Abstract
Modern operational environments can place significant demands on a service member's cognitive resources, increasing the risk of errors or mishaps due to overburden. The ability to monitor cognitive burden and associated performance within operational environments is critical to improving mission readiness. As a key step toward a field-ready system, we developed a simulated marksmanship scenario with an embedded working memory task in an immersive virtual reality environment. As participants performed the marksmanship task, they were instructed to remember numbered targets and recall the sequence of those targets at the end of the trial. Low and high cognitive load conditions were defined as the recall of three- and six-digit strings, respectively. Physiological and behavioral signals recorded included speech, heart rate, breathing rate, and body movement. These features were input into a random forest classifier that significantly discriminated between the low- and high-cognitive load conditions (AUC = 0.94). Behavioral features of gait were the most informative, followed by features of speech. We also showed the capability to predict performance on the digit recall (AUC = 0.71) and marksmanship (AUC = 0.58) tasks. The experimental framework can be leveraged in future studies to quantify the interaction of other types of stressors and their impact on operational cognitive and physical performance.
Highlights
Cognitive load is a construct that represents the amount of processing resources required by a given task (Paas et al, 2003)
This is true in modern operational environments, which place significant demands on a service member’s cognitive resources due to high physical and mental demands, sleep restriction, and extreme environmental conditions (Friedl, 2012; Choi et al, 2014; Proctor et al, 2017; Smith et al, 2019)
In the current study we developed a simulated marksmanship scenario with an embedded working memory task that includes movement, gait, and audio-visual stimulation
Summary
Cognitive load is a construct that represents the amount of processing resources (to include working memory) required by a given task (Paas et al, 2003). There is a significant gap in capability to unobtrusively monitor cognitive load in order to mitigate the deleterious effects of fatigue, facilitate learning, and optimize task performance. This is true in modern operational environments, which place significant demands on a service member’s cognitive resources due to high physical and mental demands, sleep restriction, and extreme environmental conditions (Friedl, 2012; Choi et al, 2014; Proctor et al, 2017; Smith et al, 2019). One aspect of cognitive capacity that is frequently quantified is working memory, a neural system for temporary storage and management of information required to carry out cognitive tasks (Oberauer and Kliegl, 2006). McDuff et al (2014) found that pupil diameter increased monotonically as the number of digits held in working memory increased up to 9 digits
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