If you have the ability to solve for `H`

and `K`

at any point desired, then the best option is going to be to evaluate them at specific points called 'nodes' and then use a numerical integration scheme to compute your integral. The basic idea is that, depending on the integration scheme, you can get results of different accuracy.

A basic finite sum would be simply evaluating your `H`

and `K`

at equidistant points and then taking `dx`

to be the space in between them. This can obviously be problematic with an infinite integral like you have, but you can also recast the kernel into a finite domain (take the 1/(x+1) of everything and then your integrands turn from (0,+inf) to (1,0) - obviously you will need to take the negative of the resulting integral and turn (1,0) into (0,1)).

Using a finite domain you can use the finite sum method described, or a more accurate integration scheme over a finite domain like Gauss-Legendre Quadrature.
`http://en.wikipedia.org/wiki/Gaussian_quadrature`

Finally, if you need to keep the infinite domain, it is possible use a quadrature type which is more suitable for infinite domains such as Gauss-Laguerre quadrature which will require you to premultiply your kernel by Exp(x) so that the resulting weights (Exp(-x)) do not change your kernel.
`http://en.wikipedia.org/wiki/Gauss–Laguerre_quadrature`