Sunday, April 21, 2013

SPACE in NEWS


Why do satellites fail?

Although it may seem like a simple question, the answer is sometimes elusive. When a spacecraft like the European Space Agency’s Olympus communication satellite in 1993 or the Japan Aerospace Exploration Agency’s Midori II in 2002 just stops working, it has not always been possible to determine exactly what went wrong. Micrometeoroid impacts, space debris collisions, and radiation-induced electronics hangs up can usually be tracked down. But if none of these culprits fits the available data, satellite operators have had to mark it up to fickle fortune and eat the loss.

These types of failures caught the attention of Stanford University researcher Sigrid Close. Close’s experiments have pointed to a potential culprit: space dust.


Space dust, or cosmic dust, generally travelling in the range of 10-40 km/s, becomes plasma upon collision with an object. Larger particle collisions also generate plasma, but these collisions are much rarer and generally more detectable, so they are not good candidates to explain unexplained satellite failures. Close has found through ground experiments at the Max Planck Institute that plasma striking satellite-like bodies can emit electromagnetic pulses able to disrupt spacecraft electronics.


“Spacecraft transmit a radio signal, so they can receive one that might potentially disable them,” Close told. “So our question was: Do these plasmas emit radio signals, and if so, at what frequencies and with what power?”


Close and her colleagues proved out the theory by firing 60 km/s dust particles at targets. ”We found that when these particles hit, they create a plasma or quasi-neutral gas of ions and electrons, and that plasma can then emit in the radio frequency range,” Close said. Tellingly, these radio emissions did not always occur, being highly dependent on orientation and thermal variations of the “spacecraft” targets. This variation both explains why the cause of these failures has been so elusive and provides potential protection mechanisms to prevent such failures in future. “There are solutions we could implement to save billions and billions of dollars,” Close avers.


Studying cosmic dust can be challenging, since it is very difficult to capture for study. NASA’s Stardust mission succeeded in capturing some particles of interplanetary dust, only to discover how challenging it is to find miniscule dust particles in an aerogel array. Stardust ended up enlisting thousands of volunteers to pore over thousands of  three dimensional image stacks hunting for the elusive particles; they’re still looking, seven years later. Hopefully, Close’s simulated dust behaves sufficiently like the real thing to bypass the need for improved compositional and configurational veracity. 
Close will determine whether her model fits the bill with her upcoming  in situ experiments outside the International Space Station. She is now working with NASA Jet Propulsion Laboratory scientists to prepare that hardware for deployment. Related...

Commercial Space Race Heats Up


The Falcon 9 rocket, which made its fifth successful flight on 1 March, 2013 has stolen the spotlight in the commercial space race. Built by SpaceX, a young company based in Hawthorne, California, the rocket has become NASA’s choice for hauling cargo to the International Space Station (ISS). But it may soon have competition from a rocket that has kept a low profile.

After years of delays, Orbital Sciences of Dulles, Virginia, has launched the first test flight of its Antares rocket on April 21, 2013. If that goes well, its second mission could carry an unmanned Cygnus spacecraft to the ISS within months. “There’s no one main problem, no show-stopper,” says Orbital spokesman Barron Beneski. “In hindsight, this has just taken us longer to do than we thought it would.”

Both companies have received hundreds of millions of dollars from NASA’s Commercial Orbital Transportation Services (COTS) programme. With the space shuttle retiring in 2011, the agency wanted alternatives to paying for ISS deliveries aboard the Russian Progress and Soyuz craft. NASA deliberately put two companies in competition with each other to keep prices down over the long run and to attract other customers. “The government is the necessary anchor tenant for commercial cargo, but it’s not sufficient to build a new economic ecosystem,” says Scott Hubbard, an aeronautics researcher at Stanford University in California and former director of NASA’s Ames Research Center in Moffett Field, California.

With 30 years of experience in making satellites and rockets, Orbital once seemed the safer bet. Instead of assembling its vehicles from scratch like SpaceX, Orbital uses parts made by companies with proven track records. The core of the first stage of Antares was designed and built by veterans KB Yuzhnoye and Yuzhmash, both based in Dnipropetrovsk, Ukraine. Cygnus’s sensors come from Mitsubishi Electric in Tokyo and its pressurized cargo module was built at a Thales Alenia Space plant in Turin, Italy. “Orbital used more heritage technology,” says Alan Lindenmoyer, manager of NASA’s commercial crew and cargo programme. “That was less risky for us.”  More

Chinese FAST Telescope to Surpass AreciboChinese FAST Telescope to Surpass Arecibo

Chinese FAST Telescope to Surpass AreciboWhen it comes to understand what's going on in deep space, whether asteroids and Kuiper belt objects or pulsars and galaxies, it's all about size. The bigger the telescope, the more it can detect. Since its completion in 1963, the Arecibo radio telescope in Puerto Rico has been the world's largest single aperture telescope with a diameter of 305 m.  China is looking to break that long held record with the upcoming FAST telescope. Construction on FAST began in 2011; the telescope is expected to be completed in 2016 with a diameter of 500 m. More

Rescuing Orion After Off-Nominal LandingRescuing Orion After Off-Nominal Landing

Rescuing Orion After Off-Nominal LandingRescue divers secure a flotation ring around a mockup of NASA's new Orion spacecraft during water splashdown tests in Florida in 2009 (Credits: NASA/Dmitri Gerondidakis). NASA is setting up the mission rules for the Orion spacecraft with a Concept of Operations (CONOPS) that includes scenarios for keeping a crew alive after end of mission splashdown. The scenarios include off-nominal landings to remote areas of the ocean, and crew rescue by US Department of Defense (DoD) assets.During the last thirty years, Space Shuttle crews have been landing at Kennedy Space Center, with an alternative option being Edwards Air Force Base ... More

Why Do Astronauts Grow Taller in Space?

