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

////
// This implementation AliTPCExB is using an "exact" calculation of the ExB
// effect. That is, it uses the drift ODE to calculate the distortion
// without any further assumption.
// Due to the numerical integration of the ODE, there are some numerical
// uncertencies involed.
////

#include "TMath.h"
#include "TTreeStream.h"
#include "AliFieldMap.h"
#include "AliMagF.h"
#include "AliTPCExBExact.h"

ClassImp(AliTPCExBExact)

const Double_t AliTPCExBExact::fgkEM=1.602176487e-19/9.10938215e-31;
const Double_t AliTPCExBExact::fgkDriftField=40.e3;

AliTPCExBExact::AliTPCExBExact()
  : fDriftVelocity(0),
    fkMap(0),fkField(0),fkN(0),
    fkNX(0),fkNY(0),fkNZ(0),
    fkXMin(-250.),fkXMax(250.),fkYMin(-250.),fkYMax(250.),
    fkZMin(-250.),fkZMax(250.),
    fkNLook(0),fkLook(0) {
  //
  // purely for I/O
  //
}

AliTPCExBExact::AliTPCExBExact(const AliMagF *bField,
			       Double_t driftVelocity,
			       Int_t nx,Int_t ny,Int_t nz,Int_t n)
  : fDriftVelocity(driftVelocity),
    fkMap(0),fkField(bField),fkN(n),
    fkNX(nx),fkNY(ny),fkNZ(nz),
    fkXMin(-250.),fkXMax(250.),fkYMin(-250.),fkYMax(250.),
    fkZMin(-250.),fkZMax(250.),
    fkNLook(0),fkLook(0) {
  //
  // The constructor. One has to supply a magnetic field and an (initial)
  // drift velocity. Since some kind of lookuptable is created the
  // number of its meshpoints can be supplied.
  // n sets the number of integration steps to be used when integrating
  // over the full drift length.
  //
  CreateLookupTable();
}

AliTPCExBExact::AliTPCExBExact(const AliFieldMap *bFieldMap,
			       Double_t driftVelocity,Int_t n) 
  : fDriftVelocity(driftVelocity),
    fkMap(bFieldMap),fkField(0),fkN(n), 
    fkNX(0),fkNY(0),fkNZ(0),
    fkXMin(-250.),fkXMax(250.),fkYMin(-250.),fkYMax(250.),
    fkZMin(-250.),fkZMax(250.),
    fkNLook(0),fkLook(0) {
  //
  // The constructor. One has to supply a field map and an (initial)
  // drift velocity.
  // n sets the number of integration steps to be used when integrating
  // over the full drift length.
  //

  fkXMin=bFieldMap->Xmin()
    -TMath::Ceil( (bFieldMap->Xmin()+250.0)/bFieldMap->DelX())
    *bFieldMap->DelX();
  fkXMax=bFieldMap->Xmax()
    -TMath::Floor((bFieldMap->Xmax()-250.0)/bFieldMap->DelX())
    *bFieldMap->DelX();
  fkYMin=bFieldMap->Ymin()
    -TMath::Ceil( (bFieldMap->Ymin()+250.0)/bFieldMap->DelY())
    *bFieldMap->DelY();
  fkYMax=bFieldMap->Ymax()
    -TMath::Floor((bFieldMap->Ymax()-250.0)/bFieldMap->DelY())
    *bFieldMap->DelY();
  fkZMax=bFieldMap->Zmax()
    -TMath::Floor((bFieldMap->Zmax()-250.0)/bFieldMap->DelZ())
    *bFieldMap->DelZ();
  fkZMax=TMath::Max(0.,fkZMax); // I really hope that this is unnecessary!

  fkNX=static_cast<Int_t>((fkXMax-fkXMin)/bFieldMap->DelX()+1.1);
  fkNY=static_cast<Int_t>((fkYMax-fkYMin)/bFieldMap->DelY()+1.1);
  fkNZ=static_cast<Int_t>((fkZMax-fkZMin)/bFieldMap->DelZ()+1.1);

