Stunning Views of Venus, All the Way from Saturn

Venus appears just off the edge of the dark disc of Saturn, in the upper part of the image, directly above the white streak of Saturn's G ring. Credit: NASA/JPL-Caltech/Space Science Institute

Two amazing images from the Cassini spacecraft today: We know how brightly Venus shines in our own night sky; now here’s visual proof it shines brightly even in the skies above Saturn. In one image it shines so brightly that it is even visible looking through Saturn’s rings! But in this absolutely stunning shot, above, Venus appears as a morning star, just off the edge of the planet. From Cassini, you’re looking directly above the edge of Saturn’s G ring to see the white dot, which is Venus. Lower down, Saturn’s E ring makes an appearance, looking blue thanks to the scattering properties of the dust that comprises the ring. (A bright spot near the E ring is a distant star, the Cassini CICLOPS team says.)

This beautiful image was taken on January 4, 2013.

On average, Venus and Saturn are about 1,321,200,000 km (820,955,619 mi or 8.83 astronomical units) apart, so that’s a nice, long distance shot! Venus is brighter in Saturn’s skies than Earth is, however, because Venus is covered in thick sulfuric acid clouds, making it very bright.

And here’s the other great shot, showing Saturn and its rings in true color:

NASA's Cassini spacecraft spies the bright, cloudy terrestrial planet, Venus. Credit: NASA/JPL-Caltech/Space Science Institute
NASA’s Cassini spacecraft spies the bright, cloudy terrestrial planet, Venus. Credit: NASA/JPL-Caltech/Space Science Institute

Venus is the white dot, just above and to the right of the image center. Again, its amazing that it shines through the rings.

This view looks toward the unilluminated side of the rings from about 17 degrees below the ring plane, and was taken in visible light (and it is a true-color image) with the Cassini spacecraft wide-angle camera on Nov. 10, 2012.

In an email about these images, Cassini imaging team lead Carolyn Porco said that even though Venus reaches nearly 900 degrees Fahrenheit (500 degrees Celsius) and has a surface pressure 100 times that of Earth’s, Venus is considered a twin of our planet because of their similar sizes, masses, rocky compositions and close orbits.

And so, she pointed out, “Think about Venus the next time you find yourself reveling in the thriving flora, balmy breezes, and temperate climate of a lovely day on Earth, and remember: you could be somewhere else!”

See more about these images at the CICLOPS (Cassini Imaging Central Laboratory for Operations) website.

How Do You Build a Holodeck?

Star Trek first officer William Riker steps into a simulated jungle on the USS Enterprise-D's holodeck. Credit: Paramount Pictures/CBS Studios, via Memory alpha

What would it be like to step in an ordinary room and feel a gentle, computer-generated jungle breeze, with trees swaying nearby that you could touch?

AMD, a micro processor manufacturer, is trying to figure that out. The company has been doing a conference circuit in recent weeks promoting its research in heterogeneous system architecture, which is essentially a method to bind parallel computing processes together for greater efficiency.

The “holy grail” of these efforts, according to AMD’s Phil Rogers, would be building something like the holodeck — the computer deck on Star Trek (notably in The Next Generation) where characters would play immersive games. They could dial up a mystery novel, for example, then find themselves in a seedy bar with virtual-yet-real-looking holograms in 1940s-style clothing.

Rogers, a corporate fellow at AMD, has spent years working in 3-D technologies. It’s only recently that the company felt comfortable enough to speculate about the holodeck, he says. Other entities are also working on holodeck-like technologies, such as Microsoft and Stony Brook University, so perhaps that helped.

AMD believes it could be only 10 to 15 years before a holodeck becomes real. What would it take to get there?

A better-than-Imax video experience. We hope you’ve had the experience of sitting back in a domed Imax theatre and watching the shuttle launch in Hubble 3-D. Yet despite the awesome wrap-around view, it doesn’t feel like reality. A holodeck would need 360-degree fidelity. It would need to understand that objects get closer when you step towards them, and further when you step away. Perspective must tilt as you move your head.  “You inevitably have to combine multiple video feeds to do that and stitch them together seamlessly,” Rogers said.

