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Friday, September 24, 2021

New Images From The Perseverance Rover

 

NASA’s Perseverance Rover Cameras Capture Mars Like Never Before

Sep 23, 2021
NASA's Perseverance Mars rover took this selfie over a rock nicknamed Rochette, on September 10, 2021. Two holes can be seen where the rover used its robotic arm to drill rock core samples.

Using its WATSON camera, NASA’s Perseverance Mars rover took this selfie over a rock nicknamed “Rochette,” on Sept.10, 2021, the 198th Martian day, or sol, of the mission. Two holes can be seen where the rover used its robotic arm to drill rock core samples.

 
Credit: NASA/JPL-Caltech/MSSS 

Scientists tap into an array of imagers aboard the six-wheeled explorer to get a big picture of the Red Planet.

NASA’s Perseverance rover has been exploring Jezero Crater for more than 217 Earth days (211 Martian days, or sols), and the dusty rocks there are beginning to tell their story – about a volatile young Mars flowing with lava and water.

That story, stretching billions of years into the past, is unfolding thanks in large part to the seven powerful science cameras aboard Perseverance. Able to home in on small features from great distances, take in vast sweeps of Martian landscape, and magnify tiny rock granules, these specialized cameras also help the rover team determine which rock samples offer the best chance to learn whether microscopic life ever existed on the Red Planet.

Altogether, some 800 scientists and engineers around the world make up the larger Perseverance team. That includes smaller teams, from a few dozen to as many as 100, for each of the rover’s cameras and instruments. And the teams behind the cameras must coordinate each decision about what to image.

“The imaging cameras are a huge piece of everything,” said Vivian Sun, the co-lead for Perseverance’s first science campaign at NASA’s Jet Propulsion Laboratory in Southern California. “We use a lot of them every single day for science. They’re absolutely mission-critical.”

Watch as Caltech’s Eva Scheller, a member of the Perseverance science team, provides a snapshot of the rover’s SHERLOC science instrument. Mounted on the rover’s robotic arm, SHERLOC features spectrometers, a laser, and cameras, including WATSON, which takes close-up images of rock grains and surface textures.

 Credit: NASA/JPL-Caltech

The storytelling began soon after Perseverance landed in February, and the stunning images have been stacking up as the multiple cameras conduct their scientific investigations. Here’s how they work, along with a sampling of what some have found so far:

The Big Picture

Perseverance’s two navigation cameras – among nine engineering cameras – support the rover’s autonomous driving capability. And at each stop, the rover first employs those two cameras to get the lay of the land with a 360-degree view.

NASA's Perseverance Mars rover looks back toward its tracks on July 1, 2021, after driving autonomously 358 feet (109 meters), its longest autonomous drive to date.

Perseverance looks back with one of its navigation cameras toward its tracks on July 1, 2021 (the 130th sol, or Martian day, of its mission), after driving autonomously 358 feet (109 meters) – its longest autonomous drive to date. The image has been processed to enhance the contrast. 

Credit: NASA/JPL-Caltech 

“The navigation camera data is really useful to have those images to do a targeted science follow-up with higher-resolution instruments such as SuperCam and Mastcam-Z,” Sun said.

Perseverance’s six hazard avoidance cameras, or Hazcams, include two pairs in front (with only a single pair in use at any one time) to help avoid trouble spots and to place the rover’s robotic arm on targets; the two rear Hazcams provide images to help place the rover in the context of the broader landscape.

Mastcam-Z, a pair of “eyes” on the rover’s mast, is built for the big picture: panoramic color shots, including 3D images, with zoom capability. It can also capture high-definition video.

NASA's Perseverance Mars rover used its Mastcam-Z camera system to create this panorama of its first drill site. Scientists will be looking for a rock to drill somewhere in this location.

Perseverance Mars rover used its Mastcam-Z camera system to create this enhanced-color panorama, which scientists used to look for rock-sampling sites. The panorama is stitched together from 70 individual images taken on July 28, 2021, the 155th Martian day, or sol, of the mission. 

Credit: NASA/JPL-Caltech/ASU/MSSS 

Jim Bell at Arizona State University leads the Mastcam-Z team, which has been working at high speed to produce images for the larger group. “Part of our job on this mission has been a sort of triage,” he said. “We can swing through vast swaths of real estate and do some quick assessment of geology, of color. That has been helping the team figure out where to target instruments.”

