OrbitalHub

Credits: NASA/JPL/Arizona State University

You know the frustration you experience when the new hit of your favorite band takes too long to download on your iPhone? Imagine 30 years from now (an optimistic estimate)… you are one of the happy colonists who work around the clock to build one of the first outposts on Mars.

At the end of your shift in the hydroponics, you head back to your luxurious 20mx10m quarters (the shoebox, as your relatives back on Earth like to call it), have a hot shower, and a delicious vegetarian dinner while enjoying the view over the Valles Marineris (the $100 million view, as you like to call it). You receive an email with a link to the new hit of your favorite Earth band, and after clicking on the link in your favorite Internet browser, you download the song in less than one second.

What’s wrong with this scenario? It describes what software engineers would call a wonderful user experience, but something is wrong with this picture… what is it?

One short story might give you a hint. In January 2004, when the two Mars Exploration Rovers, Spirit and Opportunity, landed on Mars, you could watch videos of the scientists in the mission control room at JPL cheering when receiving confirmations of successful landings. The detail that might have escaped you is that those confirmation messages traveled around 20 minutes through interplanetary space before reaching the room at JPL. The scientists were cheering at JPL 20 minutes after the landings happened. If anything went wrong, the bad news would have reached Earth too late to do anything about it. This kind of explains why the engineers that designed and built the rovers had to make sure that the rovers themselves were capable of making some decisions on their own.

To go back to our sci-fi novel attempt in the first paragraph, the little detail that is misplaced in our story is that the time delay is not present. Our colonist clicks on the link to a server which is somewhere on Earth and the download is performed in no time.

For someone who has a basic understanding of protocol stacks (i.e. HTTP/TCP/IP), it is obvious that it would take quite some time to download a file from a server located on Earth to our Mars colony. All of a sudden, the ACK packets have lost their charm.

No reason to worry. Even if Mars outposts are far in the future, time and effort is spent on finding solutions for such communication problems in the present. The challenges seem overwhelming: very long delays, possible communication disruptions, and significant loss due to big bit error rates. A leap is necessary. The present protocols and architecture on which Internet relays have been designed assuming continuous and bi-directional paths, short round-trip times, and small error-rates.

One architecture that promises to solve the problems inherent to our scenario is the Delay Tolerant Networking (DTN) architecture, proposed in RFC 4838. A physical architecture that could solve the problems mentioned above is also proposed by Takashi Iida (Tokyo Metropolitan University), Yoshinori Arimoto (National Institute of Information and Communications Technology), and Yoshiaki Suzuki (NEC Corporation). The architecture would include clusters of communication satellites in orbit around Earth and Mars and relay satellites located at the Lagrangian points L4 and L5 of the Sun-Earth system. The relay satellites would make communication between Earth and Mars possible even when Mars is behind the Sun. Just a smart placement of relay satellites does not do the trick. In order to increase the responsiveness of the network, mirroring of data is also necessary.

You can find more information about space data systems on The Consultative Committee for Space Data Systems website. Other good resources include The InterPlaNetary Internet Project, and The Delay Tolerant Networking Research Group.

Credits: NASA

NASA’s GRAIL mission will be one of the few missions to utilize the chaos associated with the subtle gravitational forces between planets in order to reach lunar orbit. The mission is scheduled to launch in 2011 and will use a low-fuel trajectory to the Moon.

Ed Belbruno, the first to use weak stability boundary theory to design trajectories for space missions, has agreed to answer some questions for OrbitalHub readers.

DJ: You graduated in mathematics from New York University, and received your PhD in mathematics from New York University’s Courant Institute. As a mathematician, how did you develop an interest in celestial mechanics?
Ed Belbruno: I was always interested in space since I was very young, going back to 4 years old. When I went to undergraduate school, also at NYU, I was a joint chemistry and mathematics major. At that time I was also interested in astrochemistry. When I got my BS, I went on to the Courant Institute and immediately wanted to get involved in an area of mathematics involved with space. I asked around, and found that there was a very famous mathematician there who was considered to be one of the leaders in the world in the subject, Juergen Moser. I learned that he was also a leader in a field called theoretical celestial mechanics. So, I asked to work with him and he agreed. For me it was great because I loved mathematics and I loved space. I am also an artist, and my early paintings involved a lot of space scenes. My being drawn to celestial mechanics was a natural thing.

DJ: I think of celestial mechanics as a precise discipline… the word CHAOS from the titles of the presentations you are giving would make any aerospace engineer nervous. Is this a misnomer or it is really the foundation for the new class of trajectories you designed?
E.B.: When I arrived at JPL in 1986, I was previously an assistant professor of mathematics at Boston University. I arrived at JPL and found myself at a leading space center – to work on the following missions: Galileo, Cassini, Magellan, Ulysses. My job was to do trajectory design. I noticed that all these missions and all the others I saw in the past, relied mainly on Hohmann transfers which are straightforward trajectories found using algebra. They are very well behaved and linear in nature. There was nothing chaotic about them. I noticed that in the field of astrodynamics, which designs trajectories for spacecraft, that advanced mathematical techniques using a general subject called dynamical systems theory, which includes chaos theory, was never used. I figured if you could incorporate that into astrodynamics, new exciting low fuel trajectories could be found. No one at JPL really believed me, but in 1986 I started investigating whether or not one could use the subtle gravitational interactions between the Earth and Moon to get a spacecraft into orbit about the Moon without the use of rocket engines – that is, automatically. This had never been done before. I also found that chaos methods had to be employed to do this since the gravitational interactions between the Earth and Moon give rise to chaotic motions for a spacecraft. I succeeded in 1986 and found a way to do this for a mission study at JPL called LGAS – Lunar Get Away Special, where I found a 2-year route to the Moon with automatic capture at the Moon that was chaotic. This was the first time chaos was used for a lunar capture for a spacecraft – or capture at any planet. It was the first systematic use of chaos in astrodynamics as far as I know. The LGAS design was eventually used by the European Space Agency for their SMART-1 lunar mission in 2004. In 1991 I found a 3-4 month route to the Moon using automatic chaotic capture for Japan’s Hiten mission. This transfer first moves out to 1.5 million kilometers from the Earth, then falls back to the Earth-Moon system and into automatic ballistic capture about the Moon. This same transfer type is going to be used for NASA’s GRAIL mission in 2011. All these trajectories that go to automatic capture at the Moon are chaotic since they are very sensitive to small changes.

DJ: Was there any resistance from the scientific community when you first published the results of your research?
E.B.: Yes. When I first started designing routes to the Moon that employed automatic capture (or ‘ballistic capture”) back in 1986-1990 at JPL, that employed chaos as described above there was a good deal resistance, in spite of publishing papers and demonstrating actual trajectories via computer simulations. This is because no one had ever heard of this before, and also, chaos was a not a term that was desired to be associated with space travel. In 1990 I had a disagreement at JPL over this and found myself looking for another job. Luckily, soon, a couple of months after that while still at JPL, ready to leave for another job, I was able to take part in the rescue of a Japanese lunar mission, and get its spacecraft, Hiten, successfully to the Moon on one of these new transfers employing ballistic capture, that vindicated my work – and saved my career.

DJ: Are there any computational challenges that make the class of trajectories you designed difficult to compute? Is the lack of computational power the reason they are a recent development in celestial mechanics?
E.B.: Yes, they require more accuracy than is typically used since the motions involved are very sensitive in nature. So, different methods, other than classical optimization methods, have to be employed. These methods involve using ideas from chaos theory and dynamical systems and making use of regions that support chaotic motions called weak stability boundaries. Once the motions in these regions were better understood, then the methods have been refined and the trajectories can be more easily generated. More powerful computers were/are not necessary. What was necessary were new numerical methods.

DJ: I believe solar sails would match the profile of low-energy space missions. Have you ever considered applying the weak stability boundary theory in order to design trajectories for spacecraft propelled by solar sails?
E.B.: I agree that solar sails would be a great thing to use with these low energy trajectories. I have considered them and made some designs actually, but never designed any missions using them.

DJ: Considering your experience in designing low-cost trajectories for lunar missions, have you been contacted by any Google X-Prize team for assistance? How feasible would it be for a Google X-Prize team to use such a trajectory (costs aside, they would have to launch at least three months before any other team in order to make an attempt to win the prize)?
E.B.: Yes, I was on the so-called ‘Mystery team’ for the Google X-prize from latter 2007 to latter 08. The base design was to use one of these low energy transfers to the Moon of the type that Hiten used, described earlier, and that GRAIL is planning to use. I don’t know how feasible it would be to use this trajectory – certainly no more or less feasible than using a direct Hohmann transfer. It ultimately depends on the launch vehicle, which are very expensive. I don’t think the three months flight time is a factor since it is very unlikely that there will be that kind of time pressure considering how difficult it is to send something to the Moon for a private company.

DJ: What other space missions are you currently involved in? Can you provide a brief description?
E.B.: I am involved, indirectly, with NASA’s STEREO solar science mission in the sense that they have recently redirected that mission to do an excursion to L4, L5 of the Earth-Sun to try and verify a theory of Richard Gott and myself on the origin of the Moon. This theory was published by Gott and myself in 2005 (see http://www.edbelbruno.com) in the Astronomical Journal entitled, Where Did the Moon Come From? In that paper we hypothesized that the giant Mars-sized impactor that is thought to have hit the Earth to form the Moon, billions of years ago (that Hayden has a fabulous show on), actually originated at special locations in space. These locations are called Earth-Sun equilateral L4, L5 points, 93 million miles from the Earth in either direction, on the Earth’s orbit. The impactor is called Theia. It is felt that if our theory is correct that residual material and perhaps asteroids exist near L4, L5. To verify this, the STEREO mission, consisting of two spacecraft, are being redirected to go to these points to investigate the possible remains of the mysterious planet called Theia that may have been there long ago. The NASA press release explains this in detail. The spacecraft are due to arrive at L4, L5 in September, October this year and are currently approaching these locations.

DJ: It is not often you meet someone who is both an artist and a mathematician. How do these roles complement each other?
E.B.: When I do paintings, I find that I have to completely turn off any logical mathematical way of thinking and work on a subconscious level. This is exactly the opposite of working mathematically where you have to be very logical and work mostly with the conscious part of your mind. These two processes are totally different. There is a little subconscious thought when doing mathematical/scientific work, of course, but you have to pay close attention to deductive reasoning. In doing a painting, especially abstract expressionist painting, you have to avoid as much as possible deductive reasoning and be very spontaneous without thinking, which would ruin the painting. I have found it challenging to work in these two different ways – but now I can do it fairly easily.

Credits: Linda Gambone

If you happen to be in New York on July 20, 2009, you can attend the presentation A New Path To The Moon and Beyond Using Gravitational Chaos, at the Hayden Planetarium Space Theater, American Museum of Natural History.

Ed Belbruno will present the weak stability boundary theory and the alternative approach to space travel he developed in the 1980s.