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518 lines
15 KiB
C++
518 lines
15 KiB
C++
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#ifndef sed_hpp
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#define sed_hpp
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#include "agn.hpp"
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#include "spline.h"
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namespace agn {
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// Cloudy's continuum domain, for reference
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// Pulled from cloudy 17.00, first version
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// rfield.emm = 1.001e-8f;
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// rfield.egamry = 7.354e6f;
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const double CLOUDY_EMM = 1.001e-8; // in Rydberg
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const double CLOUDY_EGAMRY = 7.354e6; // in Rydberg
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const double CLOUDY_MIN_EV=CLOUDY_EMM*RYDBERG_UNIT_EV;
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const double CLOUDY_MAX_EV=CLOUDY_EGAMRY*RYDBERG_UNIT_EV;
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// Continuum domain, step size constant in log space
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const double CONT_MIN_ENERGY=CLOUDY_MIN_EV; // eV
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const double CONT_MAX_ENERGY=CLOUDY_MAX_EV; // eV
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const double CONT_MIN_LOGX=log10(CONT_MIN_ENERGY);
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const double CONT_MAX_LOGX=log10(CONT_MAX_ENERGY);
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const double CONT_WIDTH_LOGX=CONT_MAX_LOGX - CONT_MIN_LOGX;
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const double CONT_MIN_VAL=1e-35;
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const double IN_EV_2500A=12398.41929/2500;
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// SEDs are represented by 2d histogram tables.
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struct sed_table {
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std::string header;
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table1d table;
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};
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// To account for the four main powerlaws in a typical
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// AGN SED.
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// Hardcoded infrared and gamma ray power laws and cutoffs.
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const double IR_POWER = 3;
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const double GAMMA_POWER = -5;
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const double RADIO_CUTOFF = 1e-4; // IN KEV
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const double GAMMA_CUTOFF = 1e4; // IN KEV
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struct powerlaw_bounds {
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double ir_min;
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double ir_max;
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double uv_min;
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double uv_max;
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double xray_min;
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double xray_max;
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double gamma_min;
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double gamma_max;
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};
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class powerlaw {
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private:
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// f(x) = _normal*x^_power
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double _power;
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double _normal;
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public:
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powerlaw(): _power(0), _normal(0) {}
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powerlaw(coord2d x0,coord2d x1):
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_power((log(x1.second)-log(x0.second))/(log(x1.first)-log(x0.first))),
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_normal(exp(log(x0.second)-(_power*log(x0.first))))
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{}
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powerlaw(coord2d x0,double power):
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_power(power),
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_normal(exp(log(x0.second)-(_power*log(x0.first))))
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{}
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double eval(double hnu) {
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return
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_normal
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* pow(hnu,_power)
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* exp(-(hnu)/GAMMA_CUTOFF)
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* exp(-(RADIO_CUTOFF/hnu))
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;
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}
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};
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class sed {
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public:
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// Continuum output functions
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// Returns histogram with n bins evenly space in log space
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sed_table histogram_table(int n);
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// Argument is photon energy in eV
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virtual double eval(double hnu) {};
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sed() {};
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};
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class sed_powerlaw_spline : public sed {
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private:
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Spline<double,double> _output_model;
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powerlaw _ir_powerlaw;
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powerlaw _uv_powerlaw;
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powerlaw _xray_powerlaw;
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powerlaw _gamma_powerlaw;
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powerlaw_bounds _bounds;
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// These parameters might still be useful for rolling off various quantities, but aren't used in the strict-spline case.
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// Derived values
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double _cutoff_uv_eV; // IRCut
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double _cutoff_xray_eV; // lowend_cutoff
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double _radius_in_cm;
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double _radius_in_cm_squared;
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double _scaling_factor;
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double _xray_coefficient;
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public:
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double eval(double hnu);
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sed_powerlaw_spline(agn::sed_table& samples,
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agn::sed_table& powerlaw_coords);
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powerlaw * getpowerlaw(double hnu);
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};
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class sed_pow_law : public sed {
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public:
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double eval(double hnu);
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// Argument is photon energy in eV
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double eval_uv(double hnu);
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double eval_xray(double hnu);
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// Determined differently to be of use as the
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// xray coefficient.
