BOSS 7.0.8
BESIII Offline Software System
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BesTofDigitizerBrV2 Class Reference

#include <BesTofDigitizerBrV2.hh>

+ Inheritance diagram for BesTofDigitizerBrV2:

Public Member Functions

 BesTofDigitizerBrV2 ()
 
 ~BesTofDigitizerBrV2 ()
 
virtual void Digitize (ScintSingle *, BesTofDigitsCollection *)
 
void ReadData ()
 
void TofPmtInit ()
 
void TofPmtAccum (BesTofHit *, G4int)
 
void DirectPh (G4int, G4ThreeVector, G4double &, G4int &)
 
G4double Scintillation (G4int)
 
G4double TransitTime ()
 
void AccuSignal (G4double, G4int)
 
void TofPmtRspns (G4int)
 
G4double Reflectivity (G4double n1, G4double n2, G4double theta)
 
G4double Reflectivity (G4double n1, G4double n2, G4double n3, G4double theta)
 
G4double BirksLaw (BesTofHit *hit)
 
- Public Member Functions inherited from BesTofDigitizerV
 BesTofDigitizerV ()
 
 ~BesTofDigitizerV ()
 
void Initialize ()
 
virtual void Digitize (ScintSingle *, BesTofDigitsCollection *)
 

Additional Inherited Members

- Protected Attributes inherited from BesTofDigitizerV
BesTofDigitsCollectionm_besTofDigitsCollection
 
BesTofHitsCollectionm_THC
 
ITofCaliSvcm_tofCaliSvc
 
ITofSimSvcm_tofSimSvc
 
ITofQElecSvcm_tofQElecSvc
 
G4double m_ADC [2]
 
G4double m_TDC [2]
 
G4int m_trackIndex
 
G4double m_globalTime
 
- Static Protected Attributes inherited from BesTofDigitizerV
static bool m_booked = false
 
static NTuple::Tuple * m_tupleTof1 = 0
 
static NTuple::Item< double > m_partId
 
static NTuple::Item< double > m_scinNb
 
static NTuple::Item< double > m_edep
 
static NTuple::Item< double > m_nHits
 
static NTuple::Item< double > m_time1st0
 
static NTuple::Item< double > m_time1st1
 
static NTuple::Item< double > m_timelast0
 
static NTuple::Item< double > m_timelast1
 
static NTuple::Item< double > m_totalPhot0
 
static NTuple::Item< double > m_totalPhot1
 
static NTuple::Item< double > m_NphAllSteps
 
static NTuple::Item< double > m_max0
 
static NTuple::Item< double > m_max1
 
static NTuple::Item< double > m_tdc0
 
static NTuple::Item< double > m_adc0
 
static NTuple::Item< double > m_tdc1
 
static NTuple::Item< double > m_adc1
 
static NTuple::Tuple * m_tupleTof2 = 0
 
static NTuple::Item< double > m_eTotal
 
static NTuple::Item< double > m_nDigi
 
static NTuple::Item< double > m_partIdMPV
 
static NTuple::Item< double > m_scinNbMPV
 
static NTuple::Item< double > m_edepMPV
 
static NTuple::Item< double > m_nDigiOut
 
static NTuple::Tuple * m_tupleTof3 = 0
 
static NTuple::Item< double > m_forb
 
static NTuple::Item< double > m_timeFlight
 
static NTuple::Item< double > m_ddT
 
static NTuple::Item< double > m_scinSwim
 
static NTuple::Item< double > m_scinTime
 
static NTuple::Item< double > m_transitTime
 
static NTuple::Item< double > m_endTime
 
static NTuple::Item< double > m_edepHit
 

Detailed Description

Definition at line 34 of file BesTofDigitizerBrV2.hh.

Constructor & Destructor Documentation

◆ BesTofDigitizerBrV2()

BesTofDigitizerBrV2::BesTofDigitizerBrV2 ( )

Definition at line 27 of file BesTofDigitizerBrV2.cc.

28{
29 ReadData();
30 m_timeBinSize=0.005;
31
32 //retrieve G4Svc
33 ISvcLocator* svcLocator = Gaudi::svcLocator();
34 IG4Svc* tmpSvc;
35 StatusCode sc = svcLocator->service("G4Svc", tmpSvc);
36 if(!sc.isSuccess())
37 {
38 std::cout << " Could not initialize Realization Service in BesTofDigitizerBrV2" << std::endl;
39 }
40 else
41 {
42 m_G4Svc = dynamic_cast<G4Svc *>(tmpSvc);
43 }
44
45 //retrieve RealizationSvc
46 IRealizationSvc *tmpReal;
47 StatusCode scReal = svcLocator->service("RealizationSvc",tmpReal);
48 if (!scReal.isSuccess())
49 {
50 std::cout << " Could not initialize Realization Service in BesTofDigitizerBrV2" << std::endl;
51 }
52 else
53 {
54 m_RealizationSvc = dynamic_cast<RealizationSvc*>(tmpReal);
55 }
56
57
58}
Definition: G4Svc.h:32
Definition: IG4Svc.h:30

◆ ~BesTofDigitizerBrV2()

BesTofDigitizerBrV2::~BesTofDigitizerBrV2 ( )

Definition at line 88 of file BesTofDigitizerBrV2.cc.

89{
90 ;
91}

Member Function Documentation

◆ AccuSignal()

void BesTofDigitizerBrV2::AccuSignal ( G4double  endTime,
G4int  forb 
)

Definition at line 750 of file BesTofDigitizerBrV2.cc.

751{
752 G4int ihst;
753 ihst=G4int(endTime/m_timeBinSize);
754 if (ihst>0 &&ihst<m_profBinN)
755 {
756 m_nPhot[ihst][forb]=m_nPhot[ihst][forb]+1;
757 m_totalPhot[forb]=m_totalPhot[forb]+1;
758 }
759}
const G4int m_profBinN

Referenced by TofPmtAccum().

