[u/mrichter/AliRoot.git] / RICH / AliRICHChamber.cxx

/**************************************************************************
 * Copyright(c) 1998-1999, ALICE Experiment at CERN, All rights reserved. *
 *                                                                        *
 * Author: The ALICE Off-line Project.                                    *
 * Contributors are mentioned in the code where appropriate.              *
 *                                                                        *
 * Permission to use, copy, modify and distribute this software and its   *
 * documentation strictly for non-commercial purposes is hereby granted   *
 * without fee, provided that the above copyright notice appears in all   *
 * copies and that both the copyright notice and this permission notice   *
 * appear in the supporting documentation. The authors make no claims     *
 * about the suitability of this software for any purpose. It is          *
 * provided "as is" without express or implied warranty.                  *
 **************************************************************************/

#include "AliRICHChamber.h"
#include "AliRICHConst.h" //for kR2d
#include "AliRICHParam.h"
#include <TRandom.h>
#include <TRotMatrix.h>
#include "AliRICHTresholdMap.h"
#include "AliSegmentation.h"
#include "AliRICHSegmentationV0.h"
#include "AliRICHGeometry.h"
#include "AliRICHResponse.h"

ClassImp(AliRICHChamber)	
//______________________________________________________________________________    
AliRICHChamber::AliRICHChamber() 
{//default ctor
  fpParam=0;    
  fpRotMatrix=0;
  
    fSegmentation = 0;
    fResponse = 0;
    fGeometry = 0;
    fTresh = 0;
    for(Int_t i=0; i<50; ++i) fIndexMap[i] = 0;
}
//______________________________________________________________________________
AliRICHChamber::AliRICHChamber(Int_t iModuleN,AliRICHParam *pParam)
{//main ctor. Defines all geometry parameters for the given module.
  SetToZenith();//put to up position   
  switch(iModuleN){
    case 1:
      RotateX(-pParam->AngleYZ());   
      RotateZ(-pParam->AngleXY());      
      fName="RICHc1";fTitle="RICH chamber 1";
      break;      
    case 2:
      RotateZ(-pParam->AngleXY());      
      fName="RICHc2";fTitle="RICH chamber 2";
      break;      
    case 3:
      RotateX(-pParam->AngleYZ());
      fName="RICHc3";fTitle="RICH chamber 3";
      break;      
    case 4:          
      fName="RICHc4";fTitle="RICH chamber 4";  //no turns
      break;      
    case 5:
      RotateX(pParam->AngleYZ());
      fName="RICHc5";fTitle="RICH chamber 5";
      break;      
    case 6:
      RotateZ(pParam->AngleXY());      
      fName="RICHc6";fTitle="RICH chamber 6";
      break;      
    case 7:
      RotateX(pParam->AngleYZ());            
      RotateZ(pParam->AngleXY());      
      fName="RICHc7";fTitle="RICH chamber 7";
      break;      
    default:
      Fatal("named ctor","Wrong chamber number %i, check CreateChamber ctor",iModuleN);
  }//switch(iModuleN)
  RotateZ(pParam->AngleRot());//apply common rotation  
  fpRotMatrix=new TRotMatrix("rot"+fName,"rot"+fName, Rot().ThetaX()*kR2d, Rot().PhiX()*kR2d,
                                                      Rot().ThetaY()*kR2d, Rot().PhiY()*kR2d,
                                                      Rot().ThetaZ()*kR2d, Rot().PhiZ()*kR2d);
  fpParam=pParam;
  fX=fCenterV3.X();fY=fCenterV3.Y();fZ=fCenterV3.Z();
  
  fSegmentation = 0;  fResponse = 0;    fGeometry = 0;
  fTresh = 0;    for(Int_t i=0; i<50; ++i) fIndexMap[i] = 0;
}
//______________________________________________________________________________

void AliRICHChamber::LocaltoGlobal(Float_t local[3],Float_t global[3])
{//Local coordinates to global coordinates transformation

