[u/mrichter/AliRoot.git] / FMD / AliFMDv0.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.                  *
 **************************************************************************/

/* $Id$ */

 /////////////////////////////////////////////////////////////////////
//                                                                 //
// Forward Multiplicity detector based on Silicon version 0        //
//
//Begin Html       
/*
<img src="gif/AliFMDv0Class.gif">
*/
//End Html
//                                                                  //
//                                                                  //
//////////////////////////////////////////////////////////////////////

#include <Riostream.h>
#include <stdlib.h>

#include <TGeometry.h>
#include <TLorentzVector.h>
#include <TMath.h>
#include <TNode.h>
#include <TTUBE.h>
#include <TLorentzVector.h>
#include <TVirtualMC.h>

#include "AliFMDv0.h"
#include "AliMagF.h"
#include "AliRndm.h"
#include "AliRun.h"
#include "AliFMDhit.h"

ClassImp(AliFMDv0)

//--------------------------------------------------------------------
AliFMDv0::AliFMDv0(const char *name, const char *title):
 AliFMD(name,title)
{
  //
  // Standart constructor for Forward Multiplicity Detector version 0
  //
  fIdSens1=0;
  fIdSens2=0;
  fIdSens3=0;
  fIdSens4=0;
  fIdSens5=0;
//  setBufferSize(128000);
}
//-------------------------------------------------------------------------

void AliFMDv0::CreateGeometry()
{
//
  // Create the geometry of Forward Multiplicity Detector version 0
  //
  //Detector consists of 6 volumes: 
  // 1st covered pseudorapidity interval from 3.3 to 2.0
  // and placed on 65cm in Z-direction;
  // 2nd - from 2.0 to 1.6 and Z=85 cm;
  // 3d  - the same pseudorapidity interval as the 1st 
  // but on the other side from the interaction point z=-65cm;
  // 4th - simmetricaly with the 2nd : 
  // pseudorapidity from 2.0 to 1.6, Z=-85cm   
  // 5th - from 3.6 to 4.7, Z=-270cm
  // 6th - from 4.5 to 5.5 , Z=-630cm.
  // Each part has 400mkm Si (sensetive area, detector itself),
  // 0.75cm of plastic simulated electronics material,
  // Al support ring 2cm thickness and 1cm width placed on 
  // the outer radius of each Si disk;
  //    
  // begin Html
  /*
   <img src="gif/AliFMDv0.gif">
   */
  //


  Int_t *idtmed = fIdtmed->GetArray();
   
  Int_t ifmd;
  Int_t idrotm[999];
  Float_t zFMD,par[3],ppcon[15];
  Float_t z[5]={-62.8, -75.2, 83.4, 75.2, 340.};
  Float_t NylonTube[3]={0.2,0.6,0.45};
  Float_t zPCB=0.12; Float_t zHoneyComb=0.5; 
  Float_t zSi=0.03;
 
  char nameFMD[5], nameSi[5], nameSector[5], nameRing[5];
  Char_t nameHoney[5], nameHoneyIn[5], nameHoneyOut[5];
  Char_t namePCB[5], nameCopper[5], nameChips[5], nameG10[5];
  Char_t nameLPCB[5], nameLCopper[5], nameLChips[5], nameGL10[5];;
  Float_t rin[5]={4.2,15.4,4.2,15.4,4.2};
  Float_t rout[5]={17.4,28.4,17.4,28.4,17.4};
  Float_t RinHoneyComb[5] ={ 5.15,16.4,  5.15,16.4,  5.15};
  Float_t RoutHoneyComb[5]={20.63,34.92,22.3, 32.02,20.63};
  Float_t zInside;
  Float_t zCooper=0.01; Float_t zChips=0.01;
  Float_t yNylonTube[5]={10,20,10,20,10};


  AliMatrix(idrotm[901], 90, 0, 90, 90, 180, 0);
  
  
  // Nylon tubes
   gMC->Gsvolu("GNYL","TUBE", idtmed[1], NylonTube, 3);  //support nylon tube
   Float_t wideSupport=zSi+3*zPCB+2*NylonTube[2]+zHoneyComb;
     cout<<" wideSupport "<<wideSupport<<endl;

 for (ifmd=0; ifmd<5; ifmd++)
    {
      sprintf(nameFMD,"FMD%d",ifmd+1);
      ppcon[0]=0;
      ppcon[1]=360;
      ppcon[2]=4;
      
      ppcon[3]=-wideSupport;
      ppcon[4]=rin[ifmd]+0.1;
      ppcon[5]=rout[ifmd]+0.1;
      
      ppcon[6]=ppcon[3]+2*zSi+2*zPCB+2*NylonTube[2];
      ppcon[7]=rin[ifmd]+0.1;
      ppcon[8]=rout[ifmd]+0.1;
      
