Monday, November 21, 2022
The Industrial Technology Research Institute (ITRI) has launched the High Resolution Full-Color Micro LED Display for AR Glasses. This innovation assists panel manufacturers and other industry players to upgrade their technology, expand their micro LED applications, meet market demand, and secure business opportunities in next-generation augmented reality (AR) display products for immersive experiences in the metaverse. The High Resolution Full-Color Micro LED Display for AR Glasses won a 2022 R&D 100 Award in the IT/electrical award category.
The low-power (<1W) display features a resolution of >2,000 PPI and brightness of >20,000 nits, and integrates the display and sensor functions in a compact design, giving the product a slim look (<0.5in). The design adopts heterogeneous integration technology similar to semiconductor processes to create micro-displays with wide color gamut by bringing micro LED, CMOS, and quantum-dot color conversion layers together within a single panel.
The display is sold as system-oriented industry integration and fabrication platform services, and is available globally for transfer.
ITRI’s High Resolution Full-Color Micro LED Display for AR Glasses has high resolution, high brightness, great compatibility, and low power consumption.
“ITRI’s High Resolution Full-Color Micro LED Display for AR Glasses has high commercial value and can enhance user experience due to its high resolution, high brightness, device compatibility, compact size and low power consumption. This high resolution Micro LED will help leading global display players to capitalize on the vast range of emerging Micro LED applications. ITRI has assisted manufacturers in pilot production and technology transfers, which have laid the foundation for developing in-vehicle displays and next-gen XR glasses,” said Dr. Shih-Chieh Chang, ITRI General Director of Electronic and Optoelectronic System Research Laboratories.
Micro LED Alliance
To introduce ITRI’s Micro LED technology into AR applications and deliver it from lab to market, ITRI founded an alliance in 2016 to integrate the industry chain horizontally. The alliance connects about 50 industry chain suppliers in advanced materials, semiconductor processes, and precision equipment.
It provides comprehensive upstream to downstream solutions to fulfill industry needs for different stages of verification, development, and IP licensing.
About micro LEDs
Micro LEDs are attracting attention in the fields of wearable electronics, lighting and biomedicine because of their high efficiency, small form factor, and low power consumption. Wearable micro LED displays have thin, lightweight, and unbreakable features, thus enabling the application of displays on curvilinear surfaces.
Impressive color purity and high brightness with low power consumption, high-resolution quantum-dot (QD) array patterning, ultrathin and ultrasmall form factors make QD-based Micro LEDs promising for flexible and wearable electronics. Micro LEDs are suitable for advanced display applications such as smartphones, wearable watches, microprojectors, AR/MR displays, automotive heads-up displays, ultra-high definition (UHD) (>4K resolution) televisions, and large-scale monitors including outdoor TVs, sports and advertisement signage.
The Micro LED manufacturing process
The manufacturing process for the High Resolution Full-Color Micro LED Display for AR Glasses transforms the current way of making a display module in the following aspects: It requires semiconductor-grade device process, micron (µm) grade accuracy of assembly and highly accurate yet fast-paced testing methodology. These steps usually require an upgrade or improvement in equipment, operation, logistics, materials and training.
The Micro LED display manufacturing process is different from the traditional LED manufacturing process in that Micro LED display technology requires a high-efficiency micrometer-grade LED process and heterogeneous bonding technology with high precision and high resolution on active backplane. The overall process requires additional semiconductor processes such as high-precision photolithography, CMP planarization, plating and high-precision alignment wafer bonding. Compared to the class 1000 cleanroom process used by traditional LEDs, a Micro LED lab needs a class 10 cleanroom to heterogeneously integrate all components without concerns for particle contamination.
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