Color is key: Mastcam-Z images allow scientists to make links between features seen from orbit by the Mars Reconnaissance Orbiter (MRO) and what they see on the ground.

The instrument also functions as a low-resolution spectrometer, dividing the light it captures into 11 colors. Scientists can analyze the colors for clues about the composition of the material giving off the light, helping them decide which features to zoom in on with the mission’s true spectrometers.

For instance, there’s a well-known series of images from March 17. It shows a wide escarpment, aka the “Delta Scarp,” that is part of a fan-shaped river delta that formed in the crater long ago. After Mastcam-Z provided the broad view, the mission turned to SuperCam for a closer look.

The Long View

This composite image of Jezero Crater's Delta Scarp was generated using data from the Perseverance rover's Remote Microscopic Imager and Mastcam-Z camera.

Composed of five images, this mosaic of Jezero Crater’s “Delta Scarp” was taken on March 17, 2021, by Perseverance’s Remote Microscopic Imager (RMI) camera from 1.4 miles (2.25 kilometers) away. 

Credit: RMI: NASA/JPL-Caltech/LANL/CNES/CNRS/ASU/MSSSMastcam-Z: NASA/JPL-Caltech/ASU/MSSS 

Scientists use SuperCam to study mineralogy and chemistry, and to seek evidence of ancient microbial life. Perched near Mastcam-Z on Perseverance’s mast, it includes the Remote Micro-Imager, or RMI, which can zoom in on features the size of a softball from more than a mile away.

Once Mastcam-Z provided images of the scarp, the SuperCam RMI homed in on a corner of it, providing close-ups that were later stitched together for a more revealing view.

To Roger Wiens, principal investigator for SuperCam at Los Alamos National Laboratory in New Mexico, these images spoke volumes about Mars’ ancient past, when the atmosphere was thick enough, and warm enough, to allow water to flow on the surface.

“This is showing huge boulders,” he said. “That means there had to have been some huge flash flooding that occurred that washed boulders down the riverbed into this delta formation.”

The chock-a-block layers told him even more.

“These large boulders are partway down the delta formation,” Wiens said. “If the lakebed was full, you would find these at the very top. So the lake wasn’t full at the time the flash flood happened. Overall, it may be indicating an unstable climate. Perhaps we didn’t always have this very placid, calm, habitable place that we might have liked for raising some micro-organisms.”

In addition, scientists have picked up signs of igneous rock that formed from lava or magma on the crater floor during this early period. That could mean not only flowing water, but flowing lava, before, during, or after the time that the lake itself formed.

These clues are crucial to the mission’s search for signs of ancient Martian life and potentially habitable environments. To that end, the rover is taking samples of Martian rock and sediment that future missions could return to Earth for in-depth study.

The (Really) Close-up

NASA's Perseverance Mars rover took this close-up of a rock target nicknamed Foux, using its WATSON camera on the end of the rover's robotic arm. The image was taken July 11, 2021.

Perseverance took this close-up of a rock target nicknamed “Foux” using its WATSON camera on July 11, 2021, the 139th Martian day, r sol, of the mission. The area within the camera is roughly 1.4 by 1 inches (3.5 centimeters by 2.6 centimeters).

 
Credit: NASA/JPL-Caltech/MSSS 

A variety of Perseverance’s cameras assist in the selection of those samples, including WATSON (the Wide Angle Topographic Sensor for Operations and eNgineering).

Located at the end of the rover’s robotic arm, WATSON provides extreme closeups of rock and sediment, zeroing in on the variety, size, shape, and color of tiny grains – as well as the “cement” between them – in those materials. Such information can lend insight into Mars’ history as well as the geological context of potential samples.

WATSON also helps engineers position the rover’s drill for extracting rock core samples and produces images of where the sample came from.

The imager partners with SHERLOC (Scanning Habitable Environments with Raman & Luminescence for Organics & Chemicals), which includes an Autofocus and Contextual Imager (ACI), the rover’s highest-resolution camera. SHERLOC uses an ultraviolet laser to identify certain minerals in rock and sediment, while PIXL (Planetary Instrument for X-ray Lithochemistry), also on the robotic arm, uses X-rays to determine the chemical composition. These cameras, working in concert with WATSON, have helped capture geologic data – including signs of that igneous rock on the crater floor – with a precision that has surprised scientists.

