Study on the Annual Runoff Forecast Model of the Main Stream of Nanxi River Based on PSO-ANFIS

Q3 Environmental Science
Huifang Guo, Jian Meng, Hairong Huang, Shixia Zhang, Denghong Wang
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引用次数: 0

Abstract

In 2021, Wenzhou adopted measures to restrict the use of electricity, and the shortage of electricity became an important factor affecting the production and life of Wenzhou. Nanxi River is one of the main rivers in Wenzhou City, and its water resources are very rich. According to the statistics of the water conservancy planning of the Nanxi River basin, there are 96 hydropower stations in the Nanxi River basin, with a total installed capacity of 152100 kW, accounting for 57% of the installed capacity. The development and utilization of the Nanxi River water resources can alleviate the power shortage in Wenzhou power grid to a certain extent. The development and utilization of hydropower are closely related to the runoff of the basin. The river runoff is mainly determined by rainfall, underlying surface and upstream inflow. River runoff is affected by many factors in the process of formation, so it is difficult to improve its prediction accuracy. In order to improve the prediction accuracy of the runoff of the main stream of the Nanxi River, this paper introduces the runoff prediction model of particle swarm optimization adaptive fuzzy inference system (PSO-ANFIS). ANFIS model has the advantages of applying fuzzy rules and the nonlinear approximation ability of neural network, but the antecedent parameters of ANFIS model are prone to fall into local optimization. In order to improve the generalization ability of the antecedent parameters of ANFIS model, the PSO algorithm of global optimization is introduced to optimize the antecedent parameters of ANFIS. Through the application of the example, it is found that the decision coefficient of PSO-ANFIS model in the simulation stage is 0.987, and the decision coefficient in the prediction stage is 0.856. This model can be applied in the annual runoff forecast. Through comparison with ANFIS model, it is found that PSO-ANFIS model has better prediction effect.
基于 PSO-ANFIS 的楠溪江干流年径流预报模型研究
2021 年,温州采取限电措施,电力短缺成为影响温州生产生活的重要因素。楠溪江是温州市的主要河流之一,水资源十分丰富。据楠溪江流域水利规划统计,楠溪江流域共有水电站 96 座,总装机容量 152100 千瓦,占装机容量的 57%。楠溪江水资源的开发利用,可在一定程度上缓解温州电网缺电问题。水电的开发利用与流域径流密切相关。江河径流主要由降雨、下垫面和上游来水决定。河流径流在形成过程中受多种因素影响,因此很难提高其预测精度。为了提高楠溪江干流径流的预测精度,本文引入了粒子群优化自适应模糊推理系统(PSO-ANFIS)的径流预测模型。ANFIS模型具有应用模糊规则和神经网络非线性逼近能力的优点,但ANFIS模型的前置参数容易陷入局部优化。为了提高 ANFIS 模型前置参数的泛化能力,引入了全局优化的 PSO 算法来优化 ANFIS 的前置参数。通过实例应用发现,PSO-ANFIS 模型在模拟阶段的决策系数为 0.987,在预测阶段的决策系数为 0.856。该模型可用于年径流预报。通过与 ANFIS 模型比较,发现 PSO-ANFIS 模型具有更好的预测效果。
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
Strategic Planning for Energy and the Environment
Strategic Planning for Energy and the Environment Environmental Science-Environmental Science (all)
CiteScore
1.50
自引率
0.00%
发文量
25
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