The streaked and stained surface of Phobos. (Image: NASA)
After seeing Phobos imaged from the surface of the Red Planet by Mars Curiosity, now we’re lucky to get a close-up treat: here’s a video showing Mars Express images of the Martian moon over the last 10 years. The images reveal mysterious grooves running through the small moon, which is 13.5-miles (22 kilometers) in diameter, and scientists still aren’t sure what’s going on.
“The moon’s parallel sets of grooves are perhaps the most striking feature, along with the giant 9 km-wide Stickney impact crater that dominates one face,” the European Space Agency wrote.
“The origin of the moon’s grooves is a subject of much debate. One idea assumes that the crater chains are associated with impact events on the moon itself. Another idea suggests they result from Phobos moving through streams of debris thrown up from impacts 6000 km away on the surface of Mars, with each ‘family’ of grooves corresponding to a different impact event.”
NASA astronaut Karen Nyberg created this mini-quilt based on a drawing her son, Jack, created. Picture posted in December 2013. Credit: Karen Nyberg/Pinterest
Kids’ drawings are the best, as astronaut Karen Nyberg proudly shows in her latest mini-quilt piece. The astronaut — who just spent six months in orbit during Expedition 36/37 — is also a prolific quilter and drew inspiration from her son, three-year-old Jack, in this quilt posted on Pinterest. The drawing shows how quickly Jack changed during her mission, she wrote.
“When I left for space station in May, my son was drawing only lines, circles, and squiggles. When I returned in November, he was drawing people. He told me this picture is ‘Jack playing in the grass on a sunny day.’ ”
We’re guessing Nyberg is having an easier time quilting now that she isn’t working in microgravity anymore. The video below explains the challenges she had doing quilting in orbit and making sure that sharp pins didn’t just float away and cause problems on station.
Nyberg is married to astronaut Doug Hurley (who piloted the final shuttle mission, among other things) and as the Houston Chronicle’s Eric Berger points out in November, the parents have lots of experience helping each other out with child care during training and missions.
Portion of 1st panorama around Chang’e-3 landing site after China’s Yutu rover drove onto the Moon’s surface on Dec. 15, 2013. The images were taken by Chang’e-3 lander following Dec. 14 touchdown. Panoramic view was created from screen shots of a news video assembled into a mosaic. Credit: CNSA/CCTV/screenshot mosaics & processing by Marco Di Lorenzo/Ken Kremer See the complete panorama below Story updated
Portion of 1st panorama around Chang’e-3 landing site after China’s Yutu rover drove onto the Moon’s surface on Dec. 15, 2013. The images were taken by Chang’e-3 lander following Dec. 14 touchdown. Panoramic view was created from screen shots of a news video assembled into a mosaic. Credit: CNSA/CCTV/screenshot mosaics & processing by Marco Di Lorenzo/Ken Kremer
See the complete panorama below Story updated[/caption]
China’s inaugural Chang’e-3 lunar lander has snapped the missions first panoramic view of the touchdown spot at Mare Imbrium.
To make it easier to see and sense ‘the new view from the Moon’, we have created screen shots from the rather low resolution TV broadcast and assembled them into a photo mosaic of the landing site – see above and below mosaics by Marco Di Lorenzo and Ken Kremer.
The Chang’e-3 mothership imaged the stark lunar terrain surrounding the spacecraft after the ‘Yutu’ rover perched atop successfully drove all six wheels onto the moon’s surface on Dec. 15, barely 7 hours after the momentous landing on Dec. 14.
The individual images were taken by three cameras positioned around the robotic lander.
1st panorama around Chang’e-3 landing site after China’s Yutu rover drove onto the Moon’s surface on Dec. 15, 2013. The images were taken by Chang’e-3 lander following Dec. 14 touchdown. Panoramic view was created from screen shots of a news video assembled into a mosaic. Credit: CNSA/CCTV/screenshot mosaics & processing by Marco Di Lorenzo/Ken Kremer
Chinese scientists then pieced them together to form the lander’s first panoramic view of the lunar surface, according to CCTV.
