[u/mrichter/AliRoot.git] / RICH / Opticals.h

#ifdef __CINT__
void Opticals()
{
  gROOT->Reset();
#endif   
  int i;
  const Int_t kNbins=26;
  Float_t aPckov[kNbins];
  for(i=0;i<kNbins;i++){    //Photons energy intervals
    aPckov[i]=(Float_t(i)*0.1+5.5)*1e-9;
  }
  
  Float_t aIndexFreon[kNbins];  
  Float_t aIndexQuartz[kNbins];
  Float_t aIndexOpaqueQuartz[kNbins];
  Float_t aIndexCH4[kNbins];
  Float_t aIndexGrid[kNbins];
        
  Float_t  e1= 10.666;Float_t  e2= 18.125;  Float_t  f1= 46.411; Float_t  f2= 228.71;
  for (i=0;i<kNbins;i++){
    aIndexFreon[i]        = aPckov[i] * .0172 * 1e9 + 1.177;
    Float_t ene=aPckov[i]*1e9;
    Float_t a=f1/(e1*e1 - ene*ene);
    Float_t b=f2/(e2*e2 - ene*ene);
    aIndexQuartz[i]        = TMath::Sqrt(1. + a + b );
    aIndexOpaqueQuartz[i]  =1;
    aIndexCH4[i]      =1.000444;
    aIndexGrid[i]         =1;
  } 
    
  Float_t aAbsFreon[kNbins]={179.0987,  179.0987,    179.0987,  179.0987,   179.0987,  
                             179.0987,  179.0987,    179.0987,  179.0987,   142.9206, 
                              56.64957,  25.58622,    13.95293,  12.03905,   10.42953, 
                               8.804196,  7.069031,    4.461292,  2.028366,   1.293013, 
                               0.577267,  0.40746,     0.334964,  0.0,        0.0,       
                               0};
    

  Float_t aAbsQuartz[kNbins]={105.8,   65.52,  48.58,  42.85,   35.79,
                               31.262, 28.598, 27.527, 25.007,  22.815, 
                               21.004, 19.266, 17.525, 15.878,  14.177, 
                               11.719, 9.282,   6.62,   4.0925,  2.601, 
                               1.149,  0.667,   0.3627, 0.192,   0.1497, 
                               0.10857};
    
  Float_t aAbsOpaqueQuartz[kNbins];
  Float_t aAbsCH4[kNbins];
  Float_t aAbsGrid[kNbins];
  Float_t aAbsCsI[kNbins];
    for (i=0;i<kNbins;i++){
      aAbsCH4[i]    =AbsoCH4(aPckov[i]*1e9); 
      aAbsOpaqueQuartz[i]=1e-5; 
      aAbsCsI[i]        =1e-4; 
      aAbsGrid[i]       =1e-4; 
    }
    
  Float_t aQeCsI1[kNbins] = {0.000199999995, 0.000600000028, 0.000699999975, 0.00499999989, 0.00749999983,
                            0.010125,	    0.0242999997,   0.0405000001,   0.0688500032,  0.105299994, 
                            0.121500008,    0.141749993,    0.157949999,    0.162,         0.166050002, 
                            0.167669997,    0.174299985,    0.176789999,    0.179279998,   0.182599992, 
                            0.18592,        0.187579989,    0.189239994,    0.190899998,   0.207499996, 
                            0.215799987};
  Float_t aQeCsI2[kNbins] = {0.000199999995, 0.000600000028, 0.000699999975, 0.00499999989, 0.00749999983,
                            0.010125,	    0.0242999997,   0.0405000001,   0.0688500032,  0.105299994, 
                            0.121500008,    0.141749993,    0.157949999,    0.162,         0.166050002, 
                            0.167669997,    0.174299985,    0.176789999,    0.179279998,   0.182599992, 
                            0.18592,        0.187579989,    0.189239994,    0.190899998,   0.207499996, 
                            0.215799987};
  Float_t aQeCsI3[kNbins] = {0.000199999995, 0.000600000028, 0.000699999975, 0.00499999989, 0.00749999983,
                            0.010125,	    0.0242999997,   0.0405000001,   0.0688500032,  0.105299994, 
                            0.121500008,    0.141749993,    0.157949999,    0.162,         0.166050002, 
                            0.167669997,    0.174299985,    0.176789999,    0.179279998,   0.182599992, 
                            0.18592,        0.187579989,    0.189239994,    0.190899998,   0.207499996, 
                            0.215799987};
  Float_t aQeCsI4[kNbins] = {0.000199999995, 0.000600000028, 0.000699999975, 0.00499999989, 0.00749999983,
                            0.010125,	    0.0242999997,   0.0405000001,   0.0688500032,  0.105299994, 
                            0.121500008,    0.141749993,    0.157949999,    0.162,         0.166050002, 
                            0.167669997,    0.174299985,    0.176789999,    0.179279998,   0.182599992, 
                            0.18592,        0.187579989,    0.189239994,    0.190899998,   0.207499996, 
                            0.215799987};
  Float_t aQeCsI5[kNbins] = {0.000199999995, 0.000600000028, 0.000699999975, 0.00499999989, 0.00749999983,
                            0.010125,	    0.0242999997,   0.0405000001,   0.0688500032,  0.105299994, 
                            0.121500008,    0.141749993,    0.157949999,    0.162,         0.166050002, 
                            0.167669997,    0.174299985,    0.176789999,    0.179279998,   0.182599992, 
                            0.18592,        0.187579989,    0.189239994,    0.190899998,   0.207499996, 
                            0.215799987};
  Float_t aQeCsI6[kNbins] = {0.000199999995, 0.000600000028, 0.000699999975, 0.00499999989, 0.00749999983,
                            0.010125,	    0.0242999997,   0.0405000001,   0.0688500032,  0.105299994, 
                            0.121500008,    0.141749993,    0.157949999,    0.162,         0.166050002, 
                            0.167669997,    0.174299985,    0.176789999,    0.179279998,   0.182599992, 
                            0.18592,        0.187579989,    0.189239994,    0.190899998,   0.207499996, 
                            0.215799987};
  Float_t aQeCsI7[kNbins] = {0.000199999995, 0.000600000028, 0.000699999975, 0.00499999989, 0.00749999983,
                            0.010125,	    0.0242999997,   0.0405000001,   0.0688500032,  0.105299994, 
                            0.121500008,    0.141749993,    0.157949999,    0.162,         0.166050002, 
                            0.167669997,    0.174299985,    0.176789999,    0.179279998,   0.182599992, 
                            0.18592,        0.187579989,    0.189239994,    0.190899998,   0.207499996, 
                            0.215799987};
  Float_t aQeAll[kNbins];
  for(i=0;i<kNbins;i++){
    aQeCsI1[i]/= (1.0-Fresnel(aPckov[i]*1e9,1.0,0)); //FRESNEL LOSS CORRECTION
    aQeCsI2[i]/= (1.0-Fresnel(aPckov[i]*1e9,1.0,0)); //FRESNEL LOSS CORRECTION
    aQeCsI3[i]/= (1.0-Fresnel(aPckov[i]*1e9,1.0,0)); //FRESNEL LOSS CORRECTION
    aQeCsI4[i]/= (1.0-Fresnel(aPckov[i]*1e9,1.0,0)); //FRESNEL LOSS CORRECTION
    aQeCsI5[i]/= (1.0-Fresnel(aPckov[i]*1e9,1.0,0)); //FRESNEL LOSS CORRECTION
    aQeCsI6[i]/= (1.0-Fresnel(aPckov[i]*1e9,1.0,0)); //FRESNEL LOSS CORRECTION
    aQeCsI7[i]/= (1.0-Fresnel(aPckov[i]*1e9,1.0,0)); //FRESNEL LOSS CORRECTION
    aQeAll[i]=1; //QE for all other materials except for PC must be 1.
  }
       
