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By NASA
Sandra Connelly, deputy associate administrator for NASA’s Science Mission Directorate, left, Lori Glaze, acting deputy associate administrator for NASA’s Exploration Systems Development Mission Directorate, Robyn Gatens, director of the International Space Station at NASA Headquarters, and Carrie Olsen, manager of the Next Gen STEM project for NASA’s Office of STEM Engagement, discuss key takeaways at the conclusion of NASA’s LEO Microgravity Strategy Industry and Academia Workshop, Friday, Sept. 13, 2024, at Convene in Washington. NASA’s LEO Microgravity Strategy effort aims to develop and document an objectives-based approach toward the next generation of human presence in low Earth orbit to advance microgravity science, technology, and exploration.NASA/Joel Kowsky As part of NASA’s effort to advance microgravity science, technology, and exploration in low Earth orbit (LEO), the agency conducted two stakeholder workshops in London and Washington to solicit feedback from the international community, including NASA’s international partners, American industry, and academia on Sept. 6 and Sept. 13, respectively.
The agency released a draft set of 42 objectives in late August, seeking input from U.S. industry, academia, international communities, NASA employees, and others to ensure its framework for the next generation of human presence in low Earth orbit, set to be finalized this winter, includes ideas and contributions from a range of stakeholders. The objectives span six categories: science, exploration-enabling research and technology development, commercial low Earth orbit infrastructure, operations, international cooperation, and workforce and engagement.
“As we chart the future of human exploration, it’s vital that we harness the insights and expertise of our diverse stakeholders,” said NASA Deputy Administrator Pam Melroy. “These workshops provide an invaluable platform for stakeholders to share their insights, helping us create a strategy that reflects our shared ambitions for the future of space exploration.”
Consultation is a fundamental aspect of NASA’s LEO Microgravity Strategy, emphasizing the importance of collaboration and the integration of diverse perspectives in advancing scientific research and technology development in low Earth orbit. By actively engaging with stakeholders –including scientists, industry partners, and educational institutions –NASA aims to gather valuable insights and align its objectives with the broader goals of the space community.
“Engaging with a wide array of voices allows us to tap into innovative ideas that will enhance our missions,” stated Robyn Gatens, director of the International Space Station and acting director of Commercial Spaceflight. “This collaborative approach not only strengthens our current initiatives but also lays the groundwork for future advancements in space exploration.”
To contribute to NASA’s low Earth orbit microgravity strategy, visit: www.leomicrogravitystrategy.org
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By NASA
4 Min Read NASA Seeks Input for Astrobee Free-flying Space Robots
iss069e010815 (May 16, 2023) — UAE (United Arab Emirates) astronaut and Expedition 69 Flight Engineer Sultan Alneyadi observes a free-flying Astrobee robotic assistant during the testing of its operations for an upcoming student competition to control the robotic devices. Credits: NASA NASA is seeking input from American companies for the operation and use of a system of free-flying robots aboard the International Space Station as the agency continues to foster scientific, educational, and technological developments in low Earth orbit for the benefit of all.
The colorful, cube-shaped robots – named “Bumble,” “Honey,” and “Queen” – are part of the Astrobee system helping astronauts and researchers perform technology demonstrations, scientific research, and STEM (science, technology, engineering and mathematics) activities in the unique environment of space since 2018.
“Dozens of institutions collaborate with NASA to use the Astrobee system to test new hardware and software technologies,” said Jose Benavides, project manager for the Astrobee facilities at NASA’s Ames Research Center in California’s Silicon Valley, where the system was designed and built. “I’m excited to hear how respondents think Astrobee can continue to advance robotics in space.”
NASA issued a Request for Information to inform strategic planning, inviting industry to provide information to help shape the maturation of robotics in zero gravity to achieve the greatest scientific and exploration value. Responses are due Sept. 27, 2024. To learn more about the Request for Information, visit:
https://sam.gov/opp/7893fe01e7bf4ae69029b5d8915e62c5/view
iss065e389375 (9/20/2021) — NASA astronaut Shane Kimbrough poses with the Astrobee robotic free-flyers in support of the Kibo Robot Programming Challenge (Robo-Pro Challenge). The Kibo-RPC, allows students to create programs to control Astrobee, a free-flying robot aboard the International Space Station (ISS). The battery-powered robots in the Astrobee system fly around the space station’s modules using electric fans for propulsion and “see” their surroundings using lights, cameras, and other sensors. They have interchangeable “arms” that provide ways for the robots to hold objects or keep steady for tasks requiring stability, and magnets to ensure they stay securely docked when recharging.
