Fast Approximate Polynomial Multipoint Evaluation and Applications

Abstract

It is well known that, using fast algorithms for polynomial multiplication and division, evaluation of a polynomial F ∈ C[x] of degree n at n complex-valued points can be done with O(n) exact field operations in C, where O(·) means that we omit polylogarithmic factors. We complement this result by an analysis of approximate multipoint evaluation of F to a precision of L bits after the binary point and prove a bit complexity of O(n(L + τ+ nΓ)), where 2τ and 2Γ, with τ, Γ∈ N 1, are bounds on the magnitude of the coefficients of F and the evaluation points, respectively. In particular, in the important case where the precision demand dominates the other input parameters, the complexity is soft-linear in n and L. Our result on approximate multipoint evaluation has some interesting consequences on the bit complexity of further approximation algorithms which all use polynomial evaluation as a key subroutine. Of these applications, we discuss in detail an algorithm for polynomial interpolation and for computing a Taylor shift of a polynomial. Furthermore, our result can be used to derive improved complexity bounds for algorithms to refine isolating intervals for the real roots of a polynomial. For all of the latter algorithms, we derive near-optimal running times.