Title :
Sleep spindle detection using time-frequency sparsity
Author :
Parekh, Ankit ; Selesnick, I.W. ; Rapoport, David M. ; Ayappa, Indu
Author_Institution :
Sch. of Eng., Dept. of Electr. & Comput. Eng., New York Univ., New York, NY, USA
Abstract :
This paper proposes an EEG processor for sleep spindle detection algorithms. It non-linearly separates the raw EEG signal into non-oscillatory transient and sustained rhythmic oscillation components using long and short windows for the short-time Fourier transform. The processor utilizes the fact that sleep spindles can be sparsely represented via the inverse of a short-time Fourier transform. Five sleep spindle detectors were tested on the EEG database with and without the proposed EEG processor. We achieved an improvement of 13.3% in the by-sample F1 score, and 13.9% in the by-sample Matthews Correlation Coefficient score of these algorithms when the processed EEG was used for spindle detection. The processor was able to improve the scores by reducing the number of false positive spindles and increasing the number of true positive spindles detected.
Keywords :
Fourier transforms; electroencephalography; medical signal detection; medical signal processing; sleep; time-frequency analysis; EEG database; EEG processor; EEG signal; Matthews correlation coefficient score; nonoscillatory transient; short-time Fourier transform; sleep spindle detection algorithms; sustained rhythmic oscillation components; time-frequency sparsity; Detection algorithms; Detectors; Electroencephalography; Matching pursuit algorithms; Oscillators; Sleep; Transient analysis; Short time Fourier transform; convex optimization; pursuit algorithms; spectrogram;
Conference_Titel :
Signal Processing in Medicine and Biology Symposium (SPMB), 2014 IEEE
Conference_Location :
Philadelphia, PA
DOI :
10.1109/SPMB.2014.7002965
