Posted on by Nancy Atkinson

HiRISE Camera to Attempt Imaging Curiosity’s Descent to Mars

Mars Reconnaissance Orbiter's High Resolution Imaging Science Experiment (HiRISE) camera captured this image of Phoenix hanging from its parachute as it descended to the Martian surface. Credit: NASA/JPL/University of Arizona.

[/caption]

Note: This article was updated on Aug. 3 with additional information.

The HiRISE camera crew on the Mars Reconnaissance Orbiter will attempt an audacious repeat performance of the image above, where the team was able to capture an amazing shot of the Phoenix lander descending on a parachute to land on Mars’ north polar region. Only this time it will try to focus on the Mars Science Laboratory’s Curiosity rover descending to touch down in Gale Crater. It will be all or nothing for the HiRISE team, as they get only one shot at taking what would likely be one of the most memorable images of the entire mission for MRO.

“We’re only making one attempt on MSL here,” Christian Schaller of the HiRISE team told Universe Today. “The EDL (Entry, Descent and Landing) image is set up so that as MSL is descending, MRO will be slewing the HiRISE field of view across the expected descent path. The plan is to capture MSL during the parachute phase of descent.”

Schaller is the software developer responsible for the primary planning tools the MRO and HiRISE targeting specialists and science team members use to plan their images.

Last December, when Universe Today learned of this probable imaging attempt, HiRISE Principal Investigator Alfred McEwen confirmed for us that, indeed, the team was working to make it happen. The preferred shot would be to “capture the rover hanging from the skycrane, but the timing may be difficult,” McEwen said.

It would take an impeccable – and fortuitous – sense of timing to get that shot, but since MSL’s EDL won’t happen on a precisely exact timetable, the HiRISE team will take their one shot and see what happens.

“We’ve been gradually updating the exact timing of the sequence over the past couple of weeks as the MSL navigation team, the MRO navigation team and the MRO flight engineering team refines that descent path and MRO slew,” Schaller said via email, “and we think we’ve pretty much got it nailed down at this point. I think it’s a real testament to NASA and its partners that we can even think about doing this.”

HiRISE will actually be taking two images, but the first is a “throwaway” warmup image taken about 50 minutes prior to MSL’s descent, designed to heat the camera’s electronics up to the preferred temperature for getting good image data.

“The warmup image we’re taking is a long-exposure throwaway that we’re taking on the night side of Mars,” Schaller explained. “It’s a 5,000 microsecond per line exposure, compared to a more typical 100 microsecond per line exposure during normal surface imaging. These warmup data will be useless, and we don’t even bother sending them back to Earth; we just dump them from the MRO filesystem once the exposure is complete.”

Schaller said the warmup image starts executing at 04:17 UTC/9:17 PM PDT. The real image starts executing at 05:09 UTC/10:09 PM PDT, centered on 10:16 PM as the time MSL and MRO navigation teams have determined MSL will pass through HiRISE’s field of view.

This image will be an approximately 500 microseconds per line exposure, to match the MRO’s slew rate.


Caption: Artist impression of MRO orbiting Mars. Credit: NASA

UPDATE (Aug. 3): In checking with McEwen, he said that Mars Express and Odyssey are NOT planning to image the descent, but they are supporting EDL via UHF relay, and the plans to use CTX has been dropped.

“HiRISE plans are to definitely attempt the image, unless there is a late upset to the MRO spacecraft,” McEwen said via email on August 3. “The engineers estimate we have a 60% chance of capturing MSL in our image.”

MRO’s Context Camera (CTX) will also be attempting to image Curiosity’s descent, as will NASA’s Mars Odyssey and ESA’s Mars Express and all the spacecraft have been performing special maneuvers to be aligned in just the right place – nearby to MSL’s point of entry into Mars’ atmosphere.

While Odyssey and Mars Express’ cameras may not have the resolving power to capture MSL itself, the powerful HiRISE camera does. However, it has a narrower field of view, so as much skill and planning as this requires, the team will need a little luck, too. But there’s also the CTX.

