/*
$Log$
+Revision 1.20 2001/07/20 10:03:14 morsch
+Changes needed to work with Root 3.01 (substitute lhs [] operator). (Jiri Chudoba)
+
+Revision 1.19 2001/05/16 14:57:17 alibrary
+New files for folders and Stack
+
+Revision 1.18 2001/04/11 12:33:56 morsch
+Bug in GetPadC in case of staggered planes corrected. (Thanks to J.P. Cussonneau)
+
+Revision 1.17 2001/01/30 12:17:04 morsch
+Remove obolete print-statement.
+
+Revision 1.16 2001/01/30 09:23:14 hristov
+Streamers removed (R.Brun)
+
+Revision 1.15 2001/01/26 21:25:48 morsch
+Empty default constructors and.
+
+Revision 1.14 2000/12/21 22:12:41 morsch
+Clean-up of coding rule violations,
+
+Revision 1.13 2000/12/07 10:41:51 hristov
+fCorr replaced by fCorrA
+
+Revision 1.12 2000/12/06 11:55:41 morsch
+Introduce SetOffsetY(Float_t off) method as simplified simulation of pad staggering.
+fOffset is the staggering offset in y.
+
+Revision 1.11 2000/11/06 09:20:43 morsch
+AliMUON delegates part of BuildGeometry() to AliMUONSegmentation using the
+Draw() method. This avoids code and parameter replication.
+
+Revision 1.10 2000/10/18 11:42:06 morsch
+- AliMUONRawCluster contains z-position.
+- Some clean-up of useless print statements during initialisations.
+
+Revision 1.9 2000/10/18 08:41:32 morsch
+Make NextPad() and MorePads() to iterate until the end.
+
+Revision 1.8 2000/10/03 21:48:07 morsch
+Adopt to const declaration of some of the methods in AliSegmentation.
+
+Revision 1.7 2000/10/02 21:28:09 fca
+Removal of useless dependecies via forward declarations
+
+Revision 1.6 2000/10/02 16:58:29 egangler
+Cleaning of the code :
+-> coding conventions
+-> void Streamers
+-> some useless includes removed or replaced by "class" statement
+
Revision 1.5 2000/07/13 16:19:44 fca
Mainly coding conventions + some small bug fixes
/////////////////////////////////////////////////////
#include <TBox.h>
+#include <TTUBE.h>
+#include <TBRIK.h>
+#include <TNode.h>
+#include <TGeometry.h>
#include <TF1.h>
#include <TObjArray.h>
#include <iostream.h>
#include "AliMUONSegmentationV01.h"
#include "AliMUON.h"
+#include "AliMUONChamber.h"
+#include "AliRun.h"
{
// Dummy copy constructor
}
+
AliMUONSegmentationV01::AliMUONSegmentationV01()
{
// Default constructor
- fNsec=4;
- fRSec.Set(fNsec);
- fNDiv.Set(fNsec);
- fDpxD.Set(fNsec);
- fRSec[0]=fRSec[1]=fRSec[2]=fRSec[3]=0;
- fNDiv[0]=fNDiv[1]=fNDiv[2]=fNDiv[3]=0;
- fDpxD[0]=fDpxD[1]=fDpxD[2]=fDpxD[3]=0;
- fCorr = new TObjArray(3);
- (*fCorr)[0]=0;
- (*fCorr)[1]=0;
- (*fCorr)[2]=0;
+ fRSec = 0;
+ fNDiv = 0;
+ fDpxD = 0;
+ fCorrA = 0;
+}
+
+AliMUONSegmentationV01::AliMUONSegmentationV01(Int_t nsec)
+{
+// Non default constructor
