Archive for the ‘Space News’ Category
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July 1st, 2016
Curiosity Navcam Left B image taken on Sol 1387, July 1, 2016.
Credit: NASA/JPL-Caltech
The very independent Curiosity Mars rover is to be busy wheeling into the long 4th of July weekend.
A number of sols are being planned by Earth operators, explains Ryan Anderson, a planetary scientist at the USGS Astrogeology Science Center in Flagstaff, Arizona.
At this writing, Curiosity is just wrapping up Sol 1387 activities.
Rock, soil targets
Anderson says that the plan for this sol was having the Chemistry & Camera (ChemCam) to find analyze two targets: a rock named “Noordoewer” and a soil named “Savates.”
Curiosity image taken by Rear Hazcam Left B on Sol 1387, July 1, 2016.
Credit: NASA/JPL-Caltech
Mastcam was also set to document those targets and take a mosaic of the “Murray Buttes”. After that, the rover was to perform a short drive, followed by post drive imaging, Anderson notes.
Curiosity Mars Hand Lens Imager (MAHLI) image taken on June 30, 2016, Sol 1386.
Credit: NASA/JPL-Caltech/MSSS
Lastly, a request is in, Anderson adds, for the rover’s Navcam to take imagery of Mt. Sharp along with the post drive imaging to help target more long distance ChemCam Remote Microscopic Imager (RMI) images.
“On Sol 1388, we have an easy day: ChemCam has a calibration observation and Navcam has a couple of atmospheric monitoring observations,” Anderson explains.
This map shows the route driven by NASA’s Mars rover Curiosity through the 1387 Martian day, or sol, of the rover’s mission on Mars (July, 01, 2016).
From Sol 1386 to Sol 1387, Curiosity had driven a straight line distance of about 41.43 feet (12.63 meters).
Since touching down in Bradbury Landing in August 2012, Curiosity has driven 8.22 miles (13.23 kilometers).
The base image from the map is from the High Resolution Imaging Science Experiment Camera (HiRISE) in NASA’s Mars Reconnaissance Orbiter.
Credit: NASA/JPL-Caltech/Univ. of Arizona
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Curiosity Mastcam Left image taken on Sol 1384, June 28, 2016.
Credit: NASA/JPL-Caltech/MSSS
NASA’s Curiosity Mars rover is busy at work during Sol 1386.
Ryan Anderson, a planetary scientist at the USGS Astrogeology Science Center in Flagstaff, Arizona reports the robot has been wheeled over 216 feet (66 meters) last Sol.
The Mars machinery is continuing on its path south between the “Baynes Mountains” and “Helgas Dune.”
The plan for Sol 1386 is to start off with Alpha Particle X-Ray Spectrometer (APXS) and Hand Lens Imager (MAHLI) observations of the target “Trekkopje”, followed by a short science block.
Curiosity Navcam Left B image taken on Sol 1385, June 29, 2016.
Credit: NASA/JPL-Caltech
Curiosity’s Mastcam is slated to start off the block with some atmospheric measurements, then Chemistry & Camera (ChemCam) “is to join in the fun and analyze Trekkopje too,” Anderson adds.
Curiosity Navcam Left B image taken on Sol 1385, June 29, 2016.
Credit: NASA/JPL-Caltech
Also on the schedule is for the rover to churn out a couple of small mosaics studying the rim of a nearby crater.
“Instead of driving, we will use MAHLI to do a check-up on our wheels in today’s plan,” Anderson notes.
Credit: ULA
A major U.S. launch provider has outlined a plan to enable a cislunar space economy based on their need for propellant and refueling in Earth orbit.
Dubbed the “Cislunar 1000 Vision,” the initiative foresees a self-sustaining economy that supports a 1,000 people living and working in space roughly 30 years from now.
A central element of the plan involves use of a souped-up Centaur rocket stage called ACES, standing for Advanced Cryogenic Evolved Stage. This liquid oxygen/liquid hydrogen upper stage is designed to be reusable and can be refueled, perhaps by propellant made on Earth’s moon or extracted from asteroids.
