English

Deep Proximal Learning for High-Resolution Plane Wave Compounding

Signal Processing 2021-12-24 v1

Abstract

Plane Wave imaging enables many applications that require high frame rates, including localisation microscopy, shear wave elastography, and ultra-sensitive Doppler. To alleviate the degradation of image quality with respect to conventional focused acquisition, typically, multiple acquisitions from distinctly steered plane waves are coherently (i.e. after time-of-flight correction) compounded into a single image. This poses a trade-off between image quality and achievable frame-rate. To that end, we propose a new deep learning approach, derived by formulating plane wave compounding as a linear inverse problem, that attains high resolution, high-contrast images from just 3 plane wave transmissions. Our solution unfolds the iterations of a proximal gradient descent algorithm as a deep network, thereby directly exploiting the physics-based generative acquisition model into the neural network design. We train our network in a greedy manner, i.e. layer-by-layer, using a combination of pixel, temporal, and distribution (adversarial) losses to achieve both perceptual fidelity and data consistency. Through the strong model-based inductive bias, the proposed architecture outperforms several standard benchmark architectures in terms of image quality, with a low computational and memory footprint.

Keywords

Cite

@article{arxiv.2112.12410,
  title  = {Deep Proximal Learning for High-Resolution Plane Wave Compounding},
  author = {Nishith Chennakeshava and Ben Luijten and Massimo Mischi and Yonina C. Eldar and Ruud J. G. van Sloun},
  journal= {arXiv preprint arXiv:2112.12410},
  year   = {2021}
}
R2 v1 2026-06-24T08:29:15.303Z