Generative artificial intelligence for distributed learning to enhance smart grid communication

Seyed Mahmoud Sajjadi Mohammadabadi , Mahmoudreza Entezami , Aidin Karimi Moghaddam , Mansour Orangian , Shayan Nejadshamsi
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Abstract

Machine learning models are the backbone of smart grid optimization, but their effectiveness hinges on access to vast amounts of training data. However, smart grids face critical communication bottlenecks due to the ever-increasing volume of data from distributed sensors. This paper introduces a novel approach leveraging Generative Artificial Intelligence (GenAI), specifically a type of pre-trained Foundation Model (FM) architecture suitable for time series data due to its efficiency and privacy-preserving properties. These GenAI models are distributed to agents, or data holders, empowering them to fine-tune the foundation model with their local datasets. By fine-tuning the foundation model, the updated model can produce synthetic data that mirrors real-world grid conditions. The server aggregates fine-tuned model from all agents and then generates synthetic data which considers all data collected in the grid. This synthetic data can be used to train global machine learning models for specific tasks like anomaly detection and energy optimization. Then, the trained task models are distributed to agents in the grid to leverage them. The paper highlights the advantages of GenAI for smart grid communication, including reduced communication burden, enhanced privacy through anonymized data transmission, and improved efficiency and scalability. By enabling a distributed and intelligent communication architecture, GenAI introduces a novel way for a more secure, efficient, and sustainable energy future.

用于分布式学习的生成式人工智能增强智能电网通信
机器学习模型是智能电网优化的支柱,但其有效性取决于能否获得大量的训练数据。然而,由于来自分布式传感器的数据量不断增加,智能电网面临着严重的通信瓶颈。本文介绍了一种利用生成式人工智能(GenAI)的新方法,特别是一种预训练基础模型(FM)架构,因其高效和保护隐私的特性而适用于时间序列数据。这些 GenAI 模型被分配给代理或数据持有者,使他们有能力根据自己的本地数据集对基础模型进行微调。通过微调基础模型,更新后的模型可以生成反映真实电网条件的合成数据。服务器汇总来自所有代理的微调模型,然后生成考虑了网格中收集的所有数据的合成数据。这些合成数据可用于为异常检测和能源优化等特定任务训练全局机器学习模型。然后,将训练好的任务模型分发给电网中的代理,以充分利用这些模型。本文强调了 GenAI 在智能电网通信方面的优势,包括减轻通信负担、通过匿名数据传输增强隐私性以及提高效率和可扩展性。通过启用分布式智能通信架构,GenAI 为实现更加安全、高效和可持续的能源未来提供了一种新方法。
本文章由计算机程序翻译,如有差异,请以英文原文为准。
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