Earth from 93,000 feet. Long Island in the background. Credit: The 1337Arts Group
A group of MIT students have launched a low-budget satellite to near space, taking images of the curvature of Earth and the blackness of space. Their approach was to use low tech, off the shelf equipment, which included a Styrofoam beer cooler, a camera from eBay, open source software and an inexpensive helium balloon as the launch vehicle in order to do their complete mission launch for less than $150. Total cost? $148. The experience? Priceless, including getting interviewed on CNN and Fox News about their achievement. The best news for the rest of us? They’ll soon be sharing an illustrated step-by-step guide on how to launch your own low-budget satellite.
The team, led by Justin Lee and Oliver Yeh had the goal of seeing Earth from space, but didn’t have a lot of money to do it. They knew they’d have to gather all the materials for less than $150.
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Their satellite was a huge success. It reached 93,000 feet (calculated from the linear ascent rate at the beginning of the launch), took several images of Earth from space (see their gallery here) and was retrieved using an inexpensive GPS system.
They say the time lapse video above isn’t all that great because the cooler wasn’t stabilized. But the images are incredible.
Many people have launched balloons (see some of our previous articles, here and here) but this is the lowest price to space anyone has ever accomplished. The students say they hope to be an inspiration to others. The balloon falling back to Earth after bursting. Credit: 1337arts team.
Lee and Yeh caution about making sure future explorers contact the FAA about launching a balloon, and to launch from a safe place so the balloon and equipment doesn’t land in a highly populated area.
Next, they want to do it again, but add a rocket to the balloon to launch their payload even higher.
A rocket powered vehicle successfully completed the first step toward qualifying to win a $1 million prize for NASA’s Northrop Grumman Lunar Lander Challenge. Armadillo Aerospace’s “Scorpius” lander set world records for vertical landings and takeoff flights by flying up 50 meters (164 feet) into the air, maneuvering over to land on a simulated rocky lunar surface 50 meters (164 feet) away, and then rising and flying back to land where it started. The flight included a requirement of at least 180 seconds of flying time. Watch the video from the second qualifying flight here. Armadillo is the first team of three teams looking to nab the prize this year. Continue reading “Armadillo Powers Toward $1 Million Prize”
There’s nothing prettier than watching the space shuttle land. Sure, it drops like a rock, a piano, a safe; but when the vehicle makes the final turn and lines up with the runway, and then the commander sticks the landing like Rick Sturckow did tonight, it’s a work of art. If you missed the landing in real time, here’s a great video of Discovery’s landing at Edwards Air Force Base in California, at 5:53 PDT on Friday, ending the 14-day mission to the International Space Station. Continue reading “Space Shuttle Discovery Returns Home (Video)”
Artist's impression of HTV approaching ISS. Credit: JAXA
Japan successfully launched its first re-supply spacecraft to the International Space Station today. After liftoff at 17:01 GMT (12:01 CDT) from Tanegashima Space Center in southern Japan, flight controllers confirmed the HTV-1 spacecraft separated from the H-2B rocket and now is in its preliminary orbit. The flight profile has the HTV taking seven days to reach the ISS so controllers can run various tests and demonstrations on its maiden voyage before rendezvousing with the space station. Unlike previous re-supply ships that dock directly to the station, the HTV will fly to within 10 meters from the ISS on September 17, and then astronaut Nicole Stott will reach out and grapple the spacecraft with the space station’s robotic arm, Canadarm 2, and connect it to the Harmony module on the ISS.
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The new HTV spacecraft is the latest in an international fleet of cargo ships to support the space station. While capable of carrying 6.5 tons of cargo, on this first flight it is bringing up 5 tons of food, experiments and other supplies for the ISS. Unlike previous supply ships, it can haul large unpressurized experiments and equipment to remain outside the station, as well as supplies for inside the station, too. For its flight debut, the HTV-1’s external cargo drawer is filled with two experiments – one for JAXA and one for NASA – to be attached to the Kibo lab’s external porch.
The HTV weighs about 16 tons, is 9 meters (30 feet) long and 4.2 meters (14.5 feet) in diameter. Artists impression of the HTV-1 in orbit. Credit: JAXA
Another difference is that craft doesn’t have solar array wings, but has 57 solar arrays molded around the spacecraft to gather power from sunlight.
“HTV-1 is opening up new horizons for JAXA’s undertaking of human spaceflight,” said Masazumi Miyake, deputy director of JAXA’s Houston office. “I like to say that JAXA is now entering a new era.”