Did you ever wish you could be just a teensy bit taller? Well, if you spend a few months in space, you could get your wish — temporarily. It is a commonly known fact that astronauts living aboard the International Space Station grow up to 3 percent taller while living in microgravity. They return to their normal height when back on Earth. Studying the impact of this change on the spine and advancing medical imaging technologies are the goals of the Spinal Ultrasound investigation. “This is the very first time that spinal ultrasound will be used to evaluate the changes in the spine,” said Scott A. Dulchavsky, M.D., Ph.D., principal investigator for the station study. “Spinal ultrasound is more challenging to perform than many of the previous ultrasound examinations done in space.” Part of the difficulty with imaging the spine is quite simply human anatomy. Using Ultrasound 2, the machine aboard station as a facility for human health studies, astronauts have an advanced tool to view the inner workings of their bodies. More

Cosmonaut Roman Romanenko on his first EVA (Credits: NASA).Mostly Successful Spacewalk Releases New Debris

On April 19, cosmonauts Pavel Vinogradov and Roman Romanenko conducted a nearly seven hour extravehicular activity (EVA) outside the International Space Station (ISS). The spacewalk involved installation and retrieval of experiments and installation of a navigational aid needed for the upcoming ATV-4 mission. Vinogradov is a veteran spacewalker; this was his seventh foray and a record making one. Vinogradov is ...  More

The vacuum chamber, circled by high strength magnets, could produce the first fusion-based propulsion prototype (Credits: University of Washington/MSNW).Flying to Mars on a Fusion Rocket

One of the most challenging aspects of 
sending humans to Mars is the duration of the
 flight that takes them there: over 500 days of 
putting up with the same crewmates while 
being barraged by cosmic radiation. It’s enough
to make anyone stay in Earth orbit. But a group 
of researchers at the University of Washington is 
determined to go ... More

(Credits: D-Orbit)

D-Orbit Add-on Deorbits Satellites without Sacrificing Fuel

Luca Rossettini, CEO and co-founder of D-Orbit, a start-up targeting the space debris mitigation market, has always dreamt of going to space. His dream led him from Italy to the US and back, with a revolutionary idea and a reliable business plan on how to deal with satellite disposal. Before starting D-Orbit, Rossettini joined the Italian army as a parachute ... More

Thursday, April 11, 2013

SPACE in NEWS


NASA Turns Up the Heat on Construction of the Space Launch SystemHuntsville, AL (SPX) Apr 01, 2013 - Welding engineers at NASA's Marshall Space Flight Center in Huntsville, Ala., have had an extremely busy winter assembling adapters that will connect the Orion spacecraft to a Delta IV rocket for the initial test flight of Orion in 2014. The adapter later will attach Orion to NASA's Space Launch System (SLS), a new heavy-lift rocket managed and in development at the Marshall Center that wi ... more

Future Looks Bright for Private US Space Ventures
Washington DC (RIA Novosti) Apr 01, 2013 From wealthy American technology executives to British billionaires, entrepreneurs are betting big on the emerging US private spaceflight industry. While some ventures claim to forge the path to US dominance, others aim to level the playing field for countries that lack space exploration programs. "The private sector is more efficient than the government and can do the same thing at a lo ..... more


Swiss firm plans robotic mini-shuttle
A Swiss firm says it intends to construct a robotic rocket plane that will launch satellites into orbit off the back of a modified jetliner. Swiss Space Systems - S3 - says its unmanned suborbital shuttle could be traveling to launch height atop an Airbus A300 jetliner by 2017. "S3 aims to develop, build, certify and operate suborbital space shuttles dedicated to launching smal ... more


ATK Successfully Ground Tests New CASTOR 30XL Upper Stage Solid Rocket Motor
ATK has tested its newly developed CASTOR 30XL upper stage solid rocket motor at the U.S. Air Force's Arnold Engineering Development Complex (AEDC) in Tennessee. The test was the final qualification for the ATK commercial motor, which was jointly developed by ATK and Orbital Sciences Corporation (ORB) in just 20 months from concept to completion. The CASTOR 30XL is designed to ignite ...more


Kazakhstan to launch first remote sensing satellite this year

The Kazakh space agency said  that it plans to launch the country's first Earth remote sensing satellite by the end of this year. "The launch of the first medium-resolution remote sen ... more

Europe sets June 5 for launch of space freighter

The European Space Agency (ESA) announced it would launch the fourth, and heaviest, in a series of hi-tech cargo vehicles to the International Space Station (ISS) on June 5. ... more

Beer Cans For Deep Space

The recent announcement of a NASA plan to drag an asteroid into lunar orbit with a robot spacecraft, then stage a crewed astronaut expedition to explore it, has stunned many boffins. The plan is hig ... more

XCOR Driving Rocket Science Forward With Lynx Suborbital VehicleMojave CA (SPX) Mar 28, 2013 - XCOR Aerospace has announced a first in aviation and space history, the firing of a full piston pump-powered rocket engine. This breakthrough is the foundation for fully reusable spacecraft that can fly multiple times per day, every day. It is a game changing technology that has the power to fundamentally alter the way we as a society view, visit, and utilize the abundant resources around  ... more

Friday, March 29, 2013

SPACE in NEWS

I am sorry for not posting news for the past 2 months due to preoccupation.

                                                                            - Ravindranath, C
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Price, reliability, and other challenges facing the launch industry

According to conventional wisdom, commercial customers of launch services care more about launch prices than those in government. Commercial users, after all, are trying to close a business case and generate as much profit as possible. Government users, on the other hand, are concerned about getting their payloads—often very expensive and performing critical missions—launched on schedule and safely, and have shown a willingness to help financially support their nations’ own launch systems.
That conventional wisdom, if it was ever totally accurate, is showing signs of breaking down. Commercial customers, particularly in the core market of geosynchronous communications satellites, have been less price sensitive than what some might expect, and are now expressing new concerns about the reliability of some vehicles. Government customers, meanwhile, are showing new sensitivity to price in this new era of constrained budgets, and are looking to competition from new entrants to help lower their costs. Full Story

