FaceGuard: A Wearable System To Avoid Face Touching

Allan Michael Michelin; Georgios Korres; Sara Ba'ara; Hadi Assadi; Haneen Alsuradi; Rony R Sayegh; Antonis Argyros; Mohamad Eid

doi:10.3389/frobt.2021.612392

FaceGuard: A Wearable System To Avoid Face Touching

Front Robot AI. 2021 Apr 8:8:612392. doi: 10.3389/frobt.2021.612392. eCollection 2021.

Authors

Allan Michael Michelin¹, Georgios Korres¹, Sara Ba'ara¹, Hadi Assadi¹, Haneen Alsuradi¹, Rony R Sayegh², Antonis Argyros³, Mohamad Eid¹

Affiliations

¹ Applied Interactive Multimedia Lab, Engineering Division, New York University Abu Dhabi, Abu Dhabi, United Arab Emirates.
² Clinical Associate Professor, Cornea and Refractive Surgery, Cleveland Clinic Abu Dhabi, Abu Dhabi, United Arab Emirates.
³ Professor at the Computer Science Department (CSD), University of Crete (UoC), Crete, Greece.

Abstract

Most people touch their faces unconsciously, for instance to scratch an itch or to rest one's chin in their hands. To reduce the spread of the novel coronavirus (COVID-19), public health officials recommend against touching one's face, as the virus is transmitted through mucous membranes in the mouth, nose and eyes. Students, office workers, medical personnel and people on trains were found to touch their faces between 9 and 23 times per hour. This paper introduces FaceGuard, a system that utilizes deep learning to predict hand movements that result in touching the face, and provides sensory feedback to stop the user from touching the face. The system utilizes an inertial measurement unit (IMU) to obtain features that characterize hand movement involving face touching. Time-series data can be efficiently classified using 1D-Convolutional Neural Network (CNN) with minimal feature engineering; 1D-CNN filters automatically extract temporal features in IMU data. Thus, a 1D-CNN based prediction model is developed and trained with data from 4,800 trials recorded from 40 participants. Training data are collected for hand movements involving face touching during various everyday activities such as sitting, standing, or walking. Results showed that while the average time needed to touch the face is 1,200 ms, a prediction accuracy of more than 92% is achieved with less than 550 ms of IMU data. As for the sensory response, the paper presents a psychophysical experiment to compare the response time for three sensory feedback modalities, namely visual, auditory, and vibrotactile. Results demonstrate that the response time is significantly smaller for vibrotactile feedback (427.3 ms) compared to visual (561.70 ms) and auditory (520.97 ms). Furthermore, the success rate (to avoid face touching) is also statistically higher for vibrotactile and auditory feedback compared to visual feedback. These results demonstrate the feasibility of predicting a hand movement and providing timely sensory feedback within less than a second in order to avoid face touching.

Keywords: IMU-based hand tracking; face touching avoidance; sensory feedback; vibrotactile stimulation; wearable technologies for health care.