      ppcon[9]=ppcon[6];
      ppcon[10]=RinHoneyComb[ifmd]+0.1;
      ppcon[11]=RoutHoneyComb[ifmd]+0.1;

      ppcon[12]=ppcon[9]+2*zHoneyComb+zPCB;
      ppcon[13]=RinHoneyComb[ifmd]+0.1;
      ppcon[14]=RoutHoneyComb[ifmd]+0.1;
      gMC->Gsvolu(nameFMD,"PCON",idtmed[0],ppcon,15);
      if (z[ifmd] >0){  
        zFMD=z[ifmd]+wideSupport;
        gMC->Gspos(nameFMD,1,"ALIC",0,0,zFMD,0, "ONLY");}
      else {
        zFMD=z[ifmd]-wideSupport;
        gMC->Gspos(nameFMD,1,"ALIC",0,0,zFMD,idrotm[901], "ONLY");}
     //silicon
      sprintf(nameSi,"GSI%d",ifmd+1);
      sprintf(nameSector,"GSC%d",ifmd+1);
      sprintf(nameRing,"GRN%d",ifmd+1);
      
      //honeycomb support
      sprintf(nameHoney,"GSU%d",ifmd+1);
      gMC->Gsvolu(nameHoney,"TUBE", idtmed[0], par, 0);  //honeycomb 
      sprintf(nameHoneyIn,"GHI%d",ifmd+1);
      gMC->Gsvolu(nameHoneyIn,"TUBE", idtmed[7], par, 0);  //honey comb inside 
      sprintf(nameHoneyOut,"GHO%d",ifmd+1);
      gMC->Gsvolu(nameHoneyOut,"TUBE", idtmed[6], par, 0);  //honey comb skin
      //PCB
      sprintf(namePCB,"GPC%d",ifmd+1);
      gMC->Gsvolu(namePCB,"TUBE", idtmed[0], par, 0); //PCB
      sprintf(nameCopper,"GCO%d",ifmd+1);
      gMC->Gsvolu(nameCopper,"TUBE", idtmed[3], par, 0);  // Cooper
      sprintf(nameChips,"GCH%d",ifmd+1);
      gMC->Gsvolu(nameChips,"TUBE", idtmed[5], par, 0); // Si chips
      sprintf(nameG10,"G10%d",ifmd+1);
      gMC->Gsvolu(nameG10,"TUBE", idtmed[2], par, 0);  //G10 plate
      //last PCB
      sprintf(nameLPCB,"GPL%d",ifmd+1);
      gMC->Gsvolu(nameLPCB,"TUBE", idtmed[0], par, 0); //PCB
      sprintf(nameLCopper,"GCL%d",ifmd+1);
      gMC->Gsvolu(nameLCopper,"TUBE", idtmed[3], par, 0);  // Cooper
      sprintf(nameLChips,"GHL%d",ifmd+1);
      gMC->Gsvolu(nameLChips,"TUBE", idtmed[5], par, 0); // Si chips
      sprintf(nameGL10,"G1L%d",ifmd+1);
      gMC->Gsvolu(nameGL10,"TUBE", idtmed[2], par, 0); // Last G10
      par[0]=rin[ifmd]; // pipe size
      par[1]=rout[ifmd];
      par[2]=zSi/2;
      gMC->Gsvolu(nameSi,"TUBE", idtmed[4], par, 3);
      zInside=ppcon[3]+par[2];
       gMC->Gspos(nameSi,ifmd+1,nameFMD,0,0,zInside,0, "ONLY");
      //PCB 1
      zInside += par[2]+zPCB/2;
      par[2]=zPCB/2;
      gMC->Gsposp(namePCB,1,nameFMD,0,0,zInside,0, "ONLY",par,3);
      zInside += zPCB;
      gMC->Gsposp(namePCB,2,nameFMD,0,0,zInside,0, "ONLY",par,3);
      Float_t NulonTubeBegin=zInside+2.5*zPCB;
      par[2]=zPCB/2-0.02;
      Float_t zInPCB = -zPCB/2+par[2];
      gMC->Gsposp(nameG10,1,namePCB,0,0,zInPCB,0, "ONLY",par,3);
      zInPCB+=par[2]+zCooper/2 ;
      par[2]=zCooper/2;
      gMC->Gsposp(nameCopper,1,namePCB,0,0,zInPCB,0, "ONLY",par,3);
      zInPCB += zCooper/2 + zChips/2;
      par[2]=zChips/2;
      gMC->Gsposp(nameChips,1,namePCB,0,0,zInPCB,0, "ONLY",par,3);
      //HoneyComb
      zHoneyComb=0.8;   
      par[0] = RinHoneyComb[ifmd];
      par[1] = RoutHoneyComb[ifmd];
      par[2] = zHoneyComb/2;
      zInside += 2*NylonTube[2]+par[2];
      gMC->Gsposp(nameHoney,1,nameFMD,0,0,zInside,0, "ONLY",par,3);
      par[2]=0.1/2;
      Float_t zHoney=-zHoneyComb/2+par[2];
      gMC->Gsposp(nameHoneyOut,1,nameHoney,0,0,zHoney,0,
                  "ONLY",par,3); //shkurki
      zHoney=zHoneyComb/2-par[2];
      gMC->Gsposp(nameHoneyOut,2,nameHoney,0,0,zHoney,0, "ONLY",par,3);
      par[2]=(zHoneyComb-2.*0.1)/2; //soty vnutri
      gMC->Gsposp(nameHoneyIn,1,nameHoney,0,0,0,0, "ONLY",par,3);
      
