Here is a close-up of the GE F414 engine, from the aft deck or rear, before the tail section of the X-59 is lifted into place and attached to the aircraft. The aft deck helps control the shockwaves at the end of the aircraft and reduce the noise of a sonic boom to more of a sonic thump.

The flight operations crew for NASA’s QSF18 flight series debriefs following a flight with the F/A-18 research aircraft. The flight included a quiet supersonic dive maneuver at high altitudes off the coast to produce a sonic boom out over the ocean, with the intention of producing quieter “thumps” on land.

The flight operations crew for NASA’s QSF18 flight series debriefs following a flight with the F/A-18 research aircraft. The flight included a quiet supersonic dive maneuver at high altitudes off the coast to produce a sonic boom out over the ocean, with the intention of producing quieter “thumps” on land.

The flight operations crew for NASA’s QSF18 flight series debriefs following a flight with the F/A-18 research aircraft. The flight included a quiet supersonic dive maneuver at high altitudes off the coast to produce a sonic boom out over the ocean, with the intention of producing quieter “thumps” on land.

The flight operations crew for NASA’s QSF18 flight series debriefs following a flight with the F/A-18 research aircraft. The flight included a quiet supersonic dive maneuver at high altitudes off the coast to produce a sonic boom out over the ocean, with the intention of producing quieter “thumps” on land.

The flight operations crew for NASA’s QSF18 flight series debriefs following a flight with the F/A-18 research aircraft. The flight included a quiet supersonic dive maneuver at high altitudes off the coast to produce a sonic boom out over the ocean, with the intention of producing quieter “thumps” on land.

The flight operations crew for NASA’s QSF18 flight series debriefs following a flight with the F/A-18 research aircraft. The flight included a quiet supersonic dive maneuver at high altitudes off the coast to produce a sonic boom out over the ocean, with the intention of producing quieter “thumps” on land.

The flight operations crew for NASA's QSF18 flight series debriefs following a flight with the F/A-18 research aircraft. The flight included a quiet supersonic dive maneuver at high altitudes off the coast to produce a sonic boom out over the ocean, with the intention of producing quieter "thumps" on land.

The flight operations crew for NASA’s QSF18 flight series debriefs following a flight with the F/A-18 research aircraft. The flight included a quiet supersonic dive maneuver at high altitudes off the coast to produce a sonic boom out over the ocean, with the intention of producing quieter “thumps” on land.

The flight operations crew for NASA's QSF18 flight series debriefs following a flight with the F/A-18 research aircraft. The flight included a quiet supersonic dive maneuver at high altitudes off the coast to produce a sonic boom out over the ocean, with the intention of producing quieter "thumps" on land.

Event: SEG 210 Forebody A Lockheed Martin technician prepares to install the left fuselage skins onto the X-59. Once in the air, the aircraft, currently under construction at Lockheed Martin Skunk Works in Palmdale, California, will demonstrate the ability to fly supersonic while reducing the loud sonic boom to a quiet sonic thump.

A Lockheed Martin technician prepares holes for installation of the fuselage panel on the X-59. The fuselage is the section of the aircraft that contains the cockpit. The aircraft, under construction at Lockheed Martin Skunk Works in Palmdale, California, will demonstrate the ability to fly supersonic while reducing the loud sonic boom to a quiet sonic thump.

Event: SEG 210 Forebody A Lockheed Martin technician prepares to install the left fuselage skins onto the X-59. Once in the air, the aircraft, currently under construction at Lockheed Martin Skunk Works in Palmdale, California, will demonstrate the ability to fly supersonic while reducing the loud sonic boom to a quiet sonic thump.

Lockheed Martin technicians work to align and check the fastener holes on the X-59’s fuselage skin. The aircraft, under construction at Lockheed Martin Skunk Works in Palmdale, California, will demonstrate the ability to fly supersonic while reducing the loud sonic boom to a quiet sonic thump.

A Lockheed Martin technician looks at the connector installation on the cad model of the X-59 airplane. The aircraft, under construction at Lockheed Martin Skunk Works in Palmdale, California, will demonstrate the ability to fly supersonic while reducing the loud sonic boom to a quiet sonic thump.

The Quesst mission recently completed testing of operations and equipment to be used in recording the sonic thumps of the X-59. To simulate the sonic thumps expected to be created by the X-59, NASA Armstrong Flight Researcher Center pilot Jim Less performed inverted dive maneuvers in an F-18, shown here, to generate softer sonic booms. The sonic booms were recorded by 10 ground recording stations stretched across 30 miles of desert near Edwards Air Force Base.