“CTX has a much larger field of view and will likely capture it,” McEwen said, “but at 20X lower resolution than HiRISE, which should still be good enough to detect the parachute.”

For those concerned about the fuel required for all these orbiters to reposition themselves just to take a few pictures, the expenditure is nothing that isn’t required anyway. All the spacecraft need to be in position to support MSL during the critical EDL event, and the images are pure extra-benefit, if not an incredible exercise for the imaging teams.

So while we’ll all be crossing our fingers for a successful landing for Curiosity, I’m on my way to find a rabbit’s foot or 4-leaf clover for HiRISE.

Posted on by Nancy Atkinson

Reminiscent of Apollo, Australian Facilities Will Receive First Signals of Curiosity Rover Landing

The movie “The Dish” tells the wonderful story of how Australian radio communication dishes saved the day as Apollo 11 landed on the Moon, allowing the world to watch in wonder. While the movie isn’t entirely accurate, Australia does have a marvelous history of providing tracking and communication with spacecraft on historic missions. The tradition continues with the upcoming landing of the Mars Science Laboratory Curiosity rover when it sets down on Mars on August 5/6 after a nail-biting entry, descent and landing.

The Canberra Deep Space Communication Complex (CDSCC) will be the main tracking station for the landing activities. Its 70-m and two 34-m antennas will receive signals from the spacecraft both directly and then relayed through another NASA spacecraft, Mars Odyssey, in orbit around the Red Planet.

The 64-m Parkes telescope – the one featured in “The Dish” — will record signals directly from the spacecraft as a backup in case there is a problem with the relaying. But as the spacecraft descends, it will drop below the Martian horizon (and out of direct sight of Earth-based antennas) about two minutes before touchdown, and Parkes will cease receiving its signals.

A third, smaller, antenna managed by the European Space Agency (ESA) at New Norcia near Perth in WA will provide extra redundancy. It will receive signals from the spacecraft recorded and re-sent through ESA’s Mars Express satellite, which is in orbit around Mars.

Signals from the Canberra station will be sent directly to mission scientists at NASA’s Jet Propulsion Laboratory (JPL) in Pasadena, California. Data from Parkes and New Norcia will be sent later for analysis.

While the landing is not controlled from Earth, as the lag-time in radio signals (13.8 minutes one way) makes any input from Earth impossible, tracking the spacecraft as it approaches Mars is very important.

Astrophoto: Tracking Curiosity by Glen James Nagle
Tracking Curiosity. Image Credit: Glen James Nagle

“We are looking forward to receiving and sending that touchdown signal from MSL, so we can help end those ‘7 minutes of terror’ for the amazing scientists and engineers waiting at JPL,” said Glen Nagle, Education and Public Outreach Officer at Canberra Deep Space Communication Complex, via email. Nagle took this panoramic image, above, early in December 2011 in Canberra while the dishes were getting their first data from MSL after its launch, so the facility has been an integral part of guiding the spacecraft during its entire journey to Mars.

The last opportunity to send the spacecraft any commands will be two hours before it enters the atmosphere. “After that, it’s on its own,” said Nagle.

NASA engineers also want to know exactly where the spacecraft enters the atmosphere so they can locate the rover when it lands, and of course, the hopeful rover fans back on Earth will want to find out as soon as possible to know if the landing succeeded or not.

The spacecraft will slam into the atmosphere at 20,000 km per hour. Over the next seven minutes the craft and then its payload must be slowed to essentially zero.

The landing has several stages: cruise, deployment of the entry capsule and then the parachute, separation of the heat shield, and finally the operation of the “skycrane” that will lower the 900-kg rover, Curiosity, onto the Martian surface.

As each stage is successfully completed the spacecraft will send a unique tone indicating that it has occurred.

During the landing, the mission scientists can only watch and wait. They call this time the “seven minutes of terror”.

