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catima/catima.cpp

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#include <iostream>
#include <math.h>
#include <algorithm>
#include "catima/catima.h"
#include "catima/constants.h"
#include "catima/data_ionisation_potential.h"
#include "catima/data_atima.h"
#include "catima/integrator.h"
#include "catima/storage.h"
#include "catima/nucdata.h"
#include "catima/calculations.h"
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#ifdef REACTIONS
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#include "catima/reactions.h"
#endif
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namespace catima{
Config default_config;
bool operator==(const Config &a, const Config&b){
if(std::memcmp(&a,&b,sizeof(Config)) == 0){
return true;
}
else
return false;
}
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double dedx(const Projectile &p, const Material &mat, const Config &c){
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double sum = 0;
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if(p.T<=0)return 0.0;
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sum += dedx_n(p,mat);
double se=0;
if(p.T<=10){
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se = sezi_dedx_e(p,mat,c );
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}
else if(p.T>10 && p.T<30){
double factor = 0.05 * ( p.T - 10.0 );
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se = (1-factor)*sezi_dedx_e(p,mat,c) + factor*bethek_dedx_e(p,mat,c);
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}
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else {
se = bethek_dedx_e(p,mat,c);
}
sum+=se;
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return sum;
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}
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double domega2dx(const Projectile &p, const Material &mat, const Config &c){
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double sum = 0;
for(int i=0;i<mat.ncomponents();i++){
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auto t= mat.get_element(i);
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double w = mat.weight_fraction(i);
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sum += w*dedx_variance(p,t,c);
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}
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return sum;
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}
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double da2dx(const Projectile &p, const Material &mat, const Config &c){
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const double Es2 = 198.81;
return angular_scattering_power(p,mat, Es2);
}
double da2de(const Projectile &p, const Material &mat, const Config &c){
return da2dx(p,mat,c)/dedx(p,mat,c);
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}
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double range(const Projectile &p, const Material &t, const Config &c){
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auto& data = _storage.Get(p,t,c);
//Interpolator range_spline(energy_table.values,data.range.data(),energy_table.num);
spline_type range_spline = get_range_spline(data);
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return range_spline(p.T);
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}
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double dedx_from_range(const Projectile &p, const Material &t, const Config &c){
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auto& data = _storage.Get(p,t,c);
//Interpolator range_spline(energy_table.values,data.range.data(),energy_table.num);
spline_type range_spline = get_range_spline(data);
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return p.A/range_spline.derivative(p.T);
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}
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std::vector<double> dedx_from_range(const Projectile &p, const std::vector<double> &T, const Material &t, const Config &c){
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auto& data = _storage.Get(p,t,c);
//Interpolator range_spline(energy_table.values,data.range.data(),energy_table.num);
spline_type range_spline = get_range_spline(data);
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std::vector<double> dedx;
dedx.reserve(T.size());
for(auto e:T){
if(e<catima::Ezero){
dedx.push_back(0.0);
}
else{
dedx.push_back(p.A/range_spline.derivative(e));
}
}
return dedx;
}
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double range_straggling(const Projectile &p, double T, const Material &t, const Config &c){
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auto& data = _storage.Get(p,t,c);
//Interpolator range_straggling_spline(energy_table.values,data.range_straggling.data(),energy_table.num);
spline_type range_straggling_spline = get_range_straggling_spline(data);
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return sqrt(range_straggling_spline(T));
}
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double range_variance(const Projectile &p, double T, const Material &t, const Config &c){
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auto& data = _storage.Get(p,t,c);
//Interpolator range_straggling_spline(energy_table.values,data.range_straggling.data(),energy_table.num);
spline_type range_straggling_spline = get_range_straggling_spline(data);
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return range_straggling_spline(T);
}
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double domega2de(const Projectile &p, double T, const Material &t, const Config &c){
