[u/mrichter/AliRoot.git] / TPC / AliTPCExBBShape.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.                  *
 **************************************************************************/

////////////////////////////////////////////////////////////////////////////
// AliTPCExBBShape class                                                  //
////////////////////////////////////////////////////////////////////////////

#include <AliMagF.h>
#include "TGeoGlobalMagField.h"
#include "AliTPCcalibDB.h"
#include "AliTPCParam.h"
#include "AliLog.h"

#include "AliTPCExBBShape.h"

AliTPCExBBShape::AliTPCExBBShape()
  : AliTPCCorrection("exb_bshape","ExB B-shape"),
    fC1(0.),fC2(0.),
    fBField(0)
{
  //
  // default constructor
  //
}

AliTPCExBBShape::~AliTPCExBBShape() {
  //
  // virtual destructor
  //
}

void AliTPCExBBShape::Init() {
  //
  // Initialization funtion
  //
  
  AliMagF* magF= (AliMagF*)TGeoGlobalMagField::Instance()->GetField();
  if (!magF) AliError("Magneticd field - not initialized");
  Double_t bzField = magF->SolenoidField()/10.; //field in T
  SetBField(magF);
  AliTPCParam *param= AliTPCcalibDB::Instance()->GetParameters();
  if (!param) AliError("Parameters - not initialized");
  Double_t vdrift = param->GetDriftV()/1000000.; // [cm/us]   // From dataBase: to be updated: per second (ideally)
  Double_t ezField = 400; // [V/cm]   // to be updated: never (hopefully)
  Double_t wt = -10.0 * (bzField*10) * vdrift / ezField ; 
  // Correction Terms for effective omegaTau; obtained by a laser calibration run
  SetOmegaTauT1T2(wt,fT1,fT2);


}

void AliTPCExBBShape::Update(const TTimeStamp &/*timeStamp*/) {
  //
  // Update function 
  //
  AliMagF* magF= (AliMagF*)TGeoGlobalMagField::Instance()->GetField();
  if (!magF) AliError("Magneticd field - not initialized");
  Double_t bzField = magF->SolenoidField()/10.; //field in T
  SetBField(magF);
  AliTPCParam *param= AliTPCcalibDB::Instance()->GetParameters();
  if (!param) AliError("Parameters - not initialized");
  Double_t vdrift = param->GetDriftV()/1000000.; // [cm/us]   // From dataBase: to be updated: per second (ideally)
  Double_t ezField = 400; // [V/cm]   // to be updated: never (hopefully)
  Double_t wt = -10.0 * (bzField*10) * vdrift / ezField ; 
  // Correction Terms for effective omegaTau; obtained by a laser calibration run
  SetOmegaTauT1T2(wt,fT1,fT2);


}


void AliTPCExBBShape::GetCorrection(const Float_t x[],const Short_t roc,Float_t dx[]) {
  //
  // Calculates the space point corrections of the B field inperfections (B field shape) 
  //

  if (!fBField) {
    for (Int_t j=0;j<3;++j) dx[j]=0.;
    return;
  }

  const Double_t xStart[3]={ x[0], x[1], x[2] };
  const Double_t xEnd[3]={ x[0],  x[1],  roc%36<18?fgkTPCZ0:-fgkTPCZ0 };

  Double_t intBStart[3];
  Double_t intBEnd[3];

  fBField->GetTPCRatInt(xStart,intBStart);
  fBField->GetTPCRatInt(xEnd,  intBEnd  );

  const Float_t intBxOverBz=(intBEnd[0]-intBStart[0]);
  const Float_t intByOverBz=(intBEnd[1]-intBStart[1]);
  
  dx[0]=fC2*intBxOverBz-fC1*intByOverBz;
  dx[1]=fC1*intBxOverBz+fC2*intByOverBz;
  dx[2]=0.;


}

void AliTPCExBBShape::GetBxAndByOverBz(const Float_t x[],const Short_t roc,Float_t BxByOverBz[]) {
  //
  // This function is purely for calibration purposes
  // Returns the via AliMagF obtaind B field integrals  
  // 

  if (!fBField) {
    for (Int_t j=0;j<3;++j) BxByOverBz[j]=0.;
    return;
  }

  const Double_t xStart[3]={ x[0], x[1], x[2] };
  const Double_t xEnd[3]={ x[0],  x[1],  roc%36<18?fgkTPCZ0:-fgkTPCZ0 };

  Double_t intBStart[3];
  Double_t intBEnd[3];

  fBField->GetTPCRatInt(xStart,intBStart);
  fBField->GetTPCRatInt(xEnd,  intBEnd  );

  const Float_t intBxOverBz=(intBEnd[0]-intBStart[0]);
  const Float_t intByOverBz=(intBEnd[1]-intBStart[1]);
  
  BxByOverBz[0]=intBxOverBz;
  BxByOverBz[1]=intByOverBz;

