Learning the Geometry of Wave-Based Imaging
Konik Kothari, Maarten de Hoop, Ivan Dokmanić
Spotlight presentation: Orals & Spotlights Track 28: Deep Learning
on 2020-12-10T07:20:00-08:00 - 2020-12-10T07:30:00-08:00
on 2020-12-10T07:20:00-08:00 - 2020-12-10T07:30:00-08:00
Poster Session 6 (more posters)
on 2020-12-10T09:00:00-08:00 - 2020-12-10T11:00:00-08:00
GatherTown: Deep Learning ( Town C3 - Spot D0 )
on 2020-12-10T09:00:00-08:00 - 2020-12-10T11:00:00-08:00
GatherTown: Deep Learning ( Town C3 - Spot D0 )
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Toggle Abstract Paper (in Proceedings / .pdf)
Abstract: We propose a general physics-based deep learning architecture for wave-based imaging problems. A key difficulty in imaging problems with a varying background wave speed is that the medium ``bends'' the waves differently depending on their position and direction. This space-bending geometry makes the equivariance to translations of convolutional networks an undesired inductive bias. We build an interpretable neural architecture inspired by Fourier integral operators (FIOs) which approximate the wave physics. FIOs model a wide range of imaging modalities, from seismology and radar to Doppler and ultrasound. We focus on learning the geometry of wave propagation captured by FIOs, which is implicit in the data, via a loss based on optimal transport. The proposed FIONet performs significantly better than the usual baselines on a number of imaging inverse problems, especially in out-of-distribution tests.