NASA’s X-59 quiet supersonic research aircraft successfully completed electromagnetic interference (EMI) testing at Lockheed Martin Skunk Works in Palmdale, California. During EMI tests, the team examined each of the X-59’s internal electronic systems, ensuring they worked with one another without interference. The X-59 is designed to fly faster than the speed of sound while reducing the loud sonic boom to a quieter sonic thump.

NASA’s X-59 quiet supersonic research aircraft sits on the ramp at Lockheed Martin Skunk Works in Palmdale, California during sunrise, shortly after completion of painting. With its unique design, including a 38-foot-long nose, the X-59 was built to demonstrate the ability to fly supersonic, or faster than the speed of sound, while reducing the typically loud sonic boom produced by aircraft at such speeds to a quieter sonic “thump”. The X-59 is the centerpiece of NASA’s Quesst mission, which seeks to solve one of the major barriers to supersonic flight over land, currently banned in the United States, by making sonic booms quieter.

NASA’s X-59 quiet supersonic research aircraft sits on the ramp at Lockheed Martin Skunk Works in Palmdale, California during sunrise, shortly after completion of painting. With its unique design, including a 38-foot-long nose, the X-59 was built to demonstrate the ability to fly supersonic, or faster than the speed of sound, while reducing the typically loud sonic boom produced by aircraft at such speeds to a quieter sonic “thump”. The X-59 is the centerpiece of NASA’s Quesst mission, which seeks to solve one of the major barriers to supersonic flight over land, currently banned in the United States, by making sonic booms quieter.

NASA’s X-59 quiet supersonic research aircraft sits on the ramp at Lockheed Martin Skunk Works in Palmdale, California during sunrise, shortly after completion of painting. With its unique design, including a 38-foot-long nose, the X-59 was built to demonstrate the ability to fly supersonic, or faster than the speed of sound, while reducing the typically loud sonic boom produced by aircraft at such speeds to a quieter sonic “thump”. The X-59 is the centerpiece of NASA’s Quesst mission, which seeks to solve one of the major barriers to supersonic flight over land, currently banned in the United States, by making sonic booms quieter.

NASA’s X-59 quiet supersonic research aircraft sits on the ramp at Lockheed Martin Skunk Works in Palmdale, California during sunrise, shortly after completion of painting. With its unique design, including a 38-foot-long nose, the X-59 was built to demonstrate the ability to fly supersonic, or faster than the speed of sound, while reducing the typically loud sonic boom produced by aircraft at such speeds to a quieter sonic “thump”. The X-59 is the centerpiece of NASA’s Quesst mission, which seeks to solve one of the major barriers to supersonic flight over land, currently banned in the United States, by making sonic booms quieter.

NASA’s X-59 quiet supersonic research aircraft sits on the ramp at Lockheed Martin Skunk Works in Palmdale, California during sunrise, shortly after completion of painting. With its unique design, including a 38-foot-long nose, the X-59 was built to demonstrate the ability to fly supersonic, or faster than the speed of sound, while reducing the typically loud sonic boom produced by aircraft at such speeds to a quieter sonic “thump”. The X-59 is the centerpiece of NASA’s Quesst mission, which seeks to solve one of the major barriers to supersonic flight over land, currently banned in the United States, by making sonic booms quieter.

NASA’s X-59 quiet supersonic research aircraft sits on the ramp at Lockheed Martin Skunk Works in Palmdale, California during sunrise, shortly after completion of painting. With its unique design, including a 38-foot-long nose, the X-59 was built to demonstrate the ability to fly supersonic, or faster than the speed of sound, while reducing the typically loud sonic boom produced by aircraft at such speeds to a quieter sonic “thump”. The X-59 is the centerpiece of NASA’s Quesst mission, which seeks to solve one of the major barriers to supersonic flight over land, currently banned in the United States, by making sonic booms quieter.

Event: SEG 210 Forebody A right side view of where the team is preparing the X-59 structure for installation of the forward fuselage, which contains the cockpit. The aircraft, under construction at Lockheed Martin Skunk Works in Palmdale, California, will fly to demonstrate the ability to fly supersonic while reducing the loud sonic boom to a quiet sonic thump.

Event: SEG 410 Main Wing A Lockheed Martin technician works on the installation of wiring on the trailing edge structure of the right side of the X-59’s wing. The aircraft, under construction at Lockheed Martin Skunk Works in Palmdale, California, will demonstrate the ability to fly supersonic while reducing the loud sonic boom to a quiet sonic thump.

