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Main Authors: Liu, Ya, Liu, Junbin, Ma, Wing-Kin, Konar, Aritra
Format: Preprint
Published: 2025
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Online Access:https://arxiv.org/abs/2511.11451
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author Liu, Ya
Liu, Junbin
Ma, Wing-Kin
Konar, Aritra
author_facet Liu, Ya
Liu, Junbin
Ma, Wing-Kin
Konar, Aritra
contents Given an undirected graph and a size parameter $k$, the Densest $k$-Subgraph (D$k$S) problem extracts the subgraph on $k$ vertices with the largest number of induced edges. While D$k$S is NP--hard and difficult to approximate, penalty-based continuous relaxations of the problem have recently enjoyed practical success for real-world instances of D$k$S. In this work, we propose a scalable and exact continuous penalization approach for D$k$S using the error bound principle, which enables the design of suitable penalty functions. Notably, we develop new theoretical guarantees ensuring that both the global and local optima of the penalized problem match those of the original problem. The proposed penalized reformulation enables the use of first-order continuous optimization methods. In particular, we develop a non-convex proximal gradient algorithm, where the non-convex proximal operator can be computed in closed form, resulting in low per-iteration complexity. We also provide convergence analysis of the algorithm. Experiments on large-scale instances of the D$k$S problem and one of its variants, the Densest ($k_1, k_2$) Bipartite Subgraph (D$k_1k_2$BS) problem, demonstrate that our method achieves a favorable balance between computation cost and solution quality.
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id arxiv_https___arxiv_org_abs_2511_11451
institution arXiv
publishDate 2025
record_format arxiv
spellingShingle A Scalable and Exact Relaxation for Densest $k$-Subgraph via Error Bounds
Liu, Ya
Liu, Junbin
Ma, Wing-Kin
Konar, Aritra
Signal Processing
Given an undirected graph and a size parameter $k$, the Densest $k$-Subgraph (D$k$S) problem extracts the subgraph on $k$ vertices with the largest number of induced edges. While D$k$S is NP--hard and difficult to approximate, penalty-based continuous relaxations of the problem have recently enjoyed practical success for real-world instances of D$k$S. In this work, we propose a scalable and exact continuous penalization approach for D$k$S using the error bound principle, which enables the design of suitable penalty functions. Notably, we develop new theoretical guarantees ensuring that both the global and local optima of the penalized problem match those of the original problem. The proposed penalized reformulation enables the use of first-order continuous optimization methods. In particular, we develop a non-convex proximal gradient algorithm, where the non-convex proximal operator can be computed in closed form, resulting in low per-iteration complexity. We also provide convergence analysis of the algorithm. Experiments on large-scale instances of the D$k$S problem and one of its variants, the Densest ($k_1, k_2$) Bipartite Subgraph (D$k_1k_2$BS) problem, demonstrate that our method achieves a favorable balance between computation cost and solution quality.
title A Scalable and Exact Relaxation for Densest $k$-Subgraph via Error Bounds
topic Signal Processing
url https://arxiv.org/abs/2511.11451