+
+ fNsec = nsec;
+ fRSec = new TArrayF(fNsec);
+ fNDiv = new TArrayI(fNsec);
+ fDpxD = new TArrayF(fNsec);
+
+
+ (*fRSec)[0]=(*fRSec)[1]=(*fRSec)[2]=(*fRSec)[3]=0;
+ (*fNDiv)[0]=(*fNDiv)[1]=(*fNDiv)[2]=(*fNDiv)[3]=0;
+ (*fDpxD)[0]=(*fDpxD)[1]=(*fDpxD)[2]=(*fDpxD)[3]=0;
+ fCorrA = new TObjArray(3);
+ fCorrA->AddAt(0,0);
+ fCorrA->AddAt(0,1);
+ fCorrA->AddAt(0,2);
+ fOffsetY=0;
+}
+
+AliMUONSegmentationV01::~AliMUONSegmentationV01()
+{
+// Destructor
+ if (fRSec) delete fRSec;
+ if (fNDiv) delete fNDiv;
+ if (fDpxD) delete fDpxD;
+ if (fCorrA) {
+ fCorrA->Delete();
+ delete fCorrA;
+ }
}
-Float_t AliMUONSegmentationV01::Dpx(Int_t isec)
+
+Float_t AliMUONSegmentationV01::Dpx(Int_t isec) const
{
//
// Returns x-pad size for given sector isec
- return fDpxD[isec];
+ Float_t dpx = (*fDpxD)[isec];
+ return dpx;
}
-Float_t AliMUONSegmentationV01::Dpy(Int_t isec)
+Float_t AliMUONSegmentationV01::Dpy(Int_t isec) const
{
//
// Returns y-pad size for given sector isec
//
// Set the radii of the segmentation zones
for (Int_t i=0; i<4; i++) {
- fRSec[i]=r[i];
- printf("\n R %d %f \n",i,fRSec[i]);
-
+ (*fRSec)[i]=r[i];
}
}
// fDpx
//
for (Int_t i=0; i<4; i++) {
- fNDiv[i]=ndiv[i];
- printf("\n Ndiv %d %d \n",i,fNDiv[i]);
+ (*fNDiv)[i]=ndiv[i];
}
ndiv[0]=ndiv[1];
}
// This version approximates concentric segmentation zones
//
Int_t isec;
- printf("\n Initialise segmentation v01 -- test !!!!!!!!!!!!!! \n");
- fNpy=Int_t(fRSec[fNsec-1]/fDpy)+1;
+ //printf("\n Initialise Segmentation V01\n");
+
+
+ fNpy=Int_t((*fRSec)[fNsec-1]/fDpy)+1;
- fDpxD[fNsec-1]=fDpx;
+ (*fDpxD)[fNsec-1]=fDpx;
if (fNsec > 1) {
for (Int_t i=fNsec-2; i>=0; i--){
- fDpxD[i]=fDpxD[fNsec-1]/fNDiv[i];
- printf("\n test ---dx %d %f \n",i,fDpxD[i]);
+ (*fDpxD)[i]=(*fDpxD)[fNsec-1]/(*fNDiv)[i];
}
}
//
for (Int_t iy=1; iy<=fNpy; iy++) {
//
Float_t x=iy*fDpy-fDpy/2;
- if (x > fRSec[isec]) {
+ if (x > (*fRSec)[isec]) {
fNpxS[isec][iy]=0;
fCx[isec][iy]=0;
} else {
- ry=TMath::Sqrt(fRSec[isec]*fRSec[isec]-x*x);
+ ry=TMath::Sqrt((*fRSec)[isec]*(*fRSec)[isec]-x*x);
if (isec > 1) {
- dnx= Int_t((ry-fCx[isec-1][iy])/fDpxD[isec]);
+ dnx= Int_t((ry-fCx[isec-1][iy])/(*fDpxD)[isec]);
if (isec < fNsec-1) {
if (TMath::Odd((Long_t)dnx)) dnx++;
}
fNpxS[isec][iy]=fNpxS[isec-1][iy]+dnx;
- fCx[isec][iy]=fCx[isec-1][iy]+dnx*fDpxD[isec];
+ fCx[isec][iy]=fCx[isec-1][iy]+dnx*(*fDpxD)[isec];
} else if (isec == 1) {
- dnx= Int_t((ry-fCx[isec-1][iy])/fDpxD[isec]);
+ dnx= Int_t((ry-fCx[isec-1][iy])/(*fDpxD)[isec]);
fNpxS[isec][iy]=fNpxS[isec-1][iy]+dnx;
add=4 - (fNpxS[isec][iy])%4;
if (add < 4) fNpxS[isec][iy]+=add;
dnx=fNpxS[isec][iy]-fNpxS[isec-1][iy];
- fCx[isec][iy]=fCx[isec-1][iy]+dnx*fDpxD[isec];
