[u/mrichter/AliRoot.git] / TPC / AliTPCROCVoltError3D.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.                  *
 **************************************************************************/

//////////////////////////////////////////////////////////////////////////////
//                                                                          //
// AliTPCROCVoltError3D class                                               //
// The class calculates the space point distortions due to residual voltage //
// errors on Read Out Chambers of the TPC in 3D.                            //
//                                                                          //
// The class allows "effective Omega Tau" corrections.                      // 
//                                                                          //
// NOTE: This class is capable of calculating z distortions due to          //
//       misalignment and the vd dependency on the residual drift field     //
//                                                                          //
// date: 08/08/2010                                                         //
// Authors: Jim Thomas, Stefan Rossegger                                    //
//                                                                          //
// Example usage :                                                          //
//  AliTPCROCVoltError3D ROCerror;                                            //
//////////////////////////////////////////////////////////////////////////////

#include "AliMagF.h"
#include "TGeoGlobalMagField.h"
#include "AliTPCcalibDB.h"
#include "AliTPCParam.h"
#include "AliLog.h"
#include "TMatrixD.h"
#include "TFile.h"

#include "TMath.h"
#include "AliTPCROC.h"
#include "AliTPCROCVoltError3D.h"

ClassImp(AliTPCROCVoltError3D)

AliTPCROCVoltError3D::AliTPCROCVoltError3D()
  : AliTPCCorrection("ROCVoltErrors","ROC z alignment Errors"),
    fC0(0.),fC1(0.),
    fROCdisplacement(kTRUE),
    fElectronArrivalCorrection(kTRUE),
    fInitLookUp(kFALSE),
    fROCDataFileName(""),  
    fdzDataLinFit(0)
{
  //
  // default constructor
  //

  // Array which will contain the solution according to the setted boundary conditions
  // main input: z alignment of the Read Out chambers
  // see InitROCVoltError3D() function
  for ( Int_t k = 0 ; k < kNPhi ; k++ ) {
    fLookUpErOverEz[k]   =  new TMatrixD(kNR,kNZ);  
    fLookUpEphiOverEz[k] =  new TMatrixD(kNR,kNZ);
    fLookUpDeltaEz[k]    =  new TMatrixD(kNR,kNZ);   
  }
  fROCDataFileName="$ALICE_ROOT/TPC/Calib/maps/TPCROCdzSurvey.root";
  SetROCDataFileName(fROCDataFileName.Data()); // initialization of fdzDataLinFit is included

}

AliTPCROCVoltError3D::~AliTPCROCVoltError3D() {
  //
  // destructor
  //
  
  for ( Int_t k = 0 ; k < kNPhi ; k++ ) {
    delete fLookUpErOverEz[k];
    delete fLookUpEphiOverEz[k];
    delete fLookUpDeltaEz[k];
  }

  delete fdzDataLinFit;
}

void AliTPCROCVoltError3D::SetROCData(TMatrixD * matrix){
  //
  // Set a z alignment map of the chambers not via a file, but
  // directly via a TMatrix(72,3), where dz = p0 + p1*(lx-133.4) + p2*ly (all in cm)
  //
  if (!fdzDataLinFit) fdzDataLinFit=new TMatrixD(*matrix);
  else *fdzDataLinFit = *matrix;
}


void AliTPCROCVoltError3D::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
  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);

  if (!fInitLookUp) InitROCVoltError3D();
}

void AliTPCROCVoltError3D::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
  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  AliTPCROCVoltError3D::SetROCDataFileName(const char * fname) {
  //
  // Set / load the ROC data (linear fit of ROC misalignments)
  //

  fROCDataFileName = fname;
  
  TFile f(fROCDataFileName.Data(),"READ");
  TMatrixD *m = (TMatrixD*) f.Get("dzSurveyLinFitData");
  TMatrixD &mf = *m;

  // prepare some space

  if (fdzDataLinFit) delete fdzDataLinFit;
  fdzDataLinFit = new TMatrixD(72,3);
  TMatrixD &dataIntern = *fdzDataLinFit;
  
  for (Int_t iroc=0;iroc<72;iroc++) {
    dataIntern(iroc,0) = mf(iroc,0);  // z0 offset
    dataIntern(iroc,1) = mf(iroc,1);  // slope in x
    dataIntern(iroc,2) = mf(iroc,2);  // slope in y
  }

  f.Close();

  fInitLookUp = kFALSE;

}

void AliTPCROCVoltError3D::GetCorrection(const Float_t x[],const Short_t roc,Float_t dx[]) {
  //
  // Calculates the correction due e.g. residual voltage errors on the TPC boundaries
  //   

  if (!fInitLookUp) {
    AliInfo("Lookup table was not initialized! Perform the inizialisation now ...");
    InitROCVoltError3D();
    return;
  }

  Int_t   order     = 1 ;    // FIXME: hardcoded? Linear interpolation = 1, Quadratic = 2         

  Double_t intEr, intEphi, intDeltaEz;
  Double_t r, phi, z ;
  Int_t    sign;

  r      =  TMath::Sqrt( x[0]*x[0] + x[1]*x[1] ) ;
  phi    =  TMath::ATan2(x[1],x[0]) ;
  if ( phi < 0 ) phi += TMath::TwoPi() ;                   // Table uses phi from 0 to 2*Pi
  z      =  x[2] ;                                         // Create temporary copy of x[2]

  if ( (roc%36) < 18 ) {
    sign =  1;       // (TPC A side)
  } else {
    sign = -1;       // (TPC C side)
  }
  
  if ( sign==1  && z <  fgkZOffSet ) z =  fgkZOffSet;    // Protect against discontinuity at CE
  if ( sign==-1 && z > -fgkZOffSet ) z = -fgkZOffSet;    // Protect against discontinuity at CE
  

  if ( (sign==1 && z<0) || (sign==-1 && z>0) ) // just a consistency check
    AliError("ROC number does not correspond to z coordinate! Calculation of distortions is most likely wrong!");

