English

A complexity chasm for solving univariate sparse polynomial equations over $p$-adic fields

Number Theory 2021-06-08 v4 Computational Complexity Symbolic Computation

Abstract

We reveal a complexity chasm, separating the trinomial and tetranomial cases, for solving univariate sparse polynomial equations over certain local fields. First, for any fixed field K{Q2,Q3,Q5,}K\in\{\mathbb{Q}_2,\mathbb{Q}_3,\mathbb{Q}_5,\ldots\}, we prove that any polynomial fZ[x]f\in\mathbb{Z}[x] with exactly 33 monomial terms, degree dd, and all coefficients having absolute value at most HH, can be solved over KK in deterministic time O(logO(1)(dH))O(\log^{O(1)}(dH)) in the classical Turing model. (The best previous algorithms were of complexity exponential in logd\log d, even for just counting roots in Qp\mathbb{Q}_p.) In particular, our algorithm generates approximations in Q\mathbb{Q} with bit-length O(logO(1)(dH))O(\log^{O(1)}(dH)) to all the roots of ff in KK, and these approximations converge quadratically under Newton iteration. On the other hand, we give a unified family of tetranomials requiring Ω(dlogH)\Omega(d\log H) digits to distinguish the base-pp expansions of their roots in KK.

Keywords

Cite

@article{arxiv.2003.00314,
  title  = {A complexity chasm for solving univariate sparse polynomial equations over $p$-adic fields},
  author = {J. Maurice Rojas and Yuyu Zhu},
  journal= {arXiv preprint arXiv:2003.00314},
  year   = {2021}
}

Comments

19 pages, 3 figures. This version contains an Appendix missing from the ISSAC 2021 conference version, as well as some corrections and improvements

R2 v1 2026-06-23T13:58:53.486Z