243 lines
5.9 KiB
C++
243 lines
5.9 KiB
C++
#ifndef SPLITPOLEHit_H
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#define SPLITPOLEHit_H
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#include "Isotope.h"
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#include <cmath>
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#include <random>
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// static double randZeroToOne() {
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// return static_cast<double>(rand()) / RAND_MAX;
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// }
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// // Box-Muller transform to generate random Gaussian numbers
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// static double generateGaussian(double mean, double stddev) {
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// static bool hasSpare = false;
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// static double spare;
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// if (hasSpare) {
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// hasSpare = false;
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// return mean + stddev * spare;
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// } else {
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// double u, v, s;
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// do {
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// u = 2.0 * randZeroToOne() - 1.0;
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// v = 2.0 * randZeroToOne() - 1.0;
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// s = u * u + v * v;
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// } while (s >= 1.0 || s == 0.0);
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// s = std::sqrt(-2.0 * std::log(s) / s);
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// spare = v * s;
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// hasSpare = true;
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// return mean + stddev * u * s;
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// }
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// }
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namespace SPS{
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namespace ChMap{
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const short ScinR = 0;
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const short ScinL = 1;
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const short dFR = 9;
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const short dFL = 8;
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const short dBR = 10;
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const short dBL = 11;
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const short Cathode = 7;
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const short AnodeF = 13;
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const short AnodeB = 15;
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};
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const double c = 299.792458; // mm/ns
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const double pi = M_PI;
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const double deg2rad = pi/180.;
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const double DISPERSION = 1.96; // x-position/rho
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const double MAGNIFICATION = 0.39; // in x-position
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const double X1X2Separation = 36; // cm
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}
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class SplitPoleHit{
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public:
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SplitPoleHit(){
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ClearData();
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}
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unsigned int eSR; unsigned long long tSR;
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unsigned int eSL; unsigned long long tSL;
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unsigned int eFR; unsigned long long tFR;
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unsigned int eFL; unsigned long long tFL;
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unsigned int eBR; unsigned long long tBR;
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unsigned int eBL; unsigned long long tBL;
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unsigned int eCath; unsigned long long tCath;
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unsigned int eAF; unsigned long long tAF;
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unsigned int eAB; unsigned long long tAB;
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float eSAvg;
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float x1, x2, theta;
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float xAvg;
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double GetQ0() const {return Q0;}
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double GetRho0() const {return rho0;}
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double GetZoffset() const {return zOffset;}
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void SetMassTablePath(std::string path){
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target.SetMassTablePath(path);
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beam.SetMassTablePath(path);
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recoil.SetMassTablePath(path);
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heavyRecoil.SetMassTablePath(path);
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}
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void CalConstants(std::string targetStr, std::string beamStr, std::string recoilStr, double energyMeV, double angleDeg){
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target.SetIsoByName(targetStr);
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beam.SetIsoByName(beamStr);
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recoil.SetIsoByName(recoilStr);
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heavyRecoil.SetIso(target.A + beam.A - recoil.A, target.Z + beam.Z - recoil.Z);
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angleDegree = angleDeg; // degree
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beamKE = energyMeV; // MeV
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Ei = target.Mass + beamKE + beam.Mass;
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k1 = sqrt( 2*beam.Mass*beamKE + beamKE*beamKE);
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cs = cos(angleDegree * SPS::deg2rad);
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ma = recoil.Mass;
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mb = heavyRecoil.Mass;
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isConstantCal = true;
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printf("============================================\n");
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printf(" Beam Mass : %20.4f MeV/c2\n", beam.Mass);
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printf(" beam KE : %20.4f MeV\n", beamKE);
