General Recurrence Multidimensional Zeckendorf Representations
Abstract
We present a multidimensional generalization of Zeckendorf's Theorem (any positive integer can be written uniquely as a sum of non-adjacent Fibonacci numbers) to a large family of linear recurrences. This extends work of Anderson and Bicknell-Johnson in the multi-dimensional case when the underlying recurrence is the same as the Fibonacci one. Our extension applies to linear recurrence relations defined by vectors such that and where . Under these conditions, we prove that every integer vector in admits a unique -satisfying representation (-SR) as a linear combination of vectors, defined for every by initially by zero and standard unit vectors and then the recursion To establish this, we introduce carrying and borrowing operations that use the defining recursion to transform any representation into a -SR while preserving the underlying vector. Then, by establishing bijections with properties of scalar Positive Linear Recurrence Sequences (PLRS), we prove that these multidimensional decompositions inherit various properties, such as the number of summands exhibits Gaussian behavior and summand minimality of -SRs over all all -representations.
Cite
@article{arxiv.2510.07237,
title = {General Recurrence Multidimensional Zeckendorf Representations},
author = {Jiarui Cheng and Steven J. Miller and Sebastian Rodriguez-Labastida and Tianyu Shen and Alan Sun and Garrett Tresch},
journal= {arXiv preprint arXiv:2510.07237},
year = {2025}
}
Comments
22 pages, 4 figures