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xsec.cc
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xsec.cc
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/*
* @file xsec.cc
* @author Luca Maccione, Daniele Gaggero
* @email [email protected]
* @email [email protected]
* @brief All the classes related to the cross sections are implemented.
*/
#include "xsec.h"
#include "grid.h"
#include "nucleilist.h"
#include "utilities.h"
#include "kamae.h"
#include "input.h"
#include <algorithm>
#include <fstream>
#include <gsl/gsl_errno.h>
#include <gsl/gsl_spline.h>
#include <gsl/gsl_vector.h>
using namespace std;
//ofstream outf("spallation_xsec.dat", ios::out);
const double TSpallationNetwork::ethr = 5.e1;
TSpallationNetwork::TSpallationNetwork(TGrid* co, Input* in, vector<TXSecBase*> xsecmodel, vector<int>& nuclei) {
/* the relevant structures of TSpallationNetwork to be filled are
1) for nucleus --> nucleus
-- given that pair<int,int> couple(1000*iz+ia,1000*jz+ja); is the parent-daugther uid pair --
map<pair<int,int>, vector<double> > spall; //the spallation cross section vector for all energies for each pair (primary, secondary)
the spall cross section is obtained, depending on the xsec model (Galprop, Webber, Fluka) via
spall[couple] = xsecmodel[?]->GetXSec(iz,ia,jz,ja) (parent Z,A, daughter Z,A)
or
spall[couple][ip] = xsecmodel[?]->GetXSec(couple, energy[ip])
GetXSec is a method of Galprop, Webber or Fluka classes -- that inherit from XSecBase class
in the xsec class the xsections are stored in the private object map<pair<int,int>, vector<double> > xsec;
2) for nucleus --> antiprotons
3) for nucleus --> leptons
-- pair<int,int> coupleel(1001, -1000); // Electrons from protons
-- pair<int,int> couplepos(1001, 1000); // Positrons from protons
spall_apel[coupleel] = vector< vector<double> >(dimEn, vector<double>(dimEn, 0.0));
spall_apel[couplepos] = vector< vector<double> >(dimEn, vector<double>(dimEn, 0.0));
-- pair<int,int> coupleelHe(2004, -1000); // Electrons from He
-- pair<int,int> coupleposHe(2004, 1000); // Positrons from He
spall_apel[coupleelHe] = vector< vector<double> >(dimEn, vector<double>(dimEn, 0.0));
spall_apel[coupleposHe] = vector< vector<double> >(dimEn, vector<double>(dimEn, 0.0));
In Galprop and Fluka modes, the vectors are filled in
TSpallationNetwork::InitXSecGalprop(factorelpos);
TSpallationNetwork::InitXSecFluka(factorelpos);
respectively
*/
energy = co->GetEk();
const int dimEn = energy.size();
const double factor = Clight*1.e-27;
// vector<int> nuclei = TNucleiList::GetInstance()->GetList();
//ofstream outf("spallation_xsec.dat", ios::in);
for (int iloop = 0; iloop < nuclei.size()-1; ++iloop) {
// If antiprotons or leptons, do not compute spallation. If protons, do not compute, because their spallation products will be computed elsewhere
if (nuclei[iloop] <= 1001) continue;
int iz = -1000; // parent nucleus charge
int ia = -1000; // parent nucleus mass
Utility::id_nuc(nuclei[iloop], ia, iz);
for (int idaught = iloop+1; idaught < nuclei.size(); ++idaught) {
int jz = -1000; // daughter nucleus charge
int ja = -1000; // daughter nucleus mass
Utility::id_nuc(nuclei[idaught], ja, jz);
// If nucleus is antiproton of leptons skip it. Skip also if mass(daughter) > mass(parent)
if (nuclei[idaught] < 1001 || ia < ja) continue;
pair<int,int> couple(1000*iz+ia,1000*jz+ja);
if (in->spallationxsec == GalpropXSec) spall[couple] = xsecmodel[0]->GetXSec(iz,ia,jz,ja);
else if (in->spallationxsec == Webber03) {
if (!xsecmodel[1]->IsPresent(couple)) spall[couple] = xsecmodel[0]->GetXSec(iz,ia,jz,ja);
vector<double> beta = co->GetBeta();
// TWebber03::GetInstance()->Print(co);
for(unsigned int ip = 0; ip < dimEn; ip++) {
spall[couple].push_back(xsecmodel[1]->GetXSec(couple, energy[ip])*factor*beta[ip]*(1.0*He_abundance*xsecmodel[1]->GetHefactor()));
}
}
else if (in->spallationxsec == Fluka) {
vector<double> beta = co->GetBeta();
if (!xsecmodel[1]->IsPresent(couple))
spall[couple] = xsecmodel[0]->GetXSec(iz,ia,jz,ja); //if the cross section is not present, use Galprop database
else { //do nothing at the moment --> only gaprop files are actually read...
//if the cross section is present, then use Fluka model
/*
for(unsigned int ip = 0; ip < dimEn; ip++) {
spall[couple].push_back(xsecmodel[1]->GetXSec(couple, energy[ip])*factor*beta[ip]*(1.0*He_abundance*xsecmodel[1]->GetHefactor()));
//fills spall[couple] with Fluka cross section.
