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A Physics-Constrained Learning Framework for Wave Propagation in Complex Poroelastic Multilayered Media

Medical Physics 2026-05-07 v1

Abstract

Wave propagation through complex poroelastic multilayered media is difficult to model and invert because pronounced heterogeneity, scattering, mode conversion and fluid-solid coupling jointly distort acoustic signals during propagation. Here we present Physics-Constrained Learning for Complex Multilayered Media (PCL-CMM), a general framework that integrates Biot's poroelastic theory with the elastic wave equation to bridge the gap between physically rigorous wave modelling and data-driven learning. PCL-CMM constructs a high-fidelity digital twin that dynamically computes an effective acoustic stiffness tensor for forward wave modelling and incorporates the resulting physical constraint as a loss term to regularize the training of deep neural networks. We demonstrate PCL-CMM on transcranial photoacoustic imaging, where skull-induced acoustic distortions severely degrade image formation. Across simulations and ex vivo experiments, PCL-CMM effectively compensates for these distortions and improves SSIM by more than 0.06 compared with purely data-driven neural networks. This work establishes a physics-constrained learning framework for acoustic wave modelling in complex poroelastic multilayered media.

Cite

@article{arxiv.2605.04596,
  title  = {A Physics-Constrained Learning Framework for Wave Propagation in Complex Poroelastic Multilayered Media},
  author = {Ya Gao and Yifan Wang and Yiming Chen and Haohan Sun and Shoukun Lyu and Junmei Cao and Weijiang Xu and Qian Cheng},
  journal= {arXiv preprint arXiv:2605.04596},
  year   = {2026}
}

Comments

30 pages,8 figures,2 tables

R2 v1 2026-07-01T12:52:18.334Z