Event: SEG 210 Forebody A Lockheed Martin technician works on the ejection seat support structure and once complete, the ejection seat rails will be installed on the X-59 airplane. The aircraft, under construction at Lockheed Martin Skunk Works in Palmdale, California, will demonstrate the ability to fly supersonic while reducing the loud sonic boom to a quiet sonic thump.

Event: Manufacturing Area From Above A overhead view of the X-59 with its nose on. The X-59’s nose is 38-feet long – approximately one third of the length of the entire aircraft. The aircraft, under construction at Lockheed Martin Skunk Works in Palmdale, California, will demonstrate the ability to fly supersonic while reducing the loud sonic boom to a quiet sonic thump.

Event: SEG 570 Vertical Tail Assembly - Final Install Lockheed Martin technicians work on a fit check and installation of the vertical tail onto the X-59 aircraft. The plane is under construction at Lockheed Martin Skunk Works in Palmdale, California, will fly to demonstrate the ability to fly supersonic while reducing the loud sonic boom to a quiet sonic thump.

The Quesst mission recently completed testing of operations and equipment to be used in recording the sonic thumps of the X-59. Researchers used three weather towers and a sonic anemometer to collect weather and atmospheric data while recording sonic booms generated by an F-15 and an F-18 from NASA’s Armstrong Flight Research Center.

A Lockheed Martin Skunk Works technician inspects some of the wiring and sensors on the X-59 aircraft in preparation for the first power-on system checkouts. Once complete, the X-59 aircraft will demonstrate the ability to fly supersonic while reducing the loud sonic boom to a quiet sonic thump and help enable commercial supersonic air travel over land. This aircraft is the centerpiece of NASA’s Quesst mission.

A overhead view of the X-59 with its nose on. The X-59’s nose is 38-feet long – approximately one third of the length of the entire aircraft. The plane is under construction at Lockheed Martin Skunk Works in Palmdale, California, will fly to demonstrate the ability to fly supersonic while reducing the loud sonic boom to a quiet sonic thump.

Event: SEG 510 Upper Empennage An inside peek at the X-59 gives us a view from the aft end looking at the engine bay. Later in the assembly process, the engine will be placed inside this section. The aircraft, under construction at Lockheed Martin Skunk Works in Palmdale, California, will demonstrate the ability to fly supersonic while reducing the loud sonic boom to a quiet sonic thump.

This image shows the extensive ventilation system that has been placed adjacent to the X-59 during the recent painting of the aircraft’s engine inlet. Once the aircraft build and ground testing are complete, the X-59 airplane will begin flight testing, working towards demonstrating the ability to fly supersonic while reducing the loud sonic boom to a quiet sonic thump and help enable commercial supersonic air travel over land.

Event: SEG 230 Nose - Craned Onto Tooling A close up of the X-59’s duckbill nose, which is a crucial part of its supersonic design shaping. The team prepares the nose for a fit check. The X-59’s nose is 38-feet long – approximately one third of the length of the entire aircraft. The aircraft, under construction at Lockheed Martin Skunk Works in Palmdale, California, will demonstrate the ability to fly supersonic while reducing the loud sonic boom to a quiet sonic thump.

This is an up-close view of the X-59’s engine inlet – fresh after being painted. The 13-foot F414-GE-100 engine will be placed inside the inlet bringing the X-59 aircraft one step closer to completion. Once fully assembled, the X-59 aircraft will begin flight operations, working toward demonstration of the ability to fly supersonic while reducing the loud sonic boom to a quiet sonic thump, helping to enable commercial supersonic air travel over land.

Event: SEG 230 Nose - Craned Onto Tooling A close-up of the X-59’s duckbill nose, which is a crucial part of its supersonic design shaping. The team prepares the nose for a fit check. The X-59’s nose is 38-feet long – approximately one third of the length of the entire aircraft. The aircraft, under construction at Lockheed Martin Skunk Works in Palmdale, California, will demonstrate the ability to fly supersonic while reducing the loud sonic boom to a quiet sonic thump.

A panoramic side view of the left top of the X-59 supersonic plane with the tail on and the nose in the process of installation. The X-59’s nose is 38-feet long – approximately one third of the length of the entire aircraft. The aircraft, under construction at Lockheed Martin Skunk Works in Palmdale, California, will demonstrate the ability to fly supersonic while reducing the loud sonic boom to a quiet sonic thump.

A Lockheed Martin technician works to complete wiring on the X-59 aircraft in preparation for the power-on system checkouts. Once complete, the X-59 aircraft will demonstrate the ability to fly supersonic while reducing the loud sonic boom to a quiet sonic thump and help enable commercial supersonic air travel over land. This aircraft is the centerpiece of NASA’s Quesst mission.