The success of both the HTV and the H-2B rocket will likely prove to be an important stepping stone for JAXA, as the country has ambitions of heading to the moon and Mars.
Christer Fugelsang during the third EVA of STS-128. Credit: NASA
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As the crew of the STS-128 mission pack up and prepare to get ready to undock from the International Space Station on Tuesday, it’s time to look back at the very successful mission that worked on space station construction. Here’s some of the best images of the mission.
Above, ESA astronaut Christer Fuglesang works (and waves) during the third and final EVA of the mission. Fuglesang and NASA astronaut John “Danny” Olivas installed several items and did work to prepare for the installation of Node 3, which will take place next year.
Heavy lifting in space. Credit: NASA
Here’s Fuglesang again, doing a little heavy lifting during the first EVA of the mission while anchored to the Canadarm2’s foot restraint. He’s carrying a new Ammonia Tank Assembly which was installed on the P-1 Truss. The old empty tank, attached to the arm, will be brought back home in the space shuttle’s payload bay, and refurbished and reused. New ammonia tank installed. Credit: NASA
Here’s where the new Ammonia Tank Assembly was installed on the P-1 Truss. Danny Olivas is shown here putting the final touches on the first spacewalk activities. New freezer installed in the ISS. Credit: NASAMeanwhile, inside the ISS astronauts installed a new Minus Eighty Degree Laboratory Freezer for ISS (MELFI) rack in the Destiny laboratory. Will the ISS residents now be feasting on astronaut ice cream? This freezer can maintain a temperature of -80 degrees Celsius to preserve biological and medical specimens until they can be brought back to Earth. Shown here are Fuglesang (top foreground) and Tim Kopra (background), Kevin Ford (left foreground).
Nicole Stott during an EVA. Credit: NASA
Here, Nicole Stott works during the first EVA. In addition to adding the new Ammonia Tank Assembly, Stott and Olivas retrieved the European Technology Exposure Facility (EuTEF) and Materials International Space Station Experiment (MISSE) from outside the Columbus laboratory module and installed them on Discovery’s payload bay for return to Earth. Stott will stay on board the ISS for Expedition 20 and 21. Part of the ISS backdropped by the limb of Earth. Credit: NASA
Beautiful! Part of the ISS is shown against the blackness of space and Earth’s horizon in this image photographed by one of the astronauts during the second EVA. View on Danny Olivas' helmet. Credit: NASA
I love these visor-reflection images, and this one is especially good. Danny Olivas used his digital still camera to take a picture of his own helmet visor during the second EVA. Visible in the reflections are various components of the station, along with Christer Fuglesang anchored to a Canadarm2 mobile foot restraint. Preparing tools for EVA. Credit: NASA
Every handyman loves tools, and NASA’s EVA tools top them all. Danny Olivas checks out a pistol grip power tool, getting it ready for use during the third EVA of the mission. Olivas participated in all three spacewalks. Earth and Moon from space. Credit: NASA
How much clearer is the view of the Moon without having to look through the atmosphere? Here, a gibbous moon is visible above Earth’s atmosphere, photographed by one of the STS-128 crew during flight day three. Olivas flexes his muscles. Credit: NASA
More great images from the EVAs. Above, Danny Olivas shows his strength during the second EVA and below, Nicole Stott is framed by parts of the ISS, with the solar arrays lit by the sun behind her. Stott and the ISS. Credit: NASA The astronauts from both crews on the ISS. Credit: NASA
The STS-128 and Expedition 20 crewmembers found a few moments on a day between two spacewalk days to pose for some portraits on the International Space Station. The red-clad crewmembers are with STS-128. They include, front row, from the left, astronauts Rick Sturckow, Jose Hernandez and Patrick Forrester; behind them in red, are astronauts Kevin Ford, John “Danny” Olivas, with European Space Agency astronaut Christer Fuglesang. At bottom left is Tim Kopra, who joined the station crew in July but now is scheduled to return to Earth in less than a week with the Discovery astronauts. Surrounding the Discovery crew, in clockwise fashion, are the members of Expedition 20 crew, astronaut Nicole Stott, Canadian astronaut Robert Thirsk, with cosmonaut Roman Romanenko, European Space Agency astronaut Frank De Winne, cosmonaut Gennady Padalka and astronaut Michael Barratt. Nighttime launch of STS-128. Credit: NASA
The mission began on August 28 with the nighttime launch of space shuttle Discovery. Liftoff was at 11:59 p.m. (EDT).
