Justin Link, left, pilot for small uncrewed aircraft systems, and Justin Hall, chief pilot for small uncrewed aircraft systems, install weather instruments on NASA’s Alta X drone at the agency’s Armstrong Flight Research Center in Edwards, California. Members of the center’s NASA Armstrong Dale Reed Subscale Flight Research Laboratory used the Alta X to support the NASA’s FireSense project in March 2025 for a prescribed burn in Geneva State Forest, which is about 100 miles south of Montgomery, Alabama.

Justin Link, left, pilot for small uncrewed aircraft systems, and Justin Hall, chief pilot for small uncrewed aircraft systems, install weather instruments on NASA’s Alta X drone at the agency’s Armstrong Flight Research Center in Edwards, California. Members of the center’s NASA Armstrong Dale Reed Subscale Flight Research Laboratory used the Alta X to support the NASA’s FireSense project in March 2025 for a prescribed burn in Geneva State Forest, which is about 100 miles south of Montgomery, Alabama.

Justin Link, pilot for small uncrewed aircraft systems, installs weather instruments on NASA’s Alta X drone at the agency’s Armstrong Flight Research Center in Edwards, California. Members of the center’s Dale Reed Subscale Flight Research Laboratory used the Alta X to support the agency’s FireSense project in March 2025 for a prescribed burn in Geneva State Forest, which is about 100 miles south of Montgomery, Alabama.

Justin Link, left, pilot for small uncrewed aircraft systems, and Justin Hall, chief pilot for small uncrewed aircraft systems, install weather instruments on NASA’s Alta X drone at the agency’s Armstrong Flight Research Center in Edwards, California. Members of the center’s Dale Reed Subscale Flight Research Laboratory used the Alta X to support the agency’s FireSense project in March 2025 for a prescribed burn in Geneva State Forest, which is about 100 miles south of Montgomery, Alabama.

Derek Abramson, left, chief engineer for the Dale Reed Subscale Flight Research Laboratory, and Justin Link, small unmanned aircraft systems pilot, prepare an atmospheric probe model for flight on Oct. 22, 2024. A quad rotor remotely piloted aircraft released the probe above Rogers Dry Lake, a flight area adjacent to NASA’s Armstrong Flight Research Center in Edwards, California. The probe was designed and built at the center.

Derek Abramson, left, chief engineer for the Dale Reed Subscale Flight Research Laboratory, and Justin Link, small unmanned aircraft system pilot, carry the atmospheric probe model and a quad rotor remotely piloted aircraft to position it for flight on Oct. 24, 2024. John Bodylski, probe principal investigator, right, and videographer Jacob Shaw watch the preparations. Once at altitude, the quad rotor aircraft released the probe above Rogers Dry Lake, a flight area adjacent to NASA’s Armstrong Flight Research Center in Edwards, California. The probe was designed and built at the center.

Students look at a subscale model at the Dale Reed Subscale Flight Research Laboratory at NASA’s Armstrong Research Flight Center in Edwards, California. The students are from the engineering club from Palmdale High School in Palmdale, California.

Students look at a subscale model at the Dale Reed Subscale Flight Research Laboratory at NASA’s Armstrong Research Flight Center in Edwards, California. The students are from the engineering club from Palmdale High School in Palmdale, California.

Justin Hall assembles parts of a cradle for a rotorcraft that will air launch a proposed atmospheric probe in summer 2024 at NASA’s Armstrong Flight Research Center in Edwards, California. Hall is a designer, technician, and pilot at the center’s Dale Reed Subscale Flight Research Laboratory.

Justin Hall holds a mold of the top section of an atmospheric probe. The probe is incorporated into part of a modified cradle for a rotorcraft, which will air launch the probe in summer 2024 at NASA’s Armstrong Flight Research Center in Edwards, California. Hall is a designer, technician, and pilot at the center’s Dale Reed Subscale Flight Research Laboratory.

Justin Hall bonds pieces of a cradle for a rotorcraft launch system for a proposed atmospheric probe set to fly in summer 2024 at NASA’s Armstrong Flight Research Center in Edwards, California. Hall is a designer, technician, and pilot at the center’s Dale Reed Subscale Flight Research Laboratory.

Robert “Red” Jensen and Justin Hall position an atmospheric probe, its host cradle, and the rotorcraft that will air launch the probe at NASA’s Armstrong Flight Research Center in Edwards, California. Jensen and Hall are designers, technicians, and pilots at the center’s Dale Reed Subscale Flight Research Laboratory.

The Preliminary Research Aerodynamic Design to Land on Mars, or Prandtl-M, glider flies after a magnetic release mechanism on the Carbon-Z Cub was activated to air launch the aircraft. A team from NASA's Armstrong Flight Research Center in Edwards, California, conducted the successful research flight.

