SOLARIS_Analysis/Armory/ClassReactionParas_tobeKill.h

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#ifndef ReactionParameters_H
#define ReactionParameters_H
#include "ClassDetGeo.h"
class ReactionParas{
public:
ReactionParas();
double Et; // total energy in CM frame
double beta; // Lorentz beta from Lab to CM
double gamma; // Lorentz gamma from Lab to CM
double alpha; // E-Z slope / beta
double G; //The G-coefficient....
double massB; // heavy mass
double q; // charge of light particle
double mass; //light mass
bool hasReactionPara;
double detPrepDist;
void LoadReactionParas(bool verbose = false);
std::pair<double, double> CalExTheta(double e, double z)
};
ReactionParas::ReactionParas(){
}
//~========================================= reaction parameters
inline void ReactionParas::LoadReactionParas(bool verbose = false){
//check is the transfer.root is using the latest reactionConfig.txt
//sicne reaction.dat is generated as a by-product of transfer.root
//TFile * transfer = new TFile("transfer.root");
//TString aaa1 = "";
//TString aaa2 = "";
//if( transfer->IsOpen() ){
// TMacro * reactionConfig = (TMacro *) transfer->FindObjectAny("reactionConfig");
// TMacro presentReactionConfig ("reactionConfig.txt");
// aaa1 = ((TMD5*) reactionConfig->Checksum())->AsString();
// aaa2 = ((TMD5*) presentReactionConfig.Checksum())->AsString();
//}
//printf("%s\n", aaa1.Data());
//printf("%s\n", aaa2.Data());
//if( aaa1 != aaa2 ) {
// printf("########################## recalculate transfer.root \n");
// system("../Cleopatra/Transfer");
// printf("########################## transfer.root updated\n");
//}
std::string fileName;
detPrepDist = Array::detPerpDist;
printf(" loading reaction parameters");
std::ifstream file;
file.open(fileName.c_str());
hasReactionPara = false;
if( file.is_open() ){
std::string x;
int i = 0;
while( file >> x ){
if( x.substr(0,2) == "//" ) continue;
if( i == 0 ) mass = atof(x.c_str());
if( i == 1 ) q = atof(x.c_str());
if( i == 2 ) beta = atof(x.c_str());
if( i == 3 ) Et = atof(x.c_str());
if( i == 4 ) massB = atof(x.c_str());
i = i + 1;
}
printf("........ done.\n");
hasReactionPara = true;
alpha = 299.792458 * abs(detGeo.Bfield) * q / TMath::TwoPi()/1000.; //MeV/mm
gamma = 1./TMath::Sqrt(1-beta * beta);
G = alpha * gamma * beta * detPrepDist ;
if( verbose ){
printf("\tmass-b : %f MeV/c2 \n", mass);
printf("\tcharge-b : %f \n", q);
printf("\tE-total : %f MeV \n", Et);
printf("\tmass-B : %f MeV/c2 \n", massB);
printf("\tbeta : %f \n", beta);
printf("\tB-field : %f T \n", detGeo.Bfield);
printf("\tslope : %f MeV/mm \n", alpha * beta);
printf("\tdet radius: %f mm \n", detPrepDist);
printf("\tG-coeff : %f MeV \n", G);
printf("=====================================================\n");
}
}else{
printf("........ fail.\n");
}
file.close();
}
inline std::pair<double, double> ReactionParas::CalExTheta(double e, double z){
ReactionParas * reactParas = nullptr;
if( detGeo.array1.zMin <= z && z <= detGeo.array1.zMax ){
reactParas = &reactParas1;
if( !hasReactionPara) return {TMath::QuietNaN(), TMath::QuietNaN()};
}
if( detGeo.array2.zMin <= z && z <= detGeo.array2.zMax ){
reactParas = &reactParas2;
if( !hasReactionPara) return {TMath::QuietNaN(), TMath::QuietNaN()};
}
double Ex = TMath::QuietNaN();
double thetaCM = TMath::QuietNaN();
double y = e + mass; // to give the KE + mass of proton;
double Z = alpha * gamma * beta * z;
double H = TMath::Sqrt(TMath::Power(gamma * beta,2) * (y*y - mass * mass) ) ;
if( TMath::Abs(Z) < H ) {
///using Newton's method to solve 0 == H * sin(phi) - G * tan(phi) - Z = f(phi)
double tolerrence = 0.001;
double phi = 0; ///initial phi = 0 -> ensure the solution has f'(phi) > 0
double nPhi = 0; /// new phi
int iter = 0;
do{
phi = nPhi;
nPhi = phi - (H * TMath::Sin(phi) - G * TMath::Tan(phi) - Z) / (H * TMath::Cos(phi) - G /TMath::Power( TMath::Cos(phi), 2));
iter ++;
if( iter > 10 || TMath::Abs(nPhi) > TMath::PiOver2()) break;
}while( TMath::Abs(phi - nPhi ) > tolerrence);
phi = nPhi;
/// check f'(phi) > 0
double Df = H * TMath::Cos(phi) - G / TMath::Power( TMath::Cos(phi),2);
if( Df > 0 && TMath::Abs(phi) < TMath::PiOver2() ){
double K = H * TMath::Sin(phi);
double x = TMath::ACos( mass / ( y * gamma - K));
double momt = mass * TMath::Tan(x); /// momentum of particel b or B in CM frame
double EB = TMath::Sqrt(mass * mass + Et * Et - 2 * Et * TMath::Sqrt(momt*momt + mass * mass));
Ex = EB - massB;
double hahaha1 = gamma * TMath::Sqrt(mass * mass + momt * momt) - y;
double hahaha2 = gamma * beta * momt;
thetaCM = TMath::ACos(hahaha1/hahaha2) * TMath::RadToDeg();
}
}
return std::make_pair(Ex, thetaCM);
}
#endif