“This picture is made of 60 pictures taken 3 times by the rover. The rover used three angles: vertical, 15 degrees tilted up, and 15 degrees down…so that we get an even farther view,” said Liu Enhai, Designer in Chief, Chang’E-3 Probe System, in a CCTV interview
The panoramic view shows ‘Yutu’ and its wheel tracks cutting a semi circular path at least several centimeters deep into the loose lunar regolith at the landing site at Mare Imbrium, located near the Bay of Rainbows.
After making its soft landing, the Chang’e-3’s lander took pictures around its landing spot. Credit: CCTV
A significant sized crater, several meters wide, is seen off to the left of Yutu and located only about 10 meters away from the Chang’e-3 lander.
Several more craters are visible in the pockmarked surface around the lander.
Mission leaders purposely equipped the lander with terrain recognition radar and software so that it could steer clear of hazards like craters and large boulders and find a safe spot to land.
Wheel tracks from Yutu moon rover. Credit: CNSA/CCTV
Indeed just prior to touchdown, the lander actually hovered at an altitude of 100 meters for about 20 seconds to avoid the craters and rock fields which could have doomed the mission in its final moments.
See the dramatic Chang’e-3 landing video in my earlier report – here.
Here is our annotated screen shot from the landing video showing the eventual landing site in the distance:
This screen shot from one photo of many of the moons surface snapped by the on-board descent imaging camera of the Chinese lunar probe Chang’e-3 on Dec. 14, 2013 shows the probe approaching the Montes Recti mountain ridge and approximate location of the landing site. This marks the first time that China has sent a spacecraft to soft land on the surface of an extraterrestrial body. Credit: Xinhua/CCTV/post processing and annotations Marco Di Lorenzo /Ken Kremer.
“The rover reached the point of X after it went down from the lander, then it established contact with the ground. Then it went to point A, where the rover and lander took pictures of each other. Then it reached point B, where it’s standing now.” said Liu Jianjun, Deputy Chief Designer, Chang’E-3 Ground System, to CCTV.
China thus became only the 3rd country in the world to successfully soft land a spacecraft on Earth’s nearest neighbor after the United States and the Soviet Union.
Chinese President Xi Jinping and space agency leaders have hailed the Chang’e-3 mission as a complete success for China.
The Yutu rover, which translates as ‘Jade Rabbit’ will use its science instruments to survey the moon’s geological structure and composition on a minimum three month mission to locate the moon’s natural resources for use by potential future Chinese astronauts.
The lander will conduct in-situ exploration at the landing site for at least one year, say Chinese officials.
Hopefully, China will quickly start releasing full resolution imagery and video taken by the Chang’e-3 lander and Yutu rover at a dedicated mission website, like NASA does, rather than issuing photos of imagery from projection screens and televisions – so that we all can grasp the full beauty of their tremendous lunar feat.
Stay tuned here for Ken’s continuing Chang’e-3, LADEE, MAVEN, MOM, Mars rover and more news.
Ken Kremer Landing site of Chinese lunar probe Chang’e-3 on Dec. 14, 2013. [/caption]
This broken ammonia pump is visible through the helmet camera of NASA astronaut Rick Mastracchio, who performed a spacewalk Dec. 21 to begin replacing the tank along with Mike Hopkins. Credit: NASA
The ghosts of spacewalks past did not haunt the quick-working pair of astronauts who began replacing a faulty ammonia pump on the International Space Station today (Dec. 21).
Unlike a difficult spacewalk to do a similar repair in 2010, NASA astronauts Rick Mastracchio and Mike Hopkins were so far ahead of schedule that they began doing tasks scheduled for the second in their expected trio of spacewalks.
In better news yet for the spacewalkers, a water leak in Hopkins’ spacesuit this past July — one that sent astronauts scrambling back to the airlock for safety — did not happen again, showing that the part replacement NASA directed had worked. An unrelated water issue in Mastracchio’s suit, however, made agency officials decide to delay the next spacewalk one day to Dec. 24.
The pump replacement is needed to put the space station at full fighting weight. Since Dec. 11, science experiments and other non-critical systems have been offline since a valve in the pump broke. While the astronauts are in no immediate danger, one of their two cooling loops is shut down and there is not a big margin of safety if the other loop fails.
