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catima/calculations.h

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/*
* Author: Andrej Prochazka
* Copyright(C) 2017
* This program is free software: you can redistribute it and/or modify
* it under the terms of the GNU Affero General Public License as published by
* the Free Software Foundation, either version 3 of the License, or
* (at your option) any later version.
* This program is distributed in the hope that it will be useful,
* but WITHOUT ANY WARRANTY; without even the implied warranty of
* MERCHANTABILITY or FITNESS FOR A PARTICULAR PURPOSE. See the
* GNU Affero General Public License for more details.
* You should have received a copy of the GNU Affero General Public License
* along with this program. If not, see <http://www.gnu.org/licenses/>.
*/
/// \file calculations.h
#ifndef CALCULATIONS_H
#define CALCULATIONS_H
#include <complex>
#include "catima/structures.h"
#include "catima/config.h"
namespace catima{
/**
* returns nuclear stopping power for projectile-target combination
*/
double dedx_n(const Projectile &p, const Target &t);
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double dedx_n(const Projectile &p, const Material &mat);
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/**
* returns energy loss straggling
*/
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double dedx_variance(const Projectile &p, const Target &t, const Config &c=default_config);
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/**
* returns reduced energy loss unit for projectile-target combination
*/
double reduced_energy_loss_unit(const Projectile &p, const Target &t);
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/**
* @brief bethek_dedx_e - electronics stopping power
* @return stopping power
*/
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double bethek_dedx_e(const Projectile &p,const Target &t, const Config &c=default_config, double I=0.0);
double bethek_dedx_e(const Projectile &p,const Material &mat, const Config &c=default_config);
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/**
* calculates barkas effect
*/
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double bethek_barkas(double zp_eff,double eta, double zt);
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/**
* calculates density effect
*/
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double bethek_density_effect(double beta, int zt);
/**
* calculates lindhard correction for energy loss calculation
*/
double bethek_lindhard(const Projectile &p);
/**
* calculates lindhard correction for energy loss straggling calculation
*/
double bethek_lindhard_X(const Projectile &p);
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/**
* calculates pair production stopping power
*/
double pair_production(const Projectile &p, const Target &t);
/**
* calculates bremsstrahlung stopping power
*/
double bremsstrahlung(const Projectile &p, const Target &t);
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/**
* returns linhard correction (L) calulated from tabulated precalculated data
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* if energy is less than minimal calculated energy the LS coefficient of at minimal
* calculated energy is returned and similar for highest caclulated energy limit
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*/
double precalculated_lindhard(const Projectile &p);
/**
* returns linhard energy loss straggling correction (X) calulated from tabulated precalculated data
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* if energy is less than minimal calculated energy the X coefficient of at minimal
* calculated energy is returned and similar for highest caclulated energy limit
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*/
double precalculated_lindhard_X(const Projectile &p);
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/**
* this function is not used and is not tested
*/
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double energy_straggling_firsov(double z1,double energy, double z2, double m2);
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/**
* electronic energy loss for low energy, should be like SRIM
*/
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double sezi_dedx_e(const Projectile &p, const Material &mat, const Config &c=default_config);
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double angular_scattering_variance(const Projectile &p, const Target &t);
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/**
* returns radiation length of the (M,Z) material
* for certain z the radiation length is tabulated, otherwise calculated
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* @param z - proton number of target
* @param m - weight of the target
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* @return radiation length in g/cm^2
*/
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double radiation_length(int z, double m);
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/** returns effective Z of the projectile
* @param c - Configuration, the z effective will be calculated according to c.z_effective value
* @return - z effective
*/
double z_effective(const Projectile &p, const Target &t, const Config &c=default_config);
/**
* calculates effective charge
* @param z - proton number of projectile
* @param beta - velocity of projectile
* @return effective charge
*/
double z_eff_Pierce_Blann(double z, double beta);
/**
* calculates effective charge
* @param pz - proton number of projectile
* @param beta - velocity of projectile
* @param tz - proton number of target material
* @return effective charge
*/
double z_eff_Anthony_Landford(double pz, double beta, double tz);
/**
* calculates effective charge
* @param pz - proton number of projectile
* @param beta - velocity of projectile
* @param tz - proton number of target material
* @return effective charge
*/
double z_eff_Hubert(double pz, double E, double tz);
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/**
* calculates effective charge
* @param pz - proton number of projectile
* @param beta - velocity of projectile
* @param tz - proton number of target material
* @return effective charge
*/
double z_eff_Winger(double pz, double beta, double tz);
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/**
* calculates effective charge
* @param pz - proton number of projectile
* @param beta - velocity of projectile
* @param tz - proton number of target material
* @return effective charge
*/
double z_eff_global(double pz, double E, double tz);
/**
* calculates effective charge
* @param pz - proton number of projectile
* @param beta - velocity of projectile
* @param tz - proton number of target material
* @return effective charge
*/
double z_eff_Schiwietz(double pz, double beta, double tz);
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/**
* calculates effective charge
* @param pz - proton number of projectile
* @param beta - velocity of projectile
* @param tz - proton number of target material
* @return effective charge
*/
double z_eff_atima14(double pz, double beta, double tz);
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//helper
double gamma_from_T(double T);
double beta_from_T(double T);
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double p_from_T(double T, double M);
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std::complex<double> lngamma( const std::complex<double> &z );
std::complex<double> hyperg(const std::complex<double> &a,
const std::complex<double> &b,
const std::complex<double> &z);
inline double power(double x, double y){
return exp(log(x)*y);
}
}
#endif