On a Hidden Property in Computational Imaging
This provides a novel perspective for understanding computational imaging tasks, but it is incremental as it focuses on empirical demonstration without broad SOTA impact.
The paper tackles the problem of understanding computational imaging inverse problems by empirically demonstrating that three different problems (Full Waveform Inversion, Computed Tomography, and Electromagnetic inversion) share a hidden property in their latent spaces, where modalities follow the same equations with linearly correlated initial conditions.
Computational imaging plays a vital role in various scientific and medical applications, such as Full Waveform Inversion (FWI), Computed Tomography (CT), and Electromagnetic (EM) inversion. These methods address inverse problems by reconstructing physical properties (e.g., the acoustic velocity map in FWI) from measurement data (e.g., seismic waveform data in FWI), where both modalities are governed by complex mathematical equations. In this paper, we empirically demonstrate that despite their differing governing equations, three inverse problems (FWI, CT, and EM inversion) share a hidden property within their latent spaces. Specifically, using FWI as an example, we show that both modalities (the velocity map and seismic waveform data) follow the same set of one-way wave equations in the latent space, yet have distinct initial conditions that are linearly correlated. This suggests that after projection into the latent embedding space, the two modalities correspond to different solutions of the same equation, connected through their initial conditions. Our experiments confirm that this hidden property is consistent across all three imaging problems, providing a novel perspective for understanding these computational imaging tasks.