The exact landing time for the spacecraft is determined by several factors, including descent time on the parachute, Martian winds, and any variation how the spacecraft flies under power before the landing. Confirmation of a touchdown signal could be received on Earth at 05:31 UTC on Aug. 6 (10:31 p.m. PDT on Aug. 5 and 1:31 a.m. EDT Aug. 6, 3.31 pm AEST Aug. 6) plus or minus a minute.

Winds could mean that descent time on the parachute is longer, but at this time of year on Mars the weather is very stable and is not expected to cause any problems.

If the final set of tones is not heard, Mars Odyssey will listen for them again when it orbits over the landing site 1.5 hours later.

“The expertise of Australian personnel in space communications and CSIRO’s partnership with NASA will be showcased during this critical event in the Mars Science Laboratory’s mission,” says Chief of CSIRO Astronomy and Space Science, Dr. Phil Diamond. “All of our technology and our people are ready.”

And so are all the rover fans back on Earth!

Read more about what it has taken to navigate MSL all the way to Mars at our previous article, “How Will MSL Navigate to Mars? Very Precisely.”

And here’s another previous article about how we *really* watched the footage from the Apollo 11 Moon landing, thanks to the Australian radio dishes.

Lead image caption: The 70-m antenna at the Canberra Deep Space Communication Complex. (Credit: CDSCC)

source: CSIRO

Posted on by Ken Kremer

4 Days to Mars: Curiosity activates Entry, Descent and Landing Timeline – EDL Infographic

It’s 4 Days to Mars – and NASA’s Curiosity Mars Science Lab (MSL) spacecraft is now flying under the control of the crafts autonomous entry, descent and landing timeline and picking up speed as she plunges ever faster to the Red Planet and her Rendezvous with Destiny.

“Timeline activated. Bleep-bop. I’m running entry, descent & landing flight software all on my own. Countdown to Mars: 5 days,” Curiosity tweeted Tuesday night.

See below an EDL explanatory infographic timeline outlining the critical sequence of events which must unfold perfectly for Curiosity to safely survive the “7 Minutes of Terror” set to begin on the evening of August 5/6.

Aug. 1 TV Viewing Alert – 11:30 PM EDT – see NASA Science Chief John Grunsfeld tonight (Wed, Aug. 1) on the Colbert Report


Image Caption: Curiosity EDL infographic – – click to enlarge

And the excitement is building rapidly for NASA’s biggest, boldest mission ever to the Red Planet as the flight team continues to monitor Curiosity’s onboard systems and flight trajectory. Yesterday, the flight team successfully carried out a memory test on the software for the mechanical assembly that controls MSL’s descent motor, configured the spacecraft for its transition to entry, descent and landing approach mode, and they enabled the spacecraft’s hardware pyrotechnic devices.

Curiosity remains healthy and on course. If fine tuning for the targeted landing ellipse is needed, the next chance to fire on board thrusters to adjust the trajectory is Friday, Aug. 3.

The 4th of 6 possible Trajectory Correction Maneuver (TCM) firings was just accomplished on Sunday, July 29 – details here.

The car sized Curiosity rover is scheduled to touchdown on Mars at about 1:31 a.m. EDT (531 GMT) early on Aug. 6 (10:31 p.m. PDT on Aug. 5) inside Gale Crater and next to a 3 mile (5 km) mountain taller that the tallest in the US.

Gale Crater is 154 km (96 mi) in diameter and dominated by a layered mountain rising some 5 km (3 mi) above the crater floor which exhibits exposures of minerals that may have preserved evidence of past or present Martian life.

Curiosity is packed with 10 state-of-the-art science experiments that will search for organic molecules and clay minerals, potential markers for signs of Martian microbial life and habitable zones.