  // Get the Er and Ephi field integrals plus the integral over DeltaEz 
  intEr      = Interpolate3DTable(order, r, z, phi, kNR, kNZ, kNPhi, 
				  fgkRList, fgkZList, fgkPhiList, fLookUpErOverEz  );
  intEphi    = Interpolate3DTable(order, r, z, phi, kNR, kNZ, kNPhi, 
				  fgkRList, fgkZList, fgkPhiList, fLookUpEphiOverEz);
  intDeltaEz = Interpolate3DTable(order, r, z, phi, kNR, kNZ, kNPhi, 
				  fgkRList, fgkZList, fgkPhiList, fLookUpDeltaEz   );

  //  printf("%lf %lf %lf\n",intEr,intEphi,intDeltaEz);

  // Calculate distorted position
  if ( r > 0.0 ) {
    phi =  phi + ( fC0*intEphi - fC1*intEr ) / r;      
    r   =  r   + ( fC0*intEr   + fC1*intEphi );  
  }
  
  // Calculate correction in cartesian coordinates
  dx[0] = r * TMath::Cos(phi) - x[0];
  dx[1] = r * TMath::Sin(phi) - x[1]; 
  dx[2] = intDeltaEz;  // z distortion - (internally scaled with driftvelocity dependency 
                       // on the Ez field plus the actual ROC misalignment (if set TRUE)


  if (fElectronArrivalCorrection) {

    // correction for the OROC (in average, a 0.014usec longer drift time
    // due to different position of the anode wires) -> vd*dt -> 2.64*0.014 = 0.0369 cm
    // FIXME: correction are token from Magboltz simulations
    //        should be loaded from a database
 
    AliTPCROC * rocInfo = AliTPCROC::Instance();
    Double_t rCrossingROC  =  (rocInfo->GetPadRowRadii(0,62)+rocInfo->GetPadRowRadii(36,0))/2;
  
    if (r>rCrossingROC) {
      if (sign==1)
	dx[2] += 0.0369; // A side - negative correction
      else
	dx[2] -= 0.0369; // C side - positive correction
    }
    
  }

}

void AliTPCROCVoltError3D::InitROCVoltError3D() {
  //
  // Initialization of the Lookup table which contains the solutions of the 
  // Dirichlet boundary problem
  // Calculation of the single 3D-Poisson solver is done just if needed
  // (see basic lookup tables in header file)
  //

  const Int_t   order       =    1  ;  // Linear interpolation = 1, Quadratic = 2  
  const Float_t gridSizeR   =  (fgkOFCRadius-fgkIFCRadius) / (kRows-1) ;
  const Float_t gridSizeZ   =  fgkTPCZ0 / (kColumns-1) ;
  const Float_t gridSizePhi =  TMath::TwoPi() / ( 18.0 * kPhiSlicesPerSector);

  // temporary arrays to create the boundary conditions
  TMatrixD *arrayofArrayV[kPhiSlices], *arrayofCharge[kPhiSlices] ; 
  TMatrixD *arrayofEroverEz[kPhiSlices], *arrayofEphioverEz[kPhiSlices], *arrayofDeltaEz[kPhiSlices] ; 

  for ( Int_t k = 0 ; k < kPhiSlices ; k++ ) {
    arrayofArrayV[k]     =   new TMatrixD(kRows,kColumns) ;
    arrayofCharge[k]     =   new TMatrixD(kRows,kColumns) ;
    arrayofEroverEz[k]   =   new TMatrixD(kRows,kColumns) ;
    arrayofEphioverEz[k] =   new TMatrixD(kRows,kColumns) ;
    arrayofDeltaEz[k]    =   new TMatrixD(kRows,kColumns) ;
  }
  
  // list of point as used in the poisson relation and the interpolation (during sum up)
  Double_t  rlist[kRows], zedlist[kColumns] , philist[kPhiSlices];
  for ( Int_t k = 0 ; k < kPhiSlices ; k++ ) {
    philist[k] =  gridSizePhi * k;
    for ( Int_t i = 0 ; i < kRows ; i++ )    {
      rlist[i] = fgkIFCRadius + i*gridSizeR ;
      for ( Int_t j = 0 ; j < kColumns ; j++ ) { // Fill Vmatrix with Boundary Conditions
	zedlist[j]  = j * gridSizeZ ;
      }
    }
  }

  // ==========================================================================
  // Solve Poisson's equation in 3D cylindrical coordinates by relaxation technique
  // Allow for different size grid spacing in R and Z directions
  
  const Int_t   symmetry = 0;
 
  // Set bondaries and solve Poisson's equation --------------------------
  
  if ( !fInitLookUp ) {
    
    AliInfo(Form("Solving the poisson equation (~ %d sec)",2*10*(int)(kPhiSlices/10)));
    
    for ( Int_t side = 0 ; side < 2 ; side++ ) {  // Solve Poisson3D twice; once for +Z and once for -Z
      
      for ( Int_t k = 0 ; k < kPhiSlices ; k++ )  {
	TMatrixD &arrayV    =  *arrayofArrayV[k] ;
	TMatrixD &charge    =  *arrayofCharge[k] ;
	
	//Fill arrays with initial conditions.  V on the boundary and Charge in the volume.
	for ( Int_t i = 0 ; i < kRows ; i++ ) {
	  for ( Int_t j = 0 ; j < kColumns ; j++ ) {  // Fill Vmatrix with Boundary Conditions
	    arrayV(i,j) = 0.0 ; 
	    charge(i,j) = 0.0 ;

