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Aeolus’ fiery demise to set standard for safe reentry
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By European Space Agency
In a final test before its shipping to its Indian launch site, ESA’s eclipse-making double-satellite Proba-3 mission has received commands from its science team and transmitted images back, exactly as it will operate in orbit.
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By NASA
The Moon is pictured on Dec. 7, 2022, the day before its Full Moon phase from the International Space Station as it orbited above the southern Indian Ocean.Credit: NASA NASA will coordinate with U.S. government stakeholders, partners, and international standards organizations to establish a Coordinated Lunar Time (LTC) following a policy directive from the White House in April. The agency’s Space Communication and Navigation (SCaN) program is leading efforts on creating a coordinated time, which will enable a future lunar ecosystem that could be scalable to other locations in our solar system.
The lunar time will be determined by a weighted average of atomic clocks at the Moon, similar to how scientists calculate Earth’s globally recognized Coordinated Universal Time (UTC). Exactly where at the Moon is still to be determined, since current analysis indicates that atomic clocks placed at the Moon’s surface will appear to ‘tick’ faster by microseconds per day. A microsecond is one millionth of a second. NASA and its partners are currently researching which mathematical models will be best for establishing a lunar time.
To put these numbers into perspective, a hummingbird’s wings flap about 50 times per second. Each flap is about .02 seconds, or 20,000 microseconds. So, while 56 microseconds may seem miniscule, when discussing distances in space, tiny bits of time add up.
“For something traveling at the speed of light, 56 microseconds is enough time to travel the distance of approximately 168 football fields,” said Cheryl Gramling, lead on lunar position, navigation, timing, and standards at NASA Headquarters in Washington. “If someone is orbiting the Moon, an observer on Earth who isn’t compensating for the effects of relativity over a day would think that the orbiting astronaut is approximately 168 football fields away from where the astronaut really is.”
As the agency’s Artemis campaign prepares to establish a sustained presence on and around the Moon, NASA’s SCaN team will establish a time standard at the Moon to ensure the critical time difference does not affect the safety of future explorers. The approach to time systems will also be scalable for Mars and other celestial bodies throughout our solar system, enabling long-duration exploration.
As the commercial space industry grows and more nations are active at the Moon, there is a greater need for time standardization. A shared definition of time is an important part of safe, resilient, and sustainable operations,” said Dr. Ben Ashman, navigation lead for lunar relay development, part of NASA’s SCaN program.
NASA’s SCaN program serves as the office for the agency’s space communications operations and navigation. More than 100 NASA and non-NASA missions rely on SCaN’s two networks, the Near Space Network and the Deep Space Network, to support astronauts aboard the International Space Station and future Artemis missions, monitor Earth’s weather and the effects of climate change, support lunar exploration, and uncover the solar system and beyond.
Learn more about NASA’s plan to return to the Moon at:
https://www.nasa.gov/humans-in-space/artemis
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By NASA
NASA’s Stennis Space Center near Bay St. Louis, Mississippi, announced Wednesday it will continue its historic in-space autonomous systems payload mission aboard an orbiting satellite through a follow-on agreement with Sidus Space, Inc.
“We are excited to report the historic ASTRA (Autonomous Satellite Technology for Resilient Applications) mission will continue,” said Chris Carmichael, chief, Stennis Autonomous Systems Laboratory (ASL) branch at NASA Stennis. “We look forward to working with Sidus Space to demonstrate the capabilities of the NASA Stennis payload and our autonomous systems team.”
With this new agreement, the ASTRA payload will be used to collect onboard data on satellite systems and support management of the satellite’s Electrical Power System (EPS). The NASA Stennis ASTRA system will monitor and autonomously optimize the satellite’s battery system, ensuring the satellite continues to operate as needed for the course of its remaining mission lifetime. The ASTRA EPS management capability provides a new, innovative level of adaptability and efficiency for monitoring the satellite’s ongoing operations.
Developed by NASA Stennis to fly and demonstrate an autonomous systems hardware/software payload, ASTRA is the on-orbit mission. The NASA Stennis ASTRA technology demonstrator is a payload rider aboard the Sidus Space LizzieSat-1 (LS-1) small satellite. Partner Sidus Space is responsible for all LS-1 mission operations, including launch and satellite activation.
The LS-1 small satellite launched into space on the SpaceX Transporter 10 rideshare mission March 4 and deployed the same day. Following payload activation by Sidus Space, the NASA Stennis team worked with the company to establish a telemetry link to send and receive data in the ASTRA Payload Operation Command Center located at the NASA site. The ASL team continued to checkout and verify operation of ASTRA, confirming in early July that ASTRA primary mission objectives were successful.
The team is now focused on demonstrating autonomous system management as part of the LS-1 satellite’s planned four-year mission. “We are excited about the opportunity to continue this unprecedented mission,” Carmichael said. “Every step helps advance our autonomous systems work and lays a foundation for continued development and success.”
The NASA Stennis ASL team works to create safe-by-design autonomous systems. NASA’s 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 key satellite systems, which identifies anomalies, and autonomously generates plans to resolve those issues.
The ongoing 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:
https://www.nasa.gov/stennis
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By European Space Agency
Video: 00:06:50 The first of four satellites that make up ESA’s Cluster mission is coming safely back down to Earth, marking a brilliant end to this remarkable mission.
The satellite’s orbit was tweaked back in January to target a region as far as possible from populated regions. This ensures that any spacecraft parts that survive the reentry will fall over open ocean.
During 24 years in space, Cluster has sent back precious data on how the Sun interacts with Earth’s magnetic field, helping us better understand and forecast potentially dangerous space weather.
With this first ever targeted reentry, Cluster goes down in history for a different reason, taking ESA well beyond international space safety standards and helping ensure the long-term sustainability of space activities.
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