                    
#ifdef __CINT__

  
//Freon, Quartz, Opaque Quartz,Methane,CsI,Grid   
  const Int_t kFreonMarker= 24; const Int_t kFreonColor=kRed;  
  const Int_t kCH4Marker= 25;   const Int_t kCH4Color=kGreen;  
  const Int_t kSiO2Marker= 26;  const Int_t kSiO2Color=kBlue;  
  const Int_t kCsIMarker = 2;   const Int_t kCsIColor =kMagenta;  
  
  TCanvas *pC=new TCanvas("c1","RICH optics to check",800,900);

  pC->Divide(2,2);           
           
  pC->cd(1);                 
  TGraph *pAbsFreonGr=new TGraph(kNbins,aPckov,aAbsFreon);
  pAbsFreonGr->SetMarkerStyle(kFreonMarker); pAbsFreonGr->SetMarkerColor(kFreonColor);
  TGraph *pAbsSiO2Gr=new TGraph(kNbins,aPckov,aAbsQuartz);
  pAbsSiO2Gr->SetMarkerStyle(kSiO2Marker); pAbsSiO2Gr->SetMarkerColor(kSiO2Color);  
  TMultiGraph *pAbsMG=new TMultiGraph();
  TLegend *pAbsLegend=new TLegend(0.6,0.3,0.85,0.5);
  pAbsMG->Add(pAbsFreonGr);     pAbsLegend->AddEntry(pAbsFreonGr,   "freon","p");            //1
  pAbsMG->Add(pAbsSiO2Gr);      pAbsLegend->AddEntry(pAbsSiO2Gr,  "quartz","p");          //2
  pAbsMG->Draw("APL");                       		
  pAbsMG->GetXaxis()->SetTitle("energy, GeV");
  pAbsMG->GetYaxis()->SetTitle("absorption length, cm");
  pAbsMG->Draw("APL");
  pAbsLegend->Draw();   


  pC->cd(2);
  TGraph *pIndexFreonGr=new TGraph(kNbins,aPckov,aIndexFreon);
  pIndexFreonGr->SetMarkerStyle(kFreonMarker); pIndexFreonGr->SetMarkerColor(kFreonColor);  
  TGraph *pIndexSiO2Gr=new TGraph(kNbins,aPckov,aIndexQuartz);
  pIndexSiO2Gr->SetMarkerStyle(kSiO2Marker); pIndexSiO2Gr->SetMarkerColor(kSiO2Color);  
  TGraph *pIndexCH4Gr=new TGraph(kNbins,aPckov,aIndexCH4);
  pIndexCH4Gr->SetMarkerStyle(kCH4Marker); pIndexCH4Gr->SetMarkerColor(kCH4Color);   
  TMultiGraph *pIndexMG=new TMultiGraph();
  TLegend *pIndexLegend=new TLegend(0.6,0.2,0.85,0.4);
  pIndexMG->Add(pIndexFreonGr);     pIndexLegend->AddEntry(pIndexFreonGr,   "freon","p");            //1
  pIndexMG->Add(pIndexSiO2Gr);      pIndexLegend->AddEntry(pIndexSiO2Gr,  "quartz","p");          
  pIndexMG->Add(pIndexCH4Gr);       pIndexLegend->AddEntry(pIndexCH4Gr,   "CH4","p");          
  pIndexMG->Draw("APL");                       		
  pIndexMG->GetXaxis()->SetTitle("energy, GeV");
  pIndexMG->GetYaxis()->SetTitle("refraction index");
  pIndexMG->Draw("APL");
  pIndexLegend->Draw();      

  pC->cd(3);      
  TGraph *pAbsCH4Gr=new TGraph(kNbins,aPckov,aAbsCH4);
  pAbsCH4Gr->SetMarkerStyle(kCH4Marker); pAbsCH4Gr->SetMarkerColor(kCH4Color);
  pAbsCH4Gr->Draw("APL");
  pAbsCH4Gr->GetXaxis()->SetTitle("energy, GeV");
  pAbsCH4Gr->SetTitle("CH4 absorption length, cm");
  pAbsCH4Gr->Draw("APL");

