4.7 Article

Capturing Interaction Quality in Long Duration (Simulated) Space Missions With Wearables

Journal

IEEE TRANSACTIONS ON AFFECTIVE COMPUTING
Volume 14, Issue 3, Pages 2139-2152

Publisher

IEEE-INST ELECTRICAL ELECTRONICS ENGINEERS INC
DOI: 10.1109/TAFFC.2022.3176967

Keywords

Sensors; Wearable computers; Estimation; Space missions; Particle measurements; Atmospheric measurements; Wearable sensors; Learnable pooling; long duration space missions-; missing data; social interactions; temporal convolutional networks; wearable sensing

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In this study, the use of wearables and machine learning techniques to evaluate the quality of social interactions between crew members in a long-duration space mission is proposed. The method achieves better performance compared to hand-crafted features and alternative approaches.
Space exploration is evolving with the recent increase in interest and investment. For the success of planned long-duration crewed missions, good interpersonal interactions between crew members are crucial. In this study, we evaluate the use of wearables for detection and estimation of the quality of each social interaction participants have throughout a long mission rather than aggregate measures of interactions. Our proposed method utilizes Temporal Convolutional Networks(TCNs) for extracting individual representations from acceleration and audio streams and learnable pooling layers(NetVLAD) to aggregate these representations into fixed-size representations. Use of NetVLAD layers provides an intelligent alternative to simple aggregation for handling variable-sized interactions and interactions with missing data. We evaluate our method on a 4-month simulated space mission where 5 participants wore Sociometric Badges and provided reports on their interactions in terms of effectiveness, frustration, and satisfaction. Our method provides an average ROC-AUC score of 0.64. Since we are not aware of any comparable baselines, we compare our method to hand-crafted features formerly utilized for cohesion estimation in similar scenarios and show it significantly outperforms them. We also present ablation studies where we replace the components in our approach with well-known alternatives and show that they provide better performance than their respective counterparts.

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