//Fluka->GetXSec(couple,energy) gives xsec in mbarn/GeV --> conversion to cm^3/s via "factor"
}*/
}
}
else {
cerr << "Wrong SpallationXSec option" << endl;
}
if(!in->SPALL) for(int i=0;i<spall[couple].size();i++) spall[couple][i]=0.; //fk130701 sets Xsecs to Zero i.e. no Spallation // for(unsigned int ip = 0; ip < dimEn; ip++) cout << couple.first << " " << couple.second << " " << spall[couple].back() << endl;
}
}
// outf.close();
//exit(-1);
const double factorprot = factor*co->GetDeltaE();
const double factorelpos = 1.e3*factorprot; // barn/GeV --- *10^3 ---> mbarn/GeV --- *factorprot ---> cm^3/s
double PP_inel = 0.0;
double PA_inel = 0.0;
double aPP_non = 0.0;
double aPA_non = 0.0;
double aPP_ann = 0.0;
double aPA_ann = 0.0;
if (in->spallationxsec != Fluka) {
pair<int,int> coupleprpr(1001,1001); // Secondary protons
spall[coupleprpr] = vector<double>(dimEn, 0);
for(unsigned int ip = 0; ip < dimEn; ++ip) {
xsecmodel[0]->nucleon_cs(2, energy[ip], 1, 2, 4, &PP_inel, &PA_inel, &aPP_non, &aPA_non, &aPP_ann, &aPA_ann); // Galprop CS
spall[coupleprpr][ip] = in->SPALL*factorprot*(PP_inel + He_abundance*PA_inel);
}
}
else { //fluka
pair<int,int> coupleppr(1001, 1001); // Secondary protons, from protons
pair<int,int> couplepHe(2004, 1001); // Secondary protons, from Helium
spall_apel[coupleppr] = vector< vector<double> >(dimEn, vector<double>(dimEn, 0.0));
spall_apel[couplepHe] = vector< vector<double> >(dimEn, vector<double>(dimEn, 0.0));
TSpallationNetwork::InitXSecFluka(factorelpos,2); //2-->p
//cout << "Secondary protons ok" << endl;
/*vector<double> beta = co->GetBeta();
for(unsigned int ip2 = 0; ip2 < dimEn; ip2++) {
spall[coupleprpr].push_back(xsecmodel[1]->GetXSec(coupleprpr, energy[ip2])*factor*beta[ip2]*(1.0*He_abundance*xsecmodel[1]->GetHefactor()));
}*/
}
// If antiprotons and/or leptons are wanted in output, add them, and add also secondary protons
if (in->prop_ap || in->prop_lep || in->prop_deuteron) {
if (in->prop_ap) {
if (in->spallationxsec != Fluka) {
pair<int,int> coupletert(-999,-999); // Tertiary antiprotons
spall[coupletert] = vector<double>(dimEn, 0.0);
for(unsigned int ip = 0; ip < dimEn; ++ip) {
xsecmodel[0]->nucleon_cs(2, energy[ip], -1, 2, 4, &PP_inel, &PA_inel, &aPP_non, &aPA_non, &aPP_ann, &aPA_ann);
spall[coupletert][ip] = factorprot*( aPP_non + He_abundance*aPA_non );
// Exploits approximation d\sigma/dEkin \propto 1/Ekin' [Tan & Ng '83]
}
}
else { //fluka
pair<int,int> coupleapap(-999, -999); // Tertiary antiprotons, from sec. antiprotons
spall_apel[coupleapap] = vector< vector<double> >(dimEn, vector<double>(dimEn, 0.0));
TSpallationNetwork::InitXSecFluka(factorelpos,3); //3-->tertiary ap
//cout << "Tertiary antiprotons ok" << endl;
}
spall_apel[pair<int,int>(2003,-999)] = vector< vector<double> >(dimEn, vector<double>(dimEn, 0.0));
pair<int,int> coupleappr(1001,-999); // Secondary antiprotons, from protons
pair<int,int> coupleapHe(2004,-999); // Secondary antiprotons, from Helium
vector<double> pp = co->GetMomentum();
spall_apel[coupleappr] = vector< vector<double> >(dimEn, vector<double>(dimEn, 0.0));
spall_apel[coupleapHe] = vector< vector<double> >(dimEn, vector<double>(dimEn, 0.0));
size_t limit = 100000;
gsl_integration_workspace* w = gsl_integration_workspace_alloc(limit);
if(in->SPALL) //fk 130701
{
if ( in->apy == FlukaAp)
TSpallationNetwork::InitXSecFluka(factorelpos,1); //1-->ap
//cout << "Secondary antiprotons ok" << endl;
for (unsigned int i = 0; i < dimEn; i++) {
if ( in->apy == GalpropFunction ){
for (unsigned int ii=i+1; ii < dimEn; ii++) {
spall_apel[coupleappr][i][ii] = factorelpos*energy[ii]*(xsecmodel[0]->antiproton_cc1(w,limit,in->antiproton_cs, pp[i], pp[ii], 1, 1, 1, 1) * ( (!in->scaling) + (in->scaling)*(0.12 * pow(energy[i], -1.67) + 1.78)) + (!in->scaling)*He_abundance*xsecmodel[0]->antiproton_cc1(w,limit,in->antiproton_cs, pp[i], pp[ii], 1, 1, 2, 4));
spall_apel[coupleapHe][i][ii] = factorelpos*energy[ii]*4.0*(xsecmodel[0]->antiproton_cc1(w,limit,in->antiproton_cs, pp[i], 4.0*pp[ii], 2, 4, 1, 1) * ( (!in->scaling) + (in->scaling)*(0.12 * pow(energy[i], -1.67) + 1.78)) + (!in->scaling)*He_abundance*xsecmodel[0]->antiproton_cc1(w,limit,in->antiproton_cs, pp[i], 4.0*pp[ii], 2, 4, 2, 4));
}
}
else if ( in->apy == QGSJET ){
// === TEST ===
spec_ini();
double x,es,fff;
for ( int i=1;i<=100;i++ ){
x = (double)i/100.-.005;
es = x*100.;
fff=spec_int(100.,es,1,1);
cout<<x<<"\t"<<fff<<endl;
}
exit(3);
// === END TEST ===
}
}
}
gsl_integration_workspace_free(w);
} // ap
if (in->prop_lep) {