  CreateLookupTable();
}

AliTPCExBExact::~AliTPCExBExact() {
  //
  // destruct the poor object.
  //
  delete[] fkLook;
}

void AliTPCExBExact::Correct(const Double_t *position, Double_t *corrected) {
  //
  // correct for the distortion
  //
  Double_t x=(position[0]-fkXMin)/(fkXMax-fkXMin)*(fkNX-1);
  Int_t xi1=static_cast<Int_t>(x);
  xi1=TMath::Max(TMath::Min(xi1,fkNX-2),0);
  Int_t xi2=xi1+1;
  Double_t dx=(x-xi1);
  Double_t dx1=(xi2-x);
  
  Double_t y=(position[1]-fkYMin)/(fkYMax-fkYMin)*(fkNY-1);
  Int_t yi1=static_cast<Int_t>(y);
  yi1=TMath::Max(TMath::Min(yi1,fkNY-2),0);
  Int_t yi2=yi1+1;
  Double_t dy=(y-yi1);
  Double_t dy1=(yi2-y);
  
  Double_t z=position[2]/fkZMax*(fkNZ-1);
  Int_t side;
  if (z>0) {
    side=1;
  }
  else {
    z=-z;
    side=0;
  }
  Int_t zi1=static_cast<Int_t>(z);
  zi1=TMath::Max(TMath::Min(zi1,fkNZ-2),0);
  Int_t zi2=zi1+1;
  Double_t dz=(z-zi1);
  Double_t dz1=(zi2-z);
  
  for (int i=0;i<3;++i)
    corrected[i]
      =fkLook[(((xi1*fkNY+yi1)*fkNZ+zi1)*2+side)*3+i]*dx1*dy1*dz1
      +fkLook[(((xi1*fkNY+yi1)*fkNZ+zi2)*2+side)*3+i]*dx1*dy1*dz
      +fkLook[(((xi1*fkNY+yi2)*fkNZ+zi1)*2+side)*3+i]*dx1*dy *dz1
      +fkLook[(((xi1*fkNY+yi2)*fkNZ+zi2)*2+side)*3+i]*dx1*dy *dz
      +fkLook[(((xi2*fkNY+yi2)*fkNZ+zi1)*2+side)*3+i]*dx *dy *dz1
      +fkLook[(((xi2*fkNY+yi2)*fkNZ+zi2)*2+side)*3+i]*dx *dy *dz
      +fkLook[(((xi2*fkNY+yi1)*fkNZ+zi1)*2+side)*3+i]*dx *dy1*dz1
      +fkLook[(((xi2*fkNY+yi1)*fkNZ+zi2)*2+side)*3+i]*dx *dy1*dz ;
  //    corrected[2]=position[2];
}

void AliTPCExBExact::TestThisBeautifulObject(const AliFieldMap *bFieldMap,
					     const char* fileName) {
  //
  // Have a look at the common part "TestThisBeautifulObjectGeneric".
  //
  fkMap=bFieldMap;
  fkField=0;
  TestThisBeautifulObjectGeneric(fileName);
}

void AliTPCExBExact::TestThisBeautifulObject(const AliMagF *bField,
					     const char* fileName) {
  //
  // Have a look at the common part "TestThisBeautifulObjectGeneric".
  //
  fkField=bField;
  fkMap=0;
  TestThisBeautifulObjectGeneric(fileName);
}

