Monday, August 30, 2021

Inspiration4 Update: The Mission Objectives Are Now Set For This Historic Flight...

The Inspiration4 astronauts pose in front of the Crew Dragon Resilience vehicle inside SpaceX's Dragonland facility in Florida...on August 30, 2021.
Inspiration4

Inspiration4 Crew Will Conduct Health Research to Further Human Exploration of Space (Press Release)

Historic mission to advance science and medicine for human health during spaceflight

LOS ANGELES – The crew of Inspiration4, the world’s first all-civilian human spaceflight mission to orbit, announced today that they will partake in a first-of-its-kind health research initiative to increase humanity’s knowledge on the impact of spaceflight on the human body. Once in orbit, the crew will perform carefully selected research experiments on human health and performance, which will have potential applications for human health on Earth and during future spaceflights. Additionally, SpaceX, the Translational Research Institute for Space Health (TRISH) at Baylor College of Medicine and investigators at Weill Cornell Medicine will collect environmental and biomedical data and biological samples from Inspiration4’s four crew members before, during, and after this historic spaceflight.

“The crew of Inspiration4 is eager to use our mission to help make a better future for those who will launch in the years and decades to come,” said Jared Isaacman, commander of the Inspiration4 mission. “In all of human history, fewer than 600 humans have reached space. We are proud that our flight will help influence all those who will travel after us and look forward to seeing how this mission will help shape the beginning of a new era for space exploration.”

SpaceX, TRISH, and investigators at Weill Cornell Medicine aim to continue broadening access to space medicine research by making all biomedical data collected for the Inspiration4 mission accessible through an open data repository funded and overseen by TRISH that can be easily accessed for research purposes. Empowered by NASA’s Human Research Program, TRISH is a virtual institute that finds and funds disruptive science and medical technology in order to reduce health and performance risks in space explorers. The Inspiration4 crew will conduct the following TRISH-sponsored research:

- Collect research-grade ECG activity, movement, sleep, heart rate and rhythm, blood oxygen saturation, cabin noise and light intensity.

- Perform a series of tests in the Cognition app designed to assess changes in behavioral and cognitive performance. This is the same app that is currently used by astronauts in NASA-funded research studies.

- Scan organ systems via a Butterfly IQ+ Ultrasound device, which is designed with artificial intelligence guidance for non-medical experts. Data collected will determine if non-medical experts can self-acquire clinical grade images without guidance from ground support and will provide a timeline of biological changes before and during spaceflight. This device is also currently being tested by astronauts on the International Space Station.

- Collect and test drops of blood during spaceflight for markers of immune function and inflammation using a state-of-the-art miniaturized device called the Vertical Flow Immunoassay (VFI).

- Use balance and perception tests pre-flight and immediately post-flight to measure sensorimotor adaptation during changes of gravity. These tests are currently performed by astronauts upon return from spaceflight.

- Archive, fully analyze, and share resulting biomedical samples and data in collaboration with investigators at Weill Cornell Medicine and research data in an open format database to enable greater collaborative research.

In addition, SpaceX is collaborating with investigators at Weill Cornell Medicine to perform a longitudinal, multi-omic analysis of the crew, including genome, epigenome, transcriptome, proteome, microbiome, metabolome, exosome, telomere, single-cell V(D)J immunophenotyping and epitope maps, and spatial transcriptome analysis. These samples and data will be added to a planned Biobank that will hold cryogenically-frozen samples and data from the Inspiration4 mission.

Investigators at Weill Cornell Medicine have worked closely with SpaceX’s medical team on the Inspiration4 sample collection and aim to replicate many of the same protocols and experiments that were pioneered in the NASA Twins Study and the Biomolecular Sequencer Missions. WorldQuant is providing funding support for the work at Weill Cornell Medicine. The planned Biobank will hold aliquots of the human, microbial, and environmental specimens that are collected before, during, and after missions and enable long-term research and health monitoring for astronauts.

SpaceX is targeting September 15 for Falcon 9’s launch of the Inspiration4 mission from historic Launch Complex 39A at NASA’s Kennedy Space Center. The three-day mission will target approximately a 575 km orbit, flying farther from Earth than any human spaceflight since the Hubble Space Telescope repair missions. Inspiration4’s goal is to inspire humanity and raise money for St. Jude Children’s Research Hospital. Click here to join the St. Jude fundraising adventure.

Source: Inspiration4.com

Thursday, August 19, 2021

CST-100 Update: Starliner Is Back in the Factory...

Boeing's CST-100 Starliner capsule is placed inside the Commercial Crew and Cargo Processing Facility at NASA's Kennedy Space Center in Florida...on August 19, 2021.
Boeing

Earlier today, Boeing's CST-100 Starliner was rolled back to the Commercial Crew and Cargo Processing Facility (C3PF), where the vehicle was assembled, at NASA's Kennedy Space Center in Florida.

After its launch on Orbital Flight Test (OFT)-2 was delayed due to 13 valves being stuck in the closed position inside its propulsion system, Starliner was destacked from its Atlas V rocket—which the capsule was mated to for its scheduled liftoff on August 3—and transported from Cape Canaveral Space Force Station's Space Launch Complex 41 back to the C3PF to undergo inspections.

Even if the valve issue is resolved as quickly as possible, the next opportunity to launch OFT-2 won't occur for a few months.

Worse-case scenario for OFT-2 is that the flight will be postponed to early 2022...due to the International Space Station already scheduled to receive other visitors such as SpaceX's CRS-23 cargo mission on August 28, and NASA's Crew-3 astronauts who will launch aboard a brand-new SpaceX Crew Dragon vehicle this October. Stay tuned.

