Archive for the ‘Space News’ Category

Curiosity Mastcam Right image taken on Sol 2384, April 21, 2019.
Credit: NASA/JPL-Caltech/MSSS

NASA’s Curiosity Mars rover is now performing Sol 2387 duties.

“The drilling planned for last weekend was successful,” reports Ken Herkenhoff, a planetary geologist at the USGS in Flagstaff, Arizona.

Curiosity Mastcam Left image taken on Sol 2384, April 21, 2019.
Credit: NASA/JPL-Caltech/MSSS

The recent top priority for the robot is to drop portions of the Kilmarie sample onto a closed Sample Analysis at Mars (SAM) Instrument Suite inlet cover and take Mastcam images after each dropoff to characterize the size of each portion.

“The results of this portioning test will be used to decide how many portions to eventually drop into SAM,” Herkenhoff adds. After this testing is completed, Mastcam will measure the amount of dust in the atmosphere above the robot by imaging the Sun through neutral-density filters, and Navcam will search for clouds.

Curiosity ChemCam Remote Micro-Imager photo taken on Sol 2386, April 23, 2019.
Credit: NASA/JPL-Caltech/LANL

Aberlady in focus

The Chemistry and Camera (ChemCam) Remote Micro-Imager (RMI) is scheduled to acquire a “stack” of images of the Aberlady drill hole at various focus settings to find the best focus setting for future Laser Induced Breakdown Spectroscopy (LIBS) elemental chemistry measurements from the rover’s new vantage point, Herkenhoff explains.

“The RMI will also acquire a couple mosaics of the sulfate-rich rocks exposed in the distance southeast of the rover. Mastcam will measure variations in sky brightness to constrain the size of dust grains suspended in the atmosphere before the rover takes a long nap,” Herkenhoff reports.

Also on tap is use of Curiosity’s Chemistry & Mineralogy X-Ray Diffraction/X-Ray Fluorescence Instrument (CheMin). This instrument will vibrate its inlet sieve and dump the Aberlady sample in preparation for analysis of the Kilmarie drill sample.

Dust opacity

Slated for Sol 2387 tasks, the robot’s Mastcam will again measure dust opacity and Navcam will search for dust devils and clouds.

Curiosity Front Hazcam Left B image acquired on Sol 2386, April 23, 2019.
Credit: NASA/JPL-Caltech

“ChemCam will then use its laser to measure the elemental chemistry in the wall of the new Kilmarie drill hole,” Herkenhoff notes, “and of a nearby pebble named ‘Quirang’ and a bedrock outcrop named ‘Caledonian Canal.’”

Also scheduled is use of the Right Mastcam to image all of the ChemCam targets before Dynamic Albedo of Neutrons (DAN) turns on its neutron generator to search for hydrogen up to half a meter below the surface.

Curiosity Navcam Right B image taken on Sol 2386, April 23, 2019.
Credit: NASA/JPL-Caltech

Herkenhoff concludes by noting that Mars Hand Lens Imager (MAHLI) activities are precluded while there is sample in the drill stem.

Credit: CMSA

A crucial flight of China’s Long March-5B carrier rocket is slated for launch in the first half of 2020, according to the China Manned Space Engineering Office (CMSEO).

The maiden flight of this class of Long March booster is critical to China’s human and robotic space exploration plans.

China’s state-run Xinhua News Agency reports that the Long March-5B will carry the core capsule and experiment capsules of China’s space station, expected to be completed in 2022.

Prototype of the Tianhe core module. China’s space station is expected to be operational around 2022. CCTV/Screengrab

Three phases

The country’s Tiangong space station is mainly comprised of the Core Capsule, Experiment Capsule I and Experiment Capsule II, with the aim of building a reliable operating space station and providing long-term support for the onboard astronauts.

Testing of Tianhe core module.
Credit: China Manned Space Agency (CMS) via Andrew Jones

According to Xinhua, the space station project will be implemented in three phases: key technology validation, construction and operation.