Event: SEG 230 Nose The X-59’s nose is wrapped up safely and rests on a dolly before the team temporarily attaches it to the aircraft for fit checks at Lockheed Martin in Palmdale, California. The full length of the X-plane’s nose is 38-feet – making up one third of the plane’s full length. The aircraft, under construction at Lockheed Martin Skunk Works in Palmdale, California, once in the air will demonstrate the ability to fly supersonic while reducing the loud sonic boom to a quiet sonic thump.

A Lockheed Martin Skunk Works technician works to complete wiring on the X-59 aircraft in preparation for the power-on system checkouts. Once complete, the X-59 aircraft will demonstrate the ability to fly supersonic while reducing the loud sonic boom to a quiet sonic thump and help enable commercial supersonic air travel over land. This aircraft is the centerpiece of NASA’s Quesst mission.

The upper empennage, or tail section of the plane, and engine bay is surrounded by a blue gantry that is used to assist with ground installation and removal of the X-59’s lower empennage and engine. Once fully assembled, the X-59 aircraft will demonstrate the ability to fly supersonic while reducing the loud sonic boom to a quiet sonic thump and help enable commercial supersonic air travel over land. This aircraft is the centerpiece of NASA’s Quesst mission.

A Lockheed Martin Skunk Works technician inspects some of the wiring and sensors on the X-59 aircraft in preparation for the first power-on system checkouts. Once complete, the X-59 aircraft will demonstrate the ability to fly supersonic while reducing the loud sonic boom to a quiet sonic thump and help enable commercial supersonic air travel over land. This aircraft is the centerpiece of NASA’s Quesst mission.

Here is an image of the X-59’s 13-foot General Electric F414 engine as the team prepares for a fit check. Making sure components, like the aircraft’s hydraulic lines, which help control functions like brakes or landing gear, and wiring of the engine, fit properly is essential to the aircraft’s safety. Once complete, the X-59 aircraft will demonstrate the ability to fly supersonic while reducing the loud sonic boom to a quiet sonic thump and help enable commercial supersonic air travel over land.

This is an overhead view of the X-59 aircraft at Lockheed Martin Skunk Works in Palmdale, California. The nose was installed, and the plane awaits engine installation. Technicians continue to wire the aircraft as the team preforms several system checkouts to ensure the safety of the aircraft. The X-59 aircraft will demonstrate the ability to fly supersonic while reducing the loud sonic boom to a quiet sonic thump and help enable commercial supersonic air travel over land.

An overhead view of the X-59 supersonic plane with the tail on and the nose in the process of installation. The X-59’s nose is 38-feet long – approximately one third of the length of the entire aircraft. The aircraft, under construction at Lockheed Martin Skunk Works in Palmdale, California, will demonstrate the ability to fly supersonic while reducing the loud sonic boom to a quiet sonic thump.

The Quesst mission recently completed testing of operations and equipment to be used in recording the sonic thumps of the X-59. Shown is one of 10 ground recording stations set up along a 30-mile stretch of desert to record sonic booms during the third phase of the of CarpetDIEM, Carpet Determination in Entirety Measurements flights. An F-15 and an F-18 from NASA’s Armstrong Flight Research Center created sonic booms, both loud and soft, to verify the operations of ground recording systems.

NASA test pilot Nils Larson walks around an F-15B research aircraft for a rehearsal flight supporting the agency’s Quesst mission at NASA’s Armstrong Flight Research Center in Edwards, California. The flight was part of a full-scale dress rehearsal for Phase 2 of the mission, which will eventually measure quiet sonic thumps generated by the X-59. The flight series helped NASA teams refine procedures and practice data collection ahead of future X-59 flights.

This image shows the X-59 aircraft’s lower empennage structure, or tail section of the plane, that was installed. The stabilators, the outer surfaces also seen in the photo, attach to the lower empennage and are used to help regulate the aircraft pitch which controls the up and down movement of the motion of the plane. The 13-foot engine will pack 22,000 pounds of propulsion and energy and power the X-plane to its planned cruising speed of Mach 1.4. Once complete, the X-59 aircraft will demonstrate the ability to fly supersonic while reducing the loud sonic boom to a quiet sonic thump and help enable commercial supersonic air travel over land. This aircraft is the centerpiece of NASA’s Quesst mission.

