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Communication-Efficient Training Workload Balancing for Decentralized Multi-Agent Learning

Machine Learning 2024-10-22 v1 Artificial Intelligence Distributed, Parallel, and Cluster Computing Multiagent Systems Performance

Abstract

Decentralized Multi-agent Learning (DML) enables collaborative model training while preserving data privacy. However, inherent heterogeneity in agents' resources (computation, communication, and task size) may lead to substantial variations in training time. This heterogeneity creates a bottleneck, lengthening the overall training time due to straggler effects and potentially wasting spare resources of faster agents. To minimize training time in heterogeneous environments, we present a Communication-Efficient Training Workload Balancing for Decentralized Multi-Agent Learning (ComDML), which balances the workload among agents through a decentralized approach. Leveraging local-loss split training, ComDML enables parallel updates, where slower agents offload part of their workload to faster agents. To minimize the overall training time, ComDML optimizes the workload balancing by jointly considering the communication and computation capacities of agents, which hinges upon integer programming. A dynamic decentralized pairing scheduler is developed to efficiently pair agents and determine optimal offloading amounts. We prove that in ComDML, both slower and faster agents' models converge, for convex and non-convex functions. Furthermore, extensive experimental results on popular datasets (CIFAR-10, CIFAR-100, and CINIC-10) and their non-I.I.D. variants, with large models such as ResNet-56 and ResNet-110, demonstrate that ComDML can significantly reduce the overall training time while maintaining model accuracy, compared to state-of-the-art methods. ComDML demonstrates robustness in heterogeneous environments, and privacy measures can be seamlessly integrated for enhanced data protection.

Keywords

Cite

@article{arxiv.2405.00839,
  title  = {Communication-Efficient Training Workload Balancing for Decentralized Multi-Agent Learning},
  author = {Seyed Mahmoud Sajjadi Mohammadabadi and Lei Yang and Feng Yan and Junshan Zhang},
  journal= {arXiv preprint arXiv:2405.00839},
  year   = {2024}
}

Comments

This paper has been accepted for presentation at ICDCS (44th IEEE International Conference on Distributed Computing Systems). Keywords: decentralized multi-agent learning, federated learning, edge computing, heterogeneous agents, workload balancing, and communication-efficient training )

R2 v1 2026-06-28T16:13:16.423Z