Radiation design in computed tomography via convex optimization

01/06/2023

∙

Proper X-ray radiation design (via dynamic fluence field modulation, FFM) allows to reduce effective radiation dose in computed tomography without compromising image quality. It takes into account patient anatomy, radiation sensitivity of different organs and tissues, and location of regions of interest. We account all these factors within a general convex optimization framework.

READ FULL TEXT

Radiation design in computed tomography via convex optimization

High-quality Low-dose CT Reconstruction Using Convolutional Neural Networks with Spatial and Channel Squeeze and Excitation

X-ray Dissectography Enables Stereotography to Improve Diagnostic Performance

Sinogram constrained TV-minimization for metal artifact reduction in CT

Cracking predictions of lithium-ion battery electrodes by X-ray computed tomography and modelling

Bayesian Experimental Design for Computed Tomography with the Linearised Deep Image Prior

Tensor-based formulation and nuclear norm regularization for multi-energy computed tomography

Shapley effects and proportional marginal effects for global sensitivity analysis: application to computed tomography scan organ dose estimation

Radiation design in computed tomography via convex optimization

Related Research

High-quality Low-dose CT Reconstruction Using Convolutional Neural Networks with Spatial and Channel Squeeze and Excitation

X-ray Dissectography Enables Stereotography to Improve Diagnostic Performance

Sinogram constrained TV-minimization for metal artifact reduction in CT

Cracking predictions of lithium-ion battery electrodes by X-ray computed tomography and modelling

Bayesian Experimental Design for Computed Tomography with the Linearised Deep Image Prior

Tensor-based formulation and nuclear norm regularization for multi-energy computed tomography

Shapley effects and proportional marginal effects for global sensitivity analysis: application to computed tomography scan organ dose estimation