#display

#display

Researchers Stack "Holobricks" to Generate Large Seamless Holographic 3D ImagesShould this be fully produced and utilized in the future, this newest technology could enable scalable holographic 3D displays. Imagine the possibilities!Developed by researchers from the University of Cambridge and Disney Research, the holobrick is a proof-of-concept tool. The holobrick can tile holograms together to form a large seamless 3D image. The research was done to hopefully provide a way to procure a method for generating high-quality visual experiences. “Delivering an adequate 3D experience using the current technology is a huge challenge,” explained Professor Daping Chu from Cambridge’s Department of Engineering, who led the research. “Over the past ten years, we’ve been working with our industrial partners to develop holographic displays which allow the simultaneous realization of large size and large field-of-view, which needs to be matched with a hologram with a large optical information content.”The holobrick unit was based on a seven-year-old concept developed by CAPE with Disney Research. They utilized the coarse integrated holographic displays for angularly tiled 3D images to form the holograms with large viewing areas and fields of view. Image credit: Li, et.al #research #display #holograms #3D #Disney #UniversityofCambridge #holobrick

Skin Displays: The Ultra-Thin Future of Wearable Devices“I believe skin displays can get us to a future of technologies that are gentle, kind, and spread warmth, not just information.”These are just some of the words of Takao Someya, a University of Tokyo professor that envisions a “future of electronic devices that not only transmit data but also feelings.” While smartwatches and other wearable devices are already available in the market, some people still find them clunky and impractical to use given their small display.Professor Takao, along with his group and Dai Nippon Printing Co, aims to resolve this by working on a 46mm square, 2mm thin display capable of sticking to one’s skin and other surfaces. This is made possible by using micro-LEDs attached to a stretched silicon substrate connected via silver wiring. This silver wiring comes in the form of a paste that is conductive even as it is stretched and molded into the curvature of one’s hand. The silicone material also acts as a natural adhesive, making attachment easy.  Apart from the obvious health monitoring benefits, skin displays also make accessing information easier and can be very useful in situations where both hands are preoccupied. The flexible design also makes it viable for contact sports, where traditional devices may easily break when struck.  While this design is surely promising, it is not without room for improvement. Professor Takao notes improving power sources, pixel density, and striking a balance between comfort and durability. He and his team are aiming to bring skin displays into consumer’s hands within the next three years. Image: University of Tokyo | Yoshiaki Tsutsui #wearable #display #future #technology #electronics #sports #wellness #microLED #medicaldevice