Pancake lenses: Difference between revisions - VR & AR Wiki - Virtual Reality & Augmented Reality Wiki

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{{Short description|Compact polarization-based optical system for VR/AR headsets}}

{{Infobox optical component

| name = Pancake lenses

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'''Pancake lenses''' (also known as '''pancake optics''' or '''folded optics''') are a type of compact [[catadioptric system|catadioptric]] optical system used in [[virtual reality]] (VR) and [[augmented reality]] (AR) headsets that employs polarization-based light path folding to dramatically reduce the physical distance between the display and the lens.<ref name="Wiley1978">~~{{cite journal |last1=~~LaRussa ~~|first1=~~Joseph A. ~~|last2=~~Gill ~~|first2=~~Arthur T. ~~|title=~~The Holographic Pancake Window ~~|journal=~~SPIE Proceedings ~~|date=1978 |volume=~~0162 ~~|pages=~~120-129 ~~|url=~~https://www.spiedigitallibrary.org/conference-proceedings-of-spie/0162/120/The-Holographic-Pancake-Window-/10.1117/12.956898.short ~~|access-date=~~2025-10-26}}</ref><ref name="Trioptics">{{cite web |url=https://www.trioptics.com/applications/alignment-and-testing-of-lens-systems/pancake-optics |title=Measurement solutions for pancake optics |publisher=TRIOPTICS |access-date=2025-10-26}}</ref> This technology enables VR/AR headsets to achieve 40-66% thinner profiles compared to traditional [[Fresnel lens]] designs while delivering superior edge-to-edge clarity and eliminating characteristic "god ray" artifacts.<ref name="Avantier">{{cite web |url=https://avantierinc.com/solutions/custom-optics/pancake-lenses-for-vr-optical-systems/ |title=Pancake Lenses for VR Optical Systems |publisher=Avantier Inc. |access-date=2025-10-26}}</ref><ref name="ExpandReality">{{cite web |url=https://landing.expandreality.io/pancake-vs.-fresnel-lenses-in-vr-headsets-advanced-optics-for-vr |title=Pancake vs. Fresnel Lenses in VR Headsets: Advanced Optics for VR |publisher=Expand Reality |date=2024-09-05 |access-date=2025-10-26}}</ref>

'''Pancake lenses''' (also known as '''pancake optics''' or '''folded optics''') are a type of compact [[catadioptric system|catadioptric]] optical system used in [[virtual reality]] (VR) and [[augmented reality]] (AR) headsets that employs polarization-based light path folding to dramatically reduce the physical distance between the display and the lens.<ref name="Wiley1978">LaRussa, Joseph A.; Gill, Arthur T. (1978). "The Holographic Pancake Window". ''SPIE Proceedings''. '''0162''': 120-129. [https://www.spiedigitallibrary.org/conference-proceedings-of-spie/0162/120/The-Holographic-Pancake-Window-/10.1117/12.956898.short]. Retrieved 2025-10-26.</ref><ref name="Trioptics">{{cite web |url=https://www.trioptics.com/applications/alignment-and-testing-of-lens-systems/pancake-optics |title=Measurement solutions for pancake optics |publisher=TRIOPTICS |access-date=2025-10-26}}</ref> This technology enables VR/AR headsets to achieve 40-66% thinner profiles compared to traditional [[Fresnel lens]] designs while delivering superior edge-to-edge clarity and eliminating characteristic "god ray" artifacts.<ref name="Avantier">{{cite web |url=https://avantierinc.com/solutions/custom-optics/pancake-lenses-for-vr-optical-systems/ |title=Pancake Lenses for VR Optical Systems |publisher=Avantier Inc. |access-date=2025-10-26}}</ref><ref name="ExpandReality">{{cite web |url=https://landing.expandreality.io/pancake-vs.-fresnel-lenses-in-vr-headsets-advanced-optics-for-vr |title=Pancake vs. Fresnel Lenses in VR Headsets: Advanced Optics for VR |publisher=Expand Reality |date=2024-09-05 |access-date=2025-10-26}}</ref>

The core innovation involves manipulating light [[polarization]] states to bounce photons multiple times between lens elements before reaching the user's eye, effectively "folding" the optical path within a compact module typically just 17-21mm thick.<ref name="RoadToVR">{{cite web |url=https://www.roadtovr.com/pico-4-announcement-release-date-specs-vs-quest-2/ |title=Pico 4 Announced with October Launch |publisher=Road to VR |date=2022-09-22 |access-date=2025-10-26}}</ref> However, this design suffers from extremely low light efficiency—typically transmitting only 10-25% of display light to the eye—requiring exceptionally bright displays and creating significant power consumption challenges.<ref name="Pimax">{{cite web |url=https://pimax.com/blogs/blogs/aspheric-vs-pancake-vr-lenses-and-why-glass |title=Aspheric vs. Pancake VR Lenses, and why glass? |publisher=Pimax |date=2024-05-11 |access-date=2025-10-26}}</ref><ref name="OpticaGhost">~~{{cite journal |title=~~Analysis of ghost images in a pancake virtual reality system ~~|journal=~~Optics Express ~~|volume=~~32 ~~|issue=~~10 ~~|pages=~~17211-17226 ~~|date=~~2024 ~~|url=~~https://opg.optica.org/oe/abstract.cfm?uri=oe-32-10-17211 ~~|access-date=~~2025-10-26}}</ref>

