Computational imaging through scattering materials using speckle correlation

ERC (European Research Council)HORIZON-ERCID: 101043471
EC Contribution
€21,250
Consortium Size
1 orgs
Start Year
2023
Summary

When viewed under coherent imaging conditions (e.g. laser illumination), scattering materials such as biological tissues create noise-like images known as speckle. Despite their seemingly random nature, speckle patterns have strong statistical correlation properties that are highly informative of the material producing them. These can be used to enable remarkable imaging capabilities, not possible with current state of the art, for example seeing through highly scattering layers.Unfortunately, realizing these in practical settings (tissue imaging, fluorescence microscopy) remains a challenge. Research efforts are hindered by a lack of modeling tools, resulting in an incomplete understanding of speckle properties.This project aims to use computational techniques from computer vision and computer graphics to greatly enhance our understanding of speckle statistics, and significantly expand the scope of their applications.To this end, the project will explore algorithmic tools newly-developed by the PI that can accurately and efficiently simulate speckle patterns, to formulate better models of speckle formation.We will exploit our new understanding to develop new types of computational imaging systems that can directly measure speckle correlation, rather than the traditional pipeline where one captures speckle images and estimates their correlations algorithmically in post-processing.Finally, we will exploit these tools in multiple computational imaging applications, including: (i) Acquiring material parameters: estimating the type, size and density of particles composing a material of interest. (ii) Imaging fluorescent sources deep inside scattering tissue. (iii) Adaptive optics imaging.Potential impact is anticipated in numerous areas where speckle-based imaging techniques hold promise, including medicine (increased depth penetration of tissue imaging techniques) and material fabrication and analysis (accurate characterization of scattering materials).

Consortium (1)

Project Results (7)

Source: CORDIS, the EU research results database.

Publications (5)
Rapid wavefront shaping using an optical gradient acquisition
· 2025
Sagi Monin, Marina Alterman, Anat Levin
Coherence As Texture - Passive Textureless 3D Reconstruction by Self-interference
CVPR· 2024
Wei-Yu Chen, Aswin C. Sankaranarayanan, Anat Levin, Matthew O'Toole
Nature Communications
Nature Communications· 2024DOI
Dror Aizik; Anat Levin
Understanding multi-layered transmission matrices
accepted to CVPR 2025· 2024DOI
M. Alterman, A. Levin
Efficient Monte Carlo simulation of spatiotemporal speckles and their correlations
Optica· 2023DOI
Chen Bar; Ioannis Gkioulekas; Anat Levin
Deliverables (1)
Data Management Plan
Other Results (1)
Periodic Reporting for period 1 - SpeckleCorr (Computational imaging through scattering materials using speckle correlation)