NASA Shares Use Requirements with Commercial Destination Partners

NASA Shares Use Requirements with Commercial Destination Partners

A male astronaut is looking into a glass glovebox as he works on a science experiment. Inside the glovebox there is various scientific equipment including several syringes and bags. The astronaut is holding two syringes inside the glovebox.
NASA astronaut Mike Barratt processes brain organoid samples inside the life science glovebox for a neurodegenerative disorder study. NASA plans to use future commercial low Earth orbit destinations for the continuation of scientific research.
NASA

NASA hosted a meeting to share knowledge with companies developing future commercial destinations at the agency’s Johnson Space Center in Houston. The discussion could aid in developing safe, reliable, innovative, and cost-effective space stations. Industry representatives from more than 20 companies attended.

The program focused on NASA’s planned use of commercial destinations, draft utilization requirements, and the payload life cycle. A primary interest for the use of commercial stations includes the continuation of scientific research in low Earth orbit, such as human research, technology demonstrations, biological and physical science, and Earth observation.

A man wearing a gray blazer stands at a podium with the NASA meatball logo attached to the front. The man is gesturing with his hands as he speaks to an audience.
David Caponio from Vast Space presents a five-minute lightning talk on the company’s capabilities during the program NASA’s Johnson Space Center. Vast is working with NASA under the second Collaborations for Commercial Space Capabilities initiative for technologies and operations required for its microgravity and artificial gravity stations, including the Haven-1 commercial destination.
NASA/Josh Valcarcel

“NASA has benefited from the unique microgravity environment of low Earth orbit to conduct important science investigations and technology demonstrations for more than two decades,” said Dr. Kirt Costello, utilization manager for NASA’s Commercial Low Earth Orbit Development Program. “As commercial companies make progress in the design and development of their own space stations, it is important that we share NASA’s needs and requirements as well as foster an open dialogue between government and private industry.”

The program builds on a request for information released last year, seeking feedback from industry as the agency refines its requirements for new commercial space destinations.

A group of four people are speaking to each other. There are three men and a woman. The man in the center is wearing a blue button-down shirt with a gray blazer and glasses and smiling at the other people.
Vergel Romero of Sierra Space speaks with representatives from other commercial companies during a networking opportunity. Sierra Space is working with Blue Origin on the development of Orbital Reef, and also holds an unfunded Space Act Agreement with NASA for the development of its commercial low Earth orbit ecosystem.
NASA/Josh Valcarcel

Since then, the feedback has helped develop and refine a utilization requirements strategy, including a concept of operations, basic laboratory capabilities, and common payload standards for heritage hardware. NASA will continue to refine its future requirements and incorporate future low Earth orbit needs of other U.S. government agencies and international partners.

NASA uses a two-phase strategy to support the development of commercial destinations and enable the agency to purchase services as one of many customers. Phase 1 efforts extend through 2025, before NASA plans to transition to Phase 2, which will be to certify commercial destinations and purchase services.   

A woman wearing a pink blouse and a black blazer stands at a podium with the NASA meatball logo attached to the front. The woman is speaking to a group of people.
Eleasa Kim, payload operations lead for NASA’s Commercial Low Earth Orbit Development Program, presents on NASA’s planned utilization activities for commercial destinations and expectations for provider support.
NASA/Josh Valcarcel

The agency’s commercial strategy for low Earth orbit will provide the government with reliable and safe services at a lower cost and enable the agency to focus on Artemis missions to the Moon in preparation for Mars while also continuing to use low Earth orbit as a training and proving ground for those deep space missions.

Learn more about NASA’s commercial space strategy at:

https://www.nasa.gov/humans-in-space/commercial-space/

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NASA’s Webb Captures Celestial Fireworks Around Forming Star

NASA’s Webb Captures Celestial Fireworks Around Forming Star

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NASA’s Webb Captures Celestial Fireworks Around Forming Star

A growing protostar embedded within a molecular cloud. The center of the image shows a bright, red region, where the growing protostar resides, with a thin, gray lane of matter cutting through it horizontally, which is the protostar’s accretion disk. Above and below this region are blue triangular-shaped molecular clouds, which give the overall object an hourglass shape. The areas in the molecular clouds closest to the protostar have more pronounced plumes of blue gas. There are red, yellow, orange, blue, and green stars and galaxies scattered across the background.
L1527, shown in this image from NASA’s James Webb Space Telescope’s MIRI (Mid-Infrared Instrument).

The colors within this mid-infrared image reveal details about the central protostar’s behavior.