This overhead shot of the X-59 Quiet SuperSonic Technology or QueSST aircraft shows the assembly progress of the vehicle during Spring 2021. The aircraft, under construction at Lockheed Martin Skunk Works in Palmdale, California, will fly to demonstrate the ability to fly supersonic while reducing the loud sonic boom to a quiet sonic thump. Lockheed Martin Photography By Garry Tice 1011 Lockheed Way, Palmdale, Ca. 93599

Technicians preform some installation work in the mid-bay on the X-59 Quiet SuperSonic Technology or QueSST aircraft. The aircraft, under construction at Lockheed Martin Skunk Works in Palmdale, California, will fly to demonstrate the ability to fly supersonic while reducing the loud sonic boom to a quiet sonic thump. Lockheed Martin Photography By Garry Tice 1011 Lockheed Way, Palmdale, Ca. 93599 Event: SEG 450 Mid Bay - Encoders Date: 4/28/2021

A technician is shown working on the underside of the X-59. The aircraft, under construction at Lockheed Martin Skunk Works in Palmdale, California, will fly to demonstrate the ability to fly supersonic while reducing the loud sonic boom to a quiet sonic thump. Lockheed Martin Photography By Garry Tice 1011 Lockheed Way, Palmdale, Ca. 93599 Event: SEG 450 Mid Bay - PDS Fit Check Date: 5/03/2021

A technician is shown working on the X-59 vertical tail prior to installation at Lockheed Martin Skunk Works in Palmdale, California. The aircraft will fly to demonstrate the ability to fly supersonic while reducing the loud sonic boom to a quiet sonic thump. Lockheed Martin Photography By Garry Tice 1011 Lockheed Way, Palmdale, Ca. 93599 Event: SEG 530 Vertical Tail, Landing Gear Bay Doors Date: 4/28/2021

Juliet Page, a physical scientist with the Volpe National Transportation Systems Center, calibrates a microphone station during the CarpetDIEM flight series. The array featured high-fidelity microphones arranged in several configurations, giving researchers the ability to obtain accurate sound data and assess the loudness of the sonic booms, just as they will measure the quiet sonic thumps from the X-59.

Technicians work with a laser measuring system on the X-59 spine. The X-59 Quiet SuperSonic Technology, or QueSST, aircraft is under construction at Lockheed Martin Skunk Works in Palmdale, California, and will fly to demonstrate the ability to fly supersonic while reducing the loud sonic boom to a quiet sonic thump. Lockheed Martin Photography By Garry Tice 1011 Lockheed Way, Palmdale, Ca. 93599 Event: SEG 400 Main Wing Assembly, SEG 430 Spine, SEG 500 Empennage Date: 4/28/2021

A technician is shown working on the X-59 vertical tail prior to installation. The aircraft, under construction at Lockheed Martin Skunk Works in Palmdale, California, will fly to demonstrate the ability to fly supersonic while reducing the loud sonic boom to a quiet sonic thump. Lockheed Martin Photography By Garry Tice 1011 Lockheed Way, Palmdale, Ca. 93599 Event: SEG 530 Vertical Tail - Rudder Installed Date: 5/12/2021

Dr. Alexandra Loubeau, one of the technical co-leads for sonic boom community testing for the Quesst mission, sets out a microphone in the California desert. . The Quesst mission recently completed testing of operations and equipment to be used in recording the sonic thumps of the X-59. The testing was the third phase of Carpet Determination in Entirety Measurements flights, called CarpetDIEM for short. An F-15 and an F-18 from NASA’s Armstrong Flight Research Center created sonic booms, both loud and soft, to verify the operations of ground recording systems spread out across 30 miles of open desert.

The X-59 Quiet SuperSonic Technology (QueSST) aircraft is taking shape at the Lockheed Martin Skunk Works facility in Palmdale, California. The team positioned the X-59 QueSST's nose at the front of the aircraft. As one of the more recognizable features of the X-59, the nose makes up almost a third of the aircraft length and will be essential in shaping shock waves during supersonic flight, resulting in quiet sonic thumps instead of loud sonic booms. The nose was attached and then removed from the front of the aircraft in preparation for its shipment to Fort Worth, Texas where it will undergo additional testing. The X-59 will fly at supersonic speeds above communities as part of the Low-Boom Flight Demonstration mission, during which NASA will gather community feedback to the sound of quiet supersonic flight. These findings will be shared with regulators to inform decisions on current restrictions of supersonic flight over land. Lockheed Martin Photography By Garry Tice 1011 Lockheed Way, Palmdale, Ca. 93599 Event: Manufacturing Area From Above Date: 8/18/2021 Additional Info:

