Matrix imaging: an innovation for improving ultrasound resolution


In conventional ultrasounds, variations in soft tissue structure distort ultrasound wavefronts. They blur the image and can hence prove detrimental to medical diagnosis. Researchers at the Institut Langevin (CNRS/ESPCI Paris-PSL)1 have developed a new non-invasive ultrasound method that avoids such aberrations. In an article published in the journal PNAS on 10 June 2020, the scientists showed how this method can subtly compensate for the distortions that a focused wave undergoes as it travels through the studied tissue, with an ideal resolution and contrast optimized for each pixel in the image. This approach can be extended to any type of wave, and can be controlled by a multi-sensor network. Applications range from biomedical diagnosis to optical microscopy, detection of cracks in industrial materials, and the monitoring of volcanoes and fault zones in geophysics.

This imaging method, known as matrix imaging, was also the subject of an article published recently in the journal Physical Review X, as it can also help develop new approaches to imaging. This research was funded by an ERC Consolidator grant (no. 819261) as part of the European Union’s Horizon 2020 Programme for Research and Innovation, and led to the filing of a patent by the CNRS, published in February 2020 (WO2020016250A1).

Conventional and matrix ultrasound images of a volunteer’s calf. Matrix correction of aberrations reveals structures that were previously invisible or had poor resolution in a conventional ultrasound (especially in the areas inside the white lines)
© Walter et al./PNAS


  • 1In collaboration with the company SuperSonic Imagine, based in Aix-en-Provence (France).

Distortion matrix approach for ultrasound imaging of random scattering media. W. Lambert, L. A. Cobus, T. Frappart, M. Fink and A. Aubry. PNAS, 10 June 2020.

Preliminary version posted on arXiv on 11 December 2019: arXiv:1912.05417



Alexandre Aubry
CNRS researcher
François Maginiot
CNRS Press Officer