“We’re getting really cool spectra of materials formed in aqueous [watery] environments – for example sulfate and carbonate,” said Luther Beegle, SHERLOC’s principal investigator at JPL.

Engineers also use WATSON to check on the rover’s systems and undercarriage – and to take Perseverance selfies (here’s how).

Beegle says not just the strong performance of the imaging instruments, but their ability to endure the harsh environment on the Martian surface, gives him confidence in Perseverance’s chances for major discoveries.

“Once we get over closer to the delta, where there should be really good preservation potential for signs of life, we’ve got a really good chance of seeing something if it’s there,” he said.

More About the Mission

A key objective for Perseverance’s mission on Mars is astrobiology, including the search for signs of ancient microbial life. The rover will characterize the planet’s geology and past climate, pave the way for human exploration of the Red Planet, and be the first mission to collect and cache Martian rock and regolith (broken rock and dust).

Subsequent NASA missions, in cooperation with ESA (European Space Agency), would send spacecraft to Mars to collect these sealed samples from the surface and return them to Earth for in-depth analysis.

The Mars 2020 Perseverance mission is part of NASA’s Moon to Mars exploration approach, which includes Artemis missions to the Moon that will help prepare for human exploration of the Red Planet.

JPL, which is managed for NASA by Caltech in Pasadena, California, built and manages operations of the Perseverance rover.

For more about Perseverance:

mars.nasa.gov/mars2020/

nasa.gov/perseverance

Sunday, September 19, 2021

Gwynne Shotwell- Elon Musk's secret weapon at Spacex

Elon Musk Live from SpaceX | Live Splashdown of Inspiration4 Space Orbit...

Inspiration4 Returns To Earth With All Safe

 

     The Inspiration4 manned space capsule re-entered the earth's atmosphere. It splashed down in the Atlantic Ocean without any problems. All four civilian astronauts emerged from the capsule in good health and with great spirits. (Can you imagine the party that awaited them when the helicopter took them back to dry land??!!)

    I watched the SpaceX podcast of the reentry and landing. Two young SpaceX engineers were the commentators. They projected a very nonchalant attitude. It was like the whole process was “just routine; “ like the landing of an airliner after a flight.

   I could see tension in the faces of the SpaceX personnel behind them in mission control. They had good reason to be tense. The Dragon capsule was making a reentry like no other Dragon Capsule had done before. They were coming in faster. The capsule would go to 3,500 degrees Fahrenheit while crashing to earth. There is also the crucial issue of the alignment of the capsule as it starts to reenter the earth's atmosphere. It must be "mathematically perfect." If the capsule comes one degree too shallow, it will burn up, killing the four astronauts. If the capsule comes one degree too high, it will bounce off the earth's atmosphere and be stranded in space. Most likely, the crew would run out of life support and electricity before a rescue could be mounted.

     This entire mission was a noble effort to raise money for a great hospital that has been in business some 60 years-Saint Jude's Children's Hospital. This money raising effort has been a success. The statistics vary wildly on how much money has been raised. Estimates start as low as "just under $200 million dollars" up to "more than $570 million dollars."

Saturday, September 18, 2021

SpaceX | RE-WATCH THE HIGHLIGHTS OF INSPIRATİON 4 MISSION

Inspiration4 | Splashdown

The Martian Movie Clip "If You Don't"

FAA Approves Starship to Orbit!! Sorta...

An Amazing Story From The Inspiration4 Manned Spaceflight

 

     The Inspiration4 manned space flight is scheduled to splashdown in the Atlantic at 4:06 Pacific Time today. Netflix has an incredible documentary titled Countdown that I recommend for all to watch. It is fascinating and enlightening.

      I want to share one incredible story with you that touched my heart. Let us go back to 1959 when NASA was just getting started. It was a sad time of strict racial segregation and brutal treatment of black people. Dr. Sian Proctor's father never had the money to go to college. He taught himself complex subjects like calculus, physics, engineering, etc. When he heard that NASA was hiring, he went over and applied for a job. Since he had no college degrees or experience in the aircraft industry, his chances of getting hired were small. He did not let this deter him. He applied for a job. He got the attention of one person. He took a battery of tests. This NASA employee was amazed at how good he did. He got a job offer.