Working autonomously, or via remote control by astronauts, flight controllers, or researchers on the ground, the robots can be used to off-load time-consuming tasks. For instance, the robots can work independently or collaboratively to assist with routine chores like space station monitoring, maintenance, inventory, experiment documentation, or moving cargo throughout the station. This allows astronauts more time to tackle complex work that only humans can perform.
Astrobee’s versatile design has allowed thousands of hours of testing on hundreds of microgravity experiments. Many have involved astronauts, but the facility also is regularly used by researchers and student teams across the world competing for the opportunity to run their programs on the robots in space.
Further developing human-robotic technology will pave the way for future crewed and uncrewed spacecraft maintenance and exploration tasks done by robots both off-planet and in deep space"
Jonathan Barlow
Astrobee Project Manager
For example, NASA’s ISAAC (Integrated System for Autonomous and Adaptive Caretaking) project, used the Astrobees to study how robots could assist spacecraft, vehicle systems, and ground operators. The technology could help NASA use robot caretakers for critical spacecraft in the agency’s Moon-to-Mars plans, including the Gateway lunar space station and Mars transit habitat vehicle, especially during the months-long periods when these spacecraft will be uncrewed.
“Our ISAAC work has proved out its technology in a high-fidelity space environment because of the ready availability of the capable Astrobee robots,” said Trey Smith, project manager for ISAAC at NASA Ames.
The project demonstrated using multiple Astrobees to autonomously collect the first robot-generated survey of a spacecraft interior. Other ISAAC firsts include the first use of a robot to locate the source of a sound in space, in collaboration with the Bosch USA SoundSee payload team, and the first time robots navigated between modules of a space station. Future robots could use ISAAC technology to transfer cargo between space vehicles or respond to a time-critical fault like a leak due to a micrometeoroid impact, all without human assistance.
“With Astrobee, we’ve learned about flying multiple robots in space alongside humans,” said Jonathan Barlow, project manager for Astrobee at NASA Ames. “Further developing human-robotic technology will pave the way for future crewed and uncrewed spacecraft maintenance and exploration tasks done by robots both off-planet and in deep space.”
The Astrobee Facility, operated out of NASA’s Ames Research Center, provides a free-flying robotic system for space station research and STEM outreach. NASA’s Game Changing Development Program, part of the agency’s Space Technology Mission Directorate, funded Astrobee. NASA’s International Space Station Utilization Office provides ongoing funding.
iss071e464314 (Aug. 12, 2024) — NASA astronaut and Expedition 71 Flight Engineer Jeanette Epps monitors a pair of Astrobee robotic free-flying assistants as they demonstrate autonomous docking maneuvers inside the International Space Station’s Kibo laboratory module. The cube-shaped, toaster-sized devices were operating with a connecting interface system, called CLINGERS with an embedded navigation sensor, that may benefit construction in space.View the full article
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By NASA
A waxing gibbous moon rises over the Indian Ocean as the International Space Station orbited 266 miles above.Credit: NASA As NASA and its partners continue to conduct groundbreaking research aboard the International Space Station, the agency announced Monday it is seeking U.S. industry, academia, international partners, and other stakeholders’ feedback on newly developed goals and objectives that will help guide the next generation of human presence in low Earth orbit.
“From the very beginning, NASA’s flagship human spaceflight programs have built upon each other, expanding our knowledge and experience of humans living and working in space,” said NASA Deputy Administrator Pam Melroy. “As commercial industry is constructing new human-enabled platforms for low Earth orbit, NASA must answer the question: what should our goals and objectives be to advance our future science and exploration missions?”
NASA published draft high-level goals and objectives outlining 42 key points in six main areas: science, exploration-enabling research and technology development, commercial low Earth orbit infrastructure, operations, international cooperation, and workforce and engagement.
“Feedback is essential for shaping our long-term microgravity research and development activities,” said Ken Bowersox, associate administrator, Space Operations Mission Directorate at NASA Headquarters in Washington. “We are committed to refining our objectives with input from both within NASA and external partners, ensuring alignment with industry and international goals. After reviewing feedback, we will finalize our strategy later this year.”
The agency will conduct two invite-only workshops in September to discuss feedback on the draft goals and objectives. The first workshop is with international partners, and the second will engage U.S. industry and academic representatives.
NASA employees also are invited to provide input through internal agency channels. This approach reflects NASA’s commitment to harnessing diverse perspectives to navigate the rapidly evolving low Earth orbit environment.
“Organizations are increasingly recognizing the transformative benefits of space, with both governments and commercial activities leveraging the International Space Station as a testbed,” said Robyn Gatens, International Space Station director and acting director of commercial spaceflight at NASA Headquarters. “By developing a comprehensive strategy, NASA is looking to the next chapter of U.S. human space exploration to help shape the agency’s future in microgravity for the benefit of all.”
