Abstract
Magnetic resonance imaging (MRI) has become a helpful technique and developed rapidly in clinical medicine and diagnosis. Magnetic resonance (MR) images can display more clearly soft tissue structures and are important for doctors to diagnose diseases. However, the long acquisition and transformation time of MR images may limit their application in clinical diagnosis. Compressed sensing methods have been widely used in faithfully reconstructing MR images and greatly shorten the scanning and transforming time. In this paper we present a compressed sensing model based on median filter for MR image reconstruction. By combining a total variation term, a median filter term, and a data fitting term together, we first propose a minimization problem for image reconstruction. The median filter term makes our method eliminate additional noise from the reconstruction process and obtain much clearer reconstruction results. One key point of the proposed method lies in the fact that both the total variation term and the median filter term are presented in the L1 norm formulation. We then apply the split Bregman technique for fast minimization and give an efficient algorithm. Finally, we apply our method to numbers of MR images and compare it with a related method. Reconstruction results and comparisons demonstrate the accuracy and efficiency of the proposed model.
Highlights
Compressed sensing [1,2,3] is a new sampling theory appearing in signal and image processing communities; it allows us to directly acquire a data with compressed representation
We evaluate the improvement of the proposed model by comparing the peak signal-to-noise ratio (PSNR) value and the computational time with the SBA model for a number of 100 brain Magnetic resonance (MR) images
We present a fast compressed sensing model for accurate and efficient MR image reconstruction in this paper
Summary
Compressed sensing [1,2,3] is a new sampling theory appearing in signal and image processing communities; it allows us to directly acquire a data with compressed representation. The compressed sensing method can reconstruct the original signal accurately by using a small number of linear combinations of the compression transform coefficients. The theory has been introduced to image reconstruction [4,5,6,7], wireless sensor networks [8,9,10], speech coding [11, 12], image memorability prediction [13], and others [14,15,16]. In MRI, compressed sensing has been used to shorten magnetic resonance imaging scanning sessions on conventional hardware
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