void AliTPCExBExact::TestThisBeautifulObjectGeneric(const char* fileName) {
  //
  // Well, as the name sais... it tests the object.
  //
  TTreeSRedirector ts(fileName);
  Double_t x[3];
  for (x[0]=-250.;x[0]<=250.;x[0]+=10.)
    for (x[1]=-250.;x[1]<=250.;x[1]+=10.)
      for (x[2]=-250.;x[2]<=250.;x[2]+=10.) {
	Double_t d[3];
	Double_t dnl[3];
	Correct(x,d);
	CalculateDistortion(x,dnl);
	Double_t r=TMath::Sqrt(x[0]*x[0]+x[1]*x[1]);
	Double_t rd=TMath::Sqrt(d[0]*d[0]+d[1]*d[1]);
	Double_t dr=r-rd;
	Double_t phi=TMath::ATan2(x[0],x[1]);
	Double_t phid=TMath::ATan2(d[0],d[1]);
	Double_t dphi=phi-phid;
	if (dphi<0.) dphi+=TMath::TwoPi();
	if (dphi>TMath::Pi()) dphi=TMath::TwoPi()-dphi;
	Double_t drphi=r*dphi;
	Double_t dx=x[0]-d[0];
	Double_t dy=x[1]-d[1];
	Double_t dz=x[2]-d[2];
	Double_t dnlx=x[0]-dnl[0];
	Double_t dnly=x[1]-dnl[1];
	Double_t dnlz=x[2]-dnl[2];
	Double_t b[3];
	GetB(b,x);
	ts<<"positions"
	  <<"bx="<<b[0]
	  <<"by="<<b[1]
	  <<"bz="<<b[2]
	  <<"x0="<<x[0]
	  <<"x1="<<x[1]
	  <<"x2="<<x[2]
	  <<"dx="<<dx
	  <<"dy="<<dy
	  <<"dz="<<dz
	  <<"dnlx="<<dnlx
	  <<"dnly="<<dnly
	  <<"dnlz="<<dnlz
	  <<"r="<<r
	  <<"phi="<<phi
	  <<"dr="<<dr
	  <<"drphi="<<drphi
	  <<"\n";
      }
}

void AliTPCExBExact::CreateLookupTable() {
  //
  // Helper function to fill the lookup table.
  //
  fkNLook=fkNX*fkNY*fkNZ*2*3;
  fkLook=new Double_t[fkNLook];
  Double_t x[3];
  for (int i=0;i<fkNX;++i) {
    x[0]=fkXMin+(fkXMax-fkXMin)/(fkNX-1)*i;
    for (int j=0;j<fkNY;++j) {
      x[1]=fkYMin+(fkYMax-fkYMin)/(fkNY-1)*j;
      for (int k=0;k<fkNZ;++k) {
	x[2]=1.*fkZMax/(fkNZ-1)*k;
	x[2]=TMath::Max((Double_t)0.0001,x[2]); //ugly
	CalculateDistortion(x,&fkLook[(((i*fkNY+j)*fkNZ+k)*2+1)*3]);
	x[2]=-x[2];
	CalculateDistortion(x,&fkLook[(((i*fkNY+j)*fkNZ+k)*2+0)*3]);
      }
    }
  }
}

void AliTPCExBExact::GetE(Double_t *e,const Double_t *x) const {
  //
  // Helper function returning the E field in SI units (V/m).
  //
  e[0]=0.;
  e[1]=0.;
  e[2]=(x[2]<0.?-1.:1.)*fgkDriftField; // in V/m
}

void AliTPCExBExact::GetB(Double_t *b,const Double_t *x) const {
  //
  // Helper function returning the B field in SI units (T).
  //
  Float_t xm[3];
  // the beautiful m to cm (and the ugly "const_cast") and Double_t 
  // to Float_t read the NRs introduction!:
  for (int i=0;i<3;++i) xm[i]=x[i]*100.;
  Float_t bf[3];
  if (fkMap!=0)
    fkMap->Field(xm,bf);
  else
    fkField->Field(xm,bf);
  for (int i=0;i<3;++i) b[i]=bf[i]/10.;
}