	    Float_t radius0 = rlist[i] ;
	    Float_t phi0    = gridSizePhi * k ;
	    
	    // To avoid problems at sector boundaries, use an average of +- 1 degree from actual phi location
	    if ( j == (kColumns-1) ) 
	      arrayV(i,j) = 0.5*  ( GetROCVoltOffset( side, radius0, phi0+0.02 ) + GetROCVoltOffset( side, radius0, phi0-0.02 ) ) ;

	  }
	}      
	
	for ( Int_t i = 1 ; i < kRows-1 ; i++ ) { 
	  for ( Int_t j = 1 ; j < kColumns-1 ; j++ ) {
	    charge(i,j)  =  0.0 ;
	  }
	}
      }      
      
      // Solve Poisson's equation in 3D cylindrical coordinates by relaxation technique
      // Allow for different size grid spacing in R and Z directions
      
      PoissonRelaxation3D( arrayofArrayV, arrayofCharge, 
			   arrayofEroverEz, arrayofEphioverEz, arrayofDeltaEz,
			   kRows, kColumns, kPhiSlices, gridSizePhi, kIterations, 
			   symmetry, fROCdisplacement) ;
      
      
      //Interpolate results onto a custom grid which is used just for these calculations.
      Double_t  r, phi, z ;
      for ( Int_t k = 0 ; k < kNPhi ; k++ ) {
	phi = fgkPhiList[k] ;
	
	TMatrixD &erOverEz   =  *fLookUpErOverEz[k]  ;
	TMatrixD &ephiOverEz =  *fLookUpEphiOverEz[k];
	TMatrixD &deltaEz    =  *fLookUpDeltaEz[k]   ;
	
	for ( Int_t j = 0 ; j < kNZ ; j++ ) {

	  z = TMath::Abs(fgkZList[j]) ;  // Symmetric solution in Z that depends only on ABS(Z)
  
	  if ( side == 0 &&  fgkZList[j] < 0 ) continue; // Skip rest of this loop if on the wrong side
	  if ( side == 1 &&  fgkZList[j] > 0 ) continue; // Skip rest of this loop if on the wrong side
	  
	  for ( Int_t i = 0 ; i < kNR ; i++ ) { 
	    r = fgkRList[i] ;

	    // Interpolate basicLookup tables; once for each rod, then sum the results
	    erOverEz(i,j)   = Interpolate3DTable(order, r, z, phi, kRows, kColumns, kPhiSlices, 
						 rlist, zedlist, philist, arrayofEroverEz  );
	    ephiOverEz(i,j) = Interpolate3DTable(order, r, z, phi, kRows, kColumns, kPhiSlices,
						 rlist, zedlist, philist, arrayofEphioverEz);
	    deltaEz(i,j)    = Interpolate3DTable(order, r, z, phi, kRows, kColumns, kPhiSlices,
						 rlist, zedlist, philist, arrayofDeltaEz  );

	    if (side == 1)  deltaEz(i,j) = -  deltaEz(i,j); // negative coordinate system on C side

	  } // end r loop
	}// end z loop
      }// end phi loop

      if ( side == 0 ) AliInfo(" A side done");
      if ( side == 1 ) AliInfo(" C side done");
    } // end side loop
  }
  
  // clear the temporary arrays lists
  for ( Int_t k = 0 ; k < kPhiSlices ; k++ )  {
    delete arrayofArrayV[k];
    delete arrayofCharge[k];
    delete arrayofEroverEz[k];  
    delete arrayofEphioverEz[k];
    delete arrayofDeltaEz[k];
  }
 

  fInitLookUp = kTRUE;

}


Float_t AliTPCROCVoltError3D::GetROCVoltOffset(Int_t side, Float_t r0, Float_t phi0) {
  // 
  // Returns the dz alignment data (in voltage equivalents) at 
  // the given position
  //

  Float_t xp = r0*TMath::Cos(phi0);
  Float_t yp = r0*TMath::Sin(phi0);
  
  // phi0 should be between 0 and 2pi 
  if (phi0<0) phi0+=TMath::TwoPi();
  Int_t roc = (Int_t)TMath::Floor((TMath::RadToDeg()*phi0)/20);
  if (side==1) roc+=18; // C side
  if (r0>132) roc+=36;  // OROC 
  
  // linear-plane data:  z = z0 + kx*lx + ky*ly (rotation in local coordinates)
  TMatrixD &fitData = *fdzDataLinFit;

  // local coordinates                                                          
  Double_t secAlpha = TMath::DegToRad()*(10.+20.*(((Int_t)roc)%18));
  Float_t lx = xp*TMath::Cos(secAlpha)+yp*TMath::Sin(secAlpha);
  Float_t ly = yp*TMath::Cos(secAlpha)-xp*TMath::Sin(secAlpha);

  // reference of rotation in lx is at the intersection between OROC and IROC
  // necessary, since the Fitprozedure is otherwise useless
  
  AliTPCROC * rocInfo = AliTPCROC::Instance();
  Double_t lxRef  = (rocInfo->GetPadRowRadii(0,62)+rocInfo->GetPadRowRadii(36,0))/2;
  
  Float_t dz = fitData(roc,0)+fitData(roc,1)*(lx-lxRef) + fitData(roc,2)*ly; // value in cm

  // aproximated Voltage-offset-aquivalent to the z misalignment
  // (linearly scaled with the z position)
  Double_t ezField = (fgkCathodeV-fgkGG)/fgkTPCZ0; // = ALICE Electric Field (V/cm) Magnitude ~ -400 V/cm; 
  Float_t voltOff = dz*ezField;            // values in "Volt equivalents"

  return voltOff;
}

TH2F * AliTPCROCVoltError3D::CreateHistoOfZAlignment(Int_t side, Int_t nx, Int_t ny) {
  //
  // return a simple histogramm containing the input to the poisson solver
  // (z positions of the Read-out chambers, linearly interpolated)

  char hname[100];
  if (side==0) sprintf(hname,"survey_dz_Aside");
  if (side==1) sprintf(hname,"survey_dz_Cside");