◆ BirksLaw()

G4double BesTofDigitizerBrV2::BirksLaw ( BesTofHit hit)

Definition at line 383 of file BesTofDigitizerBrV2.cc.

384{
385 const G4double kappa = 0.015*cm/MeV;
386 const G4String brMaterial = "BC408";
387 G4double dE = hit->GetEdep();
388 //G4cout << "The edep is "<< dE << G4endl;
389 G4double dX = hit->GetStepL();
390 //G4Material* materiral = hit->GetMaterial();
391 G4double charge = hit->GetCharge();
392 G4double cor_dE = dE;
393 //if((materiral->GetName()==brMaterial) && charge!=0.&& dX!=0.)
394 if(charge!=0.&& dX!=0.)
395 {
396 cor_dE = dE/(1+kappa*dE/dX);
397 //if(dE>20)
398 //{
399 // G4cout << "\n dE > 20. Details are below:" << G4endl;
400 // G4cout << "dE/dx:" << dE/dX << G4endl;
401 // G4cout << "dE:" << dE << "; dX:" << dX << G4endl;
402 // G4cout << "It is BC408. cor_dE is " << cor_dE << G4endl;
403 // G4double ratio = cor_dE/dE;
404 // G4cout << "The ratio cor_dE/edep is "<< ratio << G4endl;
405 //}
406 //G4cout << "It is BC408. cor_dE is " << cor_dE << G4endl;
407 //G4double ratio = cor_dE/dE;
408 //G4cout << "The ratio cor_dE/edep is "<< ratio << G4endl;
409 }
410 return cor_dE;
411
412}
G4double GetStepL()
Definition: BesTofHit.hh:71
G4double GetCharge()
Definition: BesTofHit.hh:80
G4double GetEdep()
Definition: BesTofHit.hh:70
float charge

Referenced by TofPmtAccum().

◆ Digitize()

void BesTofDigitizerBrV2::Digitize ( ScintSingle scint,
BesTofDigitsCollection DC 
)
virtual

Reimplemented from BesTofDigitizerV.

Definition at line 93 of file BesTofDigitizerBrV2.cc.

94{
95 m_beamTime = m_G4Svc->GetBeamTime() * ns;
97
98 G4DigiManager* digiManager = G4DigiManager::GetDMpointer();
99 G4int THCID = digiManager->GetHitsCollectionID("BesTofHitsCollection");
100 m_THC = (BesTofHitsCollection*) (digiManager->GetHitsCollection(THCID));
101
102 if (m_G4Svc->TofRootFlag())
103 {
104 m_eTotal = 0;
105 m_nDigi = 0;
106 m_partIdMPV = -9;
107 m_scinNbMPV = -9;
108 m_edepMPV = 0;
109 m_nDigiOut = 0;
110 }
111
112 if (m_THC)
113 {
114 //for each digi, compute TDC and ADC
115 G4int partId, scinNb, nHits;
116 G4double edep;
117 BesTofHit* hit;
118 partId=scint->GetPartId();
119 scinNb=scint->GetScinNb();
120 edep = scint->GetEdep();
121 nHits=scint->GetHitIndexes()->size();
122
123
124 //std::cout << "BesTofDigitizerBrV2 Partid scinNb " << partId << " " << scinNb << std::endl;
125 //cout << "*** scinNb:" << scinNb << " *** " << m_tofCaliSvc->BAtten(scinNb) << "***" << endl;
126 //cout << "*****scinNb:"<< scinNb << " ***** A2:" << m_tofCaliSvc->BGainBackward(scinNb)
127 // << " ***** A1:" << m_tofCaliSvc->BGainForward(scinNb) << endl;
128
129 TofPmtInit();
130
131 //fill tof Ntuple
132 if (m_G4Svc->TofRootFlag())
133 {
134 if (edep>m_edepMPV)
135 {
136 m_partIdMPV = partId;
137 m_scinNbMPV = scinNb;
138 m_edepMPV = edep;
139 }
140 m_eTotal += edep;
141 m_nDigi ++;
142
143 m_partId = partId;
144 m_scinNb = scinNb;
145 m_edep = edep;
146 m_nHits = nHits;
147 }
148
149 if (edep>0.01)
150 {
151 for (G4int j=0;j<nHits;j++)
152 {
153 hit= (*m_THC)[( *(scint->GetHitIndexes()) )[j]];
154 TofPmtAccum(hit, scinNb);
155 }
156 if (m_G4Svc->TofRootFlag())
157 {
158 m_time1st0=m_t1st[0];
159 m_time1st1=m_t1st[1];
160 m_timelast0=m_tLast[0];
161 m_timelast1=m_tLast[1];
162 m_totalPhot0=m_totalPhot[0];
163 m_totalPhot1=m_totalPhot[1];
164 }
165 //get final tdc and adc
166 TofPmtRspns(scinNb);
167 //G4cout<<"pre-cut " << partId << "\nadc0:"<<m_ADC[0]<<"; adc1:"
168 // <<m_ADC[1]<<"; tdc0:"<<m_TDC[0]<<"; tdc1:"
169 // <<m_TDC[1]<<G4endl;
170
171 G4double temp0 = m_ADC[0]+m_TDC[0];
172 G4double temp1 = m_ADC[1]+m_TDC[1];
173 //cout << "partid: " << partId << " temp0: " << temp0 << " temp1: " << temp1 << endl;
174 //if ( partId==1 && m_ADC[0]>255 && m_ADC[1]>255 && m_TDC[0]>0. && m_TDC[1]>0.)
175 if ( partId==1 && (temp0 > -1998. || temp1 > -1998.))
176 {
177 //const double MAX_ADC = 8191 * 0.3; // channel set up to 8192 will lead to overflow.
178 BesTofDigi* digi = new BesTofDigi;
180 digi->SetPartId(partId);
181 digi->SetScinNb(scinNb);
182 digi->SetForwADC( m_ADC[0]) ;
183 digi->SetBackADC( m_ADC[1]) ;
184 if (m_TDC[0]>0)
185 m_TDC[0] = m_TDC[0]+m_beamTime;
186 if (m_TDC[1]>0)
187 m_TDC[1] = m_TDC[1]+m_beamTime;
188 digi->SetForwTDC( m_TDC[0]) ;
189 digi->SetBackTDC( m_TDC[1]) ;
190 //G4cout<<"+++++++++++++++++++++++++++++barrel\nadc0:"<<m_ADC[0]<<"; adc1:"
191 // <<m_ADC[1]<<"; tdc0:"<<m_TDC[0]<<"; tdc1:"
192 // <<m_TDC[1]<<G4endl;
193
194 m_besTofDigitsCollection->insert(digi);
195
196 if (m_G4Svc->TofRootFlag())
197 m_nDigiOut++;
198
199 }
200 if (m_G4Svc->TofRootFlag())
201 m_tupleTof1->write();
202
203 }
204
205 if (m_G4Svc->TofRootFlag())
206 m_tupleTof2->write();
207 }
208}
G4THitsCollection< BesTofHit > BesTofHitsCollection
Definition: BesTofHit.hh:116
void SetPartId(G4int partId)
Definition: BesTofDigi.hh:37
void SetForwADC(G4double ADC)
Definition: BesTofDigi.hh:40
void SetTrackIndex(G4int index)
Definition: BesTofDigi.hh:36
void SetBackADC(G4double ADC)
Definition: BesTofDigi.hh:41
void SetForwTDC(G4double TDC)
Definition: BesTofDigi.hh:42
void SetScinNb(G4int scinNb)
Definition: BesTofDigi.hh:39
void SetBackTDC(G4double TDC)
Definition: BesTofDigi.hh:43
void TofPmtAccum(BesTofHit *, G4int)
static NTuple::Item< double > m_partId
static NTuple::Item< double > m_eTotal
static NTuple::Item< double > m_timelast1
static NTuple::Item< double > m_timelast0
static NTuple::Item< double > m_scinNb
static NTuple::Tuple * m_tupleTof2
static NTuple::Item< double > m_edep
static NTuple::Item< double > m_totalPhot0
static NTuple::Item< double > m_scinNbMPV
static NTuple::Item< double > m_nDigi
BesTofDigitsCollection * m_besTofDigitsCollection
static NTuple::Item< double > m_nHits
static NTuple::Item< double > m_partIdMPV
static NTuple::Item< double > m_time1st1
static NTuple::Item< double > m_nDigiOut
BesTofHitsCollection * m_THC
static NTuple::Item< double > m_totalPhot1
static NTuple::Tuple * m_tupleTof1
static NTuple::Item< double > m_edepMPV
static NTuple::Item< double > m_time1st0
double GetBeamTime()
Definition: G4Svc.h:85
bool TofRootFlag()
Definition: G4Svc.h:118
G4int GetPartId()
Definition: ScintSingle.hh:44
vector< G4int > * GetHitIndexes()
Definition: ScintSingle.hh:47
G4int GetScinNb()
Definition: ScintSingle.hh:45
G4double GetEdep()
Definition: ScintSingle.hh:46
#define ns(x)
Definition: xmltok.c:1504