      gMC->Gspos("GNYL",1,nameFMD,0,yNylonTube[ifmd],
                 NulonTubeBegin+NylonTube[2]/2.,0, "ONLY");
      gMC->Gspos("GNYL",2,nameFMD,0,-yNylonTube[ifmd],
                 NulonTubeBegin+NylonTube[2]/2.,0, "ONLY");
         
      //last PCB
      par[0]=RoutHoneyComb[ifmd]-9;
      par[1]=RoutHoneyComb[ifmd];
      par[2]=zPCB/2;
      zInside += zHoneyComb/2+par[2];
      gMC->Gsposp(nameLPCB,1,nameFMD,0,0,zInside,0, "ONLY",par,3);
      
       par[2]=zPCB/2-0.02;
       zInPCB = -zPCB/2+par[2];
       gMC->Gsposp(nameGL10,1,nameLPCB,0,0,zInPCB,0, "ONLY",par,3);
       zInPCB+=par[2]+zCooper/2 ;
       par[2]=zCooper/2;
       gMC->Gsposp(nameLCopper,1,nameLPCB,0,0,zInPCB,0, "ONLY",par,3);
       zInPCB += zCooper/2 + zChips/2;
       par[2]=zChips/2;
       gMC->Gsposp(nameLChips,1,nameLPCB,0,0,zInPCB,0, "ONLY",par,3);
      
           
     //Granularity
       fSectorsSi1=20;
       fRingsSi1=256*2;
    // fRingsSi1=3; // for drawing only
       fSectorsSi2=40;
       fRingsSi2=128*2;
     //  fRingsSi2=3; //for  drawing onl
    if(ifmd==1||ifmd==3)
      { 
        gMC->Gsdvn(nameSector, nameSi , fSectorsSi2, 2);
        gMC->Gsdvn(nameRing, nameSector, fRingsSi2, 1);
      }
    else
      {
        gMC->Gsdvn(nameSector, nameSi , fSectorsSi1, 2);
        gMC->Gsdvn(nameRing, nameSector , fRingsSi1, 1);
      }
    
    }
}    


//------------------------------------------------------------------------
void AliFMDv0::CreateMaterials() 
{
 Int_t isxfld   = gAlice->Field()->Integ();
 Float_t sxmgmx = gAlice->Field()->Max();

 // Plastic CH
 Float_t aPlastic[2]={1.01,12.01};
 Float_t zPlastic[2]={1,6};
 Float_t wPlastic[2]={1,1};
 Float_t denPlastic=1.03;
   //
  //     60% SiO2 , 40% G10FR4 
 // PC board
 Float_t apcb[3]  = { 28.0855,15.9994,17.749 };
 Float_t zpcb[3]  = { 14.,8.,8.875 };
 Float_t wpcb[3]  = { .28,.32,.4 };
 Float_t denspcb  = 1.8;
   //
 //*** Definition Of avaible FMD materials ***
 AliMaterial(0, "FMD Air$", 14.61, 7.3, .001205, 30423.,999); 
 AliMixture(1, "Plastic$",aPlastic,zPlastic,denPlastic,-2,wPlastic);
 AliMixture(2, "SSD PCB$",   apcb, zpcb, denspcb, 3, wpcb);
 AliMaterial(3, "SSD Copper$", 63.546, 29., 8.96, 1.43, 999.);
 AliMaterial(4, "SSD Si$",      28.0855, 14., 2.33, 9.36, 999.);
 AliMaterial(5, "SSD Si chip$", 28.0855, 14., 2.33, 9.36, 999.);
 AliMaterial(6, "SSD C$",       12.011,   6., 2.265,18.8, 999.);
 AliMaterial(7, "SSD Kapton$", 12.011, 6., 0.01, 31.27, 999.);//honeycomb
  AliMaterial(8, "SSD G10FR4$", 17.749, 8.875, 1.8, 21.822, 999.);
   

