Abstract
As a diagnostic monitoring approach, electroencephalogram (EEG) signals can be decoded by signal processing methodologies for various health monitoring purposes. However, EEG recordings are contaminated by other interferences, particularly facial and ocular artifacts generated by the user. This is specifically an issue during continuous EEG recording sessions, and is therefore a key step in using EEG signals for either physiological monitoring and diagnosis or brain–computer interface to identify such artifacts from useful EEG components. In this study, we aim to design a new generic framework in order to process and characterize EEG recording as a multi-component and non-stationary signal with the aim of localizing and identifying its component (e.g., artifact). In the proposed method, we gather three complementary algorithms together to enhance the efficiency of the system. Algorithms include time–frequency (TF) analysis and representation, two-dimensional multi-resolution analysis (2D MRA), and feature extraction and classification. Then, a combination of spectro-temporal and geometric features are extracted by combining key instantaneous TF space descriptors, which enables the system to characterize the non-stationarities in the EEG dynamics. We fit a curvelet transform (as a MRA method) to 2D TF representation of EEG segments to decompose the given space to various levels of resolution. Such a decomposition efficiently improves the analysis of the TF spaces with different characteristics (e.g., resolution). Our experimental results demonstrate that the combination of expansion to TF space, analysis using MRA, and extracting a set of suitable features and applying a proper predictive model is effective in enhancing the EEG artifact identification performance. We also compare the performance of the designed system with another common EEG signal processing technique—namely, 1D wavelet transform. Our experimental results reveal that the proposed method outperforms 1D wavelet.
Highlights
Electroencephalography (EEG) is a method for recording electrical activities of the brain, and is indicated in activities which originate from the cerebral cortex
We evaluate the performance of the proposed EEG artifact identification scheme using time–frequency (TF) analysis and multi-resolution analysis (MRA)
These values have been selected based on the previous research studies and investigations on theoretical and practical applications of TF representation of EEG signal using Gaussian kernel distribution (GKD) and modified B-distribution (MBD) approaches ([22], Sections 7.4 and 15.5), [40,41]
Summary
Electroencephalography (EEG) is a method for recording electrical activities of the brain, and is indicated in activities which originate from the cerebral cortex. Detected signals in EEG recordings which have origins other than the brain itself are considered as artifacts. The amplitude of the desired cortical-related EEG component can be somewhat smaller than the amplitude of the artifact signals. Non-cerebral sources of artifacts in the EEG recordings can be as follows: saccade, eye blinking [1,2], respiratory-related artifacts [3,4], Sensors 2017, 17, 2895; doi:10.3390/s17122895 www.mdpi.com/journal/sensors. Diagnostic information in EEG recordings can be suppressed by these categories of artifacts. Continuous EEG-based systems demand preprocessing to distinguish between artifacts and target brain activities to annotate noisy segments from clean segments of EEG activities
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