Since this is NASA’s first spacewalk since the leaky suit was last used, the agency emphasized two new measures it has to protect the astronauts if another leak occurs. The first is a new helmet absorption pad (HAP) to soak up any water in the helmet. The second is a pipe — a snorkel — that would let astronauts breathe air from another part of the suit, if required.
But with every “HAP check” that CapCom and astronaut Doug Wheelock called up to the astronauts today, they reported that the suits were dry and everything was fine. The new water issue happened after the spacewalk, while the astronauts were repressurizing the airlock. In a statement, NASA said water could have entered Mastracchio’s suit sublimator and decided to switch him to a backup suit as a precaution.
The spacewalk tasks themselves, however, went far more swiftly than problems Wheelock experienced in 2010, such as when an ammonia line on the pump refused to unhook as required and caused a lengthy delay. NASA made some changes (such as lowering the pressure on the lines, as Wheelock told Universe Today), and this time, Mastracchio powered through the line and electrical removals. The astronauts quickly moved 1.5 hours of schedule and then beyond. A few stray ammonia flakes hit Mastracchio’s suit, but not enough to cause concerns about contamination since the traces of substance baked off in the sun as he worked.
“I don’t know if you believe in miracles, but I got it on the first try,” Mastracchio radioed early in the spacewalk as he got a tricky part of a Canadian robotic arm foot restraint threaded. Mastracchio rode the arm for much of the spacewalk while Hopkins was the “free floating” colleague hovering and doing other tasks nearby.
NASA astronaut Rick Mastracchio (right) pulls an 800-pound ammonia pump module out of its spot on the space station Dec. 21, 2013. At left is fellow NASA astronaut and Expedition 38 member Mike Hopkins. Credit: NASA TV
The most spectacular television shots occurred towards the end of the five-hour, 28-minute spacewalk when Mastracchio carefully wrestled the 800-pound ammonia pump module out of its spot on the space station while riding aboard Canadarm2. (Controlling the arm was Japanese astronaut Koichi Wakata, guided by CapCom and fellow Japanese astronaut Aki Hoshide on the ground.)
After he stowed the module, Mission Control gave the astronauts the go-ahead to put in the spare. Mastracchio, however, said he felt it was best for the astronauts to leave it for next time. While the pair have three spacewalks (including today’s) slated to finish the task, it’s possible they could wrap it up in two — but only if things go as smoothly as this time.
The next spacewalk will take place Dec. 24 at 7:10 a.m. EST (12:10 p.m. UTC), and will be available on NASA Television. We’ll keep you up to speed as the next spacewalk occurs. Today’s excursion was Mastracchio’s seventh and Hopkins’ first.
NASA astronauts Rick Mastracchio and Mike Hopkins of Expedition 38 worked outside for more than five hours Dec. 21, 2013 to begin replacing a faulty ammonia pump on the International Space Station. Credit: NASA TV
NASA astronaut Rick Mastracchio during a space station spacewalk on STS-131 in 2010. Credit: NASA
There’s a cooling problem on station, and two astronauts are ready to head outside to fix it. NASA astronauts Rick Mastracchio (a six-time spacewalker) and Mike Hopkins (a rookie) are expected to spend 6.5 hours “outside” starting at 7:10 a.m. EST (12:10 p.m. UTC) on Saturday. On robotics will be Japanese astronaut Koichi Wakata, who has operated every bit of robotics currently on station.
Click to watch Expedition 38’s crew action live above. (If for some reason the stream is not working, an alternate link is available here.) We’ll have full coverage of the spacewalk after it happens, too.
For a walkthrough of what’s going to happen, NASA handily provided a video that you can see below the jump. We also have links to all of our coverage so far.
However, the station is entering a time when there will be a lot of sun shining on it, making dockings and spacewalks difficult. To be prudent, NASA decided to do a spacewalk now and replace the pump. To keep the astronauts safe if another spacesuit leak happens again, the agency has introduced soaker pads and snorkels to the spacesuits.
