 0.0) a.setMag(1.0);
1921 else cout << "newZ on X axis, a=(0,0,0)" << endl;
1922 dx = acos(a.dot(z0));
1923 if(a.dot(z0) == -1.0) dx = 0.0;
1924
1925 // b, rotate dx angle of z0 around original X axis(x0),
1926 Hep3Vector b(0, sin(dx), cos(dx));
1927 dy = acos(b.dot(newZ));
1928 if(newZ.x() > 0.0) dy = -dy;
1929
1930 Hep3Vector v(dx, dy, dz);
1931 return v;
1932}
**********Class see also m_nmax DOUBLE PRECISION m_amel DOUBLE PRECISION m_x2 DOUBLE PRECISION m_alfinv DOUBLE PRECISION m_Xenph INTEGER m_KeyWtm INTEGER m_idyfs DOUBLE PRECISION m_zini DOUBLE PRECISION m_q2 DOUBLE PRECISION m_Wt_KF DOUBLE PRECISION m_WtCut INTEGER m_KFfin *COMMON c_KarLud $ !Input CMS energy[GeV] $ !CMS energy after beam spread beam strahlung[GeV] $ !Beam energy spread[GeV] $ !z boost due to beam spread $ !electron beam mass *ff pair spectrum $ !minimum v
Definition: KarLud.h:35

Referenced by TransformToArb8().

◆ RotAngleFromNewZ() [2/2]

Hep3Vector BesEmcConstruction::RotAngleFromNewZ ( Hep3Vector  newZ)

◆ SetBSCCrystalLength() [1/2]

void BesEmcConstruction::SetBSCCrystalLength ( G4double  val)

Definition at line 1801 of file BesEmcConstruction.cc.

1802{
1803 (*besEMCGeometry).BSCCryLength = val;
1804}

Referenced by BesEmcDetectorMessenger::SetNewValue().

◆ SetBSCCrystalLength() [2/2]

void BesEmcConstruction::SetBSCCrystalLength ( G4double  )

◆ SetBSCNbPhi() [1/2]

void BesEmcConstruction::SetBSCNbPhi ( G4int  val)

Definition at line 1781 of file BesEmcConstruction.cc.

1782{
1783 (*besEMCGeometry).BSCNbPhi = val;
1784}

Referenced by BesEmcDetectorMessenger::SetNewValue().

◆ SetBSCNbPhi() [2/2]

void BesEmcConstruction::SetBSCNbPhi ( G4int  )

◆ SetBSCNbTheta() [1/2]

void BesEmcConstruction::SetBSCNbTheta ( G4int  val)

Definition at line 1788 of file BesEmcConstruction.cc.

1789{
1790 (*besEMCGeometry).BSCNbTheta = val;
1791}

Referenced by BesEmcDetectorMessenger::SetNewValue().

◆ SetBSCNbTheta() [2/2]

void BesEmcConstruction::SetBSCNbTheta ( G4int  )

◆ SetBSCPosition0() [1/2]

void BesEmcConstruction::SetBSCPosition0 ( G4double  val)

Definition at line 1822 of file BesEmcConstruction.cc.

1823{
1824 (*besEMCGeometry).BSCPosition0 = val;
1825}

◆ SetBSCPosition0() [2/2]

void BesEmcConstruction::SetBSCPosition0 ( G4double  )

◆ SetBSCPosition1() [1/2]

void BesEmcConstruction::SetBSCPosition1 ( G4double  val)

Definition at line 1829 of file BesEmcConstruction.cc.

1830{
1831 (*besEMCGeometry).BSCPosition1 = val;
1832}

◆ SetBSCPosition1() [2/2]

void BesEmcConstruction::SetBSCPosition1 ( G4double  )

◆ SetBSCRmin() [1/2]

void BesEmcConstruction::SetBSCRmin ( G4double  val)

Definition at line 1774 of file BesEmcConstruction.cc.

1775{
1776 (*besEMCGeometry).BSCRmin = val;
1777}

Referenced by BesEmcDetectorMessenger::SetNewValue().