ISRO tests cryogenic upper stage


ISRO successfully tested a cryogenic engine powered by liquid hydrogen and liquid oxygen, intended for the upper stage of its GSLV launch vehicle on March 27, 2013, at Mahendragiri, clearing the way for the next GSLV launch later this year. The test tokk place in a test stand designed to simulate the low pressure of the upper atmosphere . The test confirmed the performance of the engine, according to ISRO. The engine will be used on the upper stage of the next Geosynchronous Satellite Launch Vehicle (GSLV), slated to lift off in the latter half of July carrying a communications satellite. A previous GSLV flight using an Indian-developed cryogenic upper stage engine failed in 2010 because of a problem with that engine.
Proton returns to flight, launches Mexican satellite

The Proton rocket returned to flight on March 27, 2013 with the successful launch of a Mexican satellite. The Proton M lifted off from the Baikonur Cosmodrome in Kazakhstan at 3:07 pm EDT Tuesday (1907 GMT Tuesday, 1:07 am local time Wednesday) carrying the Satmex 8 satellite. The rocket's Breeze M upper stage released the satellite into geosynchronous transfer orbit nine hours and 13 minutes after liftoff. Satmex 8, a Space Systems/Loral 1300 model spacecraft, weighed 5,474 kilograms at launch and carries a payload of 24 C-band and 40 Ku-band transponders. Mexican satellite operator Satmex will use the spacecraft at 116.8 degrees west in GEO, replacing the existing Satmex 5 satellite. The launch was the first for the Proton since a December mission that placed a communications satellite into a lower-than-planned orbit when the upper stage shut down prematurely.
Soyuz launches crew on "express" flight to ISS


A Soyuz rocket launched a spacecraft carrying three people making what is planned to be the shortest flight to the International Space Station. The Soyuz rocket carrying the Soyuz TMA-08M spacecraft lifted off from the Baikonur Cosmodrome in Kazakhstan at 4:43 pm EDT (2043 GMT) on March 28, 2013. The spacecraft, carrying American astronaut Chris Cassidy and Russian cosmonauts Pavel Vinogradov and Alexander Misurkin, is making the first "express" trip to the ISS, a journey that normally takes two days. The Soyuz is scheduled to dock with the station's Poisk module at 10:32 pm EDT Thursday (0232 GMT Friday), or less than six hours after liftoff. The same fast approach to the station has been used by Progress cargo spacecraft going to the ISS, but never before by a Soyuz spacecraft traveling to the station.
Related Links:
SpaceX brings home Dragon with 2,700 pounds of cargo
A suite of refrigerated biomedical research samples and other equipment traveled from the International Space Station back to Earth on Tuesday, nestled inside a commercial Dragon spaceship completing a 25-day resupply flight to the orbiting scientific laboratory.   FULL STORY

Fourth launch in four months for Atlas 5
Launching. Just launching. That's been the mantra for the United Launch Alliance Atlas 5 rocket program, which successfully completed its fourth flight in four months on Tuesday by boosting a surveillance satellite into orbit for the Pentagon.   FULL STORY


How salty is that seawater? Ask the Aquarius satellite
Satellite measures ocean salinity to study circulation and the water cycle.

One of the newest members of the Earth-observing club is Aquarius (along with its friends aboard the SAC-D satellite). Launched on June 20, 2011, the satellite is a collaborative effort between the US and Argentina. Its job? To map surface ocean salinity around the globe and improve our understanding of ocean circulation and the hydrologic cycle. The Aquarius instrument consists of two main components. The actual salinity measurement is made by a microwave radiometer that surveys the radiation emitted by the ocean surface. Because salinity affects the electrical conductivity of ocean water, it changes the microwave emissions perceptibly.If the sea surface was perfectly smooth and calm, that would be pretty straightforward. But because waves affect the way that the radiation is emitted, it’s necessary to account for the roughness of the sea. This is accomplished by using a radar scatterometer that bounces energy off the surface and measures how much returns directly to the satellite. Full Story

Wednesday, January 16, 2013

'SPACE' in News



Cause of Breeze-M Failure Discovered
Final assembly of the Breeze-M at the Khrunichev Center 

Roscosmos has determined the cause of an underperforming Breeze-M upper stage on December 8 to be a broken turbopump bearing.

The incident occurred when a Proton-M with Breeze-M upper stage launched from Baikonour Cosmodrome in Kazakhstan on December 8 carrying Gazprom telecommunication satellite Yamal-402, built by Thales Alenia Space. The Breeze-M released the satellite four minutes early due to four shortened burns, ending well short of the intended orbit. Yamal-402 was eventually nudged into the correct highly elliptical orbit by means of its own emergency propellant reserve. The successful maneuver was conducted via four burns that cost the satellite four years of operational life, concluding on December 15. The satellite is now expected to last 11 years.

The Breeze-M C5.98 rocket turbopump assembly in question is said to have been produced by Isaev Khimmash design center, located near Moscow. Khimmash has accepted responsibility, although the bearing itself was purchased from an undisclosed third party.

Final results of the investigation are expected to be officially announced by the end of the year, although Kommersant reports that the announcement has been delayed seven times already because of disagreement among the investigation panel as to appropriate corrective action. In the meantime, Roscosmos is preparing to check all turbopumps that may be affected. This follows just months after all Breeze-M units were inspected as a result of an August 6 failure whose cause was declared to be a ”manufacturing defect.” That incident resulted in an orbital debris explosion and loss of communication satellites Telkom-3 and Ekspress-MD2. The investigation into the incident continued for weeks and ended with the announcement of a complete reorganization of the Russian space industry into a model that promises an increased governmental role.


Bigelow Contract Could Bring Inflatable Module to ISS by 2016
The Bigelow Expandable Activity Module (BEAM) on the ISS as it
should appear in 2016 
Bigelow Aerospace and NASA have signed a $17.8 million contract that could bring an inflatable module to be attached on the International Space Station.

NASA spokesman Trent Perrotto told Space News that the deal was signed in late December 2012, but he did not reveal the terms of the agreement, saying only that it centers on the Bigelow Expanded Aerospace Module (BEAM).