  TCanvas *pQeC=new TCanvas("pQeC","CsI QE currently all the same",800,900); 
  pQeC->Divide(2,4);
  for(int i=1;i<=7;i++){
    pQeC->cd(i);  
    switch(i){
      case 1: TGraph *pQeCsIGr=new TGraph(kNbins,aPckov,aQeCsI1);pQeCsIGr->SetTitle("Module 1");break;
      case 2: TGraph *pQeCsIGr=new TGraph(kNbins,aPckov,aQeCsI2);pQeCsIGr->SetTitle("Module 2");break;
      case 3: TGraph *pQeCsIGr=new TGraph(kNbins,aPckov,aQeCsI3);pQeCsIGr->SetTitle("Module 3");break;
      case 4: TGraph *pQeCsIGr=new TGraph(kNbins,aPckov,aQeCsI4);pQeCsIGr->SetTitle("Module 4");break;
      case 5: TGraph *pQeCsIGr=new TGraph(kNbins,aPckov,aQeCsI5);pQeCsIGr->SetTitle("Module 5");break;
      case 6: TGraph *pQeCsIGr=new TGraph(kNbins,aPckov,aQeCsI6);pQeCsIGr->SetTitle("Module 6");break;
      case 7: TGraph *pQeCsIGr=new TGraph(kNbins,aPckov,aQeCsI7);pQeCsIGr->SetTitle("Module 7");break;
    }
    pQeCsIGr->SetMarkerStyle(kCsIMarker); pQeCsIGr->SetMarkerColor(kCsIColor);  
    pQeCsIGr->Draw("APL");
    pQeCsIGr->GetXaxis()->SetTitle("energy, GeV");
    pQeCsIGr->Draw("APL");
  }
}//main

Float_t AbsoCH4(Float_t x)
{

    //KLOSCH,SCH4(9),WL(9),EM(9),ALENGTH(31)
    Float_t sch4[9] = {.12,.16,.23,.38,.86,2.8,7.9,28.,80.};              //MB X 10^22
    //Float_t wl[9] = {153.,152.,151.,150.,149.,148.,147.,146.,145};
    Float_t em[9] = {8.1,8.158,8.212,8.267,8.322,8.378,8.435,8.493,8.55};
    const Float_t kLosch=2.686763E19;                                      // LOSCHMIDT NUMBER IN CM-3
    const Float_t kIgas1=100, kIgas2=0, kOxy=10., kWater=5., kPressure=750.,kTemperature=283.;  
    Float_t pn=kPressure/760.;
    Float_t tn=kTemperature/273.16;
    
	
// ------- METHANE CROSS SECTION -----------------
// ASTROPH. J. 214, L47 (1978)
	
    Float_t sm=0;
    if (x<7.75) 
	sm=.06e-22;
    
    if(x>=7.75 && x<=8.1)
    {
	Float_t c0=-1.655279e-1;
	Float_t c1=6.307392e-2;
	Float_t c2=-8.011441e-3;
	Float_t c3=3.392126e-4;
	sm=(c0+c1*x+c2*x*x+c3*x*x*x)*1.e-18;
    }
    
    if (x> 8.1)
    {
	Int_t j=0;
	while (x<=em[j] && x>=em[j+1])
	{
	    j++;
	    Float_t a=(sch4[j+1]-sch4[j])/(em[j+1]-em[j]);
	    sm=(sch4[j]+a*(x-em[j]))*1e-22;
	}
    }
    
    Float_t dm=(kIgas1/100.)*(1.-((kOxy+kWater)/1.e6))*kLosch*pn/tn;
    Float_t abslm=1./sm/dm;
    
//    ------- ISOBUTHANE CROSS SECTION --------------
//     i-C4H10 (ai) abs. length from curves in
//     Lu-McDonald paper for BARI RICH workshop .
//     -----------------------------------------------------------
    
    Float_t ai;
    Float_t absli;
    if (kIgas2 != 0) 
    {
	if (x<7.25)
	    ai=100000000.;
	
	if(x>=7.25 && x<7.375)
	    ai=24.3;
	
	if(x>=7.375)
	    ai=.0000000001;
	
	Float_t si = 1./(ai*kLosch*273.16/293.);                    // ISOB. CRO.SEC.IN CM2
	Float_t di=(kIgas2/100.)*(1.-((kOxy+kWater)/1.e6))*kLosch*pn/tn;
	absli =1./si/di;
    }
    else
	absli=1.e18;
//    ---------------------------------------------------------
//
//       transmission of O2
//
//       y= path in cm, x=energy in eV
//       so= cross section for UV absorption in cm2
//       do= O2 molecular density in cm-3
//    ---------------------------------------------------------
    
