The increased integration of renewable energy poses a slew of technical challenges for the operation of power distribution networks. Among them, voltage fluctuations caused by the instability of renewable energy are receiving increasing attention. Utilizing MARL algorithms to coordinate multiple control units in the grid, which is able to handle rapid changes of power systems, has been widely studied in active voltage control task recently. However, existing approaches based on MARL ignore the unique nature of the grid and achieve limited performance. In this paper, we introduce the transformer architecture to extract representations adapting to power network problems and propose a Transformer-based Multi-Agent Actor-Critic framework (T-MAAC) to stabilize voltage in power distribution networks. In addition, we adopt a novel auxiliary-task training process tailored to the voltage control task, which improves the sample efficiency and facilitating the representation learning of the transformer-based model. We couple T-MAAC with different multi-agent actor-critic algorithms, and the consistent improvements on the active voltage control task demonstrate the effectiveness of the proposed method.
翻译:可再生能源一体化程度的提高给电力分配网络的运作带来了一系列技术挑战,其中,可再生能源不稳定造成的电压波动日益受到注意。利用MARL算法协调电网中能够处理电源系统迅速变化的多个控制单位,最近已在主动电压控制任务中进行了广泛研究。但是,基于MARL的现有办法忽视电网的独特性质,取得了有限的绩效。在本文件中,我们引入了变压器结构,以提取可适应电网问题的表现,并提出以变压器为基础的多行为者-批评框架(T-MAAC),以稳定电源分配网络中的电压。此外,我们还采用了针对电压控制任务的新的辅助任务培训过程,以提高样本效率,便利以变压器为基础的模型的演示学习。我们把T-MAAC与不同的多剂行为者-批评算法结合起来,并不断改进主动电压控制任务,以显示拟议方法的有效性。