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Main Author: Davies-Peck, Peter
Format: Preprint
Published: 2026
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Online Access:https://arxiv.org/abs/2605.13264
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author Davies-Peck, Peter
author_facet Davies-Peck, Peter
contents The classic lower bound of Kuhn, Moscibroda and Wattenhofer [JACM 2016] states that approximate maximum matching and approximate vertex cover (among other problems) in the LOCAL model require $Ω(\min\{\sqrt{\frac{\log n}{\log\log n}}, \frac{\log Δ}{\log\log Δ}\})$ rounds, for any polylogarithmic or smaller approximation ratio. As a function of $Δ$, this complexity was subsequently matched for constant-approximate weighted vertex cover [Bar-Yehuda, Censor-Hillel and Schwartzman, JACM 2017] and constant-approximate maximum matching [Bar-Yehuda, Censor-Hillel, Ghaffari and Schwartzman, PODC 2017]. One might expect, therefore, that the true complexity should be $Θ(\frac{\log Δ}{\log\log Δ})$, and the $n$-dependent term in the lower bound is just an artefact of the proof method. We show that this is not the case, and a term dependent on $n$ is in fact required. Specifically, we show randomized algorithms for $2+\varepsilon$-approximate maximum matching and approximate (weighted) minimum vertex cover taking $O(\frac{\log n}{\log^2 \log n})$ rounds. Our algorithms are based on a novel graph decomposition result generalizing the method of Miller, Peng and Xu [SPAA 2013], which we use to reduce the `effective' degree of high-degree graphs. We expect that this decomposition may be of further use for other problems.
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publishDate 2026
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spellingShingle Distributed Approximate Maximum Matching and Minimum Vertex Cover via Generalized Graph Decomposition
Davies-Peck, Peter
Data Structures and Algorithms
The classic lower bound of Kuhn, Moscibroda and Wattenhofer [JACM 2016] states that approximate maximum matching and approximate vertex cover (among other problems) in the LOCAL model require $Ω(\min\{\sqrt{\frac{\log n}{\log\log n}}, \frac{\log Δ}{\log\log Δ}\})$ rounds, for any polylogarithmic or smaller approximation ratio. As a function of $Δ$, this complexity was subsequently matched for constant-approximate weighted vertex cover [Bar-Yehuda, Censor-Hillel and Schwartzman, JACM 2017] and constant-approximate maximum matching [Bar-Yehuda, Censor-Hillel, Ghaffari and Schwartzman, PODC 2017]. One might expect, therefore, that the true complexity should be $Θ(\frac{\log Δ}{\log\log Δ})$, and the $n$-dependent term in the lower bound is just an artefact of the proof method. We show that this is not the case, and a term dependent on $n$ is in fact required. Specifically, we show randomized algorithms for $2+\varepsilon$-approximate maximum matching and approximate (weighted) minimum vertex cover taking $O(\frac{\log n}{\log^2 \log n})$ rounds. Our algorithms are based on a novel graph decomposition result generalizing the method of Miller, Peng and Xu [SPAA 2013], which we use to reduce the `effective' degree of high-degree graphs. We expect that this decomposition may be of further use for other problems.
title Distributed Approximate Maximum Matching and Minimum Vertex Cover via Generalized Graph Decomposition
topic Data Structures and Algorithms
url https://arxiv.org/abs/2605.13264