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auto& data = _storage.Get(p,t,c);
//Interpolator range_straggling_spline(energy_table.values,data.range_straggling.data(),energy_table.num);
spline_type range_straggling_spline = get_range_straggling_spline(data);
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return range_straggling_spline.derivative(T);
}
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/*
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double da2de(const Projectile &p, double T, const Material &t, const Config &c){
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auto& data = _storage.Get(p,t,c);
//Interpolator angular_variance_spline(energy_table.values,data.angular_variance.data(),energy_table.num);
spline_type angular_variance_spline = get_angular_variance_spline(data);
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return angular_variance_spline.derivative(T);
}
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*/
double angular_variance(Projectile p, const Material &t, const Config &c){
const double T = p.T;
auto& data = _storage.Get(p,t,c);
spline_type range_spline = get_range_spline(data);
auto fx0p = [&](double x)->double{
double e =energy_out(T,x,range_spline);
//double l = x/radiation_length(t);
//double f = 0.97*(1+log(l)/20.7) + (1+log(l)/22.7);
constexpr double f = 1;
return f*da2dx(p(e), t, c);
};
double f = 1.0;
double range = range_spline(T);
double rrange = std::min(range, t.thickness());
return f*integrator.integrate(fx0p,0, rrange);
}
double angular_straggling(Projectile p, const Material &t, const Config &c){
return sqrt(angular_variance(p,t,c));
}
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double angular_straggling_from_E(const Projectile &p, double T, double Tout, Material t, const Config &c){
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auto& data = _storage.Get(p,t,c);
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spline_type range_spline = get_range_spline(data);
double th = range_spline(T)-range_spline(Tout);
t.thickness(th);
return angular_straggling(p,t,c);
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}
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double energy_straggling_from_E(const Projectile &p, double T, double Tout,const Material &t, const Config &c){
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auto& data = _storage.Get(p,t,c);
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//Interpolator range_straggling_spline(energy_table.values,data.range_straggling.data(),energy_table.num);
//Interpolator range_spline(energy_table.values,data.range.data(),energy_table.num);
spline_type range_spline = get_range_spline(data);
spline_type range_straggling_spline = get_range_straggling_spline(data);
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double dEdxo = p.A/range_spline.derivative(Tout);
return dEdxo*sqrt(range_straggling_spline(T) - range_straggling_spline(Tout))/p.A;
}
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double energy_out(double T, double thickness, const Interpolator &range_spline){
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int counter = 0;
double range;
double dedx;
double e,r;
range = range_spline(T);
dedx = 1.0/range_spline.derivative(T);
if(range<= thickness) return 0.0;
e = T - (thickness*dedx);
while(1){
r = range - range_spline(e) - thickness;
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if(fabs(r)<Eout_epsilon)return e;
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double step = -r*dedx;
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e = e-step;
if(e<Ezero)return 0.0;
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dedx = 1.0/range_spline.derivative(e);
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counter++;
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assert(counter<=100);
if(counter>100)return -1;
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}
return -1;
}
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double energy_out(const Projectile &p, const Material &t, const Config &c){
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auto& data = _storage.Get(p,t,c);
//Interpolator range_spline(energy_table.values,data.range.data(),energy_table.num);
spline_type range_spline = get_range_spline(data);
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return energy_out(p.T,t.thickness(),range_spline);
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}
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std::vector<double> energy_out(const Projectile &p, const std::vector<double> &T, const Material &t, const Config &c){
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auto& data = _storage.Get(p,t,c);
//Interpolator range_spline(energy_table.values,data.range.data(),energy_table.num);
spline_type range_spline = get_range_spline(data);
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std::vector<double> eout;
eout.reserve(T.size());
for(auto e:T){
if(e<catima::Ezero){
eout.push_back(0.0);
}
else{
eout.push_back(energy_out(e,t.thickness(),range_spline));
}
}
return eout;
}
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std::vector<double> calculate_tof(Projectile p, const Material &t, const Config &c){
double res;
std::vector<double> values;
values.reserve(max_datapoints);
auto function = [&](double x)->double{return 1.0/(dedx(p(x),t,c)*beta_from_T(x));};
res = integrator.integrate(function,Ezero,energy_table(0));
res = res*10.0*p.A/(c_light*t.density());
values.push_back(res);
for(int i=1;i<max_datapoints;i++){