Here’s what’s going to happen during the three spacewalks that are scheduled for Saturday, Monday (Dec. 23) and if necessary, Wednesday (Dec. 25), according to lead U.S. Spacewalk Officer Allison Bolinger:
This screen shot from one photo of many of the moons surface snapped by the on-board descent imaging camera of the Chinese lunar probe Chang’e-3 on Dec. 14, 2013 shows the probe approaching the Montes Recti mountain ridge and approximate location of the landing site. This marks the first time that China has sent a spacecraft to soft land on the surface of an extraterrestrial body. Credit: Xinhua/CCTV/post processing and annotations Marco Di Lorenzo /Ken Kremer. See the entire stunning Chang’e-3 lunar landing video – below
This screen shot from one photo of many of the moons surface snapped by the on-board descent imaging camera of the Chinese lunar probe Chang’e-3 on Dec. 14, 2013 shows the probe approaching the Montes Recti mountain ridge and approximate location of the landing site in Mare Imbrium. This marks the first time that China has sent a spacecraft to soft land on the surface of an extraterrestrial body. Image and video rotated 180 degrees.
Credit: Xinhua/CCTV/post processing and annotations Marco Di Lorenzo /Ken Kremer See the entire stunning Chang’e-3 lunar landing video – below
Story updated
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China accomplished a major technological and scientific feat when the country’s ambitious Chang’e-3 robotic spacecraft successfully soft landed on the Moon on Dec. 14 – on their very first attempt to conduct a landing on an extraterrestrial body.
Along the way the descent imaging camera aboard the Chang’e-3 lander was furiously snapping photos during the last minutes of the computer guided descent.
For a firsthand look at all the thrilling action, be sure to check out the stunning landing video, below, which gives an astronauts eye view of the dramatic descent and touchdown by China’s inaugural lunar lander and rover mission.
The video was produced from a compilation of descent camera imagery. The version here has been rotated 180 degrees – so you don’t have to flip yourself over to enjoy the ride.
And it truly harkens back to the glory days of NASA’s manned Apollo lunar landing program of the 1960’s and 1970’s.
This is one photo from many of the moons surface snapped by the on-board descent imaging camera of the Chinese lunar probe Chang’e-3 on Dec. 14, 2013. This marks the first time that China has sent a spacecraft to soft land on the surface of an extraterrestrial body. Credit: Xinhua/CCTV
See the entire stunning Chang’e-3 lunar landing video – herein
The dramatic Chang’e-3 soft landing took place at Mare Imbrium at 8:11 am EST, 9:11 p.m. Beijing local time, 1311 GMT, which is to the east of the announced landing site on the lava filled plains of the Bay of Rainbows, or Sinus Iridum region.
The precise landing coordinates were 44.1260°N and 19.5014°W -located below the Montes Recti mountain ridge and about 40 kilometers south of the 6 kilometer diameter crater known as Laplace F – see image below.
Landing site of Chinese lunar probe Chang’e-3 on Dec. 14, 2013.
The video begins as Chang’e-3 is approaching the Montes Recti mountain ridge which is about 90 km in length. Its peaks rise to nearly 2 km.
Chang’e-3 carried out the rocket powered descent to the Moon’s surface by firing the landing thrusters starting at the altitude of 15 km (9 mi) for a soft landing targeted to a preselected area in Mare Imbrium.
The vehicles thrusters then fire to pivot the lander towards the surface at about the 2:40 minute mark when it’s at an altitude of roughly 3 km.
Infographic shows the process of the soft-landing on the moon of China’s lunar probe Chang’e-3 on Dec. 14, 2013. Credit: SASTIND/Xinhua /Zheng Yue
The powered descent was autonomous and preprogrammed and controlled by the probe itself, not by mission controllers on Earth stationed at the Beijing Aerospace Control Center (BACC) in Beijing.
Altogether it took about 12 minutes using the variable thrust engine which can continuously vary its thrust power between 1,500 to 7,500 newtons.
The variable thrust engine enabled Chang’e-3 to reduce its deceleration as it approached the moons rugged surface.