Discovery lift off. Credit: flyingjenny on Twitpic. Click image for more of flyingjenny's images
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The third launch attempt was a charm for space shuttle Discovery and her crew. The STS-128 mission is now underway with a successful liftoff one minute before midnight, local time, from Kennedy Space Center. Discovery is carrying the Leonardo supply module to the International Space Station, and tucked away inside is the COLBERT treadmill, along with several refrigerator-sized racks of science equipment, a freezer to store research samples, a new sleeping compartment, an air purification system, and other supplies, plus another unusual object packed in Swedish astronaut Christer Fuglesang’s belongings: a theoretical particle called a neutralino.
The plush particle with the CERN logo. Source: CERN
As you may have guessed, Fugelsang didn’t bring a real neutralino, but a soft toy version (see the whole collection of particles at Particle Zoo.) Fugelsang is a former CERN physicist and he wanted to take something representing CERN up to space on his mission. He chose the neutralino because it links together astrophysics and particle physics. In particle physics, the neutralino is a hypothetical particle, one of many predicted by supersymmetric theories.
The countdown and launch were textbook, without any hitches or delays. The valve that scrubbed a launch attempt earlier this week behaved normally, and while weather (which forced the first launch scrub) was a concern early during the countdown, the Florida skies eventually cleared allowing for a gorgeous nighttime liftoff. The stunning lead image is courtesy of flyingjenny on Twitter. Click the image for more of her images. Several comments from Twitterers attending the launch said night was turned into day as the shuttle ascended!
The mission is commanded by veteran astronaut Rick “C.J.” Sturckow. With him are pilot Kevin Ford and Mission Specialists Patrick Forrester, Jose Hernandez, John “Danny” Olivas, and Fugelsang, along with a new crew member for the station, Nicole Stott.
Of course, the treadmill is named after comedian Stephen Colbert, (if you’ve been living under a rock and haven’t heard about this, read about it here) and otherwise is called the Combined Operational Load Bearing External Resistance Treadmill.
Discovery is scheduled to dock with the ISS on Sunday August 30.
South Korea successfully launched its first rocket on Tuesday, but the satellite payload failed to reach its designated orbit, officials said. The rocket, a two-stage rocket, called the Naro lifted off on schedule at 5:00 pm local time, (0800 GMT). The first stage separated successfully less than five minutes after lift-off and the South Korean-built 100-kilogram (220-pound) scientific research satellite was placed into Earth orbit. But science and technology minister Ahn Byong-Man said it was not following the designated orbit, hampering communications with mission control. “All aspects of the launch were normal, but the satellite exceeded its planned orbit and reached an altitude of 360 kilometres (225 miles),” Ahn said. Continue reading “South Korea Launches Rocket; Satellite Fails to Reach Its Orbit”
Navigating a spacecraft through the heavens has been compared to sailing a ship on the open seas or driving a vehicle on a long, cross country journey. Analogies are necessary, since spacecraft navigation is performed by a relatively small sampling of the human race, and the job usually involves doing things that have never been done before. Those of us who have trouble making sense of a road map here on Earth stand in awe of what these celestial navigators can accomplish.
Literally, this is rocket science.
In simplest terms, spacecraft navigation entails determining where the spacecraft is and keeping it on course to the desired destination. But it’s not as easy as just getting from Point A (Earth) to Point B (a planet or other body in our solar system.) These are not fixed positions in space. Navigators must meet the challenges of calculating the exact speeds and orientations of a rotating Earth, a rotating target destination, as well as a moving spacecraft, while all are simultaneously traveling in their own orbits around the Sun. Chris Potts points to Gusev Crater on Mars on January 4, 2004, after the MER navigation team landed the Spirit rover on Mars with unprecedented accuracy. Photo courtesy of Chris Potts
Chris Potts, who helped lead the navigation teams for the Mars Exploration Rovers (MER), compared the target requirements of landing the Spirit rover inside a specific crater on Mars to being able to shoot a basketball through a hoop 9000 miles away. “Not only do you have to make the shot perfectly without the ball touching the rim, but the timing has to be perfect, so you make the shot exactly as the buzzer sounds,” he said.
