Sara Mahvash Mohammadi1, Samaneh Kouchaki2, Mohammad Ghavami3, Saeid Sanei2. 1. Department of Engineering and Design, London South Bank University, London, UK. Electronic address: saramahvash@yahoo.co.uk. 2. Faculty of Engineering and Physical Sciences, University of Surrey, Guildford, UK. 3. Department of Engineering and Design, London South Bank University, London, UK.
Abstract
BACKGROUND: Manual sleep scoring is deemed to be tedious and time consuming. Even among automatic methods such as time-frequency (T-F) representations, there is still room for more improvement. NEW METHOD: To optimise the efficiency of T-F domain analysis of sleep electroencephalography (EEG) a novel approach for automatically identifying the brain waves, sleep spindles, and K-complexes from the sleep EEG signals is proposed. The proposed method is based on singular spectrum analysis (SSA). The single-channel EEG signal (C3-A2) is initially decomposed and then the desired components are automatically separated. In addition, the noise is removed to enhance the discrimination ability of features. The obtained T-F features after preprocessing stage are classified using a multi-class support vector machines (SVMs) and used for the identification of four sleep stages over three sleep types. Furthermore, to emphasise on the usefulness of the proposed method the automatically-determined spindles are parameterised to discriminate three sleep types. RESULT: The four sleep stages are classified through SVM twice: with and without preprocessing stage. The mean accuracy, sensitivity, and specificity for before the preprocessing stage are: 71.5±0.11%, 56.1±0.09% and 86.8±0.04% respectively. However, these values increase significantly to 83.6±0.07%, 70.6±0.14% and 90.8±0.03% after applying SSA. COMPARISON WITH EXISTING METHOD: The new T-F representation has been compared with the existing benchmarks. Our results prove that, the proposed method well outperforms the previous methods in terms of identification and representation of sleep stages. CONCLUSION: Experimental results confirm the performance improvement in terms of classification rate and also representative T-F domain.
BACKGROUND: Manual sleep scoring is deemed to be tedious and time consuming. Even among automatic methods such as time-frequency (T-F) representations, there is still room for more improvement. NEW METHOD: To optimise the efficiency of T-F domain analysis of sleep electroencephalography (EEG) a novel approach for automatically identifying the brain waves, sleep spindles, and K-complexes from the sleep EEG signals is proposed. The proposed method is based on singular spectrum analysis (SSA). The single-channel EEG signal (C3-A2) is initially decomposed and then the desired components are automatically separated. In addition, the noise is removed to enhance the discrimination ability of features. The obtained T-F features after preprocessing stage are classified using a multi-class support vector machines (SVMs) and used for the identification of four sleep stages over three sleep types. Furthermore, to emphasise on the usefulness of the proposed method the automatically-determined spindles are parameterised to discriminate three sleep types. RESULT: The four sleep stages are classified through SVM twice: with and without preprocessing stage. The mean accuracy, sensitivity, and specificity for before the preprocessing stage are: 71.5±0.11%, 56.1±0.09% and 86.8±0.04% respectively. However, these values increase significantly to 83.6±0.07%, 70.6±0.14% and 90.8±0.03% after applying SSA. COMPARISON WITH EXISTING METHOD: The new T-F representation has been compared with the existing benchmarks. Our results prove that, the proposed method well outperforms the previous methods in terms of identification and representation of sleep stages. CONCLUSION: Experimental results confirm the performance improvement in terms of classification rate and also representative T-F domain.
Authors: Luis de Santiago; E M Sánchez Morla; Miguel Ortiz; Elena López; Carlos Amo Usanos; M C Alonso-Rodríguez; R Barea; Carlo Cavaliere-Ballesta; Alfredo Fernández; Luciano Boquete Journal: PLoS One Date: 2019-04-04 Impact factor: 3.240