Justin Hall, left, attaches the Preliminary Research Aerodynamic Design to Land on Mars, or Prandtl-M, glider onto the Carbon-Z Cub, which Justin Link steadies. Hall and Link are part of a team from NASA's Armstrong Flight Research Center in Edwards, California, that uses an experimental magnetic release mechanism to air launch the glider.

A team from NASA's Armstrong Flight Research Center in Edwards, California, prepares a Carbon-Z Cub to air launch the Preliminary Research Aerodynamic Design to Land on Mars, or Prandtl-M, glider from a magnetic release mechanism on the cub.

A Preliminary Research Aerodynamic Design to Land on Mars, or Prandtl-M, glider was air launched Sept. 7 using a magnetic release mechanism mounted on a Carbon-Z Cub. The team, based at NASA's Armstrong Flight Research Center in Edwards, California, includes, from left, Paul Bean, Justin Hall, Red Jensen, Justin Link, and Nathan Allaire.

Justin Hall, left, controls a subscale aircraft as Justin Link holds the aircraft in place during preliminary engine tests on Friday, Sept. 12, 2025, at NASA’s Armstong Flight Research Center in Edwards, California. Hall is chief pilot at the center’s Dale Reed Subscale Flight Research Laboratory and Link is a pilot for small uncrewed aircraft systems.

Justin Hall attaches part of the landing gear of a subscale aircraft on Friday, Sept. 12, 2025, at NASA’s Armstong Flight Research Center in Edwards, California. Hall is the chief pilot at the center’s Dale Reed Subscale Flight Research Laboratory.

Justin Link turns a subscale aircraft on its side to continue work to mark where the engine cowl will go and where to line it up for attachment on Wednesday, Sept. 3, 2025, at NASA’s Armstong Flight Research Center in Edwards, California. Link is a pilot for small uncrewed aircraft systems at the center’s Dale Reed Subscale Flight Research Laboratory.

Justin Hall, left, and Justin Link attach a section of landing gear onto a subscale aircraft on Friday, Sept. 12, 2025, at NASA’s Armstong Flight Research Center in Edwards, California. Hall is chief pilot at the center’s Dale Reed Subscale Flight Research Laboratory and Link is a pilot for small uncrewed aircraft systems.

Justin Link, left, and Justin Hall attach an engine onto a subscale aircraft on Wednesday, Sept. 3, 2025, at NASA’s Armstong Flight Research Center in Edwards, California. Link is a pilot for small uncrewed aircraft systems at the center’s Dale Reed Subscale Flight Research Laboratory and Hall is the lab’s chief pilot.

Justin Hall, left, and Justin Link attach the wings onto a subscale aircraft on Wednesday, Sept. 3, 2025, at NASA’s Armstong Flight Research Center in Edwards, California. Hall is chief pilot at the center’s Dale Reed Subscale Flight Research Laboratory and Link is a pilot for small uncrewed aircraft systems.

Justin Link, left, holds the subscale aircraft in place, while Justin Hall manages engine speed during preliminary engine tests on Friday, Sept. 12, 2025, at NASA’s Armstong Flight Research Center in Edwards, California. Link is a pilot for small uncrewed aircraft systems at the center’s Dale Reed Subscale Flight Research Laboratory and Hall is the chief pilot.

Justin Hall, left, and Justin Link secure a wing onto a subscale aircraft on Wednesday, Sept. 3, 2025, at NASA’s Armstong Flight Research Center in Edwards, California. Hall is chief pilot at the center’s Dale Reed Subscale Flight Research Laboratory and Link is a pilot for small uncrewed aircraft systems.

The atmospheric probe, right, flew after release from a quad rotor remotely piloted aircraft, left, on Oct. 22, 2024, above Rogers Dry Lake, a flight area adjacent to NASA’s Armstrong Flight Research Center in Edwards, California. The probe was designed and built at the center.

An atmospheric probe model attached upside down to a quad rotor remotely piloted aircraft ascends with the Moon visible on Oct. 22, 2024. The quad rotor aircraft released the probe above Rogers Dry Lake, a flight area adjacent NASA’s Armstrong Flight Research Center in Edwards, California. The probe was designed and built at the center.

Justin Link, left, small unmanned aircraft systems pilot, and Justin Hall, chief pilot of small unmanned aircraft systems, prepare an atmospheric probe model for flight on Oct. 22, 2024. A quad rotor remotely piloted aircraft released the probe above Rogers Dry Lake, a flight area adjacent NASA’s Armstrong Flight Research Center in Edwards, California. The probe was designed and built at the center.

