Subspace-based technique for speckle noise reduction in ultrasound images

Yahya, N. and Kamel, N.S. and Malik, A.S. (2014) Subspace-based technique for speckle noise reduction in ultrasound images. BioMedical Engineering Online, 13 (1).

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Official URL: https://www.scopus.com/inward/record.uri?eid=2-s2....

Abstract

Background and purpose: Ultrasound imaging is a very essential technique in medical diagnosis due to its being safe, economical and non-invasive nature. Despite its popularity, the US images, however, are corrupted with speckle noise, which reduces US images qualities, hampering image interpretation and processing stage. Hence, there are many efforts made by researches to formulate various despeckling methods for speckle reduction in US images. Methods: In this paper, a subspace-based speckle reduction technique in ultrasound images is proposed. The fundamental principle of subspace-based despeckling technique is to convert multiplicative speckle noise into additive via logarithmic transformation, then to decompose the vector space of the noisy image into signal and noise subspaces. Image enhancement is achieved by nulling the noise subspace and estimating the clean image from the remaining signal subspace. Linear estimation of the clean image is derived by minimizing image distortion while maintaining the residual noise energy below some given threshold. The real US data for validation purposes were acquired under the IRB protocol (200210851-7) at the University of California Davis, which is also consistent with NIH requirements. Results: Experiments are carried out using a synthetically generated B-mode ultrasound image, a computer generated cyst image and real ultrasound images. The performance of the proposed technique is compared with Lee, homomorphic wavelet and squeeze box filter (SBF) in terms of noise variance reduction, mean preservation, texture preservation and ultrasound despeckling assessment index (USDSAI). The results indicate better noise reduction capability with the simulated images by the SDC than Lee, Wavelet and SBF in addition to less blurry effect. With the real case scenario, the SDC, Lee, Wavelet and SBF are tested with images obtained from raw radio frequency (RF) data. Results generated using real US data indicate that, in addition to good contrast enhancement, the autocorrelation results shows better preservation of image texture by SDC than Lee, Wavelet and SBF. Conclusion: In general, the performance of the SDC filter is better than Lee, Wavelet and SBF in terms of noise reduction, improvement in image contrast and preservation of the autocorrelation profiles. Furthermore, the filter required less computational time compared to Lee, Wavelet and SBF, which indicates its suitability for real time application. © 2014 Yahya et al.

Item Type: Article
Impact Factor: cited By 11
Uncontrolled Keywords: Autocorrelation; Diagnosis; Image texture; Medical imaging; Signal analysis; Speckle; Speech enhancement; Textures; Ultrasonic applications; Ultrasonic imaging; Vector spaces; Vectors, B-mode ultrasound images; De-noising; Logarithmic transformations; Multiplicative speckle noise; Signal sub-space; Speckle reduction; University of California; USDSAI, Image denoising, Article; B scan; contrast enhancement; controlled study; echography; human; image analysis; image display; image enhancement; intermethod comparison; mathematical analysis; noise reduction; priority journal; signal noise ratio; spatial autocorrelation analysis; spatial domain constraint; squeeze box filter; statistical analysis; wavelet analysis; cyst; diagnostic imaging; imaging phantom; procedures; signal noise ratio, Cysts; Image Enhancement; Phantoms, Imaging; Signal-To-Noise Ratio; Ultrasonography
Depositing User: Ms Sharifah Fahimah Saiyed Yeop
Date Deposited: 25 Mar 2022 08:59
Last Modified: 25 Mar 2022 08:59
URI: http://scholars.utp.edu.my/id/eprint/31083

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