Effective sparse representation of X-ray medical images

Aims. A modulation equation relates the observed data to the object where the observation is approximated by a linear system. Reconstructing the object from the observed data is therefore equivalent to solving the modulation equation. In this work we present the synthetic direct demodulation (synDD) method to reduce the dimensionality of a general modulation equation and solve the equation in its sparse representation. Methods. A principal component analysis is used to reduce the dimensionality of the kernel matrix and k-means clustering is applied to its sparse representation in order to decompose the kernel matrix into a weighted sum of a series of circulant matrices. The matrix-vector and matrix-matrix multiplication complexities are therefore reduced from polynomial time to linear-logarithmic time. A general statistical solution of the modulation equation in sparse representation is derived. Several data-analysis pipelines are designed for the Hard X-ray modulation Telescope (Insight-HXMT) based on the synDD method. Results. In this approach, a large set of data originating from the same object but sampled irregularly and/or observed with different instruments in multiple epochs can be reduced simultaneously in a synthetic observation model. We suggest using the proposed synDD method in Insight-HXMT data analysis especially for the detection of X-ray transients and monitoring time-varying objects with scanning observations.

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Enlarge Medical Image using Line-Column Interpolation (LCI) Method

International Journal of Electrical and Computer Engineering (IJECE) ◽

10.11591/ijece.v8i5.pp3620-3626 ◽

2018 ◽

Vol 8 (5) ◽

pp. 3620

Author(s):

Jufriadif Na'am ◽

Julius Santony ◽

Yuhandri Yuhandri ◽

Sumijan Sumijan ◽

Gunadi Widi Nurcahyo

Keyword(s):

Medical Image ◽

Nearest Neighbor ◽

Medical Images ◽

Interpolation Method ◽

Clinical Analysis ◽

X Ray ◽

Chest X Ray ◽

Brain Ct Scan ◽

Image Pixels

Quality of medical image has an important role in constructing right medical diagnosis. This paper recommends a method to improve the quality of medical images by increasing the size of the image pixels. By increasing the size of pixels, the size of the objects contained therein is also greater, making it easier to observe. In this study medical images of Brain CT-Scan, Chest X-Ray and Panoramic X-Ray were processed using Line-Column Interpolation (LCI) Method. The results of the treatment are then compared to Nearest Neighbor Interpolation (NNI), Bilinear Interpolation (BLI) and Bicubic Interpolation (BCI) processing results. The experiment shows that Line-Column Interpolation Method produces a larger image with details of the objects in it are not blurred and has equal visual effects. Thus, this method is expected to be a reference material in enlarging the size of the medical image for ease in clinical analysis.<br /><br />

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Wavelet-NARM Based Sparse Representation for Bio Medical Images

International Journal of Image Graphics and Signal Processing ◽

10.5815/ijigsp.2015.03.06 ◽

2015 ◽

Vol 7 (3) ◽

pp. 38-44

Author(s):

Sushma M ◽

◽

Malaya Kumar Nath ◽

Lokeshwari R ◽

Premalatha T ◽

...

Keyword(s):

Sparse Representation ◽

Medical Images

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Two-Bit Embedding Histogram-Prediction-Error Based Reversible Data Hiding for Medical Images with Smooth Area

Computers ◽

10.3390/computers10110152 ◽

2021 ◽

Vol 10 (11) ◽

pp. 152

Author(s):

Ching-Yu Yang ◽

Ja-Ling Wu

Keyword(s):

Data Hiding ◽

Prediction Error ◽

Reversible Data Hiding ◽

Medical Images ◽

High Capacity ◽

Personal Privacy ◽

Hiding Capacity ◽

X Ray ◽

Magnetic Resonance Imaging Mri ◽

Hidden Data

During medical treatment, personal privacy is involved and must be protected. Healthcare institutions have to keep medical images or health information secret unless they have permission from the data owner to disclose them. Reversible data hiding (RDH) is a technique that embeds metadata into an image and can be recovered without any distortion after the hidden data have been extracted. This work aims to develop a fully reversible two-bit embedding RDH algorithm with a large hiding capacity for medical images. Medical images can be partitioned into regions of interest (ROI) and regions of noninterest (RONI). ROI is informative with semantic meanings essential for clinical applications and diagnosis and cannot tolerate subtle changes. Therefore, we utilize histogram shifting and prediction error to embed metadata into RONI. In addition, our embedding algorithm minimizes the side effect to ROI as much as possible. To verify the effectiveness of the proposed approach, we benchmarked three types of medical images in DICOM format, namely X-ray photography (X-ray), computer tomography (CT), and magnetic resonance imaging (MRI). Experimental results show that most of the hidden data have been embedded in RONI, and the performance achieves high capacity and leaves less visible distortion to ROIs.

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