![]() The researchers are now working to optimize the optics and further reduce the complexity of the multifocal display to make the projector more compact. “The optical design can also be seamlessly integrated with various techniques used in existing light-field displays.” “Our approach is very efficient at processing information, which enables a low computing cost as well as simple, high-quality, real-time system configuration,” said Lee. The tests showed that the prototype can synthesize a volumetric image of 21.4 cm x 21.4 cm x 32 cm, which is equivalent to 28.6 megapixels and 36 times higher resolution than the original image. “We also found a way to effectively resolve the difficulty of enlarging a volumetric scene and overcame problems with information loss that tend to affect integral imaging.”Īfter verifying the resolution of their prototype system, the researchers qualitatively confirmed that a volumetric image was reconstructed. “Our method goes beyond merely combining two existing methods to achieving an ultrahigh-definition volumetric light-field display with almost diffraction-limited resolution,” said Lee. The information conversion between the multifocal display and integral imaging is all performed optically without any digital processing. ![]() ![]() In the new design, the multifocal display generates a high-resolution 3D, or volumetric, scene while the integral imaging technology enlarges it for viewing on a large screen. On the other hand, integral imaging is better at enlarging images. Typically, a multifocal display can generate a high-quality volumetric image, but it is technically difficult to implement on a large-screen system. To overcome this limitation, the researchers designed a new optical configuration that combines a multifocal display with integral imaging. This demand creates a tradeoff between resolution and the size of the displayed image because the hardware of the display gets overwhelmed by the amount of information required. Because autostereoscopic light field displays produce different images for different viewing angles, they require a huge amount of information to be processed. Light-field displays work by reproducing light that is reflected from an object in a way that corresponds to the actual visible position. “This compensates for the limitations of each display technology to allow the creation of high-resolution 3D images on a large screen.” “We developed a way to carry out all the display processes optically without any digital processing,” said Lee. The new display is autostereoscopic, which means that it produces different 3D images so that the image can be viewed from various angles. In The Optical Society ( OSA) journal Optics Letters, the researchers describe how they combine two different light-field display technologies to project large-scale 3D images with almost diffraction-limited resolution. “Our design could also be modified to provide immersive experiences in movie theaters, for example.” ![]() “Our optical design could make it practical to replace 2D flat panel displays with 3D images for digital signs, entertainment, education and other applications where 3D images provide a significant enhancement,” said research team leader Byoungho Lee from Seoul National University in Korea. The new approach helps overcome the limitations of light-field projection, which can create natural-looking 3D images that don’t require special 3D glasses for viewing. Researchers have developed a prototype display that uses projection to create large-scale 3D images with ultra-high definition. Projection approach could enable large, high-definition 3D images for digital signs and immersive experiences
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