The core innovation involves manipulating light [[polarization]] states to bounce photons multiple times between lens elements before reaching the user's eye, effectively "folding" the optical path within a compact module typically just 17-21mm thick.<ref name="RoadToVR">{{cite web |url=https://www.roadtovr.com/pico-4-announcement-release-date-specs-vs-quest-2/ |title=Pico 4 Announced with October Launch |publisher=Road to VR |date=2022-09-22 |access-date=2025-10-26}}</ref> However, this design suffers from extremely low light efficiency—typically transmitting only 10-25% of display light to the eye—requiring exceptionally bright displays and creating significant power consumption challenges.<ref name="Pimax">{{cite web |url=https://pimax.com/blogs/blogs/aspheric-vs-pancake-vr-lenses-and-why-glass |title=Aspheric vs. Pancake VR Lenses, and why glass? |publisher=Pimax |date=2024-05-11 |access-date=2025-10-26}}</ref><ref name="OpticaGhost">"Analysis of ghost images in a pancake virtual reality system". ''Optics Express''. '''32''' (10): 17211-17226. 2024. [https://opg.optica.org/oe/abstract.cfm?uri=oe-32-10-17211]. Retrieved 2025-10-26.</ref>

Since entering the consumer market with the [[Huawei VR Glass]] in 2019, pancake lenses have rapidly become the standard for premium VR/MR headsets.<ref name="UploadVR">{{cite web |url=https://uploadvr.com/huawei-vr-glass-6dof-announced/ |title=Huawei VR Glass 6DOF announced |publisher=UploadVR |date=2019-12-19 |access-date=2025-10-26}}</ref> Major implementations include the [[Meta Quest Pro]] (2022), [[Meta Quest 3]] (2023), [[Apple Vision Pro]] (2024), and [[Pico 4]] (2022), marking a pivotal industry shift toward prioritizing comfortable, lightweight designs over optical efficiency.<ref name="InsightMedia">{{cite web |url=https://www.insightmedia.info/kopin-all-plastic-pancake-optics-for-vr-ar-mr/ |title=Kopin All-Plastic Pancake Optics for VR/AR/MR |publisher=Insight Media |date=2021 |access-date=2025-10-26}}</ref>

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The pancake lens concept originated in 1978 when Joseph A. LaRussa and Arthur T. Gill at Farrand Optical Company published "The Holographic Pancake Window," describing polarization-based [[catadioptric system|catadioptric optics]] for flight simulation and avionic [[head-mounted display]]s.<ref name="Wiley1978"/><ref name="SemanticScholar">{{cite web |url=https://www.semanticscholar.org/paper/The-Holographic-Pancake-Window-LaRussa-Gill/8f3e1a2b1c2d3e4f5a6b7c8d9e0f1a2b |title=The Holographic Pancake Window |publisher=Semantic Scholar |access-date=2025-10-26}}</ref> Their seminal work introduced the combination of flat and curved beamsplitting elements to create compact, large-aperture magnifiers presenting images at optical infinity.

The technology evolved gradually through specialized military and scientific applications for nearly four decades. Roger B. Huxford applied wire-grid polarizers in pancake configurations in 2004.<ref name="ResearchGate2004">{{cite web |url=https://www.researchgate.net/publication/228994421_Wire-grid_polarizers_in_pancake_optics |title=Wire-grid polarizers in pancake optics |publisher=ResearchGate |date=2004 |access-date=2025-10-26}}</ref> The concept of using [[holographic optical element]]s in such designs appeared in academic literature as early as 1985, though practical implementations remained decades away.<ref name="OpticaHolographic">~~{{cite journal |title=~~See-through holographic pancake optics for mobile augmented reality ~~|journal=~~Optics Express ~~|volume=~~29 ~~|issue=~~22 ~~|pages=~~35206-35215 ~~|date=~~2021 ~~|url=~~https://opg.optica.org/oe/fulltext.cfm?uri=oe-29-22-35206 ~~|access-date=~~2025-10-26}}</ref>

The technology evolved gradually through specialized military and scientific applications for nearly four decades. Roger B. Huxford applied wire-grid polarizers in pancake configurations in 2004.<ref name="ResearchGate2004">{{cite web |url=https://www.researchgate.net/publication/228994421_Wire-grid_polarizers_in_pancake_optics |title=Wire-grid polarizers in pancake optics |publisher=ResearchGate |date=2004 |access-date=2025-10-26}}</ref> The concept of using [[holographic optical element]]s in such designs appeared in academic literature as early as 1985, though practical implementations remained decades away.<ref name="OpticaHolographic">"See-through holographic pancake optics for mobile augmented reality". ''Optics Express''. '''29''' (22): 35206-35215. 2021. [https://opg.optica.org/oe/fulltext.cfm?uri=oe-29-22-35206]. Retrieved 2025-10-26.</ref>

=== VR Industry Adoption (2015-2022) ===

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* [https://www.hypervision.ai/tech-research/pancake-lens-principle HyperVision Pancake Lens Research]

[[Category:~~Terms~~]]

[[Category:Virtual reality]]

[[Category:Augmented reality]]

[[Category:Optical devices]]

[[Category:Lenses]]

[[Category:Display technology]]