//**
 AliMedium(0, "FMD air$", 0, 0, isxfld, sxmgmx, 1., .001, 1., .001, .001);
 AliMedium(1, "Plastic$", 1, 0,isxfld, sxmgmx,  10., .01, 1., .003, .003);
 AliMedium(2, "SSD PCB$", 2, 0, isxfld, sxmgmx, 1., .001, 1., .001, .001);
 AliMedium(3, "SSD Copper$", 3, 0,isxfld, sxmgmx,  10., .01, 1., .003, .003);
 AliMedium(4, "SSD Si$", 4, 1, isxfld, sxmgmx, 1., .001, 1., .001, .001);
 AliMedium(5, "SSD Si chip$", 5, 0,isxfld, sxmgmx,  10., .01, 1., .003, .003);
 AliMedium(6, "SSD C$", 6, 0,isxfld, sxmgmx,  10., .01, 1., .003, .003);
 AliMedium(7, "SSD Kapton$", 7, 0, isxfld, sxmgmx, 1., .001, 1., .001, .001);
 AliMedium(8, "SSD G10FR4$", 8, 0,isxfld, sxmgmx,  10., .01, 1., .003, .003);
 

}
//---------------------------------------------------------------------
void AliFMDv0::DrawDetector()
{
//
// Draw a shaded view of the Forward multiplicity detector version 0
//


//Set ALIC mother transparent
gMC->Gsatt("ALIC","SEEN",0);
//
//Set volumes visible
gMC->Gsatt("FMD0","SEEN",1);
gMC->Gsatt("FMD1","SEEN",1);
gMC->Gsatt("FMD2","SEEN",1);
gMC->Gsatt("FMD3","SEEN",1);
gMC->Gsatt("FMD4","SEEN",1);
gMC->Gsatt("FMD5","SEEN",1);

//
gMC->Gdopt("hide","on");
gMC->Gdopt("shad","on");
gMC->SetClipBox(".");
gMC->SetClipBox("*",0,1000,-1000,1000,-1000,1000);
gMC->DefaultRange();
gMC->Gdraw("alic",40,30,0,12,9.5,.2,0.2);
gMC->Gdhead(1111,"Forward multiplicity detector");
gMC->Gdopt("hide","off");
}
//-------------------------------------------------------------------
void AliFMDv0::Init()
{
// Initialises version 0 of the Forward Multiplicity Detector
//
AliFMD::Init();
fIdSens1=gMC->VolId("GRN1");
fIdSens2=gMC->VolId("GRN2");
fIdSens3=gMC->VolId("GRN3");
fIdSens4=gMC->VolId("GRN4");
fIdSens5=gMC->VolId("GRN5");
if (fDebug) printf("*** FMD version 0 initialized ***\n");
}