Photo taken on Dec. 14, 2013 shows the landing spot of lunar probe Chang’e-3 indicated on the screen of the Beijing Aerospace Control Center in Beijing, capital of China. Credit: Xinhua/Li
The 1200 kg lander was equipped with unprecedented terrain recognition equipment and software to hover above the landing site and confirm it was safe before proceeding.
This enabled the craft to avoid hazardous rock and boulder fields as well as craters in the pockmarked terrain that could spell catastrophe even in the final seconds before touchdown, if the vehicle were to land directly on top of them.
The descent engine continued firing to lower the lander until it was hovering some 100 meters above the lunar surface – at about the 5:10 minute mark.
Chang’e-3 hovered 100m high for 20 seconds before committing to land. This allows the on-board computer to make sure it doesn’t land in a crater or an uneven place. Credit: China Space
After hovering for about 20 seconds and determining it was safe to proceed, the lander descended further to about 3 meters. The engine then cut off and the lander free fell the remaining distance. The impact was cushioned by shock absorbers.
There is a noticeable dust cloud visible on impact as the Chang’e-3 mothership touched down atop the plains of Mare Imbrium.
Chang’e-3 lander imaged by the rover Yutu on the moon on Dec. 15, 2013. Note landing ramp at bottom. Credit: CCTV
Barely 7 hours later, China’s first ever lunar rover ‘Yutu’ rolled majestically down a pair of ramps and onto the Moon’s soil on Sunday, Dec. 15 at 4:35 a.m. Beijing local time.
The six wheeled ‘Yutu’, or Jade Rabbit, rover drove straight off the ramps and sped right into the history books as it left a noticeably deep pair of tire tracks behind in the loose lunar dirt.
China’s first lunar rover separates from Chang’e-3 moon lander early Dec. 15, 2013. Screenshot taken from the screen of the Beijing Aerospace Control Center in Beijing. Credit: Xinhua/post processing by Marco Di Lorenzo/Ken Kremer
The stunning feat was broadcast on China’s state run CCTV.
China thus became only the 3rd country in the world to successfully soft land a spacecraft on Earth’s nearest neighbor after the United States and the Soviet Union.
It’s been nearly four decades since the prior lunar landing was accomplished by the Soviet Union’s Luna 24 sample return spacecraft back in 1976.
America’s last visit to the Moon’s surface occurred with the manned Apollo 17 landing mission – crewed by astronauts Gene Cernan and Harrison ‘Jack’ Schmitt , who coincidentally ascended from the lunar soil on Dec. 14, 1972 – exactly 41 years ago.
China’s Chang’e-3 probe joins NASA’s newly arrived LADEE lunar probe which entered lunar orbit on Oct. 6 following a spectacular night time blastoff from NASA’s Wallops Flight Facility in Virginia.
Stay tuned here for Ken’s continuing Chang’e-3, LADEE, MAVEN, MOM, Mars rover and more news.
Ken Kremer Moon map showing landing site of Chinese lunar probe Chang’e-3 on Dec. 14, 2013 below Montes Recti in Mare Imbrium beside Sinus Iridum, or the Bay of Rainbows . Credit: China Space[/caption]
Image shows the trajectory of the lunar probe Chang’e-3 approaching the landing site on Dec. 14.
NASA astronaut Doug Wheelock, who was commander of Expedition 25. This 2010 picture of him also shows the Sabatier system that extracts drinkable water from the International Space Station's atmosphere. Credit: NASA
When you learned to drive a car for the first time, remember how comforting it was to have an experienced driver beside you, able to anticipate the hazards and keep you on schedule?
That’s surely how the Expedition 38 crew feels about one of the voices “on the line” as two astronauts prepare to venture outside to replace a crippled ammonia pump. One of the “CapComs” or people communicating with the crew on Saturday, Monday and Wednesday will be astronaut Doug Wheelock — who just happens to be known for co-replacing a broken ammonia tank himself in 2010. (The other CapCom is Japanese astronaut Aki Hoshide, who will chat through robotic procedures with Koichi Wakata).
Wheelock is the visible edge of hundreds — likely thousands — of people working feverishly at NASA and its international partners this past week to get the spacewalks ready through pool simulations, a virtual reality lab and other means. Several backup and non-critical space station systems are offline because of that pump, which has to regulate temperatures properly for vital electronics to work.
