How can I integrate an equation including bessel functions numerically from "0" to "infinity" in Fortran or/and C? I did in matlab, but it's not true for larger inputs and after a specific values , the bessel functions give completely wrong results(there is a restriction in Matlab)

What is it, that you have tried already? – rubenvb Mar 19 '15 at 13:33

yes , I tried in matlab, but I can't reach the exact results in matlab, I have an equation, but the website do not allow me to upload the image of that. – U3F Mar 19 '15 at 13:36
You can pretty much google and find lots of Bessel functions implemented in C already.
http://www.atnf.csiro.au/computing/software/gipsy/sub/bessel.c
http://jeanpierre.moreau.pagespersoorange.fr/c_bessel.html
https://msdn.microsoft.com/enus/library/h7zkk1bz.aspx
In the end, these use the built in types and will be limited to the ranges they can represent (just as MATLAB is). At best, expect 15 digits of precision using double precision floating point representation. So, for large numbers, they will appear to be rounded. eg. 1237846464123450000000000.00000
And, of course, others on Stack Overflow have looked into it.

No need for external libraries. They are part of standard C and standard Fortran. – Vladimir F Mar 19 '15 at 13:39

The request is vague but talked about the exact results being wrong. I thought he might be seeking to implement/use arbitrary precision numbers (like gmplib.org ) and utilize them in a homespun bessel functions to achieve "exact" results and would need source for some of the built in functions. – LawfulEvil Mar 19 '15 at 13:46

after a specific larger inputs in matlab , the bessel functions can't converge to a constant value, and the results are going to be completely wrong after that specific value. – U3F Mar 19 '15 at 13:51


if you know how to write you own, do it. don't use external libs, you have no idea about the convergence or numerical stability. grab Ab & Stegun and start hacking. – μολὼν.λαβέ Feb 26 '16 at 5:27
There's a large number of analytic results for various integrals of the Bessel functions (see DLMF, Sect. 10.22), including definite integrals over precisely this range. You'd be much better off, and almost certainly faster and more accurate, trying hard to recast your expression into something that's integrable and using an exact result.