Referenced by BesTofDigitizer::Digitize().

◆ DirectPh()

void BesTofDigitizerBrV2::DirectPh ( G4int  partId,
G4ThreeVector  emtPos,
G4double &  pathL,
G4int &  forb 
)

Definition at line 461 of file BesTofDigitizerBrV2.cc.

462{
463 //std::cout << "BesTofDigitizerBrV2::DirectPh()" << std::endl;
464 const static G4double silicon_oil_index = 1.43;
465 const static G4double glass_index = 1.532;
466 //generation photon have random direction
467 //optical parameters of scintillation simulation
468 G4double cos_span=1-cos( asin(silicon_oil_index/m_refIndex) );
469 //G4double cos_spanEc = 1;
470 G4double dcos, ran;
471 ran=G4UniformRand();
472 //assuming uniform phi distribution, simulate cos distr only
473 dcos=cos_span*(ran*2.0-1.0);
474 //G4double dcosEc = cos_spanEc*(ran*2.0-1.0);
475 G4double r2=sqrt(emtPos.x()*emtPos.x()+emtPos.y()*emtPos.y());
476 G4int nRef=0;
477 G4double costheta,sintheta;
478 G4double theta,thetaR; // thetaR is scin to air full ref angle. about 39.265 degree.
479 costheta=dcos>0?(1-dcos):(1+dcos);
480 theta=acos(costheta);
481 sintheta=sin(theta);
482 thetaR=asin(1/m_refIndex);
483 G4double R1;
484 R1=Reflectivity(m_refIndex,1.0,theta);
485 G4double ratio1Mean=(CLHEP::pi)*25.5*25.5/(57.1+60.7)/25.0; //0.693657
486 G4double ratio2Mean=(19.5/25.5)*(19.5/25.5); //0.584775
487 G4double ratio1=G4RandGauss::shoot(ratio1Mean,0.015);
488 G4double ratio2=G4RandGauss::shoot(ratio2Mean,0.015);
489 G4double ratio3Mean=0.945*ratio1Mean*ratio2Mean;
490 G4double ratio3=G4RandGauss::shoot(ratio3Mean,0.015);
491
492 G4double R2=1-Reflectivity(m_refIndex,silicon_oil_index, glass_index, theta);
493 if (dcos > 0 && dcos != 1)
494 {
495 if (theta < thetaR) // theta < 39.265 degree
496 {
497 if (G4UniformRand()<ratio1) //coup1
498 {
499 if (G4UniformRand()<R2)
500 {
501 if (G4UniformRand()<ratio2) //PMT 39mm
502 {
503 forb=0;
504 pathL=(m_scinLength/2-emtPos.z())/costheta;
505 }
506 }
507 else
508 {
509 if (G4UniformRand()<ratio3)
510 {
511 forb=1;
512 pathL=(1.5*m_scinLength-emtPos.z())/costheta;
513 }
514 }
515 }
516 else //Air
517 {
518 if (G4UniformRand()<R1)
519 {
520 G4double tempran=G4UniformRand();
521 if (tempran<ratio3)
522 {
523 forb=1;
524 pathL=(1.5*m_scinLength-emtPos.z())/costheta;
525 }
526 else if (tempran>ratio1&&G4UniformRand()<R1&&G4UniformRand()<ratio3)
527 {
528 forb=0;
529 pathL=(2.5*m_scinLength-emtPos.z())/costheta;
530 }
531 }
532 }
533 }
534 else // 39.265 <= theta < 64.832
535 {
536 if (G4UniformRand()<ratio1) //coup1
537 {
538 if (G4UniformRand()<R2)
539 {
540 if (G4UniformRand()<ratio2) //PMT 39mm
541 {
542 forb=0;
543 pathL=(m_scinLength/2-emtPos.z())/costheta;
544 }
545 }
546 else
547 {
548 if (G4UniformRand()<ratio3)
549 {
550 forb=1;
551 pathL=(1.5*m_scinLength-emtPos.z())/costheta;
552 }
553 }
554 }
555 else //Air
556 {
557 G4double tempran=G4UniformRand();
558 if (tempran<ratio3)
559 {
560 forb=1;
561 pathL=(1.5*m_scinLength-emtPos.z())/costheta;
562 }
563 else if (tempran>ratio1 && G4UniformRand()<ratio3)
564 {
565 forb=0;
566 pathL=(2.5*m_scinLength-emtPos.z())/costheta;
567 }
568 }
569 }
570 }
571 else if (dcos < 0 && dcos != -1)
572 {
573 if (theta < thetaR) // theta < 39.265 degree
574 {
575 if (G4UniformRand()<ratio1) //coup1
576 {
577 if (G4UniformRand()<R2)
578 {
579 if (G4UniformRand()<ratio2) //PMT 39mm
580 {
581 forb=1;
582 pathL=(m_scinLength/2+emtPos.z())/costheta;
583 }
584 }
585 else
586 {
587 if (G4UniformRand()<ratio3)
588 {
589 forb=0;
590 pathL=(1.5*m_scinLength+emtPos.z())/costheta;
591 }
592 }
593 }
594 else //Air
595 {
596 if (G4UniformRand()<R1)
597 {
598 G4double tempran=G4UniformRand();
599 if (tempran<ratio3)
600 {
601 forb=0;
602 pathL=(1.5*m_scinLength+emtPos.z())/costheta;
603 }
604 else if (tempran>ratio1&&G4UniformRand()<R1&&G4UniformRand()<ratio3)
605 {
606 forb=1;
607 pathL=(2.5*m_scinLength+emtPos.z())/costheta;
608 }
609 }
610 }
611 }
612 else // 39.265 <= theta < 64.832
613 {
614 if (G4UniformRand()<ratio1) //coup1
615 {
616 if (G4UniformRand()<R2)
617 {
618 if (G4UniformRand()<ratio2) //PMT 39mm
619 {
620 forb=1;
621 pathL=(m_scinLength/2+emtPos.z())/costheta;
622 }
623 }
624 else
625 {
626 if (G4UniformRand()<ratio3)
627 {
628 forb=0;
629 pathL=(1.5*m_scinLength+emtPos.z())/costheta;
630 }
631 }
632 }
633 else //Air
634 {
635 G4double tempran=G4UniformRand();
636 if (tempran<ratio3)
637 {
638 forb=0;
639 pathL=(1.5*m_scinLength+emtPos.z())/costheta;
640 }
641 else if (tempran>ratio1 && G4UniformRand()<ratio3)
642 {
643 forb=1;
644 pathL=(2.5*m_scinLength+emtPos.z())/costheta;
645 }
646 }
647 }
648 }
649
650 G4double convFactor=180./3.1415926;
651 if (theta>asin(1)-thetaR)
652 {
653 G4double alpha = G4UniformRand()*asin(1.);
654 G4int nRef1 = pathL*sintheta*cos(alpha)/50.0+0.5;
655 G4int nRef2 = pathL*sintheta*sin(alpha)/58.9+0.5;
656 G4double beta1=acos(sintheta*cos(alpha));
657 G4double beta2=acos(sintheta*sin(alpha));
658 beta2 -= 3.75/convFactor;
659 G4double R21,R22;
660 R21=Reflectivity(m_refIndex,1.0,beta1);
661 R22=Reflectivity(m_refIndex,1.0,beta2);
662 for (G4int i=0;i<nRef1;i++)
663 {
664 if (G4UniformRand()<(1-R21) && G4UniformRand()<0.15)
665 pathL=-9;
666 }
667 for (G4int i=0;i<nRef2;i++)
668 {
669 if (G4UniformRand()<(1-R22) && G4UniformRand()<0.15)
670 pathL=-9;
671 }
672 }
673}
double sin(const BesAngle a)
Definition: BesAngle.h:210
double cos(const BesAngle a)
Definition: BesAngle.h:213
const double alpha
G4double Reflectivity(G4double n1, G4double n2, G4double theta)
float costheta

Referenced by TofPmtAccum().

◆ ReadData()

void BesTofDigitizerBrV2::ReadData ( )

Definition at line 60 of file BesTofDigitizerBrV2.cc.