pair<int,int> coupleel(1001, -1000); // Electrons from protons
pair<int,int> couplepos(1001, 1000); // Positrons from protons
spall_apel[coupleel] = vector< vector<double> >(dimEn, vector<double>(dimEn, 0.0));
spall_apel[couplepos] = vector< vector<double> >(dimEn, vector<double>(dimEn, 0.0));
pair<int,int> coupleelHe(2004, -1000); // Electrons from He
pair<int,int> coupleposHe(2004, 1000); // Positrons from He
spall_apel[coupleelHe] = vector< vector<double> >(dimEn, vector<double>(dimEn, 0.0));
spall_apel[coupleposHe] = vector< vector<double> >(dimEn, vector<double>(dimEn, 0.0));
spall_apel[pair<int,int>(2003,-1000)] = vector< vector<double> >(dimEn, vector<double>(dimEn, 0.0));
spall_apel[pair<int,int>(2003,1000)] = vector< vector<double> >(dimEn, vector<double>(dimEn, 0.0));
// Read in the tabulated database
if(in->SPALL){ //fk 130628
if (in->ly == GalpropTable) TSpallationNetwork::InitXSecGalprop(factorelpos);
else if (in->ly == Pohl) TSpallationNetwork::InitXSecPohl(factorelpos);
else if (in->ly == Kamae) TSpallationNetwork::InitXSecKamae(factorelpos);
else if (in->ly == FlukaLep) {TSpallationNetwork::InitXSecFluka(factorelpos,0); cout << "Sec. leptons ok " << endl; } //0-->lep
}
} // el
if (in->prop_deuteron) {
pair<int,int> coupledeutdeut(-998,-998); // Tertiary antideuterons
pair<int,int> coupledeutapr(-999,-998); // Secondary antideuterons, from antiprotons
pair<int,int> coupledeutpr(1001,-998); // Secondary antideuterons, from protons
pair<int,int> coupledeutHe(2004,-998); // Secondary antideuterons, from Helium
}
} // either
return ;
}
vector<double> TSpallationNetwork::GetXSec(int i,int j) {
pair<int,int> input(i,j);
// return spall[pair<int,int>(i,j)];
map< pair<int,int>, vector<double> >::iterator it = spall.find(input);
if (it != spall.end()) return (*it).second;
else {
//cerr << "No channel in TSpallationNetwork. Parent = " << i << " daughter = " << j << endl;
return vector<double>();
}
}
double TSpallationNetwork::GetXSec(int i, int j, double en) {
if (en > energy.back()) {
//cerr << "Out of range!" << endl;
return 0;
}
int l = 0;
for (l = 0; l < energy.size(); ++l) {
if (en >= energy[l]) break;
}
//return spall[pair<int,int>(i,j)][l];
pair<int,int> input(i,j);
map< pair<int,int>, vector<double> >::iterator it = spall.find(input);
if (it != spall.end()) {
return (*it).second[l];
}
else {
// cerr << "Out of range in TSpallationNetwork" << endl;
return 0;
}
}
double TSpallationNetwork::GetXSec(int i, int j, int k) {
if (k >= energy.size()) {
//cerr << "Out of range!" << endl;
return 0;
}
// return spall[pair<int,int>(i,j)][k];
pair<int,int> input(i,j);
map< pair<int,int>, vector<double> >::iterator it = spall.find(input);
if (it != spall.end()) return (*it).second[k];
else {
//cerr << "Out of range in TSpallationNetwork" << endl;
return 0;
}
}
vector<double> TSpallationNetwork::GetXSecApEl(int i, int j, int k) {
if (k >= energy.size()) {
//cerr << "Out of range!" << endl;
return vector<double>();
}
//return spall_apel[pair<int,int>(i,j)][k];
pair<int,int> input(i,j);
map< pair<int,int>, vector< vector<double> > >::iterator it = spall_apel.find(input);
if (it != spall_apel.end()) return (*it).second[k];
else {
//cerr << "No channel in TSpallationNetwork. Parent = " << i << " daughter = " << j << endl;
return vector<double>();
}
}
//TPP
vector<double> TSpallationNetwork::GetXSecTPP(vector<double> nu_vector) { // nu_vector -> vector of frequencies of ISRF
//double photon_energy = 10.*1.e-9; //GeV
double m_e = 0.511e-3 ; //GeV
double hPlanck = 4.135667e-15;
vector<double> result(energy.size()*energy.size()*nu_vector.size());
for (int k =0; k<energy.size(); ++k) {
for (int inu=0; inu < nu_vector.size(); ++inu) {
for (int l = 0; l < energy.size(); ++l) { // l -> energy index of parent electron
result[(k*nu_vector.size() + inu)*energy.size() + l] = 0.;
}
}
}
for (int k =0; k<energy.size(); ++k) { // k -> energy index of secondary particle
for (int inu=0; inu < nu_vector.size(); ++inu) {
double photon_energy = hPlanck*nu_vector[inu]*1.e-9; //GeV
if (k == 0)
//cout << "***" << endl;
for (int l = 0; l < energy.size(); ++l) { // l -> energy index of parent electron
int index = (k*nu_vector.size() + inu)*energy.size() + l;
double Average_TPP_positron_energy = 0.5 * sqrt(energy[l] / photon_energy ) * m_e;
double s = energy[l] * hPlanck*nu_vector[inu]*1.e-9 / pow(m_e, 2.); //tutto in GeV; s: numero puro
double correction = 0.;
if (s>4.) {
correction = 0.1193662073189215 * exp(-3.839009766244388 - 0.1223186374016053*pow(log(-4. + s), 2) ) * pow((-4. + s),1.8194204144025334);
if (s>79.)
