SOLARIS_Analysis/Cleopatra/alpha.C

#include "ClassHelios.h"
#include "TROOT.h"
#include "TBenchmark.h"
#include "TLorentzVector.h"
#include "TMath.h"
#include "TFile.h"
#include "TF1.h"
#include "TTree.h"
#include "TRandom.h"
#include <stdlib.h>
#include <vector>
#include <fstream>
#include <TObjArray.h>

//----------- usage 
// $root transfer.C+ | tee output.txt
// this will same the massage to output.txt

const double ma = 3727.3792; // alpha mass

void alpha(){

   //================================================= User Setting
   const int numEnergy = 4;
   double energy [numEnergy] = {3.18, 5.16, 5.49, 5.81};

   int numEvent = 1000000;
   
   //---- HELIOS detector geometry
   //string heliosDetGeoFile = "detectorGeo.txt";
   string heliosDetGeoFile = "";
   double BField = 2.5; // T
   double BFieldTheta = 0.; // direction of B-field
   bool isCoincidentWithRecoil = false; 
   double eSigma = 0.040 ; // detector energy sigma MeV
   double zSigma = 0.500 ; // detector position sigma mm
   
   //---- save root file name
   TString saveFileName = "alpha.root";
   
   //=============================================================
   //=============================================================
   
   printf("===================================================\n");
   printf("=============  Alpha source in HELIOS  ============\n");
   printf("===================================================\n");
   
   printf("========= Alpha Enegry : \n");
   for( int i = 0; i < numEnergy ; i++){
      printf("%2d | %6.2f MeV\n", i, energy[i]);
   }
   
   
   //======== Set HELIOS
   printf("############################################## HELIOS configuration\n");   
   HELIOS helios;
   helios.OverrideMagneticFieldDirection(BFieldTheta);
   helios.OverrideFirstPos(-700);
   //helios.OverrideDetectorDistance(5);
   bool sethelios = helios.SetDetectorGeometry(heliosDetGeoFile);
   if( !sethelios){
		helios.OverrideMagneticField(BField);
		printf("======== B-field : %5.2f T, Theta : %6.2f deg\n", BField, BFieldTheta);
	}
   helios.SetCoincidentWithRecoil(isCoincidentWithRecoil);
   printf("========== energy resol.: %f MeV\n", eSigma);
   printf("=========== pos-Z resol.: %f mm \n", zSigma);
   
   //====================== build tree
   TFile * saveFile = new TFile(saveFileName, "recreate");
   TTree * tree = new TTree("tree", "tree");
   
   double theta, phi, T;
   
   int hit; // the output of Helios.CalHit
   double e, z, x, t;
   int loop, detID;
   double dphi, rho; //rad of rotation, and radius
   int energyID;
   double xHit, yHit;

   tree->Branch("hit", &hit, "hit/I");
   tree->Branch("theta", &theta, "theta/D");
   tree->Branch("phi", &phi, "phi/D");
   tree->Branch("T", &T, "T/D");
   tree->Branch("energy", &energy, "energy/D");
   tree->Branch("energyID", &energyID, "energyID/I");
   
   tree->Branch("e", &e, "e/D");
   tree->Branch("x", &x, "x/D");
   tree->Branch("z", &z, "z/D");
   tree->Branch("t", &t, "t/D");
   tree->Branch("detID", &detID, "detID/I");
   tree->Branch("loop", &loop, "loop/I");
   tree->Branch("dphi", &dphi, "dphi/D");
   tree->Branch("rho", &rho, "rho/D");
   tree->Branch("xHit", &xHit, "xHit/D");
   tree->Branch("yHit", &yHit, "yHit/D");
   
   //========timer
   TBenchmark clock;
   bool shown ;   
   clock.Reset();
   clock.Start("timer");
   shown = false;
   printf("############################################## generating %d events \n", numEvent);
   
   //====================================================== calculate 
   int count = 0;
   TLorentzVector P;
   TVector3 v;
   for( int i = 0; i < numEvent; i++){
      //==== generate alpha 
      theta = TMath::ACos(2 * gRandom->Rndm() - 1) ; 
      phi = TMath::TwoPi() * gRandom->Rndm(); 
      
      energyID = gRandom->Integer(numEnergy);
      T = energy[energyID];
      
      double p = TMath::Sqrt( ( ma + T )*(ma + T) - ma* ma);
      
      v.SetMagThetaPhi(p, theta, phi);
      