Ken Williams was the Navigation Team Chief for the Stardust mission’s return of pristine samples of a comet back to Earth. For a successful re-entry and landing at a precise location in Utah, the navigation team had to target the return capsule’s entry to a specific point in the Earth’s atmosphere to within eight 100ths of a degree, a feat that’s been compared to hitting the eye of a sewing needle with a piece of thread from across a room.
Navigation is essential to every robotic mission, and while mission success hinges on how well the navigation team performs, navigators aren’t usually found in the limelight, sitting up on stage for a press conference. Typically that’s reserved for the mission scientists and designers. The navigators, seemingly, work behind the scenes, manning the trenches in relative anonymity.
But I had the opportunity to talk to a few spacecraft navigators, learning more about their job and discovering the innate qualities of those who guide our spacecraft to places beyond. Neil Mottinger. Image courtesy Neil Mottinger.
Neil Mottinger has been part of numerous missions since he started working at the Jet Propulsion Laboratory in 1967. He assisted with some of the early lunar and planetary missions, and developed some of the software that navigators still use today.
There are several different sub-disciplines to spacecraft navigation, and one of Mottinger’s specialties is orbit determination. “Orbit determination is knowing where the spacecraft is and where it’s going,” said Mottinger, who currently works with the Mars Reconnaissance Orbiter (MRO) mission and the upcoming LCROSS (Lunar Crater Observation and Sensing Satellite) mission to the moon. “It starts with predicting the trajectory where the spacecraft will be immediately after launch so that the Deep Space Network (DSN) knows where to point their antenna and on what frequency to expect the signal.” The DSN consists of a network of extremely sensitive deep space communications antennas at three locations: Goldstone, California; Madrid, Spain; and Canberra, Australia. The strategic placement approximately 120 degrees apart on Earth’s surface allows constant observation of spacecraft as the Earth rotates.
Since there’s no GPS in outer space, navigators process the radiometric tracking data received from the DSN to determine the spacecraft’s position and velocity. They also use optical data, where the spacecraft takes a picture of the star background to help refine the spacecraft’s trajectory.
For many years, Mottinger worked with a group that provided navigation support for the launch of over 100 spacecraft. “I never got attached to any one mission since right after a launch we moved on the next mission,” Mottinger said. But now he stays with missions longer and has been with the MRO mission for the better part of three years. Mottinger is thrilled with the scientific data this mission has returned. “We have to provide accurate predictions of where the spacecraft is going to be. Then the engineers know how to orient spacecraft so that the scientists can make their observations,” he said. “If we do our job, the scientists can see a landslide on Mars or look at specific areas on the planet. If our predictions are wrong, the cameras are pointed in the wrong direction. Navigation is integral to the whole process of ensuring mission success.” An active volcano on Io, taken by the New Horizons spacecraft. Credit: NASA
Mottinger said that typically one doesn’t think of navigators as scientists, only as a means to an end for the scientists to get results. However, sometimes scientific by-products come from navigation. The most famous instance involved the Voyager mission when navigator Linda Morabito discovered a volcano on Jupiter’s moon Io from looking at optical navigation images. In the Lunar Orbiter missions, navigators realized there were large concentrations of mass, (now called mascons) underneath the moon’s surface that were accelerating spacecraft in orbit.
Additionally, the science used in navigation has improved dramatically over the years. “When you look at the types of things we didn’t understand when I first started versus what we know now, it’s overwhelming,” said Mottinger. For example navigators can now create very accurate models of solar pressure – how particles of sunlight push against a spacecraft and alter its trajectory — which includes not only how sunlight is reflected from different surfaces of the spacecraft, but also the re-radiation of energy absorbed by the solar panels and radiated out the back side.
Additionally ephemerides, the tables navigators use to obtain the positions of astronomical objects, have also improved in accuracy over the years. “The devil is in the details,” said Mottinger. “Navigation is getting to be an incredibly precise game.”
Like many who work at JPL, Mottinger enjoys talking to schools or community groups to share the excitement and recent discoveries of space exploration. “It’s important to be out there telling our message to get people excited about what we’re doing,” he said. “And the public is entitled to be excited, because they’re paying the bill.”