Here is a wide shot of the wing, engine and engine inlet area of NASA’s X-59 Quiet SuperSonic Technology or QueSST aircraft. The aircraft, under construction at Lockheed Martin Skunk Works in Palmdale, California, will fly to demonstrate the ability to fly supersonic while reducing the loud sonic boom to a quiet sonic thump. Lockheed Martin Photography By Garry Tice 1011 Lockheed Way, Palmdale, Ca. 93599 Event: SEG 400 Main Wing Assembly, SEG 430 Spine, SEG 500 Empennage Date: 4/28/2021

Aerospace engineer Larry Cliatt, Quesst Phase 2 Sub-Project Manager and technical lead for the acoustic validation phase of the Quesst mission, sets up a ground recording system in the California desert. The Quesst mission recently completed testing of operations and equipment to be used in recording the sonic thumps of the X-59. The testing was the third phase of Carpet Determination in Entirety Measurements flights, called CarpetDIEM for short. An F-15 and an F-18 from NASA’s Armstrong Flight Research Center created sonic booms, both loud and soft, to verify the operations of ground recording systems spread out across 30 miles of open desert.

Aerospace engineer Larry Cliatt, Quesst Phase 2 Sub-Project Manager abd technical lead for the acoustic validation phase of the Quesst mission, sets up a ground recording system in the California desert. The Quesst mission recently completed testing of operations and equipment to be used in recording the sonic thumps of the X-59. The testing was the third phase of Carpet Determination in Entirety Measurements flights, called CarpetDIEM for short. An F-15 and an F-18 from NASA’s Armstrong Flight Research Center created sonic booms, both loud and soft, to verify the operations of ground recording systems spread out across 30 miles of open desert.

Following the successful installation of mounting brackets, technicians successfully installed the pallet for the eXternal Visibility System, or XVS, onto the X-59 Quiet SuperSonic Technology X-plane, also known as X-59 QueSST. The pallet installation marks an assembly milestone as the first NASA flight systems hardware to be installed onto the vehicle. X-59 will fly to demonstrate the ability to produce quiet thumps at supersonic speeds, instead of the typical, loud sonic booms associated with supersonic flight.

Following the successful installation of mounting brackets, technicians successfully installed the pallet for the eXternal Visibility System, or XVS, onto the X-59 Quiet SuperSonic Technology X-plane, also known as X-59 QueSST. The pallet installation marks an assembly milestone as the first NASA flight systems hardware to be installed onto the vehicle. X-59 will fly to demonstrate the ability to produce quiet thumps at supersonic speeds, instead of the typical, loud sonic booms associated with supersonic flight.

NASA is targeting 2022 for the first flight of the X-59 Quiet SuperSonic Technology (QueSST) research aircraft. Its mission – fly over communities to collect data that could cut passenger travel time in half without disturbing people on the ground. NASA’s X-59 is equipped with supersonic technologies that aid in lowering the sound of the sonic boom. In this picture, the black rectangle panels are the air intakes for the environmental control system (ECS) that regulates the temperature, cabin pressure, and air distribution. The silver grate located at the rear of one of the ECS panels is the exhaust — both of these sections are traditionally housed on the underside of the plane. By placing these features on top of the X-59 wing, the wing blocks and prevents the ECS exhaust from interacting with the shock waves on the bottom of the aircraft. This unique design approach to re-shaping the shock wave pattern substantially reduces the sonic boom to more of a sonic “thump” when it reaches the ground. Lockheed Martin Photography By Garry Tice 1011 Lockheed Way, Palmdale, Ca. 93599 Event: SEG 210 Forebody Date: 1/19/2021 Additional Info:

While NASA’s F/A-18 goes supersonic off the coast, a team of researchers monitor the flight and operate multiple sound monitor stations around Galveston and its surrounding area. This allows NASA to obtain accurate sound level data, which gets matched to community response data.

While NASA’s F/A-18 goes supersonic off the coast, a team of researchers monitor the flight and operate multiple sound monitor stations around Galveston and its surrounding area. This allows NASA to obtain accurate sound level data, which gets matched to community response data.

While NASA’s F/A-18 goes supersonic off the coast, a team of researchers monitor the flight and operate multiple sound monitor stations around Galveston and its surrounding area. This allows NASA to obtain accurate sound level data, which gets matched to community response data.

While NASA's F/A-18 goes supersonic off the coast, a team of researchers monitor the flight and operate multiple sound monitor stations around Galveston and its surrounding area. This allows NASA to obtain accurate sound level data, which gets matched to community response data.