//-------------------------------------------------------------------

void AliFMDv0::StepManager()
{
  //
  // Called for every step in the Forward Multiplicity Detector
  //
}
Commit	Line	Data
4c039060	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	**************************************************************************/
88cb7938	15
	16	/* $Id$ */
	17
d28dcc0d	18	/////////////////////////////////////////////////////////////////////
	19	// //
	20	// Forward Multiplicity detector based on Silicon version 0 //
	21	//
	22	//Begin Html
fe4da5cc	23	/*
d28dcc0d	24	<img src="gif/AliFMDv0Class.gif">
fe4da5cc	25	*/
d28dcc0d	26	//End Html
	27	// //
	28	// //
	29	//////////////////////////////////////////////////////////////////////
fe4da5cc	30
88cb7938	31	#include <Riostream.h>
	32	#include <stdlib.h>
	33
d28dcc0d	34	#include <TGeometry.h>
88cb7938	35	#include <TLorentzVector.h>
88cb7938	36	#include <TMath.h>
d28dcc0d	37	#include <TNode.h>
88cb7938	38	#include <TTUBE.h>
d28dcc0d	39	#include <TLorentzVector.h>
5d12ce38	40	#include <TVirtualMC.h>
88cb7938	41
fe4da5cc	42	#include "AliFMDv0.h"
94de3818	43	#include "AliMagF.h"
88cb7938	44	#include "AliRndm.h"
88cb7938	45	#include "AliRun.h"
d28dcc0d	46	#include "AliFMDhit.h"
94de3818	47
fe4da5cc	48	ClassImp(AliFMDv0)
d28dcc0d	49
	50	//--------------------------------------------------------------------
	51	AliFMDv0::AliFMDv0(const char name, const char title):
	52	AliFMD(name,title)
fe4da5cc	53	{
fe4da5cc	54	//
d28dcc0d	55	// Standart constructor for Forward Multiplicity Detector version 0
fe4da5cc	56	//
d28dcc0d	57	fIdSens1=0;
37c55dc0	58	fIdSens2=0;
	59	fIdSens3=0;
	60	fIdSens4=0;
	61	fIdSens5=0;
d28dcc0d	62	// setBufferSize(128000);
fe4da5cc	63	}
d28dcc0d	64	//-------------------------------------------------------------------------
37c55dc0	65
fe4da5cc	66	void AliFMDv0::CreateGeometry()
fe4da5cc	67	{
46501dfb	68	//
d28dcc0d	69	// Create the geometry of Forward Multiplicity Detector version 0
46501dfb	70	//
	71	//Detector consists of 6 volumes:
	72	// 1st covered pseudorapidity interval from 3.3 to 2.0
	73	// and placed on 65cm in Z-direction;
	74	// 2nd - from 2.0 to 1.6 and Z=85 cm;
d28dcc0d	75	// 3d - the same pseudorapidity interval as the 1st
46501dfb	76	// but on the other side from the interaction point z=-65cm;
d28dcc0d	77	// 4th - simmetricaly with the 2nd :
46501dfb	78	// pseudorapidity from 2.0 to 1.6, Z=-85cm
	79	// 5th - from 3.6 to 4.7, Z=-270cm
	80	// 6th - from 4.5 to 5.5 , Z=-630cm.
	81	// Each part has 400mkm Si (sensetive area, detector itself),
d28dcc0d	82	// 0.75cm of plastic simulated electronics material,
	83	// Al support ring 2cm thickness and 1cm width placed on
	84	// the outer radius of each Si disk;
46501dfb	85	//
d28dcc0d	86	// begin Html
fe4da5cc	87	/*
d28dcc0d	88	<img src="gif/AliFMDv0.gif">
37c55dc0	89	*/
d28dcc0d	90	//
d28dcc0d	91
46501dfb	92
46501dfb	93
d28dcc0d	94	Int_t *idtmed = fIdtmed->GetArray();
46501dfb	95
d28dcc0d	96	Int_t ifmd;
d28dcc0d	97	Int_t idrotm[999];
46501dfb	98	Float_t zFMD,par[3],ppcon[15];
1663993c	99	Float_t z[5]={-62.8, -75.2, 83.4, 75.2, 340.};
46501dfb	100	Float_t NylonTube[3]={0.2,0.6,0.45};
	101	Float_t zPCB=0.12; Float_t zHoneyComb=0.5;
	102	Float_t zSi=0.03;
	103