    NASA became his life. Some ten years later, he was at the intersection of a historical moment. He was on the island of Guam. He was at a NASA deep-space communications facility. As Apollo-11 was preparing to reenter the earth's atmosphere, it lost all contact with earth except for a deep-space tracking facility on Guam. Dr. Proctor's father found himself talking on the radio with Neil Armstrong. He gave Neil all the information that he needed to come through the atmosphere and splashdown in the Pacific. When Apollo 11 hit the Pacific Ocean, Mr. Proctor guided rescue helicopters to pick up the capsule and three astronauts. When Neil Armstrong got onto the USS Hornet, he felt deep gratitude to Mr. Proctor. He wrote him a personal thank you note. He asked US Navy personnel to make sure that the note got to Mr. Proctor on Guam.

    Mr. Proctor was surprised and touched when he got the thank you note from Neil. It became a family treasure. When Dr. Proctor blasted off into space, the note was carried with her.

Continue with your hard work and preparations,

 

Tuesday, September 14, 2021

The Great Space Company Sale

 

The great space company sale


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The exhibit hall at last week’s Satellite 2021 conference in the suburbs of Washington, DC, was a little quiet. Some companies that normally exhibit at the show, one of the major conferences in the commercial space industry, elected to reduce their presence or not exhibit at all, either because of the timing of the conference—it normally takes place in the spring—or because of ongoing pandemic travel restrictions. There was, though, still an assortment of satellite operators, manufacturers, and suppliers of components and related services.

“Every smart person, every brilliant technology downstairs is going to be bought by one of these companies,” Kemp predicted.

But, in a conference room a couple floors above that exhibit call, one industry executive predicted bigger disruptions to come. “This is the last Satellite conference that will be like this,” said Chris Kemp, CEO and co-founder of Astra. He said companies like his are going to be responsible for that change.

“A dozen companies just went public and all have billions of dollars,” he explained. “Every smart person, every brilliant technology downstairs is going to be bought by one of these companies, and all of these great technologies and all these great products are not going to be available to the primes.”

Those companies that have gone public, like Astra, have done so through a merger with what’s known as a special-purpose acquisition company, or SPAC, sometimes called a “blank check” company (see “Space investors head to the exits, at last”, The Space Review, February 15, 2021.) A SPAC raises money by going public with the intent of merging with a privately held company. That allows the merged company to go public with the proceeds of the SPAC (along with, in many cases, a concurrent funding round) without having to go through the typical initial public offering (IPO) process.

SPACs gained popularity in the markets generally in the last year, and space is no exception. In the past 12 months companies ranging from launch startups to operators of satellite constellations have announced SPAC mergers, many of which have been completed. BlackSky, a geospatial intelligence company that operates a fleet of high-resolution imaging satellites, completed its SPAC merger last week; a week earlier, Redwire, a space technology firm, completed its SPAC deal.

Another company that has gone public through a SPAC is Rocket Lab, which completed its SPAC deal last month. It staged a virtual version of a bell-ringing ceremony on the Nasdaq exchange on its first day of trading, with company CEO Peter Beck and other employees participating from New Zealand rather than Nasdaq’s New York headquarters.

Rocket Lab raised $777 million in the deal, funding which will go towards its Neutron medium-class launch vehicle it announced earlier this year. But Beck said in an interview that the funding from the deal, as well as having a publicly traded stock, will allow it to go acquire other companies.

“There’s a real opportunity to do consolidation in this space, and we intend to be one of the consolidators,” he said.

“The space industry at large is hampered by scale,” Beck said. “If you go to any of these shops and ask for 2,000 of anything, generally people’s heads explode.”

In an earnings call last week, the first since Rocket Lab went public, both Beck and Rocket Lab CFO Adam Spice said they were on the lookout for companies to acquire. They didn’t mention specific companies but suggested they were interested in acquiring smaller suppliers of spacecraft components that could benefit from the resources Rocket Lab could provide.

“There’s a lot of mom-and-pop, bootstrapped companies where they’re founder-controlled,” Spice said. “They’re really nice businesses that are reasonably integratable, they’re digestible from that perspective. They’ve also had a focus on profitability, so you’re not picking up what are typically ventured-funded cash-burning operations. We’re seeing quite a bit of opportunity.”

Rocket Lab has already made one such acquisition. Last spring, it acquired Sinclair Interplanetary, a Canadian producer of smallsat components such as reaction wheels and star trackers. Rocket Lab acquired Sinclair to use those components on its own Photon spacecraft, but is also continuing to sell them to other companies. It announced at the beginning of September it was scaling up production of reaction wheels, using part of an existing production line in New Zealand.