Several years ago Mottinger returned to his hometown of Oswego, Illinois to talk to students about his job as a navigator. Sitting in the classroom was a young Chris Potts, who decided spacecraft navigation was the career he wanted to pursue. Potts, who has been at JPL since 1984, was the Deputy Navigation Team Chief for MER and now works with the Dawn Mission that is en route to orbit two asteroids, Ceres and Vesta. Chris Potts and Neil Mottinger with a model of the Mars Exploration Rover at JPL. Photo courtesy of Chris Potts
Potts’ specialty is flight path control. This involves firing the propulsion system to alter the spacecraft’s velocity or trajectory, known as Trajectory Correction Maneuvers (TCM). “That includes understanding the spacecraft’s control capabilities and determining any limitations,” said Potts. “You determine when you’re going to fire the propulsion system, how often and the objective of each maneuver. You also have to evaluate the delivery requirements, to make sure you can land within a crater on Mars, for example, and minimize risk along the way.”
The design aspect is Potts’ favorite part of the job. “You try to develop a strategy that puts all the pieces together,” he said. “You have to talk with the mission scientists and understand what their requirements are, and then know what the spacecraft can do. It’s like people who have an old car and they’ve been around it so long, they know how to get the most out of that vehicle. Taking advantage of what the spacecraft does well and working around its limitations feeds into the design of a strategy that pulls it all together to make it work.”
Much of Potts’ work involves simulations and testing. “We see how the spacecraft behaves, and try out different strategies to improve it for our situation,” he said. “The navigation section has a whole ‘toolbox’ of software that we’re able to use.” Artist concept of the Dawn spacecraft. Credit: NASA
The Dawn spacecraft uses an ion engine, and this is the first time Potts has worked with a low thrust propulsion system. “It’s quite a different mission,” he said. “The concerns are little bit different than other missions because the thrust is so efficient. One of the things you worry about is not having enough time to make any corrections that are needed. Although the thrust is low, over time it builds up quite a velocity change and you’re always designing trajectories and changing commands to make sure the ion engine is firing in the right direction. If there’s any kind of spacecraft fault or hiccup along the way, you have to scramble, and some future events might have to be moved around.” Dawn will arrive at Vesta in 2011.
Potts enjoys being part of the excitement of all the different missions at JPL. “I really enjoy working with some extremely intelligent and talented people here and you can definitely sense the passion for the work that they do,” he said. “Sometimes that can be intimidating, but you realize that everyone has their own talent to offer, and everyone helps drive you to do your best here. We get to do a variety of interesting work, and it’s very challenging. No two days are the same.”
One of the rewards of his job, Potts said, is seeing the fruition of his work come to light in scientific discoveries. “With the Stardust sample return, to watch the capsule land right where it was supposed to in Utah was very rewarding,” he said. “And to see the scientists get their hands on that data and start to perform their investigations, you sense how thrilled and excited they are to finally get to work on their lifelong ambition.”
Potts and Mottinger both worked on the Stardust mission under the leadership of Ken Williams. Williams worked at JPL for several years, but currently is employed by KinetX, a private engineering firm specializing in aerospace technology and software development. At present, KinetX provides navigation support for the New Horizons mission to Pluto, as well as the MESSENGER (Mercury Surface Space Environment Geochemistry and Ranging) mission to Mercury, and Williams is MESSENGER’s navigation team chief. Unlike Mottinger and Potts, Williams hasn’t always been involved in space missions and his career in navigation evolved from a background in physics. He worked at the Applied Physics Lab at Johns Hopkins University before coming to work at JPL in 1994. Ken Williams of KinetX.
Williams’ favorite part of being a navigator is finding and solving interesting technical problems. “That’s what gets my interest,” he said. “MESSENGER certainly has a number of those. We flew by Earth once, Venus twice and Mercury twice. We’ll have to fly by Mercury one more time before we finally go into orbit on the fourth encounter. Finding a trajectory that does all those things successfully is a very interesting technical problem that I’m very glad to be involved with. We have to consider all sorts of constraints, too, such as keeping the spacecraft pointed away from the sun so that the components don’t get too warm.”
As a Navigation Team Chief, Williams coordinates all the sub-disciplines of orbit determination, flight path control, and optical navigation along with the needs of mission scientists in terms of observations when they encounter a planet or comet.
Williams, too, enjoys the exhilaration of being in the thick of the action in important space missions. “I suppose it’s like being in a battle, or in a basketball or football game,” he said. “You feel the excitement of seeing events unfold, and responding to any anomalies or surprises that come up. And when it’s all done you have a tremendous sense of satisfaction.”
