English

On Positivity and Minimality for Second-Order Holonomic Sequences

Number Theory 2020-07-27 v1 Discrete Mathematics

Abstract

An infinite sequence unnN\langle{u_n}\rangle_{n\in\mathbb{N}} of real numbers is holonomic (also known as P-recursive or P-finite) if it satisfies a linear recurrence relation with polynomial coefficients. Such a sequence is said to be positive if each un0u_n \geq 0, and minimal if, given any other linearly independent sequence vnnN\langle{v_n}\rangle_{n \in\mathbb{N}} satisfying the same recurrence relation, the ratio un/vnu_n/v_n converges to 00. In this paper, we focus on holonomic sequences satisfying a second-order recurrence g3(n)un=g2(n)un1+g1(n)un2g_3(n)u_n = g_2(n)u_{n-1} + g_1(n)u_{n-2}, where each coefficient g3,g2,g1Q[n]g_3, g_2,g_1 \in \mathbb{Q}[n] is a polynomial of degree at most 11. We establish two main results. First, we show that deciding positivity for such sequences reduces to deciding minimality. And second, we prove that deciding minimality is equivalent to determining whether certain numerical expressions (known as periods, exponential periods, and period-like integrals) are equal to zero. Periods and related expressions are classical objects of study in algebraic geometry and number theory, and several established conjectures (notably those of Kontsevich and Zagier) imply that they have a decidable equality problem, which in turn would entail decidability of Positivity and Minimality for a large class of second-order holonomic sequences.

Keywords

Cite

@article{arxiv.2007.12282,
  title  = {On Positivity and Minimality for Second-Order Holonomic Sequences},
  author = {George Kenison and Oleksiy Klurman and Engel Lefaucheux and Florian Luca and Pieter Moree and Joël Ouaknine and Markus A. Whiteland and James Worrell},
  journal= {arXiv preprint arXiv:2007.12282},
  year   = {2020}
}

Comments

38 pages

R2 v1 2026-06-23T17:21:51.238Z