Paper ID: 2409.06714
FCDM: Sparse-view Sinogram Inpainting with Frequency Domain Convolution Enhanced Diffusion Models
Jiaze E, Srutarshi Banerjee, Tekin Bicer, Guannan Wang, Bin Ren
Reducing the radiation dose in computed tomography (CT) is crucial, but it often results in sparse-view CT, where the number of available projections is significantly reduced. This reduction in projection data makes it challenging to accurately reconstruct high-quality CT images. In this condition, a sinogram, which is a collection of these projections, becomes incomplete. Sinogram inpainting then becomes essential because it enables accurate image reconstruction with limited projections. Existing models performing well on conventional RGB images for inpainting mostly fail in the case of sinograms. Further, these models usually do not make full use of unique properties, e.g., frequency features and absorption characteristics in the sinogram, and cannot handle large-area masks and complex real-world projections well. To address these limitations, we propose a novel model called the Frequency Convolution Diffusion Model (FCDM). It employs frequency domain convolutions to extract frequency information from various angles and capture the intricate relationships between these angles, which is essential for high-quality CT reconstruction. We also design a specific loss function based on the unique properties of a sinogram to maintain the consistency in physical properties, which allows the model to learn more effectively even in larger mask areas. We compare FCDM using both simulations and real data with nine inpainting models examples, among which two are designed for sinogram and seven for RGB. The results indicate that our model significantly improves the quality of the inpainted sinograms in terms of both visually and quantitatively, with an SSIM of more than 0.95 and PSNR of more than 30, achieving up to a 33% improvement in SSIM and a 29% improvement in PSNR compared to the baseline.
Submitted: Aug 26, 2024