# How to numerically compute nonlinear polynomials efficiently and accurately?

(I'm not sure whether I should post this problem on this site or on the math site. Please feel free to migrate this post if necessary.)

My problem at hand is that given a value of `k` I'd like to numerically compute a rational function of nonlinear polynomials in `k` which looks like the following: (sorry I don't know how to typeset equations here...) where `{a_0, ..., a_N; b_0, ..., b_N}` are complex constants, `{u_0, ..., u_N, v_0, ..., v_N}` are real constants and `i` is the imaginary number. I learned from Numerical Recipes that there are whole bunch of ways to compute polynomials quickly, in the meanwhile keeping the rounding error small enough, if all coefficients were constant. But I do not think those ideas are useful in my case since the exponential prefactors also depend on `k`.

Currently I calculate it in a brute force way in C with `complex.h` (this is just a pseudo code):

``````double complex function(double k)
{
return (a_0+a_1*cexp(I*u_1*k)*k+a_2*cexp(I*u_2*k)*k*k+...)/(b_0+b_1*cexp(I*v_1*k)*k+v_2*cexp(I*v_2*k)*k*k+...);
}
``````

However when the number of calls of `function` increases (because this is just a part of my real calculation), it is very slow and inaccurate (only 6 valid digits). I appreciate any comments and/or suggestions.

-
Horner's method? `a0 + k * (a_1*cexp(I*u_1*k) + k * (a_2*cexp(I*u_2*k) + k * ... )...))` –  zch Sep 19 '13 at 23:08
What are the expected ranges of `k` and `N`? –  rob mayoff Sep 19 '13 at 23:08
@zch, yes I've been suggested Horner's rule. But I thought it's faster simply because one could store all constant coefficients in an array and multiply them using `for` loop, isn't it? Will test it later though. I just wanna make sure whether there's any similar situation (hopefully an algorithm :P) that has been analyzed thoroughly but I don't know yet. Thanks anyway! –  Leo Fang Sep 20 '13 at 1:12
@rob, `k` is in a wide range [-1000,1000] while `N` is from 1 to 20 according to the cases at hand. –  Leo Fang Sep 20 '13 at 1:14
@LeoFang it can be faster anyway. Without Horner you multiply `*k` about 200 times (for `N ~= 20`), with Horner it's about 20. –  zch Sep 20 '13 at 10:45

Although I haven't done any test yet, I would agree with your guess that factoring out k saves not too much (which is basically Horner's rule proposed by @zch in the comment). `u_i`'s and `v_i`'s are all constant, but `k` is going to be changed each run. `e^(i*u_i*k)` is indeed the same as `(e^(i*u_i))^k`, but `k` is a real number, not just an integer, so I don't think computing `(e^(i*u_i))^k`, which is done in C by using `cpow(cexp(I*u_i),k)`, is a good idea. –  Leo Fang Sep 20 '13 at 1:23
BTW, I checked that `complex.h` does work with double precision (and even beyond double) providing the functions computed are not too complicated, so I think the only reasonable guess is that those nonlinearities in my function increase the rounding error dramatically. –  Leo Fang Sep 20 '13 at 1:24