Affiliation:
1. Shanghai Institute of Optics and Fine Mechanics, Chinese Academy of Sciences
2. Wuxi University
3. Suzhou University of Science and Technology
Abstract
This study proposes a physics-enhanced neural network, PENTAGON, as an inference framework for volumetric tomography applications. By leveraging the synergistic combination of data-prior and forward-imaging model, we can accurately predict 3D optical fields, even when the number of projection views decreases to three. PENTAGON is proven to overcome the generalization limitation of data-driven deep learning methods due to data distribution shift, and eliminate distortions introduced by conventional iteration algorithms with limited projections. We evaluated PENTAGON using numerical and experimental results of a flame chemiluminescence tomography example. Results showed that PENTAGON can potentially be generalized for inverse tomography reconstruction problems in many fields.
Funder
National Natural Science Foundation of China
Shanghai Sailing Program
Program of Shanghai Academic Research Leader