Fast Single Image Super-Resolution Using Estimated Low-Frequency k-Space Data in MRI

Abstract Purpose Single image super-resolution (SR) is highly desired in many fields but obtaining it is often technically limited in practice. The purpose of this study was to propose a simple, rapid and robust single image SR method in magnetic resonance (MR) imaging (MRI). Methods The idea is bas...

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Bibliographic Details
Published in:Magnetic resonance imaging 2017-07, Vol.40, p.1-11
Main Authors: Luo, Jianhua, Mou, Zhiying, Qin, Binjie, Li, Wanqing, Yang, Feng, Robini, Marc, Zhu, Yuemin
Format: Article
Language:English
Subjects:
Computer Science
Humans
Image interpolation
Image Processing, Computer-Assisted - methods
k-Space data
Magnetic Resonance Imaging
Medical Imaging
Phantoms, Imaging - standards
Radiology
Super-resolution
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Summary:Abstract Purpose Single image super-resolution (SR) is highly desired in many fields but obtaining it is often technically limited in practice. The purpose of this study was to propose a simple, rapid and robust single image SR method in magnetic resonance (MR) imaging (MRI). Methods The idea is based on the mathematical formulation of the intrinsic link in k-space between a given (modulus) low-resolution (LR) image and the desired SR image. The method consists of two steps: 1) estimating the low-frequency k-space data of the desired SR image from a single LR image; 2) reconstructing the SR image using the estimated low-frequency and zero-filled high-frequency k-space data. The method was evaluated on digital phantom images, physical phantom MR images and real brain MR images, and compared with existing SR methods. Results The proposed SR method exhibited a good robustness by reaching a clearly higher PSNR (25.77 dB) and SSIM (0.991) averaged over different noise levels in comparison with existing edge-guided nonlinear interpolation (EGNI) (PSNR=23.78 dB, SSIM=0.983), zero-filling (ZF) (PSNR=24.09 dB, SSIM=0.985) and total variation (TV) (PSNR=24.54dB, SSIM=0.987) methods while presenting the same order of computation time as the ZF method but being much faster than the EGNI or TV method. The average PSNR or SSIM over different slice images of the proposed method (PSNR=26.33 dB or SSIM=0.955) was also higher than the EGNI (PSNR=25.07 dB or SSIM=0.952), ZF (PSNR=24.97 dB or SSIM=0.950) and TV (PSNR=25.70 dB or SSIM=0.953) methods, demonstrating its good robustness to variation in anatomical structure of the images. Meanwhile, the proposed method always produced less ringing artifacts than the ZF method, gave a clearer image than the EGNI method, and did not exhibit any blocking effect presented in the TV method. In addition, the proposed method yielded the highest spatial consistency in the inter-slice dimension among the four methods. Conclusions This study proposed a fast, robust and efficient single image SR method with high spatial consistency in the inter-slice dimension for clinical MR images by estimating the low-frequency k-space data of the desired SR image from a single spatial modulus LR image.
ISSN:0730-725X
1873-5894
DOI:10.1016/j.mri.2017.03.008