保守和风险意识离线多代理强化学习

IF 8 1区计算机科学 Q1 TELECOMMUNICATIONS IEEE Transactions on Cognitive Communications and Networking Pub Date : 2024-11-14 DOI:10.1109/TCCN.2024.3499357

Eslam Eldeeb;Houssem Sifaou;Osvaldo Simeone;Mohammad Shehab;Hirley Alves

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引用次数: 0

摘要

强化学习（RL）已被广泛应用于下一代无线网络等复杂工程系统的控制和优化。采用RL的一个重要挑战是需要直接访问物理环境。这种限制在多智能体系统中尤为严重，因为传统的多智能体强化学习（MARL）需要在训练过程中与环境进行大量协调的在线交互。当只有离线数据可用时，由于在训练期间缺乏探索所带来的认知不确定性，在线MARL方案的直接应用通常会失败。在这项工作中，我们提出了一种离线MARL方案，该方案集成了分布式强化学习和保守q学习，以解决环境固有的任意不确定性和使用离线数据产生的认知不确定性。我们探索独立和联合学习策略。提出的MARL方案，即多智能体保守分位数回归，解决了一般的风险敏感设计标准，并应用于无人机网络的轨迹规划问题，显示了其优势。

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Conservative and Risk-Aware Offline Multi-Agent Reinforcement Learning

Reinforcement learning (RL) has been widely adopted for controlling and optimizing complex engineering systems such as next-generation wireless networks. An important challenge in adopting RL is the need for direct access to the physical environment. This limitation is particularly severe in multi-agent systems, for which conventional multi-agent reinforcement learning (MARL) requires a large number of coordinated online interactions with the environment during training. When only offline data is available, a direct application of online MARL schemes would generally fail due to the epistemic uncertainty entailed by the lack of exploration during training. In this work, we propose an offline MARL scheme that integrates distributional RL and conservative Q-learning to address the environment's inherent aleatoric uncertainty and the epistemic uncertainty arising from the use of offline data. We explore both independent and joint learning strategies. The proposed MARL scheme, referred to as multi-agent conservative quantile regression, addresses general risk-sensitive design criteria and is applied to the trajectory planning problem in drone networks, showcasing its advantages.

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来源期刊

IEEE Transactions on Cognitive Communications and Networking Computer Science-Artificial Intelligence

CiteScore

15.50

自引率

7.00%

发文量

108

期刊介绍： The IEEE Transactions on Cognitive Communications and Networking (TCCN) aims to publish high-quality manuscripts that push the boundaries of cognitive communications and networking research. Cognitive, in this context, refers to the application of perception, learning, reasoning, memory, and adaptive approaches in communication system design. The transactions welcome submissions that explore various aspects of cognitive communications and networks, focusing on innovative and holistic approaches to complex system design. Key topics covered include architecture, protocols, cross-layer design, and cognition cycle design for cognitive networks. Additionally, research on machine learning, artificial intelligence, end-to-end and distributed intelligence, software-defined networking, cognitive radios, spectrum sharing, and security and privacy issues in cognitive networks are of interest. The publication also encourages papers addressing novel services and applications enabled by these cognitive concepts.