Litcius/Paper detail

Large area optimization of meta-lens via data-free machine learning

Maksym Zhelyeznyakov, Johannes E. Fröch, Anna Wirth-Singh, Jaebum Noh, Junsuk Rho, Steven L. Brunton, Arka Majumdar

2023Communications Engineering42 citationsDOIOpen Access PDF

Abstract

Abstract Sub-wavelength diffractive optics, commonly known as meta-optics, present a complex numerical simulation challenge, due to their multi-scale nature. The behavior of constituent sub-wavelength scatterers, or meta-atoms, needs to be modeled by full-wave electromagnetic simulations, whereas the whole meta-optical system can be modeled using ray/ Fourier optics. Most simulation techniques for large-scale meta-optics rely on the local phase approximation (LPA), where the coupling between dissimilar meta-atoms is neglected. Here we introduce a physics-informed neural network, coupled with the overlapping boundary method, which can efficiently model the meta-optics while still incorporating all of the coupling between meta-atoms. We demonstrate the efficacy of our technique by designing 1mm aperture cylindrical meta-lenses exhibiting higher efficiency than the ones designed under LPA. We experimentally validated the maximum intensity improvement (up to 53%) of the inverse-designed meta-lens. Our reported method can design large aperture ( ~ 10 4 − 10 5 λ ) meta-optics in a reasonable time (approximately 15 minutes on a graphics processing unit) without relying on the LPA.

Topics & Concepts

Geometrical opticsPhysical opticsGaussian opticsOpticsCoupling (piping)Meta learning (computer science)Computer scienceAperture (computer memory)Lens (geology)WavelengthArtificial neural networkPhysicsArtificial intelligenceMaterials scienceEngineeringAcousticsParaxial approximationTask (project management)MetallurgyBeam (structure)Systems engineeringPhotonic and Optical DevicesMetamaterials and Metasurfaces ApplicationsNeural Networks and Reservoir Computing