English

Webster Sequences, Apportionment Problems, and Just-In-Time Sequencing

Number Theory 2021-10-12 v4

Abstract

Given a real number α(0,1)\alpha \in (0,1), we define the Webster sequence of density α\alpha to be Wα=((n1/2)/α)nNW_\alpha = (\lceil(n-1/2) / \alpha\rceil)_{n\in\mathbb{N}}, where x\lceil x \rceil is the ceiling function. It is known that if α\alpha and β\beta are irrational with α+β=1\alpha + \beta = 1, then WαW_\alpha and WβW_\beta partition N\mathbb{N}. On the other hand, an analogous result for three-part partitions does not hold: There does not exist a partition of N\mathbb{N} into sequences Wα,Wβ,WγW_\alpha, W_\beta, W_\gamma with α,β,γ\alpha, \beta, \gamma irrational. In this paper, we consider the question of how close one can come to a three-part partition of N\mathbb{N} into Webster sequences with prescribed densities α,β,γ\alpha, \beta, \gamma . We show that if α,β,γ\alpha, \beta, \gamma are irrational with α+β+γ=1\alpha + \beta +\gamma = 1, there exists a partition of N\mathbb{N} into sequences of densities α,β,γ\alpha, \beta, \gamma, in which one of the sequences is a Webster sequence and the other two are "almost" Webster sequences that are obtained from Webster sequences by perturbing some elements by at most 1. We also provide two efficient algorithms to construct such partitions. The first algorithm outputs the nnth element of each sequence in O(1)O(1) time and the second algorithm gives the assignment of the mmth positive integer to a sequence in O(1)O(1) time. We show that the results are best-possible in several respects. Moreover, we describe applications of these results to apportionment and optimal scheduling problems.

Keywords

Cite

@article{arxiv.2006.16237,
  title  = {Webster Sequences, Apportionment Problems, and Just-In-Time Sequencing},
  author = {Xiaomin Li},
  journal= {arXiv preprint arXiv:2006.16237},
  year   = {2021}
}
R2 v1 2026-06-23T16:42:37.681Z