      P.SetVectM(v, ma);
      
      //################################### tree branches
      
      //==== Helios
      hit = helios.CalHit(P, 2, P, 2);
      
      e = helios.GetEnergy() + gRandom->Gaus(0, eSigma);
      z = helios.GetZ() ; 
      x = helios.GetX() + gRandom->Gaus(0, zSigma);
      t = helios.GetTime();
      loop = helios.GetLoop();
      detID = helios.GetDetID();
      dphi = helios.GetdPhi();
      rho = helios.GetRho();
      xHit = helios.GetXPos(z);
      yHit = helios.GetYPos(z);
      z += gRandom->Gaus(0, zSigma);
      
      
      if( hit == 1) {
         count ++;
      }
      
      tree->Fill();
      
      //#################################################################### Timer  
      clock.Stop("timer");
      Double_t time = clock.GetRealTime("timer");
      clock.Start("timer");
      
      if ( !shown ) {
         if (fmod(time, 10) < 1 ){
            printf( "%10d[%2d%%]| %8.2f sec | expect: %5.1f min \n", i, TMath::Nint((i+1)*100./numEvent), time , numEvent*time/(i+1)/60);
            shown = 1;
         }
      }else{
         if (fmod(time, 10) > 9 ){
            shown = 0;
         }
      }
   }
   
   saveFile->Write();
   saveFile->Close();
   
   printf("=============== done. saved as %s. count(hit==1) : %d\n", saveFileName.Data(), count);
   gROOT->ProcessLine(".q");
}
modified working code for the recent changes 2024-02-13 19:25:33 -05:00			`#include "ClassHelios.h"`
add Cleopatra from digios 2023-04-03 16:03:48 -04:00			`#include "TROOT.h"`
			`#include "TBenchmark.h"`
			`#include "TLorentzVector.h"`
			`#include "TMath.h"`
			`#include "TFile.h"`
			`#include "TF1.h"`
			`#include "TTree.h"`
			`#include "TRandom.h"`
			`#include <stdlib.h>`
			`#include <vector>`
			`#include <fstream>`
			`#include <TObjArray.h>`

			`//----------- usage`
			`// $root transfer.C+ \| tee output.txt`
			`// this will same the massage to output.txt`

			`const double ma = 3727.3792; // alpha mass`

			`void alpha(){`

			`//================================================= User Setting`
			`const int numEnergy = 4;`
			`double energy [numEnergy] = {3.18, 5.16, 5.49, 5.81};`

			`int numEvent = 1000000;`

			`//---- HELIOS detector geometry`
			`//string heliosDetGeoFile = "detectorGeo.txt";`
			`string heliosDetGeoFile = "";`
			`double BField = 2.5; // T`
			`double BFieldTheta = 0.; // direction of B-field`
			`bool isCoincidentWithRecoil = false;`
			`double eSigma = 0.040 ; // detector energy sigma MeV`
			`double zSigma = 0.500 ; // detector position sigma mm`

			`//---- save root file name`
			`TString saveFileName = "alpha.root";`

			`//=============================================================`
			`//=============================================================`

			`printf("===================================================\n");`
			`printf("============= Alpha source in HELIOS ============\n");`
			`printf("===================================================\n");`

			`printf("========= Alpha Enegry : \n");`
			`for( int i = 0; i < numEnergy ; i++){`
			`printf("%2d \| %6.2f MeV\n", i, energy[i]);`
			`}`


			`//======== Set HELIOS`
			`printf("############################################## HELIOS configuration\n");`
			`HELIOS helios;`
			`helios.OverrideMagneticFieldDirection(BFieldTheta);`
			`helios.OverrideFirstPos(-700);`
			`//helios.OverrideDetectorDistance(5);`
			`bool sethelios = helios.SetDetectorGeometry(heliosDetGeoFile);`
			`if( !sethelios){`
			`helios.OverrideMagneticField(BField);`
			`printf("======== B-field : %5.2f T, Theta : %6.2f deg\n", BField, BFieldTheta);`
			`}`
			`helios.SetCoincidentWithRecoil(isCoincidentWithRecoil);`
			`printf("========== energy resol.: %f MeV\n", eSigma);`
			`printf("=========== pos-Z resol.: %f mm \n", zSigma);`