61{
63
64 m_scinLength = tofPara->GetBr1L();
65 m_tau1 = tofPara->GetTau1();
66 m_tau2 = tofPara->GetTau2();
67 m_tau3 = tofPara->GetTau3();
68 m_tauRatio = tofPara->GetTauRatio();
69 m_refIndex = tofPara->GetRefIndex();
70 m_phNConst = tofPara->GetPhNConst();
71 m_Cpe2pmt = tofPara->GetCpe2pmt();
72 m_rAngle = tofPara->GetRAngle();
73 m_QE = tofPara->GetQE();
74 m_CE = tofPara->GetCE();
75 m_peCorFac = tofPara->GetPeCorFac();
76
77 m_ttsMean = tofPara->GetTTSmean();
78 m_ttsSigma = tofPara->GetTTSsigma();
79 m_Ce = tofPara->GetCe();
80 m_LLthresh = tofPara->GetLLthresh();
81 m_HLthresh = tofPara->GetHLthresh();
82 m_preGain = tofPara->GetPreGain();
83 m_noiseSigma = tofPara->GetNoiseSigma();
84
85
86}
static BesTofGeoParameter * GetInstance()

Referenced by BesTofDigitizerBrV2().

◆ Reflectivity() [1/2]

G4double BesTofDigitizerBrV2::Reflectivity ( G4double  n1,
G4double  n2,
G4double  n3,
G4double  theta 
)

Definition at line 414 of file BesTofDigitizerBrV2.cc.

415{
416 G4double I1,I2,I3,rp1,rs1,rp2,rs2,Rp1,Rs1,Rp2,Rs2,Rp,Rs;
417 G4double R=1.0;
418 //n1=m_refIndex;
419 //n2=1.0;
420 I1=theta;
421 if(I1<asin(n2/n1))
422 {
423 I2=asin(sin(I1)*(n1/n2));
424 rp1=(n1/cos(I1)-n2/cos(I2))/(n1/cos(I1)+n2/cos(I2));
425 rs1=(n1*cos(I1)-n2*cos(I2))/(n1*cos(I1)+n2*cos(I2));
426 Rp1=rp1*rp1;
427 Rs1=rs1*rs1;
428
429 I3=asin(sin(I1)*(n1/n3));
430 rp2=(n2/cos(I2)-n3/cos(I3))/(n2/cos(I2)+n3/cos(I3));
431 rs2=(n2*cos(I2)-n3*cos(I3))/(n2*cos(I2)+n3*cos(I3));
432 Rp2=rp2*rp2;
433 Rs2=rs2*rs2;
434 Rp=(Rp1+Rp2-2*Rp1*Rp2)/(1-Rp1*Rp2);
435 Rs=(Rs1+Rs2-2*Rs1*Rs2)/(1-Rs1*Rs2);
436 R=(Rp+Rs)/2.;
437 }
438 return R;
439}
int n2
Definition: SD0Tag.cxx:55
int n1
Definition: SD0Tag.cxx:54
complex_t R(double Q2, double M2, double G, double Mp2, double Mm2)
Definition: TUtil.h:27

◆ Reflectivity() [2/2]

G4double BesTofDigitizerBrV2::Reflectivity ( G4double  n1,
G4double  n2,
G4double  theta 
)

Definition at line 442 of file BesTofDigitizerBrV2.cc.

443{
444 G4double I1,I2,rp,rs,Rp,Rs;
445 G4double R=1.0;
446 //n1=m_refIndex;
447 //n2=1.0;
448 I1=theta;
449 if (I1<asin(n2/n1))
450 {
451 I2=asin(sin(I1)*(n1/n2));
452 rp=(n1/cos(I1)-n2/cos(I2))/(n1/cos(I1)+n2/cos(I2));
453 rs=(n1*cos(I1)-n2*cos(I2))/(n1*cos(I1)+n2*cos(I2));
454 Rp=rp*rp;
455 Rs=rs*rs;
456 R=(Rp+Rs)/2.;
457 }
458 return R;
459}

Referenced by DirectPh().

◆ Scintillation()

G4double BesTofDigitizerBrV2::Scintillation ( G4int  partId)

Definition at line 697 of file BesTofDigitizerBrV2.cc.

698{
699 G4double tmp_tauRatio,tmp_tau1,tmp_tau2,tmp_tau3;
700 tmp_tauRatio = m_tauRatio;
701 tmp_tau1 = m_tau1;
702 tmp_tau2 = m_tau2;
703 tmp_tau3 = m_tau3;
704 G4double UniformR = tmp_tauRatio/(1+tmp_tauRatio);
705 G4double EmissionTime;
706 if (G4UniformRand()>UniformR) {
707 while (1) {
708 EmissionTime = -tmp_tau2*log( G4UniformRand() );
709 if (G4UniformRand()-exp(EmissionTime/tmp_tau2-EmissionTime/tmp_tau1)>1.E-8)
710 break;
711 }
712 }
713 else EmissionTime = -tmp_tau3*log( G4UniformRand() );
714 return EmissionTime;
715}
EvtComplex exp(const EvtComplex &c)
Definition: EvtComplex.hh:252

Referenced by TofPmtAccum().

◆ TofPmtAccum()

void BesTofDigitizerBrV2::TofPmtAccum ( BesTofHit hit,
G4int  scinNb 
)

Definition at line 246 of file BesTofDigitizerBrV2.cc.

