Planar Fourier optics for slab waveguides, surface plasmon polaritons, and 2D materials

Wetherfield, Benjamin; Wilkinson, Timothy D.

doi:10.1364/ol.491576

Cited by 2 publications

(2 citation statements)

References 26 publications

Supporting

Mentioning

Contrasting

Order By: Relevance

“…For solving a homogeneous Helmholtz Equation with closed boundary conditions on the boundary ∂V of a volume (3D) or surface (2D) V , we can derive (equivalently for 2D and 3D cases 1,14 ) the Kirchhoff-Helmholtz-Weber formula, stating…”

Section: Introductionmentioning

confidence: 99%

Time-aware Fourier optics: modeling implications and device performance predictions

Wetherfield,

Wilkinson

2023

Optical Modeling and Performance Predictions XIII

Self Cite

View full text Add to dashboard Cite

The theory of Fourier Optics uses scalar diffraction models which provide simple, computationally efficient, and reasonably accurate tools for designing, optimizing and interpreting the performance of a wide range of devices and observed optical phenomena. Conventional approaches assume the time-separability of the relevant wave phenomena interpreted in terms of partial differential equations. Since light propagates in a time-dependent manner, certain mathematical formalisms must be injected to assure the validity of these methods. Moreover, in the case of two-dimensional propagation, the actual accuracy of the model suffers on account of the inherent time-dependent and diffusive nature of planar wave propagation. To resolve these imprecisions, we propose a “Time-Aware” approach to Fourier Optics and scalar diffraction, which closely matches the predictions of Fourier Optics for slowly changing input signals but accounts for a time-based error in integrated photonic devices with high clock speed.

show abstract

Section: Introductionmentioning

confidence: 99%

Time-aware Fourier optics: modeling implications and device performance predictions

Wetherfield,

Wilkinson

2023

Optical Modeling and Performance Predictions XIII

Self Cite

View full text Add to dashboard Cite

show abstract

“…Despite many benefits offered by on-chip diffractive optical neural networks like low-power consumption and light-speed parallel signal processing, challenges are faced because of deviations between the diffraction-based analysis methods and experimental/full-wave electromagnetic verifications. While this discrepancy was mainly attributed to the limited capability of the diffraction-based analysis methods in modelling the evolution of optical fields through the network [2,8] and several previous works attempted to unravel the problem by applying a relatively large distance between successive metasurfaces to maintain stable interference [3][4][5], restricting multiple consecutive meta-atoms to be the same in the metasurfaces to decrease the mutual coupling between the adjacent meta-atoms [3][4][5][6][7], etc.…”

Section: Introductionmentioning

confidence: 99%

Realization of optical logic gates using on-chip diffractive optical neural networks

Zarei

Khavasi

2022

Preprint

View full text Add to dashboard Cite

Optical computing is highly desired as a potential strategy for circumventing the performance limitations of semiconductor-based electronic devices and circuits. Optical logic gates are considered as fundamental building blocks for optical computation and they enable logic functions to be performed extremely quickly without the generation of heat and crosstalk. Here, we discuss the design of a multi-functional optical logic gate based on an on-chip diffractive optical neural network that can perform AND, NOT and OR logic operations at the wavelength of 1.55µm. The wavelength-independent operation of the multi-functional logic gate at seven wavelengths (over a bandwidth of 60nm) is also studied which paves the way for wavelength division multiplexed parallel computation. This simple, highly-integrable, low-loss, energy-efficient and broadband optical logic gate provides a path for the development of high-speed on-chip nanophotonic processors for future optical computing applications.

show abstract

Planar Fourier optics for slab waveguides, surface plasmon polaritons, and 2D materials

Cited by 2 publications

References 26 publications

Time-aware Fourier optics: modeling implications and device performance predictions

Time-aware Fourier optics: modeling implications and device performance predictions

Realization of optical logic gates using on-chip diffractive optical neural networks

Contact Info

Product

Resources

About