forked from IPKM/nmreval
C function for energy distribution spectral density
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@ -1,6 +1,8 @@
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/* integrands used in quadrature integration with scipy's LowLevelCallables */
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#include <math.h>
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#define KB 8.617333262145179e-05
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/* FFHS functions */
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double ffhsSD(double x, void *user_data) {
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double *c = (double *)user_data;
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@ -18,7 +20,7 @@ double ffhsSD(double x, void *user_data) {
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/* log-gaussian functions */
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double logNormalDist(double tau, double tau0, double sigma) {
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return exp(- pow((log(tau/tau0) / sigma), 2) / 2) / sqrt(2*M_PI)/sigma;
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return exp(- pow((log(tau/tau0) / sigma), 2) / 2.) / sqrt(2*M_PI)/sigma;
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}
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double logGaussianSD_high(double u, void *user_data) {
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@ -61,3 +63,26 @@ double logGaussianCorrelation(double x, void *user_data) {
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return dist * exp(-t/uu);
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}
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double normalDist(double x, double x0, double sigma) {
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return exp(- pow((x-x0) / sigma, 2) / 2.) / sqrt(2 * M_PI) / sigma;
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}
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double rate(double tau0, double ea, double t) {
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return exp(-ea / t / KB) / tau0;
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}
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double energyDist_SD(double x, void *user_data) {
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double *c = (double *)user_data;
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double omega = c[0];
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double tau0 = c[1];
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double e_m = c[2];
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double e_b = c[3];
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double temp = c[4];
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double r = rate(tau0, x, temp);
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return r/(pow(r, 2) + pow(omega, 2)) * normalDist(x, e_m, e_b);
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}
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@ -1,13 +1,18 @@
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import ctypes
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from itertools import product
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import numpy as np
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from scipy import LowLevelCallable
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from scipy.integrate import quad, simps as simpson
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from .base import Distribution
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from ..lib.utils import ArrayLike
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from ..utils.constants import kB
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from .helper import HAS_C_FUNCS, lib
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# noinspection PyMethodOverriding
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class EnergyBarriers(Distribution):
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name = 'Energy barriers'
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parameter = [r'\tau_{0}', r'E_{m}', r'\Delta E']
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@ -51,7 +56,7 @@ class EnergyBarriers(Distribution):
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omega = np.atleast_1d(omega)
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temperature = np.atleast_1d(temperature)
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e_axis = np.linspace(max(0, e_m-50*e_b), e_m+50*e_b, num=5001)
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e_axis = np.linspace(max(0., e_m-50*e_b), e_m+50*e_b, num=5001)
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ret_val = []
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for o, tt in product(omega, temperature):
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ret_val.append(simpson(_integrand_freq_real(e_axis, o, tau0, e_m, e_b, tt), e_axis) -
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@ -60,23 +65,41 @@ class EnergyBarriers(Distribution):
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return np.array(ret_val)
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@staticmethod
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def specdens(omega, temperature, *args):
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def specdens(omega, temperature, tau0: float, e_m: float, e_b: float):
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# in contrast to other spectral densities, it's omega and temperature
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tau0, e_m, e_b = args
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def integrand(e_a, w, t0, mu, sigma, t):
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r = EnergyBarriers.rate(t0, e_a, t)
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return r/(r**2 + w**2) * EnergyBarriers.energydistribution(e_a, mu, sigma)
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omega = np.atleast_1d(omega)
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temperature = np.atleast_1d(temperature)
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e_axis = np.linspace(max(0, e_m-50*e_b), e_m+50*e_b, num=5001)
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if HAS_C_FUNCS:
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ret_val = EnergyBarriers.spec_dens_c(omega, temperature, tau0, e_m, e_b)
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else:
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ret_val = EnergyBarriers.spec_dens_py(omega, temperature, tau0, e_m, e_b)
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ret_val = np.array([simpson(integrand(e_axis, o, tau0, e_m, e_b, tt), e_axis)
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for o in omega for tt in temperature])
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return ret_val.squeeze()
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return ret_val
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@staticmethod
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def spec_dens_c(omega: np.ndarray, temperature: np.ndarray, tau0: float, e_m: float, e_b: float) -> np.ndarray:
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res = []
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for o, t in product(omega, temperature):
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c = (ctypes.c_double * 5)(o, tau0, e_m, e_b, t)
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user_data = ctypes.cast(ctypes.pointer(c), ctypes.c_void_p)
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area = quad(LowLevelCallable(lib.energyDist_SD, user_data), 0, np.infty, epsabs=1e-10)[0]
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res.append(area)
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return np.array(res)
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@staticmethod
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def spec_dens_py(omega: np.ndarray, temperature: np.ndarray, tau0: float, e_m: float, e_b: float) -> np.ndarray:
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def integrand(e_a, w, t0, mu, sigma, t):
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r = EnergyBarriers.rate(t0, e_a, t)
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return r/(r**2 + w**2) * EnergyBarriers.energydistribution(e_a, mu, sigma)
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e_axis = np.linspace(max(0., e_m-50*e_b), e_m+50*e_b, num=5001)
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ret_val = [simpson(integrand(e_axis, o, tau0, e_m, e_b, tt), e_axis) for o in omega for tt in temperature]
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return np.array(ret_val)
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@staticmethod
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def mean(*args):
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