A groundbreaking study introduces a low-cost approach to manufacturing geometric optical waveguides tailored for augmented reality (AR) applications through 3D printing technology. The traditional challenges of intricate fabrication techniques and high precision are addressed by optimizing the design to enhance ease of production without the need for post-surface polishing. By integrating three dielectric reflectors, the prototype successfully demonstrates seamless immersion between virtual images and real-world scenes, showcasing potential for mass production in various AR applications.
The study delves into the comparison between geometric and diffractive waveguide structures, highlighting their respective advantages and disadvantages. While diffractive waveguides offer flexibility in design but face limitations in field of view due to chromatic aberration issues, geometric waveguides provide excellent image quality with no color dispersion but struggle with mass production capabilities. The integration of ultra-clear transparent UV resin with 3D printing technology revolutionizes the fabrication process, enabling the creation of high-quality optical components comparable to traditional methods.
Through simulation results utilizing COMSOL Multiphysics software, the optimized geometric waveguide design is meticulously analyzed to ensure optimal light transmission while considering fabrication constraints. The innovative manufacturing process involving a custom-level LCD 3D printer showcases enhanced surface roughness without requiring complex post-processing steps like molding or dicing. Experimental validation confirms the efficacy of the design by seamlessly overlapping virtual images with real-world environments, paving the way for affordable mass production of AR optical combiners.
Sang ngôn ngữ khác
từ nội dung nguồn
arxiv.org
Thông tin chi tiết chính được chắt lọc từ
by Dechuan Sun,... lúc arxiv.org 03-07-2024
https://arxiv.org/pdf/2403.03652.pdfYêu cầu sâu hơn