Wednesday, August 18, 2021

SLS Update #2: NASA's Moon Rocket Is Now in Position to Begin a Series of Ground Tests Prior to Its Launch on Artemis 1...

The Mass Simulator for Orion (MSO) is stacked atop the Space Launch System (SLS) rocket inside the Vehicle Assembly Building (VAB) at NASA's Kennedy Space Center in Florida...on August 13, 2021.
NASA / Ben Smegelsky

Earlier today, NASA released these four photos showing the Space Launch System (SLS) rocket for Artemis 1 getting primed for ground tests that will soon take place inside the Vehicle Assembly Building (VAB) at Kennedy Space Center (KSC) in Florida.

In the pictures above and directly below, the Mass Simulator for Orion (MSO) is now mated to the Orion stage adapter's structural test article (OSA STA) atop SLS. This milestone occurred on August 13.

And in the last two images of this entry, the mobile launcher's intertank umbilical arm has been attached to SLS since August 12. This arm will provide power, communications and pressurized gases from ground support equipment to the mammoth vehicle as it sits on the pad at KSC's Launch Complex (LC)-39B during countdown.

With the MSO and OSA STA stacked on SLS, and the mobile launcher's umbilical arms now connected to the Moon rocket, technicians on NASA's Exploration Ground Systems team can prepare the vehicle for two upcoming demonstrations: the Umbilical Release and Retract Test (URRT) and an Integrated Modal Test (IMT). Click here to read more about the URRT and IMT.

Once these tests are completed, the MSO and OSA STA will be removed from SLS and the actual Orion spacecraft and its Cubesat-filled stage adapter will be transported to the VAB for mating on the launch vehicle. This should take place sometime next month.

Assuming that the URRT and IMT—as well as the Wet Dress Rehearsal set to occur at LC-39B in early autumn—go as planned, Artemis 1 will launch no earlier than November 22.

The MSO is stacked atop the SLS rocket inside the VAB at NASA's Kennedy Space Center in Florida...on August 13, 2021.
NASA / Ben Smegelsky

The intertank umbilical arm is attached to the SLS rocket inside the VAB at NASA's Kennedy Space Center in Florida...on August 12, 2021.
NASA / Kim Shiflett

The intertank umbilical arm is attached to the SLS rocket inside the VAB at NASA's Kennedy Space Center in Florida...on August 12, 2021.
NASA / Kim Shiflett

Tuesday, August 17, 2021

SLS Update: The Upper Stage Booster for NASA's First Crewed Lunar Mission in Over 50 Years Arrives on the Space Coast...

The Interim Cryogenic Propulsion Stage that will fly on NASA's Artemis 2 mission in late 2023 is processed inside the Delta IV Operations Center at Cape Canaveral Space Force Station in Florida...on July 28, 2021.
ULA

First Piece of Artemis II Flight Hardware Arrives in Florida (News Release)

The Interim Cryogenic Propulsion Stage for the second flight of NASA’s Space Launch System (SLS) rocket arrived in Florida on July 28 for the final phase of production. The stage and its single RL10 engine provide the in-space propulsion needed to send NASA’s Orion spacecraft and its crew on a precise trajectory to the Moon for Artemis II, the first crewed mission of NASA’s Artemis lunar missions. It is the first piece of the rocket for the Artemis II flight to arrive in Florida. Boeing and United Launch Alliance, the contractor team for the stage, shipped the Interim Cryogenic Propulsion Stage from ULA’s facilities in Decatur, Alabama, to its Delta IV Operations Center at Cape Canaveral Space Force Station. The stage will undergo final processing and checkout before it is transported to NASA’s Kennedy Space Center for launch preparations.

With Artemis, NASA will land the first woman and the first person of color on the lunar surface and establish long-term exploration at the Moon in preparation for human missions to Mars. SLS and NASA’s Orion spacecraft, along with the commercial Human Landing System and the Gateway in orbit around the Moon, are NASA’s backbone for deep space exploration. SLS is the only rocket that can send Orion, astronauts, and supplies to the Moon in a single mission.

Source: NASA.Gov

Monday, August 16, 2021

Axiom Update: The Ax-1 Crew Has Begun Training for Its 2022 Flight to the International Space Station...

Ax-1 commander Michael López-Alegría trains inside the Space Vehicle Mockup Facility at NASA’s Johnson Space Center in Houston, Texas.
Axiom Space, Inc. / Bill Stafford

Axiom Space Private Astronauts Begin Training at NASA's Johnson Space Center (News Release)

Michael López-Alegría is pictured training at the Space Vehicle Mockup Facility at NASA’s Johnson Space Center in Houston for Axiom Mission 1 (Ax-1) to the International Space Station. Private astronauts of Axiom Space began learning about space station systems and procedures in preparation for their planned stay aboard the orbiting laboratory. The mission is scheduled for no earlier than January 2022.

For the Ax-1 mission, Axiom is proposing López-Alegría, Larry Connor, Mark Pathy, and Eytan Stibbe as prime crew members. These private astronauts will receive a standard official review by NASA and its international partners and undergo NASA medical qualification testing before being approved for flight. López-Alegría will serve as Axiom's mission commander with Peggy Whitson as his backup.

This image is available on NASA’s Image and Video Library: https://images.nasa.gov/

Source: NASA.Gov

Sunday, August 15, 2021

Photos of the Day: T-Minus ONE MONTH Till the Historic Launch of the Inspiration4 Mission!

Inspiration4 astronauts Jared Isaacman, Hayley Arceneaux, Sian Proctor and Christopher Sembroski pose underneath SpaceX's Falcon 9 rocket that will launch them on their historic three-day mission one month from now.
SpaceX

Just thought I'd share these photos of the four all-civilian astronauts who are just one month away from launching on the historic Inspiration4 mission from NASA's Kennedy Space Center (KSC) in Florida.

