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Bibliographic Details
Main Authors: Jones, Michael A., Ohlinger, Brittany, Wilson, Jennifer
Format: Preprint
Published: 2025
Subjects:
Online Access:https://arxiv.org/abs/2512.20686
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author Jones, Michael A.
Ohlinger, Brittany
Wilson, Jennifer
author_facet Jones, Michael A.
Ohlinger, Brittany
Wilson, Jennifer
contents Divisor methods are well known to satisfy house monotonicity, which allows representative seats to be allocated sequentially. We focus on stationary divisor methods defined by a rounding cutpoint $c \in [0,1]$. For such methods with integer-valued votes, the resulting apportionment sequences are periodic. Restricting attention to two-party allocations, we characterize the set of possible sequences and establish a connection between the lexicographical ordering of these sequences and the parameter $c$. We then show how sequences for all pairs of parties can be systematically extended to the $n$-party setting. Further, we determine the number of distinct sequences in the $n$-party problem for all $c$. Our approach offers a refined perspective on size bias: rather than viewing large parties as simply receiving more seats, we show that they instead obtain their seats earlier in the apportionment sequence. Of particular interest is a new relationship we uncover between the sequences generated by the smallest divisor (Adams) and greatest divisor (D'Hondt or Jefferson) methods.
format Preprint
id arxiv_https___arxiv_org_abs_2512_20686
institution arXiv
publishDate 2025
record_format arxiv
spellingShingle Sequential Apportionment from Stationary Divisor Methods
Jones, Michael A.
Ohlinger, Brittany
Wilson, Jennifer
General Mathematics
Cryptography and Security
91B32 91B12 91F10
Divisor methods are well known to satisfy house monotonicity, which allows representative seats to be allocated sequentially. We focus on stationary divisor methods defined by a rounding cutpoint $c \in [0,1]$. For such methods with integer-valued votes, the resulting apportionment sequences are periodic. Restricting attention to two-party allocations, we characterize the set of possible sequences and establish a connection between the lexicographical ordering of these sequences and the parameter $c$. We then show how sequences for all pairs of parties can be systematically extended to the $n$-party setting. Further, we determine the number of distinct sequences in the $n$-party problem for all $c$. Our approach offers a refined perspective on size bias: rather than viewing large parties as simply receiving more seats, we show that they instead obtain their seats earlier in the apportionment sequence. Of particular interest is a new relationship we uncover between the sequences generated by the smallest divisor (Adams) and greatest divisor (D'Hondt or Jefferson) methods.
title Sequential Apportionment from Stationary Divisor Methods
topic General Mathematics
Cryptography and Security
91B32 91B12 91F10
url https://arxiv.org/abs/2512.20686