Six flight missions, including the maiden flight of the Long March-5B rocket and launch of the test core capsule, have been scheduled in the first phase, and launches of experiment capsules in the second phase.

Each capsule will weigh about 20 tons. After a series of tests, the core capsule will be transferred into the flight model phase. The two experiment capsules are ready undergoing final assembly, according to China’s Science and Technology Daily.

Credit: China Manned Space Agency

Experiment racks

Xinhua News Agency also reports that there are sixteen experiment racks installed within the core module and two lab capsules of the space station, and an extravehicular experiment platform will be built.

Each rack is regarded as a lab that can support various space experiments, and astronauts can upgrade and replace the experiments.

In addition, a capsule holding a large optical telescope will fly in the same orbit as the station.

Robot arm under development for use in China’s station effort.
Credit: CGTN/screengrab

Cold atomic experiment system

The space station will carry a hydrogen clock, a cold atomic clock, and an optical clock to establish a high-precision time and frequency system.

The time and frequency system, as well as an ultra-low temperature cold atomic experiment system, will support research in general relativity, gravitational physics, and quantum physics, said Zhang Wei, director of the Utilization Development Center of the Technology and Engineering Center for Space Utilization (CSU).

China’s space station program will host international collaboration in experiments on the orbiting complex. Nearly 100 international cooperation proposals have been received, and about 30 have passed the initial evaluation, Zhang added.

Credit: Lu Liangliang/CNSA

 

 

Moon exploration

In related work, China aims to build a scientific research station in the south polar region of the Moon and realize a crewed lunar exploration mission in about ten years, reports Zhang Kejian, head of the China National Space Administration.

 

 

China will launch the Chang’e-5 lunar probe to collect and return lunar samples back to Earth at the end of 2019, Zhang said, according to Xhinua News Agency.

China’s next Moon exploration phase: Sample return from the Moon.
Credit: CCTV/Screengrab/Inside Outer Space

Shaoshan, the hometown of China’s late leader Mao Zedong, will be one of the permanent storage centers of the lunar samples, Zhang said.

Lastly, since 2016, China has set April 24 as the country’s Space Day. The theme of this year’s activities is to “pursue space dreams for win-win cooperation.”

Mars Base 1 Camp in Jinchang City of northwest China’s Gansu Province.
Credit: New China TV/Screengrab by Inside Outer Space

China has opened Mars Base 1 Camp in Jinchang City of northwest China’s Gansu Province, an expansive facility to popularize science and boost interest in space exploration.

Located in the Gobi desert of Jinchang some 12 miles (20 kilometers) from Jinchang’s urban area, the simulation camp will become an astronaut training facility in the future.

Credit: New China TV/Screengrab by Inside Outer Space

Survival, training facility

Covering 67 square kilometers, and costing $373 million, “Mars Base 1 is the most authentic Martian survival simulation facility in the country by far,” Li Tanqiu, deputy chief designer for China’s astronaut system department, said at the opening ceremony in a press statement.

Credit: New China TV/Screengrab by Inside Outer Space

“The base was developed and built with full technical support from the China Astronaut Research and Training Center,” Li added, “which means it has the scientific logic system of the aerospace team and the valuable experience accumulated by astronauts who have trained in the past.”

Go to this informative New China TV video that features an Xinhua News Agency reporter touring the Mars camp.

https://youtu.be/xp9X-Bwtlt8

Fixed image of March 27th showing individual pieces of fragmented U.S. rocket stage detected for tagging and identification.
Credit: Deimos Sky Survey

 

A discarded upper stage from a rocket launched nearly a decade ago has fragmented, adding to ongoing growth of orbital debris encircling Earth.

The large Atlas V Centaur upper stage, for an as-yet-unknown reason, broke up between March 23 – March 25.

At a recent meeting of space debris specialists, Vladimir Agapov of Keldysh Institute of Applied Mathematics unveiled the fragmentation event of object 2009-047B, estimated to have taken place on March 25th.