Although the details will be revealed later, it can be supposed that BEAM would be an inflatable addition to ISS, proving out the technologies and paving the way for future commercial space stations. The deployment of the module will represent a perfect demonstration for habitation and storage in a space environment, giving also significant data on the duration of inflatable modules compared to the existing metallic ones. According to NASA officials, the agency will ask one of its Commercial Resupply Services contractors, SpaceX or Orbital Sciences Corp., to carry BEAM to the ISS, most likely before the end of 2016.

Bigelow Aerospace, situated in Las Vegas, Nevada, has been in the space station business for several years, having deployed two orbiting prototypes called Genesis 1 and 2 in 2006 and 2007 respectivley, both launched with Russian rockets. In 2010, Bigelow won a nonpaying contract with NASA to develop a list of procedures and protocols to add BEAM to ISS. The company is now growing after a period of downturn, opening new facilities and hiring again to increase the working force up to 90 staff. Bigelow specializes in inflatable space habitat technology that it aquired from NASA. The company has aspirations to open a Commerical Space Station using the modules.

Meanwhile in Russia, RSC Energia has signed an important contract with Roscosmos to develop a draft design for for OKA-T-MKS, an orbiting unmanned lab to be connected to International Space Station. It seems clear that the ISS partners want to capitalize on the remaining funded life of the station as much as possible. ISS is currently expected to remain operational though at least 2020.

Related story
http://www.space.com/19236-space-station-inflatable-module-bigelow.html


Study Suggests Enhanced Alzheimers Risk for Spacefarers

Plaques between neurons is one of the indicators of Alzheimers
Disease and seem to be increased with GCR exposure
A study published in PLOS One on December 31 suggests that there may be unforeseen long term effects on spacefarers health. Long term exposure to heavily charged Galactic Cosmic Radiation (GCR) could increase the chances of incurring Alzheimers.

The study, which was conducted at the University of Rochester and Harvard Medical School with funding from NASA’s Space Radiobiology Research Program, exposed mice to doses of high energy, high charge (HZE) particles akin to those found in GCR. The mice received a dose of 100 cGy, equivalent to the total dose astronauts might experience on a trip to Mars. After six months, the mice experienced cognitive impairment and presented with plaques that have been correlated to Alzheimer’s disease.

It is very difficult to protect against powerful GCR radiation. ”One would have to essentially wrap a spacecraft in a 6-foot (2 meters) block of lead or concrete,” explained corresponding author M. Kerry O’Banion, something that would be clearly prohibitive for mass-constrained launches. Unlike solar radiation, GCR is emitted isotropically throughout all points in space, making avoiding such radiation nearly impossible.

Unlike astronauts, the mice received their radiation dose all at once instead of gradually over time and were irradiated with only the heaviest ion - iron – rather than a range of ions that are present in GCR. The mice were also preselected for being genetically disposed to contract Alzheimer’s. It is not known how these factors could affect the results, but it is likely that this study represents a worst case scenario for the stated conditions. “I would add that there are at least three other laboratories pursuing similar studies,” said O’Banion, so some of these questions may be answered soon.

Although the radiation hazards of space travel have been known for sometime, this is the first indication of long term effects beyond typical radiation sickness. More such effects are likely to emerge as humans spend longer periods of time in space. One such discovery was made in 2012 when it was discovered that some male astronauts’ vision became apparently permanently impacted following cumulative long duration deployments on the International Space Station and Space Shuttle.


Energomash to Develop and Test New High-Performance Rocket Fuel

Experts from Russian manufacturer NPO Energomash “V.P. Glushko” and RSC Applied Chemistry have developed a state-of-the-art high-performance rocket fuel, working on a completely novel mixture of acetylene and ammonia called Atsetam.“A mixture of acetylene and ammonia is 20 times cheaper than hydrogen, as a kilogram of hydrogen costs about 2,000 rubles ($67) and a kilo of Atsetam is maximum of 100 rubles ($3.35),” explained Energomash’s Director of Innovative Technology, Anatoly Likhvantsev.

At the beginning of December 2012, Energomash obtained the first experimental batch of Atsetam, confirming the findings of previous theoretical studies. The batch also proved the effectiveness of the technology developed for the fuel’s production. The new Atsetam fuel is not only cheaper than hydrogen but it can also be easily stored and transported, whereas hydrogen requires special storage and transportation conditions.

Energomash has also started developing an engine to work with the new mixture. The engine will be assembled on the basis of the RD-161, originally designed to work with oxygen and kerosene.  The development will not require major structural changes to existing rocket motors since the physical properties of Atsetam do not differ much from kerosene.
Energomashs liquid engines. The company has started
development of a new rocket engine using Atsetam as a
fuel, planning to reduce the cost of rocket
launches of about 1/3
Although the exact engines parameters will be determined during upcoming tests that are scheduled to last until 2016, Energomash chief executive Vladimir Solntsev is persuaded that the Atsetam fuel will help increase the efficiency of rocket engines by at least 30% in the future.

Energomash is carrying out work on processing and certifying Atsetam as a prospective rocket fuel application at its own expense, partially supported by the Skolkovo Innovation Centre. In 2013-2014, Energomash plans to develop a technology for generating industrial quantities of Atsetam. It also plans to develop a test bed and carry out firing tests of the new oxygen-Atsetam liquid propellant engine prototype.

If all goes well in the test and certification phase, and depending on funding, the first launch with the new engine will occur in 2017-2018.


Is China Preparing an Anti-Satellite Test?

U.S. experts think China is preparing to perform another anti-satellite (ASAT) test in January.

“The first media report on these rumours appeared in October,” wrote Gregory Kulacki of the Union of Concerned Scientists on a blog post dated January 4th. “China’s Ministry of Defence challenged the information in that report, but in November contacts in China told us an announcement about an upcoming ASAT test was circulated within the Chinese government.”


Rumours of an upcoming anti-satellite test have been circulating for several months in the
Debris from 2007 ASAT test involving Fengyun satellite

U.S. defence and intelligence community. China has previously carried out ASAT tests on January 11th 2007 and 2010, so it is possible that they plan to carry out the test on the same date this year. In the 2007 test China destroyed the defunct Fengyun-1C weather satellite via an anti-satellite device. The explosion created approximately 3000 pieces of debris. The 2010 test used a similar technology to destroy an object that was not in orbit.

