The
Navy Wants Special Fabrics That Can Monitor A Pilot's Health
The "biosensing garments" could help gather information about
incidents where aviators suffer hypoxia-like symptoms and about their general
wellbeing.
A Navy pilot climbs into the cockpit of an F/A-18E Super HornetUSN
The U.S. Navy is looking into buying specialized fabric to make biosensing
suits for its pilots and aircrew, which would be able to collect physiological
data, such as heart rates and deepness of breath. This comes as the service, as
well as the U.S. Air Force and NASA, continue to conduct research into and
search for solutions to the causes of hypoxia-like symptoms that have plagued
pilots across various aircraft types in recent years. The new clothing could
also collect more general data on the health and wellness of aviators to
improve their performance, avoid injuries, and more.
Naval Air Systems Command (NAVAIR) released the request for information
regarding "physiological monitoring fabrics" for "biosensing
garments suitable for Naval aviation" on Dec. 23, 2019. Steve Trimble,
Aviation Week's Defense editor and good friend of The War Zone, was among the
first notice the contracting announcement, highlighting it in a Tweet on Dec.
26.
NAVAIR says it wants fabrics that have good elasticity, being able to stretch
significantly without breaking and return to their original shape quickly,
while also having "excellent next-to-skin comfort." They also need to
pass ASTM International industrial standards for resistance to heat, helping to
ensure that they do not "melt or drip" during a fire. This is a
particularly important safety requirement as the U.S. military has found in the
past that some synthetic fabrics could melt and stick to skin, causing or
exacerbating already serious burns that personnel might suffer during combat or
accidents.
Biosensing clothing isn't new, having been in use in the professional athletic
world for years now. Typically these garments use fabrics with interwoven
silver fibers or other materials that can sense physiological changes, such as
increases and decreases in heat or pressure. They then convey that information
to a small, wearable computer that can interpret this information as a faster
or slower heart rate or deeper or shallower breathing.
Wireless links then often display the desired information on an individual's
smartphone or other devices via an app. Altogether, this kind of "smart
clothing" operates similarly in many respects to other kinds of wearable
health and fitness devices, such the Fitbit.
NAVAIR's contracting notice does not say what its specific requirement is for
the biosensing garments, but one immediate use for smart clothing could
certainly be to help the Navy gather information to gain more insight into
persistent and often unexplained reports of hypoxia-like symptoms among its
aviators. The service actually went looking for suits with built-in physiological
sensors to help combat hypoxia back in 2009, but it's not immediately clear how
far those efforts progressed.
Air Force pilots have suffered similar issues over the years, as well. The
incidents have occurred with individuals flying a number of aircraft types and
potential issues with onboard oxygen generation systems, or OBOGS, have
typically been cited as a likely root cause. You can read more about these
so-called "physiological events" and what the services have been
doing to mitigate them in these past War Zone stories.
One of the Navy's decisions was to, starting in July 2017, begin issuing $450
Garmin Fenix 3 wristwatches to all pilots flying F/A-18C/D Hornets, F/A-18E/F
Super Hornets, and EA-18G Growlers. The service has seen some of the most consistent
reports of hypoxia-like symptoms from aviators flying these types. Though the
Navy primarily purchased the Fenix 3s because they can detect changes in
ambient air pressure, as well as provide altitude and course heading
information, the watches are also billed as fitness devices and can come
equipped with a heart rate monitor and other features.
Smart clothing for naval aviators would be able to gather data to provide a
much more comprehensive picture of an aviator's health before, during, and after
any physiological event. Combined with health and flight data from other
sensors built into the aircraft, this could help the services get a better
sense of what pilots are experiencing and why.
Networked biosensing flight suits could also send data to ground stations in
near-real-time, allowing for offboard monitoring, which means commanders might
be able to warn their pilots about potential issues. Hypoxia-like symptoms can
include disorientation and confusion, which can make it difficult for an individual
to necessarily notice what is going on by themselves.
Beyond the hypoxia issue specifically, issuing smart clothing to aviators could
simply help build databases of valuable baseline physiological information.
Flying fighter jets especially is taxing on the body in many ways that aren't
necessarily well understood. In August 2018, NASA began a program that was
primarily aimed at helping to resolve the reported hypoxia issues across the
Navy and Air Force. However, the main immediate goal was simply to collect
physiological data to help researchers better understand what was normal and
abnormal for pilots flying high-performance combat jets.
NASA
NASA pilot Jim Less tries on a Cobham VigiLOX system connected to his normal
oxygen mask. This system collects physiological data, as well as information
about the ambient pressure and other environmental factors in the cockpit.
"We found that there has been very little investigation surrounding the
human in the cockpit," Clinton Cragg, a principal engineer at the NASA
Engineering and Safety Center, explained to members of Congress in 2018.
"We don't have the amount of oxygen in his mask, the amount of CO2 [carbon
dioxcide] in his mask, the pressure you'd want to know about in the cockpit,
nor the pilot's breathing rates. Those types of things are what could help us
do a full physiological assessment of what's happening to the pilot."
Databases of physiological information could also simply help maximize the
performance of naval aviators inside and out of their aircraft. The data could
allow Navy officials to gain insight into how certain demographic groups, as
well as specific individuals, perform athletically in various situations under
different circumstances.
This, in turn, could help in determine optimal fitness requirements and setting
other health-related benchmarks. The collected information could also expose
significant trends, such as the occurrence of injuries or other illnesses, and
then link them to certain activities or environmental factors. With the help of
artificial intelligence-driven algorithms, it might be possible in the future
to more quickly spot worrying increases in certain conditions among specific
groups, more conclusive determine the root causes, and remedy them.
The rest of the U.S. military has also been taking note of the potential
benefits biosensing smart clothing in recent years for the same reasons. Just
earlier this year, the U.S. Marine Corps issued their own request for
information regarding physiological monitoring garments that would allow them
to "tailor conditioning and operational training in order to minimize
injuries and optimize strength building and overall operational
performance." The U.S. Air Force and Army have also been exploring this
kind of technology.
All told, no matter how much biosensing flight suits do or don't ultimately
help with determining the causes of reported hypoxia-like symptoms among Navy
aviators, these garments could still become standard issue in the coming years.
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