247{
249 //std::cout << "BesTofDigitizerBrV2::TofPmtAccum()" << std::endl;
250 G4double cvelScint=c_light/m_refIndex/1.07;
251 //Get information of this step
252 G4ThreeVector pos=hit->GetPos();
253 G4int trackIndex = hit->GetTrackIndex();
254 G4int partId =hit->GetPartId();
255 G4double edep=hit->GetEdep();
256 G4double stepL=hit->GetStepL();
257 G4double deltaT=hit->GetDeltaT();
258 G4double timeFlight=hit->GetTime()-m_beamTime;
259 //std::cout << "timeFlight: " << timeFlight << std::endl;
260 if (timeFlight < m_globalTime)
261 {
262 m_globalTime = timeFlight;
263 m_trackIndex = trackIndex;
264 }
265
266 G4ThreeVector pDirection=hit->GetPDirection();
267 G4double nx=pDirection.x();
268 G4double ny=pDirection.y();
269 G4double nz=pDirection.z();
270
271 //phNConst=(Nph/MeV)*(QE)*(CE)*(1-cos(crit));
272 // =10000 * 0.2 * 0.6 * (1-cos(39.265))=270.931
273 //asin(1/1.58) = 39.265248
274 //only the light has theta=0---39.265 can go out to PMT, the probability is computed with solid angle
275 //solid angle = phi*(1-cos(theta)), phi=2pi
276
277 //Cpe2pmt=cathode area/scint area
278 //peCorFac=correction factor for eff. of available Npe
279
280 //G4double thetaProb = 1-sqrt(m_refIndex*m_refIndex-1)/m_refIndex;
281 G4double thetaProb=1-cos( asin(1.43/m_refIndex));
282 //G4double thetaProbEc = 1-1/m_refIndex;
283
284 //number of photons generated in this step
285 G4double nMean, nPhoton;
286 //std::cout << "0 BirksLaw(): " << std::endl;
287 nMean = m_phNConst*BirksLaw(hit);
288 G4int runId = m_RealizationSvc->getRunId();
289 if( ( runId>=-11396 && runId<=-8093 ) || ( runId>-80000 && runId<=-23463 ) ) {
290 nMean = 9000.0*BirksLaw(hit);
291 }
292 //std::cout << "1 BirksLaw(): " << std::endl;
293
294 if(nMean>10)
295 {
296 G4double resolutionScale=1.;
297 G4double sigma=resolutionScale*sqrt(nMean);
298 nPhoton=G4int(G4RandGauss::shoot(nMean,sigma)+0.5);
299 }
300 else
301 nPhoton=G4int(G4Poisson(nMean));
302 //G4cout<<"nPhoton:"<<nPhoton<<G4endl;
303
304 G4int NphStep;
305 if (partId==1)
306 NphStep=G4int(nPhoton*thetaProb*m_rAngle*m_QE*m_CE*m_peCorFac);
307 //else
308 //NphStep=G4int(edep*m_phNConstEc*m_Cpe2pmtEc*0.66*m_QEEc*m_CE*m_peCorFac);
309 //introduce poission distribution of Npe
310 //G4double Navr = NphStep;
311 //G4double NpePoiss = G4double(G4Poisson(Navr));
312 //G4double adcW_corr =5.0;
313 //NphStep=G4int( (NpePoiss - Navr)*adcW_corr + Navr );
314
315 if (m_G4Svc->TofRootFlag())
316 m_NphAllSteps += NphStep;
317 //std::cout << "m_G4Svc->TofRootFlag(): " << m_G4Svc->TofRootFlag() << std::endl;
318
319 G4double ddS, ddT;
320 if (NphStep>0)
321 {
322 for (G4int i=0;i<NphStep;i++)
323 {
324 //uniform scintilation in each step
325 ddS=stepL*G4UniformRand();
326 ddT=deltaT*G4UniformRand();
327 G4ThreeVector emtPos;
328 emtPos.setX(pos.x() + nx*ddS);
329 emtPos.setY(pos.y() + ny*ddS);
330 emtPos.setZ(pos.z() + nz*ddS);
331
332 //check scinillation light whether to hit the pmt or not
333 //forb=0/1 for forward(z>0, east) and backward(z<0, west)
334 G4double pathL=0;
335 G4int forb;
336 DirectPh(partId, emtPos, pathL, forb);
337
338
339 //check if photon can reach PMT or not, after attenuation
340
341 G4double ran = G4UniformRand();
342 //G4double attenL = tofPara->GetAtten(scinNb);
343 //G4double attenL = 10.*(m_tofCaliSvc->BAtten(scinNb))/0.75; // cm into mm
344 G4double attenL = m_tofSimSvc->BarAttenLength(scinNb);
345 attenL = 10.*attenL/0.75; // cm into mm
346
347 if (pathL>0 && exp(-pathL/attenL) > ran)
348 {
349 //propagation time in scintillator
350 G4double scinSwim=pathL/cvelScint;
351 //scintillation timing
352 //G4double scinTime=GenPhoton(partId);
353 G4double scinTime=Scintillation(partId);
354
355 //PMT transit time
356 G4double transitTime=TransitTime();
357 //sum up all time components
358 G4double endTime= timeFlight + ddT + scinSwim + scinTime + transitTime;
359 //std::cout << "endtime: " << endTime << std::endl;
360
361 if (m_G4Svc->TofRootFlag())
362 {
363 //m_forb = forb;
364 //m_timeFlight = timeFlight;
365 //m_ddT = ddT;
366 m_scinSwim = scinSwim;
367 //m_scinTime = scinTime;
368 //m_transitTime = transitTime;
369 m_endTime = endTime;
370 m_tupleTof3->write();
371 }
372 //store timing into binned buffer
373 AccuSignal(endTime, forb);
374
375 //update 1st and last timings here
376 if (m_t1st[forb]>endTime) m_t1st[forb] = endTime;
377 if (m_tLast[forb]<endTime) m_tLast[forb]= endTime;
378 }
379 }
380 }
381}
TTree * sigma
void AccuSignal(G4double, G4int)
G4double Scintillation(G4int)
void DirectPh(G4int, G4ThreeVector, G4double &, G4int &)
G4double BirksLaw(BesTofHit *hit)
static NTuple::Tuple * m_tupleTof3
static NTuple::Item< double > m_NphAllSteps
static NTuple::Item< double > m_scinSwim
static NTuple::Item< double > m_endTime
ITofSimSvc * m_tofSimSvc
G4double GetDeltaT()
Definition: BesTofHit.hh:75
G4ThreeVector GetPDirection()
Definition: BesTofHit.hh:76
G4double GetTime()
Definition: BesTofHit.hh:74
G4ThreeVector GetPos()
Definition: BesTofHit.hh:73
G4int GetPartId()
Definition: BesTofHit.hh:68
G4int GetTrackIndex()
Definition: BesTofHit.hh:66
virtual const double BarAttenLength(unsigned int id)=0

Referenced by Digitize().

