ADJUST: A Dictionary-Based Joint Reconstruction and Unmixing Method for Spectral Tomography

TL;DR

ADJUST is a novel dictionary-based joint reconstruction and unmixing method for spectral tomography that effectively estimates material maps and spectral responses, outperforming existing methods especially under limited or noisy data conditions.

Contribution

The paper introduces ADJUST, a new joint reconstruction and unmixing approach using spectral dictionaries and an efficient optimization algorithm for spectral CT.

Findings

ADJUST outperforms state-of-the-art methods in synthetic phantom tests.

It demonstrates robustness against limited and noisy measurements.

Potential applicability to real-world spectral micro-CT data.

Abstract

Advances in multi-spectral detectors are causing a paradigm shift in X-ray Computed Tomography (CT). Spectral information acquired from these detectors can be used to extract volumetric material composition maps of the object of interest. If the materials and their spectral responses are known a priori, the image reconstruction step is rather straightforward. If they are not known, however, the maps as well as the responses need to be estimated jointly. A conventional workflow in spectral CT involves performing volume reconstruction followed by material decomposition, or vice versa. However, these methods inherently suffer from the ill-posedness of the joint reconstruction problem. To resolve this issue, we propose 'A Dictionary-based Joint reconstruction and Unmixing method for Spectral Tomography' (ADJUST). Our formulation relies on forming a dictionary of spectral signatures of materials common in CT and prior knowledge of the number of materials present in an object. In particular, we decompose the spectral volume linearly in terms of spatial material maps, a spectral dictionary, and the indicator of materials for the dictionary elements. We propose a memory-efficient accelerated alternating proximal gradient method to find an approximate solution to the resulting bi-convex problem. From numerical demonstrations on several synthetic phantoms, we observe that ADJUST performs exceedingly well compared to other state-of-the-art methods. Additionally, we address the robustness of ADJUST against limited and noisy measurement patterns. The demonstration of the proposed approach on a spectral micro-CT dataset shows its potential for real-world applications. Code is available at https://github.com/mzeegers/ADJUST.