Credit: ULA
The concept stems from an analysis and on-going technical work by United Launch Alliance (ULA), a 50-50 joint venture owned by Lockheed Martin and The Boeing Company to provide Atlas and Delta launch services.
A roadmap to attain the Cislunar 1000 Vision was recently detailed at the 7th joint meeting of the Space Resources Roundtable and the Planetary & Terrestrial Mining Sciences Symposium, held June 7-9, 2016 at the Colorado School of Mines in Golden, Colorado.
Go to my new Space.com story at:
Inside ULA’s Plan to Have 1,000 People Working in Space by 2045
By Leonard David, Space.com’s Space Insider Columnist
June 29, 2016 02:55pm ET
http://www.space.com/33297-satellite-refueling-business-proposal-ula.html
NASA’s Mars 2020 rover is to seek signs of past life on Mars, collect and store a set of soil and rock samples that could be returned to Earth in the future. Shown here is an artistic representation of the robot’s SuperCam instrument during operation.
Credit: NASA
Flinging spacecraft to Mars is a multi-nation affair – driven to a large degree by the on-going quest to probe the Red Planet for signs of life, either long-gone or still in attendance.
Over the decades, billions of dollars has been spent to pick away at the question: Is there life on Mars? In 2016, that query is arguably more alive than whatever life story the planet is prepared to cough up.
Now en route, for instance, is the European Space Agency’s ExoMars 2016. It arrives at Mars this October, a mission consisting of a methane-sniffing Trace Gas Orbiter (TGO) plus an entry, descent and landing demonstrator module, known as Schiaparelli. TGO promises to churn out new data that can help unravel the biological standing of that faraway world.
Artist’s impression depicts Europe’s ExoMars 2016 Trace Gas Orbiter and separation of the entry, descent and landing demonstrator module, named Schiaparelli.
Credit: ESA/ATG medialab
Europe’s mission this year is a newbie in Mars research. But it’s a precursor of things to come as a robotic existence proof concerning Mars as an extraterrestrial address for life.
Take a look at my new story on Space.com at:
Target Mars: Red Planet in World’s Crosshairs
By Leonard David, Space.com’s Space Insider Columnist
June 28, 2016 12:04pm ET
http://www.space.com/33290-mars-missions-nasa-europe-spacex.html
Curiosity Navcam Left B image taken on Sol 1383, June 27, 2016.
Credit: NASA/JPL-Caltech
NASA’s Curiosity Mars rover is now in Sol 1383 operations. Since landing in August 2012, the robot has snagged a total of 333,808 Images.
Last Sol, Curiosity was slated to take a Mastcam video of Phobos – a moon of Mars – crossing in front of the Sun, reports Ryan Anderson a planetary scientist at the USGS Astrogeology Science Center in Flagstaff, Arizona.
Also on tap was a multispectral observation of the brushed target “Koes”. The rover’s Chemistry & Camera (ChemCam) was scheduled to analyze the targets “Koes,” “Kongola,” and “Rundu” and Mastcam was slated to document those observations. After that the robot was to drop off some of the “Oudam” sample to the Sample Analysis at Mars (SAM) Instrument Suite for analysis.
Curiosity Navcam Right B image taken on Sol 1383, June 27, 2016.
Credit: NASA/JPL-Caltech
Studying changing textures
“On Sol 1383 the rover will drive and then collect the usual post-drive images, including an 8×1 mosaic along the side of the rover to study changing textures as we drive,” Anderson said. “We’ll also take some extra Navcam images of a crater in the distance.”
The plan calls for an early morning science block for Sol 1384 to collect some atmospheric observations with Navcam and Mastcam.
Image taken by Curiosity’s ChemCam: Remote Micro-Imager on Sol 1383, June 27, 2016.