◆ TofPmtInit()

void BesTofDigitizerBrV2::TofPmtInit ( )

Definition at line 210 of file BesTofDigitizerBrV2.cc.

211{
212 Initialize();
213
214 m_t1st[0]=100;
215 m_t1st[1]=100;
216 m_tLast[0]=0.;
217 m_tLast[1]=0;
218 m_totalPhot[0]=0;
219 m_totalPhot[1]=0;
220 for (G4int i=0;i<2;i++)
221 for (G4int j=0;j<m_profBinN;j++)
222 m_nPhot[j][i]=0;
223
224 if (m_G4Svc->TofRootFlag())
225 {
226 m_partId = -9;
227 m_scinNb = -9;
228 m_edep = 0;
229 m_nHits = 0;
230 m_time1st0 = 100;
231 m_time1st1 = 100;
232 m_timelast0 = 0;
233 m_timelast1 = 0;
234 m_totalPhot0 = 0;
235 m_totalPhot1 = 0;
236 m_NphAllSteps = 0;
237 m_max0 = 0;
238 m_max1 = 0;
239 m_tdc0 = -999;
240 m_adc0 = -999;
241 m_tdc1 = -999;
242 m_adc1 = -999;
243 }
244}
static NTuple::Item< double > m_tdc1
static NTuple::Item< double > m_max0
static NTuple::Item< double > m_tdc0
static NTuple::Item< double > m_adc1
static NTuple::Item< double > m_adc0
static NTuple::Item< double > m_max1

Referenced by Digitize().

◆ TofPmtRspns()

void BesTofDigitizerBrV2::TofPmtRspns ( G4int  scinNb)

Definition at line 761 of file BesTofDigitizerBrV2.cc.