Spacecraft commander Jared Isaacman (callsign: Hanks), pilot Sian Proctor (callsign: Leo), mission specialist Christopher Sembroski (callsign: Rook) and chief medical officer Hayley Arceneaux (callsign: Nova) will fly aboard SpaceX's Crew Dragon Resilience capsule as it departs aboard a Falcon 9 rocket from KSC's Launch Complex 39A on September 15, weather and all technical factors permitting.

Inspiration4 will only last three days, but the contribution by Commander Isaacman and his fellow crewmembers to human spaceflight will endure for a very long time. So excited for this mission!

Inspiration4 astronauts Christopher Sembroski, Sian Proctor, Jared Isaacman and Hayley Arceneaux pose near a MiG-29 Fulcrum (that was piloted by Isaacman) after their formation flight in Montana...on August 8, 2021.
Inspiration4

Astronauts Christopher Sembroski, Sian Proctor, Jared Isaacman and Hayley Arceneaux pose with the Inspiration4 flag after their formation flight in Montana...on August 8, 2021.
Inspiration4 / Sian Proctor

Inspiration4 astronauts Jared Isaacman, Sian Proctor, Hayley Arceneaux and Christopher Sembroski pose inside the Crew Access Arm at Kennedy Space Center's Launch Complex 39A...the pad where they will begin their historic three-day mission aboard SpaceX's Crew Dragon Resilience capsule one month from now.
John Kraus Photography

Saturday, August 14, 2021

SLS Update: The Artemis 1 Moon Rocket Will Begin a Series of Ground Tests at KSC Soon...

The structural test article for the Orion stage adapter is attached to NASA's Space Launch System rocket...inside Kennedy Space Center's Vehicle Assembly Building on August 9, 2021.
NASA

Earlier this week, the structural test articles (STA) for the Space Launch System's (SLS) final two components for Artemis 1 were stacked on the rocket inside the Vehicle Assembly Building (VAB) at NASA's Kennedy Space Center (KSC) in Florida.

As shown in these photos, the STA for the Orion stage adapter (OSA)—in which the real flight hardware itself is currently in storage at KSC's Multi-Payload Processing Facility a few miles away—was attached to SLS on August 9. Presumably, the Mass Simulator for Orion (MSO) was placed atop the Artemis 1 rocket soon afterwards.

The OSA STA and MSO will remain on the Space Launch System as two major demonstrations—the Umbilical Release and Retract Test (or URRT...which will ensure that the mobile launcher's umbilical arms detach and swing away from SLS in a quick but safe manner at liftoff) and Integrated Modal Test (or IMT...which will be similar to the modal test that examined the SLS Core Stage's structural dynamics during its Green Run campaign at NASA's Stennis Space Center in Mississippi last year)—are conducted on the rocket inside the VAB.

Once the URRT and IMT are completed, the mobile launcher's umbilical arms will be re-attached to SLS and the actual Orion spacecraft and stage adapter (with various CubeSats installed inside it) will be brought into the VAB and mated to the Artemis 1 rocket. This milestone will take place later next month.

The SLS will then be rolled out to KSC's Launch Complex 39B for a multi-week Wet Dress Rehearsal...prior to being sent back to the VAB for final ordnance installation and other launch preps.

Liftoff of Artemis 1 is still scheduled for no earlier than November 22.

The structural test article for the Orion stage adapter is attached to NASA's Space Launch System rocket...inside Kennedy Space Center's Vehicle Assembly Building on August 9, 2021.
NASA

Friday, August 13, 2021

CST-100 Update: The Launch of Orbital Flight Test-2 Has Been Indefinitely Delayed...

The CST-100 Starliner, still attached to its Atlas V rocket, sits inside the Vertical Integration Facility at Cape Canaveral Space Force Station's Space Launch Complex 41.
Boeing

Starliner Returning to Factory to Resolve Valve Issue (News Release)

Today, Boeing informed NASA that the company will destack its CST-100 Starliner from the Atlas V rocket and return the spacecraft to the Commercial Crew and Cargo Processing Facility (C3PF) for deeper-level troubleshooting of four propulsion system valves that remain closed after last Tuesday’s scrubbed launch.

Starliner has sat atop the Atlas V rocket in ULA’s Vertical Integration Facility since August 4, where Boeing teams have worked to restore functionality to the affected valves.

The relocation of the spacecraft to the C3PF will require Boeing, NASA and United Launch Alliance to agree on a new launch date once the valve issue is resolved.

“Mission success in human spaceflight depends on thousands of factors coming together at the right time,” said John Vollmer, vice president and program manager, Boeing’s Commercial Crew Program. “We’ll continue to work the issue from the Starliner factory and have decided to stand down for this launch window to make way for other national priority missions.”

Source: Boeing

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The CST-100 Starliner undergoes final assembly for Orbital Flight Test-2 inside the Commercial Crew and Cargo Processing Facility...at NASA's Kennedy Space Center in late 2020.
Boeing

Thursday, August 12, 2021

ISS Update: The S.S. Ellison Onizuka Is Now Berthed to the Orbital Outpost...

An infographic showing where Crew Dragon, Soyuz, Progress and the Cygnus freighter are currently docked to the International Space Station.
NASA

Earlier today, Northrop Grumman's Cygnus cargo freighter—christened the S.S. Ellison Onizuka in honor of the fallen space shuttle Challenger astronaut—was successfully berthed to the International Space Station (ISS). The freighter was bolted in place to the Earth-facing port of the Unity module at 9:42 AM, Eastern Daylight Time (6:42 AM, Pacific Daylight Time).