Watch NASA TV online for live coverage of the Curiosity landing on Aug 5/6:
mars.jpl.nasa.gov or www.nasa.gov

Ken Kremer

Posted on by Nancy Atkinson

Quick and Curious Facts About the Mars Science Laboratory Mission

Since launching in November 2011, NASA’s Mars Science Laboratory (MSL) has been on a 560 million-kilometer (350 million-mile) journey to the Red Planet, with landing scheduled for late Sunday August 5 or early Monday August 6, depending on where you live on Earth. The Curiosity rover has been tucked away cozily into a spacecraft for safekeeping during flight, but when it reaches Mars’ surface it will encounter tough and frigid conditions, all in the name of science. This is NASA’s fourth rover mission to Mars, and its goal is to determine the planet’s past — and present — potential for habitability. Want to know more? Here are some facts about Curiosity and the mission:

When will it land on Mars?
For us Earthlings, the Curiosity rover will land on Mars at 05:31 UTC on Aug. 6 (10:31 p.m. PDT on Aug. 5, 1:31 a.m. EDT Aug. 6) plus or minus a minute. This is Earth-received time, which includes one-way light time (13.8 minutes) for radio signal to reach Earth from Mars. The landing will be at about 3 p.m. local time at the Mars landing site.

How long does it take for the rover to get to Mars’ surface after it reaches the outer atmosphere?
About 7 minutes. Dubbed the “seven minutes of terror” by NASA, MSL will employ a parachute, landing rockets, a hovering sky crane, and other complicated mechanisms to help lower the rover to the surface of Mars.

Watch this video to learn more about the seven minutes of terror:

How big is the parachute?
The diameter of the parachute is 15 meters (51 feet). It is a supersonic parachute, the largest ever deployed on another world. The parachute can withstand 65,000 lbs of pressure, which is critical, as in the Martian atmosphere, once the parachute deploys, it will still be forced to cope with 9Gs of pressure. It is orange and white (the school colors of Caltech, home of the Jet Propulsion Laboratory)

How big are the spacecraft and the rover?
Cruise vehicle dimensions (cruise stage and aeroshell with rover and descent stage inside): Diameter: 4.5 meters (14 feet, 9 inches); height: 3 meters (9 feet, 8 inches)

Curiosity Rover dimensions: Length: 3 meters (9 feet, 10 inches) — (not counting arm); width: 2.8 meters (9 feet, 1 inch).

Height at top of mast: 2.1 meters (7 feet)

Arm length: 2.1 meters (7 feet). The arm is capable of collecting powdered samples from rocks, scooping soil, preparing and delivering samples for analytic instruments, and brushing surfaces on the planet.

Wheel diameter: 0.5 meter (20 inches)

Mass: 3,893 kilograms (8,463 pounds) total at launch, consisting of 899-kilogram (1,982-pound) rover; 2,401-kilogram (5,293-pound) entry, descent and landing system (aeroshell plus fueled descent stage); and 539-kilogram (1,188-pound) fueled cruise stage.

How does the rover get its power for roving?
Multi-mission radioisotope thermoelectric generator and lithium-ion batteries

What are the science instruments on board Curiosity?
10 instruments weighing a total of 75 kilograms (165 pounds), to do many of the tasks scientists do in a lab. Instead of sending samples back to Earth for humans to analyze, the Curiosity rover will thus be able to do laboratory tests right from the Martian surface. The instruments are:
Alpha Particle X-ray Spectrometer, Chemistry and Camera, Chemistry and Mineralogy, Dynamic Albedo of Neutrons, Mars Descent Imager, Mars Hand Lens Imager, Mast Camera, Radiation Assessment Detector, Rover Environmental Monitoring Station, and Sample Analysis at Mars

How many cameras are on Curiosity?
17 (some of which are part of the 10 science instruments)

When did Curiosity launch?
Nov. 26, 2011, 10:02 a.m. EST, from Launch Complex 41, Cape Canaveral Air Force Station, Fla.
Launch Vehicle: Atlas V 541 provided by United Launch Alliance

How far is Mars away from Earth?
Earth–Mars distance at launch: 204 million kilometers (127 million miles)
Earth–Mars distance on landing day: 248 million kilometers (154 million miles)
Total distance of travel, from Earth to Mars: About 567 kilometers (352 million miles)

How fast can Curiosity rove?
On average, the rover is expected to travel across the surface of Mars at about 30 meters (98 feet) per hour, based on power levels, slippage, steepness of the terrain, visibility, and other variables.