correction = 0.13 * (-8.07407 + 3.11111 * log(0.0153186 * energy[l] * 3.));
}
if (k == 0)
cout << " photon energy [eV] " << photon_energy*1.e9 << " energy of electron [GeV] -> " << energy[l] << " s-> " << s << " correction-> " << correction << endl;
double sigma_tot = 9.46 * 6.65 * 1.e-2 * (1/137.) * correction;// * temp; // c sigma_Thompson alpha_F; units: cm/Myr * cm^2
//double std_dev = 30;//Average_TPP_positron_energy;
double std_dev = sqrt(Average_TPP_positron_energy); // GeV
//double x = energy[l]*photon_energy/(m_e*m_e);
//if (x>4)
result[index] = sigma_tot * energy[l] * exp( - pow(energy[k] - Average_TPP_positron_energy,2.0) / (2.*(pow(std_dev,2.0))) ) / (sqrt(2*3.14) * std_dev);
// cm^3/Myr GeV 1/GeV
}
}
}
return result;
}
//*********************************************************************************************************************************************
void TSpallationNetwork::InitDataTablesGalprop() {
cout << "Please provide Galprop leptonic cross sections: data/Electron_production.dat and data/Positron_production.dat" << endl;
Matrix_El_pp = vector<double>(401*801, 0.0);
Matrix_El_pHe = vector<double>(401*801, 0.0);
Matrix_El_Hep = vector<double>(401*801, 0.0);
Matrix_El_HeHe = vector<double>(401*801, 0.0);
Matrix_Pos_pp = vector<double>(401*801, 0.0);
Matrix_Pos_pHe = vector<double>(401*801, 0.0);
Matrix_Pos_Hep = vector<double>(401*801, 0.0);
Matrix_Pos_HeHe = vector<double>(401*801, 0.0);
ifstream infile(ElTablefile.c_str(), ios::in);
double a,b,c,d;
Nelectrons = 401;
Nprotons = 801;
for (int i = 0; i < 401; i++) {
for (int j = 0; j < 801; j++) {
infile >> a >> b >> c >> d;
int ind = index_matrix(i,j);
Matrix_El_pp[ind] = a;
Matrix_El_pHe[ind] = b;
Matrix_El_Hep[ind] = c;
Matrix_El_HeHe[ind] = d;
}
}
infile.close();
infile.open(PosTablefile.c_str(), ios::in);
for (int i = 0; i < 401; i++) {
for (int j = 0; j < 801; j++) {
infile >> a >> b >> c >> d;
int ind = index_matrix(i,j);
Matrix_Pos_pp[ind] = a;
Matrix_Pos_pHe[ind] = b;
Matrix_Pos_Hep[ind] = c;
Matrix_Pos_HeHe[ind] = d;
}
}
infile.close();
return;
}
//ofstream outf("total_xsec.dat", ios::out);
void TSpallationNetwork::InitXSecKamae(double factorelpos) {
pair<int,int> coupleel(1001, -1000); // Electrons from protons
pair<int,int> couplepos(1001, 1000); // Positrons from protons
pair<int,int> coupleelHe(2004, -1000); // Electrons from He
pair<int,int> coupleposHe(2004, 1000); // Positrons from He
const int dimEn = energy.size();
for (unsigned int j=0; j<dimEn; j++){
double Epr = energy[j];
for (unsigned int i = 0; i < dimEn; i++) {
double Eel = min(1e5,energy[i]);
double cs_pp = KamaeYields::GetSigma(Eel, Epr, ID_ELECTRON);
double cs_pHe = pow(4.0,2.0/3.0)*KamaeYields::GetSigma(Eel, Epr, ID_ELECTRON);
double cs_Hep = pow(4.0,2.0/3.0)*KamaeYields::GetSigma(Eel, Epr, ID_ELECTRON);
double cs_HeHe = pow(4.0*4.0,2.0/3.0)*KamaeYields::GetSigma(Eel, Epr, ID_ELECTRON);
spall_apel[coupleel][i][j] = Epr*(cs_pp + He_abundance*cs_pHe)*factorelpos;
spall_apel[coupleelHe][i][j] = 4.0*Epr*(cs_Hep + He_abundance*cs_HeHe)*factorelpos;
cs_pp = KamaeYields::GetSigma(Eel, Epr, ID_POSITRON);
cs_pHe = pow(4.0,2.0/3.0)*KamaeYields::GetSigma(Eel, Epr, ID_POSITRON);
cs_Hep = pow(4.0,2.0/3.0)*KamaeYields::GetSigma(Eel, Epr, ID_POSITRON);
cs_HeHe = pow(4.0*4.0,2.0/3.0)*KamaeYields::GetSigma(Eel, Epr, ID_POSITRON);
spall_apel[couplepos][i][j] = Epr*(cs_pp + He_abundance*cs_pHe)*factorelpos; // H
spall_apel[coupleposHe][i][j] = 4.0*Epr*(cs_Hep + He_abundance*cs_HeHe)*factorelpos; // He
}
}
return ;
}
void TSpallationNetwork::InitXSecGalprop(double factorelpos) {
pair<int,int> coupleel(1001, -1000); // Electrons from protons
pair<int,int> couplepos(1001, 1000); // Positrons from protons
pair<int,int> coupleelHe(2004, -1000); // Electrons from He
pair<int,int> coupleposHe(2004, 1000); // Positrons from He
const int dimEn = energy.size();
const int dimlept = 400;
const double DBlog = (log10(1e5)-log10(1e-3))/(double)dimlept;
double Elept[dimlept+1];