The cosmos seems to come alive with a crackling explosion of pyrotechnics in this new image from NASA’s James Webb Space Telescope. Taken with Webb’s MIRI (Mid-Infrared Instrument), this fiery hourglass marks the scene of a very young object in the process of becoming a star. A central protostar grows in the neck of the hourglass, accumulating material from a thin protoplanetary disk, seen edge-on as a dark line.

The protostar, a relatively young object of about 100,000 years, is still surrounded by its parent molecular cloud, or large region of gas and dust. Webb’s previous observation of L1527, with NIRCam (Near-Infrared Camera), allowed us to peer into this region and revealed this molecular cloud and protostar in opaque, vibrant colors.

Image A: L1527 – Webb/MIRI

A growing protostar embedded within a molecular cloud. The center of the image shows a bright, red region, where the growing protostar resides, with a thin, gray lane of matter cutting through it horizontally, which is the protostar’s accretion disk. Above and below this region are blue triangular-shaped molecular clouds, which give the overall object an hourglass shape. The areas in the molecular clouds closest to the protostar have more pronounced plumes of blue gas. There are red, yellow, orange, blue, and green stars and galaxies scattered across the background.
L1527, shown in this image from NASA’s James Webb Space Telescope’s MIRI (Mid-Infrared Instrument), is a molecular cloud that harbors a protostar. It resides about 460 light-years from Earth in the constellation Taurus. The more diffuse blue light and the filamentary structures in the image come from organic compounds known as polycyclic aromatic hydrocarbons (PAHs), while the red at the center of this image is an energized, thick layer of gases and dust that surrounds the protostar. The region in between, which shows up in white, is a mixture of PAHs, ionized gas, and other molecules.

This image includes filters representing 7.7 microns light as blue, 12.8 microns light as green, and 18 microns light as red.

Both NIRCam and MIRI show the effects of outflows, which are emitted in opposite directions along the protostar’s rotation axis as the object consumes gas and dust from the surrounding cloud. These outflows take the form of bow shocks to the surrounding molecular cloud, which appear as filamentary structures throughout. They are also responsible for carving the bright hourglass structure within the molecular cloud as they energize, or excite, the surrounding matter and cause the regions above and below it to glow. This creates an effect reminiscent of fireworks brightening a cloudy night sky. Unlike NIRCam, however, which mostly shows the light that is reflected off dust, MIRI provides a look into how these outflows affect the region’s thickest dust and gases.

The areas colored here in blue, which encompass most of the hourglass, show mostly carbonaceous molecules known as polycyclic aromatic hydrocarbons. The protostar itself and the dense blanket of dust and a mixture of gases that surround it are represented in red. (The sparkler-like red extensions are an artifact of the telescopes’s optics). In between, MIRI reveals a white region directly above and below the protostar, which doesn’t show as strongly in the NIRCam view. This region is a mixture of hydrocarbons, ionized neon, and thick dust, which shows that the protostar propels this matter quite far away from it as it messily consumes material from its disk.

As the protostar continues to age and release energetic jets, it’ll consume, destroy, and push away much of this molecular cloud, and many of the structures we see here will begin to fade. Eventually, once it finishes gathering mass, this impressive display will end, and the star itself will become more apparent, even to our visible-light telescopes.

The combination of analyses from both the near-infrared and mid-infrared views reveal the overall behavior of this system, including how the central protostar is affecting the surrounding region. Other stars in Taurus, the star-forming region where L1527 resides, are forming just like this, which could lead to other molecular clouds being disrupted and either preventing new stars from forming or catalyzing their development.The James Webb Space Telescope is the world’s premier space science observatory. Webb is solving mysteries in our solar system, looking beyond to distant worlds around other stars, and probing the mysterious structures and origins of our universe and our place in it. Webb is an international program led by NASA with its partners, ESA (European Space Agency) and CSA (Canadian Space Agency).  

The James Webb Space Telescope is the world’s premier space science observatory. Webb is solving mysteries in our solar system, looking beyond to distant worlds around other stars, and probing the mysterious structures and origins of our universe and our place in it. Webb is an international program led by NASA with its partners, ESA (European Space Agency) and CSA (Canadian Space Agency).

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View/Download all image products at all resolutions for this article from the Space Telescope Science Institute.

Media Contacts

Laura Betzlaura.e.betz@nasa.gov, Rob Gutrorob.gutro@nasa.gov
NASA’s Goddard Space Flight Center, Greenbelt, Md.

