I want to integrate the product of two time- and frequency-shifted Hermite functions using scipy.integrate.quad.
However, since large order-polynomials are included, there are numerical errors occuring. Here's my Code:
import numpy as np import scipy.integrate import scipy.special as sp from math import pi def makeFuncs(): # Create the 0th, 4th, 8th, 12th and 16th order hermite function return [lambda t, n=n: np.exp(-0.5*t**2)*sp.hermite(n)(t) for n in np.arange(5)*4] def ambgfun(funcs, i, k, tau, f): # Integrate f1(t)*f2(t+tau)*exp(-j2pift) over t from -inf to inf f1 = funcs[i] f2 = funcs[k] func = lambda t: np.real(f1(t) * f2(t+tau) * np.exp(-1j*(2*pi)*f*t)) return scipy.integrate.quad(func, -np.inf, np.inf) def main(): f = makeFuncs() print "A00(0,0):", ambgfun(f, 0, 0, 0, 0) print "A01(0,0):", ambgfun(f, 0, 1, 0, 0) print "A34(0,0):", ambgfun(f, 3, 4, 0, 0) if __name__ == '__main__': main()
The hermite functions are orthogonal, thus all integrals should be equal to zero. However, they are not, as the output shows:
A00(0,0): (1.7724538509055159, 1.4202636805184462e-08) A01(0,0): (8.465450562766819e-16, 8.862237123626351e-09) A34(0,0): (-10.1875, 26.317246925873935)
How can I make this calculation more accurate? The hermite-function from scipy contain a weights variable which should be used for Gaussian Quadrature, as given in the documentation (http://docs.scipy.org/doc/scipy/reference/special.html#orthogonal-polynomials). However, I have not found a hint in the docs how to use these weights.
I hope you can help :)