Where is Curiosity’s landing site?
Landing site: 4.6 degrees south latitude, 137.4 degrees east longitude, near base of Mount Sharp inside Gale Crater, a layered mountain that rises 4.8 kilometers (3 miles). The mountain was named after planetary geologist Bob Sharp.

What will the weather be like at Gale Crater?
Expected near-surface atmospheric temperatures at landing site during primary mission: minus 90 C to zero C (minus 130 F to 32 F ). Basically, cold and windy with wind gusts of up to 144 km/h (90 mph) —as strong as some hurricane winds on Earth. Mars is home to dust storms and quickly moving whirlwinds known as dust devils.

How many possible landing sites did scientists considered before deciding on Gale Crater?
60. Gale Crater was chosen because it is thought to contain elements that are important to the search for the ingredients of life.

How long is the primary mission?
One Martian year. Because a day on Mars is longer than one on Earth—39 minutes and 35.244 seconds longer, to be exact—a Martian year is equal to 98 weeks, or 687 days, on Earth.

How much does this mission cost?
$2.5 billion, including $1.8 billion for spacecraft development and science investigations and addition amounts for launch and operations.

Lead image caption: Curiosity completes Biggest Interplanetary Rocket Firing to Mars. Illustrations show (left) the Mars Science Laboratory spacecraft during its voyage from Earth to Mars and (right) the mission’s rover, Curiosity, working on Mars after landing. Credit: NASA/JPL/Caltech

Second image caption: This computer-generated view based on multiple orbital observations shows Mars’ Gale crater as if seen from an aircraft northwest of the crater. Image Credit: NASA/JPL-Caltech/ASU/UA

sources: NASA, Caltech

Posted on by Nancy Atkinson

Curious About Curiosity’s Chemistry Mission?

The Mars Science Laboratory will be seeking clues to the planetary puzzle about life on Mars, the Curiosity rover is one of the best-outfitted chemistry missions ever. Scientists say Curiosity is the next best thing to launching a team of trained chemists to Mars’ surface.

“The Mars Science Laboratory mission has the goal of understanding whether its landing site on Mars was ever a habitable environment, a place that could have supported microbial life,” says MSL Deputy Project Scientist, Ashwin Vasavada, who provides a look “under the hood” in this informative video from the American Chemical Society.

“Curiosity is really a geochemical experiment, and a whole laboratory of chemical equipment is on the rover,” says Vasavada. “It will drill into rocks, and analyze material from those rocks with sophisticated instruments.”

Curiosity will drive around the landing site at Gale Crater and sample the soil, layer by layer, to piece together the history of Mars, trying to determine if and when the planet went from a wetter, warmer world to its current cold and dry conditions.

The payload includes mast-mounted instruments to survey the surroundings and assess potential sampling targets from a distance, and there are also instruments on Curiosity’s robotic arm for close-up inspections. Laboratory instruments inside the rover will analyze samples from rocks, soils and the atmosphere.

The two instruments on the mast are a high-definition imaging system, and a laser-equipped, spectrum-reading camera called ChemCam that can hit a rock with a special laser beam, and using Laser Induced Breakdown Spectroscopy, can observe the light emitted from the laser’s spark and analyze it with the spectrometer to understand the chemical composition of the soil and rock on Mars.

The tools on the turret at the end of Curiosity’s 2.1-meter-long (7-foot-long) robotic arm include a radiation-emitting instrument that reads X-ray clues to targets’ composition and a magnifying-lens camera. The arm can deliver soil and powdered-rock samples to an instrument that uses X-ray analysis to identify minerals in the sample and to an instrument that uses three laboratory methods for assessing carbon compounds and other chemicals important to life and indicative of past and present processes.

