Root Repulsion and Faster Solving for Very Sparse Polynomials Over $p$-adic Fields
Abstract
For any fixed field , we prove that all polynomials with exactly (resp. ) monomial terms, degree , and all coefficients having absolute value at most , can be solved over within deterministic time (resp. ) in the classical Turing model: Our underlying algorithm correctly counts the number of roots of in , and for each such root generates an approximation in with logarithmic height that converges at a rate of after steps of Newton iteration. We also prove significant speed-ups in certain settings, a minimal spacing bound of for distinct roots in , and even stronger repulsion when there are nonzero degenerate roots in : -adic distance . On the other hand, we prove that there is an explicit family of tetranomials with distinct nonzero roots in indistinguishable in their first most significant base- digits.
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