The manipulaiton of spin echoes in NMR imaging

Williams, Steven Charles Rees

January 1989

No description available.

621.3994

Image enhancement

Side scan sonar image formation, restoration and modelling

Beattie, Robert Scott

January 1996

No description available.

621.3895

Image enhancement algorithms

The adaptive LMS alogrithm in image processing

Hadhoud, M. M.

January 1987

No description available.

621.3994

Digital image enhancement

Spatially localised NMR parameter measurement

Bowtell, R. W.

January 1988

No description available.

539.7

NMR image enhancement

Image Enhancement with Matlab Algorithms

Calderón González, Julian, Carmona Salazar, Òscar Daniel

January 2015

No description available.

Image Enhancement

MATLAB

Effect of JPEG2000 compression on landmark identification of lateral cephalometric digital radiographs a thesis /

Abdelkarim, Ahmad Ali.

January 2008

Thesis (M.S.) --University of Texas Graduate School of Biomedical Sciences at San Antonio, 2008. / Vita. Includes bibliographical references.

Phase extension methods

Sivia, Devinderjit Singh

January 1987

No description available.

520

Radio astronomy/image enhancement

Learning image enhancement and object localization using evolutionary algorithms

Shahbazpanahi, Shaho

01 March 2014

Imaging and image processing have been used in variety of applications, such as medical, astronomy, forensic, and industry. Numerous techniques have been proposed to solve speci c problems faced in particular applications which are comprised of a series of processes such as, image enhancement, ltering, segmentation, representation, and recognition. However, there is no a universal algorithm which can be applied to variant image modalities with corresponding applications. With the aim of learning image processing tasks, as supervised learning techniques, we can develop e ective algorithms which are image and task oriented. Learning image processing comprises two main phases, namely: training and testing phases. During training phase, the algorithm has the capability of discovering and adjusting an optimum transformation function or optimal mathematical morphology chain by utilizing a user-prepared ground-truth (gold) sample. Later on, in testing phase, the obtained transform function of morphological chain is applied to untrained test images. The current thesis has three main parts as follows. In the rst part, genetic programming (GP) is employed to obtain an optimum transformation function. The GP utilizes one user-prepared gold sample to learn from. The magni cent feature of this method is that it does not require a prior knowledge or large training set to learn from. The performance of the proposed approach has been examined on 147 X-ray lung images. The results for image thresholding (i.e., Otsu's method) after applying optimal transformation are promising. In the second part, an optimum mathematical morphology (MM) chain is obtained by applying GP to localize the object of interest in a binary image. Morphology operations use 27 regular structuring elements along with commonly used morphological operations (i.e., erosion, dilation, opening, and closing) to build an optimal MM chain. The obtained chains are tested against challenging test cases, such as, object translation, scaling, and rotation. In the third part, a hybrid genetic programming - di erential evolutionary (GP-DE) algorithm is proposed to optimize not only the morphology chain but also the utilized structuring elements. GP as an outer layer optimizer is responsible to optimize the morphology chain while the di erential evolutionary (DE) as an inner layer optimizer optimizes the structure elements. Similarly in the testing phase, the obtained morphology chain is applied on test images. In term of utilized test images, the two test cases have been employed : synthesis and music note images. The results indicate that the proposed method is able to locate the object of interest. For the music note images, the proposed approach is able to extract the head notes, sta s, and vertical lines correctly. The training phase is iii time consuming, but it is acceptable; because one time training is required to obtain an optimal chain for a speci c image processing task.

Hybrid GP-DE

Learning image enhancement

Edge detection and knowledge based segmentation of medical radiographs

Riste-Smith, Robert

January 1990

No description available.

621.3994

X-ray image enhancement

A study of image analysis tools for digital mammography

Che, Ferdinand Ndifor

January 1997

No description available.

621.3994