The S.S. Onizuka, which launched two days ago and brought 8,200 pounds of science experiments and supplies to the ISS, will remain at the orbital outpost till November. Trash will be loaded onto the Cygnus spacecraft before it is unberthed from the space station and intentionally conducts a destructive re-entry into Earth's atmosphere.

Wednesday, August 11, 2021

Photo of the Day: The Orion Stage Adapter Is One Step Closer to Being Mated to the SLS Rocket...

A snapshot of the Orion Stage Adapter--with 9 CubeSat dispensers already attached to the inside of it--that will be mated to the Space Launch System rocket for NASA's Artemis 1 mission.
NASA / Cory Huston

Orion Stage Adapter Readied for Ride on Artemis I (News Release)

Technicians continue to prepare small satellites, called CubeSats, at NASA’s Kennedy Space Center in Florida for their upcoming launch on the Artemis I mission. Technicians from the agency’s Exploration Ground Systems and contractor Jacobs worked with developers of the shoebox-sized secondary payloads as they underwent final processing and were secured inside the Orion Stage Adapter.

The ring-shaped stage adapter will be connected to the Space Launch System (SLS) Interim Cryogenic Propulsion Stage, and the Orion spacecraft will be secured on top. All CubeSats will be deployed after SLS completes its primary mission, launching the Orion spacecraft on a trajectory toward the Moon. Although small in size, the CubeSats will conduct a variety of science experiments and technology demonstrations including some that will expand our knowledge of the lunar surface during the Artemis I mission.

Artemis I will be the first integrated flight test of NASA’s deep space exploration system: the Orion spacecraft, SLS rocket, and the ground systems at Kennedy. The first in a series of increasingly complex missions, Artemis I will provide a foundation for human deep space exploration, and demonstrate commitment and capability to extend human existence to the Moon and beyond.

Source: NASA.Gov

Tuesday, August 10, 2021

ISS Update: The S.S. Ellison Onizuka Is Headed to the Orbital Outpost...

A Cygnus spacecraft--named the S.S. Ellison Onizuka after the fallen space shuttle Challenger astronaut--launches aboard an Antares 230+ rocket from NASA's Wallops Flight Facility in Virginia...on August 10, 2021.
NASA / Jamie Adkins

NASA Science, Cargo Launches on Northrop Grumman Resupply Mission (Press Release)

A Northrop Grumman Cygnus resupply spacecraft is on its way to the International Space Station with more than 8,200 pounds of science investigations and cargo after launching at 6:01 p.m. EDT Tuesday from NASA’s Wallops Flight Facility in Virginia. At 8:46 p.m., the spacecraft’s solar arrays successfully deployed to collect sunlight to power Cygnus on its journey to the station.

Cygnus is scheduled to arrive at the space station around 6:10 a.m. Thursday, Aug. 12. NASA Television, the NASA app, and the agency’s website will provide live coverage of the spacecraft’s approach and arrival beginning at 4:45 a.m.

NASA astronaut Megan McArthur will use the space station’s robotic Canadarm2 to capture Cygnus upon its arrival, while ESA (European Space Agency) astronaut Thomas Pesquet monitors telemetry during rendezvous, capture, and installation on the Earth-facing port of the Unity module.

This is Northrop Grumman’s 16th cargo flight to the space station and is the fifth under its Commercial Resupply Services 2 contract with NASA. Cygnus launched on an Antares 230+ rocket from the Virginia Mid-Atlantic Regional Spaceport’s Pad 0A at Wallops.

The resupply flight will support dozens of new and existing investigations. Included in the scientific investigations Cygnus is delivering to the space station are:

From dust to dwelling

Using resources available on the Moon and Mars to build structures and habitats could reduce how much material future explorers need to bring from Earth, significantly reducing launch mass and cost. The Redwire Regolith Print (RRP) study demonstrates 3D printing on the space station using a material simulating regolith, or loose rock and soil, found on the surfaces of planetary bodies such as the Moon. Results could help determine the feasibility of using regolith as the raw material and 3D printing as a technique for on-demand construction of habitats and other structures on future space exploration missions.

Maintaining muscles

As people age and become more sedentary on Earth, they gradually lose muscle mass, a condition called sarcopenia. Identifying drugs to treat this condition is difficult because it develops over decades. Cardinal Muscle tests whether microgravity can be used as a research tool for understanding and preventing sarcopenia. The study, funded by the National Science Foundation in collaboration with the ISS U.S. National Laboratory, seeks to determine whether an engineered tissue platform in microgravity forms the characteristic muscle tubes found in muscle tissue. Such a platform could provide a way to rapidly assess potential drugs prior to clinical trials.

Taking the heat out of space travel

Longer space missions will need to generate more power, producing more heat that must be dissipated. Transitioning from current single-phase heat transfer systems to two-phase thermal management systems reduces size and weight of the system and provides more efficient heat removal. Because greater heat energy is exchanged through vaporization and condensation, a two-phase system can remove more heat for the same amount of weight than current single-phase systems. The Flow Boiling and Condensation Experiment (FBCE) aims to develop a facility for collecting data about two-phase flow and heat transfer in microgravity. Comparisons of data from microgravity and Earth’s gravity are needed to validate numerical simulation tools for designing thermal management systems.

Cooler re-entries

The Kentucky Re-Entry Probe Experiment (KREPE) demonstrates an affordable thermal protection system (TPS) to protect spacecraft and their contents during re-entry into Earth’s atmosphere. Making these systems efficient remains one of space exploration’s biggest challenges, but the unique environment of atmospheric entry makes it difficult to accurately replicate conditions in ground simulations. TPS designers rely on numerical models that often lack flight validation. This investigation serves as an inexpensive way to compare these models to actual flight data and validate possible designs. Before flying the technology on the space station, researchers conducted a high-altitude balloon test to validate performance of the electronics and communications.

