JMIR Publications

ABSTRACT

Background:

Stress is a risk factor associated with physiological and mental health problems. Unobtrusive, continuous stress sensing would enable precision health monitoring and proactive interventions, but current sensing methods are often inconvenient, expensive, or suffer from limited adherence. Prior work has shown the possibility to detect acute stress using biomechanical models derived from passive logging of computer input devices.

Objective:

To detect acute stress from passive movement measurements of everyday interactions on a laptop trackpad (click, steer, drag and drop).

Methods:

We built upon previous work, detecting acute stress through the biomechanical analyses of canonical computer mouse interactions, and extended it to study similar interactions with the trackpad. 18 participants carried out 40 trials each of three different types of movement (click, steer, drag and drop), under both relaxed and stressed conditions.

Results:

The mean and standard deviation (SD) of the contact area under the finger were higher when clicking trials were performed under stressed versus relaxed conditions (mean area: P = .009, effect size = 0.76; SD area: P = .01, effect size = 0.69). Further, our results show that as little as four clicks on a trackpad can be used to detect binary levels of acute stress (i.e., whether it is present or not).

Conclusions:

We present evidence that scalable, inexpensive, and unobtrusive stress sensing can be done via repurposing passive monitoring of computer trackpad usage.