Multiwavelength high-order optical vortex detection and demultiplexing coding using a metasurface

Yang, Dahai; Lin, Jie; Chen, Chen; Chang, Li; Hao, Junbo; Lv, Baiying; Zhou, Keya; Wang, Yudong; Jin, Peng

doi:10.1117/1.apn.1.1.016005

Cited by 19 publications

(12 citation statements)

References 55 publications

(53 reference statements)

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Section: Discussionmentioning

confidence: 99%

“…These advantages are helpful for promoting the development of a miniature SPI system using free-space optical components 12,31,32,59 as well as chip-scale integration with silicon photonic circuits 64 or metasurfaces. [65][66][67][68][69][70][71][72] Fig. 13 Acceleration strategy of the DIP-SP processing the images of all spectral bands one by one.…”

Section: Discussionmentioning

confidence: 99%

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Deep image prior plus sparsity prior: toward single-shot full-Stokes spectropolarimetric imaging with a multiple-order retarder

Han

et al. 2023

Adv. Photon. Nexus

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Compressive full-Stokes spectropolarimetric imaging (SPI), integrating passive polarization modulator (PM) into general imaging spectrometer, is powerful enough to capture high-dimensional information via incomplete measurement; a reconstruction algorithm is needed to recover 3D data cube (x , y , and λ) for each Stokes parameter. However, existing PMs usually consist of complex elements and enslave to accurate polarization calibration, current algorithms suffer from poor imaging quality and are subject to noise perturbation. In this work, we present a single multiple-order retarder followed a polarizer to implement passive spectropolarimetric modulation. After building a unified forward imaging model for SPI, we propose a deep image prior plus sparsity prior algorithm for high-quality reconstruction. The method based on untrained network does not need training data or accurate polarization calibration and can simultaneously reconstruct the 3D data cube and achieve self-calibration. Furthermore, we integrate the simplest PM into our miniature snapshot imaging spectrometer to form a single-shot SPI prototype. Both simulations and experiments verify the feasibility and outperformance of our SPI scheme. It provides a paradigm that allows general spectral imaging systems to become passive full-Stokes SPI systems by integrating the simplest PM without changing their intrinsic mechanism.

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Section: Discussionmentioning

confidence: 99%

Section: Discussionmentioning

confidence: 99%

Deep image prior plus sparsity prior: toward single-shot full-Stokes spectropolarimetric imaging with a multiple-order retarder

Han

et al. 2023

Adv. Photon. Nexus

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“…They clarified that transmitted light and reflected light can propagate in any direction in their respective half space, and the propagation direction depends on the direction of the metasurface phase gradient, the numerical magnitude and the refractive index of the surrounding medium. Metasurfaces have been widely used in wavefront engineering [3][4][5][6], focusing or imaging elements [7][8][9][10][11], beam shaping [12], vortex beam generation [13][14][15][16], holographic technology [17][18][19], biosensing [20], electromagnetic concealment [21], achromatic focusing [22], electromagnetic wave modulation [23] and nonlinear interactions [24,25] have been applied in 3D imaging [26], Cellular-resolution optical coherence tomography [27], holographic imaging [28][29][30][31], optical cryptography [32,33] and wireless power transfer (WPT) system [34][35][36]. For example, researchers achieved optical information multiplexing by a designed multifocal metalens using of nonlinear coding Pancharatnam-Berry phase metasurface [37].…”

Section: Introductionmentioning

confidence: 99%

Off-axis bifocal metalens for displacement measurement

Cao,

Li,

et al. 2024

Nanotechnology

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Metasurface is a new type of micro-optical element developed in recent years. It can intelligently modulate electromagnetic waves by adjusting the geometrical parameters and arrangement of dielectric structures. In this paper, a bifocal metalens based on modulation of propagation phase was designed for the potential application in displacement measurement. The phase of the bifocal lens is designed by the optical holography-like method., which is verified by the scalar diffraction theory. We designed a square aperture lens with a side length of 200μm to realize two focal spots with focal lengths of 900μm and 1100μm. The two focal spots aren’t on one optical axis. The polarization insensitive TiO2 cylinders are chosen as structure units. Four structures with different radius are selected to achieve the four phase steps. We fabricated the designed bifocal metalens using electron beam lithography and atomic layer deposition (ALD) techniques, and measured the light intensity in the areas near the two foci in the direction of the longitudinal axis. The differential signal was calculated, from which we obtained a linear interval. It demonstrates the ability of bifocal differential measurement to be applied to displacement measurement. Because the metasurfaces production process is semiconductor compatible, the bifocal lens is easy to integrate and can be used for miniaturized displacement measurements, micro-resonators, acceleration measurements, and so on.

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“…These planar optical devices can flexibly manipulate the polarization, phase, and intensity of electromagnetic waves. The exceptional characteristics of metasurfaces have paved the way for their application in many fields, such as metalenses [9,10], vortex beam generators and detectors [11][12][13], waveplates [14], and holograms [15,16]. Consequently, metasurfaces have immense potential in achieving both polarization conversion and intensitycontrolled beam splitting.…”

Section: Introductionmentioning

confidence: 99%

All-dielectric metasurfaces for intensity-controllable beam splitting and polarization conversion

Wang,

Zhang

et al. 2024

J. Phys. D: Appl. Phys.

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Beam splitters and polarization converters of electromagnetic waves based on metasurfaces have been extensively studied. However, there are few reports on the ability to arbitrarily control the intensity ratio between different diffraction orders while achieving beam splitting and polarization conversion. In this paper, we propose a method to achieve polarization conversion and beam splitting with varying intensities by manipulating the superposition of the output orthogonal circularly polarized (OCP) light. Specifically, polarized light with certain intensities and phase distributions in multiple channels can be decomposed into the superposition of OCP light with varying amplitudes and phases. Under the excitation of circularly polarized (CP) light, the amplitudes and phases of the output OCP light can be manipulated by adjusting the size and rotation angle of the nanopillar within the meta-atom. We show three metasurfaces capable of converting CP light into OCP and linearly polarized light in dual channels, with the ability to vary the intensity ratios of these polarized lights. Simulations demonstrate that the diffraction efficiencies of the desired diffraction orders of three metasurfaces exceed 90%. This method provides a novel concept for the design of multifunctional meta-devices.

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Multiwavelength high-order optical vortex detection and demultiplexing coding using a metasurface

Cited by 19 publications

References 55 publications

Deep image prior plus sparsity prior: toward single-shot full-Stokes spectropolarimetric imaging with a multiple-order retarder

Deep image prior plus sparsity prior: toward single-shot full-Stokes spectropolarimetric imaging with a multiple-order retarder

Off-axis bifocal metalens for displacement measurement

All-dielectric metasurfaces for intensity-controllable beam splitting and polarization conversion

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