""" Convergence regions of the expansions used in ``struve.c`` Note that for v >> z both functions tend rapidly to 0, and for v << -z, they tend to infinity. The floating-point functions over/underflow in the lower left and right corners of the figure. Figure legend ============= Red region Power series is close (1e-12) to the mpmath result Blue region Asymptotic series is close to the mpmath result Green region Bessel series is close to the mpmath result Dotted colored lines Boundaries of the regions Solid colored lines Boundaries estimated by the routine itself. These will be used for determining which of the results to use. Black dashed line The line z = 0.7*|v| + 12 """ import numpy as np import matplotlib.pyplot as plt import mpmath def err_metric(a, b, atol=1e-290): m = abs(a - b) / (atol + abs(b)) m[np.isinf(b) & (a == b)] = 0 return m def do_plot(is_h=True): from scipy.special._ufuncs import (_struve_power_series, _struve_asymp_large_z, _struve_bessel_series) vs = np.linspace(-1000, 1000, 91) zs = np.sort(np.r_[1e-5, 1.0, np.linspace(0, 700, 91)[1:]]) rp = _struve_power_series(vs[:,None], zs[None,:], is_h) ra = _struve_asymp_large_z(vs[:,None], zs[None,:], is_h) rb = _struve_bessel_series(vs[:,None], zs[None,:], is_h) mpmath.mp.dps = 50 if is_h: sh = lambda v, z: float(mpmath.struveh(mpmath.mpf(v), mpmath.mpf(z))) else: sh = lambda v, z: float(mpmath.struvel(mpmath.mpf(v), mpmath.mpf(z))) ex = np.vectorize(sh, otypes='d')(vs[:,None], zs[None,:]) err_a = err_metric(ra[0], ex) + 1e-300 err_p = err_metric(rp[0], ex) + 1e-300 err_b = err_metric(rb[0], ex) + 1e-300 err_est_a = abs(ra[1]/ra[0]) err_est_p = abs(rp[1]/rp[0]) err_est_b = abs(rb[1]/rb[0]) z_cutoff = 0.7*abs(vs) + 12 levels = [-1000, -12] plt.cla() plt.hold(1) plt.contourf(vs, zs, np.log10(err_p).T, levels=levels, colors=['r', 'r'], alpha=0.1) plt.contourf(vs, zs, np.log10(err_a).T, levels=levels, colors=['b', 'b'], alpha=0.1) plt.contourf(vs, zs, np.log10(err_b).T, levels=levels, colors=['g', 'g'], alpha=0.1) plt.contour(vs, zs, np.log10(err_p).T, levels=levels, colors=['r', 'r'], linestyles=[':', ':']) plt.contour(vs, zs, np.log10(err_a).T, levels=levels, colors=['b', 'b'], linestyles=[':', ':']) plt.contour(vs, zs, np.log10(err_b).T, levels=levels, colors=['g', 'g'], linestyles=[':', ':']) lp = plt.contour(vs, zs, np.log10(err_est_p).T, levels=levels, colors=['r', 'r'], linestyles=['-', '-']) la = plt.contour(vs, zs, np.log10(err_est_a).T, levels=levels, colors=['b', 'b'], linestyles=['-', '-']) lb = plt.contour(vs, zs, np.log10(err_est_b).T, levels=levels, colors=['g', 'g'], linestyles=['-', '-']) plt.clabel(lp, fmt={-1000: 'P', -12: 'P'}) plt.clabel(la, fmt={-1000: 'A', -12: 'A'}) plt.clabel(lb, fmt={-1000: 'B', -12: 'B'}) plt.plot(vs, z_cutoff, 'k--') plt.xlim(vs.min(), vs.max()) plt.ylim(zs.min(), zs.max()) plt.xlabel('v') plt.ylabel('z') def main(): plt.clf() plt.subplot(121) do_plot(True) plt.title('Struve H') plt.subplot(122) do_plot(False) plt.title('Struve L') plt.savefig('struve_convergence.png') plt.show() if __name__ == "__main__": main()