762{
763 //std::cout << "BesTofDigitizerBrV2::TofPmtRspns()" << std::endl;
765 //to generate PMT signal shape for single photoelectron.
766 //only one time for a job.
767 G4double snpe[m_snpeBinN][2];
768
769 //Model: f(t)=Gain*mv_1pe* t**2 * exp-(t/tau)**2/normal-const
770 //normalization const =sqrt(pi)*tau*tau*tau/4.0
771 //G4double tau = m_riseTime;
772 G4double norma_const;
773 G4double echarge=1.6e-7; //in unit of PC
774
775 //time profile of pmt signals for Back and Forward PMT.
776 G4double profPmt[m_profBinN][2];
777
778 G4double t;
779 G4double tau;
780 G4int n1, n2, ii;
781 G4int phtn;
782 // forb = 0, east
783 for (G4int i=0;i<m_snpeBinN;i++)
784 {
785 tau = tofPara->GetBrERiseTime(scinNb);
786 norma_const = sqrt(CLHEP::pi)*tau*tau*tau/4.0; //in unit of ns**3
787 t = (i+1)*m_timeBinSize;
788 snpe[i][0] = m_Ce*t*t*exp(- (t/tau) * (t/tau) )/norma_const;// Pulse of one single photoelectron
789 }
790 // forb = 1, west
791 for (G4int i=0;i<m_snpeBinN;i++)
792 {
793 tau = tofPara->GetBrWRiseTime(scinNb);
794 norma_const = sqrt(CLHEP::pi)*tau*tau*tau/4.0; //in unit of ns**3
795 t = (i+1)*m_timeBinSize;
796 snpe[i][1] = m_Ce*t*t*exp(- (t/tau) * (t/tau) )/norma_const;
797 }
798 //for barrel and endcap tof: fb=2 or 1
799 G4int fb=2;
800 G4double Npoisson;
801 G4double pmtGain0,pmtGain,relativeGain,smearPMTgain;
802 G4double smearADC[2] = {0.,0.};
803 G4int runId = m_RealizationSvc->getRunId();
804 pmtGain0 = m_tofSimSvc->BarPMTGain();
805
806// if(runId>=-80000 && runId<=-9484)
807// {
808// // After TOF HV adjustment, PMT Gain of barrel TOF in MC is set to 5.E5
809// // High/Low Threshold for barrel: 500/125 mV
810// pmtGain0 = 6.E5;
811// }
812// else
813// {
814// // Before TOF HV adjustment, PMT Gain of barrel TOF in MC is set to 2.5E5
815// // High/Low Threshold for barrel: 600/150 mV
816// pmtGain0 = 5.E5;
817// }
818
819 G4double timeSmear = G4RandGauss::shoot(0,0.020);
820 if (runId>=-22913 && runId<=-20448) {//for 2011-psipp(20448-22913), smear barrel TOF resolution to ~78ps
821 timeSmear = G4RandGauss::shoot(0,0.040);
822 }
823 else if( ( runId>=-11396 && runId<=-8093 ) || ( runId>-80000 && runId<=-23463 ) ) {
824 timeSmear = G4RandGauss::shoot(0,0.025);
825 }
826
827 for (G4int j=0; j<fb; j++)
828 {
829 if (m_totalPhot[j] > 0)
830 {
831 n1=G4int(m_t1st[j]/m_timeBinSize);
832 n2=G4int(m_tLast[j]/m_timeBinSize);
833 //std::cout << "n1: " << n1 << std::endl;
834
835 for (G4int i=0;i<m_profBinN;i++)
836 profPmt[i][j]=0.0;
837
838 //generate PMT pulse
840 for (G4int i=n1;i<n2;i++)
841 {
842 phtn=m_nPhot[i][j];
843 if (phtn>0)
844 {
845 while(1) {
846 Npoisson = G4Poisson(10.0);
847 if(Npoisson>0.) break;
848 }
849 while(1) {
850 //pmtGain = j ? tofPara->GetBrWPMTgain(scinNb) : tofPara->GetBrEPMTgain(scinNb);
851 //relativeGain = j ? m_tofCaliSvc->BGainBackward(scinNb) : m_tofCaliSvc->BGainForward(scinNb);
852 relativeGain = j ? m_tofSimSvc->BarGain2(scinNb) : m_tofSimSvc->BarGain1(scinNb);
853 pmtGain = pmtGain0*relativeGain;
854 smearPMTgain = G4RandGauss::shoot(pmtGain,pmtGain/sqrt(Npoisson));
855 //smearPMTgain = pmtGain;
856 if(smearPMTgain>0) break;
857 }
858 smearADC[j] += phtn*smearPMTgain;
859
860 for (G4int ihst=0; ihst<m_snpeBinN; ihst++)
861 {
862 ii=i+ihst;
863 if (ii<m_profBinN)
864 profPmt[ii][j] += smearPMTgain*phtn*snpe[ihst][j];
865 else
866 break;
867 }
868 }
869 }
870