While NASA’s F/A-18 goes supersonic off the coast, a team of researchers monitor the flight and operate multiple sound monitor stations around Galveston and its surrounding area. This allows NASA to obtain accurate sound level data, which gets matched to community response data.

While NASA’s F/A-18 goes supersonic off the coast, a team of researchers monitor the flight and operate multiple sound monitor stations around Galveston and its surrounding area. This allows NASA to obtain accurate sound level data, which gets matched to community response data.

While NASA's F/A-18 goes supersonic off the coast, a team of researchers monitor the flight and operate multiple sound monitor stations around Galveston and its surrounding area. This allows NASA to obtain accurate sound level data, which gets matched to community response data.

While NASA's F/A-18 goes supersonic off the coast, a team of researchers monitor the flight and operate multiple sound monitor stations around Galveston and its surrounding area. This allows NASA to obtain accurate sound level data, which gets matched to community response data.

While NASA's F/A-18 goes supersonic off the coast, a team of researchers monitor the flight and operate multiple sound monitor stations around Galveston and its surrounding area. This allows NASA to obtain accurate sound level data, which gets matched to community response data.

While NASA’s F/A-18 goes supersonic off the coast, a team of researchers monitor the flight and operate multiple sound monitor stations around Galveston and its surrounding area. This allows NASA to obtain accurate sound level data, which gets matched to community response data.

While NASA's F/A-18 goes supersonic off the coast, a team of researchers monitor the flight and operate multiple sound monitor stations around Galveston and its surrounding area. This allows NASA to obtain accurate sound level data, which gets matched to community response data.

While NASA's F/A-18 goes supersonic off the coast, a team of researchers monitor the flight and operate multiple sound monitor stations around Galveston and its surrounding area. This allows NASA to obtain accurate sound level data, which gets matched to community response data.

While NASA’s F/A-18 goes supersonic off the coast, a team of researchers monitor the flight and operate multiple sound monitor stations around Galveston and its surrounding area. This allows NASA to obtain accurate sound level data, which gets matched to community response data.

While NASA’s F/A-18 goes supersonic off the coast, a team of researchers monitor the flight and operate multiple sound monitor stations around Galveston and its surrounding area. This allows NASA to obtain accurate sound level data, which gets matched to community response data.

While NASA's F/A-18 goes supersonic off the coast, a team of researchers monitor the flight and operate multiple sound monitor stations around Galveston and its surrounding area. This allows NASA to obtain accurate sound level data, which gets matched to community response data.

NASA’s X-59 research aircraft moves from its construction site to the flight line – or the space between the hangar and the runway – at Lockheed Martin Skunk Works in Palmdale, California, on June 16, 2023. This milestone kicks off a series of ground tests to ensure the X-59 is safe and ready to fly. The X-59 is designed to fly faster than Mach 1 while reducing the resulting sonic boom to a thump for people on the ground. NASA will evaluate this technology during flight tests as part of the agency’s Quesst mission, which helps enable commercial supersonic air travel over land. Lockheed Martin Photography By Garry Tice 1011 Lockheed Way, Palmdale, Ca. 93599 Event: Move to Run Stall 5 Date: 6/19/2023 Additional Info:

A NASA F/A-18 sits on the apron at NASA's Armstrong Flight Research Center in Edwards, California, prior to a supersonic research flight.

The pilot of NASAÕs X-59 Quiet SuperSonic Technology, or QueSST, aircraft will navigate the skies in a cockpit unlike any other. There wonÕt be a forward-facing window. ThatÕs right; itÕs actually a 4K monitor that serves as the central window and allows the pilot to safely see traffic in his or her flight path, and provides additional visual aids for airport approaches, landings and takeoffs. The 4K monitor, which is part of the aircraftÕs eXternal Visibility System, or XVS, displays stitched images from two cameras outside the aircraft combined with terrain data from an advanced computing system. The two portals and traditional canopy are real windows however, and help the pilot see the horizon. The displays below the XVS will provide a variety of aircraft systems and trajectory data for the pilot to safely fly. The XVS is one of several innovative solutions to help ensure the X-59Õs design shape reduces a sonic boom to a gentle thump heard by people on the ground. Though not intended to ever carry passengers, the X-59 boom-suppressing technology and community response data could help lift current bans on supersonic flight over land and enable a new generation of quiet supersonic commercial aircraft.