Stakeholders may submit comments by close of business on Friday, Sept. 27 to:
https://www.leomicrogravitystrategy.org/
-end-
Amber Jacobson
Headquarters, Washington
202-358-1600
amber.c.jacobson@nasa.gov
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By European Space Agency
As climate change drives more frequent and severe weather events, the need for accurate and timely forecasting has never been more critical. And now, the next Meteosat Third Generation weather satellite has passed its environmental test campaign with flying colours, taking it a significant step closer to launch.
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By NASA
On July 8, 1994, space shuttle Columbia took to the skies on its 17th trip into space, on the second International Microgravity Laboratory (IML-2) mission. Six space agencies sponsored 82 life and microgravity science experiments. The seven-person crew consisted of Commander Robert D. Cabana, Pilot James D. Halsell, Payload Commander Richard J. Hieb, Mission Specialists Carl E. Walz, Leroy Chiao, and Donald A. Thomas, and Payload Specialist Chiaki Mukai representing the National Space Development Agency (NASDA) of Japan, now the Japan Aerospace Exploration Agency. Jean-Jacques H. Favier of the French space agency CNES served as a backup payload specialist. During their then-record setting 15-day shuttle flight, the international team of astronauts successfully completed the science program. They returned to earth on July 23.
Left: The STS-65 crew patch. Middle: Official photo of the STS-65 crew of Richard J. Hieb, seated left, Robert D. Cabana, and Donald A. Thomas; Leroy Chiao, standing left, James D. Halsell, Chiaki Mukai of Japan, and Carl E. Walz. Right: The payload patch for the International Microgravity Laboratory-2.
In August 1973, NASA and the European Space Research Organization, reorganized as the European Space Agency (ESA) in 1975, agreed to build a reusable laboratory called Spacelab to fly in the space shuttle’s cargo bay. As part of the agreement, ESA built two pressurized modules in addition to other supporting hardware. First flying on STS-9 in 1983, the 18-foot-long pressurized Spacelab module made its 10th flight on STS-65. In September 1992 NASA named Hieb as the IML-2 payload commander and Mukai and Favier as prime and backup payload specialists, respectively, adding Chiao and Thomas as mission specialists in October 1992, finally designating Cabana, Halsell, and Walz as the orbiter crew in August 1993. For Cabana and Hieb, both selected as astronauts in 1985, STS-65 marked their third spaceflight. NASA selected Halsell, Walz, Chiao, and Thomas in 1990, in the class nicknamed The Hairballs. Walz would make his second flight, with the other three making their first. NASDA selected Mukai in 1985 and she holds the distinction as the first Japanese woman in space. Chiao and Mukai as part of the STS-65 crew marked the first time that two Asians flew on the shuttle at the same time, and with Kazakh cosmonaut Talgat A. Musbayev aboard Mir, the first time that three people of Asian origins flew in space at the same time.
Left: The STS-65 crew during preflight training at NASA’s Johnson Space Center in Houston. Right: Technicians at NASA’s Kennedy Space Center in Florida prepare the Spacelab module for the STS-65 mission.
Columbia returned to NASA’s Kennedy Space Center (KSC) in Florida following its previous flight, STS-62, in March 1994. Technicians in KSC’s Orbiter Processing Facility (OPF) serviced the orbiter, removed the previous payload, and installed the Spacelab module in the payload bay. Following a successful leak check of the Spacelab module, rollover of Columbia from the OPF to the Vehicle Assembly Building (VAB) took place on June 8, where workers mated it with an external tank (ET) and two solid rocket boosters (SRBs). Following integrated testing, the stack rolled out to Launch Pad 39A seven days later. The crew participated in the Terminal Countdown Demonstration Test on June 22.
Liftoff of space shuttle Columbia on STS-65 carrying the second International Microgravity Laboratory.
On July 8, 1994, precisely on time, Columbia thundered off KSC’s Launch Pad 39A to begin the STS-65 mission. For the first time in shuttle history, a video camera recorded the liftoff from the orbiter’s flight deck, showing the vibrations during the first two minutes while the SRBs fired, smoothing out once the shuttle main engines took over. Mounted inside Columbia’s payload bay, the Spacelab 18-foot-long module provided a shirt-sleeve environment for the astronauts to conduct the scientific experiments. As during many Spacelab missions, the STS-65 crew carried out science operations 24-hours a day, divided into two teams – the red shift comprised Cabana, Halsell, Hieb, and Mukai, while Chiao, Thomas, and Walz made up the blue shift.
Left: Still image from video recorded on the shuttle’s flight deck during powered ascent. Middle: James D. Halsell, left, and Carl E. Walz moments after Columbia reached orbit. Right: View of the Spacelab module in the shuttle’s payload bay.
