Generative Multi-Functional Meta-Atom and Metasurface Design Networks
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Metasurfaces are being widely investigated and adopted for their promising performances in manipulating optical wavefronts and their potential for integrating multi-functionalities into one flat optical device. A key challenge in metasurface design is the non-intuitive design process that produces models and patterns from specific design requirements (commonly electromagnetic responses). A complete exploration of all design spaces can produce optimal designs but is unrealistic considering the massive amount of computation power required to explore large parameter spaces. Meanwhile, machine learning techniques, especially generative adversarial networks, have proven to be an effective solution to non-intuitive design tasks. In this paper, we present a novel conditional generative network that can generate meta-atom/metasurface designs based on different performance requirements. Compared to conventional trial-and-error or iterative optimization design methods, this new methodology is capable of producing on-demand freeform designs on a one-time calculation basis. More importantly, an increased complexity of design goals doesn't introduce further complexity into the network structure or the training process, which makes this approach suitable for multi-functional device designs. Compared to previous deep learning-based metasurface approaches, our network structure is extremely robust to train and converge, and is readily expanded to many multi-functional metasurface devices, including metasurface filters, lenses and holograms.
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