for (int i = 0; i <= dimlept; i++) Elept[i] = pow(10, log10(1e-3)+double(i)*DBlog);
const int dimpr = 800;
const double DBprlog = (log10(1e5)-log10(1e-3))/double(dimpr);
double ET[dimpr+1];
for (int j = 0; j <= dimpr; j++) ET[j] = pow(10, log10(1e-3) + double(j)*DBprlog);
TSpallationNetwork::InitDataTablesGalprop();
gsl_interp_accel *acc = gsl_interp_accel_alloc ();
gsl_spline *spline_El_pp = gsl_spline_alloc(gsl_interp_cspline, dimlept+1);
gsl_spline *spline_El_pHe = gsl_spline_alloc(gsl_interp_cspline, dimlept+1);
gsl_spline *spline_El_Hep = gsl_spline_alloc(gsl_interp_cspline, dimlept+1);
gsl_spline *spline_El_HeHe = gsl_spline_alloc(gsl_interp_cspline, dimlept+1);
gsl_spline *spline_Pos_pp = gsl_spline_alloc(gsl_interp_cspline, dimlept+1);
gsl_spline *spline_Pos_pHe = gsl_spline_alloc(gsl_interp_cspline, dimlept+1);
gsl_spline *spline_Pos_Hep = gsl_spline_alloc(gsl_interp_cspline, dimlept+1);
gsl_spline *spline_Pos_HeHe = gsl_spline_alloc(gsl_interp_cspline, dimlept+1);
//gsl_interp_accel *acc = gsl_interp_accel_alloc ();
gsl_spline *spline_El_pp_up = gsl_spline_alloc(gsl_interp_cspline, dimlept+1);
gsl_spline *spline_El_pHe_up = gsl_spline_alloc(gsl_interp_cspline, dimlept+1);
gsl_spline *spline_El_Hep_up = gsl_spline_alloc(gsl_interp_cspline, dimlept+1);
gsl_spline *spline_El_HeHe_up = gsl_spline_alloc(gsl_interp_cspline, dimlept+1);
gsl_spline *spline_Pos_pp_up = gsl_spline_alloc(gsl_interp_cspline, dimlept+1);
gsl_spline *spline_Pos_pHe_up = gsl_spline_alloc(gsl_interp_cspline, dimlept+1);
gsl_spline *spline_Pos_Hep_up = gsl_spline_alloc(gsl_interp_cspline, dimlept+1);
gsl_spline *spline_Pos_HeHe_up = gsl_spline_alloc(gsl_interp_cspline, dimlept+1);
double Vectorlept_El_pp[dimlept+1];
double Vectorlept_El_pHe[dimlept+1];
double Vectorlept_El_Hep[dimlept+1];
double Vectorlept_El_HeHe[dimlept+1];
double Vectorlept_Pos_pp[dimlept+1];
double Vectorlept_Pos_pHe[dimlept+1];
double Vectorlept_Pos_Hep[dimlept+1];
double Vectorlept_Pos_HeHe[dimlept+1];
double Vectorlept_El_pp_up[dimlept+1];
double Vectorlept_El_pHe_up[dimlept+1];
double Vectorlept_El_Hep_up[dimlept+1];
double Vectorlept_El_HeHe_up[dimlept+1];
double Vectorlept_Pos_pp_up[dimlept+1];
double Vectorlept_Pos_pHe_up[dimlept+1];
double Vectorlept_Pos_Hep_up[dimlept+1];
double Vectorlept_Pos_HeHe_up[dimlept+1];
for (unsigned int j=0; j<dimEn; j++){
double Epr = energy[j];
double momentum = sqrt(Epr*Epr + 2.0*mp*Epr);
int j_pr = int(floor(log10(Epr/ET[0])/DBprlog));
if (j_pr > dimpr-1) j_pr = dimpr-1;
double u = (Epr-ET[j_pr])/(ET[j_pr+1]-ET[j_pr]);
for (int i = 0; i <= dimlept; i++) {
int index = index_matrix(i,j_pr);
Vectorlept_El_pp[i] = Matrix_El_pp[index];
Vectorlept_El_pHe[i] = Matrix_El_pHe[index];
Vectorlept_El_Hep[i] = Matrix_El_Hep[index];
Vectorlept_El_HeHe[i] = Matrix_El_HeHe[index];
Vectorlept_Pos_pp[i] = Matrix_Pos_pp[index];
Vectorlept_Pos_pHe[i] = Matrix_Pos_pHe[index];
Vectorlept_Pos_Hep[i] = Matrix_Pos_Hep[index];
Vectorlept_Pos_HeHe[i] = Matrix_Pos_HeHe[index];
//
if (j_pr <= dimpr)
index = index_matrix(i,j_pr+1);
else
index = dimpr;
Vectorlept_El_pp_up[i] = Matrix_El_pp[index];
Vectorlept_El_pHe_up[i] = Matrix_El_pHe[index];
Vectorlept_El_Hep_up[i] = Matrix_El_Hep[index];
Vectorlept_El_HeHe_up[i] = Matrix_El_HeHe[index];
Vectorlept_Pos_pp_up[i] = Matrix_Pos_pp[index];
Vectorlept_Pos_pHe_up[i] = Matrix_Pos_pHe[index];
Vectorlept_Pos_Hep_up[i] = Matrix_Pos_Hep[index];
Vectorlept_Pos_HeHe_up[i] = Matrix_Pos_HeHe[index];
}
gsl_spline_init(spline_El_pp, Elept, Vectorlept_El_pp, dimlept+1);
gsl_spline_init(spline_El_pHe, Elept, Vectorlept_El_pHe, dimlept+1);
gsl_spline_init(spline_El_Hep, Elept, Vectorlept_El_Hep, dimlept+1);
gsl_spline_init(spline_El_HeHe, Elept, Vectorlept_El_HeHe, dimlept+1);
gsl_spline_init(spline_Pos_pp, Elept, Vectorlept_Pos_pp, dimlept+1);
gsl_spline_init(spline_Pos_pHe, Elept, Vectorlept_Pos_pHe, dimlept+1);
gsl_spline_init(spline_Pos_Hep, Elept, Vectorlept_Pos_Hep, dimlept+1);
gsl_spline_init(spline_Pos_HeHe, Elept, Vectorlept_Pos_HeHe, dimlept+1);
//