The target of the possible test remains unclear. Some U.S. officials suspect China may want to target the medium Earth orbit (MEO) region, which can be viewed as a potential threat to the U.S. and Russian navigational satellites. However, Kulacki is not sure that the possibly imminent ASAT test, would necessarily be as destructive as the 2007 event. On the contrary, it could involve a technology that doesn’t physically destroy the satellite. Since China is planning to put more navigational satellites in MEO, it’s unlikely they would risk creating more debris which could affect their own satellites.

China is not the sole instigator of ASAT tests. Both the United States and the former Soviet Union conducted equally destructive ASAT tests during the development of their space programs. They eventually decided to stop these tests due to the danger to their own space presence; hopefully China will do the same.

Sleep Issues Could Affect Future Mars Mission

A study based on Mars500 data revealed that the crew experienced increasing lethargy over the course of the mission, resulting in hypokinesis connected to sleep disturbances.

“The success of interplanetary human spaceflight will depend on many factors,” said biomedical and psychiatric researchers from the US and Russia who published the findings in the Proceedings of the National Academy of Sciences,  “including the behavioral activity levels, sleep, and circadian timing of crews exposed to prolonged microgravity and confinement.”

In the Mars500 experiment, six volunteers were confined in a mock spaceship in Star City, Russia to simulate a 17-month journey to Mars and back. The high-fidelity ground simulation of a Mars mission was conducted to study the physical and psychological reactions of the crewmembers to isolation. The research used a number of continuous measurements including wrist actigraphy, light exposure, and weekly computer-based neurobehavioral assessments. The majority of crewmembers experienced issues connected to sleep quality resulting in a state of extended lethargy. Four had considerable trouble sleeping, with one having minor problems and the sixth mostly unaffected. It is still unknown if the men’s lethargy was just due to lack of sleep or was also caused by other factors such as lack of privacy, close quarters, or being away from their families for so long. Their state also led the crew to neglect exercise that will be extremely critical to maintaining physiological health on a long term zero gravity mission.

The loss of sleep is a crucial point in a Mars mission’s development. Astronauts will have to perform many and difficult tasks not only on their journey to Mars but also while they are on the Red Planet. Moreover there will be no real time communications with Earth, so these potentially tired and judgment-impaired astronauts will need to continually make decisions critical to their own survival.

Sleep quality is already a concern on the International Space Station where the noisy environment, microgravity, rapid solar cycle, and arrhythmic station maneuvers all contribute to less than ideal sleeping conditions. A new initiative to install blue-tinted LEDs in crew areas that can be used during rest times is expected to bring some improvements, starting with the first delivery of the lights in 2015.

The world record for continuous time in space is held by the cosmonaut Valery Polyakov, who lived on the Russian space station Mir for 14 months. In 2015, American astronaut Scott Kelly and Russian cosmonaut Mikhail Kornienko are scheduled to spend a whole year in space on the International Space Station.

Canada confirms plans for RADARSAT Constellation mission

The Canadian Space Agency announced this week that it will press ahead with the country's next-generation radar satellite imaging system, signing a contract with a Canadian firm to build the satellites. The RADARSAT Constellation system will feature three radar imaging satellites in polar orbits to provide shorter revisit times for radar imagery. MacDonald, Dettwiler and Associates (MDA) will build the three satellites under a C$706-million (US$718-million) contract announced January 9. The satellites are slated for launch in 2018 to ensure continuous service with the RADARSAT-2 satellite currently operating. There had been concerns in recent months that the program might be delayed, scaled back, or even cancelled because of funding problems.

 Competition Reshaping Launcher Industry

For decades, space-launch providers have survived, and prospered, on government support in the form of development funding, launch contracts and infrastructure subsidies to maintain access to space. That is changing as international competition increases, privately funded players enter the market and government budgets come under pressure. The result is an unprecedented set of challenges to traditional launch providers even as the industry continues to worry about future demand.

The replacement cycles of large commercial communications-satellite operators that have driven demand for launch services are nearing an end and, beginning around 2014, fewer launches are expected. In addition, budget constraints on governments are expected to limit their satellite procurements.

Europe's government-supported Ariane 5 currently launches roughly half of the world's commercial satellites, but faces increasing competition from the Russian Proton, which remains competitive despite a spate of launch mishaps. China, India and Japan are all developing potentially competing launchers, and SpaceX in the U.S. has more than $1 billion in commercial launch contracts for its privately developed, low-cost Falcon 9.

In November 2012, the European Space Agency agreed to proceed with the upgraded Ariane 5 Midlife Evolution (ME) and to continue studying a modular, lower-cost successor dubbed Ariane 6. Germany is backing the Ariane 5ME, to fly in 2017-18, and a decision has been set for 2014 on development of the French-backed Ariane 6, to enter service after 2020. French space agency CNES is studying three modular configurations for the Ariane 6, two solid-propellant and one all-liquid. All would use the Vinci cryogenic upper-stage engine under development for the 5ME.
  
Similar challenges face United Launch Alliance (ULA), which provides Atlas V and Delta IV launches for the U.S. government under the Evolved Expendable Launch Vehicle (EELV) program. The merger of Boeing and Lockheed Martin's launcher businesses to form ULA, satellite delays and NASA's withdrawal from the market have driven up launch costs under EELV.

SpaceX conducted the first of up to 12 commercial resupply missions for NASA in October 2012, its Falcon 9 launching the Dragon cargo capsule to the ISS.  Lockheed with the Athena, Orbital Sciences with the Antares and SpaceX with an upgraded Falcon 9 have formally stated their intent to certify their boosters for national security missions. Once certified, they will be allowed to compete for launches. These could begin in 2014.

