The operator[] is replaced by At() or AddAt() in case of TObjArray.

[u/mrichter/AliRoot.git] / RICH / AliRICHEllipse.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.                  *
 **************************************************************************/

/*
  $Log$
  Revision 1.3  2000/11/01 15:37:44  jbarbosa
  Removed verbose output.

  Revision 1.2  2000/06/30 16:31:51  dibari
  New drawing routine from Nico and Daniela.

  Revision 1.1  2000/06/12 15:21:57  jbarbosa
  Cleaned up version.

*/

#include "AliRICHEllipse.h"
#include "AliRICH.h"
#include "AliRun.h"
#include "AliRICHPatRec.h"

#include <TRandom.h>

ClassImp(AliRICHEllipse)

//________________________________________________________________________________
AliRICHEllipse::AliRICHEllipse()
{ 

//  Default Constructor for a RICH ellipse

    fCx = 0;
    fCy = 0;
    fOmega = 0;
    fTheta = 0;
    fPhi = 0;
    fh= 0;
}

//________________________________________________________________________________
AliRICHEllipse::~AliRICHEllipse()
{ 

// Destructor

    fCx = 0;
    fCy = 0;
    fOmega = 0;
    fTheta = 0;
    fPhi = 0;
    fh= 0;
}


//________________________________________________________________________________
AliRICHEllipse::AliRICHEllipse(Float_t cx, Float_t cy, Float_t omega, Float_t theta, Float_t phi, Float_t emiss)
{ 

//  Constructor for a RICH ellipse

    fCx = cx;
    fCy = cy;
    fOmega = omega;
    fTheta = theta;
    fPhi = phi;
    fEmissPoint = emiss;
    fh=9.25;
}

//________________________________________________________________________________
/*void AliRICHEllipse::CreatePoints(Int_t chamber)
{

// Create points along the ellipse equation

  Int_t s1,s2;
  Float_t fiducial=fh*TMath::Tan(fOmega+fTheta), l=fh/TMath::Cos(fTheta), xtrial, y=0, c0, c1, c2;
  //TRandom *random=new TRandom();

  AliRICH *pRICH  = (AliRICH*)gAlice->GetModule("RICH");
  AliRICHChamber*       iChamber;
  
  iChamber = &(pRICH->Chamber(chamber));
  //cout<<"fiducial="<<fiducial<<endl;
  
  for(Float_t i=0;i<1000;i++)
    {
      
      Float_t counter=0;
      
      c0=0;c1=0;c2=0;
      while((c1*c1-4*c2*c0)<=0 && counter<1000)
        {
          //Choose which side to go...
          if(i>250 && i<750) s1=1; 
          //if (gRandom->Rndm(1)>.5) s1=1;
          else s1=-1;
          //printf("s1:%d\n",s1);
          //Trial a y
          y=s1*i*gRandom->Rndm(Int_t(fiducial/50));
          //printf("Fiducial %f  for omega:%f theta:%f phi:%f\n",fiducial,fOmega,fTheta,fPhi);
          Float_t alfa1=fTheta;
          Float_t theta1=fPhi;
          Float_t omega1=fOmega;
          
          //Solve the eq for a trial x
          c0=-TMath::Power(y*TMath::Cos(alfa1)*TMath::Cos(theta1),2)-TMath::Power(y*TMath::Sin(alfa1),2)+TMath::Power(l*TMath::Tan(omega1),2)+2*l*y*TMath::Cos(alfa1)*TMath::Sin(theta1)*TMath::Power(TMath::Tan(omega1),2)+TMath::Power(y*TMath::Cos(alfa1)*TMath::Sin(theta1)*TMath::Tan(omega1),2);
          c1=2*y*TMath::Cos(alfa1)*TMath::Sin(alfa1)-2*y*TMath::Cos(alfa1)*TMath::Power(TMath::Cos(theta1),2)*TMath::Sin(alfa1)+2*l*TMath::Sin(alfa1)*TMath::Sin(theta1)*TMath::Power(TMath::Tan(omega1),2)+2*y*TMath::Cos(alfa1)*TMath::Sin(alfa1)*TMath::Power(TMath::Sin(theta1),2)*TMath::Power(TMath::Tan(omega1),2);
          c2=-TMath::Power(TMath::Cos(alfa1),2)-TMath::Power(TMath::Cos(theta1)*TMath::Sin(alfa1),2)+TMath::Power(TMath::Sin(alfa1)*TMath::Sin(theta1)*TMath::Tan(omega1),2);
          //cout<<"Trial: y="<<y<<"c0="<<c0<<" c1="<<c1<<" c2="<<c2<<endl;
          //printf("Result:%f\n\n",c1*c1-4*c2*c0);
          //i+=.01;
          counter +=1;
        }
      
      if (counter>=1000)
        y=0; 

