Adaptive Single-layer Aggregation Framework for Energy-efficient and Privacy-preserving Load Forecasting in Heterogeneous Federated Smart Grids

IF 6 3区计算机科学 Q1 COMPUTER SCIENCE, INFORMATION SYSTEMS

Internet of Things Pub Date : 2024-09-20 DOI:10.1016/j.iot.2024.101376

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引用次数: 0

Abstract

Federated Learning (FL) enhances predictive accuracy in load forecasting by integrating data from distributed load networks while ensuring data privacy. However, the heterogeneous nature of smart grid load forecasting introduces significant challenges that current methods struggle to address, particularly for resource-constrained devices due to high computational and communication demands. To overcome these challenges, we propose a novel Adaptive Single Layer Aggregation (ASLA) framework tailored for resource-constrained smart grid networks. The ASLA framework mitigates data heterogeneity issues by focusing on local learning and incorporating partial updates from local devices for model aggregation in adaptive manner. It is optimized for resource-constrained environments through the implementation of a stopping criterion during model training and weight quantization. Our evaluation on two distinct datasets demonstrates that quantization results in a minimal loss function degradation of 0.01% for Data 1 and 1.25% for Data 2. Furthermore, local model layer optimization for aggregation achieves substantial communication cost reductions of 829.2-fold for Data 1 and 5522-fold for Data 2. The use of an 8-bit fixed-point representation for neural network weights leads to a 75% reduction in storage/memory requirements and decreases computational costs by replacing complex floating-point units with simpler fixed-point units. By addressing data heterogeneity and reducing storage, computation, and communication overheads, the ASLA framework is well-suited for deployment in resource-constrained smart grid networks.

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用于异构联邦智能电网中节能和保护隐私的负荷预测的自适应单层聚合框架

联合学习（FL）通过整合来自分布式负载网络的数据，提高了负载预测的准确性，同时确保了数据的私密性。然而，智能电网负荷预测的异构性带来了当前方法难以解决的重大挑战，特别是对于资源受限的设备，因为它们对计算和通信的要求很高。为了克服这些挑战，我们提出了一种为资源受限的智能电网网络量身定制的新型自适应单层聚合（ASLA）框架。ASLA 框架侧重于本地学习，并结合本地设备的部分更新，以自适应的方式进行模型聚合，从而缓解数据异质性问题。通过在模型训练和权重量化过程中实施停止准则，该框架针对资源受限的环境进行了优化。我们在两个不同数据集上进行的评估表明，数据 1 和数据 2 的量化分别导致 0.01% 和 1.25% 的最小损失函数衰减。此外，用于聚合的局部模型层优化实现了通信成本的大幅降低，数据 1 的通信成本降低了 829.2 倍，数据 2 的通信成本降低了 5522 倍。对神经网络权重使用 8 位定点表示法可使存储/内存需求减少 75%，并通过用更简单的定点单元取代复杂的浮点单元降低了计算成本。通过解决数据异构问题并减少存储、计算和通信开销，ASLA 框架非常适合部署在资源受限的智能电网网络中。

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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来源期刊

Internet of Things Multiple-

CiteScore

3.60

自引率

5.10%

发文量

115

审稿时长

37 days

期刊介绍： Internet of Things; Engineering Cyber Physical Human Systems is a comprehensive journal encouraging cross collaboration between researchers, engineers and practitioners in the field of IoT & Cyber Physical Human Systems. The journal offers a unique platform to exchange scientific information on the entire breadth of technology, science, and societal applications of the IoT. The journal will place a high priority on timely publication, and provide a home for high quality. Furthermore, IOT is interested in publishing topical Special Issues on any aspect of IOT.