Abstract
The analysis of waveforms related to transient events is an important task in power system maintenance. Currently, electric power systems are monitored by several event recorders called phasor measurement units (PMUs) which generate a large amount of data. The number of records is so high that it makes human analysis infeasible. An alternative way of solving this problem is to group events in similar classes so that it is no longer necessary to analyze all the events, but only the most representative of each class. Several automatic clustering algorithms have been proposed in the literature. Most of these algorithms use validation indexes to rank the partitioning quality and, consequently, find the optimal number of clusters. However, this issue remains open, as each index has its own performance highly dependent on the data spatial distribution. The main contribution of this paper is the development of a methodology that optimizes the results of any clustering algorithm, regardless of data spatial distribution. The proposal is to evaluate the internal correlation of each cluster to proceed or not in a new partitioning round. In summary, the traditional validation indexes will continue to be used in the cluster’s partition process, but it is the internal correlation measure of each one that will define the stopping splitting criteria. This approach was tested in a real waveforms database using the K-means algorithm with the Silhouette and also the Davies–Bouldin validation indexes. The results were compared with a specific methodology for that database and were shown to be totally consistent.
Highlights
Industrial networks, as well as electric power ones, play a fundamental role in the goods and services production
The results showed a significant reduction in computational cost besides of high correlation with the results based on the hierarchization performed using database without any preprocessing
As the validation indexes are based on statistical methods or related to similarity/dissimilarity measures, the results are very dependent on the spatial distribution of each data set
Summary
Industrial networks, as well as electric power ones, play a fundamental role in the goods and services production. Reliability and security are fundamental requirements that guide the technologies development associated to these equipments. The recorded events, called oscilographies, can represent disturbances on the system. Works [1,2,3] are prominent examples in the literature. The authors of [4] made a primary classification (Table 1) of main disturbances that may affect power systems. The massive instrumentation of these networks has motivated research in data analysys for the development of predictive maintenance strategies. [5,6] bring an extensive literature review of machine learning methods applied to this theme Refs. [5,6] bring an extensive literature review of machine learning methods applied to this theme
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