◆ SetBSCRmin() [2/2]

void BesEmcConstruction::SetBSCRmin ( G4double  )

◆ SetBSCYFront() [1/2]

void BesEmcConstruction::SetBSCYFront ( G4double  val)

Definition at line 1815 of file BesEmcConstruction.cc.

1816{
1817 (*besEMCGeometry).BSCYFront = val;
1818}

◆ SetBSCYFront() [2/2]

void BesEmcConstruction::SetBSCYFront ( G4double  )

◆ SetBSCYFront0() [1/2]

void BesEmcConstruction::SetBSCYFront0 ( G4double  val)

Definition at line 1808 of file BesEmcConstruction.cc.

1809{
1810 (*besEMCGeometry).BSCYFront0 = val;
1811}

◆ SetBSCYFront0() [2/2]

void BesEmcConstruction::SetBSCYFront0 ( G4double  )

◆ SetCasingMaterial() [1/2]

void BesEmcConstruction::SetCasingMaterial ( G4String  materialChoice)

Definition at line 1751 of file BesEmcConstruction.cc.

1752{
1753 // search the material by its name
1754 G4Material* pttoMaterial = G4Material::GetMaterial(materialChoice);
1755 if (pttoMaterial)
1756 {fCasingMaterial = pttoMaterial;
1757 logicBSCTheta->SetMaterial(pttoMaterial);
1759 }
1760}

Referenced by BesEmcDetectorMessenger::SetNewValue().

◆ SetCasingMaterial() [2/2]

void BesEmcConstruction::SetCasingMaterial ( G4String  )

◆ SetCasingThickness() [1/2]

void BesEmcConstruction::SetCasingThickness ( G4ThreeVector  val)

Definition at line 1764 of file BesEmcConstruction.cc.

1765{
1766 // change Gap thickness and recompute the calorimeter parameters
1767 (*besEMCGeometry).fTyvekThickness = val('X');
1768 (*besEMCGeometry).fAlThickness = val('Y');
1769 (*besEMCGeometry).fMylarThickness = val('Z');
1770}

Referenced by BesEmcDetectorMessenger::SetNewValue().

◆ SetCasingThickness() [2/2]

void BesEmcConstruction::SetCasingThickness ( G4ThreeVector  )

◆ SetCrystalMaterial() [1/2]

void BesEmcConstruction::SetCrystalMaterial ( G4String  materialChoice)

Definition at line 1738 of file BesEmcConstruction.cc.

1739{
1740 // search the material by its name
1741 G4Material* pttoMaterial = G4Material::GetMaterial(materialChoice);
1742 if (pttoMaterial)
1743 {fCrystalMaterial = pttoMaterial;
1744 logicBSCCrystal->SetMaterial(pttoMaterial);
1746 }
1747}

Referenced by BesEmcDetectorMessenger::SetNewValue().

◆ SetCrystalMaterial() [2/2]

void BesEmcConstruction::SetCrystalMaterial ( G4String  )

◆ SetMagField() [1/2]

void BesEmcConstruction::SetMagField ( G4double  fieldValue)

Definition at line 1837 of file BesEmcConstruction.cc.

1838{
1839 //apply a global uniform magnetic field along Z axis
1840 G4FieldManager* fieldMgr
1841 = G4TransportationManager::GetTransportationManager()->GetFieldManager();
1842
1843 if(magField) delete magField; //delete the existing magn field
1844
1845 if(fieldValue!=0.) // create a new one if non nul
1846 { magField = new G4UniformMagField(G4ThreeVector(0.,0.,fieldValue));
1847 fieldMgr->SetDetectorField(magField);
1848 fieldMgr->CreateChordFinder(magField);
1849 fmagField=fieldValue;
1850 } else {
1851 magField = 0;
1852 fieldMgr->SetDetectorField(magField);
1853 fmagField=0.;
1854 }
1855}

Referenced by BesEmcDetectorMessenger::SetNewValue().

◆ SetMagField() [2/2]

void BesEmcConstruction::SetMagField ( G4double  )

◆ SetStartIDTheta() [1/2]

void BesEmcConstruction::SetStartIDTheta ( G4int  val)

Definition at line 1793 of file BesEmcConstruction.cc.