The highest-fidelity audio ever. You know those people who swear that records produce better music than MP3s? “People are very much more fussy about video than audio,” Rogers points out. To make the holodeck feel real, the audio not only has to be immersive, but also directional and able to change as the person moves. The latest in surround-sound technologies doesn’t even close to that, he said.

The sensation of touch. Sure, Captain Jean-Luc Picard can slug a virtual villain in the head, but it wouldn’t have that same oomph unless Picard could feel his hand making contact with the other guy. “We still need to develop the tactile feedback, as somebody in a holodeck interacts with an object and another person they need to touch, and they need to feel that they touched,” Rogers said. “The most likely way that we’d do that is with targeted air jets, and transducers that haven’t been developed yet.”

Efficient memory allocation. While the blue screen of death in three dimensions would be rather epic, that’s not what holodeck designers want. The best way to keep the holodeck humming will be sharing memory between the central processing unit and the graphics processing unit, Rogers said. We’ve already made strides in this direction. Still, millions of parallel processes will have to happen simultaneously, so there’s quite a ways to go.

Lots of processing power. It will take mega computer juice to sync up the images, audio and other features that make the holodeck real. Remember that line in the movie Apollo 13 when Tom Hanks refers to the impressive computer “in a single room”? It’s laughable now when glancing at an iPhone, but we face a similar challenge now with holodecks. “The problem is it would take racks and racks of mainframe-like computers,” points out Rogers. A holodeck can’t be commercially available until the components fit to a small rack and draw small amounts of power.

Find paying customers. Naturally, a holodeck won’t happen without a captive market. We’ve had at least one petition asking the White House to build the Enterprise, but looks like that won’t happen anytime soon. Luckily for humanity, AMD has a backup. The firm believes business conference calls could really use a boost from holodeck-like technologies. Instead of having a talking head and a standard PowerPoint presentation, imagine how much more interesting the report would look if said person could, say, grab a virtual model of the solar system and spin it before your eyes.

Target the open-source community. For those people who want to channel their inner Wesley Crusher, AMD plans to leave at least some of the holodeck architecture open to amateur programmers. It’s hard to predict what computer languages will take hold at that time, but it would be the equivalent of letting somebody with C++ or Java experience into the hardware. Perhaps it will let you set your phasers to … whatever you choose.

Spock Weighs in on President Obama’s ‘Meld-Gate’

President Obama & Nichelle Nichols (image credit: Nichelle Nichols).

On March 1st 2013, President Obama awoke hoards of Star Trek and Star Wars fans when during a press conference he (purposely?) fused a Jedi Mind Trick and Vulcan Mind Meld into a: Jedi Mind Meld.  According to White House transcripts, President Obama was responding to CNN’s Jessica Yellin’s remark that he should have the leadership to force Congress to accept a deal to avert the damaging sequester.  President Obama replied to her by first stating that he was not a dictator, and second that he would not use a Jedi Mind Meld to coerce Congress into accepting a deal.

For those who are unaware, a Vulcan Mind Meld and Jedi Mind Trick are indeed different. Two videos are posted below that shed light on that difference.  The first video features Spock performing a Vulcan Mind Meld (Star Trek), and the second involves Obi-Wan Kenobi inacting a Jedi Mind Trick (Star Wars).

Although the pundits initially believed that the President’s mixing of terms was a mistake, experts in some quarters now believe that by using a Jedi Mind Meld President Obama could simulatenously ascertain both his foes’ true intentions and coerce them into accepting a deal.  The President may have likewise been contemplating how Congress could be spurred into action, and perhaps thought as a last resort he’d recruit Star Trek and Star Wars fans worldwide to pressure Congress.  Toward that end the White House released the following image via their Twitter feed, and also launched the website http://www.wh.gov/jedimindmeld/:

The White House released this image to raise awarness of the sequester (http://www.wh.gov/jedimindmeld , image credit: Whitehouse).
The White House released this image and created the following website (http://www.wh.gov/jedimindmeld) to raise awareness of the damaging sequester (image credit: White House).

However, Leonard Nimoy (Spock) has weighed into ‘Meld-gate’, and advised President Obama to forget about Jedi Mind Tricks altogether since, “Only a Vulcan mind meld will help with this congress. Live Long and Prosper.