    Double_t *pMatrix;
    pMatrix =  fpRotMatrix->GetMatrix();
    global[0]=local[0]*pMatrix[0]+local[1]*pMatrix[3]+local[2]*pMatrix[6];
    global[1]=local[0]*pMatrix[1]+local[1]*pMatrix[4]+local[2]*pMatrix[7];
    global[2]=local[0]*pMatrix[2]+local[1]*pMatrix[5]+local[2]*pMatrix[8];
    global[0]+=fX;
    global[1]+=fY;
    global[2]+=fZ;
}

void AliRICHChamber::GlobaltoLocal(Float_t global[3],Float_t local[3])
{// Global coordinates to local coordinates transformation
    TMatrix matrixCopy(3,3);
    Double_t *pMatrixOrig = fpRotMatrix->GetMatrix();
    for(Int_t i=0;i<3;i++)
      {
	for(Int_t j=0;j<3;j++)
	  matrixCopy(j,i)=pMatrixOrig[j+3*i];
      }
    matrixCopy.Invert();
    local[0] = global[0] - fX;
    local[1] = global[1] - fY;
    local[2] = global[2] - fZ;
    local[0]=local[0]*matrixCopy(0,0)+local[1]*matrixCopy(0,1)+local[2]*matrixCopy(0,2);
    local[1]=local[0]*matrixCopy(1,0)+local[1]*matrixCopy(1,1)+local[2]*matrixCopy(1,2);
    local[2]=local[0]*matrixCopy(2,0)+local[1]*matrixCopy(2,1)+local[2]*matrixCopy(2,2);
} 

void AliRICHChamber::DisIntegration(Float_t eloss, Float_t xhit, Float_t yhit,
				    Int_t& iNpads,Float_t cluster[5][500],ResponseType res) 
{//Generates pad hits (simulated cluster) using the segmentation and the response model

  Float_t local[3],global[3];
// Width of the integration area
  Float_t dx=(fResponse->SigmaIntegration())*(fResponse->ChargeSpreadX());
  Float_t dy=(fResponse->SigmaIntegration())*(fResponse->ChargeSpreadY());
// Get pulse height from energy loss and generate feedback photons
  Float_t qtot=0;
  local[0]=xhit;
//z-position of the wires relative to the RICH mother volume (2 mm before CsI) old value: 6.076 ???????
  local[1]=1.276 + fGeometry->GetGapThickness()/2  - .2;
  local[2]=yhit;

  LocaltoGlobal(local,global);


//To calculate wire sag, the origin of y-position must be the middle of the photcathode
  AliRICHSegmentationV0* segmentation = (AliRICHSegmentationV0*) GetSegmentationModel();
  Float_t newy;
  if (yhit>0)
    newy = yhit - segmentation->GetPadPlaneLength()/2;
  else
    newy = yhit + segmentation->GetPadPlaneLength()/2;

  if(res==kMip){
    qtot = fResponse->IntPH(eloss, newy);
    fResponse->FeedBackPhotons(global,qtot);
  }else if(res==kPhoton){
    qtot = fResponse->IntPH(newy);
    fResponse->FeedBackPhotons(global,qtot);
  }

    // Loop Over Pads

  Float_t qcheck=0, qp=0;

  iNpads=0;
  for(fSegmentation->FirstPad(xhit, yhit, 0, dx, dy); fSegmentation->MorePads(); fSegmentation->NextPad()) {
    qp= fResponse->IntXY(fSegmentation);
    qp= TMath::Abs(qp);
    if(qp >1.e-4){
      qcheck+=qp;
      cluster[0][iNpads]=qp*qtot;// --- store signal information
      cluster[1][iNpads]=fSegmentation->Ix();
      cluster[2][iNpads]=fSegmentation->Iy();
      cluster[3][iNpads]=fSegmentation->ISector();
      iNpads++;
    }
  }//pad loop
}//void AliRICHChamber::DisIntegration(...
//__________________________________________________________________________________________________
void AliRICHChamber::GenerateTresholds()
{//Generates random treshold charges for all pads
  Int_t nx = fSegmentation->Npx();
  Int_t ny = fSegmentation->Npy();