res = integrator.integrate(function,energy_table(i-1),energy_table(i));
res = res*10.0*p.A/(c_light*t.density());
res += values[i-1];
values.push_back(res);
}
return values;
}
Result calculate(Projectile p, const Material &t, const Config &c){
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Result res;
double T = p.T;
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if(T<catima::Ezero && T<catima::Ezero-catima::numeric_epsilon){return res;}
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auto& data = _storage.Get(p,t,c);
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bool use_angular_spline = false;
if(c.scattering == scattering_types::atima_scattering){
use_angular_spline = true;
}
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//Interpolator range_spline(energy_table.values,data.range.data(),energy_table.num);
spline_type range_spline = get_range_spline(data);
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spline_type range_straggling_spline = get_range_straggling_spline(data);
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res.Ein = T;
res.range = range_spline(T);
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res.dEdxi = p.A/range_spline.derivative(T);
res.sigma_r = sqrt(range_straggling_spline(T));
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if(t.thickness()==0){
res.dEdxo = res.dEdxi;
return res;
}
res.Eout = energy_out(T,t.thickness(),range_spline);
res.Eloss = (res.Ein - res.Eout)*p.A;
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if(res.Eout<Ezero){
res.dEdxo = 0.0;
res.sigma_a = 0.0;
res.tof = 0.0;
res.sigma_E = 0.0;
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}
else{
spline_type angular_variance_spline = get_angular_variance_spline(data);
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res.dEdxo = p.A/range_spline.derivative(res.Eout);
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#ifdef THIN_TARGET_APPROXIMATION
if(thin_target_limit*res.Ein<res.Eout){
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double edif = (res.Ein-res.Eout);
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double s1 = range_straggling_spline.derivative(T);
double s2 = range_straggling_spline.derivative(res.Eout);
res.sigma_E = res.dEdxo*sqrt(edif*0.5*(s1+s2))/p.A;
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if(use_angular_spline){
s1 = angular_variance_spline.derivative(T);
s2 = angular_variance_spline.derivative(res.Eout);
res.sigma_a = sqrt(0.5*(s1+s2)*edif);
}
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}
else{
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res.sigma_E = res.dEdxo*sqrt(range_straggling_spline(T) - range_straggling_spline(res.Eout))/p.A;
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if(use_angular_spline){
res.sigma_a = sqrt(angular_variance_spline(T) - angular_variance_spline(res.Eout));
}
}
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#else
res.sigma_E = res.dEdxo*sqrt(range_straggling_spline(T) - range_straggling_spline(res.Eout))/p.A;
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if(use_angular_spline){
res.sigma_a = sqrt(angular_variance_spline(T) - angular_variance_spline(res.Eout));
}
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#endif
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if( (!use_angular_spline) && res.range>t.thickness()){ // do not calculate angle scattering when stopped inside material
res.sigma_a = angular_straggling(p(T),t,c);
}
//Interpolator tof_spline(energy_table.values, tofdata.data(), energy_table.num,interpolation_t::linear);
//res.tof = tof_spline(res.Ein) - tof_spline(res.Eout);
res.tof = calculate_tof_from_E(p,res.Eout,t);
} //end of else for non stopped case
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// position straggling in material
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double rrange = std::min(res.range/t.density(), t.thickness_cm());
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auto fx2p = [&](double x)->double{
double e =energy_out(T,x*t.density(),range_spline);
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return (rrange-x)*(rrange-x)*da2dx(p(e), t, c)*t.density();
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};
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res.sigma_x = integrator_adaptive.integrate(fx2p,0, rrange,1e-3,1e-6);
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res.sigma_x = sqrt(res.sigma_x);
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// position vs angle covariance, needed later for final position straggling
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auto fx1p = [&](double x)->double{
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double e =energy_out(T,x*t.density(),range_spline);
return (rrange-x)*da2dx(p(e), t, c)*t.density();
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};
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res.cov = integrator.integrate(fx1p,0, rrange);
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#ifdef REACTIONS
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res.sp = nonreaction_rate(p,t,c);
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#endif
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return res;
}
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MultiResult calculate(const Projectile &p, const Layers &layers, const Config &c){
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MultiResult res;
double e = p.T;
res.total_result.Ein = e;
res.results.reserve(layers.num());
for(auto&m:layers.get_materials()){
Result r = calculate(p,m,e,c);
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e = r.Eout;