+ fCx[isec][iy]=fCx[isec-1][iy]+dnx*(*fDpxD)[isec];
} else {
- dnx=Int_t(ry/fDpxD[isec]);
+ dnx=Int_t(ry/(*fDpxD)[isec]);
fNpxS[isec][iy]=dnx;
- fCx[isec][iy]=dnx*fDpxD[isec];
+ fCx[isec][iy]=dnx*(*fDpxD)[isec];
}
}
} // y-pad loop
} // sector loop
+// reference to chamber
+ AliMUON *pMUON = (AliMUON *) gAlice->GetModule("MUON");
+ fChamber=&(pMUON->Chamber(chamber));
+ fZ = fChamber->Z();
+ fId=chamber;
}
Int_t AliMUONSegmentationV01::Sector(Int_t ix, Int_t iy)
{
// Returns pad coordinates (ix,iy) for given real coordinates (x,y)
//
- iy = (y>0)? Int_t(y/fDpy)+1 : Int_t(y/fDpy)-1;
+ iy = (y-fOffsetY >0)?
+ Int_t((y-fOffsetY)/fDpy)+1
+ :
+ Int_t((y-fOffsetY)/fDpy)-1;
+
if (iy > fNpy) iy= fNpy;
if (iy < -fNpy) iy=-fNpy;
//
}
}
if (isec>0) {
- ix= Int_t((absx-fCx[isec-1][absiy])/fDpxD[isec])
+ ix= Int_t((absx-fCx[isec-1][absiy])/(*fDpxD)[isec])
+fNpxS[isec-1][absiy]+1;
} else if (isec == 0) {
- ix= Int_t(absx/fDpxD[isec])+1;
+ ix= Int_t(absx/(*fDpxD)[isec])+1;
} else {
ix=fNpxS[fNsec-1][absiy]+1;
}
{
// Returns real coordinates (x,y) for given pad coordinates (ix,iy)
//
- y = (iy>0) ? Float_t(iy*fDpy)-fDpy/2. : Float_t(iy*fDpy)+fDpy/2.;
+ y = (iy>0) ?
+ Float_t(iy*fDpy)-fDpy/2.+fOffsetY
+ :
+ Float_t(iy*fDpy)+fDpy/2.+fOffsetY;
+
//
// Find sector isec
Int_t isec=AliMUONSegmentationV01::Sector(ix,iy);
Int_t absix=TMath::Abs(ix);
Int_t absiy=TMath::Abs(iy);
if (isec) {
- x=fCx[isec-1][absiy]+(absix-fNpxS[isec-1][absiy])*fDpxD[isec];
- x=(ix>0) ? x-fDpxD[isec]/2 : -x+fDpxD[isec]/2;
+ x=fCx[isec-1][absiy]+(absix-fNpxS[isec-1][absiy])*(*fDpxD)[isec];
+ x=(ix>0) ? x-(*fDpxD)[isec]/2 : -x+(*fDpxD)[isec]/2;
} else {
x=y=0;
}
Float_t y02=yhit + dy;
//
// find the pads over which the charge distributes
+
GetPadI(x01,y01,fIxmin,fIymin);
GetPadI(x02,y02,fIxmax,fIymax);
fXmin=x01;
Int_t iyc;
// step from left to right
+
if (fX < fXmax && fX != 0) {
if (fIx==-1) fIx++;
fIx++;
// get x-pad coordiante for first pad in row (fIx)
GetPadI(fXmin,yc,fIx,iyc);
} else {
- printf("\n Error: Stepping outside integration region\n ");
+ fIx=-1;
+ fIy=-1;
}
GetPadC(fIx,fIy,fX,fY);
fSector=Sector(fIx,fIy);
}
Int_t AliMUONSegmentationV01::MorePads()
+
+{
// Stopping condition for the iterator over pads
//
// Are there more pads in the integration region
-{
+ return (fIx != -1 || fIy != -1);
+/*
if ((fX >= fXmax && fIy >= fIymax) || fY==0) {
return 0;
} else {
return 1;
}
+*/
}
void AliMUONSegmentationV01::
*Nlist=i;
}
-void AliMUONSegmentationV01::GiveTestPoints(Int_t &n, Float_t *x, Float_t *y)
+void AliMUONSegmentationV01::GiveTestPoints(Int_t &n, Float_t *x, Float_t *y) const
{
// Returns test point on the pad plane.