  fTresh = new AliRICHTresholdMap(fSegmentation);
  for(Int_t i=-nx/2;i<nx/2;i++){
    for(Int_t j=-ny/2;j<ny/2;j++){
      Int_t pedestal = (Int_t)(gRandom->Gaus(50, 10));
      fTresh->SetHit(i,j,pedestal);
    }
  }      
}//void AliRICHChamber::GenerateTresholds()
//__________________________________________________________________________________________________
void AliRICHChamber::Print(Option_t *) const
{
  printf("%s r=%8.3f theta=%5.1f phi=%5.1f x=%8.3f y=%8.3f z=%8.3f  %6.2f,%6.2f %6.2f,%6.2f %6.2f,%6.2f\n",fName.Data(),
                     Rho(), ThetaD(),PhiD(),   X(),    Y(),    Z(),
                     ThetaXd(),PhiXd(),ThetaYd(),PhiYd(),ThetaZd(),PhiZd());
}//void AliRICHChamber::Print(Option_t *option)const
//__________________________________________________________________________________________________
Commit	Line	Data
2e5f0f7b	1	/**************************************************************************
	2	* Copyright(c) 1998-1999, ALICE Experiment at CERN, All rights reserved. *
	3	* *
	4	* Author: The ALICE Off-line Project. *
	5	* Contributors are mentioned in the code where appropriate. *
	6	* *
	7	* Permission to use, copy, modify and distribute this software and its *
	8	* documentation strictly for non-commercial purposes is hereby granted *
	9	* without fee, provided that the above copyright notice appears in all *
	10	* copies and that both the copyright notice and this permission notice *
	11	* appear in the supporting documentation. The authors make no claims *
	12	* about the suitability of this software for any purpose. It is *
	13	* provided "as is" without express or implied warranty. *
	14	**************************************************************************/
	15
2e5f0f7b	16	#include "AliRICHChamber.h"
a277aaca	17	#include "AliRICHConst.h" //for kR2d
853634d3	18	#include "AliRICHParam.h"
2e5f0f7b	19	#include <TRandom.h>
488e98ba	20	#include <TRotMatrix.h>
853634d3	21	#include "AliRICHTresholdMap.h"
	22	#include "AliSegmentation.h"
	23	#include "AliRICHSegmentationV0.h"
	24	#include "AliRICHGeometry.h"
	25	#include "AliRICHResponse.h"
2e5f0f7b	26
2e5f0f7b	27	ClassImp(AliRICHChamber)
853634d3	28	//______________________________________________________________________________
2e5f0f7b	29	AliRICHChamber::AliRICHChamber()
853634d3	30	{//default ctor
	31	fpParam=0;
	32	fpRotMatrix=0;
	33
2e5f0f7b	34	fSegmentation = 0;
4faf338d	35	fResponse = 0;
	36	fGeometry = 0;
	37	fTresh = 0;
ef42d733	38	for(Int_t i=0; i<50; ++i) fIndexMap[i] = 0;
2e5f0f7b	39	}
853634d3	40	//______________________________________________________________________________
853634d3	41	AliRICHChamber::AliRICHChamber(Int_t iModuleN,AliRICHParam *pParam)
c64f7552	42	{//main ctor. Defines all geometry parameters for the given module.
c64f7552	43	SetToZenith();//put to up position
853634d3	44	switch(iModuleN){
853634d3	45	case 1:
0ffe413c	46	RotateX(-pParam->AngleYZ());
3ea9cb08	47	RotateZ(-pParam->AngleXY());
853634d3	48	fName="RICHc1";fTitle="RICH chamber 1";
	49	break;
	50	case 2:
3ea9cb08	51	RotateZ(-pParam->AngleXY());
853634d3	52	fName="RICHc2";fTitle="RICH chamber 2";