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res.total_result.Eloss += r.Eloss;
res.total_result.sigma_E += r.sigma_E*r.sigma_E;
res.total_result.tof += r.tof;
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res.total_result.Eout = r.Eout;
double a2 = res.total_result.sigma_a;
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res.total_result.sigma_x += (2*m.thickness_cm()*res.total_result.cov)
+ (a2*m.thickness_cm()*m.thickness_cm())
+ r.sigma_x*r.sigma_x;
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//res.total_result.sigma_x += (a2*m.thickness_cm()*m.thickness_cm()) + r.sigma_x*r.sigma_x;
res.total_result.cov += a2*m.thickness_cm() + r.cov;
res.total_result.sigma_a += r.sigma_a*r.sigma_a;
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#ifdef REACTIONS
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res.total_result.sp = (r.sp>=0.0)?res.total_result.sp*r.sp:-1;
#endif
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res.results.push_back(r);
}
if(e>Ezero){
res.total_result.sigma_a = sqrt(res.total_result.sigma_a);
res.total_result.sigma_E = sqrt(res.total_result.sigma_E);
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res.total_result.sigma_x = sqrt(res.total_result.sigma_x);
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}
else{
res.total_result.sigma_a = 0.0;
res.total_result.sigma_E = 0.0;
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res.total_result.sigma_x = sqrt(res.total_result.sigma_x);
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}
return res;
}
Result calculate(double pa, int pz, double T, double ta, double tz, double thickness, double density){
Projectile p(pa,pz);
Material m(ta,tz,density,thickness);
return calculate(p(T),m);
}
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DataPoint calculate_DataPoint(Projectile p, const Material &t, const Config &c){
DataPoint dp(p,t,c);
dp.range.resize(max_datapoints);
dp.range_straggling.resize(max_datapoints);
dp.angular_variance.resize(max_datapoints);
auto fdedx = [&](double x)->double{
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return 1.0/dedx(p(x),t,c);
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};
auto fomega = [&](double x)->double{
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return domega2dx(p(x),t,c)/catima::power(dedx(p(x),t,c),3);
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};
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auto ftheta = [&](double x)->double{
return da2de(p(x),t,c);
};
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//double res=0.0;
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//calculate 1st point to have i-1 element ready for loop
//res = integrator.integrate(fdedx,Ezero,energy_table(0));
//res = p.A*res;
//dp.range[0] = res;
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dp.range[0] = 0.0;
dp.angular_variance[0] = 0.0;
//res = integrator.integrate(fomega,Ezero,energy_table(0));
//res = p.A*res;
dp.range_straggling[0]=0.0;
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//p.T = energy_table(0);
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for(int i=1;i<max_datapoints;i++){
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double res = p.A*integrator.integrate(fdedx,energy_table(i-1),energy_table(i));
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dp.range[i] = res + dp.range[i-1];
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//res = da2dx(p(energy_table(i)),t)*res;
//dp.angular_variance[i] = res + dp.angular_variance[i-1];
dp.angular_variance[i] = p.A*integrator.integrate(ftheta,energy_table(i-1),energy_table(i))
+ dp.angular_variance[i-1];
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res = integrator.integrate(fomega,energy_table(i-1),energy_table(i));
res = p.A*res;
dp.range_straggling[i] = res + dp.range_straggling[i-1];
}
return dp;
}
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double calculate_tof_from_E(Projectile p, double Eout, const Material &t, const Config &c){
double res;
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auto function = [&](double x)->double{return 1.0/(dedx(p(x),t,c)*beta_from_T(x));};
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res = integrator.integrate(function,Eout,p.T);
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res = res*10.0*p.A/(c_light*t.density());
return res;
}
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std::pair<double,double> w_magnification(const Projectile &p, double Ein, const Material &t, const Config &c){
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std::pair<double, double> res{1.0,1.0};
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if(t.density()<= 0.0 || t.thickness()<=0){
return res;
}
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std::vector<double> energies{0.99*Ein, Ein, 1.01*Ein};
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auto eres = energy_out(p,energies,t,c);
if(eres[0]>0.0 && eres[1]>0.0 && eres[2]>0.0){
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res.first = energies[1]*(eres[2]-eres[0])/(eres[1]*(energies[2]-energies[0]));
res.second = p_from_T(energies[1],p.A)*(p_from_T(eres[2],p.A)-p_from_T(eres[0],p.A))/( p_from_T(eres[1],p.A)*( p_from_T(energies[2],p.A)-p_from_T(energies[0],p.A) ) );
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}
else {
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res.first = 0.0;
res.second = 0.0;
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}
return res;
}
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} // end of atima namespace