Hanna Braun hbraun@stsci.edu Christine Pulliamcpulliam@stsci.edu
Space Telescope Science Institute, Baltimore, Md.

Related Information

ARTICLE/IMAGE: Webb’s previous observation of L1527, with NIRCam (Near-Infrared Camera)

VIDEO:   Fly-through the star-forming Pillars of Creation

INTERACTIVE: Explore star formation via a multi-wavelength view of Herbig-Haro 46/47

POSTER: L1527 NIRCam poster

VIDEO: Science Snippets Video: Dust and the formation of Planetary Systems

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Jul 02, 2024
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Bente Eegholm: Ensuring Space Telescopes Have Stellar Vision

Bente Eegholm: Ensuring Space Telescopes Have Stellar Vision

Bente Eegholm is an optical engineer working to ensure missions like the Nancy Grace Roman Space Telescope have stellar vision. When it launches by May 2027, the Roman mission will shed light on many astrophysics topics, like dark energy, which are currently shrouded in mystery. Bente’s past work has included Earth-observing missions and the James Webb Space Telescope.

Name: Bente Eegholm
Title: Goddard Optics Lead for Roman Space Telescope OTA (Optical Telescope Assembly)
Formal Job Classification: Optical Engineer
Organization: Optics Branch (Code 551)

A woman seen reflected in a large mirror
Bente Eegholm stands by the NASA’s Nancy Grace Roman Space Telescope’s primary mirror at L3Harris in Rochester, New York, in 2022, before telescope integration. (The black lines are resistor wires. They will be obscured by the secondary mirror struts).
NASA/Chris Gunn

What do you do and what is most interesting about your role at Goddard?

I am an optical engineer, and I work on the Nancy Grace Roman Space Telescope as the Goddard optics lead on the observatory’s OTA (Optical Telescope Assembly). My work is a combination of optical systems work, technical meetings, and hands-on work in the labs and integration facilities. The most interesting part is that we are creating unique, one-of-a-kind instruments, which enable NASA, as well as anyone around the world, to become more knowledgeable about our universe, including our own planet.

How will your current work influence the Nancy Grace Roman Space Telescope’s future observations?

The quality of Roman’s future observations is directly tied to the telescope’s optical quality. As an optical engineer I am involved with providing the best imaging possible for the telescope and its science instruments. I work closely with the OTA management, and optical and system engineers at Goddard and at L3Harris in Rochester, New York, a mission partner that is building the OTA. The OTA consists of a series of total 10 mirrors. I am frequently on site in Rochester, most recently for the very important first light test and ensuing alignment process of the telescope. We are striving to get every photon possible delivered to Roman’s two instruments, the WFI (Wide Field Instrument) and coronagraph technology demonstration.

What motivates you as an engineer? And what was your path to your current role?

It motivates me to support a great purpose, pioneer technology for spaceflight, and to conquer the challenges that inevitably occur along the way. I also enjoy being a mentor for newer engineers, as well as giving Roman tours and presentations to Goddard visitors.

I received my M.Sc. and Ph.D. degrees in my native Denmark. The path to my current role really started in 2004 after I had obtained my green card and gotten a position with Swales Aerospace, supporting NASA Goddard’s Optics Branch, Code 551. I was a contractor for eight years, supporting the James Webb Space Telescope. This was a magnificent project to work on; it was very rewarding in terms of the optical technology to accomplish this mission, as well as the amazing and talented people with whom I was working. I supported the development and test of a speckle interferometer which we used to prove the stability of the backplane structure for Webb’s primary mirror.

Bente stands in front of the James Webb Space Telescope’s primary mirror in the clean room overlook at Goddard.
Photo courtesy of Bente Eegholm

After becoming a U.S. citizen, I obtained a civil servant position in 2012. I was appointed the ATLAS (Asteroid Terrestrial-impact Last Alert System) telescope product development lead for the ICESat-2 mission, an Earth-observing mission to measure sea ice thickness from space. Both a flight and a spare telescope were built, and after successful testing and delivery of the ATLAS flight telescope, the ATLAS spare telescope was a perfect match for GEDI (the Global Ecosystem Dynamics Investigation), a mission to measure forest canopies from the International Space Station. That naturally led to me to continue to GEDI, where I was the alignment lead. GEDI launched in December 2018.

In 2019 I started working on the Roman Space Telescope and was thrilled to work on a large astronomy mission again, and in two capacities to boot. Concurrently with my role on the telescope I was optics lead on the prism assembly (a slitless spectrometer which helps enable the WFI’s study of dark energy) from 2019 until its completion and delivery to the WFI in September 2022.