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double SED_at_2KeV();
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// Continuum shape arguments
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double _T; //TCut
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double _alpha_ox;
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double _alpha_x;
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double _alpha_uv;
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double _cutoff_uv_rydberg;
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double _cutoff_xray_rydberg;
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double _log_radius_in_cm;
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// Derived values
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double _cutoff_uv_eV; // IRCut
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double _cutoff_xray_eV; // lowend_cutoff
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double _radius_in_cm;
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double _radius_in_cm_squared;
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double _scaling_factor;
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double _xray_coefficient;
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sed_pow_law (
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double T,
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double alpha_ox,
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double alpha_x,
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double alpha_uv,
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double cutoff_uv_rydberg,
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double cutoff_xray_rydberg,
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double log_radius_in_cm,
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double scaling_factor = 1.0
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// EL[e] model scaling factor
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// double scaling_factor = 1.39666E44
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);
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};
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// Returns coord in eV for given relative coord.
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double logspace_hnu_at(int i,int n);
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// Takes an SED table as input and returns a string with format:
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// '<h*nu>\t<flux>\n' for each energy-flux pair
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std::string format_sed_table(sed_table table);
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// Read continuum from file with '<h*nu>\t<flux>\n' formatting.
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// Will ignore up to 1 header.
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sed_table read_sed_table(std::ifstream& table_file);
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// Does the same but converts hnu from rydberg to eV.
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sed_table read_and_convert_sed_table(std::ifstream& table_file);
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// Cloudy takes the SED density as input. This function outputs
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// the corresponding SED table's SED density function in the form
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// of a cloudy input script "interpolate" command.
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std::string cloudy_interpolate_str(sed_table SED);
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} // end namespace agn
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// Constructors
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agn::sed_powerlaw_spline::sed_powerlaw_spline(
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agn::sed_table& samples,
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agn::sed_table& powerlaw_coords
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)
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{
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// coordinate vectors will be used to construct spline sed model
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std::vector<double> x0;
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std::vector<double> x1;
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// powerlaws are evaluated across four regions of the sed, first
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// we construct the powerlaws, here, and locate them
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iterator1d table_it = powerlaw_coords.table.begin();
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double ir_power = agn::IR_POWER;
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double gamma_power = agn::GAMMA_POWER;
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coord2d ir_high_point = *table_it; table_it++;
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coord2d uv_low_point = *table_it; table_it++;
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coord2d uv_high_point = *table_it; table_it++;
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coord2d xray_low_point = *table_it; table_it++;
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coord2d xray_high_point = *table_it; table_it++;
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coord2d gamma_low_point = *table_it;
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_ir_powerlaw = powerlaw(ir_high_point,ir_power);
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_uv_powerlaw = powerlaw(uv_low_point,uv_high_point);
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_xray_powerlaw = powerlaw(xray_low_point,xray_high_point);
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_gamma_powerlaw = powerlaw(gamma_low_point,gamma_power);