While Europe sees India and Russia as its main competitors in the future, it is SpaceX that continues to shake up the market. The company conducted its first two resupply missions to the International Space Station (ISS) in 2012 using the Falcon 9 booster and Dragon cargo spacecraft, and is on contract to fly 20,000 kg to the ISS through 2015.

CCiCap is a commercial adjunct to NASA's plan to develop the heavy-lift Space Launch System (SLS) to support human spaceflight missions and replace the space shuttle, which was retired in 2012. The SLS is intended to launch the Orion multi-purpose crew vehicle—development of which began under the now-canceled Constellation program—and other equipment into deep space.

A first uncrewed flight of the SLS is planned for 2017, followed in 2021 by the first launch of the Orion capsule and up to four astronauts. The SLS will use RS-25 engines from the shuttle and the J-2X upper-stage engine developed for the canceled Ares I booster. The initial 70,000 kg-payload version of the SLS will use two shuttle-style solid-rocket boosters. The evolved version, with up to a 130,000-kg payload, will use advanced liquid or solid boosters.

As NASA develops the SLS, Russia and China will be the only countries able to transport humans into space. While Russia continues to fly the Soyuz to ferry crews to the ISS, China is developing a manned space program that includes the Shenzhou capsule (four crewed flights to 2012), Tiangong laboratory (first launch in 2011), and a space station that is planned to be launched in sections between 2015 and 2020.

A new era in commercial space transportation is open.


ASA's Robotic Refueling Demo Set to Jumpstart Expanded Capabilities in Space

This artist's concept shows a scene from the upcoming refueling demo aboard the International Space Station. The Robotic Refueling Mission, or RRM, Multifunction Tool (right) removes a cap from the RRM module (left).

In mid-January, NASA will take the next step in advancing robotic satellite-servicing technologies as it tests the Robotic Refueling Mission, or RRM aboard the International Space Station. The investigation may one day substantially impact the many satellites that deliver products Americans rely upon daily, such as weather reports, cell phones and television news.

During five days of operations, controllers from NASA and the Canadian Space Agency will use the space station's remotely operated Special Purpose Dexterous Manipulator, or Dextre, robot to simulate robotic refueling in space. Operating a space-based robotic arm from the ground is a feat on its own, but NASA will do more than just robotics work as controllers remotely snip wires, unscrew caps and transfer simulated fuel. The team also will demonstrate tools, technologies and techniques that could one day make satellites in space greener, more robust and more capable of delivering essential services to people on Earth.

Why Fix or Refuel a Satellite?

"Every satellite has a lifespan and eventual retirement date, determined by the reliability of its components and how much fuel it can carry," explains Benjamin Reed, deputy project manager of NASA's Satellite Servicing Capabilities Office, or SSCO.

Repairing and refueling satellites already in place, Reed asserts, can be far less expensive than building and launching entirely new spacecraft, potentially saving millions, even billions of dollars and many years of work.

The RRM demonstration specifically tests what it would take to repair and refuel satellites traveling the busy space highway of geosynchronous Earth orbit, or GEO. Located about 22,000 miles above Earth, this orbital path is home to more than 400 satellites, many of which beam communications, television and weather data to customers worldwide.

By developing robotic capabilities to repair and refuel GEO satellites, NASA hopes to add precious years of functional life to satellites and expand options for operators who face unexpected emergencies, tougher economic demands and aging fleets. NASA also hopes that these new technologies will help boost the commercial satellite-servicing industry that is rapidly gaining momentum.

Besides aiding the GEO satellite community, a capability to fix and relocate "ailing" satellites also could help manage the growing orbital debris problem that threatens continued space operations, ultimately making space greener and more sustainable.

What's Next in Robotic Satellite Servicing?

The satellite-servicing concept that RRM is advancing is one that NASA has been developing for years. Beginning with the Solar Maximum repair mission in 1984, the servicing philosophy paved the way for five successful astronaut-based missions to upgrade and repair the Hubble Space Telescope and has been practiced more recently in spacewalks to assemble and maintain the space station.

On July 12, 2011, spacewalking astronauts Mike Fossum and Ron Garan successfully transferred the Robotic Refueling Mission, or RRM, module from the Atlantis shuttle cargo bay to a temporary platform on the International Space Stations Dextre robot.

With the RRM on the space station and a robust technology development campaign being conducted on the ground, NASA is testing capabilities for a new robotic servicing frontier. Since 2009, the Satellite Servicing Capabilities Office at NASA's Goddard Space Flight Center in Greenbelt, Md., has been aggressively advancing the robotic technologies for a free-flying servicer spacecraft that could access, repair and refuel satellites in GEO.

To this end, the SSCO team has been studying a conceptual servicing mission and building technologies to address uncharted territory such as autonomous rendezvous and docking, propellant transfer systems for zero gravity and specialized algorithms (computer commands) to orchestrate and synchronize satellite-servicing operations. A systems engineering review on this conceptual mission was recently conducted with positive responses from peer experts and external participants.

Reed and the SSCO team see many applications across NASA for these new, game-changing capabilities.

"The technologies we're building to help rescue satellites in five years could be the very same ones used to clean up space ten years in the future or save a spacecraft on the way to Mars 30 years from now," says Reed. "NASA is acting today to ensure that we have the capabilities America needs for the future. With satellite servicing technologies, we're bolstering the agency's long-term strategy as we invest in near-term tactical technology investments. RRM is just the beginning."