gsl_spline_init(spline_El_pp_up, Elept, Vectorlept_El_pp_up, dimlept+1);
gsl_spline_init(spline_El_pHe_up, Elept, Vectorlept_El_pHe_up, dimlept+1);
gsl_spline_init(spline_El_Hep_up, Elept, Vectorlept_El_Hep_up, dimlept+1);
gsl_spline_init(spline_El_HeHe_up, Elept, Vectorlept_El_HeHe_up, dimlept+1);
gsl_spline_init(spline_Pos_pp_up, Elept, Vectorlept_Pos_pp_up, dimlept+1);
gsl_spline_init(spline_Pos_pHe_up, Elept, Vectorlept_Pos_pHe_up, dimlept+1);
gsl_spline_init(spline_Pos_Hep_up, Elept, Vectorlept_Pos_Hep_up, dimlept+1);
gsl_spline_init(spline_Pos_HeHe_up, Elept, Vectorlept_Pos_HeHe_up, dimlept+1);
for (unsigned int i = 0; i < dimEn; i++) {
double Eel = min(1e5,energy[i]);
double Eel_tot = energy[i] + MeleGeV;
int i_lept = int(floor(log10(Eel/Elept[0])/DBlog));
if (i_lept > dimlept-1) i_lept = dimlept-1;
//double t = (Eel-Elept[i_lept])/(Elept[i_lept+1]-Elept[i_lept]);
double valuefix = gsl_spline_eval(spline_El_pp, Eel, acc);
double valueup = gsl_spline_eval(spline_El_pp_up, Eel, acc);
double cs_pp = valuefix*(1-u) + valueup*u;
valuefix = gsl_spline_eval(spline_El_pHe, Eel, acc);
valueup = gsl_spline_eval(spline_El_pHe_up, Eel, acc);
double cs_pHe = valuefix*(1-u) + valueup*u;
valuefix = gsl_spline_eval(spline_El_Hep, Eel, acc);
valueup = gsl_spline_eval(spline_El_Hep_up, Eel, acc);
double cs_Hep = valuefix*(1-u) + valueup*u;
valuefix = gsl_spline_eval(spline_El_HeHe, Eel, acc);
valueup = gsl_spline_eval(spline_El_HeHe_up, Eel, acc);
double cs_HeHe = valuefix*(1-u) + valueup*u;
spall_apel[coupleel][i][j] = Epr*(cs_pp + He_abundance*cs_pHe)*factorelpos;
spall_apel[coupleelHe][i][j] = 4.0*Epr*(cs_Hep + He_abundance*cs_HeHe)*factorelpos;
//
valuefix = gsl_spline_eval(spline_Pos_pp, Eel, acc);
valueup = gsl_spline_eval(spline_Pos_pp_up, Eel, acc);
cs_pp = valuefix*(1-u) + valueup*u;
valuefix = gsl_spline_eval(spline_Pos_pHe, Eel, acc);
valueup = gsl_spline_eval(spline_Pos_pHe_up, Eel, acc);
cs_pHe = valuefix*(1-u) + valueup*u;
valuefix = gsl_spline_eval(spline_Pos_Hep, Eel, acc);
valueup = gsl_spline_eval(spline_Pos_Hep_up, Eel, acc);
cs_Hep = valuefix*(1-u) + valueup*u;
valuefix = gsl_spline_eval(spline_Pos_HeHe, Eel, acc);
valueup = gsl_spline_eval(spline_Pos_HeHe_up, Eel, acc);
cs_HeHe = valuefix*(1-u) + valueup*u;
spall_apel[couplepos][i][j] = Epr*(cs_pp + He_abundance*cs_pHe)*factorelpos; // H
spall_apel[coupleposHe][i][j] = 4.0*Epr*(cs_Hep + He_abundance*cs_HeHe)*factorelpos; // He
}
}
return ;
}
//*********************************************************************************************************************************************
// Fluka model
//*********************************************************************************************************************************************
void TSpallationNetwork::InitDataTablesFluka(int which_particle) {
cout << "Entering in TSpallationNetwork InitDataTablesFluka routine ..." << endl;
cout << "which particle? "<< which_particle << endl;
//reads from the tables
if (which_particle == 0) { //Leptonic tables
cout << "leptonic tables" << endl;
Matrix_El_pp = vector<double>(408*380, 0.0);
Matrix_El_pHe = vector<double>(408*380, 0.0);
Matrix_El_Hep = vector<double>(408*380, 0.0);
Matrix_El_HeHe = vector<double>(408*380, 0.0);
Matrix_Pos_pp = vector<double>(408*380, 0.0);
Matrix_Pos_pHe = vector<double>(408*380, 0.0);
Matrix_Pos_Hep = vector<double>(408*380, 0.0);
Matrix_Pos_HeHe = vector<double>(408*380, 0.0);
ifstream infile(FlukaElTablefile.c_str(), ios::in);
double a,b,c,d;
Nelectrons = 408;
Nprotons = 380;
for (int i = 0; i < Nelectrons; i++) {
for (int j = 0; j < Nprotons; j++) {
infile >> a >> b >> c >> d;
int ind = index_matrix(i,j);
Matrix_El_pp[ind] = a;
Matrix_El_pHe[ind] = b;
Matrix_El_Hep[ind] = c;
Matrix_El_HeHe[ind] = d;
}
}
infile.close();
infile.open(FlukaPosTablefile.c_str(), ios::in);
for (int i = 0; i < Nelectrons; i++) {
for (int j = 0; j < Nprotons; j++) {
infile >> a >> b >> c >> d;
int ind = index_matrix(i,j);
Matrix_Pos_pp[ind] = a;
Matrix_Pos_pHe[ind] = b;
Matrix_Pos_Hep[ind] = c;
