Professor Sosumu Tachi's cloak works by projecting an image onto itself of what is behind the wearer.
A computer generates the image that is projected, so the viewer effectively sees "through" the cloak.

The key development of the cloak, however, was the development of a new material called retro-reflectum. Retro-reflectum is manufactured using a process very similar to that of the materials used for the reflective surfaces on traffic signs.

Unlike other reflective materials, "This material allows you to see a three-dimensional image," Professor Tachi said.
"This material is the key to our technology."
 
Professor Tachi said that he had first had the idea of developing something to make objects invisible in 1977.
But he said it was "hard to make it into reality," as the image looked flat and unrealistic.
"It didn't work at all when we just projected the image onto a normal screen," he added.
"We tried hard, but it took a while before we came up with this retro-reflective material."
 
This method of cloaking is only practical for certain “non-dynamic environment” uses.   However, this method is not true invisibility.   It is a hyper hi definition illusion.......all be-it a very realistic one........and it is limited.   It only works from certain angles due to the projective/reflective nature of the design schematic, and relies on an external eye (the camera picking up the surroundings).  
 
There are pending advancements in REAL atomic invisibility using nanotech.
 
A new theoretical design using nanowires provides a way to hide devices from visible light.
 
 
Cloak on, cloak off: Simulations show how light interacts with the cross section of the cloaking device. When it’s uncloaked (top), light is reflected off the object. But when it’s cloaked (bottom), light is guided around the object and anything within it.
Credit: Birck Nanotechnology Center, Purdue University
 
A hairbrush-shaped device has been theoretically designed that would use bristles made out of nanowires to bend light around it, rendering the object invisible. The researchers who came up with the design say that it's the first practical design for an "optical cloak" to work in the visible spectrum. They are now working on building an actual device based on their calculations.
Although still only a theoretical design, it is the first to show how a recently discovered cloaking effect could be made to work for all wavelengths of visible light, says Vladimir Shalaev, a professor of electrical and computer engineering at Purdue University, in West Lafayette, IN, who led the research effort.

"It sets out a road map for building these sorts of structures," says John Pendry, a professor of theoretical physics at Imperial College London, U.K. Besides making it possible to turn things invisible, the work could lead to ways to create heat shields by bending infrared light around objects, he says. Pendry's initial research led to last year's creation of the first working cloaking device, which operated in the microwave range. (See "Cloaking Breakthrough.") This latest work now shows a way to extend this into the visible-light range, says Pendry.

To become invisible, an object must do two things: it has to be able to bend light around itself, so that it casts no shadow, and it must produce no reflection. While naturally occurring materials are unable to do this, a new class of materials called metamaterials is now making it possible. (See "TR10: Invisible Revolution.")

Bending light around an object requires a material to have a negative refractive index. The refractive index is a property that dictates how light passes through a medium; it's the reason a stick will look bent when placed in water. If water had a negative refractive index, it would make the stick look as though it were bending back on itself.

Last year, Pendry demonstrated that it is theoretically possible to design structures of very thin conducting wires that could have an effect on the electric and magnetic fields of microwaves, causing them to bend in unnatural ways such as this. This theory was later backed up by experiments carried out by David Smith and David Schurig at Duke University, in Durham, NC.

But repeating the success for visual light seemed to present problems. For one thing, making the design used by Smith and Schurig work for visible light would require components just 40 nanometers in size.








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