void AliTPCExBExact::Motion(const Double_t *x,Double_t,
			    Double_t *dxdt) const {
  //
  // The differential equation of motion of the electrons.
  //
  Double_t tau=fDriftVelocity/fgkDriftField/fgkEM;
  Double_t tau2=tau*tau;
  Double_t e[3];
  Double_t b[3];
  GetE(e,x);
  GetB(b,x);
  Double_t wx=fgkEM*b[0];
  Double_t wy=fgkEM*b[1];
  Double_t wz=fgkEM*b[2];
  Double_t ex=fgkEM*e[0];
  Double_t ey=fgkEM*e[1];
  Double_t ez=fgkEM*e[2];
  Double_t w2=(wx*wx+wy*wy+wz*wz);
  dxdt[0]=(1.+wx*wx*tau2)*ex+(wz*tau+wx*wy*tau2)*ey+(-wy*tau+wx*wz*tau2)*ez;
  dxdt[1]=(-wz*tau+wx*wy*tau2)*ex+(1.+wy*wy*tau2)*ey+(wx*tau+wy*wz*tau2)*ez;
  dxdt[2]=(wy*tau+wx*wz*tau2)*ex+(-wx*tau+wy*wz*tau2)*ey+(1.+wz*wz*tau2)*ez;
  Double_t fac=tau/(1.+w2*tau2);
  dxdt[0]*=fac;
  dxdt[1]*=fac;
  dxdt[2]*=fac;
}

void AliTPCExBExact::CalculateDistortion(const Double_t *x0,
					 Double_t *dist) const {
  //
  // Helper function that calculates one distortion by integration
  // (only used to fill the lookup table).
  //
  Double_t h=0.01*250./fDriftVelocity/fkN;
  Double_t t=0.;
  Double_t xt[3];
  Double_t xo[3];
  for (int i=0;i<3;++i)
    xo[i]=xt[i]=x0[i]*0.01;
  while (TMath::Abs(xt[2])<250.*0.01) {
    for (int i=0;i<3;++i)
      xo[i]=xt[i];
    DGLStep(xt,t,h);
    t+=h;
  }
  if (t!=0.) {
    Double_t p=((xt[2]<0.?-1.:1.)*250.*0.01-xo[2])/(xt[2]-xo[2]);
    dist[0]=(xo[0]+p*(xt[0]-xo[0]))*100.;
    dist[1]=(xo[1]+p*(xt[1]-xo[1]))*100.;
    //    dist[2]=(xo[2]+p*(xt[2]-xo[2]))*100.;
    dist[2]=(x0[2]>0.?-1:1.)*(t-h+p*h)*fDriftVelocity*100.;
    dist[2]+=(x0[2]<0.?-1:1.)*250.;
  }
  else {
    dist[0]=x0[0];
    dist[1]=x0[1];
    dist[2]=x0[2];
  }
  // reverse the distortion, i.e. get the correction
  dist[0]=x0[0]-(dist[0]-x0[0]);
  dist[1]=x0[1]-(dist[1]-x0[1]);
}

void AliTPCExBExact::DGLStep(Double_t *x,Double_t t,Double_t h) const {
  //
  // An elementary integration step.
  // (simple Euler Method)
  //
  Double_t dxdt[3];
  Motion(x,t,dxdt);
  for (int i=0;i<3;++i)
    x[i]+=h*dxdt[i];

  /* suggestions about how to write it this way are welcome!
     void DGLStep(void (*f)(const Double_t *x,Double_t t,Double_t *dxdt),
                   Double_t *x,Double_t t,Double_t h,Int_t n) const;
  */

