image: Figure 1. Working principle of the conventional and novel pancake optics systems. (a) configuration of the conventional pancake optics. (b) polarization conversion process in the conventional pancake optics. (c) configuration of the novel pancake optics. (d) polarization conversion process in the novel pancake optics.
Credit: OEA
A new publication from Opto-Electronic Advances, 10.29026/oea.2024.230178 discusses revolutionizing next-generation VR and MR displays with a novel pancake optics.
Augmented reality (AR), virtual reality (VR) and mixed reality (MR) have expanded our perceptual horizons and ushered in deeper human-digital interactions that transcend the confines of traditional flat panel displays. This evolution has unlocked a realm of exciting new possibilities, encompassing the metaverse, digital twins, and spatial computing, all of which have found widespread applications in diverse fields such as smart education and training, healthcare, navigation, gaming, entertainment, and smart manufacturing.
For AR, VR and MR displays to become truly wearable for an extended period, there is a pressing need for compact and stylish formfactor, lightweight, and low power consumption. Compared to Fresnel lens and refractive lens, polarization-based folded optics, often referred to as pancake optics, has emerged as a pivotal breakthrough for compact and lightweight VR headsets in the past few years, such as Apple Vision Pro and Meta Quest 3. Such a pancake optics greatly reduces the volume of a VR display, which in turn improves the center of gravity for the headset. However, the employed half mirror causes a tremendous optical loss, which limits the maximum efficiency to 25%. Therefore, a novel optical structure with the same folding capability as the pancake lens, while without the optical loss is in urgent need.
The authors of this article have extensively explored light engines, imaging optics, and power consumption of AR, VR and MR displays. A game-changing pancake optics system for reducing the volume of VR and MR displays, while keeping a high efficiency is proposed by this article. The motivation behind this research is the increasing demand for wearable VR/MR headsets that are not only visually impressive but also comfortable for extended use. Present VR headsets with conventional pancake optics face challenges such as low optical efficiency which in turn leads to increased thermal effect of the headset and short battery life due to the tremendous optical loss induced by the half mirror. As depicted in Fig. 1(a-b), only about 25% of the light (assuming no other loss) from the display panel reaches the observer's eye. However, if the microdisplay emits an unpolarized light, then the maximum optical efficiency is further reduced to 12.5%. The unused light will be either absorbed by the headset which would increase the thermal effect or become stray light which would degrade the image quality.
The novel pancake optics system addresses this challenge by introducing a theoretically lossless design, incorporating a nonreciprocal polarization rotator, also known as Faraday rotator, between reflective polarizers as shown in Fig. 1(c-d). In such design, the nonreciprocal polarization rotator plays a critical role in folding the optical paths. Compared to reciprocal polarization rotator (e.g., half-wave plates), the nonreciprocal polarization rotator rotates the linearly polarized light irrespective of the optical wave’s propagation direction as Fig. 2(a-d) depicts. Consequently, a roundtrip of forward and backward propagations through the nonreciprocal polarization rotator results in a net rotation of 2θ.
Preliminary experiments were conducted with a laser source and a micro-OLED panel to verify its optical efficiency and folding capability as depicted in Fig. 3(a) and (b-c) respectively. The measured optical efficiency is around 71.5% due to the lack of anti-reflection (AR) coating and nonideal performance of the employed reflective polarizers. After using high-performance reflective polarizers and AR coating, the optical efficiency is improved to 93.2%, which is approaching the theoretical prediction. Besides, four types of possible ghost images are analyzed in this novel pancake optical system. Through identifying the root cause of these ghost images, new methods are proposed to enhance the image contrast ratio. Additionally, a multi-layer structure is proposed to broaden the bandwidth of the Faraday rotator to enable full color displays. As indicated in Fig. 3(d-f), a three sequences of nonreciprocal polarization rotators and quarter-wave plates are adequate to achieve a broadband spectral response. Finally, to achieve a large field of view and truly compact formfactor, some possible candidates of thin-film magneto-optics material are analyzed and discussed in the article.
Overall, these demonstrations showcase the potential that such a novel pancake optics system could revolutionize next-generation VR and MR displays with lightweight, compact formfactor, and low power consumption. Besides, the pressing need for a thin-film Faraday rotator that is both magnetless and highly transparent, while possessing a large Verdet constant in the visible region, is expected to inspire the next-round magneto-optic material development in the future.
Keywords: near-eye display / virtual reality / pancake optics / folded optics / nonreciprocal polarization rotator
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Shin-Tson Wu is a Trustee Chair Professor at College of Optics and Photonics, University of Central Florida. He received his PhD in Physics from the University of Southern California and BS in Physics from National Taiwan University. He is an Academician of Academia Sinica, a Charter fellow of National Academy of Inventors, and a recipient of Optica (formerly OSA) Edwin H. Land Medal (2022), SPIE Maria Goeppert-Mayer Award (2022), OSA Esther Hoffman Beller Medal (2014), SID Slottow-Owaki Prize (2011), OSA Joseph Fraunhofer Award (2010), SPIE G. G. Stokes Award (2008), and SID Jan Rajchman Prize (2008). His research group focuses on augmented reality and virtual reality, including light engines (LCOS, mini-LED, micro-LED, and OLED), optical systems (lightguide, diffractive optics, and projection optics), and display materials (liquid crystals, quantum dots, and perovskites).
Currently, Prof. Wu’s group has 9 Ph.D. students, 1 M.S. student, 1 B.S. student, and 2 visiting scholars. His students have received numerous national and international recognitions, such as SID distinguished paper awards, ILCS (International Liquid Crystal Society) Glenn H. Brown prize, SPIE Optics and Photonics education scholarship, SPIE AR/VR/MR optical design challenge awards, and IEEE outstanding graduate student award, just to name a few. Since 2020, Facebook Reality Lab (FRL) and ILCS jointly sponsor the FRL-ILCS liquid crystal research excellent awards. Each year, only top three winners are selected worldwide. In 2020, Prof. Wu’s student Tao Zhan won the platinum award. In 2021, two students from his group, Jianghao Xiong and Kun Yin, received the diamond award and platinum award, respectively. In 2022, Yannanqi Li received the gold award. This year, Zhenyi Luo defended the diamond award successfully. More information can be found in Prof. Wu’s group website: https://lcd.creol.ucf.edu
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Opto-Electronic Advances (OEA) is a high-impact, open access, peer reviewed monthly SCI journal with an impact factor of 8.933 (Journal Citation Reports for IF2021). Since its launch in March 2018, OEA has been indexed in SCI, EI, DOAJ, Scopus, CA and ICI databases over the time and expanded its Editorial Board to 36 members from 17 countries and regions (average h-index 49).
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Article reference: Ding YQ, Luo ZY, Borjigin G et al. Breaking the optical efficiency limit of virtual reality with a nonreciprocal polarization rotator. Opto-Electron Adv 7, 230178 (2024). doi: 10.29026/oea.2024.230178
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Opto-Electronic Advances