dc.identifier.citation |
Arguello, H., Bacca, J., Kariyawasam, H., Vargas, E., Marquez, M., Hettiarachchi, R., Garcia, H., Herath, K., Haputhanthri, U., Ahluwalia, B., So, P., Wadduwage, D., & Edussooriya, C. (2023). Deep Optical Coding Design in Computational Imaging: A data-driven framework. IEEE Signal Processing Magazine, 40, 75–88. https://doi.org/10.1109/MSP.2022.3200173 |
en_US |
dc.description.abstract |
Computational optical imaging (COI) systems leverage optical
coding elements (CEs) in their setups to encode a highdimensional
scene in a single or in multiple snapshots and
decode it by using computational algorithms. The performance
of COI systems highly depends on the design of its main components:
the CE pattern and the computational method used
to perform a given task. Conventional approaches rely on random
patterns or analytical designs to set distribution of the CE.
However, the available data and algorithm capabilities of deep
neural networks (DNNs) have opened a new horizon in CE
data-driven designs that jointly consider the optical and computational
decoders. Specifically, by modeling the COI measurements
through a fully differentiable image-formation model
that considers the physics-based propagation of light and its interaction
with the CEs, the parameters that define the CE and
the computational decoder can be optimized in an end-to-end
(E2E) manner. Moreover, by optimizing just CEs in the same
framework, inference tasks can be performed from pure optics.
This work surveys the recent advances in CE data-driven design
and provides guidelines on how to parameterize different
optical elements to include them in the E2E framework. As the
E2E framework can handle different inference applications by
changing the loss function and the DNN, we present low-level
tasks such as spectral imaging reconstruction or high-level tasks
such as pose estimation with privacy preservation enhanced by
using optimal task-based optical architectures. Finally, we illustrate
classification and 3D object-recognition applications performed
at the speed of the light using all-optics DNNs. |
en_US |