“The space industry at large is hampered by scale,” Beck said. Sinclair used to produce no more than 100–150 reaction wheels a year, but the new production line can produce up to 2,000 such components annually. “If you go to any of these shops and ask for 2,000 of anything, generally people’s heads explode.”

Spice said Rocket Lab had about a half dozen potential acquisitions in its pipeline but didn’t indicate when it would complete any of them. “The outlook looks good for us,” he said. “The Sinclair acquisition has really emboldened us to lean forward and look at opportunities.”

Astra, too, has started acquiring companies. In June, it announced it was buying Apollo Fusion, a startup developing electric propulsion for satellites. The companies said the deal was worth up to $145 million based on Apollo Fusion’s ability to meet technical and revenue milestones.

“What this is about is adding a really core piece of technology to Astra’s platform,” Kemp said when Astra announced the deal. “It’ll unlock a whole new set of customer opportunities for us.”

Astra, when it announced its SPAC merger earlier this year, said it planned to move beyond launch to spacecraft. The company will develop satellite buses designed to launch on its rockets, providing a vertically integrated solution like Rocket Lab with its Photon satellites launched on Electron rockets, and thus may be in the market for suppliers of key technologies.

Others going public may have similar views. Last month, launch company Virgin Orbit announced it would go public via a SPAC. The deal with NextGen Acquisition Corp. II would raise up to $483 million, including an investment by Boeing. Part of those proceeds would go to scaling up its current LauncherOne air-launch business, as well as investing in new launch capabilities (a slide in an investor presentation showed a larger rocket, called LauncherTwo, placed on top of its Boeing 747 aircraft rather than attached to its wing as LauncherOne is.)

“If you’re a company that’s thinking about selling out, taking stock in a company that has never launched a satellite and whose valuation is based on launching every single day is hard to do,” Musey said.

Virgin Orbit also announced it would go into the “space solutions” business, developing a constellation of satellites to provide Internet of Things services and Earth observation. The company plans to start launching satellites in 2023, and projects that part of the business to be more than 20% of its overall revenues by 2026. It would certainly be a candidate for making acquisitions to build up a satellite manufacturing line.

Redwire, while not in the launch business, is another public company likely to use its capital and stock to buy up companies. Redwire was formed last year through the merger of two space component suppliers, and has since bought several more, such as space manufacturing company Made In Space.

“We do have a number of opportunities that we are looking at” in terms of companies it’s considering buying, said Peter Cannito, CEO of Redwire, during an analyst day presentation in July. “Space is a highly fragmented market and Redwire has been the buyer of choice, combining niche technology companies that provide tremendous flight heritage with new space startups with disruptive technologies.”

Not every space company going public through SPACs is likely to be buying up companies. Some have said they plan to spend their capital on their own capabilities, like Satellogic, an Earth observation company that plans to use its SPAC proceeds to build out its satellite constellation.

At Satellite 2021, some of the other people on the same panel as Astra’s Kemp offered a more cautious assessment. “There’s always the questions of when you think the consolidation will happen and where are the acquisitions,” said Michael Collett, managing partner of Promus Ventures, a fund that has invested in several space companies. “We just haven’t seen a lot in space.”

Some the early-stage companies, like Astra, that have gone public might struggle to use their stock as capital for acquiring companies. “I don’t think a SPAC stock will be a good acquisition vehicle in many cases because a company hasn’t been proven out,” said J. Armand Musey, president and founder of Summit Ridge Group.

Share in some space companies that have going public via SPACs have been languished, or in the case of Astra, fell sharply after its latest failed effort to get to orbit (see “Small launch vehicles face their biggest test,” The Space Review, September 7, 2021.) “If you’re a company that’s thinking about selling out, taking stock in a company that has never launched a satellite and whose valuation is based on launching every single day is hard to do,” Musey said.

But even skeptics say that capital sloshing around the industry thanks to SPACs might prompt companies to acquire suppliers or make other strategic deals—or encourage competitors to make their own deals. “Space is having its moment,” said Collett. “Traditionally, people who weren’t acquisitive may change.”

As for whether it will revamp the roster of companies that participate at conferences like Satellite 2021, well, we won’t have long to wait. Conference organizers plan to move back to their traditional March date for the next conference, meaning that Satellite 2022 will take place in just six months.


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