Crumbling culprit: Atlas V Centaur upper stage.
Credit: NASA/Roy Allison

2009-047B is the second stage of the Atlas V launcher which put in orbit USA 207, an American military communications satellite on September 8, 2009.

Detailed images

Just hours after learning of the breakup, the Zimmerwald Observatory in Switzerland scheduled immediate observations of the cloud of fragments, and by March 26 had acquired the first views.

Deimos Sky Survey observatory.
Credit: Elecnor Deimos Sky Survey

 

Also following the announcement, the Deimos Sky Survey observatory provided detailed images of the central body and between 40 and 60 fragments larger than 30 centimeters in size.

Deimos Sky Survey (DeSS) is an advanced complex in Spain equipped with the latest technology for the observation (surveillance and tracking) and catalog of near-Earth space objects. These objects can be natural, such as near asteroids also known as NEOs (Near Earth Objects), or human-made, like satellites and space debris.

Results of the Elecnor Deimos Space Situational Awareness (SSA) team analyses, — such as the expected evolution of the fragments cloud around the Earth or the spatial density at different altitudes and timeframe — are being shared with the space surveillance and tracking international community.

In-orbit explosions can be related to the mixing of residual fuel that remain in tanks or fuel lines once a rocket stage or satellite is discarded in Earth orbit. The resulting explosion can destroy the object and spread its mass across numerous fragments with a wide spectrum of masses and imparted speeds.
Credit: ESA

Technological trash

“Leaving a trail of debris in its wake, this fragmentation event provides space debris experts with a rare opportunity to test their understanding of such hugely important processes,” explains Tim Flohrer, a European Space Agency (ESA) senior space debris monitoring expert in an ESA statement.

Fragmentation events like this one – either break ups or collisions – are the primary source of debris objects in space in the range of a few millimeters to tens of centimeters in size.

Travelling at high speeds, these bits of “technological trash” pose a threat to crucial space infrastructure, such as satellites providing weather and navigation services – including astronauts aboard the International Space Station, the ESA statement points out.

Video captured by the Deimos Sky Survey in Spain showing the stream of newly-made debris objects as they rush across the sky:

 

Credit: SpaceX

The SpaceX Crew Dragon capsule mishap on April 20 is sure to be a hot topic at the forthcoming meeting of the Aerospace Safety Advisory Panel.

Established by Congress in 1968 to provide advice and make recommendations to the NASA Administrator on safety matters, the Aerospace Safety Advisory Panel (ASAP) is holding its second quarterly meeting for 2019 this Thursday at NASA’s Marshall Space Flight Center in Huntsville, Alabama.

Frames from purported video of Crew Dragon test shows capsule undergoing a serious “anomaly.”
Screengrab/Inside Outer Space

Detecting anomalies

SpaceX technicians were performing a series of engine tests on the test vehicle.

“The initial tests completed successfully but the final test resulted in an anomaly on the test stand,” SpaceX said in a statement.

“Ensuring that our systems meet rigorous safety standards and detecting anomalies like this prior to flight are the main reasons why we test. Our teams are investigating and working closely with our NASA partners.”

Perils inherent to space flight

In the ASAP’s last report, Dr. Patricia Sanders Chair of ASAP noted in an open letter to NASA Administrator, Jim Bridenstine:

“As both the Commercial Crew Program and Exploration Systems Development move beyond design into hardware production and test, we continue to note that NASA maintains focus on the requisite details for risk management and mission success without apparent neglect or omission of planned content. To date, but with technical challenges remaining, there has been no direct evidence that schedule pressure is driving decisions that will adversely impact safety,” Sanders explains.

“As NASA transitions from development to operational launch and flight of its astronauts—something it has not done for several years, since the end of the Shuttle era—it is essential to remain cognizant of the perils inherent to space flight,” Sanders adds.

