基于解释驱动信任的物联网设备联邦学习调度策略的增强型动态深度Q-Network

IF 7.2 1区计算机科学 Q1 COMPUTER SCIENCE, ARTIFICIAL INTELLIGENCE

Knowledge-Based Systems Pub Date : 2025-04-26 DOI:10.1016/j.knosys.2025.113574

Gaith Rjoub , Hanae Elmekki , Jamal Bentahar , Witold Pedrycz , Sofian Kassaymeh , Shahed Bassam Almobydeen , Rachida Dssouli

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引用次数: 0

摘要

物联网（IoT）和边缘计算的最新进展导致物联网设备数量的快速增长，在网络边缘产生大量数据。在这些设备上有效地调度任务，特别是在联邦学习（FL）环境中严格的延迟限制下，带来了巨大的挑战。在本文中，我们提出了一种新的信任能量感知调度框架，专门为延迟受限的联邦边缘计算场景设计。我们的创新策略将动态深度q -网络（Dynamic- dqn）强化学习与局部可解释模型不可知论解释（LIME）相结合，实现了具有可解释性和透明度的设备可靠性的动态、实时评估。这种组合方法允许框架智能地将任务分配给物联网设备，明确优化减少延迟，提高能源效率，增强系统可靠性。广泛的实验评估证实，我们提出的方法大大优于传统的强化学习和启发式调度算法，证明了延迟的显著减少，卓越的能量管理和改进的可扩展性。这些结果强调了我们的框架在解决关键FL挑战方面的稳健性和实际有效性。

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Enhanced Dynamic Deep Q-Network for Federated Learning scheduling policies on IoT devices using explanation-driven trust

Recent advancements in Internet of Things (IoT) and edge computing have led to rapid growth in the number of IoT devices generating extensive volumes of data at the network edge. Efficiently scheduling tasks on these devices, particularly under strict latency constraints in federated learning (FL) environments, poses substantial challenges. In this paper, we propose a novel trust-energy-aware scheduling framework specifically designed for latency-constrained federated edge computing scenarios. Our innovative strategy integrates Dynamic Deep Q-Network (Dynamic-DQN) reinforcement learning with Local Interpretable Model-agnostic Explanations (LIME), enabling dynamic, real-time assessment of device trustworthiness with interpretability and transparency. This combined approach allows the framework to intelligently allocate tasks to IoT devices, explicitly optimizing for reduced latency, improved energy efficiency, and enhanced system reliability. Extensive experimental evaluations confirm that our proposed method substantially outperforms conventional reinforcement learning and heuristic scheduling algorithms, demonstrating significant reductions in latency, superior energy management, and improved scalability. These results underscore the robustness and practical effectiveness of our framework in addressing critical FL challenges.

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来源期刊

Knowledge-Based Systems 工程技术-计算机：人工智能

CiteScore

14.80

自引率

12.50%

发文量

1245

审稿时长

7.8 months

期刊介绍： Knowledge-Based Systems, an international and interdisciplinary journal in artificial intelligence, publishes original, innovative, and creative research results in the field. It focuses on knowledge-based and other artificial intelligence techniques-based systems. The journal aims to support human prediction and decision-making through data science and computation techniques, provide a balanced coverage of theory and practical study, and encourage the development and implementation of knowledge-based intelligence models, methods, systems, and software tools. Applications in business, government, education, engineering, and healthcare are emphasized.