}
Commit	Line	Data
cf585711	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	////
	17	// This implementation AliTPCExB is using an "exact" calculation of the ExB
	18	// effect. That is, it uses the drift ODE to calculate the distortion
	19	// without any further assumption.
	20	// Due to the numerical integration of the ODE, there are some numerical
	21	// uncertencies involed.
	22	////
	23
faf93237	24	#include "TMath.h"
faf93237	25	#include "TTreeStream.h"
cf585711	26	#include "AliFieldMap.h"
cf585711	27	#include "AliMagF.h"
faf93237	28	#include "AliTPCExBExact.h"
	29
	30	ClassImp(AliTPCExBExact)
	31
	32	const Double_t AliTPCExBExact::fgkEM=1.602176487e-19/9.10938215e-31;
	33	const Double_t AliTPCExBExact::fgkDriftField=40.e3;
	34
481f877b	35	AliTPCExBExact::AliTPCExBExact()
	36	: fDriftVelocity(0),
	37	fkMap(0),fkField(0),fkN(0),
	38	fkNX(0),fkNY(0),fkNZ(0),
	39	fkXMin(-250.),fkXMax(250.),fkYMin(-250.),fkYMax(250.),
	40	fkZMin(-250.),fkZMax(250.),
	41	fkNLook(0),fkLook(0) {
	42	//
	43	// purely for I/O
	44	//
	45	}
	46
faf93237	47	AliTPCExBExact::AliTPCExBExact(const AliMagF *bField,
	48	Double_t driftVelocity,
	49	Int_t nx,Int_t ny,Int_t nz,Int_t n)
481f877b	50	: fDriftVelocity(driftVelocity),
481f877b	51	fkMap(0),fkField(bField),fkN(n),
faf93237	52	fkNX(nx),fkNY(ny),fkNZ(nz),
faf93237	53	fkXMin(-250.),fkXMax(250.),fkYMin(-250.),fkYMax(250.),
481f877b	54	fkZMin(-250.),fkZMax(250.),
481f877b	55	fkNLook(0),fkLook(0) {
faf93237	56	//
	57	// The constructor. One has to supply a magnetic field and an (initial)
	58	// drift velocity. Since some kind of lookuptable is created the
	59	// number of its meshpoints can be supplied.
	60	// n sets the number of integration steps to be used when integrating
	61	// over the full drift length.
	62	//
faf93237	63	CreateLookupTable();
	64	}
	65
	66	AliTPCExBExact::AliTPCExBExact(const AliFieldMap *bFieldMap,
	67	Double_t driftVelocity,Int_t n)
481f877b	68	: fDriftVelocity(driftVelocity),
	69	fkMap(bFieldMap),fkField(0),fkN(n),
	70	fkNX(0),fkNY(0),fkNZ(0),
	71	fkXMin(-250.),fkXMax(250.),fkYMin(-250.),fkYMax(250.),
	72	fkZMin(-250.),fkZMax(250.),
	73	fkNLook(0),fkLook(0) {
faf93237	74	//
	75	// The constructor. One has to supply a field map and an (initial)
	76	// drift velocity.
	77	// n sets the number of integration steps to be used when integrating
	78	// over the full drift length.
	79	//
faf93237	80
	81	fkXMin=bFieldMap->Xmin()
	82	-TMath::Ceil( (bFieldMap->Xmin()+250.0)/bFieldMap->DelX())
	83	*bFieldMap->DelX();
	84	fkXMax=bFieldMap->Xmax()
	85	-TMath::Floor((bFieldMap->Xmax()-250.0)/bFieldMap->DelX())
	86	*bFieldMap->DelX();
	87	fkYMin=bFieldMap->Ymin()
	88	-TMath::Ceil( (bFieldMap->Ymin()+250.0)/bFieldMap->DelY())
	89	*bFieldMap->DelY();
