OrbitalHub

Credits: NASA

On January 3, 2004, the MER-A rover a.k.a. Spirit landed on Mars at the Gusev Crater. The second rover, MER-B a.k.a. Opportunity, followed twenty-one days later and landed at the Meridiani Planum.

They were both designed to operate for three months on the surface of Mars. Five years later, they are still operational and NASA has planned new missions for them.

Considering the harsh conditions on Mars, NASA’s twin rovers have accomplished remarkable things: they have returned a quarter-million images, driven more than thirteen miles, climbed a mountain, descended into impact craters, and survived dust storms. Using the Mars Odyssey orbiter as a communication relay, the rovers have sent more than 36 GB of scientific data back to Earth.

“These rovers are incredibly resilient considering the extreme environment the hardware experiences every day,” said John Callas, JPL project manager for Spirit and Opportunity. “We realize that a major rover component on either vehicle could fail at any time and end a mission with no advance notice, but on the other hand, we could accomplish the equivalent duration of four more prime missions on each rover in the year ahead.”

Credits: NASA

Digging into the MER mission archive, one detail caught my eye. The rovers carry plaques commemorating the crews of Columbia and Challenger, and some of the landmarks surrounding the landing sites of the rovers are dedicated to the astronauts of Apollo 1, Columbia, and Challenger.

Spirit is carrying a plaque commemorating the STS-107 Space Shuttle Columbia crew, which has been mounted on the high-gain antenna of the rover.

The names of the STS-107 crew are inscribed on the plaque: Rick D. Husband, William C. McCool, Michael P. Anderson, Kalpana Chawla, David M. Brown, Laurel B. Clark, and Ilan Ramon. Their names are now looking over the Martian landscapes.

To further honor their memory, the landing site of the MER Spirit is called the Columbia Memorial Station.

Credits: NASA

Three of the hills surrounding the Columbia Memorial Station are dedicated to the Apollo 1 crew: Gus Grissom, Ed White, and Roger Chafee. Grissom Hill is located 7.5 km to the southwest of Columbia Memorial Station, White Hill is 11.2 km northwest of the landing site, and Chafee Hill is located 14.3 km south-southwest of the landing site.

The area where Opportunity landed in the Meridiani Planum is called Challenger Memorial Station, in memory of the last crew of the Space Shuttle Challenger: Francis R. Scobee, Michael J. Smith, Judith A. Resnik, Ellison S. Onizuka, Ronald E. McNair, Gregory B. Jarvis, and Sharon Christa McAuliffe. I remember that Sharon Christa McAuliffe was NASA’s first teacher in space.

“The journeys have been motivated by science, but have led to something else important,” said Steve Squyres of Cornell University, in Ithaca, N.Y. Squyres is principal investigator for the rover science instruments. “This has turned into humanity’s first overland expedition on another planet. When people look back on this period of Mars exploration decades from now, Spirit and Opportunity may be considered most significant not for the science they accomplished, but for the first time we truly went exploring across the surface of Mars.”

Credits: NASA

If you want free lecture notes, exams, and videos from MIT, without any registration required, you can find them at MIT Open Courseware.

MIT Open Courseware reflects most of the undergraduate and graduate subjects taught at MIT. One of the courses that caught my eye was an engineering course called Aircraft Systems Engineering.

Even if the formal title of the course is Aircraft Systems Engineering, the lectures are focused on Space Shuttle design. If you are a space enthusiast and have a technical background, you will probably enjoy these lectures.

The course was taught by Professor Jeff Hoffman and Professor Aaron Cohen.

Jeff Hoffman is a former Space Shuttle astronaut. He was a NASA astronaut from 1978 to 1997, having made five space flights and becoming the first astronaut to log 1,000 hours of flight time aboard the Space Shuttle. In 2001, Jeff Hoffman joined the MIT faculty, where he teaches courses on space operations and design and space policy. His principal areas of research are advanced EVA systems, space radiation protection, management of space science projects, and space systems architecture.

Aaron Cohen served as Director of NASA’s Lyndon B. Johnson Space Center in Houston, Texas. He was Manager of the Command and Service Module in the Apollo Spacecraft Program Office. In 1972, he was appointed Space Shuttle Orbiter Project Manager, responsible for design, development, production, and test flights. He also served for a year as the Acting Deputy Administrator for NASA.

One of the guest lecturers is Dale D. Myers. He was NASA Deputy Administrator between October 6, 1986 and May 13, 1989. In the first lecture of the course, Dale D. Myers gives a presentation on the beginning of the Space Shuttle program and describes how the external environment generated the requirements that forced the configuration of the Space Shuttle. This is a must-see, like any other lecture given by someone who has many years of experience under his/her belt. Watching this lecture reminded me of one of my professors back in university, who used to say that the must-have organ for a good engineer is the nose.

The course covers the subsystems of the Space Shuttle, including the requirements that shaped the design, the testing of each subsystem, and how they were operated. The structure of the orbiter, the thermal protection subsystem, the Space Shuttle main engines, landing and mechanical systems, the power systems, accident investigation, etc. are all covered by guest lecturers that were directly involved in the design and construction of the Space Shuttle.

I hope you enjoy the videos as much as I have. Happy New Year and all the best for 2009!

The awarded contracts are fixed-price indefinite delivery, indefinite quantity contracts. They will begin January 1, 2009, and are effective through December 31, 2016. SpaceX and Orbital each will have to deliver a minimum of twenty metric tons of cargo to the space station, and they will also have to deliver non-standard services in support of the cargo resupply, including analysis and special tasks as the government deems necessary.

SpaceX will service the ISS with its Falcon9/Dragon system.

“The SpaceX team is honored to have been selected by NASA as the winner of the Cargo Resupply Services contract,” said Elon Musk, CEO and CTO, SpaceX. “This is a tremendous responsibility, given the swiftly approaching retirement of the Space Shuttle and the significant future needs of the Space Station. This also demonstrates the success of the NASA COTS program, which has opened a new era for NASA in US Commercial spaceflight.”

Orbital will employ the Taurus II^TM medium-lift launch vehicle and the Cygnus^TM maneuvering space vehicle.

“We are very appreciative of the trust NASA has placed with us to provide commercial cargo transportation services to and from the International Space Station, beginning with our demonstration flight scheduled in late 2010,” said Mr. David W. Thompson, Orbital’s Chairman and Chief Executive Officer. “The CRS program will serve as a showcase for the types of commercial services U.S. space companies can offer NASA, allowing the space agency to devote a greater proportion of its resources for the challenges of human spaceflight, deep space exploration and scientific investigations of our planet and the universe in which we live.”

Both Orbital and SpaceX have issued press releases with more details about the CRS contracts.

Credits: NASA/JPL

Carnival of Space #84 is hosted by Next Big Future.

This week you can read about space solar power, oceans on Venus, Mars rovers, the top ten astronomy pictures of 2008, the AGU Conference, and many more interesting topics.

OrbitalHub has submitted an update on the Mars Reconnaissance Orbiter science mission.

Credits: SpaceX

Another critical milestone has been reached by SpaceX with the arrival of Falcon 9 hardware at Cape Canaveral.

After the full mission-length firing test of the Falcon 9 first stage engines and the firing test of the Dragon maneuvering thruster, the arrival of the Falcon 9 first stage fuel tank fulfills SpaceX’s commitment to having Falcon 9 hardware at Cape Canaveral by year-end.

“Christmas has arrived a few days early for our team at the Cape,” said Brian Mosdell, Director of Florida Launch Operations for SpaceX. “The packages measure extra large this year, and they will keep everyone busy in the coming weeks.”

All of the Falcon 9 elements and the ground support hardware have already left the SpaceX manufacturing facility in Hawthorne, California. The hardware will make its way to the launch site at Cape Canaveral over the next two weeks. The Falcon 9 will then be assembled on horizontal and raised to vertical on the custom built erector.

Credits: SpaceX

There are four Falcon 9 launches scheduled for 2009. Two of these launches are demonstration flights with the Dragon spacecraft as part of the NASA Commercial Orbital Transportation Services (COTS) competition. A total of three flights of the Falcon 9/Dragon launch system will be conducted under the agreement, in order to demonstrate cargo delivery capability to the International Space Station (ISS).

NASA’s agreement with SpaceX can be extended to include demonstrating transport of crew to and from the ISS.

“2008 has been a year of rapid progress for SpaceX,” said Elon Musk, CEO and CTO of SpaceX. “The delivery of the Falcon 9 to the Cape is a major milestone in designing and deploying the most reliable, cost-efficient fleet of launch vehicles in the world. I applaud our SpaceX team who has worked 24/7 to make this happen.”

SpaceX has made available a video of Elon Musk giving a tour of the SpaceX Falcon 9 launch site at Space Launch Complex 40, Cape Canaveral AFS, Florida.

Credits: XCOR Aerospace

XCOR completed the first test fire of the rocket engine that will power the Lynx suborbital launch vehicle. The test was performed on Monday, December 15, 2008, at XCOR’s rocket test facility located at the Mojave Air and Space Port.

The rocket engine is designated as 5K18. The engine is powered by liquid oxygen and kerosene and can produce up to 2900 lbf of thrust.

The 5K18 is the eleventh in a series of rocket engines that XCOR has designed and fired during its nine years of existence.

“Today’s successful hot fire marks an important step forward in building the Lynx,” said XCOR CEO Jeff Greason. “The 5K18 builds on our previous experience in designing and building reliable, durable and fully reusable rocket engines from 15 lbf thrust up to 7500 lbf, that will make it possible to provide affordable access to space.”

The Lynx will use four 5K18 engines and it will be able to perform suborbital flights. Space tourists can buy tickets to fly on the Lynx for $95,000 through RocketShip Tours. The full press release is available on the XCOR Aerospace web site.