Abstract
Sleep staging is the basis of sleep assessment and plays a crucial role in the early diagnosis and intervention of sleep disorders. Manual sleep staging by a specialist is time-consuming and is influenced by subjective factors. Moreover, some automatic sleep staging algorithms are complex and inaccurate. The paper proposes a single-channel EEG-based sleep staging method that provides reliable technical support for diagnosing sleep problems. In this study, 59 features were extracted from three aspects: time domain, frequency domain, and nonlinear indexes based on single-channel EEG data. Support vector machine, neural network, decision tree, and random forest classifier were used to classify sleep stages automatically. The results reveal that the random forest classifier has the best sleep staging performance among the four algorithms. The recognition rate of the Wake phase was the highest, at 92.13%, and that of the N1 phase was the lowest, at 73.46%, with an average accuracy of 83.61%. The embedded method was adopted for feature filtering. The results of sleep staging of the 11-dimensional features after filtering show that the random forest model achieved 83.51% staging accuracy under the condition of reduced feature dimensions, and the coincidence rate with the use of all features for sleep staging was 94.85%. Our study confirms the robustness of the random forest model in sleep staging, which also represents a high classification accuracy with appropriate classifier algorithms, even using single-channel EEG data. This study provides a new direction for the portability of clinical EEG monitoring.
Highlights
This study aimed to find an optimal feature set that can perform automatic sleep staging based on single-channel EEG signals by optimizing classifier algorithms, feature extraction, and feature filtering, which provide a theoretical reference for the design of clinical portable devices
It can be seen that the rapid eye movement (REM) period and N1 period were the two most confused, but the distinction between these two periods and the NREM 3 (N3) period was relatively high, and this model had a better effect in distinguishing deep sleep from light sleep; the false prediction of the N3 period was mainly concentrated in the NREM 2 (N2) period; the false prediction of the N2 period was scattered in the other four periods, and the false prediction of the W period was mainly concentrated in the N1 period
In this study, based on EEG signals of the Fpz-Cz-channel, a total of 57 features were extracted from three dimensions: time domain, frequency domain, and nonlinear parameters
Summary
This study aimed to find an optimal feature set that can perform automatic sleep staging based on single-channel EEG signals by optimizing classifier algorithms, feature extraction, and feature filtering, which provide a theoretical reference for the design of clinical portable devices
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