“Given the great uncertainties of the space operational environment,” Sanders continues, “it is critical to maintain vigilance and attention to test results, engineering understanding, disciplined processes, and consideration of mitigation alternatives. We have often commented on the need for constancy of purpose for exploration, but along with that must go constancy of standards for certification, flight test, and acceptable risk.”

Credit: ASAP

Required actions

In the 2018 ASAP report, a number of recommendations were provided to NASA, including:

Required Actions for Crewed Flight Test Risk Reduction: NASA should confirm and then clearly communicate the required content and configuration for the upcoming CCP test flights-Demo-1 and Orbital Flight Test (OFT)-specifically, those items that must be successfully demonstrated prior to the first crewed flights.

Action to Ensure U.S. Access to the International Space Station Given Commercial Crew Program Schedule Risk: Due to the potential for delays in the schedule for the first Commercial Crew Program (CCP) flights with crew, senior NASA leadership should work with the Administration and the Congress to guarantee continuing access to ISS for U.S. crew members until such time that U.S. capability to deliver crew to the International Space Station (ISS) is established.

The entire Aerospace Safety Advisory Panel report for 2018 is available here:

https://oiir.hq.nasa.gov/asap/documents/2018_ASAP_Report-TAGGED.pdf

 

International Space Station
Credit: Roscosmos/NASA

 

A catalog of the bacteria and fungi found on surfaces inside the International Space Station (ISS) has been presented in a study published in the open access journal Microbiome.

The study — Characterization of the total and viable bacterial and fungal communities associated with the International Space Station surfaces – reveal a diverse population of bacteria and fungi on ISS environmental surfaces that changed over time but remained similar between locations.

The dominant organisms are associated with the human microbiome and may include opportunistic pathogens is a study finding.

Illustration of the eight locations sampled on the ISS over three flight sampling sessions. a Schematic of the US module of the ISS depicting various nodes and modules. The red arrows point to locations sampled during this study. b Detailed images of the sampled area at each location as outlined by blue lines. Location #1, port panel next to cupola (Node 3); location #2, waste and hygiene compartment (node 3); location #3, advanced resistive exercise device (ARED) foot platform (node 3); location #4, dining table (node 1); location #5, zero G stowage rack (node 1); location #6, permanent multipurpose module (PMM) port 1 (PMM); location #7, panel near portable water dispenser (LAB); and location #8, port crew quarters, bump out exterior aft wall (node 2).
Credit: Aleksandra Checinska Sielaff, et. al

Comprehensive catalog

“This study provides the first comprehensive catalog of both total and intact/viable bacteria and fungi found on surfaces in closed space systems and can be used to help develop safety measures that meet NASA requirements for deep space human habitation,” the study explains. “The results of this study can have significant impact on our understanding of other confined built environments on the Earth such as clean rooms used in the pharmaceutical and medical industries.”

The research work was led by Aleksandra Checinska Sielaff and Camilla Urbaniak of the Biotechnology and Planetary Protection Group at the Jet Propulsion Laboratory in Pasadena, California.

Microbial communities

The study points out that the ISS is a closed system inhabited by microorganisms originating from life support systems, cargo, and crew that are exposed to unique selective pressures such as microgravity.

ISS safety measures regarding the human microbiome are prelude to NASA requirements for deep space human habitation.
Credit: Bob Sauls – XP4D/Explore Mars, Inc. (used with permission)

“To date, mandatory microbial monitoring and observational studies of spacecraft and space stations have been conducted by traditional culture methods, although it is known that many microbes cannot be cultured with standard techniques.”

 

 

 

 

 

To fully appreciate the true number and diversity of microbes that survive in the ISS, molecular and culture-based methods were used to assess microbial communities on ISS surfaces. Samples were taken at eight pre-defined locations during three flight missions spanning 14 months and analyzed upon return to Earth.

