# Ultrathin, polarization-independent, and focus-tunable liquid crystal   diffractive lens for augmented reality

**Authors:** Mareddi Bharath Kumar, Daekyung Kang, Jihoon Jung, Hongsik Park,, Joonku Hahn, Muhan Choi, Jin-Hyuk Bae, Hyunmin Kim, Jonghoo Park

arXiv: 1902.10889 · 2020-01-22

## TL;DR

This paper introduces an ultrathin, polarization-independent, focus-tunable liquid crystal diffractive lens that can be integrated into AR glasses to improve virtual image focus without increasing device bulk.

## Contribution

The work presents a novel ultrathin liquid crystal diffractive lens with polarization independence, enabling compact AR glasses with adjustable focus to reduce visual discomfort.

## Key findings

- Demonstrated a polarization-independent liquid crystal lens using birefringent substrates.
- Built a prototype AR glasses with addressable focal planes.
- Achieved focus adjustment in AR glasses without increasing device size.

## Abstract

Despite the recent advances in augmented reality (AR), which has shown the potential to significantly impact on our daily lives by offering a new way to manipulate and interact with virtual information, minimizing visual discomfort due to the vergence-accommodation conflict remains a challenge. Emerging AR technologies often exploit focus-tunable optics to address this problem. Although they demonstrated improved depth perception by enabling proper focus cues, a bulky form factor of focus-tunable optics prevents their use in the form of a pair of eyeglasses. Herein, we describe an ultrathin, focus-tunable liquid crystal (LC) diffractive lens with a large aperture, a low weight, and a low operating voltage. In addition, we show that the polarization dependence of the lens, which is an inherent optical property of LC lenses, can be eliminated using birefringent thin films as substrates and by aligning the optical axes of the birefringent substrates and LC at a specific angle. The polarization independence eliminates the need for a polarizer, thus further reducing the form factor of the optical system. Next, we demonstrate a prototype of AR glasses with addressable focal planes using the ultrathin lens. The prototype AR glasses can adjust the accommodation distance of the virtual image, mitigating the vergence-accommodation conflict without substantially compromising the form factor or image quality. This research on ultrathin lens technology shows promising potential for developing compact optical displays in various applications.

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Source: https://tomesphere.com/paper/1902.10889