  TH2F *h = new TH2F(hname,hname,nx,-250.,250.,ny,-250.,250.);

  for (Int_t iy=1;iy<=ny;++iy) {
    Double_t yp = h->GetYaxis()->GetBinCenter(iy);
    for (Int_t ix=1;ix<=nx;++ix) {
      Double_t xp = h->GetXaxis()->GetBinCenter(ix);
    
      Float_t r0 = TMath::Sqrt(xp*xp+yp*yp);
      Float_t phi0 = TMath::ATan2(yp,xp); 
   
      Float_t dz = GetROCVoltOffset(side,r0,phi0); // in [volt]

      Double_t ezField = (fgkCathodeV-fgkGG)/fgkTPCZ0; // = ALICE Electric Field (V/cm) Magnitude ~ -400 V/cm; 
      dz = dz/ezField;    // in [cm]

      if (85.<=r0 && r0<=245.) {
	h->SetBinContent(ix,iy,dz); 
      } else {
	h->SetBinContent(ix,iy,0.);
      }
    }
  }
  
  h->GetXaxis()->SetTitle("x [cm]");
  h->GetYaxis()->SetTitle("y [cm]");
  h->GetZaxis()->SetTitle("dz [cm]");
  h->SetStats(0);
  //  h->DrawCopy("colz");

  return h;
} 

void AliTPCROCVoltError3D::Print(const Option_t* option) const {
  //
  // Print function to check the settings of the Rod shifts and the rotated clips
  // option=="a" prints the C0 and C1 coefficents for calibration purposes
  //

  TString opt = option; opt.ToLower();
  printf("%s\n",GetTitle());
  printf(" - z aligmnet of the TPC Read-Out chambers \n");
  printf("   (linear interpolation within the chamber:  dz = z0 + kx*(lx-133) + ky*ly [cm] ) \n");
  printf("   Info: Check the following data-file for more details: %s \n",fROCDataFileName.Data());

  if (opt.Contains("a")) { // Print all details
    TMatrixD &fitData = *fdzDataLinFit;
    printf(" A side:  IROC   ROCX=(z0,kx,ky): \n");
    for (Int_t roc = 0; roc<18; roc++) 
      printf("ROC%d:(%.2e,%.2e,%.2e) ",roc,fitData(roc,0),fitData(roc,1),fitData(roc,2));
    printf("\n A side:  OROC   ROCX=(z0,kx,ky): \n");
    for (Int_t roc = 36; roc<54; roc++) 
      printf("ROC%d:(%.2e,%.2e,%.2e) ",roc,fitData(roc,0),fitData(roc,1),fitData(roc,2));
    printf("\n C side:  IROC   ROCX=(z0,kx,ky): \n");
    for (Int_t roc = 18; roc<36; roc++) 
      printf("ROC%d:(%.2e,%.2e,%.2e) ",roc,fitData(roc,0),fitData(roc,1),fitData(roc,2));
    printf("\n C side:  OROC   ROCX=(z0,kx,ky): \n");
    for (Int_t roc = 54; roc<72; roc++) 
      printf("ROC%d:(%.2e,%.2e,%.2e) ",roc,fitData(roc,0),fitData(roc,1),fitData(roc,2));
    printf("\n\n");
    printf(" - T1: %1.4f, T2: %1.4f \n",fT1,fT2);
    printf(" - C1: %1.4f, C0: %1.4f \n",fC1,fC0);
  }

  if (!fInitLookUp) AliError("Lookup table was not initialized! You should do InitROCVoltError3D() ...");