	90	fkYMax=bFieldMap->Ymax()
	91	-TMath::Floor((bFieldMap->Ymax()-250.0)/bFieldMap->DelY())
	92	*bFieldMap->DelY();
	93	fkZMax=bFieldMap->Zmax()
	94	-TMath::Floor((bFieldMap->Zmax()-250.0)/bFieldMap->DelZ())
	95	*bFieldMap->DelZ();
	96	fkZMax=TMath::Max(0.,fkZMax); // I really hope that this is unnecessary!
	97
	98	fkNX=static_cast<Int_t>((fkXMax-fkXMin)/bFieldMap->DelX()+1.1);
	99	fkNY=static_cast<Int_t>((fkYMax-fkYMin)/bFieldMap->DelY()+1.1);
	100	fkNZ=static_cast<Int_t>((fkZMax-fkZMin)/bFieldMap->DelZ()+1.1);
	101
	102	CreateLookupTable();
	103	}
	104
	105	AliTPCExBExact::~AliTPCExBExact() {
	106	//
	107	// destruct the poor object.
	108	//
481f877b	109	delete[] fkLook;
faf93237	110	}
faf93237	111
481f877b	112	void AliTPCExBExact::Correct(const Double_t position, Double_t corrected) {
	113	//
	114	// correct for the distortion
	115	//
	116	Double_t x=(position[0]-fkXMin)/(fkXMax-fkXMin)*(fkNX-1);
	117	Int_t xi1=static_cast<Int_t>(x);
	118	xi1=TMath::Max(TMath::Min(xi1,fkNX-2),0);
	119	Int_t xi2=xi1+1;
	120	Double_t dx=(x-xi1);
	121	Double_t dx1=(xi2-x);
	122
	123	Double_t y=(position[1]-fkYMin)/(fkYMax-fkYMin)*(fkNY-1);
	124	Int_t yi1=static_cast<Int_t>(y);
	125	yi1=TMath::Max(TMath::Min(yi1,fkNY-2),0);
	126	Int_t yi2=yi1+1;
	127	Double_t dy=(y-yi1);
	128	Double_t dy1=(yi2-y);
	129
	130	Double_t z=position[2]/fkZMax*(fkNZ-1);
	131	Int_t side;
	132	if (z>0) {
	133	side=1;
faf93237	134	}
faf93237	135	else {
481f877b	136	z=-z;
481f877b	137	side=0;
faf93237	138	}
481f877b	139	Int_t zi1=static_cast<Int_t>(z);
	140	zi1=TMath::Max(TMath::Min(zi1,fkNZ-2),0);
	141	Int_t zi2=zi1+1;
	142	Double_t dz=(z-zi1);
	143	Double_t dz1=(zi2-z);
	144
	145	for (int i=0;i<3;++i)
	146	corrected[i]
	147	=fkLook[(((xi1fkNY+yi1)fkNZ+zi1)2+side)3+i]dx1dy1*dz1
	148	+fkLook[(((xi1fkNY+yi1)fkNZ+zi2)2+side)3+i]dx1dy1*dz
	149	+fkLook[(((xi1fkNY+yi2)fkNZ+zi1)2+side)3+i]dx1dy *dz1
	150	+fkLook[(((xi1fkNY+yi2)fkNZ+zi2)2+side)3+i]dx1dy *dz
	151	+fkLook[(((xi2fkNY+yi2)fkNZ+zi1)2+side)3+i]dx dy *dz1
	152	+fkLook[(((xi2fkNY+yi2)fkNZ+zi2)2+side)3+i]dx dy *dz
	153	+fkLook[(((xi2fkNY+yi1)fkNZ+zi1)2+side)3+i]dx dy1*dz1
	154	+fkLook[(((xi2fkNY+yi1)fkNZ+zi2)2+side)3+i]dx dy1*dz ;
	155	// corrected[2]=position[2];
	156	}
	157
	158	void AliTPCExBExact::TestThisBeautifulObject(const AliFieldMap *bFieldMap,
	159	const char* fileName) {
cf585711	160	//
	161	// Have a look at the common part "TestThisBeautifulObjectGeneric".
	162	//
481f877b	163	fkMap=bFieldMap;
	164	fkField=0;
	165	TestThisBeautifulObjectGeneric(fileName);
	166	}
	167
	168	void AliTPCExBExact::TestThisBeautifulObject(const AliMagF *bField,
	169	const char* fileName) {
cf585711	170	//
	171	// Have a look at the common part "TestThisBeautifulObjectGeneric".
	172	//