President Obama isn’t the only politician who happens to be an avid Star Trek fan. King Abdullah II of Jordan was lucky enough to make a cameo on Star Trek Voyager.  Will President Obama be making a cameo in the new Star Trek film “Into the Darkness” directed by J. J. Abrams?  Incidentally, Abrams will likewise be directing the new Star Wars: Episode VII movie.  Perhaps the President is on to something?


Newly Found Asteroid to Pass Within Moon’s Orbit on March 4, 2013

A newly found asteroid, 2013 EC can be seen in the lower left corner of the red box in this image. Screen capture from Virtual Telescope webcast on 3/3/2013.

A newly found asteroid will pass just inside the orbit of the Moon, with its closest approach on March 4, 2013 at 07:35 UTC. Named 2013 EC, the asteroid is about the size of the space rock that exploded over Russia two and a half weeks ago, somewhere between 10-17 meters wide. The asteroid that sparked the Russian meteor is estimated to have been about 17 meters wide when it entered Earth’s atmosphere.

2013 EC was discovered by the Mt. Lemmon Observatory in Arizona on March 2. There is no chance this asteroid will hit Earth.

2013 EC will come within 396,000 kilometers from Earth, (246,000 miles, or around 1.0 lunar distances, 0.0026 AU.

The Moon’s distance from the Earth varies between 363,104 km (225,622 miles) at perigee (closest) and 406,696 km (252,088 miles) at apogee (most distant point).

Gianluca Masi from the Virtual Telescope Project had a live view of the asteroid when it was about twice the distance of the Moon, and a replay of that webcast is available below. (Views of the asteroid start at about 31:00 in the video.)

“That we are finding all these asteroids recently does not mean that we are being visited by more asteroids,” Masi said during the webcast, “just that our ability to detect them has gotten so much better. Our technology has improved a lot over the past decades.”

More info about 2013 EC on the JPL Small Body Database.

Berth of a Dragon after Thruster Failure Recovery Establishes American Lifeline to ISS

SpaceX Dragon berthing at ISS on March 3, 2013. Credit: NASA

Kennedy Space Center – After overcoming a frightening thruster failure that could have spelled rapid doom on the heels of a breathtakingly beautiful launch, the privately developed Dragon spacecraft successfully berthed at the International Space Station (ISS) a short while ago, at 8:56 a.m. EST Sunday morning, March 3, 2013 – thereby establishing an indispensable American Lifeline to the massive orbiting lab complex.

Hearts sank and hopes rose in the span of a few troubling hours following Friday’s (Mar. 1) flawless launch of the Dragon cargo resupply capsule atop the 15 story tall Falcon 9 rocket from Cape Canaveral Air Force Station, Florida and the initial failure of the life giving solar arrays to deploy and failure of the maneuvering thrusters to fire.

“Congrats to the @NASA/@SpaceX team. Great work getting #Dragon to the #ISS…our foothold for future exploration!” tweeted NASA Deputy Administrator Lori Garver.

Space station Expedition 34 crew members Kevin Ford and Tom Marshburn of NASA used the station’s 58 foot long Canadian supplied robotic arm to successfully grapple and capture Dragon at 5:31 a.m. Sunday as the station was flying 253 miles above northern Ukraine. See the grappling video – here.

SpaceX Dragon holding at 10m capture point. ISS crew standing by for "go" to perform grapple. Credit: NASA
SpaceX Dragon holding at 10m capture point. ISS crew standing by for “go” to perform grapple. Credit: NASA

“The vehicle’s beautiful, space is beautiful, and the Canadarm2 is beautiful too”, said station commander Kevin Ford during the operation.

The capsule pluck from free space came one day, 19 hours and 22 minutes after the mission’s launch.

Ground controllers at NASA’s Johnson Space Center in Houston then commanded the arm to install Dragon onto the Earth-facing port of the Harmony module – see schematic.

Schematic shows location of Dragon docking port for CRS-2 mission and ISS modules. Credit: NASA
Schematic shows location of Dragon docking port for CRS-2 mission and ISS modules. Credit: NASA

Originally, Dragon capture was slated only about 20 hours after launch. But that all went out the window following the serious post-launch anomalies that sent SpaceX engineers desperately scrambling to save the flight from a catastrophic finale.