}
Commit	Line	Data
c9cbd2f2	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	// //
	18	// AliTPCROCVoltError3D class //
	19	// The class calculates the space point distortions due to residual voltage //
	20	// errors on Read Out Chambers of the TPC in 3D. //
	21	// //
	22	// The class allows "effective Omega Tau" corrections. //
	23	// //
	24	// NOTE: This class is capable of calculating z distortions due to //
	25	// misalignment and the vd dependency on the residual drift field //
	26	// //
	27	// date: 08/08/2010 //
	28	// Authors: Jim Thomas, Stefan Rossegger //
	29	// //
	30	// Example usage : //
	31	// AliTPCROCVoltError3D ROCerror; //
	32	//////////////////////////////////////////////////////////////////////////////
	33
	34	#include "AliMagF.h"
	35	#include "TGeoGlobalMagField.h"
	36	#include "AliTPCcalibDB.h"
	37	#include "AliTPCParam.h"
	38	#include "AliLog.h"
	39	#include "TMatrixD.h"
	40	#include "TFile.h"
	41
	42	#include "TMath.h"
	43	#include "AliTPCROC.h"
	44	#include "AliTPCROCVoltError3D.h"
	45
	46	ClassImp(AliTPCROCVoltError3D)
	47
	48	AliTPCROCVoltError3D::AliTPCROCVoltError3D()
	49	: AliTPCCorrection("ROCVoltErrors","ROC z alignment Errors"),
	50	fC0(0.),fC1(0.),
	51	fROCdisplacement(kTRUE),
7a348589	52	fElectronArrivalCorrection(kTRUE),
c9cbd2f2	53	fInitLookUp(kFALSE),
acf5907b	54	fROCDataFileName(""),
c9cbd2f2	55	fdzDataLinFit(0)
	56	{
	57	//
	58	// default constructor
	59	//
	60
	61	// Array which will contain the solution according to the setted boundary conditions
	62	// main input: z alignment of the Read Out chambers
	63	// see InitROCVoltError3D() function
	64	for ( Int_t k = 0 ; k < kNPhi ; k++ ) {
	65	fLookUpErOverEz[k] = new TMatrixD(kNR,kNZ);
	66	fLookUpEphiOverEz[k] = new TMatrixD(kNR,kNZ);
	67	fLookUpDeltaEz[k] = new TMatrixD(kNR,kNZ);
	68	}
acf5907b	69	fROCDataFileName="$ALICE_ROOT/TPC/Calib/maps/TPCROCdzSurvey.root";
acf5907b	70	SetROCDataFileName(fROCDataFileName.Data()); // initialization of fdzDataLinFit is included
c9cbd2f2	71
	72	}
	73
	74	AliTPCROCVoltError3D::~AliTPCROCVoltError3D() {
	75	//
	76	// destructor
	77	//
	78
	79	for ( Int_t k = 0 ; k < kNPhi ; k++ ) {
	80	delete fLookUpErOverEz[k];
	81	delete fLookUpEphiOverEz[k];
	82	delete fLookUpDeltaEz[k];
	83	}
	84
	85	delete fdzDataLinFit;
	86	}
	87
acf5907b	88	void AliTPCROCVoltError3D::SetROCData(TMatrixD * matrix){
2bbac918	89	//
c756f562	90	// Set a z alignment map of the chambers not via a file, but
7a348589	91	// directly via a TMatrix(72,3), where dz = p0 + p1(lx-133.4) + p2ly (all in cm)
2bbac918	92	//
	93	if (!fdzDataLinFit) fdzDataLinFit=new TMatrixD(*matrix);
	94	else fdzDataLinFit = matrix;
	95	}
	96
	97
c9cbd2f2	98	void AliTPCROCVoltError3D::Init() {
	99	//
	100	// Initialization funtion
	101	//
	102
	103	AliMagF* magF= (AliMagF*)TGeoGlobalMagField::Instance()->GetField();
	104	if (!magF) AliError("Magneticd field - not initialized");
	105	Double_t bzField = magF->SolenoidField()/10.; //field in T
	106	AliTPCParam *param= AliTPCcalibDB::Instance()->GetParameters();
	107	if (!param) AliError("Parameters - not initialized");
	108	Double_t vdrift = param->GetDriftV()/1000000.; // [cm/us] // From dataBase: to be updated: per second (ideally)
	109	Double_t ezField = 400; // [V/cm] // to be updated: never (hopefully)
	110	Double_t wt = -10.0 * (bzField10) vdrift / ezField ;
	111	// Correction Terms for effective omegaTau; obtained by a laser calibration run
	112	SetOmegaTauT1T2(wt,fT1,fT2);
	113
35ae345f	114	if (!fInitLookUp) InitROCVoltError3D();
c9cbd2f2	115	}
	116
	117	void AliTPCROCVoltError3D::Update(const TTimeStamp &/timeStamp/) {
	118	//
	119	// Update function
	120	//
	121	AliMagF* magF= (AliMagF*)TGeoGlobalMagField::Instance()->GetField();
	122	if (!magF) AliError("Magneticd field - not initialized");
	123	Double_t bzField = magF->SolenoidField()/10.; //field in T
	124	AliTPCParam *param= AliTPCcalibDB::Instance()->GetParameters();
	125	if (!param) AliError("Parameters - not initialized");
	126	Double_t vdrift = param->GetDriftV()/1000000.; // [cm/us] // From dataBase: to be updated: per second (ideally)
	127	Double_t ezField = 400; // [V/cm] // to be updated: never (hopefully)
	128	Double_t wt = -10.0 * (bzField10) vdrift / ezField ;
	129	// Correction Terms for effective omegaTau; obtained by a laser calibration run
	130	SetOmegaTauT1T2(wt,fT1,fT2);
	131
	132	}
	133
acf5907b	134	void AliTPCROCVoltError3D::SetROCDataFileName(const char * fname) {
c9cbd2f2	135	//
	136	// Set / load the ROC data (linear fit of ROC misalignments)
