Computer-generated stratified diffractive optical elements

Borgsmüller, Stefan; Noehte, S.; Dietrich, Christoph H.; Kresse, Tobias; Männer, Reinhard

doi:10.1364/ao.42.005274

Cited by 34 publications

(12 citation statements)

References 9 publications

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“…4, [3,4]). The result of the design algorithm are required fields u el,l (x) that have to be realized by the height structures.…”

Section: Design and Analysis Of Multi Plane Cghmentioning

confidence: 99%

“…1). With this concept it is for example possible to achieve higher diffraction efficiencies in the case of gratings [1,2], the multiplexing of several pages of information into one CGH [3], the creation of color images [4] or the combination of several different optical functionalities [5]. The reaction of a multi plane setup to a change in any setup parameter (like illumination wavelength, illumination direction, distance between the planes, refractive index) is a lot more complex than in the single plane case.…”

Section: Introductionmentioning

confidence: 99%

“…The most common one is the iterative Fourier transform algorithm (IFTA). A method that extends these algorithm to more than one plane while maintaining its original flexibility is described in [3,4]. It allows to encode multiple arbitrary pages of information into a multi plane CGH.…”

Section: Introductionmentioning

confidence: 99%

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Comparison of different simulation methods for multiplane computer generated holograms

et al. 2008

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Computer generated holograms (CGH) are used to transform an incoming light distribution into a desired output. Recently multi plane CGHs became of interest since they allow the combination of some well known design methods for thin CGHs with unique properties of thick holograms. Iterative methods like the iterative Fourier transform algorithm (IFTA) require an operator that transforms a required optical function into an actual physical structure (e.g. a height structure). Commonly the thin element approximation (TEA) is used for this purpose. Together with the angular spectrum of plane waves (APSW) it has also been successfully used in the case of multi plane CGHs. Of course, due to the approximations inherent in TEA, it can only be applied above a certain feature size. In this contribution we want to give a first comparison of the TEA & ASPW approach with simulation results from the Fourier modal method (FMM) for the example of one dimensional, pattern generating, multi plane CGH

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“…4, [3,4]). The result of the design algorithm are required fields u el,l (x) that have to be realized by the height structures.…”

Section: Design and Analysis Of Multi Plane Cghmentioning

confidence: 99%

Section: Introductionmentioning

confidence: 99%

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Comparison of different simulation methods for multiplane computer generated holograms

et al. 2008

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“…Diffraction properties of stratified volume holographic optical elements have been researched and, for example, the angular selectivity of such devices has been demonstrated as a function of buffer layer parameters [3]. Several works have examined angular and wavelength selectivity with possible practical applications for iteratively designed multiple CGH planes in a cascaded setup [4][5][6]. In addition, a general design procedure has been proposed, and some multiplexing characteristics have been shown, for classes of volumetric optical devices [7,8].…”

Section: Introductionmentioning

confidence: 99%

Cascaded diffractive optical elements for improved multiplane image reconstruction

Gulses

Jenkins

2013

Appl. Opt.

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Computer-generated phase-only diffractive optical elements in a cascaded setup are designed by one deterministic and one stochastic algorithm for multiplane image formation. It is hypothesized that increasing the number of elements as wavefront modulators in the longitudinal dimension would enlarge the available solution space, thus enabling enhanced image reconstruction. Numerical results show that increasing the number of holograms improves quality at the output. Design principles, computational methods, and specific conditions are discussed.

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“…Further, new insight in wave manipulation and the ever-increasing power of computers enable diffractive optics to generate user-defined wavefronts from arbitrary inputs, by virtue of degrees of freedom from pixels that can be addressed individually and independently 9-11 . Beyond classical applications such as beam shaping 12,13 , 3D display 14,15 , information security 16,17 , spectroscopy 18 , metrology 19 , and astronomical imaging 20 , emerging areas include optical tweezers 21,22 , novel microscopies 23,24 , coherent control 25,26 , quantum information 27,28 , neural networks 29,30 , and optogenetics 31,32 .Three dimensional (3D) diffractive optics expand the capabilities of traditional two-dimensional elements not only by providing higher diffraction efficiency and higher information capacity, but also enabling functionalities such as multiplexing and space-variant functions [33][34][35] . The capability of controlling multidimensional spatial, spectral, temporal, and coherence functions of light fields is originated from the multi-subject nature of 3D diffractive optics involving diffraction, refraction, absorption, resonances, and scattering.In spite of being a topic of great interest, 3D diffractive optics have not been fully investigated due to their physical and mathematical complexity, where the challenge stems from three aspects: First, the wavefront propagation must obey Maxwell's equations, while most arbitrary target patterns do not, causing the problem to be inconsistent.…”

mentioning

confidence: 99%

Azimuthal multiplexing 3D diffractive optics

Wang

Piestun

2020

Sci Rep

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Diffractive optics have increasingly caught the attention of the scientific community. Classical diffractive optics are 2D diffractive optical elements (DOEs) and computer-generated holograms (CGHs), which modulate optical waves on a solitary transverse plane. However, potential capabilities are missed by the inherent two-dimensional nature of these devices. Previous work has demonstrated that extending the modulation from planar (2D) to volumetric (3D) enables new functionalities, such as generating space-variant functions, multiplexing in the spatial or spectral domain, or enhancing information capacity. Unfortunately, despite significant progress fueled by recent interest in metasurface diffraction, 3D diffractive optics still remains relatively unexplored. Here, we introduce the concept of azimuthal multiplexing. We propose, design, and demonstrate 3D diffractive optics showing this multiplexing effect. According to this new phenomenon, multiple pages of information are encoded and can be read out across independent channels by rotating one or more diffractive layers with respect to the others. We implement the concept with multilayer diffractive optical elements. An iterative projection optimization algorithm helps solve the inverse design problem. The experimental realization using photolithographically fabricated multilevel phase layers demonstrates the predicted performance. We discuss the limitations and potential of azimuthal multiplexing 3D diffractive optics.With feature sizes comparable to electromagnetic wavelength, diffractive optics offers a unique pathway to light manipulation 1-3 . It expands the capabilities of conventional optics based on refraction or reflection and in conjunction with free-form 4,5 , graded index 6 , and artificial (meta) materials 7,8 provide full access to the spatial degrees of freedom of light. Further, new insight in wave manipulation and the ever-increasing power of computers enable diffractive optics to generate user-defined wavefronts from arbitrary inputs, by virtue of degrees of freedom from pixels that can be addressed individually and independently 9-11 . Beyond classical applications such as beam shaping 12,13 , 3D display 14,15 , information security 16,17 , spectroscopy 18 , metrology 19 , and astronomical imaging 20 , emerging areas include optical tweezers 21,22 , novel microscopies 23,24 , coherent control 25,26 , quantum information 27,28 , neural networks 29,30 , and optogenetics 31,32 .Three dimensional (3D) diffractive optics expand the capabilities of traditional two-dimensional elements not only by providing higher diffraction efficiency and higher information capacity, but also enabling functionalities such as multiplexing and space-variant functions [33][34][35] . The capability of controlling multidimensional spatial, spectral, temporal, and coherence functions of light fields is originated from the multi-subject nature of 3D diffractive optics involving diffraction, refraction, absorption, resonances, and scattering.In spite of being a topic of gr...

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Computer-generated stratified diffractive optical elements

Cited by 34 publications

References 9 publications

Comparison of different simulation methods for multiplane computer generated holograms

Comparison of different simulation methods for multiplane computer generated holograms

Cascaded diffractive optical elements for improved multiplane image reconstruction

Azimuthal multiplexing 3D diffractive optics

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