			`//====================== build tree`
			`TFile * saveFile = new TFile(saveFileName, "recreate");`
			`TTree * tree = new TTree("tree", "tree");`

			`double theta, phi, T;`

			`int hit; // the output of Helios.CalHit`
			`double e, z, x, t;`
			`int loop, detID;`
			`double dphi, rho; //rad of rotation, and radius`
			`int energyID;`
			`double xHit, yHit;`

			`tree->Branch("hit", &hit, "hit/I");`
			`tree->Branch("theta", &theta, "theta/D");`
			`tree->Branch("phi", &phi, "phi/D");`
			`tree->Branch("T", &T, "T/D");`
			`tree->Branch("energy", &energy, "energy/D");`
			`tree->Branch("energyID", &energyID, "energyID/I");`

			`tree->Branch("e", &e, "e/D");`
			`tree->Branch("x", &x, "x/D");`
			`tree->Branch("z", &z, "z/D");`
			`tree->Branch("t", &t, "t/D");`
			`tree->Branch("detID", &detID, "detID/I");`
			`tree->Branch("loop", &loop, "loop/I");`
			`tree->Branch("dphi", &dphi, "dphi/D");`
			`tree->Branch("rho", &rho, "rho/D");`
			`tree->Branch("xHit", &xHit, "xHit/D");`
			`tree->Branch("yHit", &yHit, "yHit/D");`

			`//========timer`
			`TBenchmark clock;`
			`bool shown ;`
			`clock.Reset();`
			`clock.Start("timer");`
			`shown = false;`
			`printf("############################################## generating %d events \n", numEvent);`

			`//====================================================== calculate`
			`int count = 0;`
			`TLorentzVector P;`
			`TVector3 v;`
			`for( int i = 0; i < numEvent; i++){`
			`//==== generate alpha`
			`theta = TMath::ACos(2 * gRandom->Rndm() - 1) ;`
			`phi = TMath::TwoPi() * gRandom->Rndm();`

			`energyID = gRandom->Integer(numEnergy);`
			`T = energy[energyID];`

			`double p = TMath::Sqrt( ( ma + T )(ma + T) - ma ma);`

			`v.SetMagThetaPhi(p, theta, phi);`

			`P.SetVectM(v, ma);`

			`//################################### tree branches`

			`//==== Helios`
			`hit = helios.CalHit(P, 2, P, 2);`

			`e = helios.GetEnergy() + gRandom->Gaus(0, eSigma);`
			`z = helios.GetZ() ;`
			`x = helios.GetX() + gRandom->Gaus(0, zSigma);`
			`t = helios.GetTime();`
			`loop = helios.GetLoop();`
			`detID = helios.GetDetID();`
			`dphi = helios.GetdPhi();`
			`rho = helios.GetRho();`
			`xHit = helios.GetXPos(z);`
			`yHit = helios.GetYPos(z);`
			`z += gRandom->Gaus(0, zSigma);`


			`if( hit == 1) {`
			`count ++;`
			`}`

			`tree->Fill();`

			`//#################################################################### Timer`
			`clock.Stop("timer");`
			`Double_t time = clock.GetRealTime("timer");`
			`clock.Start("timer");`

			`if ( !shown ) {`
			`if (fmod(time, 10) < 1 ){`
			`printf( "%10d[%2d%%]\| %8.2f sec \| expect: %5.1f min \n", i, TMath::Nint((i+1)100./numEvent), time , numEventtime/(i+1)/60);`
			`shown = 1;`
			`}`
			`}else{`
			`if (fmod(time, 10) > 9 ){`
			`shown = 0;`
			`}`
			`}`
			`}`

			`saveFile->Write();`
			`saveFile->Close();`

			`printf("=============== done. saved as %s. count(hit==1) : %d\n", saveFileName.Data(), count);`
			`gROOT->ProcessLine(".q");`
			`}`