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I would like to integrate a function in python and provide the probability density (measure) used to sample values. If it's not obvious, integrating f(x)dx in [a,b] implicitly use the uniform probability density over [a,b], and I would like to use my own probability density (e.g. exponential).

I can do it myself, using np.random.* but then

  • I miss the optimizations available in scipy.integrate.quad. Or maybe all those optimizations assume the uniform density?
  • I need to do the error estimation myself, which is not trivial. Or maybe it is? Maybe the error is just the variance of sum(f(x))/n?

Any ideas?

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Can the integral of f(x) d(mu) (where mu is the measure) be represented as the integral of f(x)g(x) dx for some density function g? – unutbu Sep 3 '12 at 10:46
    
yes, I can assume either that I have g explicitly or that I can sample x according to g. I see where you're headed :) – Uri Cohen Sep 3 '12 at 10:50
up vote 0 down vote accepted

As unutbu said, if you have the density function, the you can just integrate the product of your function with the pdf using scipy.integrate.quad.

For the distribution that are available in scipy.stats, we can also just use the expect function.

For example

>>> from scipy import stats

>>> f = lambda x: x**2

>>> stats.norm.expect(f, loc=0, scale=1)
1.0000000000000011

>>> stats.norm.expect(f, loc=0, scale=np.sqrt(2))
1.9999999999999996

scipy.integrate.quad also has some predefined weight functions, although they are not normalized to be probability density functions.

The approximation error depends on the settings for the call to integrate.quad.

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Just for the sake of brevity, 3 ways were suggested for calculating the expected value of f(x) under the probability p(x):

  • Assuming p is given in closed-form, use scipy.integrate.quad to evaluate f(x)p(x)
  • Assuming p can be sampled from, sample N values x=P(N), then evaluate the expected value by np.mean(f(X)) and the error by np.std(f(X))/np.sqrt(N)
  • Assuming p is available at stats.norm, use stats.norm.expect(f)
  • Assuming we have the CDF(x) of the distribution rather than p(x), calculate H=Inverse[CDF] and then integrate f(H(x)) using scipy.integrate.quad
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Another possibilty would be to integrate x -> f( H(x)) where H is the inverse of the cumulative distribution of your probability distribtion.

[This is because of change of variable: replacing y=CDF(x) and noting that p(x)=CDF'(x) yields the change dy=p(x)dx and thus int{f(x)p(x)dx}==int{f(x)dy}==int{f(H(y))dy with H the inverse of CDF.]

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