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arxiv: 2506.06258 · v1 · pith:FYJW7W7Pnew · submitted 2025-06-06 · 🧮 math.OC

PDHCG: A Scalable First-Order Method for Large-Scale Competitive Market Equilibrium Computation

classification 🧮 math.OC
keywords equilibriummarketlarge-scaleproblemsalgorithmcompetitivecomputationalframework
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Large-scale competitive market equilibrium problems arise in a wide range of important applications, including economic decision-making and intelligent manufacturing. Traditional solution methods, such as interior-point algorithms and certain projection-based approaches, often fail to scale effectively to large problem instances. In this paper, we propose an efficient computational framework that integrates the primal-dual hybrid conjugate gradient (PDHCG) algorithm with GPU-based parallel computing to solve large-scale Fisher market equilibrium problems. By exploiting the underlying mathematical structure of the problem, we establish a theoretical guarantee of linear convergence for the proposed algorithm. Furthermore, the proposed framework can be extended to solve large-scale Arrow-Debreu market equilibrium problems through a fixed-point iteration scheme. Extensive numerical experiments conducted on GPU platforms demonstrate substantial improvements in computational efficiency, significantly expanding the practical solvable scale and applicability of market equilibrium models.

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  1. D-PDLP: Scaling PDLP to Distributed Multi-GPU Systems

    math.OC 2026-01 unverdicted novelty 5.0

    D-PDLP is the first distributed multi-GPU framework for PDLP that uses 2D grid partitioning of the constraint matrix plus nonzero-aware and random-permutation strategies to scale PDHG iterations with low overhead and ...