Equalization of RGB coupling efficiencies of metasurface waveguide coupler by adjusting imaginary part of refractive index.

Optical metasurfaces offer high-efficiency and flexible wavefront shaping for near-eye displays, especially in wideband waveguide couplers accommodating RGB primary colors. By leveraging the resonance characteristics of sub-wavelength periodic nanostructures, metasurfaces surpass the limitations of traditional optics that rely on multiple components and mediums. In this study, we propose adjustment of the imaginary parts of the material refractive indices as a new method to achieve balanced first-order diffraction efficiencies among RGB colors over a wide field of view (FOV) in an in-coupling metasurface waveguide coupler. Physical mechanism is investigated deeply and systematically in theory. It is found that nanostructure resonances deflect the wavefront and Poynting vector, significantly enhancing first-order diffraction efficiency, while resonance-enhanced absorption plays a crucial role in balancing the diffraction efficiency of RGB primary colors. First experimental demonstration well confirms the practical feasibility of this method and a uniform first-order diffraction efficiency of approximately 20% is achieved among RGB colors across a FOV as large as ∼30° over a single-piece glass substrate. This research provides insights into the design and mechanisms of metasurface waveguide couplers, advancing our understanding of metasurface-based RGB displays and facilitating further advancements in this field.

Improving fast auto-focus with event polarity.

Fast and accurate auto-focus in adverse conditions remains an arduous task. The emergence of event cameras has opened up new possibilities for addressing the challenge. This paper presents a new high-speed and accurate event-based focusing algorithm. Specifically, the symmetrical relationship between the event polarities in focusing is investigated, and the event-based focus evaluation function is proposed based on the principles of the event cameras and the imaging model in the focusing process. Comprehensive experiments on the public event-based autofocus dataset (EAD) show the robustness of the model. Furthermore, precise focus with less than one depth of focus is achieved within 0.004 seconds on our self-built high-speed focusing platform. The dataset and code will be made publicly available.

Optical metasurfaces for waveguide couplers with uniform efficiencies at RGB wavelengths.

Optical metasurfaces hold great potential for near-eye display applications with high optical efficiency, light-weight and compactness. Taking advantage of optical resonances in subwavelength features, metasurfaces can diffract optical beams at RGB primary colors efficiently, forming superimposed virtual images over a real-world scene with merely a single glass substrate in augmented realities (AR) applications. We report for the first time a metasurface with double or triple nano-beams in each period for high angle diffraction with a uniform efficiency at RGB wavelengths. An efficiency as high as 30-40% of the first diffraction order is obtained across field of view, allowing a single piece of AR glass for light in-coupling to deliver image uniformly. The underlying physics is investigated through systematic full-vector numerical simulations. It is found that strong resonances inside the nano-beams with different sizes are the main reason for the deflection of wavefront as well as the Poynting vectors, leading to an efficient coupling of the incident light into the first-order diffraction. The resonances also manipulate the light absorption among the RGB colors for uniform efficiency. This work provides a new understanding of optimal metasurface structure for waveguide couplers using multiple nano-beams.