His experiences with Stardust’s return to Earth stand out as a highlight. “Getting all that effort coordinated and getting the spacecraft down successfully was probably the single most rewarding experience in all the time I was at JPL,” he said. “On nearly every mission I’ve worked on there has been a time where you have a sense of euphoria about having the spacecraft be in the right place at the right time. That’s a good feeling to have.” The Stardust Mission Navigation Team was presented with Popular Mechanics’ Breakthrough Award. Said Team Chief Ken Williams: “The day we took this picture, I felt a strong sense of camaraderie with all these folks after everything had worked so well. They’re a very talented group of people who did a tremendous job.” FRONT ROW – left to right:Tung-Han You, Ken Williams, Prem Menon. 2nd Row: Roby Wilson, Katherine Nakazono, Julie Kangas. 3RD Row: Daniel Lyons, Ram Ramachand, Bhat Shyam Bhaskaran, Cliff Helfrich, Jeff Tooley, David Jefferson, Dimitri Gerasimatos, Paul Thompson, Neil Mottinger. Last row: Darren Baird, Jae Lee, Chris Potts, Tim McElrath, Brian Kennedy
Although leaving JPL was a difficult decision, Williams enjoys his experiences at a private company. “It would have been easy to stay at JPL and be what they call a ‘greybeard’ in terms of having experience, but after Stardust, I liked the challenge of leading a navigation team and growing in technical areas,” he said. “I thought there would be a better opportunity to do that with a small team in a small company, and I thought KinetX was a good place to accomplish that.“
Quite the opposite of a ‘greybeard’ is navigator Emily Gist. She has been at JPL for 4 years and is part of the navigation team for the Cassini mission at Saturn. Like Potts, she works in flight path control, helping to plan the trajectory and estimate the future position of the spacecraft, and to control the corrections required to achieve the mission objectives. Artist concept of the Cassini spacecraft at Saturn. Credit: NASA
She takes great satisfaction knowing she is helping to facilitate exploration. “The Saturnian system is more beautiful than most would have imagined and more diverse than previously known,” she said. “The information Cassini has provided has enlightened us all. More specifically I love how much I learn each and every day at JPL and working on the Cassini Mission.”
As part of the ‘next generation’ of navigators, Gist enjoys the challenging environment that JPL provides. “We had an Operations Readiness Test on Cassini where the team was tested to see how we would react to a failure or fault on the spacecraft in an operational environment,” she said. “The senior engineers weren’t in play so the newer generation had to figure it out on our own and we did an excellent job. It made me proud of all the folks I work with. They are truly talented people.”
Gist said gender has never been an issue in her job as a navigator. “JPL has a wonderfully diverse staff and while there are not very many female navigators we are not treated differently,” she said. “I am pretty biased, but I think what we lack in quantity we make up for in quality. I work with some amazing women.”
“Additionally, I feel fortunate to live in a time and society where regardless of gender one can find the thing they want to do and do it to the best of their ability. I love being an engineer and what I try to convey to young women is that they can love anything they want, even if it’s math and science, without fear that it’s a less feminine job.”
The hardest question for all the navigators to answer was if they had a least favorite part of the job. They cited the usual problems with any job: not enough time and too much paperwork. And stress comes with the job. “Deadlines, especially working at JPL, are very real,” said Potts. “If you’re not prepared for a critical event in the mission, you usually don’t get a second chance. There’s a lot riding on getting your job done properly.”
But all the navigators emphasized the importance of the team aspect in their job. “You look for the inherent quality of the team,” said Mottinger. “I had a project manager who said that a team catches each other’s mistakes and the whole is greater than the sum of the parts. Everything is done in a spirit of camaraderie, and there’s no such thing as a stupid question.” Galileo at Jupiter. Credit: NASA
But seeking individual limelight just doesn’t seem to be in a navigator’s makeup.
“I’m more comfortable working behind the scenes than doing an interview,” said Potts. “When I know I’ve done my job, and contributed to the mission success, that’s enough for me.”
“I am fine with my work being behind the scenes,” added Gist. “However when I consider the work the engineers before me and around me have done I sometimes feel they should get more recognition.”
Williams feels, in general, the field of navigation itself should get more recognition. “I think scientists and people who do purely hardware systems underestimate the difficulty of what navigators have to do,” he said. “It would be nice if we got more recognition from our peers just from the standpoint of being able to influence how missions are planned and designed to begin with so that navigation issues can be addressed before launch and not only left for us to deal with after launch. I feel more strongly about that than any recognition of my own accomplishments.”
Williams said that what navigators do is more of an art form. “It’s not reducible to a set of algorithms that can be stored on board a flight system like power or propulsion, for example. It’s constant refining.”