The X-59, NASA’s quiet supersonic technology experimental aircraft, is suspended in the air at Lockheed Martin’s Skunk Works facility in Palmdale, California, following several months of critical ground testing in Ft. Worth, Texas

The X-59, NASA’s quiet supersonic technology experimental aircraft, arrives back at Lockheed Martin’s Skunk Works facility in Palmdale, California, following several months of critical ground testing in Ft. Worth, Texas

The X-59, NASA's quiet supersonic technology experimental aircraft, sits in Lockheed Martin's Skunk Works facility in Palmdale, California, following its return from several months of critical ground testing in Ft. Worth, Texas

Part of the mission criteria that led to the decision to fly off the coast of Galveston for QSF18 was the convenience of having NASA Johnson Space Center's facilities at Ellington Field.

In order to make sure weather conditions are acceptable at multiple altitudes, NASA meteorologists on the ground conduct constant monitoring operations, and launch weather balloons to get accurate data for aircraft and pilot.

NASA's F/A-18 research aircraft stands ready prior to a QSF18 supersonic research flight off the coast of Galveston, Texas.

NASA mission controllers, engineers, pilots and communications specialists in the mission control room monitor the supersonic research flight off the coast of Galveston, as part of the QSF18 flight series. The flight operations crew tracks the status of the flights, maintains communications with the aircraft, communicates with U.S. Coast Guard, and coordinates community feedback data.

NASA ground and maintenance crews prepare the F/A-18 research aircraft for a supersonic research flight off the coast of Galveston, Texas in support of the QSF18 flight campaign. These crews are vital to making sure the aircraft is ready to operate safely and efficiently for NASA’s research.

NASA test pilots perform the quiet supersonic dive maneuver off the coast of Galveston, Texas to create a quieter version of the sonic boom, in order to obtain recruited community survey feedback data. The test pilot climbs to around 50,000 feet, followed by a supersonic, inverted dive. This creates sonic boom shockwaves in a way that they are quieter in a specific area. Meanwhile, NASA researchers match community feedback to the sound levels of the flights, using an electronic survey and microphone monitor stations on the ground. This is preparing NASA for community response models for the future X-59 QueSST.

While NASA's F/A-18 goes supersonic off the coast, a team of researchers monitor the flight and operate multiple sound monitor stations around Galveston and its surrounding area. This allows NASA to obtain accurate sound level data, which gets matched to community response data.

The Gulf of Mexico as seen from NASA photographer Carla Thomas at high altitude in the F/A-18 research aircraft during a flight in support of the Quiet Supersonic Flights 2018 series, or QSF18. The high altitude is necessary as part of the quiet supersonic dive maneuver, climbing to around 50,000 feet, followed by a supersonic, inverted dive. This creates sonic boom shockwaves in a way that they are quieter in a specific area.

NASA mission controllers, engineers, pilots and communications specialists in the mission control room monitor the supersonic research flight off the coast of Galveston, as part of the QSF18 flight series. The flight operations crew tracks the status of the flights, maintains communications with the aircraft, communicates with U.S. Coast Guard, and coordinates community feedback data.

NASA mission controllers, engineers, pilots and communications specialists in the mission control room monitor the supersonic research flight off the coast of Galveston, as part of the QSF18 flight series. The flight operations crew tracks the status of the flights, maintains communications with the aircraft, communicates with U.S. Coast Guard, and coordinates community feedback data.

NASA ground and maintenance crews prepare the F/A-18 research aircraft for a supersonic research flight off the coast of Galveston, Texas in support of the QSF18 flight campaign. These crews are vital to making sure the aircraft is ready to operate safely and efficiently for NASA’s research.

In order to make sure weather conditions are acceptable at multiple altitudes, NASA meteorologists on the ground conduct constant monitoring operations, and launch weather balloons to get accurate data for aircraft and pilot.

NASA test pilot Wayne “Ringo” Ringelberg and photographer Carla Thomas prepare to take off for a supersonic research flight in support of the QSF18 campaign off the coast of Texas. NASA photographers and videographers take part in operations to support mission documentation.

NASA test pilots Jim “Clue” Less and Wayne “Ringo” Ringelberg step to the F/A-18 research aircraft at Ellington Field and conduct pre-flight safety checks on the aircraft prior to a supersonic research flight for the QSF18 series.

NASA’s F/A-18 research aircraft takes off from Ellington Field in Houston, Texas for a quiet supersonic research flight off the coast of Galveston, as part of the QSF18 flight series. The F/A-18 will climb to 50,000 feet over the Gulf of Mexico, where it will perform the quiet supersonic dive maneuver.

NASA test pilot Wayne “Ringo” Ringelberg and photographer Carla Thomas prepare to take off for a supersonic research flight in support of the QSF18 campaign off the coast of Texas. NASA photographers and videographers take part in operations to support mission documentation.