	53	break;
	54	case 3:
3ea9cb08	55	RotateX(-pParam->AngleYZ());
853634d3	56	fName="RICHc3";fTitle="RICH chamber 3";
853634d3	57	break;
3ea9cb08	58	case 4:
3ea9cb08	59	fName="RICHc4";fTitle="RICH chamber 4"; //no turns
853634d3	60	break;
853634d3	61	case 5:
3ea9cb08	62	RotateX(pParam->AngleYZ());
853634d3	63	fName="RICHc5";fTitle="RICH chamber 5";
	64	break;
	65	case 6:
3ea9cb08	66	RotateZ(pParam->AngleXY());
853634d3	67	fName="RICHc6";fTitle="RICH chamber 6";
853634d3	68	break;
3ea9cb08	69	case 7:
	70	RotateX(pParam->AngleYZ());
	71	RotateZ(pParam->AngleXY());
	72	fName="RICHc7";fTitle="RICH chamber 7";
	73	break;
853634d3	74	default:
c64f7552	75	Fatal("named ctor","Wrong chamber number %i, check CreateChamber ctor",iModuleN);
853634d3	76	}//switch(iModuleN)
853634d3	77	RotateZ(pParam->AngleRot());//apply common rotation
a277aaca	78	fpRotMatrix=new TRotMatrix("rot"+fName,"rot"+fName, Rot().ThetaX()kR2d, Rot().PhiX()kR2d,
	79	Rot().ThetaY()kR2d, Rot().PhiY()kR2d,
	80	Rot().ThetaZ()kR2d, Rot().PhiZ()kR2d);
853634d3	81	fpParam=pParam;
c60862bf	82	fX=fCenterV3.X();fY=fCenterV3.Y();fZ=fCenterV3.Z();
1f63a0be	83
	84	fSegmentation = 0; fResponse = 0; fGeometry = 0;
	85	fTresh = 0; for(Int_t i=0; i<50; ++i) fIndexMap[i] = 0;
853634d3	86	}
853634d3	87	//______________________________________________________________________________
2e5f0f7b	88
0ffe413c	89	void AliRICHChamber::LocaltoGlobal(Float_t local[3],Float_t global[3])
853634d3	90	{//Local coordinates to global coordinates transformation
237c933d	91
2d857021	92	Double_t *pMatrix;
2d857021	93	pMatrix = fpRotMatrix->GetMatrix();
0ffe413c	94	global[0]=local[0]pMatrix[0]+local[1]pMatrix[3]+local[2]*pMatrix[6];
	95	global[1]=local[0]pMatrix[1]+local[1]pMatrix[4]+local[2]*pMatrix[7];
	96	global[2]=local[0]pMatrix[2]+local[1]pMatrix[5]+local[2]*pMatrix[8];
	97	global[0]+=fX;
	98	global[1]+=fY;
	99	global[2]+=fZ;
2e5f0f7b	100	}
2e5f0f7b	101
0ffe413c	102	void AliRICHChamber::GlobaltoLocal(Float_t global[3],Float_t local[3])
853634d3	103	{// Global coordinates to local coordinates transformation
2d857021	104	TMatrix matrixCopy(3,3);
2d857021	105	Double_t *pMatrixOrig = fpRotMatrix->GetMatrix();
2e5f0f7b	106	for(Int_t i=0;i<3;i++)
	107	{
	108	for(Int_t j=0;j<3;j++)
2d857021	109	matrixCopy(j,i)=pMatrixOrig[j+3*i];
2e5f0f7b	110	}
2d857021	111	matrixCopy.Invert();
0ffe413c	112	local[0] = global[0] - fX;
	113	local[1] = global[1] - fY;
	114	local[2] = global[2] - fZ;
	115	local[0]=local[0]matrixCopy(0,0)+local[1]matrixCopy(0,1)+local[2]*matrixCopy(0,2);
	116	local[1]=local[0]matrixCopy(1,0)+local[1]matrixCopy(1,1)+local[2]*matrixCopy(1,2);
	117	local[2]=local[0]matrixCopy(2,0)+local[1]matrixCopy(2,1)+local[2]*matrixCopy(2,2);
2e5f0f7b	118	}
2e5f0f7b	119
2e5f0f7b	120	void AliRICHChamber::DisIntegration(Float_t eloss, Float_t xhit, Float_t yhit,
3ea9cb08	121	Int_t& iNpads,Float_t cluster[5][500],ResponseType res)
3ea9cb08	122	{//Generates pad hits (simulated cluster) using the segmentation and the response model
0ffe413c	123
0ffe413c	124	Float_t local[3],global[3];
3ea9cb08	125	// Width of the integration area
