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Paper detail

A Deep Learning Approach for the Segmentation of Electroencephalography Data in Eye Tracking Applications

The collection of eye gaze information provides a window into many critical aspects of human cognition, health and behaviour. Additionally, many neuroscientific studies complement the behavioural information gained from eye tracking with the high temporal resolution and neurophysiological markers provided by electroencephalography (EEG). One of the essential eye-tracking software processing steps is the segmentation of the continuous data stream into events relevant to eye-tracking applications, such as saccades, fixations, and blinks. Here, we introduce DETRtime, a novel framework for time-series segmentation that creates ocular event detectors that do not require additionally recorded eye-tracking modality and rely solely on EEG data. Our end-to-end deep learning-based framework brings recent advances in Computer Vision to the forefront of the times series segmentation of EEG data. DETRtime achieves state-of-the-art performance in ocular event detection across diverse eye-tracking experiment paradigms. In addition to that, we provide evidence that our model generalizes well in the task of EEG sleep stage segmentation.

preprint2022arXivOpen access
Lukas WolfArd KastratiMartyna Beata PłomeckaJie-Ming LiDustin KlebeAlexander VeichtRoger WattenhoferNicolas Langer
eess.SPMachine LearningArtificial Intelligence
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Lukas WolfArd KastratiMartyna Beata PłomeckaJie-Ming LiDustin KlebeAlexander VeichtRoger WattenhoferNicolas Langer

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