#ifndef APPROX8_H #define APPROX8_H #include #include #include "network.h" /** * @file approx8.h * @brief Header file for the Approx8 nuclear reaction network. * * This file contains the definitions and declarations for the Approx8 nuclear reaction network. * The network is based on Frank Timmes' "aprox8" and includes 8 isotopes and various nuclear reactions. * The rates are evaluated using a fitting function with coefficients from reaclib.jinaweb.org. */ /** * @typedef vector_type * @brief Alias for a vector of doubles using Boost uBLAS. */ typedef boost::numeric::ublas::vector< double > vector_type; /** * @typedef matrix_type * @brief Alias for a matrix of doubles using Boost uBLAS. */ typedef boost::numeric::ublas::matrix< double > matrix_type; /** * @typedef vec7 * @brief Alias for a std::array of 7 doubles. */ typedef std::array vec7; namespace nnApprox8{ using namespace boost::numeric::odeint; /** * @struct Net * @brief Contains constants and arrays related to the nuclear network. */ struct Net{ const static int ih1=0; const static int ihe3=1; const static int ihe4=2; const static int ic12=3; const static int in14=4; const static int io16=5; const static int ine20=6; const static int img24=7; const static int itemp=img24+1; const static int iden =itemp+1; const static int iener=iden+1; const static int niso=img24+1; // number of isotopes const static int nvar=iener+1; // number of variables static constexpr std::array aion = { 1, 3, 4, 12, 14, 16, 20, 24 }; static constexpr std::array mion = { 1.67262164e-24, 5.00641157e-24, 6.64465545e-24, 1.99209977e-23, 2.32462686e-23, 2.65528858e-23, 3.31891077e-23, 3.98171594e-23 }; }; /** * @brief Multiplies two arrays and sums the resulting elements. * @param a First array. * @param b Second array. * @return Sum of the product of the arrays. * @example * @code * vec7 a = {1.0, 2.0, 3.0, 4.0, 5.0, 6.0, 7.0}; * vec7 b = {0.5, 0.5, 0.5, 0.5, 0.5, 0.5, 0.5}; * double result = sum_product(a, b); * @endcode */ double sum_product( const vec7 &a, const vec7 &b); /** * @brief Returns an array of T9 terms for the nuclear reaction rate fit. * @param T Temperature in GigaKelvin. * @return Array of T9 terms. * @example * @code * double T = 1.5; * vec7 T9_array = get_T9_array(T); * @endcode */ vec7 get_T9_array(const double &T); /** * @brief Evaluates the nuclear reaction rate given the T9 array and coefficients. * @param T9 Array of T9 terms. * @param coef Array of coefficients. * @return Evaluated rate. * @example * @code * vec7 T9 = get_T9_array(1.5); * vec7 coef = {1.0, 0.1, 0.01, 0.001, 0.0001, 0.00001, 0.000001}; * double rate = rate_fit(T9, coef); * @endcode */ double rate_fit(const vec7 &T9, const vec7 &coef); /** * @brief Calculates the rate for the reaction p + p -> d. * @param T9 Array of T9 terms. * @return Rate of the reaction. */ double pp_rate(const vec7 &T9); /** * @brief Calculates the rate for the reaction p + d -> he3. * @param T9 Array of T9 terms. * @return Rate of the reaction. */ double dp_rate(const vec7 &T9); /** * @brief Calculates the rate for the reaction he3 + he3 -> he4 + 2p. * @param T9 Array of T9 terms. * @return Rate of the reaction. */ double he3he3_rate(const vec7 &T9); /** * @brief Calculates the rate for the reaction he3(he3,2p)he4. * @param T9 Array of T9 terms. * @return Rate of the reaction. */ double he3he4_rate(const vec7 &T9); /** * @brief Calculates the rate for the reaction he4 + he4 + he4 -> c12. * @param T9 Array of T9 terms. * @return Rate of the reaction. */ double triple_alpha_rate(const vec7 &T9); /** * @brief Calculates the rate for the reaction c12 + p -> n13. * @param T9 Array of T9 terms. * @return Rate of the reaction. */ double c12p_rate(const vec7 &T9); /** * @brief Calculates the rate for the reaction c12 + he4 -> o16. * @param T9 Array of T9 terms. * @return Rate of the reaction. */ double c12a_rate(const vec7 &T9); /** * @brief Calculates the rate for the reaction n14(p,g)o15 - o15 + p -> c12 + he4. * @param T9 Array of T9 terms. * @return Rate of the reaction. */ double n14p_rate(const vec7 &T9); /** * @brief Calculates the rate for the reaction n14(a,g)f18 assumed to go on to ne20. * @param T9 Array of T9 terms. * @return Rate of the reaction. */ double n14a_rate(const vec7 &T9); /** * @brief Calculates the rate for the reaction n15(p,a)c12 (CNO I). * @param T9 Array of T9 terms. * @return Rate of the reaction. */ double n15pa_rate(const vec7 &T9); /** * @brief Calculates the rate for the reaction n15(p,g)o16 (CNO II). * @param T9 Array of T9 terms. * @return Rate of the reaction. */ double n15pg_rate(const vec7 &T9); /** * @brief Calculates the fraction for the reaction n15(p,g)o16. * @param T9 Array of T9 terms. * @return Fraction of the reaction. */ double n15pg_frac(const vec7 &T9); /** * @brief Calculates the rate for the reaction o16(p,g)f17 then f17 -> o17(p,a)n14. * @param T9 Array of T9 terms. * @return Rate of the reaction. */ double o16p_rate(const vec7 &T9); /** * @brief Calculates the rate for the reaction o16(a,g)ne20. * @param T9 Array of T9 terms. * @return Rate of the reaction. */ double o16a_rate(const vec7 &T9); /** * @brief Calculates the rate for the reaction ne20(a,g)mg24. * @param T9 Array of T9 terms. * @return Rate of the reaction. */ double ne20a_rate(const vec7 &T9); /** * @brief Calculates the rate for the reaction c12(c12,a)ne20. * @param T9 Array of T9 terms. * @return Rate of the reaction. */ double c12c12_rate(const vec7 &T9); /** * @brief Calculates the rate for the reaction c12(o16,a)mg24. * @param T9 Array of T9 terms. * @return Rate of the reaction. */ double c12o16_rate(const vec7 &T9); /** * @struct Jacobian * @brief Functor to calculate the Jacobian matrix for implicit solvers. */ struct Jacobian { /** * @brief Calculates the Jacobian matrix. * @param y State vector. * @param J Jacobian matrix. * @param t Time. * @param dfdt Derivative of the state vector. */ void operator() ( const vector_type &y, matrix_type &J, double /* t */, vector_type &dfdt ); }; /** * @struct ODE * @brief Functor to calculate the derivatives for the ODE solver. */ struct ODE { /** * @brief Calculates the derivatives of the state vector. * @param y State vector. * @param dydt Derivative of the state vector. * @param t Time. */ void operator() ( const vector_type &y, vector_type &dydt, double /* t */); }; /** * @class Approx8Network * @brief Class for the Approx8 nuclear reaction network. */ class Approx8Network : public nuclearNetwork::Network { public: /** * @brief Evaluates the nuclear network. * @param netIn Input parameters for the network. * @return Output results from the network. */ virtual nuclearNetwork::NetOut evaluate(const nuclearNetwork::NetIn &netIn); /** * @brief Sets whether the solver should use a stiff method. * @param stiff Boolean indicating if a stiff method should be used. */ void setStiff(bool stiff); /** * @brief Checks if the solver is using a stiff method. * @return Boolean indicating if a stiff method is being used. */ bool isStiff() { return m_stiff; } private: vector_type m_y; double m_tmax; double m_dt0; bool m_stiff = false; /** * @brief Converts the input parameters to the internal state vector. * @param netIn Input parameters for the network. * @return Internal state vector. */ vector_type convert_netIn(const nuclearNetwork::NetIn &netIn); }; } // namespace nnApprox8 #endif