5.4M dot bicolor and tricolor OLED microdisplays for enhanced digital image fusion
The company will present a technical paper “A 5.4M dot OLED Microdisplay for Digital Night Vision and Image Fusion” at SPIE DSS in Baltimore, April 23 – 27. It will demonstrate two prototype 5.4M dot 0.61-inch diagonal OLED microdisplays in bicolor and tricolor. Digital image fusion, a process of combining video streams from multiple sensors into a single composite image, has important applications in thermal weapon sights, aviator night vision imaging systems and other emerging night sight and situational awareness equipment. Also, surgeons use image fusion systems to integrate and analyze preoperative images to plan and perform brain, spinal and other complex surgeries.
“MicroOLED’s bi- and tricolor OLED microdisplays broaden the performance attributes of our monochrome 5.4M pitch 0.61-inch diagonal microdisplay with a sub-pixel pitch of 4.7 microns by 4.7 microns operating at 0.2W, that we announced earlier this year. This megapixel pitch monochrome microdisplay was well received by professional camera and night vision system makers worldwide, so we are optimistic about the bicolor and tricolor 5.4M dot versions,” said Eric Marcellin-Dibon, CEO of MicroOLED. “In addition, with our quad pixel architecture, we have increasing flexibility to create new color filter arrangements. These will enable MicroOLED to develop new displays, which will further open up opportunities in the defense and medical markets.
The bicolor OLED microdisplays can merge a 4.0M pixel image from a night vision sensor with a 1.3M pixel image from a thermal sensor, and its 0.61 inch diagonal is directly compatible with existing systems. The tricolor version enables MicroOLED to merge up to three high resolution images or two images and a graphical overlay, with the following resolutions: a 2.6M pixel black and white image with a 1.3M pixel red image and a 1.3M pixel cyan image. They will provide system integrators and end-users all of the strengths of optical and digital image fusion systems with none of the trade-offs.
MicroOLED conserves energy in digital image fusion systems by merging the video input signals from multiple sensors directly in the microdisplay rather than the processor. Also, as the sub-pixels in the quad-pixel architecture are square, the same shape as pixels used in night vision and thermal sensors, each sub-pixel can be used as a full pixel. This is unlike the stripe pixel architecture where one needs to use the full color triplet for each pixel.
The strength of optical image fusion is that it can combine images originating from tube intensifiers with a high resolution (up to 2000 pixels) and thermal sensors (up to 1280×1024 pixels) with a fraction of energy, but at the expense of producing a lower quality composite image. The strength of digital image fusion is that it can record, compress and transmit data, as well as improve the quality of the composite image by adjusting visual parameters. However, it draws more heavily on energy. Current models have a limited image resolution of approximately 1000 line maximum. For existing models to process images at a higher resolution would require not only increasing the power consumption, but possibly enlarging the display, as well as other system optics, which run counter to the military market trend in Swap (Size, Weight and Power) reductions.
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