The atmospheric probe model flies free after release from a quad rotor remotely piloted aircraft above Rogers Dry Lake, a flight area adjacent NASA’s Armstrong Flight Research Center in Edwards, California, on Oct. 22, 2024. The probe was designed and built at the center.

A quad rotor remotely piloted aircraft releases the atmospheric probe model above Rogers Dry Lake, a flight area adjacent NASA’s Armstrong Flight Research Center in Edwards, California, on Oct. 22, 2024. The probe was designed and built at the center.

Justin Link, left, unmanned aircraft systems pilot, and Justin Hall, chief pilot for small unmanned aircraft systems, prepare to fly a quad rotor remotely piloted aircraft and an atmospheric probe model on Oct. 22, 2024. John Bodylski, probe principal investigator, watches the preparation for flight. The quad rotor aircraft released the probe above Rogers Dry Lake, a flight area adjacent NASA’s Armstrong Flight Research Center in Edwards, California. The probe was designed and built at the center.

Justin Hall, left, chief pilot of small unmanned aircraft systems, carries the atmospheric probe at NASA’s Armstrong Flight Research Center in Edwards, California. The probe, which was designed and built at the center, flew after release from a quad rotor remotely piloted aircraft on Oct. 22, 2024, above Rogers Dry Lake, a flight area adjacent to the NASA center. At right, Justin Link, unmanned aircraft systems pilot, checks out the controllers for the two aircraft.

An atmospheric probe model attached upside down to a quad rotor remotely piloted aircraft ascends with the Moon visible on Oct. 22, 2024. The quad rotor aircraft released the probe above Rogers Dry Lake, a flight area adjacent NASA’s Armstrong Flight Research Center in Edwards, California. The probe was designed and built at the center.

The atmospheric probe model flies free after release from a quad rotor remotely piloted aircraft above Rogers Dry Lake, a flight area adjacent NASA’s Armstrong Flight Research Center in Edwards, California, on Oct. 22, 2024. The probe was designed and built at the center.

An atmospheric probe model attached upside down to a quad rotor remotely piloted aircraft ascends with the Moon visible on Oct. 22, 2024. The quad rotor aircraft released the probe above Rogers Dry Lake, a flight area adjacent NASA’s Armstrong Flight Research Center in Edwards, California. The probe was designed and built at the center.

Justin Link, left, small unmanned aircraft systems pilot; John Bodylski, atmospheric probe principal investigator; and Justin Hall, chief pilot of small unmanned aircraft systems, discuss details of the atmospheric probe flight plan on Oct. 22, 2024. A quad rotor remotely piloted aircraft released the probe above Rogers Dry Lake, a flight area adjacent NASA’s Armstrong Flight Research Center in Edwards, California. The probe was designed and built at the center.

An atmospheric probe model attached upside down to a quad rotor remotely piloted aircraft ascends with the Moon visible on Oct. 22, 2024. The quad rotor aircraft released the probe above Rogers Dry Lake, a flight area adjacent NASA’s Armstrong Flight Research Center in Edwards, California. The probe was designed and built at the center.

The atmospheric probe model on a stand is prepped for flight and release from a quad rotor remotely piloted aircraft. The probe successfully flew on Oct. 22, 2024, above Rogers Dry Lake, a flight area adjacent to NASA’s Armstrong Flight Research Center in Edwards, California. The probe was designed and built at the center. In the background from left are Justin Hall, chief pilot of small, unmanned aircraft systems; Justin Link, small unmanned aircraft systems pilot; communications writer Jay Levine; and John Bodylski, atmospheric probe principal investigator.

An atmospheric probe model attached upside down to a host quad rotor remotely piloted aircraft lifts off on Oct. 22, 2024. The quad rotor aircraft released the probe above Rogers Dry Lake, a flight area adjacent NASA’s Armstrong Flight Research Center in Edwards, California. The probe was designed and built at the center.

An atmospheric probe model is attached upside down to a quad rotor remotely piloted aircraft on Oct. 22, 2024. The quad rotor aircraft released the probe above Rogers Dry Lake, a flight area adjacent NASA’s Armstrong Flight Research Center in Edwards, California. The probe was designed and built at the center.

Justin Hall, chief pilot of small unmanned aircraft systems, prepares the atmospheric probe for flight above Rogers Dry Lake, a flight area adjacent NASA’s Armstrong Flight Research Center in Edwards, California. At right, Justin Link, small unmanned aircraft systems pilot, assists. The probe, designed and built at the center, flew after release from a quad rotor remotely piloted aircraft on Oct. 22, 2024.