To read the full report, go to:

https://microbiomejournal.biomedcentral.com/track/pdf/10.1186/s40168-019-0666-x

 

A Dutch radio antenna on the farside of the Moon has successfully provided its first data.

The Netherlands-China Low-Frequency Explorer (NCLE) is onboard China’s Queqiao relay satellite in a halo orbit about the Earth-Moon L2 Lagrange point.

From that position, Queqiao is enabling communications between the China’s Chang’e-4 farside lander and Yutu-2 rover and the Earth.

NCLE is an instrument designed to measure radio waves from the Universe and was developed by a team from the Radboud Radio Lab of the Radboud University, the Netherlands Institute for Radio Astronomy (ASTRON) and the company Innovative Solutions in Space (ISIS).

The Netherlands-China Low-Frequency Explorer (NCLE) is onboard China’s Queqiao relay satellite.
Credit: Radboud Radio Lab of the Radboud University, the Netherlands Institute for Radio Astronomy (ASTRON) and the company Innovative Solutions in Space (ISIS)

Data looks good

The NCLE data show that the radio antenna is doing well under the extreme conditions in space and operates as planned.

“Now, the most dangerous phase of the mission is behind us,” says Christiaan Brinkerink from Radboud Radio Lab in a statement. “We are very happy to see that NCLE is in perfect health. The data look good, and we can now proceed with the next phases of our research.”

Radio antennas of the Netherlands Chinese Low-Frequency Explorer (NCLE), developed by ASTRON, Radboud Radio Lab, ISIS and the National Astronomical Observatories of China (NAOC).
Credit: Radboud Radio Lab/ASTRON/Albert-Jan Boonstra

 

Next phase

The next phase lasts for one month, and is meant to investigate how the performance of NCLE varies under the changing conditions during one orbit around the Earth.

After the first full month of commissioning is done with stowed antennas, the following run of measurements will be performed with partially deployed antennas.

“This process will allow us to perform a complete characterization of the instrument response at different positions in space and for different antenna lengths. It will provide data that we need to calibrate science measurements in the future”, says Albert-Jan Boonstra from ASTRON.

Image from Queqiao relay satellite shows NCLE stowed antenna, the Earth, and farside of the Moon. Queqiao is in a halo orbit at L2 Lagrange point.
Courtesy: Radboud Radio Lab

Full length deployment

The collection of actual scientific data by NCLE is planned to start in six months. At that point, the antennas will be deployed to their full length of a little over 16 feet (5 meters).

“This is what we are really looking forward to,” adds Eric Bertels from ISIS. “The calibration of the instrument is a crucial step in the project, but in the end we are looking for science data.”

According to Marc Klein Wolt from the Radboud Radio Lab: “We are taking it step-by-step working towards doing real science, but getting the first data of the instrument is a major step in the right direction.”

Pathfinder experiment

NCLE focuses on measurements at low radio frequencies, spanning the spectrum from 1 to 80 megahertz. The science cases of NCLE are diverse, and include the study of solar storms, the interaction of planetary magnetospheres with the solar wind, the mapping of low-frequency Galactic emission and ultimately to study the signature of neutral hydrogen in the early Universe.

The Dutch radio instrument the Netherlands-China Low-Frequency Explorer (NCLE) on the Chinese Queqiao satellite behind the moon, has successfully collected data.
The DVD with the data is handed over to Taake Manning, counsel for science and technology of the Dutch Embassy in Beijing.
Courtesy: Radboud Radio Lab/Radboud University

 

NLCE is described as a pathfinder experiment. Experience with its operation and data will be useful to aid in the development of future radio astronomy instruments.

The Chinese Queqiao relay satellite and Dutch antenna were launched from China in May 2018, prior to the Chang’e-4 farside. Queqiao means “Bridge of Magpies” referring to a Chinese folktale about magpies forming a bridge with their wings to allow Zhi Nu, the seventh daughter of the Goddess of Heaven, to reach her husband.