}

void AliTPCExBBShape::Print(Option_t* option) const {
  //
  // Print function to check the settings (e.g. voltage offsets)
  // option=="a" prints details of the B field settings and the 
  // C0 and C1 coefficents (for calibration purposes)
  //
  TString opt = option; opt.ToLower();
  printf("%s\t%s\n - B field settings:\n",GetTitle(),GetName());
  fBField->Print(option);
  //  printf(" - B field: X-Twist: %1.5lf rad, Y-Twist: %1.5lf rad \n",fBField->Print(option));
  if (opt.Contains("a")) { // Print all details  
    printf(" - T1: %1.4f, T2: %1.4f \n",fT1,fT2);
    printf(" - C1: %1.4f, C2: %1.4f \n",fC1,fC2);
  }    
}

Double_t AliTPCExBBShape::GetBFieldXYZ(Double_t gx, Double_t gy, Double_t gz, Int_t axisType){
  //
  // return B field at given x,y,z
  // 
  AliMagF* field = (AliMagF*)TGeoGlobalMagField::Instance()->GetField();
  if (!field) return 0;
  Double_t xyz[3]={gx,gy,gz};
  Double_t bxyz[3]={0};
  field->Field(xyz,bxyz);
  //
  Double_t r=TMath::Sqrt(gx*gx+gy*gy);
  //  Double_t b=TMath::Sqrt(bxyz[0]*bxyz[0]+bxyz[1]*bxyz[1]);
  if (axisType==0) {
    return (xyz[0]*bxyz[1]-xyz[1]*bxyz[0])/(bxyz[2]*r);
  }
  if (axisType==1){
    return (xyz[0]*bxyz[0]+xyz[1]*bxyz[1])/(bxyz[2]*r);
  }
  if (axisType==2) return bxyz[2];
  if (axisType==3) return bxyz[0];
  if (axisType==4) return bxyz[1];
  if (axisType==5) return bxyz[2];
  return bxyz[2];
}
Commit	Line	Data
0116859c	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
	16	////////////////////////////////////////////////////////////////////////////
b4caed64	17	// AliTPCExBBShape class //
0116859c	18	////////////////////////////////////////////////////////////////////////////
	19
	20	#include <AliMagF.h>
534fd34a	21	#include "TGeoGlobalMagField.h"
	22	#include "AliTPCcalibDB.h"
	23	#include "AliTPCParam.h"
	24	#include "AliLog.h"
0116859c	25
	26	#include "AliTPCExBBShape.h"
	27
	28	AliTPCExBBShape::AliTPCExBBShape()
	29	: AliTPCCorrection("exb_bshape","ExB B-shape"),
	30	fC1(0.),fC2(0.),
	31	fBField(0)
	32	{
	33	//
	34	// default constructor
	35	//
	36	}
	37
	38	AliTPCExBBShape::~AliTPCExBBShape() {
	39	//
	40	// virtual destructor
	41	//
	42	}
	43
e527a1b9	44	void AliTPCExBBShape::Init() {
e527a1b9	45	//
534fd34a	46	// Initialization funtion
e527a1b9	47	//
e527a1b9	48
534fd34a	49	AliMagF* magF= (AliMagF*)TGeoGlobalMagField::Instance()->GetField();
	50	if (!magF) AliError("Magneticd field - not initialized");
	51	Double_t bzField = magF->SolenoidField()/10.; //field in T
	52	SetBField(magF);
	53	AliTPCParam *param= AliTPCcalibDB::Instance()->GetParameters();
	54	if (!param) AliError("Parameters - not initialized");
	55	Double_t vdrift = param->GetDriftV()/1000000.; // [cm/us] // From dataBase: to be updated: per second (ideally)
e527a1b9	56	Double_t ezField = 400; // [V/cm] // to be updated: never (hopefully)
e527a1b9	57	Double_t wt = -10.0 * (bzField10) vdrift / ezField ;
e527a1b9	58	// Correction Terms for effective omegaTau; obtained by a laser calibration run
534fd34a	59	SetOmegaTauT1T2(wt,fT1,fT2);
e527a1b9	60
	61
	62	}
	63
	64	void AliTPCExBBShape::Update(const TTimeStamp &/timeStamp/) {
	65	//
	66	// Update function
	67	//
534fd34a	68	AliMagF* magF= (AliMagF*)TGeoGlobalMagField::Instance()->GetField();
	69	if (!magF) AliError("Magneticd field - not initialized");
	70	Double_t bzField = magF->SolenoidField()/10.; //field in T
	71	SetBField(magF);
	72	AliTPCParam *param= AliTPCcalibDB::Instance()->GetParameters();
	73	if (!param) AliError("Parameters - not initialized");
	74	Double_t vdrift = param->GetDriftV()/1000000.; // [cm/us] // From dataBase: to be updated: per second (ideally)
