# MATLAB/OCTAVE- Numerical integration of an integrand containing terms obtained from numerical solution of a system of ODE

I want to calculate the following integral on Octave(or Matlab):

However, I don't have an explicit expression for H and K. The H and K are actually numerical solutions of the following differential equations. The initial conditions of h,k, dh/dr, and dk/dr are 0,1,1/2,0 respectively.

How do I go about doing this? Can I solve it directly somehow, or do I need to find the numerical solutions to H and K first, find a polynomial approximation, and then integrate? I am completely new to Matlab and numerical methods, so a detailed method describing everything will be most appreciated.

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to solve differential equations need initial or boundary conditions, you put nothing here. your question is badly put. put complete correct math question first –  Robert H Jul 13 '12 at 14:50
@RobertH: edited equation and added the required details..hope this helps..Please let me know anything else that needs to be changed/added. –  ramanujan_dirac Jul 13 '12 at 15:03
what you think happen when r=0 then? just look at your equations and think about it. what is lambda value? you can not do numerical when no numbers for symbol. post complete and correct questions. –  Robert H Jul 13 '12 at 15:50
i disagree, the specifics of his problem do not need to be stated. the fact that H and K can be solved for numerically imply that the way in which H and K are found are irrelevant as it does not affect the integral he is attempting to solve. –  Laurbert515 Jul 13 '12 at 15:56
@RobertH: extremely sorry, forgot to specify lamda, it is a parameter, assume its anything other than 0. Assuming 0 is fine, but 0 has a analytical solution, so the problem is not relevant in this case. I have been working with this equations for many days (deriving not solving), so didnt cross my mind I need to specify lamda for the solution. –  ramanujan_dirac Jul 13 '12 at 16:06

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`