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printf("Target Mass : %20.4f MeV/c2\n", target.Mass);
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printf("Recoil Mass : %20.4f MeV/c2\n", recoil.Mass);
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printf("H. Rec Mass : %20.4f MeV/c2\n", heavyRecoil.Mass);
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printf(" angle : %20.4f deg\n", angleDegree);
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printf(" k1 : %20.4f MeV/c\n", k1);
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printf(" Ei : %20.4f MeV\n", Ei);
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}
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double CalRecoilMomentum(double Ex){
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if( !isConstantCal ) return 0;
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double p = Ei*Ei - k1*k1;
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double q = ma*ma - (mb + Ex)*(mb + Ex);
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double x = k1* ( p + q) * cs;
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double y = pow( p, 2) + pow(q, 2)- 2 * Ei * Ei * (ma* ma + (mb + Ex)*(mb + Ex)) + 2 * k1 * k1 * (ma*ma * cos(2* angleDegree * SPS::deg2rad) + (mb + Ex)*(mb + Ex));
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double z = 2 * ( Ei*Ei - k1*k1 * cs * cs) ;
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return (x + Ei * sqrt(y))/z;
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}
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double Momentum2Rho(double ka){
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return ka / (recoil.Z * Bfield * SPS::c);
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}
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double Momentum2Ex(double ka){
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return sqrt( Ei*Ei - k1*k1 + ma*ma + 2 * cs * k1 * ka - 2*Ei*sqrt(ma*ma + ka*ka)) - mb;
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}
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double Rho2Ex(double rhoInM){
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double ka = rhoInM * (recoil.Z * Bfield * SPS::c);
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return Momentum2Ex(ka);
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}
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void CalZoffset(double magFieldinT){
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Bfield = magFieldinT;
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if( !isConstantCal ) return;
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double recoilP = CalRecoilMomentum(0);
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Q0 = target.Mass + beam.Mass - recoil.Mass - heavyRecoil.Mass;
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double recoilKE = sqrt(ma*ma + recoilP* recoilP) - ma;
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printf("Q value : %f \n", Q0);
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printf("recoil enegry for ground state: %f MeV = %f MeV/c\n", recoilKE, recoilP);
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rho0 = recoilP/(recoil.Z * Bfield * SPS::c); // in m
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double haha = sqrt( ma * beam.Mass * beamKE / recoilKE );
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double k = haha * sin(angleDegree * SPS::deg2rad) / ( ma + mb - haha * cs);
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zOffset = -100.0 * rho0 * k * SPS::DISPERSION * SPS::MAGNIFICATION;
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printf("rho: %f m; z-offset: %f cm\n", rho0, zOffset);
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}
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void ClearData(){
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eSR = 0; tSR = 0;
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eSL = 0; tSL = 0;
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eFR = 0; tFR = 0;
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eFL = 0; tFL = 0;
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eBR = 0; tBR = 0;
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eBL = 0; tBL = 0;
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eCath = 0; tCath = 0;
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eAF = 0; tAF = 0;
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eAB = 0; tAB = 0;
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eSAvg = -1;
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x1 = NAN;
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x2 = NAN;
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theta = NAN;
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xAvg = NAN;
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isConstantCal = false;
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}
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void CalData(){
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if( eSR > 0 && eSL > 0 ) eSAvg = (eSR + eSL)/2;
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if( eSR > 0 && eSL == 0 ) eSAvg = eSR;
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if( eSR == 0 && eSL > 0 ) eSAvg = eSL;
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if( tFR > 0 && tFL > 0 ) x1 = (tFL - tFR)/2./2.1;
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if( tBR > 0 && tBL > 0 ) x2 = (tBL - tBR)/2./1.98;
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if( !std::isnan(x1) && !std::isnan(x2)) {
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if( x2 > x1 ) {
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theta = atan((x2-x1)/SPS::X1X2Separation);
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}else if(x2 < x1){
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theta = SPS::pi + atan((x2-x1)/SPS::X1X2Separation);
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}else{
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theta = SPS::pi * 0.5;
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}
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double w1 = 0.5 - zOffset/4.28625;
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xAvg = w1 * x1 + (1-w1)* x2;
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}
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}
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private:
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Isotope target;
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Isotope beam;
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Isotope recoil;
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Isotope heavyRecoil;
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double Bfield;
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double angleDegree;
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double beamKE;
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double zOffset;
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double Q0, rho0;
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bool isConstantCal;
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double Ei, k1, cs, ma, mb;
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};
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#endif |