I feel very fortunate to have experience from both astronomy and Earth-observing missions! It definitely widens your technical experience. Often, the telescopes and science instruments for astronomy missions typically take longer to develop and implement than the ones for Earth-observing missions. With the shorter time to launch, you have the opportunity to see the fruits of your labor fly into space within a few years, and it is beneficial to go through the steps of an entire development and launch cycle.

How do you stay updated on the latest technological advancements? How do you apply that knowledge to your work?

I enjoy learning something new every day, either by individual research or via professional organizations. I use it in my own work and in working with many optics vendors, and being a reviewer on projects and proposals. Bringing new technology to Goddard is important, and we must approve each technology for space flight before we can use it in our next missions.

A woman seen reflected in
Bente with the GEDI (Global Ecosystem Dynamics Investigation) telescope at Goddard.
NASA/Desiree Stover

What is your favorite project or challenge you’ve worked on so far in your career?

That is a really hard question. Just like you can’t choose between your children! All four of the missions I have worked on have been awesome experiences. A recent amazing event, though, was on Roman, watching the first fringes emerge on the OTA interferometer screen at the “first light” session in the integration facility. This was the result of several years of hard work for many people, and it indicated that all the 10 telescope mirrors were well-positioned, boding well for the successful final alignment, which we achieved.

What do you like best about working for NASA?

I enjoy working on unique projects, always reaching for the stars, and using new technology and methods. NASA is a unique organization, known by everyone around the globe. For example, it has been a great honor to hear from many people who follow our work how much they appreciate Webb. NASA’s work is very visible, and that commits us and holds us accountable. And we are up to the challenge!

What hobbies fill your time outside of work?

I love yoga, and hiking in nature. I also love singing in choir, especially classical music. The magnificent sound we can achieve with 75 singers, and how the different types of voices merge to convey the music, is an example of collaboration that is a bit like succeeding in a flight mission. All the different people, tasks and parts synchronized and coming together to make it work!

What advice do you have for others who are interested in working in engineering?

Maybe I am a bit biased, since both my husband and I are engineers, my son is in grad school for engineering, and my daughter is in grad school for ocean science. In my opinion, an engineering degree offers highly transferable skills, and is a great path for everyone who enjoys math and physics. People skills are also important in engineering, as most projects are performed in teams. Make sure to select math and science classes in high school, and aim for internships in college. An engineering degree requires effort and dedication, but it’s worth it!

By Ashley Balzer
NASA’s Goddard Space Flight Center, Greenbelt, Md.

A banner graphic with a group of people smiling and the text "Conversations with Goddard" on the right. The people represent many genders, ethnicities, and ages, and all pose in front of a soft blue background image of space and stars.

Conversations With Goddard is a collection of Q&A profiles highlighting the breadth and depth of NASA’s Goddard Space Flight Center’s talented and diverse workforce. The Conversations have been published twice a month on average since May 2011. Read past editions on Goddard’s “Our People” webpage.

   

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Ashley Balzer

Bente Eegholm: Ensuring Space Telescopes Have Stellar Vision

Bente Eegholm: Ensuring Space Telescopes Have Stellar Vision

Bente Eegholm is an optical engineer working to ensure missions like the Nancy Grace Roman Space Telescope have stellar vision. When it launches by May 2027, the Roman mission will shed light on many astrophysics topics, like dark energy, which are currently shrouded in mystery. Bente’s past work has included Earth-observing missions and the James Webb Space Telescope.

Name: Bente Eegholm
Title: Goddard Optics Lead for Roman Space Telescope OTA (Optical Telescope Assembly)
Formal Job Classification: Optical Engineer
Organization: Optics Branch (Code 551)

A woman seen reflected in a large mirror
Bente Eegholm stands by the NASA’s Nancy Grace Roman Space Telescope’s primary mirror at L3Harris in Rochester, New York, in 2022, before telescope integration. (The black lines are resistor wires. They will be obscured by the secondary mirror struts).
NASA/Chris Gunn

What do you do and what is most interesting about your role at Goddard?

I am an optical engineer, and I work on the Nancy Grace Roman Space Telescope as the Goddard optics lead on the observatory’s OTA (Optical Telescope Assembly). My work is a combination of optical systems work, technical meetings, and hands-on work in the labs and integration facilities. The most interesting part is that we are creating unique, one-of-a-kind instruments, which enable NASA, as well as anyone around the world, to become more knowledgeable about our universe, including our own planet.

