End-to-end metasurface inverse design for single-shot multi-channel imaging
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<jats:p>We introduce end-to-end inverse design for multi-channel imaging, in which a nanophotonic frontend is optimized in conjunction with an image-processing backend to extract depth, spectral and polarization channels from a single monochrome image. Unlike diffractive optics, we show that subwavelength-scale “metasurface” designs can easily distinguish similar wavelength and polarization inputs. The proposed technique integrates a single-layer metasurface frontend with an efficient Tikhonov reconstruction backend, without any additional optics except a grayscale sensor. Our method yields multi-channel imaging by spontaneous demultiplexing: the metaoptics front-end separates different channels into distinct spatial domains whose locations on the sensor are optimally discovered by the inverse-design algorithm. We present large-area metasurface designs, compatible with standard lithography, for multi-spectral imaging, depth-spectral imaging, and “all-in-one” spectro-polarimetric-depth imaging with robust reconstruction performance (≲ 10% error with 1% detector noise). In contrast to neural networks, our framework is physically interpretable and does not require large training sets. It can be used to reconstruct arbitrary three-dimensional scenes with full multi-wavelength spectra and polarization textures.</jats:p>
Date issued
2022-07-19Department
Massachusetts Institute of Technology. Department of Mathematics; Massachusetts Institute of Technology. Research Laboratory of Electronics; Massachusetts Institute of Technology. Department of PhysicsPublisher
Optica Publishing Group
Citation
Lin, Zin, Pestourie, Raphaël, Roques-Carmes, Charles, Li, Zhaoyi, Capasso, Federico et al. 2022. "End-to-end metasurface inverse design for single-shot multi-channel imaging." 30 (16).
Version: Final published version
ISSN
1094-4087
Keywords
Atomic and Molecular Physics, and Optics