    Float_t abslo;
    Float_t so=0;
    if(x>=6.0)
    {
	if(x>=6.0 && x<6.5)
	{
	    so=3.392709e-13 * TMath::Exp(2.864104 *x);
	    so=so*1e-18;
	}
	
	if(x>=6.5 && x<7.0) 
	{
	    so=2.910039e-34 * TMath::Exp(10.3337*x);
	    so=so*1e-18;
	}
	    

	if (x>=7.0) 
	{
	    Float_t a0=-73770.76;
	    Float_t a1=46190.69;
	    Float_t a2=-11475.44;
	    Float_t a3=1412.611;
	    Float_t a4=-86.07027;
	    Float_t a5=2.074234;
	    so= a0+(a1*x)+(a2*x*x)+(a3*x*x*x)+(a4*x*x*x*x)+(a5*x*x*x*x*x);
	    so=so*1e-18;
	}
	
	Float_t dox=(kOxy/1e6)*kLosch*pn/tn;
	abslo=1./so/dox;
    }
    else
	abslo=1.e18;
//     ---------------------------------------------------------
//
//       transmission of H2O
//
//       y= path in cm, x=energy in eV
//       sw= cross section for UV absorption in cm2
//       dw= H2O molecular density in cm-3
//     ---------------------------------------------------------
    
    Float_t abslw;
    
    Float_t b0=29231.65;
    Float_t b1=-15807.74;
    Float_t b2=3192.926;
    Float_t b3=-285.4809;
    Float_t b4=9.533944;
    
    if(x>6.75)
    {    
	Float_t sw= b0+(b1*x)+(b2*x*x)+(b3*x*x*x)+(b4*x*x*x*x);
	sw=sw*1e-18;
	Float_t dw=(kWater/1e6)*kLosch*pn/tn;
	abslw=1./sw/dw;
    }
    else
    	abslw=1.e18;
	    
//    ---------------------------------------------------------
    
    Float_t alength=1./(1./abslm+1./absli+1./abslo+1./abslw);
    return (alength);
}//AbsoCH4


Float_t Fresnel(Float_t ene,Float_t pdoti, Bool_t pola)
{

    //ENE(EV), PDOTI=COS(INC.ANG.), PDOTR=COS(POL.PLANE ROT.ANG.)
    
    Float_t en[36] = {5.0,5.1,5.2,5.3,5.4,5.5,5.6,5.7,5.8,5.9,6.0,6.1,6.2,
		      6.3,6.4,6.5,6.6,6.7,6.8,6.9,7.0,7.1,7.2,7.3,7.4,7.5,7.6,7.7,
		      7.8,7.9,8.0,8.1,8.2,8.3,8.4,8.5};
     

    Float_t csin[36] = {2.14,2.21,2.33,2.48,2.76,2.97,2.99,2.59,2.81,3.05,
			2.86,2.53,2.55,2.66,2.79,2.96,3.18,3.05,2.84,2.81,2.38,2.11,
			2.01,2.13,2.39,2.73,3.08,3.15,2.95,2.73,2.56,2.41,2.12,1.95,
			1.72,1.53};
      
    Float_t csik[36] = {0.,0.,0.,0.,0.,0.196,0.408,0.208,0.118,0.49,0.784,0.543,
	 		0.424,0.404,0.371,0.514,0.922,1.102,1.139,1.376,1.461,1.253,0.878,
			0.69,0.612,0.649,0.824,1.347,1.571,1.678,1.763,1.857,1.824,1.824,
			1.714,1.498};
    Float_t xe=ene;
    Int_t  j=Int_t(xe*10)-49;
    Float_t cn=csin[j]+((csin[j+1]-csin[j])/0.1)*(xe-en[j]);
    Float_t ck=csik[j]+((csik[j+1]-csik[j])/0.1)*(xe-en[j]);

    //FORMULAE FROM HANDBOOK OF OPTICS, 33.23 OR
    //W.R. HUNTER, J.O.S.A. 54 (1964),15 , J.O.S.A. 55(1965),1197

    Float_t sinin=TMath::Sqrt(1-pdoti*pdoti);
    Float_t tanin=sinin/pdoti;

    Float_t c1=cn*cn-ck*ck-sinin*sinin;
    Float_t c2=4*cn*cn*ck*ck;
    Float_t aO=TMath::Sqrt(0.5*(TMath::Sqrt(c1*c1+c2)+c1));
    Float_t b2=0.5*(TMath::Sqrt(c1*c1+c2)-c1);
    
    Float_t rs=((aO-pdoti)*(aO-pdoti)+b2)/((aO+pdoti)*(aO+pdoti)+b2);
    Float_t rp=rs*((aO-sinin*tanin)*(aO-sinin*tanin)+b2)/((aO+sinin*tanin)*(aO+sinin*tanin)+b2);
    

    //CORRECTION FACTOR FOR SURFACE ROUGHNESS
    //B.J. STAGG  APPLIED OPTICS, 30(1991),4113

    Float_t sigraf=18.;
    Float_t lamb=1240/ene;
    Float_t fresn;
 
    Float_t  rO=TMath::Exp(-(4*TMath::Pi()*pdoti*sigraf/lamb)*(4*TMath::Pi()*pdoti*sigraf/lamb));

    if(pola)
    {
	Float_t pdotr=0.8;                                 //DEGREE OF POLARIZATION : 1->P , -1->S
	fresn=0.5*(rp*(1+pdotr)+rs*(1-pdotr));
    }
    else
	fresn=0.5*(rp+rs);
      