Credit: NASA/JPL-Caltech/LANL
Good viewing
Sol 1384 activities also include the robot collecting some atmospheric observations with Navcam and Mastcam.
On the schedule is a drive for about 230 feet (70 meters) and then collect standard post-drive images.
“Since the drive is expected to put us in a location with a good view of the surrounding geology, we will also do a 360 degree Mastcam mosaic at the end of the sol,” Anderson adds.
New map
Credit: NASA/JPL-Caltech/Univ. of Arizona
Meanwhile, a new map has been issued showing the Curiosity rover’s location for Sol 1383.
The map shows the route driven by the Mars machinery through the 1383 Martian day, or sol, of the rover’s mission on Mars (June, 27, 2016).
Numbering of the dots along the line in the map (click for larger image) indicate the sol number of each drive. North is up.
From Sol 1378 to Sol 1383, Curiosity had driven a straight line distance of about 100.29 feet (30.57 meters).
Since touching down in Bradbury Landing in August 2012, Curiosity has driven 8.13 miles (13.09 kilometers).
The base image from the map is from the High Resolution Imaging Science Experiment Camera (HiRISE) aboard NASA’s Mars Reconnaissance Orbiter.
Long March 7 departs Wenchang coastal spaceport.
Credit: New China
Update: Videos
To view the Chinese reentry module landing via a You Tube/CCTV video, go to:
https://www.youtube.com/watch?v=Sw4_H33K3vg
Also, go to:
https://www.youtube.com/watch?v=JFybXN7aRHM
New booster
China’s maiden voyage of its Long March 7 booster yesterday is a prelude of things to come this year – focused on expanding and upgrading its human spaceflight program.
Rocketing from the country’s new Kennedy Space Center-like Wenchang coastal spaceport, Long March 7 carried mini-satellites, as well as a sub-scale test capsule for future piloted space missions in low Earth orbit and deep space.
China’s prototype reentry module has parachuted to a landing in Badain Jaran Desert in north China.
Credit: New China
Reports from Chinese news agencies say the 2.6 metric ton (2,600 kilograms) reentry module has parachuted to a landing in Badain Jaran Desert in north China.
Recovery operations for test capsule.
Credit: New China
Space lab next
Long March 7 is the booster assigned the duty of launching cargo resupply ships – dubbed Tianzhou – to China’s multi-modular space station to be orbiting in the early 2020s.
Later this year, China is to loft the Tiangong-2 space lab. Following that launch, a two-person Shenzhou-11 craft will link up with the space lab. Early next year, a Long March 7 will loft a Tianzhou supply ship to the Tiangong-2 space lab.
Pre-launch photo shows team members with subscale reentry capsule.
Credit: CAST
Also on tap this year is the maiden blastoff of China’s Long March 5. This booster is scripted to hurl into Earth orbit space station modules, as well as support robotic lunar sample return from the Moon, and hurl a rover to Mars in 2020.
Credit: CCTV
Credit: CCTV
Credit: CCTV
Tiangong-2 space lab being readied for flight.
Credit: CAST
Credit: CNS via GBTimes
UPDATE: Chinese media is reporting the successful launch of the Long-March-7. CCTV (China television) is broadcasting the liftoff of the vehicle, also showing staging of the booster as it roared toward space. Still to come, full technical details on the outcome of this premier mission.
China’s new generation booster is ready for launch between June 25 and 29 from Wenchang – a new launch location in south China’s Hainan Province.
While weather at the launch facility may play a factor, the Long March-7 rocket is expected to blastoff around 20:00 Beijing time (12:00 UTC) on Saturday, according to sources.
Among duties, the Long March-7 is designed to transport cargo for China’s planned space station in the 2020’s. The Long March-7 is a medium-sized rocket that can carry up to 13.5 tons to low Earth orbit.
This maiden voyage of the rocket also carries a subscale version of a new Chinese re-entry capsule for human spaceflight.