Getting the carbon dioxide out

Four Bed CO2 Scrubber demonstrates a technology to remove carbon dioxide from a spacecraft. Based on the current system and lessons learned from its nearly 20 years of operation, the Four Bed CO2 Scrubber includes mechanical upgrades and an improved, longer-lasting absorbent material that reduces erosion and dust formation. Absorption beds remove water vapor and carbon dioxide from the atmosphere, returning water vapor to the cabin and venting carbon dioxide overboard or diverting it to a system that uses it to produce water. This technology could improve the reliability and performance of carbon dioxide removal systems in future spacecraft, helping to maintain the health of crews and ensure mission success. It has potential applications on Earth in closed environments that require carbon dioxide removal to protect workers and equipment.

Mold in microgravity

An ESA investigation, Blob, allows students aged 10 to 18 to study a naturally-occurring slime mold, Physarum polycephalum, that is capable of basic forms of learning and adaptation. Although it is just one cell and lacks a brain, Blob can move, feed, organize itself, and even transmit knowledge to other slime molds. Students replicate experiments conducted by ESA astronaut Thomas Pesquet to see how the Blob’s behavior is affected by microgravity. Using time-lapse video from space, students can compare the speed, shape, and growth of the slime molds in space and on the ground. The French space agency Centre National d'Etudes Spatiales and the French National Center for Scientific Research coordinate Blob.

These are just a few of the hundreds of investigations currently being conducted aboard the orbiting laboratory in the areas of biology and biotechnology, physical sciences, and Earth and space science. Advances in these areas will help keep astronauts healthy during long-duration space travel and demonstrate technologies for future human and robotic exploration missions as part of NASA’s Moon and Mars exploration approach, including lunar missions through NASA’s Artemis program.

Cygnus also will deliver a new mounting bracket that astronauts will attach to the port side of the station’s backbone truss during a spacewalk planned for late August. The mounting bracket will enable the installation of one of the next pair of new solar arrays at a later date.

The Cygnus spacecraft will remain at the space station until November before it disposes of several thousand pounds of trash through its destructive re-entry into Earth’s atmosphere.

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Monday, August 9, 2021

Artemis 1 Update: SLS Has Been Powered Up for the First Time at Kennedy Space Center...

The Space Launch System rocket that will fly on NASA's Artemis 1 mission undergoes processing inside the Vehicle Assembly Building at Kennedy Space Center in Florida.
NASA / Kim Shiflett

NASA Moon Rocket Flight Software Readied for Artemis I Launch (News Release)

As crews at NASA’s Kennedy Space Center in Florida assemble the Moon rocket for the Artemis I mission, teams have installed the flight software that will help steer, fly, track, and guide the Space Launch System (SLS) rocket during launch and ascent to space. Engineers loaded the flight software onto the rocket on Aug. 6 after powering up the core stage that contains the flight computers for the first time since stacking began.

With the software installed, the engineers that developed the flight software at NASA’s Marshall Space Flight Center in Huntsville, Alabama, are supporting final checkouts and completing tests to certify the software for the mission.

“NASA’s Space Launch System is on the path to the pad, and the SLS flight computer application software is complete and ready to perform the mission,” said David Beaman, SLS systems engineering and integration manager. “The mission certification and performance certification tests are the next step for the rocket’s software on the path to launch and flight ahead of Artemis I.”

The software is loaded on three flight computers, along with the avionics systems inside the SLS rocket’s core stage. On the day of launch, the SLS’s twin solid rocket boosters and four RS-25 engines fire together to produce more than 8.8 million pounds of thrust to send NASA’s Orion spacecraft to the Moon. The software and avionics operate with the rocket’s three flight computers to harness the power of the rocket through ascent and communicate with avionics systems inside the engines and the boosters. That same software is monitored in real time by NASA’s Exploration Ground Systems team at the agency’s launch complex at Kennedy and SLS Program engineers at the SLS Engineering Support Center at Marshall.

Once the rocket and Orion are fully stacked and assembled on the mobile launcher, they will undergo several additional tests and checkouts leading up to launch. The software is designed to be tested and certified for each launch window so that ascent performance parameters can be updated right up until launch to enhance mission success.

“It is important to test and certify the SLS flight software for each launch opportunity to account for day of launch weather and other factors,” said Dan Mitchell, lead SLS integrated avionics and software engineer. “Those tests also ensure that all the software elements and systems on the rocket, Orion, and the ground work together seamlessly for prelaunch checks and preparations, liftoff, and ascent.”

NASA conducts integrated end-to-end testing for the software, hardware, avionics, and integrated systems needed to fly Artemis missions. In addition to testing with each hardware element before delivery to Kennedy, testing in the agency’s sophisticated software development laboratories use actual SLS, Orion, and Exploration Ground Systems flight hardware and software, as well as emulators—versions of the software that each team employs to test how their code works with the integrated system—to support both system-level interface testing and integrated mission testing to ensure software and avionics systems work together.

Earlier this year, the flight software and avionics systems completed a series of checkouts and tests as part of the comprehensive, eight-part SLS core stage Green Run test series at NASA’s Stennis Space Center near Bay St. Louis, Mississippi. Key tests and checkouts included powering on the stage, simulating the launch countdown, and operating the flight computers and avionics systems during the eight-minute hot fire test on March 18.

During Green Run, the core stage flight computers, software, and avionics systems performed as expected as test teams monitored and operated the flight software just like they would in a launch environment for the first time. Those data findings were then used to inform the mission certification testing for the Artemis I flight software.