	126	Float_t dx=(fResponse->SigmaIntegration())*(fResponse->ChargeSpreadX());
	127	Float_t dy=(fResponse->SigmaIntegration())*(fResponse->ChargeSpreadY());
	128	// Get pulse height from energy loss and generate feedback photons
	129	Float_t qtot=0;
	130	local[0]=xhit;
	131	//z-position of the wires relative to the RICH mother volume (2 mm before CsI) old value: 6.076 ???????
	132	local[1]=1.276 + fGeometry->GetGapThickness()/2 - .2;
	133	local[2]=yhit;
2e5f0f7b	134
3ea9cb08	135	LocaltoGlobal(local,global);
2e5f0f7b	136
0ffe413c	137
0ffe413c	138
3ea9cb08	139	//To calculate wire sag, the origin of y-position must be the middle of the photcathode
	140	AliRICHSegmentationV0* segmentation = (AliRICHSegmentationV0*) GetSegmentationModel();
	141	Float_t newy;
	142	if (yhit>0)
	143	newy = yhit - segmentation->GetPadPlaneLength()/2;
	144	else
	145	newy = yhit + segmentation->GetPadPlaneLength()/2;
0ffe413c	146
3ea9cb08	147	if(res==kMip){
3ea9cb08	148	qtot = fResponse->IntPH(eloss, newy);
0ffe413c	149	fResponse->FeedBackPhotons(global,qtot);
0ffe413c	150	}else if(res==kPhoton){
3ea9cb08	151	qtot = fResponse->IntPH(newy);
0ffe413c	152	fResponse->FeedBackPhotons(global,qtot);
3ea9cb08	153	}
2e5f0f7b	154
2e5f0f7b	155	// Loop Over Pads
0ffe413c	156
3ea9cb08	157	Float_t qcheck=0, qp=0;
0ffe413c	158
3ea9cb08	159	iNpads=0;
c712cb2f	160	for(fSegmentation->FirstPad(xhit, yhit, 0, dx, dy); fSegmentation->MorePads(); fSegmentation->NextPad()) {
3ea9cb08	161	qp= fResponse->IntXY(fSegmentation);
	162	qp= TMath::Abs(qp);
	163	if(qp >1.e-4){
	164	qcheck+=qp;
	165	cluster[0][iNpads]=qp*qtot;// --- store signal information
	166	cluster[1][iNpads]=fSegmentation->Ix();
	167	cluster[2][iNpads]=fSegmentation->Iy();
	168	cluster[3][iNpads]=fSegmentation->ISector();
0ffe413c	169	iNpads++;
3ea9cb08	170	}
3ea9cb08	171	}//pad loop
853634d3	172	}//void AliRICHChamber::DisIntegration(...
0ffe413c	173	//__________________________________________________________________________________________________
4faf338d	174	void AliRICHChamber::GenerateTresholds()
0ffe413c	175	{//Generates random treshold charges for all pads
4faf338d	176	Int_t nx = fSegmentation->Npx();
	177	Int_t ny = fSegmentation->Npy();
	178
4faf338d	179	fTresh = new AliRICHTresholdMap(fSegmentation);
853634d3	180	for(Int_t i=-nx/2;i<nx/2;i++){
	181	for(Int_t j=-ny/2;j<ny/2;j++){
	182	Int_t pedestal = (Int_t)(gRandom->Gaus(50, 10));
	183	fTresh->SetHit(i,j,pedestal);
4faf338d	184	}
853634d3	185	}
853634d3	186	}//void AliRICHChamber::GenerateTresholds()
0ffe413c	187	//__________________________________________________________________________________________________
cc23c5c6	188	void AliRICHChamber::Print(Option_t *) const
853634d3	189	{
0ffe413c	190	printf("%s r=%8.3f theta=%5.1f phi=%5.1f x=%8.3f y=%8.3f z=%8.3f %6.2f,%6.2f %6.2f,%6.2f %6.2f,%6.2f\n",fName.Data(),
0ffe413c	191	Rho(), ThetaD(),PhiD(), X(), Y(), Z(),
3ea9cb08	192	ThetaXd(),PhiXd(),ThetaYd(),PhiYd(),ThetaZd(),PhiZd());
853634d3	193	}//void AliRICHChamber::Print(Option_t *option)const
0ffe413c	194	//__________________________________________________________________________________________________