	137	//
	138
	139	fROCDataFileName = fname;
	140
acf5907b	141	TFile f(fROCDataFileName.Data(),"READ");
c9cbd2f2	142	TMatrixD m = (TMatrixD) f.Get("dzSurveyLinFitData");
	143	TMatrixD &mf = *m;
	144
	145	// prepare some space
	146
	147	if (fdzDataLinFit) delete fdzDataLinFit;
	148	fdzDataLinFit = new TMatrixD(72,3);
	149	TMatrixD &dataIntern = *fdzDataLinFit;
	150
	151	for (Int_t iroc=0;iroc<72;iroc++) {
	152	dataIntern(iroc,0) = mf(iroc,0); // z0 offset
	153	dataIntern(iroc,1) = mf(iroc,1); // slope in x
	154	dataIntern(iroc,2) = mf(iroc,2); // slope in y
	155	}
	156
	157	f.Close();
	158
	159	fInitLookUp = kFALSE;
	160
	161	}
	162
	163	void AliTPCROCVoltError3D::GetCorrection(const Float_t x[],const Short_t roc,Float_t dx[]) {
	164	//
	165	// Calculates the correction due e.g. residual voltage errors on the TPC boundaries
	166	//
	167
	168	if (!fInitLookUp) {
	169	AliInfo("Lookup table was not initialized! Perform the inizialisation now ...");
	170	InitROCVoltError3D();
	171	return;
	172	}
	173
7a348589	174	Int_t order = 1 ; // FIXME: hardcoded? Linear interpolation = 1, Quadratic = 2
c9cbd2f2	175
	176	Double_t intEr, intEphi, intDeltaEz;
	177	Double_t r, phi, z ;
	178	Int_t sign;
	179
	180	r = TMath::Sqrt( x[0]x[0] + x[1]x[1] ) ;
	181	phi = TMath::ATan2(x[1],x[0]) ;
	182	if ( phi < 0 ) phi += TMath::TwoPi() ; // Table uses phi from 0 to 2*Pi
	183	z = x[2] ; // Create temporary copy of x[2]
	184
	185	if ( (roc%36) < 18 ) {
	186	sign = 1; // (TPC A side)
	187	} else {
	188	sign = -1; // (TPC C side)
	189	}
	190
	191	if ( sign==1 && z < fgkZOffSet ) z = fgkZOffSet; // Protect against discontinuity at CE
	192	if ( sign==-1 && z > -fgkZOffSet ) z = -fgkZOffSet; // Protect against discontinuity at CE
	193
	194
	195	if ( (sign==1 && z<0) \|\| (sign==-1 && z>0) ) // just a consistency check
	196	AliError("ROC number does not correspond to z coordinate! Calculation of distortions is most likely wrong!");
	197
	198	// Get the Er and Ephi field integrals plus the integral over DeltaEz
	199	intEr = Interpolate3DTable(order, r, z, phi, kNR, kNZ, kNPhi,
	200	fgkRList, fgkZList, fgkPhiList, fLookUpErOverEz );
	201	intEphi = Interpolate3DTable(order, r, z, phi, kNR, kNZ, kNPhi,
	202	fgkRList, fgkZList, fgkPhiList, fLookUpEphiOverEz);
	203	intDeltaEz = Interpolate3DTable(order, r, z, phi, kNR, kNZ, kNPhi,
	204	fgkRList, fgkZList, fgkPhiList, fLookUpDeltaEz );
	205
	206	// printf("%lf %lf %lf\n",intEr,intEphi,intDeltaEz);
	207
	208	// Calculate distorted position
	209	if ( r > 0.0 ) {
	210	phi = phi + ( fC0intEphi - fC1intEr ) / r;
	211	r = r + ( fC0intEr + fC1intEphi );
	212	}
	213
	214	// Calculate correction in cartesian coordinates
	215	dx[0] = r * TMath::Cos(phi) - x[0];
	216	dx[1] = r * TMath::Sin(phi) - x[1];
	217	dx[2] = intDeltaEz; // z distortion - (internally scaled with driftvelocity dependency
	218	// on the Ez field plus the actual ROC misalignment (if set TRUE)
	219
7a348589	220
	221	if (fElectronArrivalCorrection) {
	222
	223	// correction for the OROC (in average, a 0.014usec longer drift time
	224	// due to different position of the anode wires) -> vddt -> 2.640.014 = 0.0369 cm
	225	// FIXME: correction are token from Magboltz simulations
	226	// should be loaded from a database
	227
	228	AliTPCROC * rocInfo = AliTPCROC::Instance();
	229	Double_t rCrossingROC = (rocInfo->GetPadRowRadii(0,62)+rocInfo->GetPadRowRadii(36,0))/2;
	230
	231	if (r>rCrossingROC) {
	232	if (sign==1)
	233	dx[2] += 0.0369; // A side - negative correction
	234	else
	235	dx[2] -= 0.0369; // C side - positive correction
	236	}
	237
	238	}
	239
c9cbd2f2	240	}
	241
	242	void AliTPCROCVoltError3D::InitROCVoltError3D() {
	243	//
	244	// Initialization of the Lookup table which contains the solutions of the
	245	// Dirichlet boundary problem
	246	// Calculation of the single 3D-Poisson solver is done just if needed
	247	// (see basic lookup tables in header file)
	248	//
	249
	250	const Int_t order = 1 ; // Linear interpolation = 1, Quadratic = 2
	251	const Float_t gridSizeR = (fgkOFCRadius-fgkIFCRadius) / (kRows-1) ;
	252	const Float_t gridSizeZ = fgkTPCZ0 / (kColumns-1) ;
	253	const Float_t gridSizePhi = TMath::TwoPi() / ( 18.0 * kPhiSlicesPerSector);
	254
	255	// temporary arrays to create the boundary conditions
	256	TMatrixD arrayofArrayV[kPhiSlices], arrayofCharge[kPhiSlices] ;
	257	TMatrixD arrayofEroverEz[kPhiSlices], arrayofEphioverEz[kPhiSlices], *arrayofDeltaEz[kPhiSlices] ;
	258
	259	for ( Int_t k = 0 ; k < kPhiSlices ; k++ ) {
