English

Efficiently Computing Real Roots of Sparse Polynomials

Symbolic Computation 2017-04-25 v1

Abstract

We propose an efficient algorithm to compute the real roots of a sparse polynomial fR[x]f\in\mathbb{R}[x] having kk non-zero real-valued coefficients. It is assumed that arbitrarily good approximations of the non-zero coefficients are given by means of a coefficient oracle. For a given positive integer LL, our algorithm returns disjoint disks Δ1,,ΔsC\Delta_{1},\ldots,\Delta_{s}\subset\mathbb{C}, with s<2ks<2k, centered at the real axis and of radius less than 2L2^{-L} together with positive integers μ1,,μs\mu_{1},\ldots,\mu_{s} such that each disk Δi\Delta_{i} contains exactly μi\mu_{i} roots of ff counted with multiplicity. In addition, it is ensured that each real root of ff is contained in one of the disks. If ff has only simple real roots, our algorithm can also be used to isolate all real roots. The bit complexity of our algorithm is polynomial in kk and logn\log n, and near-linear in LL and τ\tau, where 2τ2^{-\tau} and 2τ2^{\tau} constitute lower and upper bounds on the absolute values of the non-zero coefficients of ff, and nn is the degree of ff. For root isolation, the bit complexity is polynomial in kk and logn\log n, and near-linear in τ\tau and logσ1\log\sigma^{-1}, where σ\sigma denotes the separation of the real roots.

Keywords

Cite

@article{arxiv.1704.06979,
  title  = {Efficiently Computing Real Roots of Sparse Polynomials},
  author = {Gorav Jindal and Michael Sagraloff},
  journal= {arXiv preprint arXiv:1704.06979},
  year   = {2017}
}
R2 v1 2026-06-22T19:25:05.114Z