	104	char nameFMD[5], nameSi[5], nameSector[5], nameRing[5];
	105	Char_t nameHoney[5], nameHoneyIn[5], nameHoneyOut[5];
	106	Char_t namePCB[5], nameCopper[5], nameChips[5], nameG10[5];
	107	Char_t nameLPCB[5], nameLCopper[5], nameLChips[5], nameGL10[5];;
	108	Float_t rin[5]={4.2,15.4,4.2,15.4,4.2};
	109	Float_t rout[5]={17.4,28.4,17.4,28.4,17.4};
	110	Float_t RinHoneyComb[5] ={ 5.15,16.4, 5.15,16.4, 5.15};
	111	Float_t RoutHoneyComb[5]={20.63,34.92,22.3, 32.02,20.63};
	112	Float_t zInside;
	113	Float_t zCooper=0.01; Float_t zChips=0.01;
	114	Float_t yNylonTube[5]={10,20,10,20,10};
37c55dc0	115
d28dcc0d	116
d28dcc0d	117	AliMatrix(idrotm[901], 90, 0, 90, 90, 180, 0);
46501dfb	118
	119
	120	// Nylon tubes
	121	gMC->Gsvolu("GNYL","TUBE", idtmed[1], NylonTube, 3); //support nylon tube
	122	Float_t wideSupport=zSi+3zPCB+2NylonTube[2]+zHoneyComb;
	123	cout<<" wideSupport "<<wideSupport<<endl;
d28dcc0d	124
46501dfb	125	for (ifmd=0; ifmd<5; ifmd++)
	126	{
	127	sprintf(nameFMD,"FMD%d",ifmd+1);
	128	ppcon[0]=0;
	129	ppcon[1]=360;
	130	ppcon[2]=4;
	131
	132	ppcon[3]=-wideSupport;
	133	ppcon[4]=rin[ifmd]+0.1;
	134	ppcon[5]=rout[ifmd]+0.1;
	135
	136	ppcon[6]=ppcon[3]+2zSi+2zPCB+2*NylonTube[2];
	137	ppcon[7]=rin[ifmd]+0.1;
	138	ppcon[8]=rout[ifmd]+0.1;
	139
	140	ppcon[9]=ppcon[6];
	141	ppcon[10]=RinHoneyComb[ifmd]+0.1;
	142	ppcon[11]=RoutHoneyComb[ifmd]+0.1;
d28dcc0d	143
46501dfb	144	ppcon[12]=ppcon[9]+2*zHoneyComb+zPCB;
	145	ppcon[13]=RinHoneyComb[ifmd]+0.1;
	146	ppcon[14]=RoutHoneyComb[ifmd]+0.1;
	147	gMC->Gsvolu(nameFMD,"PCON",idtmed[0],ppcon,15);
	148	if (z[ifmd] >0){
	149	zFMD=z[ifmd]+wideSupport;
	150	gMC->Gspos(nameFMD,1,"ALIC",0,0,zFMD,0, "ONLY");}
	151	else {
	152	zFMD=z[ifmd]-wideSupport;
	153	gMC->Gspos(nameFMD,1,"ALIC",0,0,zFMD,idrotm[901], "ONLY");}
	154	//silicon
	155	sprintf(nameSi,"GSI%d",ifmd+1);
	156	sprintf(nameSector,"GSC%d",ifmd+1);
	157	sprintf(nameRing,"GRN%d",ifmd+1);
	158
	159	//honeycomb support
	160	sprintf(nameHoney,"GSU%d",ifmd+1);
	161	gMC->Gsvolu(nameHoney,"TUBE", idtmed[0], par, 0); //honeycomb
	162	sprintf(nameHoneyIn,"GHI%d",ifmd+1);
	163	gMC->Gsvolu(nameHoneyIn,"TUBE", idtmed[7], par, 0); //honey comb inside
	164	sprintf(nameHoneyOut,"GHO%d",ifmd+1);
	165	gMC->Gsvolu(nameHoneyOut,"TUBE", idtmed[6], par, 0); //honey comb skin
	166	//PCB
	167	sprintf(namePCB,"GPC%d",ifmd+1);
	168	gMC->Gsvolu(namePCB,"TUBE", idtmed[0], par, 0); //PCB
	169	sprintf(nameCopper,"GCO%d",ifmd+1);
	170	gMC->Gsvolu(nameCopper,"TUBE", idtmed[3], par, 0); // Cooper
	171	sprintf(nameChips,"GCH%d",ifmd+1);
	172	gMC->Gsvolu(nameChips,"TUBE", idtmed[5], par, 0); // Si chips
	173	sprintf(nameG10,"G10%d",ifmd+1);
	174	gMC->Gsvolu(nameG10,"TUBE", idtmed[2], par, 0); //G10 plate
	175	//last PCB
	176	sprintf(nameLPCB,"GPL%d",ifmd+1);
	177	gMC->Gsvolu(nameLPCB,"TUBE", idtmed[0], par, 0); //PCB
	178	sprintf(nameLCopper,"GCL%d",ifmd+1);
	179	gMC->Gsvolu(nameLCopper,"TUBE", idtmed[3], par, 0); // Cooper
	180	sprintf(nameLChips,"GHL%d",ifmd+1);
	181	gMC->Gsvolu(nameLChips,"TUBE", idtmed[5], par, 0); // Si chips
	182	sprintf(nameGL10,"G1L%d",ifmd+1);
	183	gMC->Gsvolu(nameGL10,"TUBE", idtmed[2], par, 0); // Last G10
	184	par[0]=rin[ifmd]; // pipe size
	185	par[1]=rout[ifmd];
	186	par[2]=zSi/2;
	187	gMC->Gsvolu(nameSi,"TUBE", idtmed[4], par, 3);