871 //add preamplifier and noise
872 for (int i=0;i<m_profBinN;i++)
873 {
874 if (profPmt[i][j]>0)
875 profPmt[i][j] = m_preGain*profPmt[i][j]+G4RandGauss::shoot(0,m_noiseSigma);
876 }
877
878 //get pulse height
879 G4double max=0;
880 for (int i=n1;i<m_profBinN;i++)
881 {
882 if (profPmt[i][j]>max)
883 max=profPmt[i][j];
884 }
885 if (m_G4Svc->TofRootFlag())
886 {
887 if (j==0) m_max0=max;
888 else m_max1=max;
889 }
890
891 G4double tmp_HLthresh, tmp_LLthresh, adcFactor;
892 G4double ratio;
893
894 if(runId>=-80000 && runId<=-9484)
895 {
896 // After TOF HV adjustment, PMT Gain of barrel TOF in MC is set to 5.E5
897 // High/Low Threshold for barrel: 500/125 mV
898 tmp_HLthresh = m_HLthresh;
899 tmp_LLthresh = m_LLthresh;
900 adcFactor = 5.89;
901 }
902 else
903 {
904 // Before TOF HV adjustment, PMT Gain of barrel TOF in MC is set to 2.5E5
905 // High/Low Threshold for barrel: 600/150 mV
906 tmp_HLthresh = 600;
907 tmp_LLthresh = 150;
908 adcFactor = 4.8;
909 }
910// if(runId>=-80000 && runId<=-9484)
911// {
912// ratio=2.16*1923.8/2197.8;
913// }
914// else
915// {
916// ratio = 2.11*2437.0/3102.9;
917// }
918 tmp_HLthresh = m_tofSimSvc->BarHighThres();
919 tmp_LLthresh = m_tofSimSvc->BarLowThres();
920 ratio = m_tofSimSvc->BarConstant();
921
922 //get final tdc and adc
923 if (max>=tmp_HLthresh)
924 {
925 for (int i=0;i<m_profBinN;i++)
926 {
927 if ( profPmt[i][j] >= tmp_LLthresh )
928 {
929 m_TDC[j] = i*m_timeBinSize + timeSmear +G4RandGauss::shoot(0,0.025); // Adding Electronical Uncertainty of 25ps
930// hhliu 20140724, setting tdc-smear for inner and outer separately
931 if( ( runId>=-11396 && runId<=-8093 ) || ( runId>-80000 && runId<=-23463 ) ) {
932 if( scinNb<88 ) {
933 m_TDC[j] = i*m_timeBinSize + timeSmear +G4RandGauss::shoot(0,0.055);
934 }
935 else {
936 m_TDC[j] = i*m_timeBinSize + timeSmear +G4RandGauss::shoot(0,0.062);
937 }
938 }
939
940 if( m_G4Svc->TofSaturationFlag())
941 {
942 //get ADC[j] using tofQElecSvc
943 double x = m_preGain*smearADC[j]*echarge*ratio;
944 if (j==0)
945 {
946 m_ADC[j] = m_tofQElecSvc->BQChannel1(scinNb,x);
947 }
948 else
949 {
950 m_ADC[j] = m_tofQElecSvc->BQChannel2(scinNb,x);
951 }
952 }
953 else
954 m_ADC[j] = m_preGain*smearADC[j]*echarge*adcFactor;
955
956
957 if (m_G4Svc->TofRootFlag())
958 {
959 if (j==0) {
960 m_tdc0 = m_TDC[0];
961 m_adc0 = m_ADC[0];
962 }
963 else {
964 m_tdc1 = m_TDC[1];
965 m_adc1 = m_ADC[1];
966 }
967 }
968 break;
969 }
970 }
971 }
972 }
973 }
974}
const G4int m_snpeBinN
Double_t x[10]
TTree * t
Definition: binning.cxx:23
ITofQElecSvc * m_tofQElecSvc
G4double GetBrWRiseTime(int scinNb)
G4double GetBrERiseTime(int scinNb)
bool TofSaturationFlag()
Definition: G4Svc.h:122
virtual const double BQChannel2(int id, double q)=0
virtual const double BQChannel1(int id, double q)=0
virtual const double BarConstant()=0
virtual const double BarLowThres()=0
virtual const double BarPMTGain()=0
virtual const double BarGain2(unsigned int id)=0
virtual const double BarHighThres()=0
virtual const double BarGain1(unsigned int id)=0

Referenced by Digitize().

◆ TransitTime()

G4double BesTofDigitizerBrV2::TransitTime ( )

Definition at line 744 of file BesTofDigitizerBrV2.cc.

745{
746 //get time transit spread
747 return G4RandGauss::shoot(m_ttsMean,m_ttsSigma);
748}

Referenced by TofPmtAccum().


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