The $133 million mission dubbed CRS-2 is only the 2nd contracted commercial resupply mission ever to berth at the ISS under NASA’s Commercial Resupply Services (CRS) contract. The contract is worth $1.6 Billion for at least a dozen resupply flights.

Following the forced retirement of NASA’s space shuttle orbiters in July 2011, American was left with zero capability to launch either cargo or astronauts to the primarily American ISS. NASA astronauts are 100% reliant on Russian Soyuz capsules for launch to the ISS.

Both the Falcon 9 rocket and Dragon spacecraft were designed and built by SpaceX Corporation based in Hawthorne, Calif., and are entirely American built.

The Falcon 9/Dragon commercial system restores America’s unmanned cargo resupply capability. But the time gap will be at least 3 to 5 years before American’s can again launch to the ISS aboard American rockets from American soil.

And continuing, relentless cuts to NASA’s budget are significantly increasing that human spaceflight gap and consequently forces more payments to Russia.

“Today we marked another milestone in our aggressive efforts to make sure American companies are launching resupply missions from U.S. shores,” said NASA Admisistrator Charles Bolden in a NASA statement.

“Our NASA-SpaceX team completed another successful berthing of the SpaceX Dragon cargo module to the International Space Station (ISS) following its near flawless launch on the Falcon-9 booster out of Cape Canaveral, Florida Friday morning. Launching rockets is difficult, and while the team faced some technical challenges after Dragon separation from the launch vehicle, they called upon their thorough knowledge of their systems to successfully troubleshoot and fully recover all vehicle capabilities. Dragon is now once again safely berthed to the station.”

“I was pleased to watch the launch from SpaceX’s facility in Hawthorne, CA, and I want to congratulate the SpaceX and NASA teams, who are working side by side to ensure America continues to lead the world in space.”

“Unfortunately, all of this progress could be jeopardized with the sequestration ordered by law to be signed by the President Friday evening. The sequester could further delay the restarting of human space launches from U.S. soil, push back our next generation space vehicles, hold up development of new space technologies, and jeopardize our space-based, Earth observing capabilities,” said Bolden.

ISS crew given GO for second stage capture of SpaceX Dragon with ISS on March 3, 2013.  Credit: NASA
ISS crew given GO for second stage capture of SpaceX Dragon with ISS on March 3, 2013. Credit: NASA

Dragon is loaded with about 1,268 pounds (575 kilograms) of vital supplies and provisions to support the ongoing science research by the resident six man crew, including more than a ton of vital supplies, science gear, research experiments, spare parts, food, water and clothing.

NASA says that despite the one-day docking delay, the Dragon unberthing will still be the same day as originally planned on March 25 – followed by a parachute assisted splashdown in the Pacific Ocean off the coast of Baja California.

Dragon will spend 22 days docked to the ISS. The station crew will soon open the hatch and unload all the up mass cargo and research supplies. Then they will pack the Dragon with about 2,668 pounds (1,210 kilograms) of science samples from human research, biology and biotechnology studies, physical science investigations, and education activities for return to Earth.

Canadian built robotic arm grapples SpaceX Dragon on March 3, 2013.  Credit:
Canadian built robotic arm grapples SpaceX Dragon on March 3, 2013. Credit:

Dragon is the only spacecraft in the world today capable of returning significant amounts of cargo to Earth.

Orbital Sciences Corp also won a $1.9 Billion cargo resupply contract from NASA to deliver cargo to the ISS using the firm’s new Antares rocket and Cygnus capsule.

NASA hopes the first Antares/Cygnus demonstration test flight from NASA’s Wallops Island Facility in Virginia will follow in April. Cygnus cargo transport is one way – to orbit only.

“SpaceX is proud to execute this important work for NASA, and we’re thrilled to bring this capability back to the United States,” said Gwynne Shotwell, President of SpaceX.

“Today’s launch continues SpaceX’s long-term partnership with NASA to provide reliable, safe transport of cargo to and from the station, enabling beneficial research and advancements in technology and research.”

The SpaceX CRS-3 flight is slated to blast off in September 2013.

