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Imaging depth and spectrum have been extensively studied in isolation from each other for decades. Recently, hyperspectral-depth (HS-D) imaging emerges to capture both information simultaneously by combining two different imaging systems; one for depth, the other for spectrum. While being accurate, this combinational approach induces increased form factor, cost, capture time, and alignment/registration problems. In this work, departing from the combinational principle, we propose a compact single-shot monocular HS-D imaging method. Our method uses a diffractive optical element (DOE), the point spread function of which changes with respect to both depth and spectrum. This enables us to reconstruct spectrum and depth from a single captured image. To this end, we develop a differentiable simulator and a neural-network-based reconstruction that are jointly optimized via automatic differentiation. To facilitate learning the DOE, we present a first HS-D dataset by building a benchtop HS-D imager that acquires high-quality ground truth. We evaluate our method with synthetic and real experiments by building an experimental prototype and achieve state-of-the-art HS-D imaging results.
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@InProceedings{Baek_2021_ICCV,
author = {Seung-Hwan Baek and Hayato Ikoma and Daniel S. Jeon and Yuqi Li
and Wolfgang Heidrich and Gordon Wetzstein and Min H. Kim},
title = {Single-shot Hyperspectral-Depth Imaging with Learned Diffractive
Optics},
booktitle = {Proc. IEEE International Conference on Computer Vision (ICCV)},
month = {Oct},
year = {2021}
}
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