The flight computer application software for Artemis I also completed extensive testing in Marshall’s System Integration Lab. Inside, software engineers create real-time launch simulations to further test the flight software under normal and unplanned mission scenarios.

“The flight software test campaign for the Artemis I mission involves more than 300,000 different mission scenarios to satisfy all flight software requirements,” said Shaun Phillips, SLS flight software project team lead based at Marshall. “Each of these scenarios are focused on evaluating different interfaces and situations the vehicle may face during launch and flight.”

NASA thoroughly tests and evaluates all software and hardware for every phase of the Artemis I mission to ensure that it meets safety requirements and is fully qualified for human spaceflight. With Artemis, NASA will land the first woman and the first person of color on the Moon and establish a long-term presence while preparing for human missions to Mars. SLS and NASA’s Orion spacecraft, along with the commercial Human Landing System and the Gateway in orbit around the Moon, are NASA’s backbone for deep space exploration. SLS is the only rocket that can send Orion, astronauts, and supplies to the Moon in a single mission.

Source: NASA.Gov

Saturday, August 7, 2021

The First Lunar Mission Under the Artemis Program Is Set to Launch Later This Year...

An Electron rocket sits atop its pad at Rocket Lab's Launch Complex 1 in New Zealand.
Rocket Lab

Rocket Lab to Launch NASA-Funded Commercial Moon Mission from New Zealand (Press Release - August 6)

The CAPSTONE mission will be Rocket Lab’s first launch to the Moon

Long Beach, California – Rocket Lab, the leading launch and space systems company, today announced it will launch the CAPSTONE mission to the Moon from Launch Complex 1 in New Zealand from Q4 2021. It will be Rocket Lab’s first launch to the Moon. CAPSTONE (the Cislunar Autonomous Positioning System Technology Operations and Navigation Experiment) aids NASA’s Artemis program, which includes landing the first woman and the first person of color on the Moon and establishing a long-term presence there.

Launching on an Electron launch vehicle and deploying from Rocket Lab’s Photon spacecraft platform, CAPSTONE is a 55-pound satellite created by Advanced Space that will serve as the first spacecraft to test a unique, elliptical lunar orbit. As a precursor for Gateway and other Artemis elements, an international and commercial Moon-orbiting outpost that is part of NASA’s Artemis program, CAPSTONE will help reduce risk for future spacecraft by validating innovative navigation technologies and verifying the dynamics of this halo-shaped orbit.

The mission is the first time Rocket Lab will use its Photon spacecraft platform as a trans-lunar injection stage to place a satellite on a trajectory that will take it beyond Earth orbit to the Moon. After lifting off on Electron to an initial elliptical low-Earth orbit, Photon will separate and use its 3D printed HyperCurie engine to provide in-space propulsion to allow CAPSTONE to break free of Earth’s gravity and set a course for the Moon. After deploying the CAPSTONE satellite, Photon will continue on its own trajectory to conduct a lunar fly-by, while CAPSTONE will use its own propulsion system to enter a cislunar orbit.

Following a three-to-four-month trip to the Moon, the CAPSTONE CubeSat will enter a near rectilinear halo orbit (NRHO), which is a highly elliptical orbit over the Moon’s poles. During its six-month primary mission in orbit around the Moon, CAPSTONE will validate the propulsion requirements for maintaining this type of orbit as predicted by models, reducing logistical uncertainties for future missions. It will also test the accuracy of innovative spacecraft-to-spacecraft navigation solutions as well as demonstrate capabilities for commercial support of future lunar missions. The NRHO provides the advantage of an unobstructed view of Earth in addition to coverage of the lunar South Pole.

Originally slated for lift-off from Rocket Lab’s Launch Complex 2 in Virginia, the CAPSTONE mission will now take place from Launch Complex 1 to support a Q4 launch window.

“Flexible isn’t a word usually used to describe lunar missions but operating two launch complexes gives us the freedom to select a site that best meets mission requirements and schedule,” said Rocket Lab Chief Executive Officer, Mr. Peter Beck. “Our team is immensely proud to be launching one of the first pathfinding missions to support NASA’s goal of delivering a sustainable and robust presence on the Moon. We’ve teamed up with the NASA Launch Services Program on previous Electron missions to low-Earth orbit, so it’s exciting to be working with them again to go just a bit further than usual...some 380,000 km further.”

Advanced Space of Colorado, a leading commercial space solutions company, owns the satellite and operates the mission. CAPSTONE development is supported by NASA’s Space Technology Mission Directorate via the Small Spacecraft Technology Program at NASA’s Ames Research Center in California’s Silicon Valley. Advanced Exploration Systems within NASA’s Human Exploration and Operations Mission Directorate supports the launch and mission operations. NASA’s Launch Services Program at Kennedy Space Center in Florida is responsible for launch management.

Source: Rocket Lab

****

CAPSTONE’s propulsion system undergoes environmental testing at Stellar Exploration Inc. in San Luis Obispo, California.
Stellar Exploration Inc.

An artist's concept of Rocket Lab's Photon spacecraft transporting CAPSTONE to the Moon.
Rocket Lab

An artist's concept of NASA's Gateway orbiting the Moon.
NASA

Friday, August 6, 2021

STARSHIP SUPER HEAVY Has Officially Become a Reality!

Starship Super Heavy stands tall on its Orbital Launch Table at Starbase, Texas...on August 6, 2021.
Elon Musk

A few hours ago, Starship Serial No. 20 (SN20) was briefly mated to Super Heavy Booster 4 (B4) at Starbase, Texas...giving the world a quick glimpse of the giant Mars rocket that SpaceX founder Elon Musk first unveiled in late 2016.