Go to this video showing one of the NCLE antenna elements deploying during a pre-launch test.

https://www.youtube.com/watch?time_continue=16&v=hca3MeX-8rw

Chang’e-5 and Chang’e-6 missions are intended to return lunar samples back to Earth.
Credit: CCTV/Screengrab/Inside Outer Space

The China National Space Administration (CNSA) has invited international partners for cooperation on the country’s Chang’e-6 lunar mission and an asteroid exploration effort.

China announced its cooperation plan for the future Chang’e-6 mission, offering to carry a total of over 40 pounds (20 kilograms) of solicited payloads.

The orbiter and lander of the Chang’e-6 mission will each reserve 10 kilograms for payloads, to be selected from both domestic colleges, universities, private enterprises and foreign scientific research institutions, said Liu Jizhong, director of the China Lunar Exploration and Space Engineering Center of the CNSA.

Credit: CCTV/Screengrab Inside Outer Space

The deadline for applying to join the cooperation plan is Aug 31, 2019.

Asteroid sample return mission. Credit: NASA/JPL-Caltech

According to China’s state-run Xinhua news agency, China’s asteroid project involves a decade-long sojourn to return samples from the near-Earth asteroid, known as 2016 HO3, as well as exploration of a main asteroid belt comet, known as Comet 133P/(7986) Elst–Pizarro.

Moon sampling

Next up for China’s lunar exploration activities is launch by year’s end of the Chang’e-5 sample return mission. However, that venture will be governed by a successful return to flight of the Long March-5 booster this July.

Long March-5 booster’s first liftoff occurred in early November 2016. Mishap on launcher’s second flight in July 2017. A return-to-flight Long March-5 mission is slated for this year.
Credit: CASC

As the backup of the Chang’e-5 mission, the Chang’e-6 mission will also collect lunar samples automatically for comprehensive analysis and research, Liu said. Its launch time and landing site will depend on the performance of the Chang’e-5 mission, he explained.

According to Liu, like Chang’e-5, the Chang’e-6 return sample lunar mission will be comprised of an orbiter, a lander, an ascender and an Earth-return capsule.

Chang’e-4 farside mission – lander and Yutu-2 rover
Credit: CNSA/CLEP

Farside science data

Meanwhile, the scientific data from international payloads onboard the Chang’e-4 farside mission has been delivered to the Netherlands, Sweden and Germany.

The Dutch radio instrument the Netherlands-China Low-Frequency Explorer (NCLE) on the Chinese Queqiao satellite behind the Moon, has successfully collected data.
The DVD with the data is handed over to Taake Manning, counsel for science and technology of the Dutch Embassy in Beijing.
Courtesy: Radboud Radio Lab/Radboud University

The Chang’e-4 farside mission carries four payloads developed by the Netherlands, Germany, Sweden and Saudi Arabia.

The CNSA delivered the data collected by the neutral atom detector aboard the Chang’e-4 rover to Sweden, the data from the neutron radiation detector aboard the Chang’e-4 lander to Germany and the data from the low-frequency radio astronomical instrument aboard the Chang’e-4 relay satellite Queqiao to the Netherlands.

Letters of intent

Pei Zhaoyu, deputy director of Lunar Exploration and Space Engineering Center of CNSA, said China has signed memorandums in space exploration cooperation with dozens of countries so far.

“China has already signed letters of intent for cooperation with dozens of countries. We have signed a memorandum of understanding with Russia on lunar and deep space exploration and an agreement with France this year on the Chang’e-6 carrier cooperation,” Pei said.

 

 

 

 

 

 

Go to this CGTN video that details China’s cooperative space overture:

https://news.cgtn.com/news/3d3d514f3345544d34457a6333566d54/share_p.html

Also go to this CNSA/CCTV provided video:

https://youtu.be/LsVBzPRa0G8?list=PLpGTA7wMEDFjz0Zx93ifOsi92FwylSAS3

Curiosity Front Hazcam Right B photo acquired on Sol 2382, April 19, 2019.
Credit: NASA/JPL-Caltech

NASA’s Curiosity Mars rover is now performing Sol 2383 duties.