The three methods are an evolved gas experiment, which uses a mass spectrometer to look for potential long chain organic molecules on Mars; CheMin, an X-ray diffraction experiment to determine mineralogy; and an Alpha Particle X-Ray Spectrometer (APXS) on Curiosity’s robotic arm, like its predecessors on the arms of all previous Mars rovers, will identify chemical elements in rocks and soils.

In total Curiosity has 10 different instruments on board the roving laboratory, and test results from these instruments will pave the way for future Mars missions, and may provide insight in the search for life on other planets.

Image caption: Artist depiction of the Curiosity rover on Mars. Credit: NASA

Sources: NASA, ACS

Posted on by Nancy Atkinson

What Will Curiosity’s “View” Be as it Approaches the Red Planet?

Curiosity made a risky landing that was partly made possible from learning from mistakes, according to a NASA official. Credit: NASA

Imagine if you were tucked away inside the Mars Science Laboratory backshell, just like the Curiosity rover. What would you see as you approached Mars? Bill Dunford from Riding With Robots on the High Frontier wanted to know the same thing. “I was wondering what Mars would look like if you could physically ride along,” he wrote. “If you were somehow onboard the spacecraft that’s carrying the rover, and you had a window to look through, what would you be able to see?”

To find out, he took advantage of NASA’s Eyes on the Solar System website. This amazing tool creates realistic simulated views based on real data, and allows you to travel to any planet, moon or spacecraft across time and space, in 3D and in real time. It is absolutely awesome and very fun to play with! Bill created the video above by using Eyes on the Solar System, which provides a great look at the view approaching Mars.

Then, Bill also used Eyes on the Solar System to follow Curiosity down to the surface and view the landing, which, if all goes well on 10:31 p.m. PDT on August 5th (05:31 UTC on Aug. 6), should look something like this:

Of course, no one will be there on Mars to see it happen, and we won’t know for at least 14 minutes after the fact if it happened successfully. So consider yourself lucky to have this sneak peak!

See more screenshots and information at Riding With Robots, and check out Bill’s one-page “Cheat Sheet” which provides a quick guide to the mission and the landing, with links to all sorts of information.

Posted on by Nancy Atkinson

Join Universe Today’s Live Webcast of the Curiosity Rover Landing

The NASA team threw in every bit of data they could to model the Mars Curiosity landing. Credit: NASA

Want to be part of the Mars Science Laboratory landing event and join thousands of others in watching it live? Universe Today is teaming up with Google, the SETI Institute and CosmoQuest to provide unprecedented, live coverage of the historic landing of the Curiosity rover on Mars. Starting at 8 pm PDT on August 5th (03:00 UTC August 6th) a live, 4-hour webcast will highlight the landing of the car-sized robotic roving laboratory. During the webcast, via a Google+ Hangout on Air, scientists, engineers and other experts will provide unique insight into the rover and the landing, and viewers will have the chance to interact and ask questions.

Hosted by Universe Today’s Fraser Cain, along with Dr. Pamela Gay and Dr. Phil Plait, the webcast will feature interviews with special guests, a live video feed from NASA of the landing, and live coverage from the Jet Propulsion Laboratory (JPL) and the Planetary Society’s PlanetFest by reporters Scott Lewis and Amy Shira Teitel, who will be on location to interview members of the MSL team, as well as and other scientists and NASA officials that will be on hand.

The landing itself is scheduled for 10:31 p.m. PDT Aug. 5 (05:31 UTC Aug. 6). Curiosity’s landing will mark the start of a two-year mission to investigate whether one of the most intriguing places on Mars ever has offered an environment favorable for microbial life.

As you know, Universe Today, in collaboration with CosmoQuest hosts weekly virtual star parties and science conversations via Google+ Hangouts on Air, and for the Transit of Venus, hosted a special Hangout event that was watched by nearly 7,000 viewers.