1794{
1795 startID = val;
1796}

Referenced by BesEmcDetectorMessenger::SetNewValue().

◆ SetStartIDTheta() [2/2]

void BesEmcConstruction::SetStartIDTheta ( G4int  )

◆ SetVerboseLevel() [1/2]

void BesEmcConstruction::SetVerboseLevel ( G4int  val)
inline

Definition at line 69 of file InstallArea/include/EmcSim/EmcSim/BesEmcConstruction.hh.

69{ verboseLevel=val;}

Referenced by BesEmcDetectorMessenger::SetNewValue().

◆ SetVerboseLevel() [2/2]

void BesEmcConstruction::SetVerboseLevel ( G4int  val)
inline

Definition at line 69 of file Simulation/BOOST/EmcSim/EmcSim-00-00-46/EmcSim/BesEmcConstruction.hh.

69{ verboseLevel=val;}

◆ SetVisAndSD() [1/2]

void BesEmcConstruction::SetVisAndSD ( )

Definition at line 1393 of file BesEmcConstruction.cc.

1394{
1395 //-------------------------------------------------------------
1396 //Barrel
1397 G4VisAttributes* bscVisAtt= new G4VisAttributes(G4Colour(0.5,0.5,0.5));
1398 bscVisAtt->SetVisibility(false);
1399 logicEMC->SetVisAttributes(bscVisAtt);
1400 if(logicBSCWorld)
1401 logicBSCWorld->SetVisAttributes(G4VisAttributes::Invisible);
1402
1403 if (logicBSCCrystal) {
1404 //G4cout<<"find BSCCrystal "<<G4endl;
1405 G4VisAttributes* crystalVisAtt= new G4VisAttributes(G4Colour(0,0,1.0));
1406 crystalVisAtt->SetVisibility(true);
1407 logicBSCCrystal->SetVisAttributes(crystalVisAtt);
1408 logicBSCCrystal->SetSensitiveDetector(besEMCSD);
1409 }
1410
1411 if(logicBSCPhi) {
1412 G4VisAttributes* rightVisAtt= new G4VisAttributes(G4Colour(1.0,0.,1.0));
1413 rightVisAtt->SetVisibility(false);
1414 logicBSCPhi->SetVisAttributes(rightVisAtt);
1415 }
1416
1417 if(logicRear)
1418 logicRear->SetVisAttributes(G4VisAttributes::Invisible);
1419 if(logicOrgGlass)
1420 logicOrgGlass->SetVisAttributes(G4VisAttributes::Invisible);
1421 if(logicRearCasing)
1422 logicRearCasing->SetVisAttributes(G4VisAttributes::Invisible);
1423 if(logicAlPlate)
1424 logicAlPlate->SetVisAttributes(G4VisAttributes::Invisible);
1425 if(logicPD) {
1426 logicPD->SetVisAttributes(G4VisAttributes::Invisible);
1427 logicPD->SetSensitiveDetector(besEMCSD);
1428 }
1429 if(logicPreAmpBox)
1430 logicPreAmpBox->SetVisAttributes(G4VisAttributes::Invisible);
1431 if(logicAirInPABox)
1432 logicAirInPABox->SetVisAttributes(G4VisAttributes::Invisible);
1433 if(logicHangingPlate)
1434 logicHangingPlate->SetVisAttributes(G4VisAttributes::Invisible);
1435 if(logicWaterPipe)
1436 logicWaterPipe->SetVisAttributes(G4VisAttributes::Invisible);
1437
1438 //-------------------------------------------------------------
1439 //Support system
1440 G4VisAttributes* ringVisAtt= new G4VisAttributes(G4Colour(0.5,0.25,0.));
1441 ringVisAtt->SetVisibility(false);
1442 if(logicSupportBar)
1443 logicSupportBar->SetVisAttributes(ringVisAtt);
1444 if(logicSupportBar1)
1445 logicSupportBar1->SetVisAttributes(ringVisAtt);
1446 if(logicEndRing)
1447 logicEndRing->SetVisAttributes(ringVisAtt);
1448 if(logicGear)
1449 logicGear->SetVisAttributes(ringVisAtt);
1450 if(logicTaperRing1)
1451 logicTaperRing1->SetVisAttributes(ringVisAtt);
1452 if(logicTaperRing2)
1453 logicTaperRing2->SetVisAttributes(ringVisAtt);
1454 if(logicTaperRing3)
1455 logicTaperRing3->SetVisAttributes(ringVisAtt);
1456
1457 //-------------------------------------------------------------
1458 //Endcap
1459 G4VisAttributes* endPhiVisAtt= new G4VisAttributes(G4Colour(0,1.0,0));
1460 endPhiVisAtt->SetVisibility(false);
1461 if(logicEnd)
1462 logicEnd->SetVisAttributes(endPhiVisAtt);
1463}

