On the characterization of cognitive tasks using activity-specific short-lived synchronization between electroencephalography channels


Olcay B. O., Ozgoren M., Karacali B.

NEURAL NETWORKS, vol.143, pp.452-474, 2021 (SCI-Expanded) identifier identifier identifier

  • Publication Type: Article / Article
  • Volume: 143
  • Publication Date: 2021
  • Doi Number: 10.1016/j.neunet.2021.06.022
  • Journal Name: NEURAL NETWORKS
  • Journal Indexes: Science Citation Index Expanded (SCI-EXPANDED), Scopus, Academic Search Premier, PASCAL, Applied Science & Technology Source, BIOSIS, Biotechnology Research Abstracts, Communication Abstracts, Compendex, Computer & Applied Sciences, EMBASE, INSPEC, MEDLINE, Psycinfo, zbMATH
  • Page Numbers: pp.452-474
  • Keywords: EEG, Short-lived synchronization, Motor imagery activity characterization, Systematic timing organization, Synchronization measures, BRAIN-COMPUTER INTERFACE, SINGLE-TRIAL EEG, MUTUAL INFORMATION ANALYSIS, MOTOR-IMAGERY, FUNCTIONAL CONNECTIVITY, FEATURE-EXTRACTION, SPATIAL-PATTERNS, PHASE SYNCHRONY, TIME-FREQUENCY, NONLINEAR DYNAMICS
  • Dokuz Eylül University Affiliated: No

Abstract

Accurate characterization of brain activity during a cognitive task is challenging due to the dynamically changing and the complex nature of the brain. The majority of the proposed approaches assume stationarity in brain activity and disregard the systematic timing organization among brain regions during cognitive tasks. In this study, we propose a novel cognitive activity recognition method that captures the activity-specific timing parameters from training data that elicits maximal average short-lived pairwise synchronization between electroencephalography signals. We evaluated the characterization power of the activity-specific timing parameter triplets in a motor imagery activity recognition framework. The activity-specific timing parameter triplets consist of latency of the maximally synchronized signal segments from activity onset Delta t, the time lag between maximally synchronized signal segments t, and the duration of the maximally synchronized signal segments w. We used cosine-based similarity, wavelet bi-coherence, phase-locking value, phase coherence value, linearized mutual information, and cross-correntropy to calculate the channel synchronizations at the specific timing parameters. Recognition performances as well as statistical analyses on both BCI Competition-III dataset IVa and PhysioNet Motor Movement/Imagery dataset, indicate that the interchannel short-lived synchronization calculated using activity-specific timing parameter triplets elicit significantly distinct synchronization profiles for different motor imagery tasks and can thus reliably be used for cognitive task recognition purposes. (C) 2021 Elsevier Ltd. All rights reserved.