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Friday, December 14, 2012

'SPACE' in News

Do We Really Need So Many Satellites?
US Agency Admits Underutilizing Resources

While the international debate about space debris mitigation is getting ever more intense, one might wonder whether all the cubesats, constellations, or communication satellites newly launched or planned are really needed. Are all the existing capacities necessary and fully utilized? New concerns might arise after the revelations, made by the U.S. Defense Information Systems Agency (DISA) representative Cindy Moran at the Global Milsatcom Conference on November 28, were reported by Space News.
According to Moran, out of the $ 1 billion commercial satellite capacity purchased by the U.S. Government every year, only 3-5 % on average is used on a daily basis. “It’s like buying a Smartphone, with a contract, and then never turning it on!” said Moran, the director of network services at DISA. Especially the American tax payers probably won’t be particularly happy upon hearing such news.
While the unpredictable nature of military usage of satellite telecommunication services is definitely one part of the problem, additional responsibility for the incredible waste of satellite bandwidth lies on nothing else but poor management. “I don’t get to reallocate across the spectrum if the customer that is ostensibly using it is not using it,” Moran said. “I am buying at the commercial tariff rate.”
The U.S. Government, and the Department of Defense in particular, is the world’s largest customer for short-term leases of commercial satellite capacity. As Moran explains, various governmental users don’t coordinate with each other when it comes to sharing the purchased satellite bandwidth capacity. Moran fears that such inefficiency, together with other blunders, might affect the future willingness of the U.S. Congress to increase funding. “Having satellites in orbit and ready to operate well before the associated ground infrastructure is ready does not give us a whole lot of credibility when we go back to them to ask for additional funding for satellite capacity,” she said.
Moran believes that changes proposed recently by DISA regarding the procedures for satellite capacity purchases might help tackle the problem. The new procurement tool, called the Future Commercial Satellite Communications Services Acquisition (FCSA), opens the system to new players allowing greater competition and quicker access to emerging technologies. The main drawback of the new arrangement is increased length of contract negotiating and making satellite capacity available. Also the move to the Internet Protocol planned by DISA is expected to improve the situation.Epsilon Rocket Data Stolen by Hackers

On Friday November 30th, the Japanese Aerospace Exploration Agency (JAXA) announced an investigation into a possible data leak relating to its Epsilon rocket due to a computer virus.
“The data stolen from the space agency included information about the Epsilon, a solid-fuel rocket still under development,” said New York Times reporter Martin Fackler. “While the Epsilon is intended to launch satellite and space probes, solid-fuel rockets of that size can also have a military use as intercontinental ballistic missiles.”
The news, first reported by the Kyodo news agency, stems from discovery of spyware on November 21 on one of JAXA’s personal computers at Tsukuba Space Centre, northeast of Tokyo. Although the computer was immediately disconnected from the local area network, the virus was found to be secretly collecting data to be sent outside the agency.
Epsilon is a small next-generation solid propellant rocket. The program started in 2007 and the maiden flight has been already scheduled for autumn 2013. Epsilon is supposed to join the existing H-IIA and H-IIB liquid engine rockets, providing Japan the capability of competing with the US, Europe and Russia as a satellite launch vehicle provider. Epsilon will also feature a new cost-saving technology. In fact, the rocket is going to have the capability to be remotely controlled by a personal computer.
The security breach, which included engine parameters,  involved more than data just on Epsilon. According to an agency statement, data on H-IIA, H-IIB, and the Epsilon’s ancestor, MV-5 may also have been leaked. The investigation is now focused on finding the malware’s origin. JAXA cannot confirm if the virus is a stray one or the result of a hacker attack. However, this situation is not entirely new. In early September, it was reported that many Japanese defense companies were targeted by similar information-stealing viruses. The origin of some of those has been traced to China.
According to Motohiro Tsuchiya, professor at Keio University and member of a government cyber security advisory body,  attacks on the Japanese system are increasingly sophisticated and subtle. JAXA has been targeted before, when technical specifications for the H-IIA were stolen from a laptop in 2011. Nor is Japan the only target. In 2008 a virus was found on a laptop aboard the International Space Station and in 2007-2008, two of NASA’s satellites were hacked. More recently, British Aerospace has confirmed that its computers were breached by Chinese hackers stealing details about the US F35 Joint Strike Fighter.

Related stories: Japan Epsilon Rocket Data Leak Is Probed By Nation's Space Agency

Japan confesses data breach on Epsilon rocket

Delta 4 Investigation Uncovers Anomaly Sequence; X-37B Cleared for Launch

On October 4, a United Launch Alliance (ULA) Delta 4 rocket took off, carrying a GPS satellite. Low thrust in its upper stage could have resulted in a misplaced satellite that day but for a successful compensation using reserve fuel. As a result of the anomaly, Delta 4 flights were delayed, as was flight of the X-37B which launches from an Atlas 5 using the same engine family, the RL-10, that experienced the anomaly.
It now seems that an investigation has uncovered the main events of the anomaly, as reported by Spaceflight Now. When the Delta 4′s upper stage ignited, a leak began above the trust chamber. Each of the subsequent burns produced less thrust than planned due to the leaking propellant. In what turned out to be a combination of good planning and sheer luck, the closed loop guidance system observed the subnormal thrust and compensated using reserves. The satellite was luckily below Delta 4′s lift capacity, so there was more reserve available to draw upon than is usually the case. After placing the GPS satellite in its intended orbit, the upper stage even had about 30 seconds of burn left in it. “We were later informed by our GPS customer that this was the most accurate placement of the three GPS 2F spacecraft that have been launched,” said  ULA vice president of mission operations Jim Sponnick.
The guidance system more or less saved this mission on its own, since mission control would have been unable to develop a solution in th available time. In fact, they were not able to precisely quantify the leak until after the fact, leaving great uncertainty at the time as to whether the propellant reserves would be adequate to compensate.
ULA has still not discovered what could have caused the leak in the first place. They are in the process of narrowing potential causes down from an initial brainstorm of over 500. One of the first steps was to evaluate which of these potential causes would have crossover – i.e. would also impact the RL10A-4 engine used by Atlas 5′s upper stage. Officials with both ULA and the US Air Force seem convinced that crossover causes have been adequately assessed, since they have put the third X-37B flight back on the launch pad.
The X-37B Orbital Test Vehicle 3 (OTV-3) space plane is now slated to launch on the afternoon of December 11. This is the third test flight of the snub-nosed shuttle-esque vehicle and the first reflight of an OTV. As usual, the Air Force is keeping mum on the duration and mission of the reusable space plane. The last X-37B test flight remained aloft for 468 days, well beyond its designed flight duration of 270 days.
All ULA launches are expected to be back on scheduled by mid-February.
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Breeze-M Fails Again