	188	zInside=ppcon[3]+par[2];
	189	gMC->Gspos(nameSi,ifmd+1,nameFMD,0,0,zInside,0, "ONLY");
	190	//PCB 1
	191	zInside += par[2]+zPCB/2;
	192	par[2]=zPCB/2;
	193	gMC->Gsposp(namePCB,1,nameFMD,0,0,zInside,0, "ONLY",par,3);
	194	zInside += zPCB;
	195	gMC->Gsposp(namePCB,2,nameFMD,0,0,zInside,0, "ONLY",par,3);
	196	Float_t NulonTubeBegin=zInside+2.5*zPCB;
	197	par[2]=zPCB/2-0.02;
	198	Float_t zInPCB = -zPCB/2+par[2];
	199	gMC->Gsposp(nameG10,1,namePCB,0,0,zInPCB,0, "ONLY",par,3);
	200	zInPCB+=par[2]+zCooper/2 ;
	201	par[2]=zCooper/2;
	202	gMC->Gsposp(nameCopper,1,namePCB,0,0,zInPCB,0, "ONLY",par,3);
	203	zInPCB += zCooper/2 + zChips/2;
	204	par[2]=zChips/2;
	205	gMC->Gsposp(nameChips,1,namePCB,0,0,zInPCB,0, "ONLY",par,3);
	206	//HoneyComb
	207	zHoneyComb=0.8;
208	par[0] = RinHoneyComb[ifmd];
209	par[1] = RoutHoneyComb[ifmd];
210	par[2] = zHoneyComb/2;
211	zInside += 2*NylonTube[2]+par[2];
212	gMC->Gsposp(nameHoney,1,nameFMD,0,0,zInside,0, "ONLY",par,3);
213	par[2]=0.1/2;
214	Float_t zHoney=-zHoneyComb/2+par[2];
215	gMC->Gsposp(nameHoneyOut,1,nameHoney,0,0,zHoney,0,
216	"ONLY",par,3); //shkurki
217	zHoney=zHoneyComb/2-par[2];
218	gMC->Gsposp(nameHoneyOut,2,nameHoney,0,0,zHoney,0, "ONLY",par,3);
219	par[2]=(zHoneyComb-2.*0.1)/2; //soty vnutri
220	gMC->Gsposp(nameHoneyIn,1,nameHoney,0,0,0,0, "ONLY",par,3);
221
222	gMC->Gspos("GNYL",1,nameFMD,0,yNylonTube[ifmd],
223	NulonTubeBegin+NylonTube[2]/2.,0, "ONLY");
224	gMC->Gspos("GNYL",2,nameFMD,0,-yNylonTube[ifmd],
225	NulonTubeBegin+NylonTube[2]/2.,0, "ONLY");
226
227	//last PCB
228	par[0]=RoutHoneyComb[ifmd]-9;
229	par[1]=RoutHoneyComb[ifmd];
230	par[2]=zPCB/2;
231	zInside += zHoneyComb/2+par[2];
232	gMC->Gsposp(nameLPCB,1,nameFMD,0,0,zInside,0, "ONLY",par,3);
233
234	par[2]=zPCB/2-0.02;
235	zInPCB = -zPCB/2+par[2];
236	gMC->Gsposp(nameGL10,1,nameLPCB,0,0,zInPCB,0, "ONLY",par,3);
237	zInPCB+=par[2]+zCooper/2 ;
238	par[2]=zCooper/2;
239	gMC->Gsposp(nameLCopper,1,nameLPCB,0,0,zInPCB,0, "ONLY",par,3);
240	zInPCB += zCooper/2 + zChips/2;
241	par[2]=zChips/2;
242	gMC->Gsposp(nameLChips,1,nameLPCB,0,0,zInPCB,0, "ONLY",par,3);
243
244
a39f3926	245	//Granularity
46501dfb	246	fSectorsSi1=20;
	247	fRingsSi1=256*2;
	248	// fRingsSi1=3; // for drawing only
	249	fSectorsSi2=40;
	250	fRingsSi2=128*2;
	251	// fRingsSi2=3; //for drawing onl
a39f3926	252	if(ifmd==1\|\|ifmd==3)
37c55dc0	253	{
46501dfb	254	gMC->Gsdvn(nameSector, nameSi , fSectorsSi2, 2);
46501dfb	255	gMC->Gsdvn(nameRing, nameSector, fRingsSi2, 1);
37c55dc0	256	}
	257	else
	258	{
46501dfb	259	gMC->Gsdvn(nameSector, nameSi , fSectorsSi1, 2);
46501dfb	260	gMC->Gsdvn(nameRing, nameSector , fRingsSi1, 1);
37c55dc0	261	}
46501dfb	262
46501dfb	263	}
d28dcc0d	264	}
37c55dc0	265
37c55dc0	266
d28dcc0d	267	//------------------------------------------------------------------------
46501dfb	268	void AliFMDv0::CreateMaterials()
d28dcc0d	269	{
	270	Int_t isxfld = gAlice->Field()->Integ();
	271	Float_t sxmgmx = gAlice->Field()->Max();
fe4da5cc	272
d28dcc0d	273	// Plastic CH
	274	Float_t aPlastic[2]={1.01,12.01};
	275	Float_t zPlastic[2]={1,6};
	276	Float_t wPlastic[2]={1,1};
	277	Float_t denPlastic=1.03;
	278	//
46501dfb	279	// 60% SiO2 , 40% G10FR4
	280	// PC board
	281	Float_t apcb[3] = { 28.0855,15.9994,17.749 };
