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Reweighted Spectral Partitioning Works: A Simple Algorithm for Vertex Separators in Special Graph Classes

February 23, 2026

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📝 Original Info

Title: Reweighted Spectral Partitioning Works: A Simple Algorithm for Vertex Separators in Special Graph Classes
ArXiv ID: 2506.01228
Date: 2025-06-02
Authors: Jack Spalding-Jamieson

📝 Abstract

We establish that a simple polynomial-time algorithm that we call reweighted spectral partitioning obtains small 2/3-balanced vertex-separators for a number of graph classes, including $O(\sqrt{n})$-sized separators for planar graphs, $O(\min\{(\log g)^2,\logΔ\}\cdot\sqrt{gn})$-sized separators for genus-$g$ graphs of maximum degree $Δ$, and $O(\min\{\log h,\sqrt{\logΔ}\}(h\log h\log\log h)\sqrt{n})$-sized separators for $K_h$-minor-free graphs of maximum degree $Δ$. To accomplish this, we first obtain a refined form of a Cheeger-style inequality relating the vertex expansion of a graph and the solution to a semidefinite program defined over the graph. Then, to obtain the guarantees for specific graph classes, we derive direct bounds on the value of the semidefinite program. We also obtain several other results of independent interest, including an improved separator theorem for the intersection graphs of $d$-dimensional balls with bounded ply, a new bound on the Fiedler value of genus-$g$ graphs, and a new "spectral" proof of the planar separator theorem.

💡 Deep Analysis

This research explores the key findings and methodology presented in the paper: Reweighted Spectral Partitioning Works: A Simple Algorithm for Vertex Separators in Special Graph Classes.

We establish that a simple polynomial-time algorithm that we call reweighted spectral partitioning obtains small 2/3-balanced vertex-separators for a number of graph classes, including $O(\sqrt{n})$-sized separators for planar graphs, $O(\min\{(\log g)^2,\logΔ\}\cdot\sqrt{gn})$-sized separators for genus-$g$ graphs of maximum degree $Δ$, and $O(\min\{\log h,\sqrt{\logΔ}\}(h\log h\log\log h)\sqrt{n})$-sized separators for $K_h$-minor-free graphs of maximum degree $Δ$. To accomplish this, we first obtain a refined form of a Cheeger-style inequality relating the vertex expansion of a graph and the solution to a semidefinite program defined over the graph. Then, to obtain the guarantees for specific graph classes, we derive direct bounds on the value of the semidefinite program. We also obtain several other results of independent interest, including an improved separator theorem for the intersection graphs of $d$-dimensional balls with bounded ply, a new bound on the Fiedler value of g

📄 Full Content

We establish that a simple polynomial-time algorithm that we call reweighted spectral partitioning obtains small 2/3-balanced vertex-separators for a number of graph classes, including $O(\sqrt{n})$-sized separators for planar graphs, $O(\min\{(\log g)^2,\logΔ\}\cdot\sqrt{gn})$-sized separators for genus-$g$ graphs of maximum degree $Δ$, and $O(\min\{\log h,\sqrt{\logΔ}\}(h\log h\log\log h)\sqrt{n})$-sized separators for $K_h$-minor-free graphs of maximum degree $Δ$. To accomplish this, we first obtain a refined form of a Cheeger-style inequality relating the vertex expansion of a graph and the solution to a semidefinite program defined over the graph. Then, to obtain the guarantees for specific graph classes, we derive direct bounds on the value of the semidefinite program. We also obtain several other results of independent interest, including an improved separator theorem for the intersection graphs of $d$-dimensional balls with bounded ply, a new bound on the Fiedler value of genus-$g$ graphs, and a new "spectral" proof of the planar separator theorem.

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