This could lead to an absolutely amazing display.
In a recently published patent application, Apple describes a technology that could reduce image artifacts in high dynamic range (HDR) dual-layer LCDs, technology that could theoretically boost a typical display’s contrast ratio to 1,000,000 to 1.
In its “Devices and methods of image-splitting for dual-layer high dynamic range displays” application, published by the U.S. Patent and Trademark Office, Apple touts the optical benefits of dual-layer LCD systems, specifically the ability to reproduce high contrast imagery.
In simple terms, a traditional LCD creates images by modulating light transmitted through a liquid crystal layer. Applying varying voltages to individual pixel electrodes generates electric fields that change liquid crystal molecule arrangement, thus allowing more or less light to pass through. Sandwiching the liquid crystal module between polarizing films and color filters produces a recognizable image.
The patent looks to go around the standard trick of raising brightness by increasing backlit illumination, something that leads to overall contrast being affected by light leakage, by stacking one grayscale and one color LCD panel on top of each other create dual-layer LCDs. These, in turn, can modulate light emitted by the backlight at least twice prior to reaching a viewer’s eyes, resulting in higher contrast ratios.
Multi-layer LCDs have a fundamental architectural problem, however, as the gap between panels causes a parallax effect when viewed at certain angles, which could lead to muddied image quality depending on the extent of perceived misalignment.
The technique could prevent parallax artifacts, moire, halo artifacts and clipping and Apple has also proposed an improved image-splitting algorithm capable of intelligently processing an original image for output on a per-panel basis. More specifically, the algorithm analyzes an image and splits it into two separate images generated for display on the front and back LCD panels. Depending on image content, hardware limitations and other considerations, the system blurs and downsizes the image sent to drive the back LCD panel, a grayscale module closest to the device light source.
Using optimization methods bounded by constraints laid out by an objective function, Apple’s system is able to prevent parallax without negatively impacting brightness or clarity. The algorithm also prevents clipping artifacts and light bloom, or halos, from appearing on the front panel. Apple says the technique can be used in both small and large format screens, from iPhone to Mac.
The patent application also mentions other workarounds to introduced artifacts, including increasing back LCD panel luminance compared to the front panel and reducing module thickness.
At present, typical LCDs boast a contrast ratio of 1,000 to 1, meaning a well implemented dual-layer LCD would theoretically yield a contrast ratio of up to 1,000,000 to 1. That figure might be higher for devices like iPhone, as the most recent models boast contrast ratios hovering at around 1,500 to 1.
It’s presently unclear as to whether Apple intends to implement the technology in an upcoming product. Recent efforts include the 9.7-inch iPad Pro, which features a high-resolution True Tone display, a technology that uses ambient light sensors to dynamically adjust screen color temperature for a consistent viewing experience.
Apple’s dual-layer LCD patent application was first filed for in August 2015 and credits Jun Jiang, Cheng Chen, Gabriel Marcu and Jiaying Wu as its inventors.
Stay tuned for additional details as they become available.
Via AppleInsider and the United States Patent and Technology Office
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