可再生能源发电总量预测的神经网络可解释性

2021 IEEE International Conference on Communications, Control, and Computing Technologies for Smart Grids (SmartGridComm) Pub Date : 2021-06-19 DOI:10.1109/SmartGridComm51999.2021.9631993

Y. Lu, Ilgiz Murzakhanov, Spyros Chatzivasileiadis

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引用次数: 5

摘要

随着可再生能源的快速发展，出现了大量的小型光伏产消户。由于太阳能发电的不确定性，需要聚合产消者预测太阳能发电量以及太阳能发电量是否会大于负荷。本文提出了两种可解释神经网络来解决这个问题:一种是二值分类神经网络，另一种是回归神经网络。神经网络是使用TensorFlow构建的。通过三种基于梯度的方法:集成梯度、期望梯度和DeepLIFT来检测全局特征重要性和局部特征贡献。此外，我们利用贝叶斯神经网络估计预测的不确定性，从而检测出预测可能失败的异常情况。神经网络通过基于梯度的方法进行解释，并辅以不确定性估计，为决策者提供了鲁棒性和可解释性的预测。

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Neural network interpretability for forecasting of aggregated renewable generation

With the rapid growth of renewable energy, lots of small photovoltaic (PV) prosumers emerge. Due to the uncertainty of solar power generation, there is a need for aggregated prosumers to predict solar power generation and whether solar power generation will be larger than load. This paper presents two interpretable neural networks to solve the problem: one binary classification neural network and one regression neural network. The neural networks are built using TensorFlow. The global feature importance and local feature contributions are examined by three gradient-based methods: Integrated Gradients, Expected Gradients, and DeepLIFT. Moreover, we detect abnormal cases when predictions might fail by estimating the prediction uncertainty using Bayesian neural networks. Neural networks, which are interpreted by the gradient-based methods and complemented with uncertainty estimation, provide robust and explainable forecasting for decision-makers.

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来源期刊

2021 IEEE International Conference on Communications, Control, and Computing Technologies for Smart Grids (SmartGridComm)

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