Left: Richard J. Hieb opens the hatch from the airlock to the tunnel leading to the Spacelab module. Middle: Hieb and Chiaki Mukai begin activating Spacelab and its experiments. Right: The view from the tunnel showing astronauts at work in the Spacelab module.
After reaching orbit, the crew opened the payload bay doors and deployed the shuttle’s radiators, and removed their bulky launch and entry suits, stowing them for the remainder of the flight. Shortly after, Hieb opened the hatch to the transfer tunnel and translated through it to enter the Spacelab module for the first time. He and Mukai activated the module and turned on the first experiments. For the next 14 days, the astronauts worked round the clock, with Cabana, Halsell, and Walz managing the shuttle’s systems while Hieb, Chiao, Thomas, and Mukai conducted the bulk of the research. The astronauts commemorated the 25th anniversary of the Apollo 11 launch on July 16 and the Moon landing four days later, recalling that their spacecraft and the Command Module shared the name Columbia.
Left: Chiaki Mukai of the National Space Development Agency of Japan, now the Japan Aerospace Exploration Agency, talks to students in Japan using the shuttle’s amateur radio. Middle: Richard J. Hieb, left, and Robert D. Cabana take an air sample from an experiment. Right: Hieb in the Lower Body Negative Pressure device.
Left: Donald A. Thomas, left, Leroy Chiao, Richard J. Hieb, and Chiaki Mukai at work in the Spacelab module. Middle: Chiao, left, and Thomas work on the Biorack instruments. Right: Goldfish swim in the Aquatic Animal Experiment Unit.
Left: Robert D. Cabana uses the shuttle’s amateur radio. Middle: Leroy Chiao looks out at the Earth. Right: Carl E. Walz working on the shuttle’s flight deck.
Left: Carl E. Walz flies through the Spacelab module. Middle: Donald A. Thomas gives two thumbs up for the crew’s performance during the mission. Right: Thomas, left, Walz, and Leroy Chiao pay tribute to Apollo 11 on the 25th anniversary of the Moon landing mission.
Left: The first time two Asians fly on the shuttle at the same time – Chiaki Mukai, left, of the National Space Development Agency of Japan, now the Japan Aerospace Exploration Agency, left, and NASA astronaut Leroy Chiao. Middle: Donald A. Thomas, left, James D. Halsell, Carl E. Walz, and Chiao, all selected in 1990 as part of astronaut class 13, nicknamed The Hairballs. Right: Inflight photograph of the STS-65 crew.
A selection of the STS-65 crew Earth observation photographs. Left: Rio de Janeiro. Middle: Barrier islands in Papua New Guinea. Right: Hurricane Emilia in the central Pacific Ocean.
Left: James D. Halsell uses the laptop-based PILOT to train for the entry and landing. Middle: The astronauts close Columbia’s payload bay doors prior to entry. Right: Flash of plasma seen through Columbia’s overhead window during reentry.
At the end of 13 days, the astronauts finished the last of the experiments and deactivated the Spacelab module. Managers waved off the planned landing on July 22 due to cloudy weather at KSC. On July 23, the astronauts closed the hatch to the Spacelab module for the final time, closed Columbia’s payload bay doors, donned their launch and entry suits, and strapped themselves into their seats for entry and landing. Cabana piloted Columbia to a smooth landing on KSC’s Shuttle Landing Facility, completing 236 orbits around the Earth in 14 days, 17 hours, and 55 minutes, at the time the longest shuttle flight. Mukai set a then-record for the longest single flight by a woman. In October 1994, Columbia returned to its manufacturer, Rockwell International in Palmdale, California, for scheduled modification and refurbishment before its next mission, STS-73, in October 1995.
Left: Robert D. Cabana pilots Columbia during the final approach to NASA’s Kennedy Space Center (KSC) in Florida, with the Vehicle Assembly Building visible through the window. Middle: Columbia touches down on KSC’s Shuttle Landing Facility to end the STS-65 mission. Right: Donald A. Thomas, left, and Cabana give a thumbs up after the successful mission.
The two Spacelab modules flew a total of 16 times, the last one during the STS-90 Neurolab mission in April 1998. Visitors can view the module that flew on STS-65 and eight other missions on display at the Stephen F. Udvar-Hazy Center of the Smithsonian Institution’s National Air and Space Museum in Chantilly, Virginia. The other module resides at the Airbus Defence and Space plant in Bremen, Germany, and not accessible to the public.
The Spacelab long module that flew on STS-65 and eight other missions on display at the Stephen F. Udvar-Hazy Center of the Smithsonian Institution’s National Air and Space Museum in Chantilly, Virginia.
Enjoy the crew narrate a video about the STS-65 mission. Read Cabana’s and Chiao’s recollections of the STS-65 mission in their oral histories with the JSC History Office.
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