Matrix_Pos_HeHe[ind] = d;
}
}
infile.close();
}
if (which_particle == 1) { //sec Antiproton tables
cout << "ap tables " << endl;
Matrix_Ap_pp = vector<double>(408*380, 0.0);
Matrix_Ap_pHe = vector<double>(408*380, 0.0);
Matrix_Ap_Hep = vector<double>(408*380, 0.0);
Matrix_Ap_HeHe = vector<double>(408*380, 0.0);
ifstream infile(FlukaApTablefile.c_str(), ios::in);
double a,b,c,d;
Nap = 408;
Nprotons = 380;
for (int i = 0; i < Nap; i++) {
for (int j = 0; j < Nprotons; j++) {
infile >> a >> b >> c >> d;
int ind = index_matrix(i,j);
Matrix_Ap_pp[ind] = a;
Matrix_Ap_pHe[ind] = b;
Matrix_Ap_Hep[ind] = c;
Matrix_Ap_HeHe[ind] = d;
}
}
infile.close();
}
if (which_particle == 2) { //sec Proton tables
cout << "proton tables " << endl;
Matrix_p_pp = vector<double>(408*380, 0.0);
Matrix_p_pHe = vector<double>(408*380, 0.0);
Matrix_p_Hep = vector<double>(408*380, 0.0);
Matrix_p_HeHe = vector<double>(408*380, 0.0);
ifstream infile(FlukaProtTablefile.c_str(), ios::in);
double a,b,c,d;
Nap = 408;
Nprotons = 380;
for (int i = 0; i < Nap; i++) {
for (int j = 0; j < Nprotons; j++) {
infile >> a >> b >> c >> d;
int ind = index_matrix(i,j);
Matrix_p_pp[ind] = a;
Matrix_p_pHe[ind] = b;
Matrix_p_Hep[ind] = c;
Matrix_p_HeHe[ind] = d;
if (i%100==0 && j%100==0)
cout << i << " <-i,j-> " << j << "; abcd= " << a << " " << b << " " << c << " " << d << endl;
}
}
infile.close();
}
if (which_particle == 2) { //tertiary antiProton tables
cout << "tertiary antiproton tables " << endl;
Matrix_3Ap_app = vector<double>(408*380, 0.0);
Matrix_3Ap_apHe = vector<double>(408*380, 0.0);
ifstream infile(FlukaTertiaryApTablefile.c_str(), ios::in);
double a,b,c,d;
Nap = 408;
Nprotons = 380;
for (int i = 0; i < Nap; i++) {
for (int j = 0; j < Nprotons; j++) {
infile >> a >> b;
int ind = index_matrix(i,j);
Matrix_3Ap_app[ind] = a;
Matrix_3Ap_apHe[ind] = b;
if (i%100==0 && j%100==0)
cout << i << " <-i,j-> " << j << "; abcd= " << a << " " << b << endl;
}
}
infile.close();
}
return;
}
void TSpallationNetwork::InitXSecFluka(double factorelpos, int which_particle) {
//which_particle: 0-->leptons
//1-->sec antiprotons
//2-->sec protons
//3-->tertiary antiprotons
cout << "Entering in TSpallationNetwork InitXSecFluka routine ..." << endl;
pair<int,int> coupleel(1001, -1000); // Electrons from protons
pair<int,int> couplepos(1001, 1000); // Positrons from protons
pair<int,int> coupleelHe(2004, -1000); // Electrons from He
pair<int,int> coupleposHe(2004, 1000); // Positrons from He
pair<int,int> coupleappr(1001,-999); // Secondary antiprotons, from CR protons
pair<int,int> coupleapHe(2004,-999); // Secondary antiprotons, from CR Helium
pair<int,int> coupleppr(1001,1001); // Secondary antiprotons, from CR protons
pair<int,int> couplepHe(2004,1001); // Secondary antiprotons, from CR Helium
pair<int,int> coupleapap(-999,-999); // Tertiary antiprotons
const int dimEn = energy.size();
const int dimlept = 407;
const int dimap = 407;
const int dimp = 407;
const double DBlog = log10(1.05);
double Elept[dimlept+1];
double Eap[dimap+1];
for (int i = 0; i <= dimlept; i++) {
Elept[i] = 0.001*pow(1.05, double(i)+0.5);
Elept[i] = pow(10., log10(1e-3)+double(i)*DBlog+0.5*DBlog);
Eap[i] = Elept[i];
//cout << i << " " << Elept[i] << endl;
}
const int dimpr = 379;
const double DBprlog = log10(1.05);
double ET[dimpr+1];
for (int j = 0; j <= 94; j++) ET[j] = pow(10, log10(1e-3) + double(j)*DBprlog);
for (int j = 0; j <= 284; j++) {
ET[j+95] = 0.1*pow(1.05, double(j));
ET[j+95] = pow(10, log10(1e-1) + double(j)*DBprlog);
}
// for (int j = 0; j <= dimpr; j++) {
// cout << j << " " << ET[j] << endl;
// }
TSpallationNetwork::InitDataTablesFluka(which_particle);
cout << "test" << endl;
gsl_interp_accel *acc = gsl_interp_accel_alloc ();
gsl_spline *spline_El_pp = gsl_spline_alloc(gsl_interp_cspline, dimlept+1);
gsl_spline *spline_El_pHe = gsl_spline_alloc(gsl_interp_cspline, dimlept+1);
gsl_spline *spline_El_Hep = gsl_spline_alloc(gsl_interp_cspline, dimlept+1);
gsl_spline *spline_El_HeHe = gsl_spline_alloc(gsl_interp_cspline, dimlept+1);