      //Choose which side to go...
      //if(gRandom->Rndm(1)>.5) s=1; 
      //else s=-1;
      if(i>500) s2=1;
      //if (gRandom->Rndm(1)>.5) s2=1;
      else s2=-1;
      xtrial=fCx+(-c1+s2*TMath::Sqrt(c1*c1-4*c2*c0))/(2*c2);
      //cout<<"x="<<xtrial<<" y="<<cy+y<<endl;
      //printf("Coordinates: %f %f\n",xtrial,fCy+y);

      Float_t vectorLoc[3]={xtrial,6.276,(fCy+y)};
      Float_t  vectorGlob[3];
      iChamber->LocaltoGlobal(vectorLoc,vectorGlob);
      SetPoint(i,vectorGlob[0],vectorGlob[1],vectorGlob[2]);
      //printf("Coordinates: %f %f %f\n",vectorGlob[0],vectorGlob[1],vectorGlob[2]);
    }
    }*/


void AliRICHEllipse::CerenkovRingDrawing(Int_t chamber,Int_t track)
{

//to draw Cherenkov ring by known Cherenkov angle

  Int_t nmaxdegrees;
  Int_t Nphpad;
  Float_t phpad;
  Float_t nfreonave, nquartzave;
  Float_t aveEnerg;
  Float_t energy[2];
  Float_t e1, e2, f1, f2;
  Float_t pointsOnCathode[3];

  //printf("Drawing ring in chamber:%d\n",chamber);


  AliRICH *pRICH  = (AliRICH*)gAlice->GetModule("RICH");
  AliRICHChamber*       iChamber;
  
  iChamber = &(pRICH->Chamber(chamber));

  AliRICHPatRec *PatRec = new AliRICHPatRec;
  PatRec->TrackParam(track,chamber,fTheta,fOmega);

  //printf("Just created PateRec\n");

//parameters to calculate freon window refractive index vs. energy

    Float_t a = 1.177;
    Float_t b = 0.0172;
    
//parameters to calculate quartz window refractive index vs. energy
/*
   Energ[0]  = 5.6;
   Energ[1]  = 7.7;
*/      
    energy[0]  = 5.0;
    energy[1]  = 8.0;
    e1  = 10.666;
    e2  = 18.125;
    f1  = 46.411;
    f2  = 228.71;
  

    /*Float_t nquartz = 1.585;
      Float_t ngas    = 1.;
      Float_t nfreon  = 1.295;
      Float_t value;
    */



   nmaxdegrees = 360;
   
   for (Nphpad=0; Nphpad<nmaxdegrees;Nphpad++) { 

       phpad = (360./(Float_t)nmaxdegrees)*(Float_t)Nphpad;
      
       aveEnerg =  (energy[0]+energy[1])/2.;
       //aveEnerg = 6.5;
       
       
       nfreonave  = a+b*aveEnerg;
       nquartzave = sqrt(1+(f1/(TMath::Power(e1,2)-TMath::Power(aveEnerg,2)))+
                         (f2/(TMath::Power(e2,2)-TMath::Power(aveEnerg,2))));

       //nfreonave = 1.295;
       //nquartzave = 1.585;
       
       ///printf("Calling DistancefromMip %f %f \n",fEmissPoint,fOmega);
       
       //Float_t dummy = 
         PatRec->DistanceFromMip(nfreonave, nquartzave,fEmissPoint,fOmega, phpad, pointsOnCathode,fTheta,fPhi);

       //Float_t points[3];

       //points = pointsOnCathode;


       //printf(" values %f %f %f\n",points[0],points[1],points[2]);
       
       Float_t vectorLoc[3]={pointsOnCathode[0],pointsOnCathode[2],pointsOnCathode[1]};
       Float_t  vectorGlob[3];
       iChamber->LocaltoGlobal(vectorLoc,vectorGlob);
       SetPoint(Nphpad,vectorGlob[0],vectorGlob[1],vectorGlob[2]);
      //fCoordEllipse[0][Nphpad] = pointsOnCathode[0];
      //fCoordEllipse[1][Nphpad] = pointsOnCathode[1];
       
       //printf(" values %f %f \n",pointsOnCathode[0],pointsOnCathode[1]);
       
   }

}