Friday, December 7, 2012

Augmented reality LCD contact lens

Researchers have created a spherical LCD display system that can be embedded in contact lenses. Breakthrough will usher the next generation of wearable displays

The Centre of Microsystems Technology at Ghent University (Belgium), announced today it has developed an innovative spherical curved LCD display, which can be embedded in contact lenses.
The first step toward fully pixelated contact lens displays, this achievement has potential widespread applications in medical and cosmetic domains.


   Unlike LED-based contact lens displays, which are limited to a few small pixels, the innovative LCDbased technology permits the use of the entire display surface.
   By adapting the patterning process of the conductive layer, this technology enables applications with a broad range of pixel number and sizes, such as a one pixel, fully covered contact lens acting as adaptable sunglasses, or a highly pixelated contact lens display.
   The first prototype presented today contains a patterned dollar sign, depicting the many cartoons that feature people or figures with dollars in their eyes. It can only display rudimentary patterns, similar to an electronic pocket calculator. In the future, the researchers envision fully autonomous electronic contact lenses embedded with this display.
   These next-generation solutions could be used for medical purposes, for example to control the light transmission toward the retina in case of a damaged iris, or for cosmetic purposes such as an iris with a tunable color. In the future, the display could also function as a head-up display, superimposing an image onto the user’s normal view.


   However, there are still hurdles to overcome for broader consumer and civilian implementation.
   “Normally, flexible displays using liquid crystal cells are not designed to be formed into a new shape, especially not a spherical one. Thus, the main challenge was to create a very thin, spherically curved substrate with active layers that could withstand the extreme molding processes,” said Jelle De Smet, the main researcher on the project.
   “Moreover, since we had to use very thin polymer films, their influence on the smoothness of the display had to be studied in detail. By using new kinds of conductive polymers and integrating them into a smooth spherical cell, we were able to fabricate a new LCD-based contact lens display.”
   “Now that we have established the basic technology, we can start working towards real applications, possibly available in only a few years time,” commented Herbert De Smet, who is supervising CMST’s display group.

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