2 research outputs found
Computational Spectral Imaging: A Contemporary Overview
Spectral imaging collects and processes information along spatial and
spectral coordinates quantified in discrete voxels, which can be treated as a
3D spectral data cube. The spectral images (SIs) allow identifying objects,
crops, and materials in the scene through their spectral behavior. Since most
spectral optical systems can only employ 1D or maximum 2D sensors, it is
challenging to directly acquire the 3D information from available commercial
sensors. As an alternative, computational spectral imaging (CSI) has emerged as
a sensing tool where the 3D data can be obtained using 2D encoded projections.
Then, a computational recovery process must be employed to retrieve the SI. CSI
enables the development of snapshot optical systems that reduce acquisition
time and provide low computational storage costs compared to conventional
scanning systems. Recent advances in deep learning (DL) have allowed the design
of data-driven CSI to improve the SI reconstruction or, even more, perform
high-level tasks such as classification, unmixing, or anomaly detection
directly from 2D encoded projections. This work summarises the advances in CSI,
starting with SI and its relevance; continuing with the most relevant
compressive spectral optical systems. Then, CSI with DL will be introduced, and
the recent advances in combining the physical optical design with computational
DL algorithms to solve high-level tasks