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_bounds.ir_min = agn::CLOUDY_MIN_EV;
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_bounds.ir_max = ir_high_point.first;
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_bounds.uv_min = uv_low_point.first;
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_bounds.uv_max = uv_high_point.first;
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_bounds.xray_min = xray_low_point.first;
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_bounds.xray_max = xray_high_point.first;
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_bounds.gamma_min = gamma_low_point.first;
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_bounds.gamma_max = agn::CLOUDY_MAX_EV;
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if(agn::debug) {
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std::cout << "[Constructor] Powerlaw Boundaries: \n";
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std::cout << _bounds.ir_min << std::endl;
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std::cout << _bounds.ir_max << std::endl;
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std::cout << _bounds.uv_min << std::endl;
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std::cout << _bounds.uv_max << std::endl;
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std::cout << _bounds.xray_min << std::endl;
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std::cout << _bounds.xray_max << std::endl;
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std::cout << _bounds.gamma_min << std::endl;
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std::cout << _bounds.gamma_max << std::endl;
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}
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// here we inject the powerlaws into the samples
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int segments=100;
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double hnu = 0;
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double value = 0;
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for (int i=0; i<=segments; i++) {
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hnu =
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_bounds.ir_min +
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(i/(double)segments)*(_bounds.ir_max - _bounds.ir_min);
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value = _ir_powerlaw.eval(hnu);
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coord2d point = coord2d(hnu,value);
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samples.table.insert(samples.table.end(),point);
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}
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for (int i=0; i<=segments; i++) {
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hnu =
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_bounds.uv_min +
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(i/(double)segments)*(_bounds.uv_max - _bounds.uv_min);
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value = _uv_powerlaw.eval(hnu);
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coord2d point = coord2d(hnu,value);
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samples.table.insert(samples.table.end(),point);
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}
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for (int i=0; i<=segments; i++) {
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hnu =
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_bounds.xray_min +
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(i/(double)segments)*(_bounds.xray_max - _bounds.xray_min);
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value = _xray_powerlaw.eval(hnu);
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coord2d point = coord2d(hnu,value);
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samples.table.insert(samples.table.end(),point);
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}
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for (int i=0; i<=segments; i++) {
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hnu =
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_bounds.gamma_min +
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(i/(double)segments)*(_bounds.gamma_max - _bounds.gamma_min);
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value = _gamma_powerlaw.eval(hnu);
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coord2d point = coord2d(hnu,value);
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samples.table.insert(samples.table.end(),point);
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}
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if(agn::debug) {
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std::cout
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<< "[Constructor] Samples after evaluating powerlaws: \n";
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std::cout << agn::format_sed_table(samples);
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}
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// load all samples into coordinate vectors
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table_it = samples.table.begin();
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while(table_it != samples.table.end()) {
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x0.push_back(table_it->first);
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x1.push_back(table_it->second);
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table_it++;
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}
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Spline<double,double> newspline(x0,x1);
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_output_model = newspline;
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}
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agn::sed_pow_law::sed_pow_law (
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double T,