// Used during determination of the segmoid correction of the COG-method
n=3;
- x[0]=(fRSec[0]+fRSec[1])/2/TMath::Sqrt(2.);
+ x[0]=((*fRSec)[0]+(*fRSec)[1])/2/TMath::Sqrt(2.);
y[0]=x[0];
- x[1]=(fRSec[1]+fRSec[2])/2/TMath::Sqrt(2.);
+ x[1]=((*fRSec)[1]+(*fRSec)[2])/2/TMath::Sqrt(2.);
y[1]=x[1];
- x[2]=(fRSec[2]+fRSec[3])/2/TMath::Sqrt(2.);
+ x[2]=((*fRSec)[2]+(*fRSec)[3])/2/TMath::Sqrt(2.);
y[2]=x[2];
}
-void AliMUONSegmentationV01::Draw(const char *)
+void AliMUONSegmentationV01::Draw(const char* opt) const
{
+
// Draws the segmentation zones
//
+ if (!strcmp(opt,"eventdisplay")) {
+ const int kColorMUON = kBlue;
+
+ TRotMatrix* rot000 = new TRotMatrix("Rot000"," ", 90, 0, 90, 90, 0, 0);
+ TRotMatrix* rot090 = new TRotMatrix("Rot090"," ", 90, 90, 90,180, 0, 0);
+ TRotMatrix* rot180 = new TRotMatrix("Rot180"," ", 90,180, 90,270, 0, 0);
+ TRotMatrix* rot270 = new TRotMatrix("Rot270"," ", 90,270, 90, 0, 0, 0);
+
+ char nameChamber[9], nameSense[9], nameFrame[9], nameNode[9];
+ char nameSense1[9], nameSense2[9];
+ TNode *node, *nodeF;
+
+ sprintf(nameChamber,"C_MUON%d",fId+1);
+ sprintf(nameSense,"S_MUON%d",fId+1);
+ sprintf(nameSense1,"S1_MUON%d",fId+1);
+ sprintf(nameSense2,"S2_MUON%d",fId+1);
+ sprintf(nameFrame,"F_MUON%d",fId+1);
+
+ TNode* top=gAlice->GetGeometry()->GetNode("alice");
+
+ Float_t rmin = (*fRSec)[0]-3;
+ Float_t rmax = (*fRSec)[3]+3;
+ new TTUBE(nameChamber,"Mother","void",rmin,rmax,0.25,1.);
+ rmin = (*fRSec)[0];
+ rmax = (*fRSec)[3];
+ new TTUBE(nameSense,"Sens. region","void",rmin,rmax,0.25, 1.);
+ Float_t dx=(rmax-rmin)/2;
+ Float_t dy=3.;
+ Float_t dz=0.25;
+ TBRIK* frMUON = new TBRIK(nameFrame,"Frame","void",dx,dy,dz);
+ top->cd();
+ sprintf(nameNode,"MUON%d",100+fId+1);
+ node = new TNode(nameNode,"ChamberNode",nameChamber,0,0,fChamber->Z(),"");
+ node->SetLineColor(kColorMUON);
+ AliMUON *pMUON = (AliMUON *) gAlice->GetModule("MUON");
+ (pMUON->Nodes())->Add(node);
+ node->cd();
+ sprintf(nameNode,"MUON%d",200+fId+1);
+ node = new TNode(nameNode,"Sens. Region Node",nameSense,0,0,0,"");
+ node->SetLineColor(kColorMUON);
+ node->cd();
+ Float_t dr=dx+rmin;
+ sprintf(nameNode,"MUON%d",300+fId+1);
+ nodeF = new TNode(nameNode,"Frame0",frMUON,dr, 0, 0,rot000,"");