For about an hour, SpaceX employees and public spectators who dropped by Starbase had the opportunity to photograph Starship Super Heavy as it stood tall on its Orbital Launch Table. SN20 was then destacked from B4 after that.

According to Musk, SN20 will be rolled back to the Starbase production site to have the final heat shield tiles installed (98% of the tiles have now been attached to the vehicle), while B4 itself will have thermal protection placed around its 29 methane-fueled Raptor engines. Work will also be done on completing the installation of cryoshells over ground support equipment at the Orbital Launch Site.

An umbilical arm will also be attached to the Orbital Launch Tower that will provide methane and liquid oxygen fuel to Starship at the pad.

All of the remaining work mentioned above will take about two weeks to accomplish before SN20 and B4 become one once more. At the speed that this rocket is moving towards launch, there's no reason why we can't see its first orbital test flight sometime next season.

Crossing fingers that the Federal Aviation Administration is aware of the history that's being made in South Texas this week, and will give SpaceX the greenlight to launch as soon as it's safe and prudent to do so. Mars est.

Starship Super Heavy as seen from an upper floor on the Orbital Launch Tower at Starbase, Texas...on August 6, 2021.
Elon Musk

Starship Super Heavy stands tall on its Orbital Launch Table at Starbase, Texas...on August 6, 2021.
SpaceX

Thursday, August 5, 2021

SpaceShipTwo Update: Virgin Galactic Lays Out Plans for Its Future Commercial Spaceflight Operations...

VSS Unity soars 53.5 miles (86 kilometers) above the Earth during the Unity 22 flight...on July 11, 2021.
Virgin Galactic

Virgin Galactic Announces Second Quarter 2021 Financial Result (Press Release)

LAS CRUCES, N.M.--(BUSINESS WIRE)-- Virgin Galactic Holdings, Inc. (NYSE: SPCE) (“Virgin Galactic” or the "Company”), a vertically integrated aerospace and space travel company, today announced its financial results for the second quarter ended June 30, 2021.

“In the second quarter, we made meaningful progress towards commencing commercial service in 2022. We successfully completed two spaceflights from New Mexico — the latest carrying a full crew of mission specialists in the cabin and garnering an extraordinary global media and consumer response. In addition, we received FAA approval to expand our existing launch license, marking the first time the FAA has licensed a Spaceline to fly customers to space,” said Michael Colglazier, Chief Executive Officer of Virgin Galactic. “Leveraging the surge in consumer interest following the Unity 22 flight, we are excited to announce the reopening of sales effective today, beginning with our Spacefarer community. As we endeavor to bring the wonder of space to a broad global population, we are delighted to open the door to an entirely new industry and consumer experience.”

Business Highlights:

-- On July 11, 2021, successfully completed first fully-crewed spaceflight. This spaceflight marked VSS Unity’s 22nd flight and its fourth spaceflight. The flight fulfilled test objectives including evaluating the cabin and customer experience.

-- On May 22, 2021, successfully completed first spaceflight from Spaceport America, New Mexico. This spaceflight marked VSS Unity’s 21st flight and its third spaceflight. The flight fulfilled test objectives including confirming the technical readiness of the spaceship’s upgraded flight controls and horizontal stabilizers. The flight also carried revenue-generating scientific research experiments.

-- In June, the Federal Aviation Administration (“FAA”) updated the Company's existing commercial space transportation operator license to allow the spaceline to fly customers to space. The adjustment marked the first time the FAA has licensed a spaceline to fly customers.

-- In June, we announced a new contract for a human-tended research spaceflight. The company will fly Kellie Gerardi, a researcher for the International Institute for Astronautical Sciences (IIAS), on a dedicated research flight, during which Kellie will conduct experiments and test new healthcare technologies while she is in space.

-- Total retention of existing Future Astronaut reservations remained steady at approximately 600, as of June 30, 2021.

-- Announced plans to reopen sales effective today. For the private astronaut market, the Company will have three consumer offerings: i) a single seat; ii) a multi-seat couples / friends / family package; and iii) full-flight buy out. Pricing for these offers will begin at $450,000 per seat. Sales will initially open to the Company's significant list of early hand-raisers, prioritizing the Spacefarer Community, who, as promised, will be given first opportunity to reserve their place in space. A follow-on priority list will be opened to customers interested in reserving future spaceflights.

-- Announced that the next rocket-powered spaceflight, Unity 23, is targeted to occur in late-September from Spaceport America in New Mexico. This flight will be a revenue-generating flight with the Italian Air Force.

Second Quarter 2021 Financial Highlights:

-- Cash position remains strong, with cash and cash equivalents of $552 million as of June 30, 2021.

-- In July, the Company completed an “at-the-market” equity offering program (the “ATM Offering”). In connection with the ATM Offering, the Company filed a prospectus supplement with the U.S. Securities and Exchange Commission to offer and sell up to $500 million of shares of the Company’s common stock from time to time. The Company ultimately generated $500 million in gross proceeds through the sale of approximately 13.7 million shares of common stock. The Company intends to use the net proceeds generated from the ATM Offering for general corporate purposes, with a priority on expansion of its spaceship fleet.

-- GAAP selling, general, and administrative expenses of $39 million, compared to $26 million in the second quarter of 2020. Non-GAAP selling, general and administrative expenses of $26 million in the second quarter of 2021, compared to $21 million in the second quarter of 2020.

-- GAAP research and development expenses of $36 million, compared to $37 million in the second quarter of 2020. Non-GAAP research and development expenses of $31 million in the second quarter of 2020, compared to $34 million in the second quarter of 2020.

-- Adjusted EBITDA totaled $(56) million, compared to $(54) million in the second quarter of 2020.

-- Net loss of $94 million, compared to a $72 million net loss in the second quarter of 2020.

