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Excision of Ocular Artifacts from EEG Using NVFF-RLS Adaptive Algorithm

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Abstract

This paper presents a technique for the removal of ocular artifacts from electro-encephalogram (EEG) by using adaptive filtering. The major concern is electro-oculogram (EOG) signal present in a recorded EEG signal, which appears due to abrupt eye movements. In the presented method, we use separately recorded horizontal EOG (HEOG) and vertical EOG (VEOG) signals as two reference inputs, which are processed using finite impulse response (FIR) filters. The linear filter coefficients are adaptively updated using a numerical variable forgetting factor (NVFF) recursive least squares (RLS) algorithm, which tracks nonstationary EOG signals. Subsequently, the processed HEOG and VEOG signals are subtracted from recorded EEG signal to obtain an artifact-free EEG signal. Simulation is conducted using synthetic EEG signal corrupted by noise, synthetic HEOG and VEOG signals. The real-time recorded EEG signal (corrupted by EOG and noise) is also refined using the separately recorded reference EOG signals and FIR filtering technique. For synthetic and real-time signals, the simulation results are presented to demonstrate that linear NVFF-RLS algorithm-based artifact and noise excision technique outperforms conventional fixed forgetting factor RLS, fixed step-size NLMS and generalized variable step-size NLMS algorithms, in terms of the reduction in mean-squared error, under low as well as high signal-to-noise ratio conditions.

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Acknowledgments

Authors are thankful to Dr. Poonam Gakhar Kohli, Associate Professor, Physiology Department, Punjab Institute of Medical Science Jalandhar, affiliated to Baba Farid University, Punjab, India, for her fruitful suggestions and motivational discussions regarding Physiology and Neurology. However, the EEG signals (publicly available) can be downloaded from a web page entitled with EEG recordings database on https://www.physionet.org.

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  1. Department of Electronics and Communication Engineering, Thapar University, Patiala, Punjab, 147004, India

    Harish Kumar Garg & Amit Kumar Kohli

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  1. Harish Kumar Garg
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Correspondence to Amit Kumar Kohli.

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Harish Kumar Garg and Amit Kumar Kohli declare that they have no conflict of interest in relation to the research work presented in this article.

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Garg, H.K., Kohli, A.K. Excision of Ocular Artifacts from EEG Using NVFF-RLS Adaptive Algorithm. Circuits Syst Signal Process 36, 404–419 (2017). https://doi.org/10.1007/s00034-016-0293-8

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