A dual-agent adversarial DRL method solves the MCLIP bi-level problem with superior efficiency and competitive quality versus baselines on synthetic and real datasets.
An End-to-End Learning Approach for Solving Capacitated Location-Routing Problems
2 Pith papers cite this work. Polarity classification is still indexing.
abstract
The capacitated location-routing problems (CLRPs) are classical problems in combinatorial optimization, which require simultaneously making location and routing decisions. In CLRPs, the complex constraints and the intricate relationships between various decisions make the problem challenging to solve. With the emergence of deep reinforcement learning (DRL), it has been extensively applied to address the vehicle routing problem and its variants, while the research related to CLRPs still needs to be explored. In this paper, we propose the DRL with heterogeneous query (DRLHQ) to solve CLRP and open CLRP (OCLRP), respectively. We are the first to propose an end-to-end learning approach for CLRPs, following the encoder-decoder structure. In particular, we reformulate the CLRPs as a markov decision process tailored to various decisions, a general modeling framework that can be adapted to other DRL-based methods. To better handle the interdependency across location and routing decisions, we also introduce a novel heterogeneous querying attention mechanism designed to adapt dynamically to various decision-making stages. Experimental results on both synthetic and benchmark datasets demonstrate superior solution quality and better generalization performance of our proposed approach over representative traditional and DRL-based baselines in solving both CLRP and OCLRP.
fields
cs.LG 2years
2026 2verdicts
UNVERDICTED 2representative citing papers
R2E-IG combines residual refined experts with instance-level gating and mixed-distribution training using dynamic weight adaptation to improve generalization of DRL solvers for vehicle routing problems.
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Adversarial Training for Robust Coverage Network under Worst-case Facility Losses
A dual-agent adversarial DRL method solves the MCLIP bi-level problem with superior efficiency and competitive quality versus baselines on synthetic and real datasets.
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Towards Generalization-Oriented Models for Vehicle Routing Problems with Mixture-of-Experts
R2E-IG combines residual refined experts with instance-level gating and mixed-distribution training using dynamic weight adaptation to improve generalization of DRL solvers for vehicle routing problems.