Those interested in watching Universe Today’s MSL landing event can find more information and also sign up to “attend” the Hangout on Air here.

The feed will also be available on Universe Today’s YouTube live feed.

You can also follow the action via Twitter from Universe Today (@universetoday) and CosmoQuest (@CosmoQuestX ) by using the hashtag #marshangout

We also have the event listed on Facebook.

Posted on by Ken Kremer

Curiosity’s Grand Entrance with Star Trek’s William Shatner and Wil Wheaton – Video Duet

Video Caption: Star Trek’s Captain Kirk, actor William Shatner, guides viewers through the video titled, “Grand Entrance,” showing NASA’s Curiosity Mars Science Lab mission from atmospheroic entry through descent, and after landing on the Red Planet on August 6 2012.

As NASA engineers and scientists make final preparations for the Red Planet landing of NASA’s most difficult planetary science mission to date – the Curiosity Mars Science Lab – inside Gale Crater on the night of August 5/6, Star Trek actors William Shatner and Wil Wheaton lend their voices to a pair of new mission videos titled “Grand Entrance”

The video duet describes the thrilling story of how Curiosity will touch down on Mars and guides viewers through the nail biting “7 Minutes of Terror” – from entry into the Martian atmosphere at over 13,000 MPH and then how the rover must slow down through descent, set down for a soft and safe landing and ultimately how Curiosity will search for signs of life. Continue reading “Curiosity’s Grand Entrance with Star Trek’s William Shatner and Wil Wheaton – Video Duet”

Posted on by Elizabeth Howell

The Most Epic Curiosity Countdown Clock

A screenshot from "Get Curious" website.

If you can’t get to a Mars Science Lab landing party, one website aims to bring the party to you.

Explore Mars, a not-for-profit, has joined up with several space-faring organizations and firms to create Get Curious. It’s a one-stop shop for all things concerning Curiosity, the centerpiece of MSL.

“Curiosity will rock the world” proclaims an all-caps banner at the top of the website as an animated picture of Curiosity dangles beneath a jetting shell.

Below the banner sits a large clock, counting down the seconds until Curiosity’s wheels touch Martian ground.

You can simulate the touchdown on this website simply by scrolling down – the animated Curiosity picture slowly lowers to a picture of what looks to be Martian rocks and soil. (The animation actually falls past the surface instead of touching down, but you get the idea.)

Explore Mars’ aim is to drum up interest for its Human-to-Mars Summit next year. Delegates, including several senior NASA scientists involved with MSL, will gather in Washington, D.C. April 6-8, 2013 to discuss how to get humans on the Red Planet by 2030. The George Washington University Space Policy Institute is a co-sponsor of the conference.

“The mission of Explore Mars is to make humans a multi-planet species,” the Get Curious website states.

“Our programs are aimed at making that happen within the next 20 years, while being safe, well-planned and relatively comfortable for the humans we send to Mars. To accomplish this, Explore Mars runs technical challenges to stimulate the development and/or improvement of technologies that will make human Mars missions more efficient and feasible.”

Included on Get Curious is a list of MSL landing parties (compiled with help from Yuri’s Night), a summary of Curiosity’s objectives, and pictures and videos of the mission.

Additionally, several cities – such as Detroit, Houston and Atlanta – agreed to display gigantic simulated Mars rocks between July 26 and Aug. 9 (dates vary by city) to promote Explore Mars and the website.

The list of participating entities in Get Curious includes Aerojet, Explore Mars, National Geographic, Phillips & Co., United Launch Alliance and Yuri’s Night.

The car-sized Curiosity is expected to reach Mars Aug. 6. It will dig for signs of habitable conditions in Gale Crater.

Lead image caption: A screenshot from Get Curious website.

Elizabeth Howell (M.Sc. Space Studies ’12) is a contributing editor for SpaceRef and award-winning space freelance journalist living in Ottawa, Canada. Her work has appeared in publications such as SPACE.com, Air & Space Smithsonian, Physics Today, the Globe and Mail, the Canadian Broadcasting Corp.,  CTV and the Ottawa Business Journal.