“I am their choreographer,” Wheelock told Universe Today of his plan for the astronauts. While spacewalkers Mike Hopkins and Rick Mastracchio already know what they are supposed to do when, Wheelock said he will be “their eyes and ears on the timeline.” If something needs to be stopped or changed, he’ll help them figure out what to do next.
NASA astronaut Doug Wheelock anchored to Canadarm2 during an August 2010 spacewalk. He and Tracy Caldwell Dyson ventured outside three times during Expedition 24 to swap out and replace a broken ammonia pump. Credit: NASA
Wheelock and fellow astronaut Tracy Caldwell Dyson had to spring into action themselves in August 2010. A pump in the same location broke, forcing space station systems offline and requiring them to go outside a few days later. With astronaut Shannon Walker piloting Canadarm2, the astronauts accomplished their tasks in three spacewalks — but encountered obstacles along the way.
During the first spacewalk, as Wheelock disconnected lines from the broken pump, he not only faced a pipe that wouldn’t let go, but a shower of ammonia snowflakes. That was “what got me on the EVA [extra-vehicular activity],” he recalled. That’s why NASA plans to lower the line pressure on the cooling system before the astronauts head outside this time. Normally the lines are pressurized at 360 pounds per square inch, but they’ll be lowered to 120 psi through commands from the ground.
Other “lessons learned” are more recent. Italian astronaut Luca Parmitano was wearing a NASA spacesuit in July when he experienced a water leak in his helmet, putting him at risk and terminating the spacewalk early. This will be the first spacewalk since that time. NASA believes it has replaced the part of the suit that failed, but the agency has new backups in place. Hopkins and Mastracchio will have soaker pads in their helmets as well as a “snorkel”-like device, or tube that will let them breathe oxygen from a different part of the suit if water flows into the helmet again.
Allison Bolinger, NASA’s lead U.S. spacewalk officer, holds up a snorkel-like device that astronauts began using in spacesuits in December 2013. The pipe (modified from spacesuit parts) is supposed to be a backup if a helmet fills with water, as what occurred during a July 2013 spacewalk. Credit: NASA (YouTube/screenshot)
So what are some key parts of the spacewalks to look for? Wheelock identified a few spots.
‘HAP’ check. That soaker pad is called a “helmet absorption pad”, and as a matter of course the astronauts will be asked to verify that the pad is not wet at the same time that they also check their gloves for tears (another lesson learned from a past spacewalk.) So you will hear Wheelock calling “HAP check” from time to time to the crew.
Unlatching and latching the ammonia connectors on the pumps. Because this is when leaks are most likely to occur — posing a risk to Mastracchio, who is performing the work — Wheelock is going to do a “challenge and response” procedure. He will read up the step, the astronaut will verify it and will do the work. There will be “a lot more chatter on the [voice] loop” during those times, Wheelock said, with everyone on the ground watching through Mastracchio’s head camera feed (visible at the front of the room) to see what is happening. “There will be a lot of people standing in Mission Control at that point,” he joked, himself included.
Leak procedures. If ammonia does start to shower out, Mastracchio will quickly close the valve and wait a few minutes as it could be just residual ammonia in the line. If that doesn’t work out, Mastracchio is trained on a procedure to attach a device to the front end of the connector and move a lever that prevents a cavity in the line from filling with ammonia. Then he can open the valve again, bleed out the ammonia that’s left over and keep going.
NASA astronaut Rick Mastracchio inspects two spacesuits to be used during spacewalks in December 2013. The spacewalks were to remove and replace a faulty ammonia pump. Credit: NASA TV
Decontamination procedures. The ammonia makes a distinctive “ping” when it hits the helmet, says Wheelock (who yes, heard that happen himself.) You can also see ammonia on the suit, he said, as it looks a bit like candle wax and obscures the stitching. All of which to say, NASA has procedures in place if the agency suspects or can confirm large amounts of ammonia got on Mastracchio’s suit. (Small amounts would essentially fleck off in the sun.) Hopkins, who will be out of the line of fire, can do a thorough inspection of Mastracchio and scrape off any ammonia with a warm metal tool — without hurting the suit underneath. The astronauts could also do a “bakeout” in the airlock — 30 minutes if suspected, an hour if confirmed — where they will sit with the hatch open and wait for any ammonia to sublimate off the suit. Once they close the hatch, the astronauts can verify if the ammonia is gone using Drager tubes, which have gold crystals inside that turn “purpleish blue” in the presence of ammonia, Wheelock said.