From left Eric Becker watches as Nathan Sam, Robert 'Red' Jensen and Justin Hall attach a Prandtl-M aircraft onto the Carbon Cub aircraft that air launched it at NASA's Armstrong Flight Research Center in California. The aircraft is the second of three prototypes of varying sizes to provide scientists with options to fly sensors in the Martian atmosphere to collect weather and landing site information for future human exploration of Mars.

Nathan Sam and Robert “Red” Jensen lay material into a Prandtl-M aircraft mold at NASA’s Armstrong Flight Research Center in California. The aircraft is the second of three prototypes of varying sizes to provide scientists with options to fly sensors in the Martian atmosphere to collect weather and landing site information for future human exploration of Mars.

A Prandtl-M prototype is air launched from the Carbon Cub aircraft March 13, 2020, at NASA’s Armstrong Flight Research Center in California. The aircraft is the second of three prototypes of varying sizes to provide scientists with options to fly sensors in the Martian atmosphere to collect weather and landing site information for future human exploration of Mars.

The first of three Prandtl-M prototype aircraft was air launched Aug. 16, 2019, from an Aerostat blimp at NASA’s Armstrong Flight Research Center in California. Three different prototypes of varying size, two still in development, eventually will be air launched from a weather balloon at 100,000 feet to simulate the atmosphere on Mars. The validated Prandtl-M could give scientists options to fly sensors in the Martian atmosphere to collect weather and landing site information for future human exploration of Mars.

Nathan Sam shows the Prandtl-M aircraft he helped fabricate at NASA’s Armstrong Flight Research Center in California. The aircraft is the second of three prototypes of varying sizes to provide scientists with options to fly sensors in the Martian atmosphere to collect weather and landing site information for future human exploration of Mars.

An Alta X drone is positioned at altitude for an air launch of the Enhancing Parachutes by Instrumenting the Canopy test experiment on June 4, 2025, at NASA’s Armstong Flight Research Center in Edwards, California. NASA researchers are developing technology to make supersonic parachutes safer and more reliable for delivering science instruments and payloads to Mars.

The parachute of the Enhancing Parachutes by Instrumenting the Canopy test experiment deploys following an air launch from an Alta X drone on June 4, 2025, at NASA’s Armstong Flight Research Center in Edwards, California. NASA researchers are developing technology to make supersonic parachutes safer and more reliable for delivering science instruments and payloads to Mars.

The Enhancing Parachutes by Instrumenting the Canopy test experiment lands following an air launch from an Alta X drone on June 4, 2025, at NASA’s Armstong Flight Research Center in Edwards, California. NASA researchers are developing technology to make supersonic parachutes safer and more reliable for delivering science instruments and payloads to Mars.

An Alta X drone air launches the Enhancing Parachutes by Instrumenting the Canopy test experiment on June 4, 2025, at NASA’s Armstong Flight Research Center in Edwards, California. NASA researchers are developing technology to make supersonic parachutes safer and more reliable for delivering science instruments and payloads to Mars.

Derek Abramson, left, and Justin Link, right, attach an Alta X drone to the Enhancing Parachutes by Instrumenting the Canopy test experiment on June 4, 2025, at NASA’s Armstong Flight Research Center in Edwards, California. Abramson is NASA chief engineer at the center’s Dale Reed Subscale Flight Research Laboratory, where Link also works as a pilot for small uncrewed aircraft systems. NASA researchers are developing technology to make supersonic parachutes safer and more reliable for delivering science instruments and payloads to Mars.

The Enhancing Parachutes by Instrumenting the Canopy project team examines a capsule and parachute following an air launch from an Alta X drone on June 4, 2025, at NASA’s Armstong Flight Research Center in Edwards, California. NASA researchers are developing technology to make supersonic parachutes safer and more reliable for delivering science instruments and payloads to Mars.

NASA researchers Paul Bean, center, and Mark Hagiwara, right, attach the capsule with parachute system to the Enhancing Parachutes by Instrumenting the Canopy test experiment on June 4, 2025, at NASA’s Armstong Flight Research Center in Edwards, California. NASA researchers are developing technology to make supersonic parachutes safer and more reliable for delivering science instruments and payloads to Mars.

In this photo of the M2-F1 lifting body and the Paresev 1B on the ramp, the viewer sees two vehicles representing different approaches to building a research craft to simulate a spacecraft able to land on the ground instead of splashing down in the ocean as the Mercury capsules did. The M2-F1 was a lifting body, a shape able to re-enter from orbit and land. The Paresev (Paraglider Research Vehicle) used a Rogallo wing that could be (but never was) used to replace a conventional parachute for landing a capsule-type spacecraft, allowing it to make a controlled landing on the ground.