Posted on by Ken Kremer

T Minus 9 Days – Mars Orbiters Now in Place to Relay Critical Curiosity Landing Signals

Image Caption: NASA’s Mars Odyssey will relay near real time signals of this artist’s concept depicting the moment that NASA’s Curiosity rover touches down onto the Martian surface. NASA’s Mars Reconnaissance Orbiter (MRO) and ESA’s Mars Express (MEX) orbiter will also record signals from Curiosity for later playback, not in real time. Credit: NASA

It’s now just T minus 9 Days to the most difficult and complex Planetary science mission NASA has ever attempted ! The potential payoff is huge – Curiosity will search for signs of Martian life

The key NASA orbiter at Mars required to transmit radio signals of a near real-time confirmation of the August 5/6 Sunday night landing of NASA’s car sized Curiosity Mars Science Lab (MSL) rover is now successfully in place, and just in the nick of time, following a successful thruster firing on July 24.

Odyssey will transmit the key signals from Curiosity as she plunges into the Martian atmosphere at over 13,000 MPH (21,000 KPH) to begin the harrowing “7 Minutes of Terror” known as “Entry, Descent and Landing” or EDL – all of which is preprogrammed !

Engines aboard NASA’s long lived Mars Odyssey spacecraft fired for about 6 seconds to adjust the orbiters location about 6 minutes ahead in its orbit. This will allow Odyssey to provide a prompt confirmation of Curiosity’s landing inside Gale crater at about 1:31 a.m. EDT (531 GMT) early on Aug. 6 (10:31 p.m. PDT on Aug. 5) – as NASA had originally planned.

Without the orbital nudge, Odyssey would have arrived over the landing site about 2 minutes after Curiosity landed and the signals from Curiosity would have been delayed.

A monkey wrench was recently thrown into NASA relay signal plans when Odyssey unexpectedly went into safe mode on July 11 and engineers weren’t certain how long recovery operations would take.

“Information we are receiving indicates the maneuver has completed as planned,” said Mars Odyssey Project Manager Gaylon McSmith of NASA’s Jet Propulsion Laboratory, Pasadena, Calif. “Odyssey has been working at Mars longer than any other spacecraft, so it is appropriate that it has a special role in supporting the newest arrival.”

Odyssey has been in orbit at Mars since 2001 conducting orbital science investigations.

Read my review article on Odyssey’s science discoveries – here

Odyssey serves as the primary communications relay for NASA’s other recent surface explorers – Opportunity, Spirit and Phoenix. Opportunity recently passed 3000 Sols of continuous operations.

Two other Mars orbiters, NASA’s Mars Reconnaissance Orbiter and the European Space Agency’s Mars Express, also will be in position to receive radio transmissions from the Mars Science Laboratory during its descent. However, they will be recording information for later playback, not relaying it immediately, as only Odyssey can.

“We began optimising our orbit several months ago, so that Mars Express will have an orbit that is properly “phased” and provides good visibility of MSL’s planned trajectory,” says Michel Denis, Mars Express Spacecraft Operations Manager.

Mars Express has been orbiting the planet since December 2003.


Image Caption: Mars Express supports Curiosity MSL. Credit: ESA

“NASA supported the arrival of Mars Express at Mars in 2003, and, in the past few years, we have relayed data from the rovers Spirit and Opportunity,” says ESA’s Manfred Warhaut, Head of Mission Operations.

“Mars Express also tracked the descent of NASA’s Phoenix lander in 2008 and we routinely share our deep space networks.

“Technical and scientific cooperation at Mars between ESA and NASA is a long-standing and mutually beneficial activity that helps us both to reduce risk and increase the return of scientific results.”

Watch NASA TV online for live coverage of Curiosity landing: mars.jpl.nasa.gov or www.nasa.gov

Ken Kremer