e527a1b9	75	Double_t ezField = 400; // [V/cm] // to be updated: never (hopefully)
e527a1b9	76	Double_t wt = -10.0 * (bzField10) vdrift / ezField ;
e527a1b9	77	// Correction Terms for effective omegaTau; obtained by a laser calibration run
534fd34a	78	SetOmegaTauT1T2(wt,fT1,fT2);
e527a1b9	79
	80
	81	}
	82
	83
	84
0116859c	85	void AliTPCExBBShape::GetCorrection(const Float_t x[],const Short_t roc,Float_t dx[]) {
	86	//
	87	// Calculates the space point corrections of the B field inperfections (B field shape)
	88	//
	89
	90	if (!fBField) {
	91	for (Int_t j=0;j<3;++j) dx[j]=0.;
	92	return;
	93	}
	94
	95	const Double_t xStart[3]={ x[0], x[1], x[2] };
b1f0a2a5	96	const Double_t xEnd[3]={ x[0], x[1], roc%36<18?fgkTPCZ0:-fgkTPCZ0 };
0116859c	97
	98	Double_t intBStart[3];
	99	Double_t intBEnd[3];
	100
	101	fBField->GetTPCRatInt(xStart,intBStart);
	102	fBField->GetTPCRatInt(xEnd, intBEnd );
	103
	104	const Float_t intBxOverBz=(intBEnd[0]-intBStart[0]);
	105	const Float_t intByOverBz=(intBEnd[1]-intBStart[1]);
	106
	107	dx[0]=fC2intBxOverBz-fC1intByOverBz;
	108	dx[1]=fC1intBxOverBz+fC2intByOverBz;
	109	dx[2]=0.;
	110
	111
	112	}
	113
	114	void AliTPCExBBShape::GetBxAndByOverBz(const Float_t x[],const Short_t roc,Float_t BxByOverBz[]) {
	115	//
	116	// This function is purely for calibration purposes
	117	// Returns the via AliMagF obtaind B field integrals
	118	//
	119
	120	if (!fBField) {
	121	for (Int_t j=0;j<3;++j) BxByOverBz[j]=0.;
	122	return;
	123	}
	124
	125	const Double_t xStart[3]={ x[0], x[1], x[2] };
b1f0a2a5	126	const Double_t xEnd[3]={ x[0], x[1], roc%36<18?fgkTPCZ0:-fgkTPCZ0 };
0116859c	127
	128	Double_t intBStart[3];
	129	Double_t intBEnd[3];
	130
	131	fBField->GetTPCRatInt(xStart,intBStart);
	132	fBField->GetTPCRatInt(xEnd, intBEnd );
	133
	134	const Float_t intBxOverBz=(intBEnd[0]-intBStart[0]);
	135	const Float_t intByOverBz=(intBEnd[1]-intBStart[1]);
	136
	137	BxByOverBz[0]=intBxOverBz;
	138	BxByOverBz[1]=intByOverBz;
	139
	140	}
	141
	142	void AliTPCExBBShape::Print(Option_t* option) const {
	143	//
	144	// Print function to check the settings (e.g. voltage offsets)
	145	// option=="a" prints details of the B field settings and the
	146	// C0 and C1 coefficents (for calibration purposes)
	147	//
	148	TString opt = option; opt.ToLower();
534fd34a	149	printf("%s\t%s\n - B field settings:\n",GetTitle(),GetName());
0116859c	150	fBField->Print(option);
0116859c	151	// printf(" - B field: X-Twist: %1.5lf rad, Y-Twist: %1.5lf rad \n",fBField->Print(option));
534fd34a	152	if (opt.Contains("a")) { // Print all details
534fd34a	153	printf(" - T1: %1.4f, T2: %1.4f \n",fT1,fT2);
0116859c	154	printf(" - C1: %1.4f, C2: %1.4f \n",fC1,fC2);
0116859c	155	}
0116859c	156	}
46e89793	157
	158	Double_t AliTPCExBBShape::GetBFieldXYZ(Double_t gx, Double_t gy, Double_t gz, Int_t axisType){
	159	//
	160	// return B field at given x,y,z
	161	//
	162	AliMagF* field = (AliMagF*)TGeoGlobalMagField::Instance()->GetField();
	163	if (!field) return 0;
	164	Double_t xyz[3]={gx,gy,gz};
	165	Double_t bxyz[3]={0};
	166	field->Field(xyz,bxyz);
	167	//
	168	Double_t r=TMath::Sqrt(gxgx+gygy);
a8ef8a9c	169	// Double_t b=TMath::Sqrt(bxyz[0]bxyz[0]+bxyz[1]bxyz[1]);
46e89793	170	if (axisType==0) {
	171	return (xyz[0]bxyz[1]-xyz[1]bxyz[0])/(bxyz[2]*r);
	172	}
	173	if (axisType==1){
	174	return (xyz[0]bxyz[0]+xyz[1]bxyz[1])/(bxyz[2]*r);
	175	}
	176	if (axisType==2) return bxyz[2];
	177	if (axisType==3) return bxyz[0];
	178	if (axisType==4) return bxyz[1];
	179	if (axisType==5) return bxyz[2];
	180	return bxyz[2];
	181	}