    fresn = fresn*rO;
    return(fresn);
}//Fresnel(...)
#endif
Commit	Line	Data
d48cca74	1	#ifdef __CINT__
	2	void Opticals()
	3	{
	4	gROOT->Reset();
	5	#endif
	6	int i;
	7	const Int_t kNbins=26;
	8	Float_t aPckov[kNbins];
	9	for(i=0;i<kNbins;i++){ //Photons energy intervals
	10	aPckov[i]=(Float_t(i)0.1+5.5)1e-9;
	11	}
	12
	13	Float_t aIndexFreon[kNbins];
	14	Float_t aIndexQuartz[kNbins];
	15	Float_t aIndexOpaqueQuartz[kNbins];
	16	Float_t aIndexCH4[kNbins];
	17	Float_t aIndexGrid[kNbins];
	18
	19	Float_t e1= 10.666;Float_t e2= 18.125; Float_t f1= 46.411; Float_t f2= 228.71;
	20	for (i=0;i<kNbins;i++){
	21	aIndexFreon[i] = aPckov[i] * .0172 * 1e9 + 1.177;
	22	Float_t ene=aPckov[i]*1e9;
	23	Float_t a=f1/(e1e1 - eneene);
	24	Float_t b=f2/(e2e2 - eneene);
	25	aIndexQuartz[i] = TMath::Sqrt(1. + a + b );
	26	aIndexOpaqueQuartz[i] =1;
	27	aIndexCH4[i] =1.000444;
	28	aIndexGrid[i] =1;
	29	}
	30
	31	Float_t aAbsFreon[kNbins]={179.0987, 179.0987, 179.0987, 179.0987, 179.0987,
	32	179.0987, 179.0987, 179.0987, 179.0987, 142.9206,
	33	56.64957, 25.58622, 13.95293, 12.03905, 10.42953,
	34	8.804196, 7.069031, 4.461292, 2.028366, 1.293013,
	35	0.577267, 0.40746, 0.334964, 0.0, 0.0,
	36	0};
	37
	38
	39	Float_t aAbsQuartz[kNbins]={105.8, 65.52, 48.58, 42.85, 35.79,
	40	31.262, 28.598, 27.527, 25.007, 22.815,
	41	21.004, 19.266, 17.525, 15.878, 14.177,
	42	11.719, 9.282, 6.62, 4.0925, 2.601,
	43	1.149, 0.667, 0.3627, 0.192, 0.1497,
	44	0.10857};
	45
	46	Float_t aAbsOpaqueQuartz[kNbins];
	47	Float_t aAbsCH4[kNbins];
	48	Float_t aAbsGrid[kNbins];
	49	Float_t aAbsCsI[kNbins];
	50	for (i=0;i<kNbins;i++){
	51	aAbsCH4[i] =AbsoCH4(aPckov[i]*1e9);
	52	aAbsOpaqueQuartz[i]=1e-5;
	53	aAbsCsI[i] =1e-4;
	54	aAbsGrid[i] =1e-4;
	55	}
	56
303f57b3	57	Float_t aQeCsI1[kNbins] = {0.000199999995, 0.000600000028, 0.000699999975, 0.00499999989, 0.00749999983,
	58	0.010125, 0.0242999997, 0.0405000001, 0.0688500032, 0.105299994,
	59	0.121500008, 0.141749993, 0.157949999, 0.162, 0.166050002,
	60	0.167669997, 0.174299985, 0.176789999, 0.179279998, 0.182599992,
	61	0.18592, 0.187579989, 0.189239994, 0.190899998, 0.207499996,
	62	0.215799987};
	63	Float_t aQeCsI2[kNbins] = {0.000199999995, 0.000600000028, 0.000699999975, 0.00499999989, 0.00749999983,
	64	0.010125, 0.0242999997, 0.0405000001, 0.0688500032, 0.105299994,
	65	0.121500008, 0.141749993, 0.157949999, 0.162, 0.166050002,
	66	0.167669997, 0.174299985, 0.176789999, 0.179279998, 0.182599992,
	67	0.18592, 0.187579989, 0.189239994, 0.190899998, 0.207499996,
	68	0.215799987};
	69	Float_t aQeCsI3[kNbins] = {0.000199999995, 0.000600000028, 0.000699999975, 0.00499999989, 0.00749999983,
	70	0.010125, 0.0242999997, 0.0405000001, 0.0688500032, 0.105299994,
	71	0.121500008, 0.141749993, 0.157949999, 0.162, 0.166050002,
	72	0.167669997, 0.174299985, 0.176789999, 0.179279998, 0.182599992,
	73	0.18592, 0.187579989, 0.189239994, 0.190899998, 0.207499996,
	74	0.215799987};
	75	Float_t aQeCsI4[kNbins] = {0.000199999995, 0.000600000028, 0.000699999975, 0.00499999989, 0.00749999983,
	76	0.010125, 0.0242999997, 0.0405000001, 0.0688500032, 0.105299994,
	77	0.121500008, 0.141749993, 0.157949999, 0.162, 0.166050002,
	78	0.167669997, 0.174299985, 0.176789999, 0.179279998, 0.182599992,
	79	0.18592, 0.187579989, 0.189239994, 0.190899998, 0.207499996,
	80	0.215799987};
	81	Float_t aQeCsI5[kNbins] = {0.000199999995, 0.000600000028, 0.000699999975, 0.00499999989, 0.00749999983,
	82	0.010125, 0.0242999997, 0.0405000001, 0.0688500032, 0.105299994,
	83	0.121500008, 0.141749993, 0.157949999, 0.162, 0.166050002,
	84	0.167669997, 0.174299985, 0.176789999, 0.179279998, 0.182599992,