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double alpha_ox,
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double alpha_x,
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double alpha_uv,
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double cutoff_uv_rydberg,
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double cutoff_xray_rydberg,
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double log_radius_in_cm,
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double scaling_factor
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):
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_T(T),
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_alpha_ox(alpha_ox),
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_alpha_x(alpha_x),
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_alpha_uv(alpha_uv),
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_cutoff_uv_rydberg(cutoff_uv_rydberg),
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_cutoff_xray_rydberg(cutoff_xray_rydberg),
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_log_radius_in_cm(log_radius_in_cm),
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_scaling_factor(scaling_factor)
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{
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_cutoff_uv_eV = cutoff_uv_rydberg*RYDBERG_UNIT_EV;
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_cutoff_xray_eV = cutoff_xray_rydberg*RYDBERG_UNIT_EV;
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_radius_in_cm = pow(10,log_radius_in_cm);
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_radius_in_cm_squared = _radius_in_cm*_radius_in_cm;
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_xray_coefficient = agn::sed_pow_law::SED_at_2KeV();
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}
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// Class Functions
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// writes log-space histogram with n data
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agn::sed_table agn::sed::histogram_table(int n){
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agn::sed_table table;
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double max=0,min=1,hnu;
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for(int i=0; i<n; i++) {
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// evenly space coordinates in log space and save values
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hnu = logspace_hnu_at(i,n);
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table.table[hnu] = this->eval(hnu);
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// Just collects min and max
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if (table.table[hnu] > max) max = table.table[hnu];
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if (table.table[hnu] < min) min = table.table[hnu];
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}
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return table;
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}
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// sed_powerlaw_spline evaluation
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double agn::sed_powerlaw_spline::eval(double hnu) {
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double magnitude=0.0;
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agn::powerlaw * here = this->getpowerlaw(hnu);
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if (here == NULL)
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magnitude += this->_output_model[hnu];
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else
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magnitude += here->eval(hnu);
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if (magnitude < agn::CONT_MIN_VAL) return agn::CONT_MIN_VAL;
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return magnitude;
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}
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agn::powerlaw * agn::sed_powerlaw_spline::getpowerlaw(double hnu) {
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if (hnu <= _bounds.gamma_max && hnu >= _bounds.gamma_min )
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return &_gamma_powerlaw;
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if (hnu <= _bounds.uv_max && hnu >= _bounds.uv_min )
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return &_uv_powerlaw;
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if (hnu <= _bounds.xray_max && hnu >= _bounds.xray_min )
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return &_xray_powerlaw;
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if (hnu <= _bounds.ir_max && hnu >= _bounds.ir_min )
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return &_ir_powerlaw;
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return NULL;
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}
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// sed_pow_law evaluations
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double agn::sed_pow_law::eval(double hnu) {
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double magnitude=0.0;
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magnitude += this->eval_uv(hnu);
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magnitude += this->eval_xray(hnu);
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return magnitude;
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}
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double agn::sed_pow_law::eval_uv(double hnu) {
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double bigbump_kT = _T
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* agn::BOLTZMANN_CONST;
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double magnitude = pow(hnu,(1+_alpha_uv))
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* exp(-(hnu)/bigbump_kT)