	282	Float_t zpcb[3] = { 14.,8.,8.875 };
	283	Float_t wpcb[3] = { .28,.32,.4 };
	284	Float_t denspcb = 1.8;
	285	//
d28dcc0d	286	//* Definition Of avaible FMD materials *
46501dfb	287	AliMaterial(0, "FMD Air$", 14.61, 7.3, .001205, 30423.,999);
	288	AliMixture(1, "Plastic$",aPlastic,zPlastic,denPlastic,-2,wPlastic);
	289	AliMixture(2, "SSD PCB$", apcb, zpcb, denspcb, 3, wpcb);
	290	AliMaterial(3, "SSD Copper$", 63.546, 29., 8.96, 1.43, 999.);
	291	AliMaterial(4, "SSD Si$", 28.0855, 14., 2.33, 9.36, 999.);
	292	AliMaterial(5, "SSD Si chip$", 28.0855, 14., 2.33, 9.36, 999.);
	293	AliMaterial(6, "SSD C$", 12.011, 6., 2.265,18.8, 999.);
	294	AliMaterial(7, "SSD Kapton$", 12.011, 6., 0.01, 31.27, 999.);//honeycomb
	295	AliMaterial(8, "SSD G10FR4$", 17.749, 8.875, 1.8, 21.822, 999.);
	296
fe4da5cc	297
d28dcc0d	298	//**
46501dfb	299	AliMedium(0, "FMD air$", 0, 0, isxfld, sxmgmx, 1., .001, 1., .001, .001);
	300	AliMedium(1, "Plastic$", 1, 0,isxfld, sxmgmx, 10., .01, 1., .003, .003);
	301	AliMedium(2, "SSD PCB$", 2, 0, isxfld, sxmgmx, 1., .001, 1., .001, .001);
	302	AliMedium(3, "SSD Copper$", 3, 0,isxfld, sxmgmx, 10., .01, 1., .003, .003);
	303	AliMedium(4, "SSD Si$", 4, 1, isxfld, sxmgmx, 1., .001, 1., .001, .001);
	304	AliMedium(5, "SSD Si chip$", 5, 0,isxfld, sxmgmx, 10., .01, 1., .003, .003);
	305	AliMedium(6, "SSD C$", 6, 0,isxfld, sxmgmx, 10., .01, 1., .003, .003);
	306	AliMedium(7, "SSD Kapton$", 7, 0, isxfld, sxmgmx, 1., .001, 1., .001, .001);
	307	AliMedium(8, "SSD G10FR4$", 8, 0,isxfld, sxmgmx, 10., .01, 1., .003, .003);
d28dcc0d	308
	309
	310
	311	}
	312	//---------------------------------------------------------------------
	313	void AliFMDv0::DrawDetector()
fe4da5cc	314	{
d28dcc0d	315	//
	316	// Draw a shaded view of the Forward multiplicity detector version 0
	317	//
fe4da5cc	318
d28dcc0d	319
d28dcc0d	320	//Set ALIC mother transparent
5d02ea6f	321	gMC->Gsatt("ALIC","SEEN",0);
d28dcc0d	322	//
	323	//Set volumes visible
	324	gMC->Gsatt("FMD0","SEEN",1);
	325	gMC->Gsatt("FMD1","SEEN",1);
	326	gMC->Gsatt("FMD2","SEEN",1);
	327	gMC->Gsatt("FMD3","SEEN",1);
	328	gMC->Gsatt("FMD4","SEEN",1);
	329	gMC->Gsatt("FMD5","SEEN",1);
	330
	331	//
	332	gMC->Gdopt("hide","on");
	333	gMC->Gdopt("shad","on");
	334	gMC->SetClipBox(".");
	335	gMC->SetClipBox("*",0,1000,-1000,1000,-1000,1000);
	336	gMC->DefaultRange();
	337	gMC->Gdraw("alic",40,30,0,12,9.5,.2,0.2);
	338	gMC->Gdhead(1111,"Forward multiplicity detector");
	339	gMC->Gdopt("hide","off");
	340	}
	341	//-------------------------------------------------------------------
	342	void AliFMDv0::Init()
	343	{
	344	// Initialises version 0 of the Forward Multiplicity Detector
	345	//
d28dcc0d	346	AliFMD::Init();
37c55dc0	347	fIdSens1=gMC->VolId("GRN1");
	348	fIdSens2=gMC->VolId("GRN2");
	349	fIdSens3=gMC->VolId("GRN3");
	350	fIdSens4=gMC->VolId("GRN4");
	351	fIdSens5=gMC->VolId("GRN5");
0422d7f8	352	if (fDebug) printf("* FMD version 0 initialized *\n");
fe4da5cc	353	}
fe4da5cc	354
d28dcc0d	355	//-------------------------------------------------------------------
	356
	357	void AliFMDv0::StepManager()
fe4da5cc	358	{
fe4da5cc	359	//
d28dcc0d	360	// Called for every step in the Forward Multiplicity Detector
fe4da5cc	361	//
37c55dc0	362	}
fe4da5cc	363