Cities are complicated places to fly. Tall buildings, local microclimates, high winds, and other factors present challenges – both known and unpredictable – for current and future air vehicles. But creating new air mobility solutions to move people and cargo will require addressing those challenges. And that’s where NASA’s Data & Reasoning Fabric (DRF) project can help.
DRF designs technology to help autonomous
airborne activities safely meet their full potential for
society’s benefit. Its intent is to form a connected,
interwoven “fabric” of intelligence that sends aircraft specific, tailored
information, wherever they are.
Reducing airspace congestion to increase
safety in cities while connecting people and services are the kinds of
considerations driving the DRF team. And so, in February and March, the team is
performing the first test of its technology in a simulated urban area, one
modeled on the Phoenix metropolitan area.
The DRF technology helps assemble diverse
sets of data from various providers, as well as reasoning services powered by
artificial intelligence, to make sense of the complex and dynamic airspace.
A familiar reasoning service is the
navigation app many people have on their phone. Different kinds of data – maps,
accident reports, traffic conditions – are drawn in by the app, which sorts
through it all and tells the driver the best route to take at the time.
Decisions needed by autonomous aircraft of
the future could be made in a similar way. And the web, or “fabric,” of
intelligence enabled by DRF will provide critical information to operators and
autonomous aircraft, wherever they are, to make decisions in time.
Across NASA, researchers are conducting Advanced Air Mobility studies that will transform U.S. communities, creating new ways to move people and goods in the sky. The data and AI-based decision-support tools enabled by the Data & Reasoning Fabric concept will help further the AAM community’s goals by providing information needed for future flight operations. Credits: NASA
Data and Decision-Making
In early February, NASA, along with its partners, began field trials for
the current prototype system. This partnership group included Autonomy
Association International of Mountain View, California, as well as members from
academia, industry, government, communities, tribal nations, and more than 22
cities across Arizona’s Maricopa, Pinal, Pima, and Yuma Counties.
“This activity can help providers of data and decision-support services
better understand the needs of future airspace users and the benefits of DRF,”
said Kenneth Freeman, DRF’s principal investigator at NASA’s Ames Research
Center in California’s Silicon Valley. “Users are able to compare multiple
services to select the one that fits their needs: weather data from this
source, air traffic updates from another. With further development, we expect
this model to potentially drive innovation in the industry, which could lead to
improvements in the quality of airspace services.”
The Phoenix test looks at specific scenarios where DRF could be useful, studying
them in the context of a simulated drone flight to deliver medical equipment
and supplies from downtown Phoenix to the outermost areas of the greater
region.
Future scenarios might involve insulin delivery for people in locations
with limited access to health care services or re-routing an air taxi around a
sudden dust storm.
The test participants are working within the digital ecosystem enabled by
DRF, assessing their ability to select data and reasoning services that support
safe and autonomous flight.
DRF’s potential to accelerate airborne emergency response was illustrated
in a previous test with the California wing of the Civil Air Patrol. Using
simulated drone flights, the DRF technology helped locate lightning-induced
wildfires more quickly than usual.
Agile Responses to Anomalies
When something unexpected occurs in a flight path, such as a storm, the
announcement of a no-fly zone, or a drop in communication coverage, safety
depends on the ability to make critical choices at a moment’s notice.
DRF’s current field test studies how well its system can support rerouting
an aircraft due to several different anomalies: communication disruptions – for
instance, between the aircraft and weather sensors, navigation aids, or ground
control – an unidentified or unexpected drone in the flight path, and sudden
changes in local weather conditions.
In such scenarios, DRF technology is designed to alert an aircraft
approaching one of these anomalies and connect them to services that can
provide more information and guidance to respond with agility.
To accomplish its goals, DRF uses edge computing, a system where data is
handled, processed, and stored locally – at the “edge” of the network – rather
than being sent to a cloud or a data center. This reduces the delays associated
with transmitting large sets of data and allows for faster decision-making in
time-sensitive situations.
A Future of Advanced Air Mobility
Across NASA, researchers are conducting Advanced Air Mobility studies that
will transform U.S. communities, creating new ways to move people and goods in
the sky. The data and AI-based decision-support tools enabled by the DRF
concept will help further the AAM community’s goals by providing information
needed for future flight operations.
This air transportation system of the future will include low-altitude
passenger travel options, cargo delivery, and public service capabilities. NASA
is delivering data that guides industry's development of electric air taxis and
drones and assists the Federal Aviation Administration’s safe integration of such
vehicles into the national airspace.
Today, the DRF team is looking ahead for needs that can be addressed with
autonomous flights supported by their digital ecosystem, helping enable the
future of air mobility.
DRF is an exploratory activity under the Convergent Aeronautics Solutions project, which is designed to give NASA researchers the resources and
pathways they need to determine whether their ideas to solve some of aviation’s
biggest technical challenges are feasible and potentially worthy of additional
pursuit within NASA or by industry.
Service providers, academics, and end users interested in partnering with
DRF can visit the project's website to learn more and connect with the team.
For news media: Members of the news media interested in covering this topic should reach out to the Ames newsroom.
Source: NASA’s Autonomous Aircraft Decision Tech Gets Simulated Urban Test | NASA
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