Long March-7, a prelude to bigger boosters set to come.
Credit: New China
Mega-moon booster
Meanwhile, according to China’s state-run Xinhua news service, China is planning to start using a huge carrier rocket powerful enough to support piloted lunar missions before 2031.
According to a statement issued on Friday by the China Academy of Launch Vehicle Technologies (CALT), developer of the country’s Long March rocket series, the country’s Moon rocket would measure over a hundred meters in length and nearly 10 meters in diameter under the current design.
It would have a maximum payload capacity more than five times as high as the current Long March series rockets, the CALT said.
At present, the Chinese rocket capable of lifting the most weight is the Long March-5, which is scheduled to debut in the latter half of this year, in the September-October time frame.
For a fascinating look at the Long March-7 launch preparations, go to these two You Tube videos:
President Barack Obama delivers a speech at the Operations and Checkout Building at NASA Kennedy Space Center in Cape Canaveral, Fla. on Thursday, April 15, 2010. Obama visited Kennedy Space Center to deliver remarks on a new course the Administration is charting for NASA and the future of U.S. leadership in human space flight.
Credit: NASA/Bill Ingalls
Earlier this week, the White House Office of the Press Secretary released “100 Examples of President Obama’s Leadership in Science, Technology, and Innovation.”
Private sector boosterism is on display as SpaceX CEO, Elon Musk discusses space matters with President Barack Obama at the Kennedy Space Center in Cape Canaveral, Florida.
Courtesy: White House
This Impact Report is admittedly a self examination of Obama’s interest and investment in science and technology, a review that includes a section (#84-87) on “Reinvigorating America’s Space Program,” underscoring efforts and elaborating on such areas as:
- Fostering a burgeoning private space sector.
- Driving down the cost of space exploration, while increasing capabilities for NASA’s journey to Mars.
- Extending the life of the International Space Station (ISS).
- Expanding the capabilities of robotic space missions.
As noted by the Wilson Center: “Of course, only the passage of time will allow for anyone to definitively measure the impact of the Obama White House on science, technology, and innovation, and their impacts on our nation in turn, but, according to the Office of the Press Secretary, we have at least 100 things to be thankful for.”
President Obama looks through a telescope during the 2009 White House Astronomy Night.
Credit: Chuck Kennedy
President Barack Obama meets with Apollo 11 astronauts Buzz Aldrin and Michael Collins, right, Carol Armstrong, widow of Apollo 11 commander Neil Armstrong, NASA Administrator Charles Bolden, and Patricia Falcone, OSTP Associate Director for National Security and International Affairs, left, in the Oval Office. This gathering marked the 45th anniversary of the Apollo 11 lunar landing. July 22, 2014.
Credit: Official White House Photo by Pete Souza
Furthermore, as the Obama White House folds up shop and the nation decides on the next administration, how the President valued the space program will come under new scrutiny and review.
To read through this IMPACT REPORT: 100 Examples of President Obama’s Leadership in Science, Technology, and Innovation, go to:
Credit: OSTP/White House
Sources: Virgin Galactic, SpaceX via GAO report.
The U.S. Government Accountability Office (GAO) has issued a new report on commercial space: Industry Developments and FAA Challenges.
GAO has taken a look at the U.S. commercial space launch industry noting it has changed considerably since the enactment of the Commercial Space Launch Amendments Act of 2004.
Space tourism
The Federal Aviation Administration (FAA) is required to license or permit commercial space launches; however, to allow space tourism to develop, the act prohibited FAA from regulating crew and spaceflight participant safety before 2012 – a moratorium that was extended to 2023.
The U.S. Commercial Space Launch Competitiveness Act, enacted in November 2015, addressed other aspects of the commercial space launch industry.
Licensing workload
GAO testimony and the new report summarizes and updates findings from GAO’s 2015 report, specifically industry developments and FAA challenges, including FAA’s launch licensing workload and budget.