481f877b	173	fkField=bField;
	174	fkMap=0;
	175	TestThisBeautifulObjectGeneric(fileName);
faf93237	176	}
faf93237	177
481f877b	178	void AliTPCExBExact::TestThisBeautifulObjectGeneric(const char* fileName) {
faf93237	179	//
cf585711	180	// Well, as the name sais... it tests the object.
faf93237	181	//
	182	TTreeSRedirector ts(fileName);
	183	Double_t x[3];
	184	for (x[0]=-250.;x[0]<=250.;x[0]+=10.)
	185	for (x[1]=-250.;x[1]<=250.;x[1]+=10.)
	186	for (x[2]=-250.;x[2]<=250.;x[2]+=10.) {
	187	Double_t d[3];
	188	Double_t dnl[3];
	189	Correct(x,d);
	190	CalculateDistortion(x,dnl);
	191	Double_t r=TMath::Sqrt(x[0]x[0]+x[1]x[1]);
	192	Double_t rd=TMath::Sqrt(d[0]d[0]+d[1]d[1]);
	193	Double_t dr=r-rd;
	194	Double_t phi=TMath::ATan2(x[0],x[1]);
	195	Double_t phid=TMath::ATan2(d[0],d[1]);
	196	Double_t dphi=phi-phid;
	197	if (dphi<0.) dphi+=TMath::TwoPi();
	198	if (dphi>TMath::Pi()) dphi=TMath::TwoPi()-dphi;
	199	Double_t drphi=r*dphi;
	200	Double_t dx=x[0]-d[0];
	201	Double_t dy=x[1]-d[1];
	202	Double_t dz=x[2]-d[2];
	203	Double_t dnlx=x[0]-dnl[0];
	204	Double_t dnly=x[1]-dnl[1];
	205	Double_t dnlz=x[2]-dnl[2];
941daeb8	206	Double_t b[3];
941daeb8	207	GetB(b,x);
faf93237	208	ts<<"positions"
941daeb8	209	<<"bx="<<b[0]
	210	<<"by="<<b[1]
	211	<<"bz="<<b[2]
faf93237	212	<<"x0="<<x[0]
	213	<<"x1="<<x[1]
	214	<<"x2="<<x[2]
	215	<<"dx="<<dx
	216	<<"dy="<<dy
	217	<<"dz="<<dz
	218	<<"dnlx="<<dnlx
	219	<<"dnly="<<dnly
	220	<<"dnlz="<<dnlz
	221	<<"r="<<r
	222	<<"phi="<<phi
	223	<<"dr="<<dr
	224	<<"drphi="<<drphi
	225	<<"\n";
	226	}
	227	}
	228
	229	void AliTPCExBExact::CreateLookupTable() {
	230	//
	231	// Helper function to fill the lookup table.
	232	//
481f877b	233	fkNLook=fkNXfkNYfkNZ23;
481f877b	234	fkLook=new Double_t[fkNLook];
faf93237	235	Double_t x[3];
	236	for (int i=0;i<fkNX;++i) {
	237	x[0]=fkXMin+(fkXMax-fkXMin)/(fkNX-1)*i;
	238	for (int j=0;j<fkNY;++j) {
	239	x[1]=fkYMin+(fkYMax-fkYMin)/(fkNY-1)*j;
	240	for (int k=0;k<fkNZ;++k) {
	241	x[2]=1.fkZMax/(fkNZ-1)k;
	242	x[2]=TMath::Max((Double_t)0.0001,x[2]); //ugly
481f877b	243	CalculateDistortion(x,&fkLook[(((ifkNY+j)fkNZ+k)2+1)3]);
faf93237	244	x[2]=-x[2];
481f877b	245	CalculateDistortion(x,&fkLook[(((ifkNY+j)fkNZ+k)2+0)3]);
faf93237	246	}
	247	}
	248	}
	249	}
	250
cf585711	251	void AliTPCExBExact::GetE(Double_t e,const Double_t x) const {
faf93237	252	//
	253	// Helper function returning the E field in SI units (V/m).
	254	//
cf585711	255	e[0]=0.;
	256	e[1]=0.;
	257	e[2]=(x[2]<0.?-1.:1.)*fgkDriftField; // in V/m
faf93237	258	}
faf93237	259
cf585711	260	void AliTPCExBExact::GetB(Double_t b,const Double_t x) const {
faf93237	261	//
	262	// Helper function returning the B field in SI units (T).
	263	//
	264	Float_t xm[3];
	265	// the beautiful m to cm (and the ugly "const_cast") and Double_t