Ken Kremer

Falcon 9 SpaceX CRS-2 launch on March 1, 2013 ISS - shot from the roof of the Vehicle Assembly Building.  .  Credit: Ken Kremer/www.kenkremer.com
Falcon 9 SpaceX CRS-2 launch on March 1, 2013 to the ISS – shot from the roof of the Vehicle Assembly Building. Credit: Ken Kremer/www.kenkremer.com

Video: Dragon Grappled and Berthed at Space Station

The Dragon approaches the ISS over sub-Saharan Africa. Credit: NASA/Chris Hadfield.

SpaceX’s Dragon spacecraft has arrived at the International Space Station! After overcoming a problem with its thrusters after reaching orbit on on Friday, today, Dragon successfully approached the Station, where it was captured by Expedition 34 Commander Kevin Ford and crewmate Tom Marshburn using the station’s Canadarm2 robotic arm. Dragon was grappled at 5:31 a.m. EST, and was berthed to the Earth-facing port of the Harmony module at approximately 8:56 a.m. EST on March 3.

Below, Canadian astronaut Chris Hadfield snapped a photo of Dragon as it approached the station over sub-Saharan Africa. “A surreal juxtaposition,” Hadfied said via Twitter.

SpaceX Dragon Recovers from Frightening Propulsion System Failure – Sunday Docking Set

Launch of SpaceX Falcon 9 on CRS-2 mission on March 1, 2013 from Cape Canaveral, Florida. Credit: Jeff Seibert

Kennedy Space Center – Barely 11 minutes after the spectacular Friday morning, March 1 launch of the SpaceX Falcon 9 rocket and unmanned Dragon capsule bound for the International Space Station (ISS), absolute glee suddenly threatened to turn to total gloom when the mission suffered an unexpected failure in the critical propulsion system required to propel the Dragon to the Earth orbiting outpost.

An alarming issue with the Dragons thrust pods prevented three out of four from initializing and firing.

For several hours the outlook for the $133 million mission appeared dire, but gradually began to improve a few hours after launch.

“It was a little frightening,” said SpaceX CEO Elon Musk at a Friday afternoon media briefing for reporters gathered at the Kennedy Space Center, commenting on the moments after the glitch appeared out of nowhere.

“We noticed after separation that only one of the four thruster pods engaged or was ready to engage,” Musk explained. “And then we saw that the oxidizer pressure in three of the four tanks was low.”

Launch of SpaceX Falcon 9 on CRS-2 mission on March 1, 2013 from Cape Canaveral, Florida. Credit: Jeff Seibert
Launch of SpaceX Falcon 9 on CRS-2 mission on March 1, 2013 from Cape Canaveral, Florida. Credit: Jeff Seibert/Wired4Space.com

The situation progressed onto the road to recovery after SpaceX engineers immediately sprang into action and frantically worked to troubleshoot the thruster problems in an urgent bid to try and bring the crucial propulsion systems back on line and revive the mission.

By late Saturday afternoon sufficient recovery work had been accomplished to warrant NASA, ISS and SpaceX managers to give the go-ahead for the Dragon to rendezvous with the station early Sunday morning, March 3.

“The station’s Mission Management Team unanimously agreed that Dragon’s propulsion system is operating normally along with its other systems and ready to support the rendezvous two days after Friday’s launch on a Falcon 9 rocket from the Cape Canaveral Air Force Station in Florida,” NASA announced in a statement on Saturday, March 2.

A failure to ignite the thrusters within 1 or 2 days would have resulted in unacceptable orbital decay and a quick and unplanned fiery reentry into the earth’s atmosphere, said Musk.

Reentry would cause a total loss of the mission – carrying more than a ton of vital supplies, science gear, research experiments, spare parts, food, water and provisions to orbit for the stations six man crew.

Shortly after the Dragon achieved orbit and separated from the second stage, the solar arrays failed to deploy and the live webcast stopped prematurely.

Falcon 9 SpaceX CRS-2 launch on March 1, 2013 ISS - shot from the roof of the Vehicle Assembly Building.  .  Credit: Ken Kremer/www.kenkremer.com
Falcon 9 SpaceX CRS-2 launch on March 1, 2013 to the ISS – shot from the roof of the Vehicle Assembly Building. Credit: Ken Kremer/www.kenkremer.com

During the course of the Friday afternoon briefing, Musk and NASA officials received continuous updates indicating the situating was changing and slowly improving.