Referenced by Construct().

◆ SetVisAndSD() [2/2]

void BesEmcConstruction::SetVisAndSD ( )

◆ ThreeVectorTrans() [1/2]

void BesEmcConstruction::ThreeVectorTrans ( G4ThreeVector  fPnt[8],
double  x[8],
double  y[8],
double  z[8] 
)

Definition at line 1897 of file BesEmcConstruction.cc.

1898{
1899 for (int i = 0; i < 8; i++) {
1900 x[i] = fPnt[i].x();
1901 y[i] = fPnt[i].y();
1902 z[i] = fPnt[i].z();
1903 }
1904}
Double_t x[10]

◆ ThreeVectorTrans() [2/2]

void BesEmcConstruction::ThreeVectorTrans ( G4ThreeVector  fPnt[8],
double  x[8],
double  y[8],
double  z[8] 
)

◆ TransformToArb8() [1/2]

void BesEmcConstruction::TransformToArb8 ( const G4ThreeVector  fPnt[8],
G4ThreeVector  newfPnt[8],
G4ThreeVector &  center,
G4ThreeVector &  rotAngle 
)

Definition at line 1867 of file BesEmcConstruction.cc.

1868{
1869 HepPoint3D point[8];
1870 center = G4ThreeVector(0.0, 0.0, 0.0);
1871 for (int i = 0; i < 8; i++) {
1872 point[i] = HepPoint3D( fPnt[i].x(), fPnt[i].y(), fPnt[i].z() );
1873 center += point[i];
1874 }
1875 center /= 8.0;
1876
1877 HepPlane3D bottomPlane( point[4], point[5], point[6] );
1878 HepPoint3D centerProject = bottomPlane.point( center );
1879 Hep3Vector newZ = center - centerProject;
1880
1881 rotAngle = RotAngleFromNewZ( newZ );
1882 G4RotationMatrix *g4Rot = new G4RotationMatrix();
1883 g4Rot->rotateX( rotAngle.x() );
1884 g4Rot->rotateY( rotAngle.y() );
1885
1886 G4AffineTransform *transform = new G4AffineTransform( g4Rot, center );
1887 transform->Invert();
1888 for (int i = 0; i < 8; i++) {
1889 newfPnt[i] = transform->TransformPoint(fPnt[i]);
1890 }
1891 delete g4Rot;
1892 delete transform;
1893}
Hep3Vector RotAngleFromNewZ(Hep3Vector newZ)

Referenced by ConstructEndGeometry().

◆ TransformToArb8() [2/2]

void BesEmcConstruction::TransformToArb8 ( const G4ThreeVector  fPnt[8],
G4ThreeVector  newfPnt[8],
G4ThreeVector &  center,
G4ThreeVector &  rotAngle 
)

◆ UpdateGeometry() [1/2]

void BesEmcConstruction::UpdateGeometry ( )

Definition at line 1859 of file BesEmcConstruction.cc.

1860{
1861 ;//G4RunManager::GetRunManager()->DefineWorldVolume(BesDetectorConstruction::Construct());
1862}

Referenced by BesEmcDetectorMessenger::SetNewValue().

◆ UpdateGeometry() [2/2]

void BesEmcConstruction::UpdateGeometry ( )

The documentation for this class was generated from the following files: