July 12, 2010
'Smart textile ears make the eyes blink. Build your own!'
From the website:
Smart, simple Japanese design.
Round with a flat base to give the frame stability.
The inside is lined with a double layer of clear polymer.
Use this 3-D frame to exhibit and protect your little treasures.
All you do is open the frame, separate the layers, put in your object, and close the frame.
17cm W x 16.5cm H x 3.5cm D (7" x 6.5" x 1.4").
'When origami meets rocket science'
Origami master Robert J. Lang, 49, was a laser physicist at NASA's Jet Propulsion Laboratory before moving to a private technology firm in Silicon Valley.
In 2001 he threw it all overboard in favor of origami.
Rachel Saslow's May 11, 2010 Washington Post Health & Science section front page story about Lang's remarkable journey follows.
Photos of Lang's work appear above and below.
Robert J. Lang had a good career as a laser physicist. He worked at NASA's Jet Propulsion Laboratory, researching semiconductor lasers used in fiber-optic communications, before switching to a private technology firm in Silicon Valley, where he held positions such as chief scientist and vice president of research and development.
Then in 2001, he gave it all up. To fold paper.
Lang, 49, is an origami master. Paper cranes? Pshaw. Try a rattlesnake with 1,500 scales, a life-size replica of comedian Drew Carey or an American flag that was photographed for the New York Times magazine. Lang is pushing the limits of what one can make by folding paper, but he's also a leader in an emerging field of study called computational origami, which he boils down to this question: "How do you use rules and math to create an object of art?"
"In both origami and science, you're discovering patterns and relationships that, in a sense, already existed before we discovered them," Lang says. "There's a joy of discovery and of being the first explorer in this little nook."
He and others are using the Japanese art form to solve scientific problems. About 10 years ago, for instance, Lang collaborated with Lawrence Livermore National Laboratory to design a telescope lens that could go to space. Origami principles were ideal for the task because the lens, called the Eyeglass, needed to be big -- about the size of a football field -- once in space but also small enough to be shot into orbit by a rocket. A prototype demonstrated that hinged panes of glass could be used to compact the lens down to dimensions of no more than about 13 feet without degrading the optical performance. But the Eyeglass was never sent into space for lack of funding.
Lang has also worked on computer models for folding car air bags. Simulating air-bag deployment is important because otherwise auto manufacturers would have to crash a lot of cars to determine which ones are safe -- an expensive prospect.
Oxford University researchers have used origami techniques to design stents, which must be small enough for doctors to thread through a blood vessel but then pop open big enough to hold the artery or vein open.
"The things we do for fun and pleasure turn out to have practical applications, and in the case of origami, it might save a life," Lang says.
An updated tradition
Art historians aren't sure when origami started, but traditional designs such as cranes and boats existed in the 1700s. The craft didn't change much until the middle of the 20th century, when Akira Yoshizawa inspired a renaissance in paper folding.
Yoshizawa, who died in 2005, developed a language of arrows and lines to show people how to fold different designs. Yoshizawa's instructions included no words, so anyone could understand them.
In the 1990s, the craze for origami morphed into what origamists refer to as "The Bug Wars." After figuring out that it was possible to fold paper into the shape of an insect, origamists began to one-up one another. Someone would fold a beetle with six legs, someone else would create one with eight legs and two antennae, and so on. The Bug Wars have "never really ended," says Lang. In the past few years, he has folded a flying katydid and two praying mantises mating.
There are different genres of origami so there are no "rules," per se, but Lang mostly creates single-sheet origami without any cutting, taping or gluing.
In 2003, Lang published "Origami Design Secrets: Mathematical Methods for an Ancient Art," a book that has become the bible for complex origami designers; he calls it his magnum opus. (He has also published seven books of folding instructions.) The most recent addition to his oeuvre is Opus 571, a surfer on a surfboard folded from a dollar bill, a design he created for an advertising campaign for The Post. Lang's very first origami model was a variation on the traditional boat, which he designed at age 10.
While it might seem that a career as a Silicon Valley physicist would be more profitable than full-time origamist, Lang has no trouble making ends meet, with a full schedule of lectures plus book royalties, scientific commissions, art sales and commercial advertising projects, including origami creations for McDonald's, Mitsubishi and Toyota.
The wonk factor
Lang isn't the only math and science wonk enchanted by paper folding.
"I remember being 10 years old and unfolding an origami crane and looking at the crease pattern and thinking, 'There are all these nice geometric lines and points. There's got to be math here,' " recalls Tom Hull, an associate professor of mathematics at Western New England College in Springfield, Mass. "But I had no clue what it was, because I was 10."
Today, Hull uses origami when he teaches, finding ways to tie it into to concepts in calculus, number theory, geometry and algebra. He says it's a quick way to engage his students and to help them understand vague concepts in a visual way. In 2006, he published "Project Origami," a book filled with activities that teachers can use in math classes.
"Kids are so afraid of math. The world is so afraid of math," Hull says. "But with origami, they're not thinking, 'I'm doing this scary math thing,' they're just folding paper. It's a neat way to break the barriers down."
While most advanced origamists turn to math to fold bigger and better models, Massachusetts Institute of Technology associate professor Erik Demaine turned to origami to find more difficult geometric problems to solve. In 1996, Demaine was starting a PhD in computer science at the University of Waterloo in Ontario (he was 15 at the time) and stumbled upon Lang's work. "I thought, 'Oh, that sounds cool. Maybe we can do something new.' "
Now, Lang and Demaine are working together on a mathematical proof of the tree method of origami design. (Their paper is so long now that they might end up publishing it as a book.) The tree method is the idea that origami models can be thought of as stick figures; for instance, an origami beetle's body is the trunk, and each leg is a branch. The proof would rule out the possibility that any origami figure could not be made using this method. Lang has released five versions of TreeMaker, a software program that allows origami artists to sketch stick figures and have their computer spit out a crease pattern that they can follow.
Separately, Demaine is researching the microbiological applications of origami. He suspects that the principles that govern origami might also dictate how protein molecules fold in our bodies -- a process that, when it goes wrong, has been linked to illnesses such as Alzheimer's and Parkinson's diseases.
"That would be the endpoint, to predict what nature is doing," Demaine says.
Demaine has three paper sculptures in the permanent collection at the Museum of Modern Art in New York, works that he created with his father, visual artist Martin Demaine. In 2003, he was awarded a MacArthur Foundation "genius grant" for computational origami. The $500,000 award cited him for "tackling and solving difficult problems related to folding and bending -- moving readily between the theoretical and the playful, with a keen eye to revealing the former in the latter."
"It was more the recognition and acceptance that were meaningful," Demaine says. "Computational origami was initially a very crazy idea, and yet it has so many practical applications."
Lang, meanwhile, continues to spread the origami way. At a recent lecture at the Walters Art Museum in Baltimore, Lang showed photos of his Black Forest Cuckoo Clock, a tree frog, a Roosevelt elk and more. Fittingly, the Walters partnered with Baltimore's Space Telescope Science Institute to bring him to the area.
"Handmade in England, each of these pewter utensils has a magnifying glass inserted into the head of the character to allow you to see your food more clearly or read the fine print on a menu."
[via Running Dive]
BehindTheMedspeak: Should you friend your psychiatrist?
Before you get your baggies in a twist, consider that it's quite possible she/he's already googled you — so why not go all in?
From the website:
This small light is made out of a classic white china cup from Arzberg and a furry pull switch which reminds one a bit of a teabag.
Metal socket for 25 watt bulb.
10cm x 12cm.
[via Interior design room]
Ekranoplan — Once upon a time in the U.S.S.R.
From English Russia:
1987 was the year when the first-350 ton ground effect "ship" in a series of Soviet battle missile carriers was produced.
It was called "Lun" after the Russian name for a bird of prey, the hen harrier.
Another name for this vehicle was Project 903.
It carried 6 Moskit cruise missiles (SS-N-22 Sunburn in NATO classification).
Being hit by four of them causes inevitable sinking of a vessel of any known type and size.
The second Lun-class battle aircraft was supposed to be produced in several years, but due to the end of Cold War and partial disarmament, the project was changed to a rescue aircraft and it was never finished.
This type of vehicle is called in Russian "ekranoplan," it uses so-called "ground effects" — extra lift of large wings in proximity to the surface.
For this reason they have been designed to travel at a maximum of three meters above the sea but at the same time provide take-off, stable "flight" and safe landing in conditions of up to 5-meter waves.
These craft were originally developed by the Soviet Union as high-speed military transports, and were based mostly on the shores of the Caspian Sea and Black Sea.
In 2005 craft of this type have been classified by the International Marine Organization so they probably should be considered flying ships rather than swimming planes.
It is also interesting to note that this aircraft is one of the largest ever built, with a length of 73.8 meters (comparing with 73 of Airbus A380).
Apron Cooking Guide — "Printed with all the information you'll ever need"
What took so long?
"Apron full of useful information. Guide includes numeric conversions, cooking times for vegetables, roasting times for birds, freezing instructions, defrosting times, a cooking glossary and more."