How will your current work influence the Nancy Grace Roman Space Telescope’s future observations?

The quality of Roman’s future observations is directly tied to the telescope’s optical quality. As an optical engineer I am involved with providing the best imaging possible for the telescope and its science instruments. I work closely with the OTA management, and optical and system engineers at Goddard and at L3Harris in Rochester, New York, a mission partner that is building the OTA. The OTA consists of a series of total 10 mirrors. I am frequently on site in Rochester, most recently for the very important first light test and ensuing alignment process of the telescope. We are striving to get every photon possible delivered to Roman’s two instruments, the WFI (Wide Field Instrument) and coronagraph technology demonstration.

What motivates you as an engineer? And what was your path to your current role?

It motivates me to support a great purpose, pioneer technology for spaceflight, and to conquer the challenges that inevitably occur along the way. I also enjoy being a mentor for newer engineers, as well as giving Roman tours and presentations to Goddard visitors.

I received my M.Sc. and Ph.D. degrees in my native Denmark. The path to my current role really started in 2004 after I had obtained my green card and gotten a position with Swales Aerospace, supporting NASA Goddard’s Optics Branch, Code 551. I was a contractor for eight years, supporting the James Webb Space Telescope. This was a magnificent project to work on; it was very rewarding in terms of the optical technology to accomplish this mission, as well as the amazing and talented people with whom I was working. I supported the development and test of a speckle interferometer which we used to prove the stability of the backplane structure for Webb’s primary mirror.

Bente stands in front of the James Webb Space Telescope’s primary mirror in the clean room overlook at Goddard.
Photo courtesy of Bente Eegholm

After becoming a U.S. citizen, I obtained a civil servant position in 2012. I was appointed the ATLAS (Asteroid Terrestrial-impact Last Alert System) telescope product development lead for the ICESat-2 mission, an Earth-observing mission to measure sea ice thickness from space. Both a flight and a spare telescope were built, and after successful testing and delivery of the ATLAS flight telescope, the ATLAS spare telescope was a perfect match for GEDI (the Global Ecosystem Dynamics Investigation), a mission to measure forest canopies from the International Space Station. That naturally led to me to continue to GEDI, where I was the alignment lead. GEDI launched in December 2018.

In 2019 I started working on the Roman Space Telescope and was thrilled to work on a large astronomy mission again, and in two capacities to boot. Concurrently with my role on the telescope I was optics lead on the prism assembly (a slitless spectrometer which helps enable the WFI’s study of dark energy) from 2019 until its completion and delivery to the WFI in September 2022.

I feel very fortunate to have experience from both astronomy and Earth-observing missions! It definitely widens your technical experience. Often, the telescopes and science instruments for astronomy missions typically take longer to develop and implement than the ones for Earth-observing missions. With the shorter time to launch, you have the opportunity to see the fruits of your labor fly into space within a few years, and it is beneficial to go through the steps of an entire development and launch cycle.

How do you stay updated on the latest technological advancements? How do you apply that knowledge to your work?

I enjoy learning something new every day, either by individual research or via professional organizations. I use it in my own work and in working with many optics vendors, and being a reviewer on projects and proposals. Bringing new technology to Goddard is important, and we must approve each technology for space flight before we can use it in our next missions.

A woman seen reflected in
Bente with the GEDI (Global Ecosystem Dynamics Investigation) telescope at Goddard.
NASA/Desiree Stover

What is your favorite project or challenge you’ve worked on so far in your career?

That is a really hard question. Just like you can’t choose between your children! All four of the missions I have worked on have been awesome experiences. A recent amazing event, though, was on Roman, watching the first fringes emerge on the OTA interferometer screen at the “first light” session in the integration facility. This was the result of several years of hard work for many people, and it indicated that all the 10 telescope mirrors were well-positioned, boding well for the successful final alignment, which we achieved.

What do you like best about working for NASA?

I enjoy working on unique projects, always reaching for the stars, and using new technology and methods. NASA is a unique organization, known by everyone around the globe. For example, it has been a great honor to hear from many people who follow our work how much they appreciate Webb. NASA’s work is very visible, and that commits us and holds us accountable. And we are up to the challenge!

What hobbies fill your time outside of work?

I love yoga, and hiking in nature. I also love singing in choir, especially classical music. The magnificent sound we can achieve with 75 singers, and how the different types of voices merge to convey the music, is an example of collaboration that is a bit like succeeding in a flight mission. All the different people, tasks and parts synchronized and coming together to make it work!

