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Main Authors: Li, Zhi, Luo, Xuhao, Wang, Jing, Yuan, Xin, Teng, Dongdong, Song, Qiang, Duan, Huigao
Format: Preprint
Published: 2024
Subjects:
Online Access:https://arxiv.org/abs/2406.15456
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author Li, Zhi
Luo, Xuhao
Wang, Jing
Yuan, Xin
Teng, Dongdong
Song, Qiang
Duan, Huigao
author_facet Li, Zhi
Luo, Xuhao
Wang, Jing
Yuan, Xin
Teng, Dongdong
Song, Qiang
Duan, Huigao
contents The fast algorithms in Fourier optics have invigorated multifunctional device design and advanced imaging technologies. However, the necessity for fast computations has led to limitations in the widely used conventional Fourier methods, manifesting as fixed size image plane at a certain diffraction distance. These limitations pose challenges in intricate scaling transformations, 3D reconstructions and full-color displays. Currently, there is a lack of effective solutions, often resorting to pre-processing that compromise fidelity. In this paper, leveraging a higher-dimensional phase space method, we present a universal framework allowing for customized diffraction calculation methods. Within this framework, we establish a variable-scale diffraction computation model which allows the adjustment of the size of the image plane and can be operated by fast algorithms. We validate the model's robust variable-scale capabilities and its aberration automatic correction capability for full-color holography, achieving high fidelity. The large-magnification tomography experiment demonstrates that this model provides a superior solution for holographic 3D reconstruction. In addition, this model is applied to achieve full-color metasurface holography with near-zero crosstalk, showcasing its versatile applicability at nanoscale. Our model presents significant prospects for applications in the optics community, such as beam shaping, computer-generated holograms (CGHs), augmented reality (AR), metasurface optical elements (MOEs) and advanced holographic head-up display (HUD) systems.
format Preprint
id arxiv_https___arxiv_org_abs_2406_15456
institution arXiv
publishDate 2024
record_format arxiv
spellingShingle Phase space framework enables a variable-scale diffraction model for coherent imaging and display
Li, Zhi
Luo, Xuhao
Wang, Jing
Yuan, Xin
Teng, Dongdong
Song, Qiang
Duan, Huigao
Applied Physics
Optics
The fast algorithms in Fourier optics have invigorated multifunctional device design and advanced imaging technologies. However, the necessity for fast computations has led to limitations in the widely used conventional Fourier methods, manifesting as fixed size image plane at a certain diffraction distance. These limitations pose challenges in intricate scaling transformations, 3D reconstructions and full-color displays. Currently, there is a lack of effective solutions, often resorting to pre-processing that compromise fidelity. In this paper, leveraging a higher-dimensional phase space method, we present a universal framework allowing for customized diffraction calculation methods. Within this framework, we establish a variable-scale diffraction computation model which allows the adjustment of the size of the image plane and can be operated by fast algorithms. We validate the model's robust variable-scale capabilities and its aberration automatic correction capability for full-color holography, achieving high fidelity. The large-magnification tomography experiment demonstrates that this model provides a superior solution for holographic 3D reconstruction. In addition, this model is applied to achieve full-color metasurface holography with near-zero crosstalk, showcasing its versatile applicability at nanoscale. Our model presents significant prospects for applications in the optics community, such as beam shaping, computer-generated holograms (CGHs), augmented reality (AR), metasurface optical elements (MOEs) and advanced holographic head-up display (HUD) systems.
title Phase space framework enables a variable-scale diffraction model for coherent imaging and display
topic Applied Physics
Optics
url https://arxiv.org/abs/2406.15456