	85	0.18592, 0.187579989, 0.189239994, 0.190899998, 0.207499996,
	86	0.215799987};
	87	Float_t aQeCsI6[kNbins] = {0.000199999995, 0.000600000028, 0.000699999975, 0.00499999989, 0.00749999983,
	88	0.010125, 0.0242999997, 0.0405000001, 0.0688500032, 0.105299994,
	89	0.121500008, 0.141749993, 0.157949999, 0.162, 0.166050002,
	90	0.167669997, 0.174299985, 0.176789999, 0.179279998, 0.182599992,
	91	0.18592, 0.187579989, 0.189239994, 0.190899998, 0.207499996,
	92	0.215799987};
	93	Float_t aQeCsI7[kNbins] = {0.000199999995, 0.000600000028, 0.000699999975, 0.00499999989, 0.00749999983,
d48cca74	94	0.010125, 0.0242999997, 0.0405000001, 0.0688500032, 0.105299994,
	95	0.121500008, 0.141749993, 0.157949999, 0.162, 0.166050002,
	96	0.167669997, 0.174299985, 0.176789999, 0.179279998, 0.182599992,
	97	0.18592, 0.187579989, 0.189239994, 0.190899998, 0.207499996,
	98	0.215799987};
	99	Float_t aQeAll[kNbins];
	100	for(i=0;i<kNbins;i++){
303f57b3	101	aQeCsI1[i]/= (1.0-Fresnel(aPckov[i]*1e9,1.0,0)); //FRESNEL LOSS CORRECTION
	102	aQeCsI2[i]/= (1.0-Fresnel(aPckov[i]*1e9,1.0,0)); //FRESNEL LOSS CORRECTION
	103	aQeCsI3[i]/= (1.0-Fresnel(aPckov[i]*1e9,1.0,0)); //FRESNEL LOSS CORRECTION
	104	aQeCsI4[i]/= (1.0-Fresnel(aPckov[i]*1e9,1.0,0)); //FRESNEL LOSS CORRECTION
	105	aQeCsI5[i]/= (1.0-Fresnel(aPckov[i]*1e9,1.0,0)); //FRESNEL LOSS CORRECTION
	106	aQeCsI6[i]/= (1.0-Fresnel(aPckov[i]*1e9,1.0,0)); //FRESNEL LOSS CORRECTION
	107	aQeCsI7[i]/= (1.0-Fresnel(aPckov[i]*1e9,1.0,0)); //FRESNEL LOSS CORRECTION
d48cca74	108	aQeAll[i]=1; //QE for all other materials except for PC must be 1.
	109	}
	110
	111
	112	#ifdef __CINT__
	113
	114
	115	//Freon, Quartz, Opaque Quartz,Methane,CsI,Grid
	116	const Int_t kFreonMarker= 24; const Int_t kFreonColor=kRed;
	117	const Int_t kCH4Marker= 25; const Int_t kCH4Color=kGreen;
	118	const Int_t kSiO2Marker= 26; const Int_t kSiO2Color=kBlue;
	119	const Int_t kCsIMarker = 2; const Int_t kCsIColor =kMagenta;
	120
	121	TCanvas *pC=new TCanvas("c1","RICH optics to check",800,900);
	122
	123	pC->Divide(2,2);
	124
	125	pC->cd(1);
	126	TGraph *pAbsFreonGr=new TGraph(kNbins,aPckov,aAbsFreon);
	127	pAbsFreonGr->SetMarkerStyle(kFreonMarker); pAbsFreonGr->SetMarkerColor(kFreonColor);
	128	TGraph *pAbsSiO2Gr=new TGraph(kNbins,aPckov,aAbsQuartz);
	129	pAbsSiO2Gr->SetMarkerStyle(kSiO2Marker); pAbsSiO2Gr->SetMarkerColor(kSiO2Color);
	130	TMultiGraph *pAbsMG=new TMultiGraph();
	131	TLegend *pAbsLegend=new TLegend(0.6,0.3,0.85,0.5);
	132	pAbsMG->Add(pAbsFreonGr); pAbsLegend->AddEntry(pAbsFreonGr, "freon","p"); //1
	133	pAbsMG->Add(pAbsSiO2Gr); pAbsLegend->AddEntry(pAbsSiO2Gr, "quartz","p"); //2
	134	pAbsMG->Draw("APL");
	135	pAbsMG->GetXaxis()->SetTitle("energy, GeV");
	136	pAbsMG->GetYaxis()->SetTitle("absorption length, cm");
	137	pAbsMG->Draw("APL");
	138	pAbsLegend->Draw();
	139
	140
	141	pC->cd(2);
	142	TGraph *pIndexFreonGr=new TGraph(kNbins,aPckov,aIndexFreon);
	143	pIndexFreonGr->SetMarkerStyle(kFreonMarker); pIndexFreonGr->SetMarkerColor(kFreonColor);
	144	TGraph *pIndexSiO2Gr=new TGraph(kNbins,aPckov,aIndexQuartz);
	145	pIndexSiO2Gr->SetMarkerStyle(kSiO2Marker); pIndexSiO2Gr->SetMarkerColor(kSiO2Color);
	146	TGraph *pIndexCH4Gr=new TGraph(kNbins,aPckov,aIndexCH4);
	147	pIndexCH4Gr->SetMarkerStyle(kCH4Marker); pIndexCH4Gr->SetMarkerColor(kCH4Color);
	148	TMultiGraph *pIndexMG=new TMultiGraph();
	149	TLegend *pIndexLegend=new TLegend(0.6,0.2,0.85,0.4);
	150	pIndexMG->Add(pIndexFreonGr); pIndexLegend->AddEntry(pIndexFreonGr, "freon","p"); //1
	151	pIndexMG->Add(pIndexSiO2Gr); pIndexLegend->AddEntry(pIndexSiO2Gr, "quartz","p");
	152	pIndexMG->Add(pIndexCH4Gr); pIndexLegend->AddEntry(pIndexCH4Gr, "CH4","p");
