Abstract
This article proposes the design of an automatic classifier using the empirical mode decomposition (EMD) along with machine learning techniques for identifying the five most important types of events of the Ubinas volcano, the most active volcano in Peru. The proposed method uses attributes from temporal, spectral, and cepstral domains, extracted from the EMD of the signals, as well as a set of preprocessing and instrument correction techniques. Due to the fact that multichannel sensors are currently being installed in seismic networks worldwide, the proposed approach uses a multichannel sensor to perform the classification, contrary to the usual approach of the literature of using a single channel. The presented method is scalable to use data from multiple stations with one or more channels. The principal component analysis method is applied to reduce the dimensionality of the feature vector and the supervised classification is carried out by means of several machine learning algorithms, the support vector machine providing the best results. The presented investigation was tested with a large database that has a considerable number of explosion events, measured at the Ubinas volcano, located in Arequipa, Peru. The proposed classification system achieved a success rate of more than 90%.
Highlights
T HE recent eruption of the Volcan de Fuego volcano (June 2018, Guatemala) showed the catastrophic effects of a small volcanic eruption
The gain provided by the empirical mode decomposition (EMD) in the overall success rate is not very high, it should be highlighted that the EMD yielded more significant gains for long period (LP) and EX classes (2.7% and 4.2%, respectively)
An automatic classification system for identifying the five most important types of events of a volcano was presented in this article, using the EMD in the feature extraction block
Summary
T HE recent eruption of the Volcan de Fuego volcano (June 2018, Guatemala) showed the catastrophic effects of a small volcanic eruption. LARA et al.: AUTOMATIC MULTICHANNEL VOLCANO-SEISMIC CLASSIFICATION USING MACHINE LEARNING AND EMD work in[18] uses attributes in the temporal, spectral, and cepstral domains for the extraction of attributes, along with the SVM classifier. In order to clarify the importance of the use multichannel sensors, let us consider that a seismic signal is recorded by a vertical single-channel sensor. Multichannel sensors allow capturing all the information of the seismic wavefront caused by the magmatic activity, unlike single-channel sensors, which neglects some parts of the wavefront This kind of triaxial sensors is currently being installed in seismic networks worldwide. 1) The inclusion of a multichannel sensor and data from two seismic stations to model the behavior of the volcano, contrary to previous works that use only a single channel.
Sign-in/Register to view highlights & summary Sign-in/Register to access full text options 
Free) 
Talk to us
Join us for a 30 min session where you can share your feedback and ask us any queries you have
Schedule a call