A recent drill pre-load test was successful, so a go has been given for a drill attempt at “Kilmarie,” reports Abigail Fraeman, a planetary geologist at NASA/JPL in Pasadena, California.

The new drill location is nearby the last drilling area at “Aberlady.”

Recent imagery taken by the robot shows the point of the drill on the future Kilmarie drill target along with the old Aberlady drill hole, a little to the left of the arm.

Curiosity Navcam Left B image acquired on Sol 2382, April 19, 2019.
Credit: NASA/JPL-Caltech

Drilling irregularities

“It’s been a while since we’ve drilled two locations so close together,” explains Fraeman. “We decided to drill again in this area because we saw some irregularities during drilling Aberlady.”

Specifically, scientists were not sure Curiosity collected enough drill material for both the Chemistry & Mineralogy X-Ray Diffraction/X-Ray Fluorescence Instrument (CheMin) and the Sample Analysis at Mars (SAM) Instrument Suite at the Aberlady location, “so we’re hoping we can be more confident in the amount of sample we collect at Kilmarie,” Fraeman adds.

Curiosity Mastcam Right photo acquired on Sol 2381, April 18, 2019.
Credit: NASA/JPL-Caltech/MSSS

Stable parking position

Fraeman notes her role as Surface Properties Scientist (SPS).

“One of my responsibilities as SPS is to help assess whether the terrain Curiosity is parked on is stable. Curiosity’s arm is so big and heavy that moving it causes the rover’s center of gravity to shift,” Fraeman explains. “If Curiosity isn’t firmly parked, moving the arm could inadvertently move the entire ~1 ton rover, which could result in hardware damage.”

Curiosity Mars Hand Lens Imager (MAHLI) photo produced on Sol 2382, April 19, 2019. MAHLI is located on the turret at the end of the rover’s robotic arm.
Credit: NASA/JPL-Caltech/MSSS

Vehicle slipping

It was determined that Curiosity had parked on a flat surface and five of the wheels were firmly in contact with the ground.

“However, the right front wheel appeared to be sitting on a very small rock (~2-3 centimeters) that was located right in the middle of the wheel. We had a lot of conversations about what the risk of the vehicle slipping was and whether we thought the rock we were sitting on might shift,” Fraeman notes.

Curiosity ChemCam Remote Micro-Imager photo taken on Sol 2382, April 19, 2019.
Credit: NASA/JPL-Caltech/LANL

 

 

 

“Using our experience testing similar situations in the Mars Yard at JPL and knowledge of properties of the terrain around the rover, we decided the risk we’d slip was very small, and gave the ‘OK’ to go ahead with arm activities,” Fraeman says. “Images taken before and after the drill pre-load yesterday confirmed we hadn’t moved at all and were correct in our assessment.”

Space Launch System (SLS) Credit: NASA/MSFC

The U.S. Government Accountability Office (GAO) has issued Priority Open Recommendations: NASA.

In March 2018, GAO identified 18 priority recommendations for NASA. Since then, NASA has implemented 10 of those recommendations by, among other things, taking actions to better align its strategic sourcing practices with those used by leading commercial companies and improving controls over some of its information systems.

Credit Roscosmos/NASA

SLS and ISS

In April 2019, GAO identified one additional priority recommendation for NASA, bringing the total number to nine. These recommendations involve the following areas: monitoring program costs and execution as well as improving efficiency and effectiveness.

“NASA’s continued attention to these issues could lead to significant improvements in government operations,” the GAO document points out.

Among topics spotlighted in the report is developing a contingency plan for access to the International Space Station, as well as Space Launch System (SLS) Block I, as well as Exploration Mission (EM) 1 and 2.

To read the full GAO document, go to:

https://www.gao.gov/assets/700/698632.pdf

Griffith Observatory Event