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arxiv: 2011.11754 · v2 · pith:KBSKZ5G7new · submitted 2020-11-23 · ⚛️ physics.optics · cs.LG· physics.app-ph

Machine Learning enables Ultra-Compact Integrated Photonics through Silicon-Nanopattern Digital Metamaterials

classification ⚛️ physics.optics cs.LGphysics.app-ph
keywords devicesdigitalmetamaterialsultra-compactlearningmachinemanufacturablephotonics
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In this work, we demonstrate three ultra-compact integrated-photonics devices, which are designed via a machine-learning algorithm coupled with finite-difference time-domain (FDTD) modeling. Through digitizing the design domain into "binary pixels" these digital metamaterials are readily manufacturable as well. By showing a variety of devices (beamsplitters and waveguide bends), we showcase the generality of our approach. With an area footprint smaller than ${\lambda_0}^2$, our designs are amongst the smallest reported to-date. Our method combines machine learning with digital metamaterials to enable ultra-compact, manufacturable devices, which could power a new "Photonics Moore's Law."

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