Musk confirmed that SpaceX was able to bring all four of Dragon’s thruster pods back up and running. Engineers were able to identify and correct the issue, normalizing the pressure in the oxidation tanks.

The problem may have been caused by stuck valves or frozen oxidizer in the lines. Dragon has four oxidizer tanks and four fuel tanks.

“We think there may have been a blockage of some kind or stuck check valves going from the helium pressure tank to the oxidizer tank,” Musk hypothesized. “Whatever that blockage is seems to have alleviated.”

Three of the four thruster pods must be active before the Dragon would be permitted to dock, said Mike Suffredini, NASA program manager for the ISS. There are a total of 18 Draco thrusters.

SpaceX and the ISS partners conducted a thorough review process to assure that the thrusters will work as advertised and allow the Dragon to safely enter the stations keep out zone and physically dock at the berthing port onto the Earth-facing port of the Harmony module.

“SpaceX said it has high confidence there will be no repeat of the thruster problem during rendezvous, including its capability to perform an abort, should that be required,” NASA said in a statement.

Dragon is now slated to be grappled early Sunday morning at 6:31 a.m. by NASA Expedition 34 Commander Kevin Ford and NASA Flight Engineer Tom Marshburn – that’s one day past the originally planned Saturday morning docking.


Video: Falcon 9 SpaceX CRS-2 launch on March 1, 2013 bound for the ISS – shot from the roof of the Vehicle Assembly Building. Credit: Matthew Travis/Spacearium

NASA says that despite the one-day docking delay, the Dragon unberthing and parachute assisted return to Earth will still be the same day as originally planned on March 25.

There are numerous docking opportunities available in the coming days if SpaceX and NASA determined that more time was needed to gain confidence that Dragon could safely carry out an attempt.

Musk said the Dragon could stay on orbit for several additional months if needed.

We have to review the data with NASA before docking to make sure it’s safe, Musk emphasized on Friday.

Falcon 9 SpaceX CRS-2 launch on March 1, 2013.  Credit: Mike Killian/www.zerognews.com
Falcon 9 SpaceX CRS-2 launch on March 1, 2013. Credit: Mike Killian/www.zerognews.com

The mission dubbed CRS-2 will be only the 2nd commercial resupply mission ever to berth at the ISS. SpaceX is under contract to NASA to conduct a dozen Dragon resupply flight to the ISS over the next few years at a cost of about $1.6 Billion.

NASA TV coverage of rendezvous and grapple on Sunday, March 3 will begin at 3:30 a.m. EST. Coverage of berthing operations on NASA TV will begin at 8 a.m.

SpaceX’s live coverage at http://www.spacex.com/webcast begins at 6:00 a.m. Eastern.

Ken Kremer

Falcon 9 SpaceX CRS-2 launch on March 1, 2013.  Credit: Mike Killian/www.zerognews.com
Falcon 9 SpaceX CRS-2 launch on March 1, 2013. Credit: Mike Killian/www.zerognews.com

Curiosity’s Landing Leftovers

Enhanced-color HiRISE image of impact craters from MSL's ballast weights (NASA/JPL-Caltech)

During its “seven minutes of terror” landing on August 6, 2012, NASA’s Mars Science Laboratory dropped quite a few things down onto the Martian surface: pieces from the cruise stage, a heat shield, a parachute, the entry capsule’s backshell, a sky crane, one carefully-placed rover (obviously) and also eight tungsten masses — weights used for ballast and orientation during the descent process.

Two 75 kilogram (165 lb) blocks were released near the top of the atmosphere and six 25 kg (55 lb) weights a bit farther down, just before the deployment of the parachute. The image above, an enhanced-color image from the HiRISE camera aboard the Mars Reconnaissance Orbiter, shows the impact craters from four of these smaller tungsten masses in high resolution. This is part of a surface scan acquired on Jan. 29, 2013.