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* exp(-(_cutoff_uv_eV/hnu))
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* _scaling_factor;
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if (magnitude < agn::CONT_MIN_VAL) return agn::CONT_MIN_VAL;
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return magnitude;
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}
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double agn::sed_pow_law::eval_xray(double hnu) {
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return _xray_coefficient
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* pow(hnu/2000,1+_alpha_x)
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* exp(-_cutoff_xray_eV/hnu)
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* _scaling_factor;
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}
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double agn::sed_pow_law::SED_at_2KeV() {
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double ELe_at_2500A_no_scale = eval_uv(IN_EV_2500A)
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/ _scaling_factor;
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double energy_ratio = 2000/IN_EV_2500A;
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// Returns EL[e] at 2 KeV
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return ELe_at_2500A_no_scale
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* pow(energy_ratio,_alpha_ox + 1);
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}
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// Utilities
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agn::sed_table agn::read_sed_table(std::ifstream& table_file) {
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sed_table resultant;
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std::string line;
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double hnu;
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if(!isdigit(table_file.peek()) && table_file.peek() != '#') {
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std::getline(table_file,resultant.header);
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}
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while(!table_file.eof()) {
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std::getline(table_file,line);
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if (line[0] == '#') continue;
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std::stringstream scratch(line);
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scratch >> hnu;
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scratch >> resultant.table[hnu];
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|
}
|
||
|
return resultant;
|
||
|
}
|
||
|
|
||
|
|
||
|
agn::sed_table agn::read_and_convert_sed_table(std::ifstream& table_file) {
|
||
|
sed_table resultant;
|
||
|
std::string scratch;
|
||
|
int current_line=0;
|
||
|
double hnu_in_ryd,hnu_in_ev,table;
|
||
|
std::getline(table_file,scratch);
|
||
|
if(!isdigit(scratch[0])) {
|
||
|
resultant.header = scratch;
|
||
|
current_line++;
|
||
|
}
|
||
|
int c=0;
|
||
|
while(!table_file.eof()) {
|
||
|
//std::cout << c;
|
||
|
table_file >> hnu_in_ryd;
|
||
|
hnu_in_ev = hnu_in_ryd*agn::RYDBERG_UNIT_EV;
|
||
|
table_file >> resultant.table[hnu_in_ev];
|
||
|
getline(table_file,scratch);
|
||
|
}
|
||
|
}
|
||
|
|
||
|
std::string agn::format_sed_table(agn::sed_table table) {
|
||
|
std::stringstream output;
|
||
|
if (!table.header.empty()) output << table.header;
|
||
|
output << std::setprecision(5);
|
||
|
agn::table1d::iterator table_iterator;
|
||
|
table_iterator=table.table.begin();
|
||
|
while(table_iterator != table.table.end()) {
|
||
|
output
|
||
|
<< std::fixed
|
||
|
<< std::scientific
|
||
|
<< table_iterator->first
|
||
|
<< "\t"
|
||
|
<< std::scientific
|
||
|
<< table_iterator->second
|
||
|
<< "\n";
|
||
|
table_iterator++;
|
||
|
}
|
||
|
return output.str();
|
||
|
}
|
||
|
|
||
|
std::string agn::cloudy_interpolate_str(agn::sed_table table) {
|
||
|
std::stringstream output;
|
||
|
agn::table1d::iterator table_iterator = table.table.begin();
|
||
|
// Lead in to uv bump at slope=2 in log(energy [rydberg]) space
|
||
|
double energy_in_rydbergs = table_iterator->first
|
||
|
/ agn::RYDBERG_UNIT_EV;
|
||
|
double log_uv_bump_start = log10( energy_in_rydbergs );
|
||
|
double log_lowest_value = log10(table_iterator->second
|
||
|
/ table_iterator->first);
|
||
|
double log_min_energy = log10(agn::CLOUDY_EMM)
|
||
|
- 1;
|
||
|
double log_SED_density = log_lowest_value
|
||
|
- 2*(log_uv_bump_start
|
||
|
- log_min_energy);
|
||
|
if ( log_SED_density < 1e-36 ) log_SED_density = 1e-36;
|
||
|
output
|
||
|
<< "interpolate ("
|
||
|
<< pow(10,log_min_energy)
|
||
|
<< " "
|
||
|
<< log_SED_density
|
||
|
<< ")";
|
||
|
int count=0;
|
||
|
|
||
|
while(table_iterator != table.table.end()) {
|
||
|
energy_in_rydbergs = table_iterator->first
|
||
|
/ agn::RYDBERG_UNIT_EV;
|
||
|
double log_SED_density = log10( table_iterator->second
|
||
|
/ table_iterator->first);
|
||
|
if ((count%5)==0) output << "\n" << "continue ";
|
||
|
else output << " ";
|
||
|
output
|
||
|
<< "("
|
||
|
<< energy_in_rydbergs
|
||
|
<< " "
|
||
|
<< log_SED_density
|
||
|
<< ")";
|
||
|
count++;
|
||
|
table_iterator++;
|
||
|
}
|
||
|
// Trail off at slope=-2 in log(energy [rydberg]) space
|
||
|
while ( energy_in_rydbergs < agn::CLOUDY_EGAMRY ) {
|
||
|
double log_energy = log10(energy_in_rydbergs);
|
||
|
energy_in_rydbergs = pow(10,log_energy+1);
|
||
|
log_SED_density -= 2;
|
||
|
output
|
||
|
<< "("
|
||
|
<< energy_in_rydbergs
|
||
|
<< " "
|
||
|
<< log_SED_density
|
||
|
<< ")";
|
||
|
}
|
||
|
return output.str();
|
||
|
}
|
||
|
|
||
|
|
||
|
double agn::logspace_hnu_at(int i,int n) {
|
||
|
double relative_coord_logspace=(double)(i)/n;
|
||
|
double abs_coord_logspace = relative_coord_logspace*CONT_WIDTH_LOGX + CONT_MIN_LOGX;
|
||
|
return pow(10,abs_coord_logspace);
|
||
|
}
|
||
|
|
||
|
|
||
|
#endif
|