On December 8 at 17:13 Moscow time, a Proton-M rocket with Breeze-M upper stage launched from Baikonur Cosmodrome carrying Yamal-402, a communications satellite built by Thales Alenia Space for the Russian-owned Gazprom company. Instead of announcing successful separation nine hours later, International Launch Services (ILS) found itself announcing an anomaly: “Preliminary flight information indicates that the 4th and final burn of the Breeze-M engine ended about four minutes early and subsequently separated [from] the spacecraft.” 
It seems that it was not just the final stage that was anomalous. The three preceding maneuvers and external tank separation had been concluding increasingly earlier than scheduled, Anatoly Zak reports. The result: Yamal-402 was placed in a perigee of 3,100 km instead of the intended 7,470 km. It is reported that the apogee is pretty close to the intended 35,696 km and two maneuvers executed by the satellite’s own propulsion system may be sufficient to place it in an operational orbit. The maneveurs are expected to reduce Yamal-402′s operational life by about four years.
This is the third Breeze-M failure Khrunichev has suffered in the past 16 months. The space industry restructuring prompted by the last incident has not even begun, while a new investigation is being opened into the latest Breeze-M disaster. ”In parallel with the State Commission, ILS will form its own Failure Review Oversight Board (FROB),” said international Proton marketer ILS in a statement. ”The FROB will review the commission’s final report and corrective action plan, in accord with U.S. and Russian government export control regulations.” Fortunately, it is unlikely that a debris event will occur this time around, unlike the October 16 explosion that followed an August 6 Breeze-M failure.
Proton manufacturer Krunichev executed three successful launches between the two most recent failures, but that is unlikely to reassure Mexican satellite operator Satmex, whose December 28 launch will almost certainly be postponed. Satmex’s business is already on shaky ground, and inability to put Satmex 8 in place before Satmex 5 runs out of fuel in May 2013 could ring the company’s death knell. Satmex 5 was launched in 1998 and lost its backup propulsion system several years ago.

The Russian Pioneers of Space Safety: Reinventing Rocket Design

After working in rocket design for 23 years, one may think it could be difficult to re-invent the profession, but that wasn’t true for Professor Valery Trushlyakov. Trushlyakov contributed to the design of Cosmos 3M, one of the most reliable launchers ever built but also nowadays  one of the major contributors to  low Earth orbit debris, having left  many rocket bodies orbiting uncontrolled. Trushlyakov is now leading a project with the aim to avoid creating new debris from launchers’ upper stage but also to clean the existing space debris.
The gasification system, developed by Trushlyakov and Victor Shalaj   for reducing the harm from toxic fuel in Proton’s first stage was the starting point for a new system concept, able not only to make a rocket clean in flight, but also to direct it to a specific landing location. In fact, retrieving rocket body parts that have fallen to Earth is still an issue, especially if you consider the geography of the Russian dropping zone, with mountains, lakes, immense taiga, frozen for the greater part of the year.

Trushlyakov explained that they soon realized that the technology used to reduce toxic waste for the rocket’s fuel, could also be used to direct its landing. Every rocket has a certain percentage of propellant  not used after the separation of the stage as margin. This unused propellant in the end represents a loss in the total payload capacity.  The system that Trushlyakov and his team studied, in cooperation with Politecnico di Milano, is an Autonomous Onboard De-orbiting System or ADOS. The goal of ADOS is to take this  propellant margin and make it useful.
The liquid propellant  in the tank, once gasified (link to the previous article), is used  to feed a Gas Rocket Engine (GRE). The GRE was built in the ’60s by Valentin Petrovich Glushko, principal soviet designer of rocket engine, but it was never used. This approach both reduces the harm from pollutant products and redirects the rocket to a safe and more accessible drop point. For upper stages this system can also be  used to give additional burns to de-orbit the stage after the payload’s deployment with few maneuvers. ADOS can basically be used for every liquid stage, increasing safety and decreasing, at least theoretically, the impact of future launches on low Earth orbit.
This is not a totally new concept. The Americans, Japanese, and French have explored use of residual fuel for controlled re-entry of the 2nd  stages of the Delta IV, HII-B, and Ariane 5 respectively. However, since these rockets use, liquid hydrogen-oxygen (LOX/LH2) as fuel/oxidizer, it is less problematic to re-start the main liquid propulsion engine. Russian space launchers use instead either high boiling toxic fuel such as UDMH (Proton-M, Rokot) or kerosene (Angara, Zenit, Soyuz). Ensuring the restartability of the main engine with such fuels is more problematic and this is why Trushlyakov started developing the ADOS concept in the first place.
The research, now in the design phase, is being conducted with Roscosmos and Samara Space Centre, for the improvement of Soyuz 2.1B, a green and lighter version of the Soyuz-2 family. According to the results so far, the ADOS system can produce a ∆V of 370 m/s for the 1st stage and 500 m/s for the 2nd stage using just the remnant propellant in the tanks
Although so far the initiative has been Russian in origin, Trushlyakov emphasizes the need for an international effort from every country involved in space. He and his team are ready to work with international teams to develop similar system for other launchers, whenever they demonstrate interest.
ADOS addresses the need to keep near-Earth space free of new debris. But since Earth orbit has been already polluted with tons of debris since 1957, mitigation might not be the only approach to address the space debris issue. In the third and final installment in this series, we will learn of the steps Trushlyakov is taking to meet this looming hazard and Shalaj’s prognosis for the Russian Space industry.



New ESA Safety Standard Now Available



The European Space Agency (ESA) has just issued Safety System Engineering: Safety Technical Requirements for Human Rated Space Systems, a new human spaceflight standard. Chapter 1 describes the scope of the document:

"This document establishes the requirements applicable to the development and operations of human‐rated space systems for ESA human spaceflight missions. These requirements are intended to protect the public, the ground and flight personnel, the space system, any interfacing system, public and private property and the environment from hazards associated with flight operations, and with ground operations with fight personnel on‐board the system (e.g. launch pad operations)."            
 Open publication     -  
Other European Document resources on Human Spaceflight