+ nodeF->SetLineColor(kColorMUON);
+ node->cd();
+ sprintf(nameNode,"MUON%d",400+fId+1);
+ nodeF = new TNode(nameNode,"Frame1",frMUON,0 ,dr,0,rot090,"");
+ nodeF->SetLineColor(kColorMUON);
+ node->cd();
+ sprintf(nameNode,"MUON%d",500+fId+1);
+ nodeF = new TNode(nameNode,"Frame2",frMUON,-dr,0,0,rot180,"");
+ nodeF->SetLineColor(kColorMUON);
+ node ->cd();
+ sprintf(nameNode,"MUON%d",600+fId+1);
+ nodeF = new TNode(nameNode,"Frame3",frMUON,0,-dr,0,rot270,"");
+ nodeF->SetLineColor(kColorMUON);
+ } else {
TBox *box;
Float_t dx=0.95/fCx[3][1]/2;
Float_t xc=0.5;
Float_t yc=0.5;
- for (Int_t iy=1; iy<Npy(); iy++)
- {
- for (Int_t isec=0; isec<4; isec++) {
- if (isec==0) {
- x0=0;
- x1=fCx[isec][iy]*dx;
- } else {
- x0=fCx[isec-1][iy]*dx;
- x1=fCx[isec][iy]*dx;
- }
- y0=Float_t(iy-1)*dy;
- y1=y0+dy;
- box=new TBox(x0+xc,y0+yc,x1+xc,y1+yc);
- box->SetFillColor(isec+1);
- box->Draw();
-
- box=new TBox(-x1+xc,y0+yc,-x0+xc,y1+yc);
- box->SetFillColor(isec+1);
- box->Draw();
-
- box=new TBox(x0+xc,-y1+yc,x1+xc,-y0+yc);
- box->SetFillColor(isec+1);
- box->Draw();
-
- box=new TBox(-x1+xc,-y1+yc,-x0+xc,-y0+yc);
- box->SetFillColor(isec+1);
- box->Draw();
+ for (Int_t iy=1; iy<Npy(); iy++) {
+ for (Int_t isec=0; isec<4; isec++) {
+ if (isec==0) {
+ x0=0;
+ x1=fCx[isec][iy]*dx;
+ } else {
+ x0=fCx[isec-1][iy]*dx;
+ x1=fCx[isec][iy]*dx;
}
+ y0=Float_t(iy-1)*dy;
+ y1=y0+dy;
+ box=new TBox(x0+xc,y0+yc,x1+xc,y1+yc);
+ box->SetFillColor(isec+1);
+ box->Draw();
+
+ box=new TBox(-x1+xc,y0+yc,-x0+xc,y1+yc);
+ box->SetFillColor(isec+1);
+ box->Draw();
+
+ box=new TBox(x0+xc,-y1+yc,x1+xc,-y0+yc);
+ box->SetFillColor(isec+1);
+ box->Draw();
+
+ box=new TBox(-x1+xc,-y1+yc,-x0+xc,-y0+yc);
+ box->SetFillColor(isec+1);
+ box->Draw();
+ }
}
+ }
}
void AliMUONSegmentationV01::SetCorrFunc(Int_t isec, TF1* func)
{
- (*fCorr)[isec]=func;
+// Set the correction function
+ fCorrA->AddAt(func,isec);
}
-TF1* AliMUONSegmentationV01::CorrFunc(Int_t isec)
+TF1* AliMUONSegmentationV01::CorrFunc(Int_t isec) const
{
- return (TF1*) (*fCorr)[isec];
+// Get correction function
+ //PH return (TF1*) (*fCorrA)[isec];
+ return (TF1*) fCorrA->At(isec);
}
AliMUONSegmentationV01& AliMUONSegmentationV01::operator
// Dummy assignment operator
return *this;
}
+