For its 2015 report, GAO reviewed FAA’s guidance on its launch permit, licensing, and safety oversight activities; interviewed FAA officials, industry stakeholders, and experts who were selected on the basis of their knowledge of FAA’s oversight of the commercial space launch industry; and visited spaceports where two 2014 launch mishaps occurred.
Credit: GAO
Resources
To access GAO-16-765T, issued on June 22, go to:
http://www.gao.gov/assets/680/677943.pdf
Testimony on their report is available at:
http://www.gao.gov/products/GAO-16-765T
Highlights of the review can be found at:
Curiosity Mars Hand Lens Imager (MAHLI) image taken on Sol 1378, June 22, 2016.
Credit: NASA/JPL-Caltech/MSSS
NASA’s Curiosity rover on Mars is now in Sol 1380.
Over last weekend, the wheeled robot stopped after about 55 feet (17 meters) of a planned drive of 213 feet (65 meters) drive.
“The rover is fine, the drive just tripped one of the very conservative limits on how the rover’s suspension was expected to behave, causing Curiosity to stop and check in with Earth,” reports Ryan Anderson, a planetary scientist at the USGS Astrogeology Science Center at Flagstaff, Arizona.
Curiosity Navcam Left B image taken on Sol 1378, June 22, 2016.
Credit: NASA/JPL-Caltech
Word is that rover drivers are trying to make up this week some of the lost distance from the weekend plan.
Bedrock targeting
According to a Sol 1378 plan, the rover’s Chemistry & Camera (ChemCam) was to make observations bedrock at the target “Tombua” and a rock named “Ai Ais.”
Curiosity Navcam Left B image taken on Sol 1378, June 22, 2016.
Credit: NASA/JPL-Caltech
Curiosity’s Mastcam was then slated to image the two ChemCam targets, as well as use on Sol 1376 the Autonomous Exploration for Gathering Increased Science (AEGIS) system.
Atmospheric observations
The rover’s Mastcam will on tap to image some veins at a location called “Helgas.” After that, the plan called for driving and collecting some typical post-drive imaging.
Curiosity Mastcam Right image taken on Sol 1378, June 21, 2016.
Credit: NASA/JPL-Caltech/MSSS
On Sol 1379, the rover was to use its ChemCam, NavCam, and Mastcam gear to make atmospheric observations. Then in the afternoon, ChemCam had some calibration observations, followed by a few more Mastcam atmospheric observations.
Dust on the deck
Turning back the clock a bit to Sol 1377, the Left Mastcam acquired a mosaic of the rover deck, to serve as a baseline for comparison with future images taken after passing the sand dunes along the path ahead.
Curiosity Mastcam Left image of rover’s deck on Sol 1375, June 19, 2016.
Credit: NASA/JPL-Caltech/MSSS
Reports Ken Herkenhoff, also of the USGS Astrogeology Science Center, sand blown across the rover might remove some of the dust on the rover deck.
Volcanism finding
Meanwhile, NASA announced yesterday that scientists using Curiosity have discovered an unexpected mineral in a rock sample at Gale Crater on Mars.
Analyzing data from an X-ray diffraction instrument on the rover that identifies minerals, scientists detected significant amounts of a silica mineral called tridymite.
Tridymite is generally associated with silicic volcanism.
The discovery of tridymite – led by scientists in the Astromaterials Research and Exploration Science (ARES) Division at NASA’s Johnson Space Center in Houston — might induce scientists to rethink the volcanic history of Mars, suggesting that the planet once had explosive volcanoes that led to the presence of the mineral.
Making tracks
A recently released map of the rover’s traverse indicates that from Sol 1376 to Sol 1378 Curiosity had driven a straight line distance of about 139.03 feet (42.38 meters).
Since touching down on the Red Planet in August 2012, Curiosity has wheeled itself over 8.10 miles (13.04 kilometers).
As always, dates of planned rover activities are subject to change due to a variety of factors related to the martian environment, communication relays and rover status.
