English

Root Repulsion and Faster Solving for Very Sparse Polynomials Over $p$-adic Fields

Number Theory 2021-07-21 v1 Computational Complexity

Abstract

For any fixed field K ⁣ ⁣{Q2,Q3,Q5,}K\!\in\!\{\mathbb{Q}_2,\mathbb{Q}_3,\mathbb{Q}_5, \ldots\}, we prove that all polynomials f ⁣ ⁣Z[x]f\!\in\!\mathbb{Z}[x] with exactly 33 (resp. 22) monomial terms, degree dd, and all coefficients having absolute value at most HH, can be solved over KK within deterministic time log7+o(1)(dH)\log^{7+o(1)}(dH) (resp. log2+o(1)(dH)\log^{2+o(1)}(dH)) in the classical Turing model: Our underlying algorithm correctly counts the number of roots of ff in KK, and for each such root generates an approximation in Q\mathbb{Q} with logarithmic height O(log3(dH))O(\log^3(dH)) that converges at a rate of O ⁣((1/p)2i)O\!\left((1/p)^{2^i}\right) after ii steps of Newton iteration. We also prove significant speed-ups in certain settings, a minimal spacing bound of pO(plogp2(dH)logd)p^{-O(p\log^2_p(dH)\log d)} for distinct roots in Cp\mathbb{C}_p, and even stronger repulsion when there are nonzero degenerate roots in Cp\mathbb{C}_p: pp-adic distance pO(logp(dH))p^{-O(\log_p(dH))}. On the other hand, we prove that there is an explicit family of tetranomials with distinct nonzero roots in Zp\mathbb{Z}_p indistinguishable in their first Ω(dlogpH)\Omega(d\log_p H) most significant base-pp digits.

Keywords

Cite

@article{arxiv.2107.09173,
  title  = {Root Repulsion and Faster Solving for Very Sparse Polynomials Over $p$-adic Fields},
  author = {J. Maurice Rojas and Yuyu Zhu},
  journal= {arXiv preprint arXiv:2107.09173},
  year   = {2021}
}

Comments

36 pages, 3 figures, submitted to a journal for publication. A much shorter preliminary version appeared as an extended abstract at ISSAC 2021

R2 v1 2026-06-24T04:20:35.961Z