-- Cash paid for capital expenditures totaled $1 million, compared to $6 million in the second quarter of 2020.

COVID-19 Impact

The Company is continuing to experience ongoing delays to its business and operations due to COVID-19. The Company continues to operate under strict protocols and follows rigorous health and safety procedures, in line with CDC, state and local guidelines, to ensure employee safety.

Source: Virgin Galactic

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Virgin Galactic founder Sir Richard Branson and his three Unity 22 crewmembers float around inside VSS Unity's cabin during their 53.5-mile (86-kilometer) journey into space...on July 11, 2021.
Virgin Galactic

Wednesday, August 4, 2021

Photos of the Day #3: Starship SN20 Now Has All 6 of Her Engines, and Super Heavy B4 Is at the Launch Pad...

Inside the High Bay at Starbase, Texas, the three Raptor Vacuum engines and a trio of sea-level Raptors are installed on Starship SN20...on August 3, 2021.
Elon Musk

In the latest update on Elon Musk's quest to launch the Starship Super Heavy on its first orbital test flight as soon as possible, Starship Serial No. 20 (SN20) now has all six of her engines installed, and Super Heavy Booster 4 (B4) was placed near Starbase's Orbital Launch Tower about two hours ago.

Unlike the previous Starship prototypes that took flight in Texas since last December, SN20 will not only be equipped with three sea-level Raptor engines, but it will also fly with three larger Raptor Vacuum (RVac) thrusters which will be needed for Starship to maneuver in low-Earth orbit and beyond.

All three RVac engines were installed yesterday.

And at the Orbital Launch Site a few miles from the High Bay where SN20's engines were attached, B4 has now been placed atop its Orbital Launch Table...which itself was mated to its mount near the Orbital Launch Tower less than a week ago.

Also accomplished inside the High Bay was SN20's nosecone installation, of which there are no official photos yet.

Once SN20 is completed (the remaining heat tiles need to be attached to the bottom of its fuselage), it will be rolled over to the Orbital Launch Site and mated to B4 for a photo op that will no doubt set the spaceflight community abuzz.

After the photo op, SN20 will be removed from B4 and placed on a suborbital launch mount for its own engine test firing. Both SN20 and B4 will conduct cryogenic proof tests and static fires before they're re-combined in preparation for their highly-anticipated orbital flight...which does not have a launch date yet.

At Starbase's Orbital Launch Site, Super Heavy Booster 4 (B4) is about to be installed on its Orbital Launch Table near the Orbital Launch Tower...on August 4, 2021.
Elon Musk

At Starbase's Orbital Launch Site, Super Heavy B4 is about to be installed on its Orbital Launch Table near the Orbital Launch Tower...on August 4, 2021.
Elon Musk

A glimpse of the 29 Raptor engines that grace the bottom of Super Heavy B4...as seen on August 4, 2021.
Elon Musk

Tuesday, August 3, 2021

Photos of the Day #2: Super Heavy Booster 4 Is Rolled Out to the Orbital Launch Site at Starbase, Texas...

Super Heavy Booster 4 (B4) as seen from the top of its High Bay at SpaceX's launch facility in Starbase, Texas...on August 3, 2021.
Elon Musk

Earlier today, SpaceX's Super Heavy Booster 4 (B4) was slowly rolled out of the High Bay and transported to the Orbital Launch Site in Starbase, Texas.

This movement comes just a few days after all 29 methane-fueled Raptor engines were installed on B4. With the Super Heavy Booster close to being placed on its launch pedestal near the newly-assembled Orbital Launch Tower, the next milestones to be achieved are static fires...in which B4 and Starship Serial No. 20 (SN20) will conduct separate tests on different launch mounts before the two vehicles are finally mated together (for possibly more static fires).

Starship SN20 itself was rolled out of Starbase's Mid Bay and transported to the High Bay to complete construction a few hours ago.

Even once SN20 is finally mated to B4 to begin launch preps before their inevitable orbital test flight, it remains to be seen when the Federal Aviation Administration will complete its Environmental Impact Study and clear the Starship Super Heavy rocket for its highly-anticipated launch. Stay tuned.

B4 is about to be transported to Starbase's Orbital Launch Site while Starship SN20 is rolled out of the nearby Mid Bay...on August 3, 2021.
Elon Musk



Monday, August 2, 2021

Photos of the Day: SpaceX's Super Heavy Booster Continues to Get Prepped for Starship's First Orbital Test Flight...

Elon Musk and his infant son visit the High Bay where Super Heavy Booster 4 is getting its 29 methane-fueled Raptor engines installed...at the SpaceX launch site in Starbase, Texas.
Elon Musk

Over the past weekend, SpaceX founder Elon Musk tweeted these photos showing the rapid progress being made at Starbase, Texas for Starship's first orbital test flight.

In these two images, engineers are shown installing the 29 methane-fueled Raptor engines that will power Super Heavy Booster 4...which will lift Starship out of Earth's atmosphere.

It remains to be seen when SpaceX's giant Mars rocket will see its inaugural flight to low-Earth orbit...as the Federal Aviation Administration (FAA) continues to conduct an environmental impact study pertaining to Starship heading into space for the first time. It may take months for the FAA to grant its approval for launch.

Once the Starship Super Heavy combo does rocket away from its Texas launch site and heads toward the Kármán line and beyond, this will be a watershed moment in human spaceflight.

Not only will its role as the Human Landing System on Artemis 3 move that much closer to reality, but humanity's goal of journeying to Mars within our lifetimes will also be in reach thanks to Starship. Mars est.

At SpaceX's launch site in Starbase, Texas, all 29 Raptor engines are now installed on Super Heavy Booster 4.
Elon Musk