Toward Cognitive Load Inference for Attention Management in Ubiquitous Systems

From not disturbing a focused programmer to entertaining a restless commuter waiting for a train, personal ubiquitous computing devices could greatly enhance their interaction with humans, should these devices only be aware of their users’ cognitive engagement. Despite impressive advances in the inference of human movement, physical activity, routines, and other behavioral aspects, inferring cognitive load remains challenging due to the subtle manifestations of users’ mental engagements via vital signal reactions. These signals are traditionally captured with expensive, obtrusive, and purpose-built equipment, preventing seamless cognitive load inference for human–computer interaction adaptation. In this article, we present our achievements toward enabling large-scale unobtrusive cognitive load inference. Our approaches rely on mining sensor data collected by commodity wearable devices, and software-defined radio-based wireless radars. We also discuss further related research avenues, as well as ethical issues surrounding automatic cognitive load inference.

[1]  Alain Pruski,et al.  Emotion recognition for human-machine communication , 2008, 2008 IEEE/RSJ International Conference on Intelligent Robots and Systems.

[2]  Veljko Pejovic,et al.  My Watch Says I'm Busy: Inferring Cognitive Load with Low-Cost Wearables , 2018, UbiComp/ISWC Adjunct.

[3]  Jim Nixon,et al.  Measuring mental workload using physiological measures: A systematic review. , 2019, Applied ergonomics.

[4]  Rob Miller,et al.  Smart Homes that Monitor Breathing and Heart Rate , 2015, CHI.

[5]  G. Benchetrit Breathing pattern in humans: diversity and individuality. , 2000, Respiration physiology.

[6]  Veljko Pejovic,et al.  Wi-Mind: Wireless Mental Effort Inference , 2018, UbiComp/ISWC Adjunct.

[7]  John R Anderson,et al.  An integrated theory of the mind. , 2004, Psychological review.

[8]  Veljko Pejovic,et al.  A Survey of Attention Management Systems in Ubiquitous Computing Environments , 2018, Proc. ACM Interact. Mob. Wearable Ubiquitous Technol..

[9]  G. Zajicek,et al.  The Wisdom of the Body , 1934, Nature.

[10]  Cary Stothart,et al.  The attentional cost of receiving a cell phone notification. , 2015, Journal of experimental psychology. Human perception and performance.

[11]  F. Vetere,et al.  Cognitive Heat , 2017 .

[12]  N. Taatgen,et al.  The problem state: a cognitive bottleneck in multitasking. , 2010, Journal of experimental psychology. Learning, memory, and cognition.

[13]  Brian P. Bailey,et al.  Understanding changes in mental workload during execution of goal-directed tasks and its application for interruption management , 2008, TCHI.

[14]  Gloria Mark,et al.  The cost of interrupted work: more speed and stress , 2008, CHI.

[15]  Eleanor O' Neill,et al.  The cost of not paying attention , 2017 .

[16]  P. Palatini,et al.  Need for a revision of the normal limits of resting heart rate. , 1999, Hypertension.

[17]  Ted Selker,et al.  Task Load Estimation and Mediation Using Psycho-physiological Measures , 2016, IUI.

[18]  Dario D. Salvucci,et al.  Threaded cognition: an integrated theory of concurrent multitasking. , 2008, Psychological review.

[19]  F. Shaffer,et al.  A healthy heart is not a metronome: an integrative review of the heart's anatomy and heart rate variability , 2014, Front. Psychol..

[20]  James H. Aylor,et al.  Computer for the 21st Century , 1999, Computer.

[21]  Farrokh Marvasti,et al.  Heart Rate Tracking using Wrist-Type Photoplethysmographic (PPG) Signals during Physical Exercise with Simultaneous Accelerometry , 2015, IEEE Signal Processing Letters.

[22]  Jodi Forlizzi,et al.  Psycho-physiological measures for assessing cognitive load , 2010, UbiComp.

[23]  Adrian Basarab,et al.  Towards an automatic early stress recognition system for office environments based on multimodal measurements: A review , 2016, J. Biomed. Informatics.