Is it possible to compute double integral using scipy.integrate.fixed_quad?

Question

I am trying to compute a double integral (over a triangle with nodes at (0,0), (0,1), (1,0)) using Gaussian quadrature of order n. However, running

import scipy.integrate as integrate
f = lambda x,y: x+y
inside = lambda x: integrate.fixed_quad(f, 0, 1-x, args=(x,), n=5)[0]
outside = integrate.fixed_quad(inside, 0, 1, n=5)

gives

Traceback (most recent call last): File "", line 1, in File "/Users/username/anaconda/lib/python3.5/site-packages/scipy/integrate/quadrature.py", line 82, in fixed_quad return (b-a)/2.0 * np.sum(w*func(y, *args), axis=0), None File "", line 1, in File "/Users/username/anaconda/lib/python3.5/site-packages/scipy/integrate/quadrature.py", line 78, in fixed_quad if np.isinf(a) or np.isinf(b):

ValueError: The truth value of an array with more than one element is ambiguous. Use a.any() or a.all()

This is the second part of the question Can scipy.integrate.fixed_quad compute integral with functional boundaries?.

Answer 1

The answer to your question is, yes, under certain conditions.

For demonstration purposes, I first choose different bounds than you (11 instead of 1 - x).

Generally, one can solve these types of integrals using dblquad:

area_dblquad = integrate.dblquad(lambda x, y: x + y, 0, 1, lambda x: 0, lambda x: 11)[0]

which here returns 66. That is not an option as you mentioned in the comments.

One can now do this integration stepwise and it works fine for quad as well as fixed_quad:

def integrand(x, y):
    return x + y

def fint_quad(x):
    return integrate.quad(integrand, 0, 11, args=(x, ))[0]

def fint_fixed_quad(x):
    return integrate.fixed_quad(integrand, 0, 11, args=(x, ), n=5)[0]

res_quad = integrate.quad(lambda x: fint_quad(x), 0, 1)
res_fixed_quad = integrate.fixed_quad(lambda x: fint_fixed_quad(x), 0, 1, n=5)

They both return 66 as well, as expected. That shows that it can work to compute double integrals using scipy.integrate.fixed_quad.

However, when one now changes the upper bound back to the one you had (from 11 to 1 - x), it still works for quad but crashes for fixed_quad:

area_dblquad = integrate.dblquad(lambda x, y: x + y, 0, 1, lambda x: 0, lambda x: 1 - x)[0]
res_quad = integrate.quad(lambda x: fint_quad(x), 0, 1)

both return 0.333333..., the call with fixed_quad results in the error you received. One can understand the error by looking on the source code:

x, w = _cached_roots_legendre(n)
x = np.real(x)
if np.isinf(a) or np.isinf(b):
    raise ValueError("Gaussian quadrature is only available for "
                         "finite limits.")
y = (b-a)*(x+1)/2.0 + a
return (b-a)/2.0 * np.sum(w*func(y, *args), axis=-1), None

When one prints a and b one gets:

a:  0
b:  1
a:  0
b:  [ 0.95308992  0.76923466  0.5         0.23076534  0.04691008]

So for the call with 1-x, b is actually a numpy array with n elements and one cannot compare an array to infinity, that's why it crashes. Whether that is an intended behavior or a bug, I can't answer; might be worth opening an issue on github.

Answer 2

fixed_quad requires f to accept vector inputs. And the result should be the mapped values for the inputs (i.e. something like map(f, xs)). With this in mind, just ensure your inside function returns mapped values, and you're ready to go.

import scipy.integrate as integrate
f = lambda y,x: x+y
inside = lambda xs, n: np.array([integrate.fixed_quad(f, 0, 1-x, args=(x,), n=n)[0]
                                 for x in np.array(xs)])
order = 5
outside = integrate.fixed_quad(inside, 0, 1, n=order, args=(order,))

Also, be careful with the order of arguments for your integrand. Judging from your code arg=(x,), it seems that you want the inner integral to be done along y dimension. The first argument of the integrand is the dimension along which it is integrated. So it should be lambda y,x instead (note that this is also the shape of integrand expected by dblquad).