Multi-Agent Reinforcement Learning for the Energy Optimization of Cyber-Physical Production Systems

Jupiter Bakakeu, Dominik Kißkalt, J. Franke, S. Baer, H. Klos, J. Peschke
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引用次数: 7

Abstract

The paper proposes an artificial intelligence-based solution for the efficient operation of a heterogeneous cluster of flexible manufacturing machines with energy generation and storage capabilities in an electricity micro-grid featuring high volatility of electricity prices. The problem of finding the optimal control policy is first formulated as a game-theoretic sequential decision-making problem under uncertainty, where at every time step the uncertainty is characterized by future weather-dependent energy prices, high demand fluctuation, as well as random unexpected disturbances on the factory floor. Because of the parallel interaction of the machines with the grid, the local viewpoints of an agent are non-stationary and non-Markovian. Therefore, traditional methods such as standard reinforcement learning approaches that learn a specialized policy for a single machine are not applicable. To address this problem, we propose a multi-agent actor-critic method that takes into account the policies of other participants to achieve explicit coordination between a large numbers of actors. We show the strength of our approach in mixed cooperative and competitive scenarios where different production machines were able to discover different coordination strategies in order to increase the energy efficiency of the whole factory floor.
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面向信息物理生产系统能量优化的多智能体强化学习
针对具有发电和储能能力的异构柔性制造机群在电价波动较大的微电网中的高效运行问题,提出了一种基于人工智能的解决方案。寻找最优控制策略的问题首先被描述为不确定性下的博弈论顺序决策问题,其中在每个时间步长的不确定性特征是未来天气相关的能源价格,高需求波动以及工厂车间的随机意外干扰。由于机器与网格的并行交互,智能体的局部视点是非平稳和非马尔可夫的。因此,传统的方法,如标准的强化学习方法,为单个机器学习专门的策略是不适用的。为了解决这个问题,我们提出了一种多智能体行为者批评方法,该方法考虑了其他参与者的政策,以实现大量行为者之间的显式协调。我们展示了我们的方法在混合合作和竞争场景中的优势,在这种情况下,不同的生产机器能够发现不同的协调策略,以提高整个工厂的能源效率。
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