	153	pIndexMG->Draw("APL");
	154	pIndexMG->GetXaxis()->SetTitle("energy, GeV");
	155	pIndexMG->GetYaxis()->SetTitle("refraction index");
	156	pIndexMG->Draw("APL");
	157	pIndexLegend->Draw();
	158
	159	pC->cd(3);
	160	TGraph *pAbsCH4Gr=new TGraph(kNbins,aPckov,aAbsCH4);
	161	pAbsCH4Gr->SetMarkerStyle(kCH4Marker); pAbsCH4Gr->SetMarkerColor(kCH4Color);
	162	pAbsCH4Gr->Draw("APL");
	163	pAbsCH4Gr->GetXaxis()->SetTitle("energy, GeV");
	164	pAbsCH4Gr->SetTitle("CH4 absorption length, cm");
	165	pAbsCH4Gr->Draw("APL");
	166
303f57b3	167	TCanvas *pQeC=new TCanvas("pQeC","CsI QE currently all the same",800,900);
	168	pQeC->Divide(2,4);
	169	for(int i=1;i<=7;i++){
	170	pQeC->cd(i);
	171	switch(i){
	172	case 1: TGraph *pQeCsIGr=new TGraph(kNbins,aPckov,aQeCsI1);pQeCsIGr->SetTitle("Module 1");break;
	173	case 2: TGraph *pQeCsIGr=new TGraph(kNbins,aPckov,aQeCsI2);pQeCsIGr->SetTitle("Module 2");break;
	174	case 3: TGraph *pQeCsIGr=new TGraph(kNbins,aPckov,aQeCsI3);pQeCsIGr->SetTitle("Module 3");break;
	175	case 4: TGraph *pQeCsIGr=new TGraph(kNbins,aPckov,aQeCsI4);pQeCsIGr->SetTitle("Module 4");break;
	176	case 5: TGraph *pQeCsIGr=new TGraph(kNbins,aPckov,aQeCsI5);pQeCsIGr->SetTitle("Module 5");break;
	177	case 6: TGraph *pQeCsIGr=new TGraph(kNbins,aPckov,aQeCsI6);pQeCsIGr->SetTitle("Module 6");break;
	178	case 7: TGraph *pQeCsIGr=new TGraph(kNbins,aPckov,aQeCsI7);pQeCsIGr->SetTitle("Module 7");break;
	179	}
	180	pQeCsIGr->SetMarkerStyle(kCsIMarker); pQeCsIGr->SetMarkerColor(kCsIColor);
	181	pQeCsIGr->Draw("APL");
	182	pQeCsIGr->GetXaxis()->SetTitle("energy, GeV");
	183	pQeCsIGr->Draw("APL");
	184	}
d48cca74	185	}//main
	186
	187	Float_t AbsoCH4(Float_t x)
	188	{
	189
	190	//KLOSCH,SCH4(9),WL(9),EM(9),ALENGTH(31)
	191	Float_t sch4[9] = {.12,.16,.23,.38,.86,2.8,7.9,28.,80.}; //MB X 10^22
	192	//Float_t wl[9] = {153.,152.,151.,150.,149.,148.,147.,146.,145};
	193	Float_t em[9] = {8.1,8.158,8.212,8.267,8.322,8.378,8.435,8.493,8.55};
	194	const Float_t kLosch=2.686763E19; // LOSCHMIDT NUMBER IN CM-3
303f57b3	195	const Float_t kIgas1=100, kIgas2=0, kOxy=10., kWater=5., kPressure=750.,kTemperature=283.;
d48cca74	196	Float_t pn=kPressure/760.;
	197	Float_t tn=kTemperature/273.16;
	198
	199
	200	// ------- METHANE CROSS SECTION -----------------
	201	// ASTROPH. J. 214, L47 (1978)
	202
	203	Float_t sm=0;
	204	if (x<7.75)
	205	sm=.06e-22;
	206
	207	if(x>=7.75 && x<=8.1)
	208	{
	209	Float_t c0=-1.655279e-1;
	210	Float_t c1=6.307392e-2;
	211	Float_t c2=-8.011441e-3;
	212	Float_t c3=3.392126e-4;
	213	sm=(c0+c1x+c2xx+c3xxx)*1.e-18;
	214	}
	215
	216	if (x> 8.1)
	217	{
	218	Int_t j=0;
	219	while (x<=em[j] && x>=em[j+1])
	220	{
	221	j++;
	222	Float_t a=(sch4[j+1]-sch4[j])/(em[j+1]-em[j]);
	223	sm=(sch4[j]+a(x-em[j]))1e-22;
	224	}
	225	}
	226
	227	Float_t dm=(kIgas1/100.)(1.-((kOxy+kWater)/1.e6))kLosch*pn/tn;
	228	Float_t abslm=1./sm/dm;
	229
	230	// ------- ISOBUTHANE CROSS SECTION --------------
	231	// i-C4H10 (ai) abs. length from curves in
	232	// Lu-McDonald paper for BARI RICH workshop .
	233	// -----------------------------------------------------------
	234
	235	Float_t ai;
	236	Float_t absli;
	237	if (kIgas2 != 0)
	238	{
	239	if (x<7.25)
	240	ai=100000000.;
	241
	242	if(x>=7.25 && x<7.375)
	243	ai=24.3;
	244
	245	if(x>=7.375)
	246	ai=.0000000001;
	247
	248	Float_t si = 1./(aikLosch273.16/293.); // ISOB. CRO.SEC.IN CM2
	249	Float_t di=(kIgas2/100.)(1.-((kOxy+kWater)/1.e6))kLosch*pn/tn;
	250	absli =1./si/di;
	251	}
	252	else
	253	absli=1.e18;
	254	// ---------------------------------------------------------
	255	//
	256	// transmission of O2
	257	//