Margin calls. Because NASA needs to make sure the astronauts have 30 to 60 minutes to decontaminate at the end of their spacewalks, officials will preserve a margin of oxygen available for the astronauts to walk through that work. So it’s possible the agency may terminate a spacewalk before all tasks are completed just because they need that bit of margin at the end.
To learn more, Wheelock has been answering questions occasionally on his Twitter account from followers, and you can read through what he posts when he finds the time. Universe Today will also cover the spacewalks (currently planned for Saturday, Monday and Wednesday) as they occur.
The Kirobo talking robot on the ISS. Credit: Toyota.
Just how human-sounding is Kirobo, the first talking robot on the station? This amusing conversation, recorded on the International Space Station and broadcast on a Toyota YouTube channel, shows a pint-sized robot that not only responds to questions, but also gestures and moves around in a scary person-like way.
As Kirobo chats with Japanese astronaut Koichi Wakata — who is excellent at deadpan, by the way — the two discussed matters such as how the Earth looks from space, the Japanese robotic arm Kibo and — right at the end — the most important difference between Kirobo and his backup, Mirata.
We don’t want to spoil the joy of the conversation for you by repeating what Kirobo says, but let’s just say there’s something special about watching a Japanese space robot make a reference to the first landing on the moon, which was hailed as a huge technological achievement when it happened in 1969.
The 13.4-inch (0.34 meter) Kirobo is sponsored by Toyota and the University of Tokyo and is supposed to be able to pick up on the facial expressions of crewmates. The robot will be working closely with Wakata during Expedition 38 and then Expedition 39, when Wakata assumes command of station.
One goal is to see how well humans and semi-autonomous robots can work together in space. To see Kirobo’s first words from station, check out our past story from September.
Chris Hadfield in the Cupola of the ISS. Credit: NASA
And we have liftoff … for a social media sensation! Canadian astronaut Chris Hadfield rocketed into orbit a year ago today (Dec. 19, 2012) accompanied by NASA astronaut Tom Marshburn and Russian cosmonaut Roman Romanenko.
Hadfield was a part of the Expedition 34 crew, then took command of the station during Expedition 35 in early 2013. While running an extremely productive science mission, he did tons of public outreach, ranging from singing to humorous space-y how-to videos to chatting with numerous celebrities before landing in May.
The Canadian Space Agency invited folks on Twitter to share their reflections under the hashtag #hadfield1yr, which is already producing a lot of thoughtful responses (a few of which you can see below the jump). What was your favorite part of the mission? Feel free to share in the comments.
While Hadfield is retired as an astronaut, he remains very busy. He’s in the middle of a multi-country book tour and will begin teaching at the University of Waterloo in Ontario, Canada in fall 2014.
NASA astronaut Rick Mastracchio during a spacewalk on STS-118. Credit: NASA
When NASA astronaut Mike Hopkins steps into space for the first time this week, he will wear a spacesuit that previously sprung a water leak and forced Italian astronaut Luca Parmitano back to station in July, NASA officials said Wednesday (Dec. 18).
While at first glance this sounds like an extra bit of drama as Hopkins and Rick Mastracchio make contingency spacewalks Dec. 21, 23 and 25 to kickstart a shut-down cooling loop, NASA officials say the suit is ready to go for another trip outside because astronauts (under NASA’s direction) have made a bunch of changes to the unit.
Repurposing spacesuit parts, a new pad will be added to the back of all NASA spacesuit helmets to soak up water, should one leak again. Astronauts also velcroed a pipe into each suit — a sort of snorkel — that in the worst case, would give an astronaut with a water leak an alternate route for drawing in air.
