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Soon gi Park (LetinAR): PinMR: Novel Optical Solution for AR Glasses
- 1. Pin MR: Novel Optical Solution forAR Glasses Soon-gi Park, Ph. D. Principal Research Scientist AWE 2019
- 2. Introduction Pin Mirror technology Manufacturing Cost comparison Milestone Contents
- 3. LetinAR Inc. Is established Horizontal expansion of PinMRTM Seed funding from & Reducing of distortion using aspheric surface PinMRTM design Plastic PinMRTM lens development by ultra- Precision diamond cutting Plastic aspheric surface PinMRTM lens Development by injection molding technology Development of prototype PinMRTM AR glasses Design of expanded FOV lens vertically Introduction PinMRTM AR glasses at CES / MWC 2018 Series A funding from , . & 3 VC’s Introduction PinMRTM AR lens for 4K wide FOV and Small Form Factor smart glasses at CES/MWC 2019 Series A funding from KB Investment 5 Patents registered in Korea / 9 Patents are filed in Korea / 11 Patents are filed globally Development history of LetinAR PinMRTM lens 10 3 6 7 8 10 11 12 1 7 12 1 2 2016 2017 2018 2019
- 4. FOVImage quality Focus Form Factor There are many requirements and issues for popularization of AR glasses. Normal vision Issues for the Optics
- 5. The bending of light based on wavelength & The image light bounce many times across the waveguide Color uniformity white color breaking into red, green, and blue Degrading of color uniformity in conventional AR glasses Diffraction efficiency according the angle for RGB wavelengths (Jolly et al., Proc. SPIE 10127) Degrading of color uniformity in conventional lens
- 7. Vergence-Accommodation Conflict in conventional optic solution the LetinAR PinMR™ lens has clear viewing zone between 25cm, and theoretically, an infinite distance away Wide viewing zone (DOF, Depth of Field) à Virtual image can be focused on at any time and multi focal plane can be supported
- 9. One PinMR provides 12 - 15o of FOV. FOV can be simply expanded with additional PinMR. LetinAR PinMR lens supports more than 80o. Glasses type ~ 30o Goggle type ~ 80o Wide FOV
- 11. HoloLens 2 HoloLens MagicLeap One Lumus OE Vision WaveOptics Phlox (DMD) WaveOptics Phlox (LCoS) Vuzix Blade DigiLens Form-factor
- 12. Micro display Lens substrate Pin MRTM Simple structure and small form-factor Small-form factor Glasses High performance Goggle Lens substrate Micro display module Pin MRTM
- 13. Normal transparency 90% Optic efficiency = Typically more than 10% No tunneling view effect Tunneling view Unobstructed view View through PinMR combiner Flares Normal vision
- 14. Light efficiency Source: Cnet Source: TechCrunch Source: Engadget HOE/DOE Aluminum mirror Source: Mobilegeeks.de YouTube channel
- 15. Raw materials Optical glass Optical plastic Glass Plastic Optical quality Very good Moderate to good Price moderate good Hardness good moderate Weight moderate good Durability poor good Manufacturing cost Poor to moderate Moderate to good Manufacturing process
- 16. LetinAR Pin MR lens substrate sample Mold core Extracted plastic combiner substrate Finalized combiner module
- 17. Resin injection Coating PinMR Bonding Various choice of optical materials High compatibility with conventional manufacturing process Low cost manufacturing Finishing
- 18. Source: Arburg.com Injection molding (example) Optical coating (example) Source: Schneider GmbH Vacuuming Loading lenses Masking & optical coating Coated product
- 19. Lens module assembly (example) Source: Fraunhofer IPT Dispensing adhesive Adhesive calibration Positioning & assembly UV hardening & curing
- 20. Display modules (example) Flat panel micro display can be used for a display module LCoS (North Carolina State University/Imagine Optix, Nikkei BP) Micro OLED (Sony, Fraunhofer FEP) Micro LED (Jasper Display/Plessy, Samsung)
- 22. System Assembly
- 23. Cost comparison DOE/HOE waveguide Half mirror waveguide PinMR combiner Key process Nanoimprint lithography / Laser exposure Coating / slicing Injection molding Raw material Medium to high Medium Low to medium Tooling Medium to high Medium to high low Facility Medium to high Low to medium Low to medium Tolerance Medium to high Medium to high Low to medium Yield Medium Medium Medium to high Manufacturing capacity Low to medium Low to medium Medium to high Overall cost per unit High Medium to high Low to medium No consideration for the optical performance
- 24. Moderate tolerance for optical surfaces Robust coating requirement Flat mirrors (Edmund Optics) DigiLens waveguide example (J. Waldern et al, Proc. SPIE 10676) LetinAR combiner Simple manufacturing steps Surface relief grating manufacturing (Captured from DigiLens talk, PW2019) LetinAR 4-step manufacturing How does it possible?
- 25. Mass production partnership Korean Domestic Partners / Global manufacturing partners
- 26. Lens Module Special Purpose HMD or Smartglasses with OLEDoS LCoS MicroLED μDisplay Display manufacturer Lens + Final Product Manufacturer Smart Glasses Personal TV AR/VR Monitor - Smart Office - Personal Vehicles Consumer Sports Medical OEM on demand 26 Military Business collaboration Use cases
- 27. Milestone for mass production 2021 Q1 Pilot production for “Glasses-type” optic solution Pilot production for “Goggle-type” optic solution Pilot production for mass-production-ready optic solution Mass production (expected Q’ty of 320K /mth)