Enriching Neural Network Training Dataset to Improve Worst-Case Performance Guarantees

03/23/2023

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Machine learning algorithms, especially Neural Networks (NNs), are a valuable tool used to approximate non-linear relationships, like the AC-Optimal Power Flow (AC-OPF), with considerable accuracy – and achieving a speedup of several orders of magnitude when deployed for use. Often in power systems literature, the NNs are trained with a fixed dataset generated prior to the training process. In this paper, we show that adapting the NN training dataset during training can improve the NN performance and substantially reduce its worst-case violations. This paper proposes an algorithm that identifies and enriches the training dataset with critical datapoints that reduce the worst-case violations and deliver a neural network with improved worst-case performance guarantees. We demonstrate the performance of our algorithm in four test power systems, ranging from 39-buses to 162-buses.

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Enriching Neural Network Training Dataset to Improve Worst-Case Performance Guarantees

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Application of the Neural Network Dependability Kit in Real-World Environments

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ORSA: Outlier Robust Stacked Aggregation for Best- and Worst-Case Approximations of Ensemble Systems

Physics-Informed Neural Networks for Minimising Worst-Case Violations in DC Optimal Power Flow

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Enriching Neural Network Training Dataset to Improve Worst-Case Performance Guarantees

Related Research

Minimizing Worst-Case Violations of Neural Networks

Global Performance Guarantees for Neural Network Models of AC Power Flow

Application of the Neural Network Dependability Kit in Real-World Environments

Worst-Case Dynamic Power Distribution Network Noise Prediction Using Convolutional Neural Network

ORSA: Outlier Robust Stacked Aggregation for Best- and Worst-Case Approximations of Ensemble Systems

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