Transparent flexible display fabricated by self-emitting quantum dot devicebank-free panel technology

We developed a Multiview 3D capturing system based on camera array for generating stereoscopic 3D printing. Based on the framework, we are capable to create well aligned 3D contentcalibrated color images. The depth perception of content can be manually adjusted for preview,for generating quality 3D stereoscopic printing.

PetaRay’s solution is called LiFiD, which is delivered in the form of optical module for near-eye displays. It reproduces the light rays of a sceneprojects them directly onto user’s retinas. Besides projecting light rays directly onto user’s retina to solve the vergence-accommodation conflict, LiFid has continuous focal planesallows the display content to precisely match the desired depth of field. No eye tracker and/or other sensors are needed for the projection.

As we know, most flowering devices are usually connected with a water pipe. when water goes through the pipeinto the flowering device, we can adjust the type of spray, especially when used for taking a shower. With technology keeping improving, we know that flowering devices have been designed to light

The present invention aims to develop of novel wavelength converting films with the composited perovskite quantum dots,facilitating the application of this technology for LED backlight module.We applying PQD on chip to the components of LED backlight modules. The PQD-LEDs that are used for the backlight transmitted through a color filter exhibit the ITU-R Recommendation BT.2020 approximately 90

Provided are a series of novel organometallic iridium complexes, a synthetic method thereof,an organic light emitting device using the same.

This project with aim of promoting digital optics education is funded by Ministry of Education. In the entry-level class, students are guided in the hand-on experiments to bring up the ability to set up optical pathsto learn the basic optics principles. In the advance-level class, students are encouraged to work on a 3D holographic project using the fast-response LCOS-SLM developed in Digital Optics Teaching Laboratory of NYCU. Students are able to apply different computer-generated holography (CGH) algorithmsdesign optical path accordingly to obtain desired holographic images.

We provide antibody-based solutions to human diseases with short development course at low cost, are based on the phage-displayed GH (Generic Human) synthetic antibody libraries designedconstructed with enabling approaches, leading to the throughput capacities to uplift the innovativenessproductivity in developing antibody therapeuticsdiagnostics. In conjunction with the core technologies, antibody bioinformatics capable of extracting knowledge from big data of human antibody repertoires is used to elucidate human antibody responsesto assist antibody library design.

This demonstration presents an active-matrix, 1920x1080, 370 nm UV MicroLED display. There are 2,073,600 pixels fabricated on this display which is smaller than a dollar coin,its diagonal has an extremely high pixel density of 3200 pixels per inch (ppi). The size of each pixel is 5 μm in diameter,the pixel pitch is 8 μm. The key technology of this achievement lies in the fabrication of pixels with good characteristicshigh uniformity,the successful development of flip-chip technology combining MicroLEDdriving integrated circuit pixels. This result can display imagesvideos.

A new emission model of organic light-emitting diode (OLED) based on triplet-triplet annihilation upconversion (TTAUC) with a high intrinsic upconversion efficiency (86.1) by using tris-(8-hydroxyquinoline)aluminum (Alq3)9,10-Bis(2-naphthyl)anthracene (ADN) as green sensitizerblue emitter, respectively. This structure improved the device efficiencyoperation lifetime compared to the conventional TTA-OLEDs. A record-high efficiency of 15.4EQEa 1.5x lifetime performance comparing to the commercial blue OLED are obtained by utilizing the TTAUC mechanism.