On quantitative aspects of trace polynomials
Abstract
By the classic results of Fricke and Klein, for every word in the free group there exists a unique integer \it{trace polynomial} such that . for all . We study quantitative aspects of trace polynomials. We prove an exact formula for the leading homogeneous part of for every nontrivial cyclically reduced word . In particular, if is cyclically reduced over , and if is the number of cyclic occurrences of , then We obtain sharp general bounds for with cyclically reduced length . We also study for random positive words and for random freely reduced and random cyclically reduced words. We obtain explicit exponential upper bounds for the growth of the and norms of and exhibit examples with exponential coefficient growth at rate , where is the golden ratio. We show that for random freely reduced, random cyclically reduced and random positive words of length in , the size of grows at least quadratically in and the total bit-size of grows at least as . Hence, any algorithm computing in totally expanded form has worst-case time complexity as well as generic-case time complexity for the above models bounded below by . We also give a deterministic algorithm which computes the fully expanded polynomial in time and space , in terms of the input word length .
Keywords
Cite
@article{arxiv.2605.25265,
title = {On quantitative aspects of trace polynomials},
author = {Ilya Kapovich},
journal= {arXiv preprint arXiv:2605.25265},
year = {2026}
}
Comments
Updated version with improvements of the main results to include a quadratic support size growth and cubic total bitsize growth for f_w of random words, with consequences for lower bounds on generic-case complexity of computing f_w