基于图卷积和树突状深度学习的短期负荷预测

IF 6.7 2区计算机科学 Q1 ENGINEERING, MULTIDISCIPLINARY

IEEE Transactions on Network Science and Engineering Pub Date : 2025-04-08 DOI:10.1109/TNSE.2025.3558193

Chunyang Zhang;Yang Yu;Tengfei Zhang;Keyu Song;Yirui Wang;Shangce Gao

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引用次数: 0

摘要

短期负荷预测是未来电力系统规划、运行和控制的一项重要任务。随着接入系统的设备数量的不断增加，负载的特性和形式也越来越复杂，这给相关方法实现更高的负荷预测精度和可靠性带来了相当大的困难。为此，本研究提出了一种结合图卷积网络（GCN）、门控循环单元（GRU）和树突状神经模型（DNM）的深度学习模型，以更准确地预测电力负荷。首先，将样本载荷数据构建成以单个时间步长为节点的图数据；GCN用于提取隐藏特征，同时允许时间步长特征数据之间的充分通信。然后使用GRU来捕获数据的时间依赖关系。最后，用树突层代替全连接层作为输出，对数据特征进行深度整合。实验验证了该模型的有效性，并将其与几种有效的深度学习模型（包括CNN_LSTM、Transformer和Kolmogorov-Arnold Networks (KAN)）进行了比较。结果表明，与基线模型相比，该模型在全国和地区不同聚集水平的负荷数据集上的平均绝对百分比误差（$MAPE$）分别为1.62%和3.98%，决定系数（$R^{2}$）分别为0.983和0.928。

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Short-Term Load Forecasting Based on Graph Convolution and Dendritic Deep Learning

Short-term load forecasting (STLF) is a significant task to the planning, operation and control of future power systems. The increasing number of devices connected to the system has led to more complex characteristics and forms of load, which has brought considerable difficulties to the relevant methods in achieving higher load prediction accuracy and reliability. In this regard, this study proposes a deep learning model that combines graph convolutional network (GCN), gated recurrent unit (GRU), and dendritic neural model (DNM) to forecast electric load more accurately. Firstly, the sample load data is constructed into graph data with individual time steps as nodes. A GCN is used to extract the hidden features while allowing a full communication between the time steps feature data. A GRU is then used to capture the time-dependent relationship of the data. Finally, a dendritic layer instead of a fully connected layer is used as the output to integrate data features in depth. Experiments are conducted to verify the validity of the proposed model and compared it with several effective deep learning models, including CNN_LSTM, Transformer and Kolmogorov-Arnold Networks (KAN). The results show a significant improvement in prediction compared to the baseline models, with mean absolute percentage error(

$MAPE$

) of 1.62% and 3.98%, coefficient of determination(

$R^{2}$

) of 0.983 and 0.928 respectively on two load datasets at different levels of aggregation, nationally and regionally.

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来源期刊

IEEE Transactions on Network Science and Engineering Engineering-Control and Systems Engineering

CiteScore

12.60

自引率

9.10%

发文量

393

期刊介绍： The proposed journal, called the IEEE Transactions on Network Science and Engineering (TNSE), is committed to timely publishing of peer-reviewed technical articles that deal with the theory and applications of network science and the interconnections among the elements in a system that form a network. In particular, the IEEE Transactions on Network Science and Engineering publishes articles on understanding, prediction, and control of structures and behaviors of networks at the fundamental level. The types of networks covered include physical or engineered networks, information networks, biological networks, semantic networks, economic networks, social networks, and ecological networks. Aimed at discovering common principles that govern network structures, network functionalities and behaviors of networks, the journal seeks articles on understanding, prediction, and control of structures and behaviors of networks. Another trans-disciplinary focus of the IEEE Transactions on Network Science and Engineering is the interactions between and co-evolution of different genres of networks.