Zusammenfassung
There is a critical need to reconstruct clinically usable images at a low dose. One way of achieving this is to reconstruct with as few projections as possible. Due to the undersampling, streak artifacts degrade image quality for traditional CT reconstruction. Compressed sensing (CS) [1] theory uses sparsity as a prior and improves the reconstruction quality considerably using only few projections. CS formulates the reconstruction problem to an optimization problem. The objective function consists of one data fidelity term and one regularization term which enforce the sparsity under a certain sparsifying transform. Curvelet is an effective sparse representation for objects [2]. In this work, we introduce to use curvelet as the sparsifying transform in the CS based reconstruction framework. The algorithm was evaluated with one physical phantom dataset and one in vitro dataset and was compared against and two state-of-art approach, namely, wavelet-based regularization (WR) [3] and total variation based regularization methods (TVR) [4]. The results show that the reconstruction quality of our approach is superior to the reconstruction quality of WR and TVR.
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Literatur
Donoho DL. Compressed sensing. IEEE Trans Inf Theory. 2006;52(4):1289–306.
Starck JL, Candès EJ, Donoho DL. The curvelet transform for image denoising. IEEE Trans Image Process. 2002;11(6):670–84.
Yu H, Wang G. SART-type image reconstruction from a limia fast and accurate method to solveted number of projections with the sparsity constraint. Int J Biomed Imaging. 2010;2010:3.
Sidky EY, Pan X, Reiser IS, et al. Enhanced imaging of microcalcifications in digital breast tomosynthesis through improved image-reconstruction algorithms. Med Phys. 2009;36:4920.
Brenner DJ, Hall EJ. Computed tomography: an increasing source of radiation exposure. N Engl J Med. 2007;357(22):2277–84.
Wu H, Maier A, Fahrig R, et al. Spatial-temporal total variation regularization (STTVR) for 4D-CT reconstruction. SPIE. 2012;8313:83133 J.
Starck JL, Candès EJ, Donoho DL. The curvelet transform for image denoising. IEEE Trans Image Process. 2002;11(6):670–84.
Donoho DL. De-noising by soft-thresholding. IEEE Trans Inf Theory. 1995;41(3):613–27.
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Wu, H., Maier, A., Hornegger, J. (2013). Iterative CT Reconstruction Using Curvelet-Based Regularization. In: Meinzer, HP., Deserno, T., Handels, H., Tolxdorff, T. (eds) Bildverarbeitung für die Medizin 2013. Informatik aktuell. Springer, Berlin, Heidelberg. https://doi.org/10.1007/978-3-642-36480-8_41
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DOI: https://doi.org/10.1007/978-3-642-36480-8_41
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