电工技术学报2024,Vol.39Issue(11):3379-3391,13.DOI:10.19595/j.cnki.1000-6753.tces.230554
基于非侵入式负荷分解的家庭负荷两阶段超短期负荷预测模型
Two-Stage Ultra-Short-Term Load Forecasting Model of Household Appliances Based on Non-Intrusive Load Disaggregation
摘要
Abstract
Due to the impact of large-scale renewable energy on the safe and stable operation of power systems,the demand for flexible sources is increasing.The home energy management system is a promising approach to enhance the flexible regulation capability of power systems and improve grid energy efficiency.However,the randomness of residents'electricity behavior,the uncertainty of market information,and the diversity of decision-making subjects make it extremely challenging for residents to participate in fast demand responses.To address these issues,this paper proposes a two-stage household load forecasting method based on the integration of load disaggregation and forecasting.By learning the correlation information from historical electricity consumption data of each appliance obtained by non-intrusive load monitoring(NILM)technology,it accurately realizes the load forecasting of household appliances and flexible cluster load prediction. First,a NILM model based on convolutional neural network(CNN)and bi-directional gated unit(BiGRU)neural network is established to solve the problem of obtaining the operation data of appliances.Subsequently,considering the randomness and uncertainty of user behavior,a time convolutional network(TCN)load forecasting model based on the time pattern attention(TPA)mechanism is constructed to mine the deep interaction information of input variables.Finally,the proposed method is verified by the UK-DALE data set.The results show that the proposed method can obtain high disaggregation accuracy and prediction effect. This paper implements two simulations using Keras with a TensorFlow backend.The first one is designed to monitor the appliance-level energy consumption with the proposed CNN-BiGRU-enabled NILM.The results show that the proposed NILM-Based model can accurately capture the start and end time of the appliance,and has a good trend-tracking effect.With the NILM results,the second one is conducted to verify the effectiveness of the proposed load forecasting model.Compared with other deep learning models such as long short-term memory,the eMAE and eRMSE of washing machines,microwave ovens,dishwashers and refrigerators based on the proposed forecasting method are reduced by 18.65%and 4.99%,13.28%and 0.72%,32.04%and 5.55%,4.53%and 5.70%,respectively.The comparison of load forecasting results between the ground truth data and the NILM-based data shows that the eMAE is controlled within 15%and the eRMSE is controlled within 6%.Finally,to verify the robustness of the proposed model in cluster load forecasting,a bottom-up strategy is applied to obtain the flexible load prediction of group users or communities based on appliance prediction. The following conclusions can be drawn from the simulation analysis:(1)The load forecasting framework based on NILM reduces the dependence on intrusive monitoring systems,and has strong adaptability and scalability,which can provide a new method for the development of household energy management system-related businesses.(2)Compared with shallow neural networks,CNN-BiGRU has powerful mapping ability and can achieve high accuracy in load disaggregation and event detection.(3)The proposed forecasting model extracts temporal informative features using TCN and subsequently implements dynamic weighting of inputs using TPA to highlight the impact of key features.The case study shows that the proposed method can improve forecasting accuracy compared with traditional deep learning models.关键词
非侵入式负荷分解/负荷预测/卷积神经网络/双向门控单元神经网络/时间卷积网络/注意力机制Key words
Non-intrusive load disaggregation/load forecasting/convolutional neural network/bidirectional gated unit neural network/time convolutional network/attention mechanism分类
信息技术与安全科学引用本文复制引用
李延珍,王海鑫,杨子豪,陈哲,杨俊友..基于非侵入式负荷分解的家庭负荷两阶段超短期负荷预测模型[J].电工技术学报,2024,39(11):3379-3391,13.基金项目
高等学校学科创新引智计划资助项目(D23005). (D23005)