These four craters are part of a chain of six from all the 55 kg weights. See below for context:

CLICK TO PLAY - Before-and-after images of the 55 kg-mass landing sites (NASA/JPL/MSSS)
CLICK TO PLAY – Before-and-after images of the 55 kg-mass landing sites (NASA/JPL/MSSS)

Captured by MRO’s Context Camera shortly after the rover landed, the animation above shows the impact site of all six 55 kg masses. These impacted the Martian surface about 12 km (7.5 miles) from the Curiosity rover’s landing site.

A mosaic has been assembled showing potential craters from the larger ballast blocks as well as other, smaller pieces of the cruise stage. Check it out below or download the full 50mb image here.

HiRISE images of MSL's impact craters (NASA/JPL/University of Arizona)
HiRISE images of MSL’s impact craters (NASA/JPL/University of Arizona)

As Alfred McEwen wrote in his article on the University of Arizona’s HiRISE site: “most of the stuff we sent to Mars crashed on the surface–everything except the Curiosity rover.”

 

Giveaway: Win a Free Copy of the Sun Surveyor App for Your iPhone

It’s time for another giveaway. This time we’re giving out 10 copies of the Sun Surveyor App for iOS. This is an app that helps photographers know where the Sun is going to be, to get that perfect mountain photo.

Sun Surveyor calculates Sun and Moon positions, Sun and Moon rise & set times, solar noon, golden hour and blue hour times, moon phases, sun shadow ratios and many other pieces of related information. A 3D Compass, Augmented Reality View and Interactive Map enable use as a visualizer, tracker and predictor of Sun and Moon paths, with many practical uses for photographers & filmmakers, stargazers, solar industry & real estate professionals, architects and others.

Sun Surveyor is available for iOS and Android. But this promotion is open to iOS users only, unfortunately (iOS lets developers give away free copies of their apps, but Google Play doesn’t).

This Giveaway is now closed. Thank you for your interest!

You can learn more about the iOS version here, or from Google Play.

Just put your email into the box below to enter the giveaway. The giveaway ends on Saturday, March 9th, 2013.

Curiosity Rover Has Computer Problems

Curiosity Rover's Self Portrait at 'John Klein' Drilling Site, which combines dozens of exposures taken by the rover's Mars Hand Lens Imager (MAHLI) during the 177th Martian day, or sol, of Curiosity's work on Mars (Feb. 3, 2013). Credit: NASA/JPL-Caltech/MSSS

A problem with the memory on the Curiosity rover’s main computer has caused engineers to switch the rover over to a redundant onboard computer. This caused the rover to go into “safe mode,” which was anticipated in the computer switch. And so now over the next few days, the team will be shifting the rover from safe mode to operational status. They are also troubleshooting the condition that affected operations yesterday.

The @MarsCuriosity Twitter feed posted: “Don’t flip out: I just flipped over to my B-side computer while the team looks into an A-side memory issue.”

JPL said the condition is related to a glitch in flash memory linked to the other, now-inactive, computer in response to a memory issue on the computer that had been active.

The intentional swap occurred at about 2:30 a.m. PST on Thursday, Feb. 28.

“We switched computers to get to a standard state from which to begin restoring routine operations,” said Richard Cook. .

Like many spacecraft, Curiosity carries a pair of redundant main computers in order to have a backup available if one fails. Each of the computers, A-side and B-side, also has other redundant subsystems linked to just that computer. Curiosity is now operating on its B-side, as it did during part of the flight from Earth to Mars. It operated on its A-side from before the August 2012 landing through Wednesday.

“While we are resuming operations on the B-side, we are also working to determine the best way to restore the A-side as a viable backup,” said JPL engineer Magdy Bareh, leader of the mission’s anomaly resolution team.

The spacecraft remained in communications at all scheduled communication windows on Wednesday, but it did not send recorded data, only current status information. The status information revealed that the computer had not switched to the usual daily “sleep” mode when planned. Diagnostic work in a testing simulation at JPL indicates the situation involved corrupted memory at an A-side memory location used for addressing memory files.

Scientific investigations by the rover were suspended Wednesday and today. Resumption of science investigations is anticipated within several days. This week, laboratory instruments inside the rover have been analyzing portions of the first sample of rock powder ever collected from the interior of a rock on Mars.

Source: JPL