	260	arrayofArrayV[k] = new TMatrixD(kRows,kColumns) ;
	261	arrayofCharge[k] = new TMatrixD(kRows,kColumns) ;
	262	arrayofEroverEz[k] = new TMatrixD(kRows,kColumns) ;
	263	arrayofEphioverEz[k] = new TMatrixD(kRows,kColumns) ;
	264	arrayofDeltaEz[k] = new TMatrixD(kRows,kColumns) ;
	265	}
	266
	267	// list of point as used in the poisson relation and the interpolation (during sum up)
	268	Double_t rlist[kRows], zedlist[kColumns] , philist[kPhiSlices];
	269	for ( Int_t k = 0 ; k < kPhiSlices ; k++ ) {
	270	philist[k] = gridSizePhi * k;
	271	for ( Int_t i = 0 ; i < kRows ; i++ ) {
	272	rlist[i] = fgkIFCRadius + i*gridSizeR ;
	273	for ( Int_t j = 0 ; j < kColumns ; j++ ) { // Fill Vmatrix with Boundary Conditions
	274	zedlist[j] = j * gridSizeZ ;
	275	}
	276	}
	277	}
	278
	279	// ==========================================================================
	280	// Solve Poisson's equation in 3D cylindrical coordinates by relaxation technique
	281	// Allow for different size grid spacing in R and Z directions
	282
	283	const Int_t symmetry = 0;
	284
	285	// Set bondaries and solve Poisson's equation --------------------------
	286
	287	if ( !fInitLookUp ) {
	288
	289	AliInfo(Form("Solving the poisson equation (~ %d sec)",210(int)(kPhiSlices/10)));
	290
	291	for ( Int_t side = 0 ; side < 2 ; side++ ) { // Solve Poisson3D twice; once for +Z and once for -Z
	292
	293	for ( Int_t k = 0 ; k < kPhiSlices ; k++ ) {
	294	TMatrixD &arrayV = *arrayofArrayV[k] ;
	295	TMatrixD &charge = *arrayofCharge[k] ;
	296
	297	//Fill arrays with initial conditions. V on the boundary and Charge in the volume.
	298	for ( Int_t i = 0 ; i < kRows ; i++ ) {
	299	for ( Int_t j = 0 ; j < kColumns ; j++ ) { // Fill Vmatrix with Boundary Conditions
	300	arrayV(i,j) = 0.0 ;
	301	charge(i,j) = 0.0 ;
	302
	303	Float_t radius0 = rlist[i] ;
304	Float_t phi0 = gridSizePhi * k ;
305
306	// To avoid problems at sector boundaries, use an average of +- 1 degree from actual phi location
307	if ( j == (kColumns-1) )
308	arrayV(i,j) = 0.5* ( GetROCVoltOffset( side, radius0, phi0+0.02 ) + GetROCVoltOffset( side, radius0, phi0-0.02 ) ) ;
309
310	}
311	}
312
313	for ( Int_t i = 1 ; i < kRows-1 ; i++ ) {
314	for ( Int_t j = 1 ; j < kColumns-1 ; j++ ) {
315	charge(i,j) = 0.0 ;
316	}
317	}
318	}
319
320	// Solve Poisson's equation in 3D cylindrical coordinates by relaxation technique
321	// Allow for different size grid spacing in R and Z directions
322
323	PoissonRelaxation3D( arrayofArrayV, arrayofCharge,
324	arrayofEroverEz, arrayofEphioverEz, arrayofDeltaEz,
325	kRows, kColumns, kPhiSlices, gridSizePhi, kIterations,
326	symmetry, fROCdisplacement) ;
327
328
329	//Interpolate results onto a custom grid which is used just for these calculations.
330	Double_t r, phi, z ;
331	for ( Int_t k = 0 ; k < kNPhi ; k++ ) {
332	phi = fgkPhiList[k] ;
333
334	TMatrixD &erOverEz = *fLookUpErOverEz[k] ;
335	TMatrixD &ephiOverEz = *fLookUpEphiOverEz[k];
336	TMatrixD &deltaEz = *fLookUpDeltaEz[k] ;
337
338	for ( Int_t j = 0 ; j < kNZ ; j++ ) {
339
340	z = TMath::Abs(fgkZList[j]) ; // Symmetric solution in Z that depends only on ABS(Z)
341
342	if ( side == 0 && fgkZList[j] < 0 ) continue; // Skip rest of this loop if on the wrong side
343	if ( side == 1 && fgkZList[j] > 0 ) continue; // Skip rest of this loop if on the wrong side
344
345	for ( Int_t i = 0 ; i < kNR ; i++ ) {
346	r = fgkRList[i] ;
347
348	// Interpolate basicLookup tables; once for each rod, then sum the results
349	erOverEz(i,j) = Interpolate3DTable(order, r, z, phi, kRows, kColumns, kPhiSlices,
350	rlist, zedlist, philist, arrayofEroverEz );
351	ephiOverEz(i,j) = Interpolate3DTable(order, r, z, phi, kRows, kColumns, kPhiSlices,
352	rlist, zedlist, philist, arrayofEphioverEz);
353	deltaEz(i,j) = Interpolate3DTable(order, r, z, phi, kRows, kColumns, kPhiSlices,
354	rlist, zedlist, philist, arrayofDeltaEz );
355
356	if (side == 1) deltaEz(i,j) = - deltaEz(i,j); // negative coordinate system on C side
357
358	} // end r loop
359	}// end z loop
360	}// end phi loop
361
362	if ( side == 0 ) AliInfo(" A side done");
363	if ( side == 1 ) AliInfo(" C side done");
364	} // end side loop
365	}
366
367	// clear the temporary arrays lists
368	for ( Int_t k = 0 ; k < kPhiSlices ; k++ ) {
369	delete arrayofArrayV[k];
370	delete arrayofCharge[k];
371	delete arrayofEroverEz[k];
372	delete arrayofEphioverEz[k];
373	delete arrayofDeltaEz[k];
374	}
375
376
377	fInitLookUp = kTRUE;
378
379	}
380
381
382	Float_t AliTPCROCVoltError3D::GetROCVoltOffset(Int_t side, Float_t r0, Float_t phi0) {
