Microsleep and alertness monitoring in French Air Force long haul pilots

Chennaoui, Mounir; Beers, Pascal Van; Caid, Samira; Guillard, Mathias; Boissin, Jacqueline; Sauvet, Fabien

doi:10.1016/j.jsams.2017.09.499

Cited by 1 publication

(1 citation statement)

References 0 publications

Supporting

Mentioning

Contrasting

Order By: Relevance

“…36 The French military is now using a system developed by military researchers to optimize rest and flight schedules and to modify tactics, techniques and procedures for more effective performance. 37 This represents an important near term military PSM application. The value of near infrared spectroscopy forehead measurements, perhaps in conjunction with single channel EEG, may add to alertness predictions.…”

Section: Early Models Of Alertness and Fitness For Duty Assessmentmentioning

confidence: 99%

Military applications of soldier physiological monitoring

Friedl

2018

Journal of Science and Medicine in Sport

135

View full text Add to dashboard Cite

Wearable physiological status monitoring is part of modern precision medicine that permits predictions about an individual's health and performance from their real-time physiological status (RT-PSM) instead of relying on population-based predictions informed by estimated human, mission, and environmental/ambient conditions. RT-PSM systems have useful military applications if they are soldier-acceptable and provide important actionable information. Most commercially available systems do not address relevant military needs, typically lack the validated algorithms that make real time computed information useful, and are not open architected to be integrated with the soldier technological ecology. Military RT-PSM development requires committed investments in iterative efforts involving physiologists, biomedical engineers, and the soldier users. Military operational applications include: (1) technological enhancement of performance by providing individual status information to optimize self-regulation, workload distribution, and enhanced team sensing/situational awareness; (2) detection of impending soldier failure from stress load (physical, psychological, and environmental); (3) earliest possible detection of threat agent exposure that includes the "human sensor"; (4) casualty detection, triage, and early clinical management; (5) optimization of individual health and fitness readiness habits; and (6) long term health risk-associated exposure monitoring and dosimetry. This paper is focused on the performance-related applications and considers near term predictions such as thermal-work limits, alertness and fitness for duty status, musculoskeletal fatigue limits, neuropsychological status, and mission-specific physiological status. Each new measurement capability has provided insights into soldier physiology and advances the cycle of invention, lab and field testing, new discovery and redesign.

show abstract

Section: Early Models Of Alertness and Fitness For Duty Assessmentmentioning

confidence: 99%