This paper proposes an automatic multiclass classification method using metaheuristic-based wrapper strategies and shallow learning classifiers to maximize the primary focal mechanism classification in seismic motion data. The contribution behind the goal is to reduce the original feature space from a bioinspired perspective while maximizing the classification performance of three seismic activity classes: Strike-Slip (SS), Reverse-Oblique (RO), and Normal-Oblivious (NO). The proposed method was trained and validated on a public seismic motion database, after transforming the raw signals into numerical feature vectors. The best classification scheme was formed using the wrapper method using a genetic algorithm approach and a naive Bayes-based fitness function, combined with a seven-nearest neighbors classifier. This scheme achieved a successful area under the receiver operating characteristic curve score of 0.807 and 0.940 for the training and test stages, respectively. These results corroborate the effective reduction of the original feature space from 25 to 12 features while maximizing the classification performance of three seismic activity classes: strike-slip, reverse-oblique, and normal-oblique. The promising results obtained allow the proposed method to be considered a powerful tool for monitoring primary earthquake focal mechanisms.

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Multiclass Seismic Focal Mechanism Classification Using Metaheuristic-Based Wrapper Strategies and Shallow Learning Classifiers

  • Mateo Moreno,
  • Fabricio Yépez,
  • Noel Pérez-Pérez,
  • Diego Benítez,
  • Álvaro D. Orjuela-Cañon

摘要

This paper proposes an automatic multiclass classification method using metaheuristic-based wrapper strategies and shallow learning classifiers to maximize the primary focal mechanism classification in seismic motion data. The contribution behind the goal is to reduce the original feature space from a bioinspired perspective while maximizing the classification performance of three seismic activity classes: Strike-Slip (SS), Reverse-Oblique (RO), and Normal-Oblivious (NO). The proposed method was trained and validated on a public seismic motion database, after transforming the raw signals into numerical feature vectors. The best classification scheme was formed using the wrapper method using a genetic algorithm approach and a naive Bayes-based fitness function, combined with a seven-nearest neighbors classifier. This scheme achieved a successful area under the receiver operating characteristic curve score of 0.807 and 0.940 for the training and test stages, respectively. These results corroborate the effective reduction of the original feature space from 25 to 12 features while maximizing the classification performance of three seismic activity classes: strike-slip, reverse-oblique, and normal-oblique. The promising results obtained allow the proposed method to be considered a powerful tool for monitoring primary earthquake focal mechanisms.