And are navigators bothered by the sometimes long and odd hours their job requires? “No,” said Mottinger, “I wouldn’t trade it for anything. There’s nothing else like it.”
The Korea Space Launch Vehicle-1, South Korea's first space rocket, sits on its launch pad at the Naro Space Center in Goheung, South Korea, Wednesday, Aug. 19, 2009. Space officials aborted South Korea's first rocket launch just minutes before liftoff Wednesday. AP Photo/Yonhap. Lim Hun-jung
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The launch of South Korea’s first domestic rocket launch was aborted on Wednesday just minutes before scheduled liftoff because of a technical problem, delaying South Korea’s mini space race with North Korea. The two-stage rocket, called the Naro will be South Korea’s first launch from its own territory. Officials expect another liftoff will be attempted in a few days. Another launch attempt on July 30 was also aborted. The satellite was domestically built, with help from Russia and will observe the atmosphere and ocean. The launch attempt came about four months after North Korea was widely criticized for firing its own rocket in defiance of United Nations sanctions.
Meanwhile, NASA officials have cleared space shuttle Discovery to launch on August 25 for the STS-128 mission to the International Space Station. As of now, weather is the only issue that might delay the mission.
Discovery will carry the Leonardo supply module to the International Space Station during STS-128, along with a new crew member for the station, Nicole Stott.
Launch is set for 1:36 am EDT (yes, that’s EXTREME am!) on the 25th. The good news about that hour is that launch should come well before any typical afternoon storms can brew up in the Florida skies. But then, it is hurricane season, and NASA is keeping an eye on a few tropical storms on the horizon.
Commanded by veteran astronaut Rick “C.J.” Sturckow, the STS-128 mission crew will deliver refrigerator-sized racks full of equipment, including the COLBERT treadmill, an exercise device named after comedian Stephen Colbert.
Stott will take the place of Tim Kopra, who moved into the station during STS-127. Pilot Kevin Ford and Mission Specialists Patrick Forrester, Jose Hernandez, John “Danny” Olivas and Sweden’s Christer Fuglesang round out the crew.
Screen shot of the IRVE inflatable heat sheild during Monday's test flight. Credit: Wallops Flight Facility
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NASA conducted a successful test Monday morning of a new type of heat shield that could make it possible to land larger payloads on Mars. The Inflatable Re-entry Vehicle Experiment (IRVE) demonstrated an inflatable heat shield which could slow and protect spacecraft entering atmospheres at hypersonic speeds. “This was a small-scale demonstrator,” said Mary Beth Wusk, IRVE project manager, based at Langley Research Center. “Now that we’ve proven the concept, we’d like to build more advanced aeroshells capable of handling higher heat rates.”
IRVE launch from Wallops Island, Virginia. Credit: NASA
IRVE was vacuum-packed into a 38 cm (15-inch) diameter payload shroud and launched with a Black Brant 9 sounding rocket from NASA’s Wallops Flight Facility on Wallops Island, Va., at 8:52 a.m. EDT. The 3 meter (10-foot) diameter heat shield, made of several layers of silicone-coated industrial fabric, inflated with nitrogen to a mushroom shape in space several minutes after liftoff.
At four minutes into the flight, the rocket reached 210 km (131 miles), and deployed the heat shield, which took less than 90 seconds to inflate. According to the cameras and sensors on board, which relayed real-time data back to engineers on the ground, the heat shield expanded to its full size and went into a high-speed free fall. The key focus of the research came about six and a half minutes into the flight, at an altitude of about 50 miles, when the aeroshell re-entered Earth’s atmosphere and experienced its peak heating and pressure measurements for a period of about 30 seconds.
“Our inflation system, which is essentially a glorified scuba tank, worked flawlessly and so did the flexible aeroshell,” said Neil Cheatwood, IRVE principal investigator and chief scientist for the Hypersonics Project at NASA’s Langley Research Center in Hampton, Va. “We’re really excited today because this is the first time anyone has successfully flown an inflatable reentry vehicle.” NASA engineers check out the Inflatable Re-entry Vehicle Experiment (IRVE) in the lab. Credit: NASA/Sean Smith
Inflatable heat shields hold promise for future planetary missions, according to researchers. To land more mass on Mars at higher surface elevations, for instance, mission planners need to maximize the drag area of the entry system. The larger the diameter of the aeroshell, the bigger the payload can be.