	258	// y= path in cm, x=energy in eV
	259	// so= cross section for UV absorption in cm2
260	// do= O2 molecular density in cm-3
261	// ---------------------------------------------------------
262
263	Float_t abslo;
264	Float_t so=0;
265	if(x>=6.0)
266	{
267	if(x>=6.0 && x<6.5)
268	{
269	so=3.392709e-13 * TMath::Exp(2.864104 *x);
270	so=so*1e-18;
271	}
272
273	if(x>=6.5 && x<7.0)
274	{
275	so=2.910039e-34 * TMath::Exp(10.3337*x);
276	so=so*1e-18;
277	}
278
279
280	if (x>=7.0)
281	{
282	Float_t a0=-73770.76;
283	Float_t a1=46190.69;
284	Float_t a2=-11475.44;
285	Float_t a3=1412.611;
286	Float_t a4=-86.07027;
287	Float_t a5=2.074234;
288	so= a0+(a1x)+(a2xx)+(a3xxx)+(a4xxxx)+(a5xxxx*x);
289	so=so*1e-18;
290	}
291
292	Float_t dox=(kOxy/1e6)kLoschpn/tn;
293	abslo=1./so/dox;
294	}
295	else
296	abslo=1.e18;
297	// ---------------------------------------------------------
298	//
299	// transmission of H2O
300	//
301	// y= path in cm, x=energy in eV
302	// sw= cross section for UV absorption in cm2
303	// dw= H2O molecular density in cm-3
304	// ---------------------------------------------------------
305
306	Float_t abslw;
307
308	Float_t b0=29231.65;
309	Float_t b1=-15807.74;
310	Float_t b2=3192.926;
311	Float_t b3=-285.4809;
312	Float_t b4=9.533944;
313
314	if(x>6.75)
315	{
316	Float_t sw= b0+(b1x)+(b2xx)+(b3xxx)+(b4xxxx);
317	sw=sw*1e-18;
318	Float_t dw=(kWater/1e6)kLoschpn/tn;
319	abslw=1./sw/dw;
320	}
321	else
322	abslw=1.e18;
323
324	// ---------------------------------------------------------
325
326	Float_t alength=1./(1./abslm+1./absli+1./abslo+1./abslw);
327	return (alength);
328	}//AbsoCH4
329
330
331	Float_t Fresnel(Float_t ene,Float_t pdoti, Bool_t pola)
332	{
333
334	//ENE(EV), PDOTI=COS(INC.ANG.), PDOTR=COS(POL.PLANE ROT.ANG.)
335
336	Float_t en[36] = {5.0,5.1,5.2,5.3,5.4,5.5,5.6,5.7,5.8,5.9,6.0,6.1,6.2,
337	6.3,6.4,6.5,6.6,6.7,6.8,6.9,7.0,7.1,7.2,7.3,7.4,7.5,7.6,7.7,
338	7.8,7.9,8.0,8.1,8.2,8.3,8.4,8.5};
339
340
341	Float_t csin[36] = {2.14,2.21,2.33,2.48,2.76,2.97,2.99,2.59,2.81,3.05,
342	2.86,2.53,2.55,2.66,2.79,2.96,3.18,3.05,2.84,2.81,2.38,2.11,
343	2.01,2.13,2.39,2.73,3.08,3.15,2.95,2.73,2.56,2.41,2.12,1.95,
344	1.72,1.53};
345
346	Float_t csik[36] = {0.,0.,0.,0.,0.,0.196,0.408,0.208,0.118,0.49,0.784,0.543,
347	0.424,0.404,0.371,0.514,0.922,1.102,1.139,1.376,1.461,1.253,0.878,
348	0.69,0.612,0.649,0.824,1.347,1.571,1.678,1.763,1.857,1.824,1.824,
349	1.714,1.498};
350	Float_t xe=ene;
351	Int_t j=Int_t(xe*10)-49;
352	Float_t cn=csin[j]+((csin[j+1]-csin[j])/0.1)*(xe-en[j]);
353	Float_t ck=csik[j]+((csik[j+1]-csik[j])/0.1)*(xe-en[j]);
354
355	//FORMULAE FROM HANDBOOK OF OPTICS, 33.23 OR
356	//W.R. HUNTER, J.O.S.A. 54 (1964),15 , J.O.S.A. 55(1965),1197
357
358	Float_t sinin=TMath::Sqrt(1-pdoti*pdoti);
359	Float_t tanin=sinin/pdoti;
360
361	Float_t c1=cncn-ckck-sinin*sinin;
362	Float_t c2=4cncnckck;
363	Float_t aO=TMath::Sqrt(0.5(TMath::Sqrt(c1c1+c2)+c1));
364	Float_t b2=0.5(TMath::Sqrt(c1c1+c2)-c1);
365
366	Float_t rs=((aO-pdoti)(aO-pdoti)+b2)/((aO+pdoti)(aO+pdoti)+b2);
367	Float_t rp=rs((aO-sinintanin)(aO-sinintanin)+b2)/((aO+sinintanin)(aO+sinin*tanin)+b2);
368
369
370	//CORRECTION FACTOR FOR SURFACE ROUGHNESS
371	//B.J. STAGG APPLIED OPTICS, 30(1991),4113
372
373	Float_t sigraf=18.;
374	Float_t lamb=1240/ene;
375	Float_t fresn;
376
377	Float_t rO=TMath::Exp(-(4TMath::Pi()pdotisigraf/lamb)(4TMath::Pi()pdoti*sigraf/lamb));
378
379	if(pola)
380	{
381	Float_t pdotr=0.8; //DEGREE OF POLARIZATION : 1->P , -1->S
382	fresn=0.5(rp(1+pdotr)+rs*(1-pdotr));
383	}
384	else
385	fresn=0.5*(rp+rs);
386
387	fresn = fresn*rO;
388	return(fresn);
389	}//Fresnel(...)
390	#endif