	266	// to Float_t read the NRs introduction!:
	267	for (int i=0;i<3;++i) xm[i]=x[i]*100.;
cf585711	268	Float_t bf[3];
faf93237	269	if (fkMap!=0)
cf585711	270	fkMap->Field(xm,bf);
faf93237	271	else
cf585711	272	fkField->Field(xm,bf);
cf585711	273	for (int i=0;i<3;++i) b[i]=bf[i]/10.;
faf93237	274	}
	275
	276	void AliTPCExBExact::Motion(const Double_t *x,Double_t,
	277	Double_t *dxdt) const {
	278	//
	279	// The differential equation of motion of the electrons.
	280	//
cf585711	281	Double_t tau=fDriftVelocity/fgkDriftField/fgkEM;
	282	Double_t tau2=tau*tau;
	283	Double_t e[3];
	284	Double_t b[3];
	285	GetE(e,x);
	286	GetB(b,x);
	287	Double_t wx=fgkEM*b[0];
	288	Double_t wy=fgkEM*b[1];
	289	Double_t wz=fgkEM*b[2];
	290	Double_t ex=fgkEM*e[0];
	291	Double_t ey=fgkEM*e[1];
	292	Double_t ez=fgkEM*e[2];
faf93237	293	Double_t w2=(wxwx+wywy+wz*wz);
	294	dxdt[0]=(1.+wxwxtau2)ex+(wztau+wxwytau2)ey+(-wytau+wxwztau2)*ez;
	295	dxdt[1]=(-wztau+wxwytau2)ex+(1.+wywytau2)ey+(wxtau+wywztau2)*ez;
	296	dxdt[2]=(wytau+wxwztau2)ex+(-wxtau+wywztau2)ey+(1.+wzwztau2)*ez;
	297	Double_t fac=tau/(1.+w2*tau2);
	298	dxdt[0]*=fac;
	299	dxdt[1]*=fac;
	300	dxdt[2]*=fac;
	301	}
	302
	303	void AliTPCExBExact::CalculateDistortion(const Double_t *x0,
	304	Double_t *dist) const {
	305	//
	306	// Helper function that calculates one distortion by integration
	307	// (only used to fill the lookup table).
	308	//
cf585711	309	Double_t h=0.01*250./fDriftVelocity/fkN;
faf93237	310	Double_t t=0.;
	311	Double_t xt[3];
	312	Double_t xo[3];
	313	for (int i=0;i<3;++i)
	314	xo[i]=xt[i]=x0[i]*0.01;
	315	while (TMath::Abs(xt[2])<250.*0.01) {
	316	for (int i=0;i<3;++i)
	317	xo[i]=xt[i];
	318	DGLStep(xt,t,h);
	319	t+=h;
	320	}
	321	if (t!=0.) {
	322	Double_t p=((xt[2]<0.?-1.:1.)250.0.01-xo[2])/(xt[2]-xo[2]);
	323	dist[0]=(xo[0]+p(xt[0]-xo[0]))100.;
	324	dist[1]=(xo[1]+p(xt[1]-xo[1]))100.;
	325	// dist[2]=(xo[2]+p(xt[2]-xo[2]))100.;
	326	dist[2]=(x0[2]>0.?-1:1.)(t-h+ph)fDriftVelocity100.;
	327	dist[2]+=(x0[2]<0.?-1:1.)*250.;
	328	}
	329	else {
	330	dist[0]=x0[0];
	331	dist[1]=x0[1];
	332	dist[2]=x0[2];
	333	}
	334	// reverse the distortion, i.e. get the correction
	335	dist[0]=x0[0]-(dist[0]-x0[0]);
	336	dist[1]=x0[1]-(dist[1]-x0[1]);
	337	}
	338
	339	void AliTPCExBExact::DGLStep(Double_t *x,Double_t t,Double_t h) const {
	340	//
	341	// An elementary integration step.
	342	// (simple Euler Method)
	343	//
	344	Double_t dxdt[3];
	345	Motion(x,t,dxdt);
	346	for (int i=0;i<3;++i)
	347	x[i]+=h*dxdt[i];
	348
	349	/* suggestions about how to write it this way are welcome!
	350	void DGLStep(void (f)(const Double_t x,Double_t t,Double_t *dxdt),
	351	Double_t *x,Double_t t,Double_t h,Int_t n) const;
	352	*/
	353
	354	}