# Accuracy of Fourier series program

I have a program in Python which calculates the Fourier coefficients of a function with non-uniform point sampling (the function is obtained via edge detection).

My problem is that when I try to calculate the coefficients of higher frequency components, these add significant errors to the reconstructed function. There is a sweet spot of number of coefficients to calculate which produces an acceptable reconstruction, below that and the image is missing features, too far above that and higher order errors are introduced.

I was wondering if anyone has encountered this before and how I could fix this? Is it possible to identify this sweet spot in the program automatically?

Below is the code for calculating the sin coefficients. It uses trapezoid integration to find the integral.

``````def sine_coefficients(xs,ys,period,terms):
""" terms is number of coefficients to calculate."""
coefficients = []
data_len = len(xs)
for i in range(terms):
integrand = []
for a in range(data_len):
integrand.append(ys[a] * math.sin(xs[a] * math.pi * i * 2 / float(period)))
integrate_ans = trapezoid_integrate(xs,integrand)
result = integrate_ans * 2 / float(period)
coefficients.append(result)
return coefficients
``````
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Gibbs phenomenon says you can't ever get rid of oscillations near discontinuities, no matter how many terms you add. Is that what you're seeing? –  duffymo Apr 30 '13 at 10:37