基于互信息参数优化BP神经网络的生物质发电量预测研究

生物质直燃发电是目前应用最广、规模最大的生物质能利用方式。然而由于生物质种类繁多、理化性质多变、燃烧不稳定，使得发电量难以准确预计，这为电网调度、安全运行带来隐患。为此，提出一种基于互信息参数优化BP神经网络的生物质发电量预测模型。从生物质电厂收集发电量以及物料参数、锅炉参数、汽机参数、环境参数等实际生产数据，采用平均影响值分析、相关分析和互信息分析对发电量的影响因素进行优化选择，并利用电厂实际数据建立BP神经网络模型。测试结果表明，采用优化影响因素建立的神经网络模型预测误差大幅度降低，其中互信息分析优化效果最佳，平均预测误差从未优化模型的4.59%降至0.66%，且进一步优化神经网络参数后，平均预测误差降至0.50%。

Research on biomass power generation prediction based on mutual information parameter optimization and BP neural networ

Biomass direct combustion power generation is the most widely and largest biomass energy utilization technology at present. It has various advantages such as simplicity, high efficiency, economics, etc. However, due to the wide variety, changeable physicochemical properties and unstable combustion of biomass, it is difficult to accurately predict the power generation, which brings hidden dangers to power grid dispatching and safe operation. Based on this, this study proposes a BP neural network biomass power generation prediction model based on mutual information parameter optimization. Firstly, the actual power production data are collected from a biomass power plant, including power generation, material parameters, boiler parameters, steam turbine parameters, flue gas parameters, etc. Then, the influencing factors of power generation are optimized and filtered by using average influence value analysis, correlation analysis and mutual information analysis. Finally, the whole collected data of power plant are used to establish BP neural network models. The test results show that the relative error of the neural network model established by optimizing data is greatly reduced, the mutual information analysis shows the best optimization effect, and the corresponding average prediction error reduces from 4.59% to 0.66%. Further, the parameters of the neural network model is optimized, and the average prediction error can reduce to 0.50%.