glō, Jasper Display to Demonstrate Micro LED Display with High Brightness

At SID's Display Week 2018 in Los Angeles, glō and Jasper Display Corp. (JDC) will, for the first time ever, demo the world's brightest self-emitting display panel. The industry's brightest Micro LEDs (10 μm), developed and integrated by glō, paired with JDC's new silicon backplane, the JD67E2, make it possible to deliver the high brightness and contrast that will benefit the next wave of watches, phones, heads-up-displays (HUDs), and augmented reality (AR) products.

Display Week Exhibition 2018 starts on May 22nd. (Image: Witsview)

With the JD67E2 the Micro LED industry can take advantage of silicon that is tailored for the needs of high performance Micro LED devices. JDC’s expertise in digitally modulated pixel arrays is the key to their lead in Micro LED-focused silicon platforms. JDC’s history of developing industry firsts has made it possible to anticipate the rise of Micro LEDs. Jeffrey Li, Director of Applications, is excited about the new product possibilities that JDC's new silicon opens up for customers worldwide.

“Our JD67E2 silicon backplane demonstrates our ability to deliver on the promise of Micro LEDs. We’re excited to offer what the industry has been waiting for - silicon that has been designed to realize super-bright Micro LED panels. glō's super-high efficiency Micro LEDs, coupled with their silicon integration expertise, made it possible to demo a blindingly bright self-emissive display - the brightest in the world. Our Micro LED backplane technology can be customized on a per-project basis, allowing us to make specialized silicon suiting needs ranging from low-power AR headsets all the way to projection displays.”

The full-color capable JD67E2 die features a resolution of 1920 x 1080, a pixel pitch of 8 um, and offers excellent current uniformity via a proprietary current source pixel. Uniformity is better than 1% across the array. The device-ready die is now shipping as part of the JD27E2 8" wafer product. JDC’s DFM methodologies enable high-yield volume production of their wafers.

Besides increased brightness and contrast, JDC’s patented, per-pixel pulse width modulation technology is ideally suited to Micro LEDs because digital switching allows for precise and consistent coloring; a single on-state current will deliver a single, stable color. Conversely, an analog drive scheme puts different current levels through the Micro LEDs which is undesirable because wavelengths vary and color shifting occurs.

The JD67E2 is software configurable which allows hardware developers to easily and independently set brightness (via PWM) and color (via current).

Disclaimers of Warranties
1. The website does not warrant the following:
1.1 The services from the website meets your requirement;
1.2 The accuracy, completeness, or timeliness of the service;
1.3 The accuracy, reliability of conclusions drawn from using the service;
1.4 The accuracy, completeness, or timeliness, or security of any information that you download from the website
2. The services provided by the website is intended for your reference only. The website shall be not be responsible for investment decisions, damages, or other losses resulting from use of the website or the information contained therein<
Proprietary Rights
You may not reproduce, modify, create derivative works from, display, perform, publish, distribute, disseminate, broadcast or circulate to any third party, any materials contained on the services without the express prior written consent of the website or its legal owner.
The new IR:6 thin-film infrared LED chip technology is available in 850nm, 940nm and new 920nm wavelength options First IR:6-based products are the OSLON® P1616 and OSLON® Black series, giving customers a drop-in replacement that o... READ MORE
Display devices have been used for many years as a means of HMI (Human Machine Interface) to connect humans and machines interactively, and their usage are still expanding. Automotive interiors are no exception to this trend, with an increasing ... READ MORE