gsl_spline *spline_Pos_pp = gsl_spline_alloc(gsl_interp_cspline, dimlept+1);
gsl_spline *spline_Pos_pHe = gsl_spline_alloc(gsl_interp_cspline, dimlept+1);
gsl_spline *spline_Pos_Hep = gsl_spline_alloc(gsl_interp_cspline, dimlept+1);
gsl_spline *spline_Pos_HeHe = gsl_spline_alloc(gsl_interp_cspline, dimlept+1);
//
gsl_spline *spline_Ap_pp = gsl_spline_alloc(gsl_interp_cspline, dimap+1);
gsl_spline *spline_Ap_pHe = gsl_spline_alloc(gsl_interp_cspline, dimap+1);
gsl_spline *spline_Ap_Hep = gsl_spline_alloc(gsl_interp_cspline, dimap+1);
gsl_spline *spline_Ap_HeHe = gsl_spline_alloc(gsl_interp_cspline, dimap+1);
//
gsl_spline *spline_p_pp = gsl_spline_alloc(gsl_interp_cspline, dimp+1);
gsl_spline *spline_p_pHe = gsl_spline_alloc(gsl_interp_cspline, dimp+1);
gsl_spline *spline_p_Hep = gsl_spline_alloc(gsl_interp_cspline, dimp+1);
gsl_spline *spline_p_HeHe = gsl_spline_alloc(gsl_interp_cspline, dimp+1);
//
gsl_spline *spline_3Ap_app = gsl_spline_alloc(gsl_interp_cspline, dimp+1);
gsl_spline *spline_3Ap_apHe = gsl_spline_alloc(gsl_interp_cspline, dimp+1);
//gsl_interp_accel *acc = gsl_interp_accel_alloc ();
gsl_spline *spline_El_pp_up = gsl_spline_alloc(gsl_interp_cspline, dimlept+1);
gsl_spline *spline_El_pHe_up = gsl_spline_alloc(gsl_interp_cspline, dimlept+1);
gsl_spline *spline_El_Hep_up = gsl_spline_alloc(gsl_interp_cspline, dimlept+1);
gsl_spline *spline_El_HeHe_up = gsl_spline_alloc(gsl_interp_cspline, dimlept+1);
gsl_spline *spline_Pos_pp_up = gsl_spline_alloc(gsl_interp_cspline, dimlept+1);
gsl_spline *spline_Pos_pHe_up = gsl_spline_alloc(gsl_interp_cspline, dimlept+1);
gsl_spline *spline_Pos_Hep_up = gsl_spline_alloc(gsl_interp_cspline, dimlept+1);
gsl_spline *spline_Pos_HeHe_up = gsl_spline_alloc(gsl_interp_cspline, dimlept+1);
//
gsl_spline *spline_Ap_pp_up = gsl_spline_alloc(gsl_interp_cspline, dimap+1);
gsl_spline *spline_Ap_pHe_up = gsl_spline_alloc(gsl_interp_cspline, dimap+1);
gsl_spline *spline_Ap_Hep_up = gsl_spline_alloc(gsl_interp_cspline, dimap+1);
gsl_spline *spline_Ap_HeHe_up = gsl_spline_alloc(gsl_interp_cspline, dimap+1);
//
gsl_spline *spline_p_pp_up = gsl_spline_alloc(gsl_interp_cspline, dimp+1);
gsl_spline *spline_p_pHe_up = gsl_spline_alloc(gsl_interp_cspline, dimp+1);
gsl_spline *spline_p_Hep_up = gsl_spline_alloc(gsl_interp_cspline, dimp+1);
gsl_spline *spline_p_HeHe_up = gsl_spline_alloc(gsl_interp_cspline, dimp+1);
//
gsl_spline *spline_3Ap_app_up = gsl_spline_alloc(gsl_interp_cspline, dimap+1);
gsl_spline *spline_3Ap_apHe_up = gsl_spline_alloc(gsl_interp_cspline, dimap+1);
double Vectorlept_El_pp[dimlept+1];
double Vectorlept_El_pHe[dimlept+1];
double Vectorlept_El_Hep[dimlept+1];
double Vectorlept_El_HeHe[dimlept+1];
double Vectorlept_Pos_pp[dimlept+1];
double Vectorlept_Pos_pHe[dimlept+1];
double Vectorlept_Pos_Hep[dimlept+1];
double Vectorlept_Pos_HeHe[dimlept+1];
//
double Vector_Ap_pp[dimap+1];
double Vector_Ap_pHe[dimap+1];
double Vector_Ap_Hep[dimap+1];
double Vector_Ap_HeHe[dimap+1];
//
double Vector_p_pp[dimp+1];
double Vector_p_pHe[dimp+1];
double Vector_p_Hep[dimp+1];
double Vector_p_HeHe[dimp+1];
//
double Vector_3Ap_app[dimap+1];
double Vector_3Ap_apHe[dimap+1];
//
double Vectorlept_El_pp_up[dimlept+1];
double Vectorlept_El_pHe_up[dimlept+1];
double Vectorlept_El_Hep_up[dimlept+1];
double Vectorlept_El_HeHe_up[dimlept+1];
double Vectorlept_Pos_pp_up[dimlept+1];
double Vectorlept_Pos_pHe_up[dimlept+1];
double Vectorlept_Pos_Hep_up[dimlept+1];
double Vectorlept_Pos_HeHe_up[dimlept+1];
//
double Vector_Ap_pp_up[dimap+1];
double Vector_Ap_pHe_up[dimap+1];
double Vector_Ap_Hep_up[dimap+1];
double Vector_Ap_HeHe_up[dimap+1];
//
double Vector_p_pp_up[dimp+1];
double Vector_p_pHe_up[dimp+1];
double Vector_p_Hep_up[dimp+1];
double Vector_p_HeHe_up[dimp+1];
//
double Vector_3Ap_app_up[dimp+1];
double Vector_3Ap_apHe_up[dimp+1];
if (which_particle == 0) { //leptons
for (unsigned int j=0; j<dimEn; j++){
double Epr = energy[j];
double momentum = sqrt(Epr*Epr + 2.0*mp*Epr);