383	//
384	// Returns the dz alignment data (in voltage equivalents) at
385	// the given position
386	//
387
388	Float_t xp = r0*TMath::Cos(phi0);
389	Float_t yp = r0*TMath::Sin(phi0);
390
391	// phi0 should be between 0 and 2pi
392	if (phi0<0) phi0+=TMath::TwoPi();
393	Int_t roc = (Int_t)TMath::Floor((TMath::RadToDeg()*phi0)/20);
394	if (side==1) roc+=18; // C side
395	if (r0>132) roc+=36; // OROC
396
c756f562	397	// linear-plane data: z = z0 + kxlx + kyly (rotation in local coordinates)
c9cbd2f2	398	TMatrixD &fitData = *fdzDataLinFit;
c756f562	399
	400	// local coordinates
	401	Double_t secAlpha = TMath::DegToRad()(10.+20.(((Int_t)roc)%18));
	402	Float_t lx = xpTMath::Cos(secAlpha)+ypTMath::Sin(secAlpha);
	403	Float_t ly = ypTMath::Cos(secAlpha)-xpTMath::Sin(secAlpha);
	404
7a348589	405	// reference of rotation in lx is at the intersection between OROC and IROC
	406	// necessary, since the Fitprozedure is otherwise useless
	407
	408	AliTPCROC * rocInfo = AliTPCROC::Instance();
	409	Double_t lxRef = (rocInfo->GetPadRowRadii(0,62)+rocInfo->GetPadRowRadii(36,0))/2;
	410
	411	Float_t dz = fitData(roc,0)+fitData(roc,1)(lx-lxRef) + fitData(roc,2)ly; // value in cm
c9cbd2f2	412
	413	// aproximated Voltage-offset-aquivalent to the z misalignment
	414	// (linearly scaled with the z position)
	415	Double_t ezField = (fgkCathodeV-fgkGG)/fgkTPCZ0; // = ALICE Electric Field (V/cm) Magnitude ~ -400 V/cm;
	416	Float_t voltOff = dz*ezField; // values in "Volt equivalents"
	417
	418	return voltOff;
	419	}
	420
7a348589	421	TH2F * AliTPCROCVoltError3D::CreateHistoOfZAlignment(Int_t side, Int_t nx, Int_t ny) {
c9cbd2f2	422	//
	423	// return a simple histogramm containing the input to the poisson solver
	424	// (z positions of the Read-out chambers, linearly interpolated)
	425
	426	char hname[100];
	427	if (side==0) sprintf(hname,"survey_dz_Aside");
	428	if (side==1) sprintf(hname,"survey_dz_Cside");
	429
	430	TH2F *h = new TH2F(hname,hname,nx,-250.,250.,ny,-250.,250.);
	431
	432	for (Int_t iy=1;iy<=ny;++iy) {
	433	Double_t yp = h->GetYaxis()->GetBinCenter(iy);
	434	for (Int_t ix=1;ix<=nx;++ix) {
	435	Double_t xp = h->GetXaxis()->GetBinCenter(ix);
	436
	437	Float_t r0 = TMath::Sqrt(xpxp+ypyp);
	438	Float_t phi0 = TMath::ATan2(yp,xp);
	439
	440	Float_t dz = GetROCVoltOffset(side,r0,phi0); // in [volt]
	441
	442	Double_t ezField = (fgkCathodeV-fgkGG)/fgkTPCZ0; // = ALICE Electric Field (V/cm) Magnitude ~ -400 V/cm;
	443	dz = dz/ezField; // in [cm]
	444
	445	if (85.<=r0 && r0<=245.) {
	446	h->SetBinContent(ix,iy,dz);
	447	} else {
	448	h->SetBinContent(ix,iy,0.);
	449	}
	450	}
	451	}
	452
	453	h->GetXaxis()->SetTitle("x [cm]");
	454	h->GetYaxis()->SetTitle("y [cm]");
	455	h->GetZaxis()->SetTitle("dz [cm]");
	456	h->SetStats(0);
	457	// h->DrawCopy("colz");
	458
	459	return h;
	460	}
	461
	462	void AliTPCROCVoltError3D::Print(const Option_t* option) const {
	463	//
	464	// Print function to check the settings of the Rod shifts and the rotated clips
	465	// option=="a" prints the C0 and C1 coefficents for calibration purposes
	466	//
	467
	468	TString opt = option; opt.ToLower();
	469	printf("%s\n",GetTitle());
7a348589	470	printf(" - z aligmnet of the TPC Read-Out chambers \n");
	471	printf(" (linear interpolation within the chamber: dz = z0 + kx(lx-133) + kyly [cm] ) \n");
	472	printf(" Info: Check the following data-file for more details: %s \n",fROCDataFileName.Data());
c9cbd2f2	473
c9cbd2f2	474	if (opt.Contains("a")) { // Print all details
7a348589	475	TMatrixD &fitData = *fdzDataLinFit;
	476	printf(" A side: IROC ROCX=(z0,kx,ky): \n");
	477	for (Int_t roc = 0; roc<18; roc++)
	478	printf("ROC%d:(%.2e,%.2e,%.2e) ",roc,fitData(roc,0),fitData(roc,1),fitData(roc,2));
	479	printf("\n A side: OROC ROCX=(z0,kx,ky): \n");
	480	for (Int_t roc = 36; roc<54; roc++)
	481	printf("ROC%d:(%.2e,%.2e,%.2e) ",roc,fitData(roc,0),fitData(roc,1),fitData(roc,2));
	482	printf("\n C side: IROC ROCX=(z0,kx,ky): \n");
	483	for (Int_t roc = 18; roc<36; roc++)
	484	printf("ROC%d:(%.2e,%.2e,%.2e) ",roc,fitData(roc,0),fitData(roc,1),fitData(roc,2));
	485	printf("\n C side: OROC ROCX=(z0,kx,ky): \n");
	486	for (Int_t roc = 54; roc<72; roc++)
	487	printf("ROC%d:(%.2e,%.2e,%.2e) ",roc,fitData(roc,0),fitData(roc,1),fitData(roc,2));
	488	printf("\n\n");
c9cbd2f2	489	printf(" - T1: %1.4f, T2: %1.4f \n",fT1,fT2);
	490	printf(" - C1: %1.4f, C0: %1.4f \n",fC1,fC0);
	491	}
	492
	493	if (!fInitLookUp) AliError("Lookup table was not initialized! You should do InitROCVoltError3D() ...");
	494
	495	}