Abstract
Event detection in electrical grids is a challenging problem for machine learning methods due to spatiotemporally nonstationary systems and the inability to automate event labeling in high-volume data such as PMU measurements. As a result, the existing historical event logs created manually do not correlate well with the corresponding PMU measurements due to scarce and temporally imprecise labels. Trying to overcome this problem by extending event logs to a complete set of labeled events is very costly and often infeasible. We focused on utilizing a transfer learning model to reduce the need for additional data labeling by leveraging some labeled data instances available from a small number of well-defined event detection task. To demonstrate the feasibility, we tested our approach on a large dataset collected by 38 PMUs from the Western Interconnection of the U.S.A. over two years. The model evaluation performed based on varying percentages of labeled source data corresponding to $\sim 20$ -700 characteristic events on different sizes of time windows ranging from 2-seconds to 1-minute demonstrates that the developed method can significantly improve automated event detection based on PMU measurements when extensive labeling is costly or impossible to obtain. When compared to the state-of-the-art machine learning algorithms (unsupervised, semi-supervised, and supervised), the results show that the transfer learning method has significantly better performances when detecting events by learning from as low as 20 representative labeled data instances.
Highlights
We demonstrate that a transfer learning method is applicable for Phasor Measurement Units (PMUs) data and can detect events without having to rely on an extensive number of labels or event logs of PMU data
Our study extends the benefits of using transfer learning to solve the problem of transmission system event detection from an exceedingly small number of labeled events based on PMU data
Two semi-supervised learning algorithms that do not rely entirely on labels obtained from event logs or by visual inspection to classify data samples as normal or anomalous events were utilized: 1) the semi-supervised k-nearest neighbor anomaly (SSKNNO) detection algorithm, which is a combination of the well-known kNN classifier and the kNNO (k-nearest neighbor outlier detection) method [5]
Summary
Experiments conducted show that the employed transfer learning method is capable of detecting events with as low as ~20 representative labeled data instances. Our study extends the benefits of using transfer learning to solve the problem of transmission system event detection from an exceedingly small number of labeled events based on PMU data. Related instances can aid semi-supervised learning algorithms to detect events based on minimal labeled data, since it only selects and transfers tasks that are similar to instances in the target set. Since this study concerns event detection, the task is to compute and assign an anomaly score to each time window (data instance) in the target dataset that quantifies how anomalous the time window is based on similarity measures; assigning an anomaly score to a time window can be compared with a predefined threshold to classify whether an anomalous event exists within a given time window [21].
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