Diffraction Characteristics of a Digital Micromirror Device for Computer Holography Based on an Accurate Three-Dimensional Phase Model

Wang, Xiaoyu; Zhang, Hao

doi:10.3390/photonics10020130

Cited by 2 publications

(1 citation statement)

References 34 publications

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“…The experiments reported here used a green laser (532 nm), but any other wavelength can be used as well, provided the desired wavelength is used in the hologram computation and the SLM is calibrated for that particular wavelength. If a DMD is used, then wavelength calibration will not be necessary [37].…”

Section: Resultsmentioning

confidence: 99%

Tailoring Large Asymmetric Laguerre–Gaussian Beam Array Using Computer-Generated Holography

et al. 2023

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Laguerre–Gaussian beams are structured light beams with a donut-shaped symmetric intensity profile and a helical phase profile. The beam profile is defined by a quantized parameter known as the mode number which extends to infinity. The availability of unbounded modes makes these beams a promising candidate for next-generation optical computing, and optical communication technologies. The symmetric intensity profile of a Laguerre–Gaussian beam can be made asymmetric through certain techniques and these beams are known by the term `asymmetric Laguerre–Gaussian beams’. Here, the asymmetricity adds another degree of freedom to the beam (apart from its mode number) which helps in encoding more information compared to a symmetric beam. However, in order to harness the benefits of all the available degrees of freedom, it is required to generate a large number of such beams in a multiplexed fashion. Here, we report the generation of such a large array of asymmetric Laguerre–Gaussian beams for the first time. Computer-generated holography and spatial multiplexing techniques were employed to generate a large array comprising of 12 × 16 = 192 asymmetric Laguerre–Gaussian beams with an arbitrary mode index and asymmetricity.

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Section: Resultsmentioning

confidence: 99%

Tailoring Large Asymmetric Laguerre–Gaussian Beam Array Using Computer-Generated Holography

et al. 2023

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A practical guide to digital micro-mirror devices (DMDs) for wavefront shaping

Popoff,

Gutiérrez-Cuevas,

Bromberg

et al. 2024

J. Phys. Photonics

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Digital micromirror devices have gained popularity in wavefront shaping, offering a high frame rate alternative to liquid crystal spatial light modulators. They are relatively inexpensive, offer high resolution, are easy to operate, and a single device can be used in a broad optical bandwidth. However, some technical drawbacks must be considered to achieve optimal performance. These issues, often undocumented by manufacturers, mostly stem from the device's original design for video projection applications. Herein, we present a guide to characterize and mitigate these effects. Our focus is on providing simple and practical solutions that can be easily incorporated into a typical wavefront shaping setup.

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Diffraction Characteristics of a Digital Micromirror Device for Computer Holography Based on an Accurate Three-Dimensional Phase Model

Cited by 2 publications

References 34 publications

Tailoring Large Asymmetric Laguerre–Gaussian Beam Array Using Computer-Generated Holography

Tailoring Large Asymmetric Laguerre–Gaussian Beam Array Using Computer-Generated Holography

A practical guide to digital micro-mirror devices (DMDs) for wavefront shaping

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