An SEELM-based ensemble method for load forecasting in a distributed photovoltaic systems

被引：0

作者：

Zhang H. ^{[1
]}

Chen J. ^{[1
]}

Chen G. ^{[2
]}

机构：

[1] School of Electrical and Electronic Engineering, Hubei University of Technology, Wuhan

[2] School of Electrical Engineering, Zhengzhou University, Zhengzhou

来源：

Dianli Xitong Baohu yu Kongzhi/Power System Protection and Control | 2022年 / 50卷 / 10期

基金：

中国国家自然科学基金;

关键词：

ensemble systems; load forecast; photovoltaic systems; SEELM;

D O I：

10.19783/j.cnki.pspc.220116

中图分类号：

TP18 [人工智能理论];

学科分类号：

081104 ; 0812 ; 0835 ; 1405 ;

摘要：

Given the nonlinear and non-stationary data distribution characteristics of distributed photovoltaic system load, this paper proposes a suspended ensemble extreme learning machine (SEELM) method based on neural networks and a hanging criterion to implement power load prediction in distributed photovoltaic systems. First, multiple neural network models are built, and the initial input weights of each model are randomly assigned. Then the hanging criteria are designed to divide the models into two parts according to the numerical fluctuation ranges at different time spots. For large error models with larger fluctuation ranges, the online updates will be carried out in a probabilistic way to optimize the training error and input weights simultaneously. Finally, the outputs of all submodels are taken for the final output, which can reduce the error fluctuation impacts in the initial weight selection step. Based on an empirical simulation of the actual distributed photovoltaic system in a region, the advantages of the proposed method in terms of prediction accuracy and output stability under the scenarios of large fluctuation in photovoltaic load can be verified, and better capability and performance of load forecasting in the high-proportion photovoltaic systems can thus be achieved. © 2022 Power System Protection and Control Press. All rights reserved.

引用

页码：69 / 75

页数：6

共 30 条

[1] PAN Qingyu, Research on key technologies of substation planning considering distributed power access, Power System Protection and Control, 49, 6, pp. 98-104, (2021)
[2] XIAO Yiyao, XIONG Ning, ZHOU Chenxi, Et al., Booster planning considering dynamic development of load and distributed generator for substations in low-load density areas, Power System Protection and Control, 49, 7, pp. 86-93, (2021)
[3] LI Jiaming, AI Xiaomeng, WEN Jinyu, Et al., Quantitative analysis of probability distribution for duration time characteristic of photovoltaic Power, Automation of Electric Power Systems, 41, 6, pp. 30-36, (2017)
[4] FARIAS-BASULTO G, REYES-FIGUEROA P, ULBRICH C, Et al., Validation of a multiple linear regression model for CIGSSE photovoltaic module performance and PMPP prediction, Solar Energy, 208, 1, pp. 859-865, (2020)
[5] FANG Baomin, LI Hongzhi, KONG Xiangpeng, Et al., Research on long-term distributed energy storage configuration with a high proportion of photovoltaic output, Power System Protection and Control, 49, 2, pp. 121-129, (2021)
[6] ZHU H, SHI Y, WANG H, Et al., New feature extraction method for photovoltaic array output time series and its application in fault diagnosis, IEEE Journal of Photovoltaics, 10, 4, pp. 1133-1141, (2020)
[7] WANG Lianmin, LI Wei, ZHANG Kejia, Et al., Research on grid connected reliability of distributed photovoltaic power generation, Manufacturing Automation, 43, 3, pp. 156-159, (2021)
[8] XU Kehan, ZHANG Zhe, LIU Huiyuan, Et al., Study on fault characteristics and its related impact factors of photovoltaic generator, Transactions of China Electrotechnical Society, 35, 2, pp. 359-371, (2020)
[9] GUO Shan, ZHANG Yuanyuan, JIA Junqing, Et al., Evaluation of photovoltaic consumption capacity of distribution network based on Monte Carlo method, Zhejiang Electric Power, 40, 6, pp. 8-14, (2021)
[10] CHEN W, DUAN Y, GUO L, Et al., Modeling and prediction of radiated emission from solar cellina photovoltaic generation system, IEEE Journal of Photovoltaics, 6, 2, pp. 540-545, (2016)

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