What advice do you have for others who are interested in working in engineering?

Maybe I am a bit biased, since both my husband and I are engineers, my son is in grad school for engineering, and my daughter is in grad school for ocean science. In my opinion, an engineering degree offers highly transferable skills, and is a great path for everyone who enjoys math and physics. People skills are also important in engineering, as most projects are performed in teams. Make sure to select math and science classes in high school, and aim for internships in college. An engineering degree requires effort and dedication, but it’s worth it!

By Ashley Balzer
NASA’s Goddard Space Flight Center, Greenbelt, Md.

A banner graphic with a group of people smiling and the text "Conversations with Goddard" on the right. The people represent many genders, ethnicities, and ages, and all pose in front of a soft blue background image of space and stars.

Conversations With Goddard is a collection of Q&A profiles highlighting the breadth and depth of NASA’s Goddard Space Flight Center’s talented and diverse workforce. The Conversations have been published twice a month on average since May 2011. Read past editions on Goddard’s “Our People” webpage.

   

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Ashley Balzer

NASA Stennis Achieves Primary Success for Historic In-Space Mission

NASA Stennis Achieves Primary Success for Historic In-Space Mission

Travis Martin is pictured sitting at a desk while using the ASTRA software
NASA Stennis Autonomous Systems Laboratory Project Engineer Travis Martin monitors successful data delivery from the center’s ASTRA payload aboard the orbiting Sidus Space LizzieSat-1 satellite. The ASTRA autonomous systems hardware/software payload represents the first-ever in-space mission for NASA Stennis.
NASA/Danny Nowlin

NASA’s Stennis Space Center and partner Sidus Space Inc. announced primary mission success July 2 for the center’s historic in-space mission – an autonomous systems payload aboard an orbiting satellite.

“Our ASTRA (Autonomous Satellite Technology for Resilient Applications) payload is active and operational,” NASA Stennis Center Director John Bailey said. “This is an incredible achievement for Stennis, our first-ever in-space mission flying on a new state-of-the-art satellite. We are all celebrating the news.”

ASTRA is the on-orbit payload mission developed by NASA Stennis and is an autonomous systems hardware/software payload. The NASA Stennis ASTRA technology demonstrator is a payload rider aboard the Sidus Space premier satellite, LizzieSat-1 (LS-1) small satellite. Partner Sidus Space is responsible for all LS-1 mission operations, including launch and satellite activation, which allowed the NASA Stennis ASTRA team to complete its primary mission objectives.

LS-1 launched into space on the SpaceX Transporter 10 rideshare mission March 4 and deployed the same day. The LS-1 satellite commissioning began after deployment and was completed on May 12. Sidus Space’s next step was to begin activation of payloads, including ASTRA.

After the payload was activated, the NASA Stennis Autonomous Systems Laboratory (ASL) team confirmed they had established a telemetry link to send and receive data in the ASTRA Payload Operation Command Center. The ASL team continued to checkout and verify operation of ASTRA and has confirmed that ASTRA primary mission objectives have been successfully achieved.  

“This is just a remarkable and inspiring accomplishment for the entire team,” said Chris Carmichael, NASA Stennis ASL branch chief. “So many people put in a tremendous effort to bring us to this point. It is a great demonstration of the team’s vision and capabilities, and I am excited to see what the future holds.”

The NASA Stennis ASL works to create safe-by-design autonomous systems. ASTRA demonstrates technology that is required by NASA and industry for upcoming space missions. The ASTRA computer on the satellite runs a digital twin of satellite systems, which detects and identifies the causes of anomalies, and autonomously generates plans to resolve those issues. Ultimately, ASTRA will demonstrate autonomous operations of LS-1.

“Achieving ASTRA’s primary mission objectives underscores our dedication and commitment to driving innovation while advancing space technology alongside NASA, our trusted partner,” said Carol Craig, Founder and CEO of Sidus Space. “We are proud to support such groundbreaking projects in our industry and eagerly anticipate the continued progress of our LizzieSat-1 mission.”

The success of the ASTRA mission comes as NASA Stennis moves forward with strategic plans to design autonomous systems that will help accelerate development of intelligent aerospace systems and services for government and industry.

For information about NASA’s Stennis Space Center, visit:

Stennis Space Center – NASA

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Last Updated

Jul 02, 2024

Editor
NASA Stennis Communications
Contact
C. Lacy Thompson
Location
Stennis Space Center

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