Also, the Expedition 38 crew swapped out a fan pump separator that likely malfunctioned and caused the spacesuit leak. The cause is still under investigation, but NASA believes that a problem in the water chemistry caused contamination that plugged a tiny hole inside the water separation part of the unit. This allowed the water to escape, enter the air loop and get into the helmet.
Finally, there are new procedures in place for the astronauts themselves. They will monitor the helmet pad for fluid. NASA additionally plotted out its spacewalk procedures — which include the use of a Canadian robotic arm on station — to make sure the astronauts are always within reasonable reach of an airlock.
NASA astronauts Rick Mastracchio and Mike Hopkins will do spacewalks in December 2013 to swap out a cooling pump on the International Space Station. Credit: NASA
So here’s why the spacewalks are happening: a week ago (Dec. 11), a flow control valve inside of a pump — the pump is located outside of the station — stopped regulating ammonia temperatures inside of an external cooling loop. The loop is required to, as the name implies, cool down space station electronics. The loop got too cold, it shut down automatically, and NASA took science experiments and redundant systems offline to deal with the problem. (The main problem is NASA can’t run a heat exchanger on Node 2, which affects experiments in the U.S. Columbus laboratory and Japanese Experiment Module. No completed research has been lost to date, however.)
After figuring out that it couldn’t control the valve again, NASA shifted its attention to an isolation valve upstream. That valve is only designed to be in two positions — opened or closed — but the hardware vendor said it could be used at spots in between to regulate the ammonia flow. So software engineers created a patch to make this happen, and uploaded it to station.
Throw in another element, however: the station is about to enter what’s called an annual “high beta” period, when orbital dynamics mean the sun will be shining on it for longer periods of time than usual. (Read more technical details here.) When the angle exceeds 60 degrees, for safety reasons NASA suspends all cargo flights to station as well as spacewalks. This year, it will happen between about Dec. 30, 2013 and Jan. 9, 2014.
The International Space Station in 2010. Credit: NASA
So if NASA spent time playing with the valve and found out it couldn’t work in the long run, a couple of problems could happen. First, it would be harder to do a spacewalk to fix it.
Here’s a diagram of the pump that Mastracchio and Hopkins plan to replace:
A view of a pump module aboard the International Space Station that is used to maintain ammonia at the correct temperature in an external cooling loop. Credit: NASA
The “nominal” plan is for three spacewalks, but it could range anywhere from two to four depending on how things go. To put things simply, here’s how the spacewalks would go:
EVA 1: The pump with the broken valve would be disconnected and a spare pump (which is some distance away, but reachable using Canadarm2) would be prepped for the swap.
EVA 2: The pump with the broken valve would be removed and set aside while the spare pump is partially installed (meaning, only the bolts and electrical connections would be put in.)
EVA 3: The spare pump’s installation would be finished, and the pump with the broken valve would be stowed more permanently outside. NASA thinks that eventually, it could use that first pump again if astronauts installed a new valve on it, but that isn’t a need for the time being.
Flying Canadarm2 would be Japanese astronaut Koichi Wakata, who has operated every type of robotics currently in orbit. Mastracchio has six spacewalks under his belt already, while Hopkins will be on his first go.
If all goes to plan, NASA will not only swap out the pump, but also preserve the option for the Russians to proceed with a planned Dec. 27 spacewalk that is less urgent. In that case, the cosmonauts plan to swap out experiments, put in a foot restraint and install some cameras.
We’ll cover the spacewalks as they happen. They’re scheduled for Dec. 21, 23 and 25 at 7:10 a.m. EST (12:10 p.m. UTC) and should run about 6.5 hours each. Broadcasts will run live on NASA Television.
By the way, the pump with the problem is just three years old — astronauts had to make three spacewalks in 2010 to install it after a more severe failure. NASA characterized this situation as a more unusual failure and said this is not a symptom of an aging station at all.
Overview of the tasks that Rick Mastracchio and Mike Hopkins will perform during three spacewalks in December 2013 to remove and replace a pump with a faulty valve inside of it. The pump is required to maintain the external cooling system at the right temperature. Credit: NASA
