I'm dealing with the problem of accurately calculating the modified Bessel function of zero-th order I0 in CUDA.

For a long time, I have been using a rational Chebyshev approximation according to the paper

J.M. Blair, "Rational Chebyshev approximations for the modified Bessel functions I_0(x) and I_1(x)", Math. Comput., vol. 28, n. 126, pp. 581-583, Apr. 1974.

which, as compared to the result provided by Matlab, gives an average error of the order of 1e-29. Unfortunately, this seemingly high accuracy is not anymore enough for a new application I'm working on.

Matlab uses the Fortran routines developed by D.E. Amos

Amos, D.E., "A Subroutine Package for Bessel Functions of a Complex Argument and Nonnegative Order," Sandia National Laboratory Report, SAND85-1018, May, 1985.

Amos, D.E., "A Portable Package for Bessel Functions of a Complex Argument and Nonnegative Order," Trans. Math. Software, 1986.

which are available for download from the netlib/amos website.

There are ways to use those Fortran routines in a C/C++ code by compiling them in a library file and then using a C/C++ wrapper (see for example netlib_wrapping). I'm wondering if there is any means to make device functions out of those Fortran routines to be then called by a CUDA kernel).

**MORE DETAILS ON THE PROBLEM**

I have two codes, one written in Matlab and one in CUDA. Both operate on three steps:

1) *Scaling by the modified Bessel function I0 and zero padding of data*;

2) *FFT*;

3) *Interpolation*.

I'm comparing both with an "exact" result: As output of step 3), Matlab gives a relative root mean square error of 1e-10 % while CUDA of 1e-2%, so I started investigating why.

The root mean square difference between the first step of the two codes, namely `100*sqrt(sum(abs(U_Matlab_step_1-U_CUDA_step_1).^2))/sqrt(sum(abs(U_Matlab_step_1).^2))`

, is `0%`

(`mean(mean(abs(U_Matlab-U_CUDA)))=6e-29`

instead) so I would say it is good. Unfortunately, when I go to step 2, the error raises to `2e-4%`

. Finally, if I feed step 2) of CUDA with the output of step 1) of Matlab, then the rms error of step 2) becomes `1e-14%`

, which makes me think that a source of inaccuracy is due to the first step, namely, the calculation of the modified Bessel function.

**FOR INTERESTING DEVELOPMENTS OF THIS DISCUSSION**

Have a look at the NVIDIA Developer Zone Forum

`mean(mean(abs(U_CUDA-U_Matlab)))`

and I get`6.7036920e-029`

as an answer. I need such a high accuracy as I'm implementing a 2D Non-Uniform FFT routine in CUDA. I have a Matlab routine which is much more accurate than the one I have written in CUDA, so I would like first to understand the reason of the loss of accuracy (and the calculation of the Bessel function is one of the reasons) as well as to improve the results provided by CUDA. – JackOLantern Jan 2 '13 at 14:54