3D orientation field transform
3D orientation field transform
Vascular structure enhancement is very useful in image processing and computer vision. The enhancement of the presence of the structures like tubular networks in given images can improve image-dependent diagnostics and can also facilitate tasks like segmentation. The two-dimensional (2D) orientation field transform has been proved to be effective at enhancing 2D contours and curves in images by means of top-down processing. It, however, has no counterpart in 3D images due to the extremely complicated orientation in 3D against 2D. Given the rising demand and interest in handling 3D images, we experiment with modularising the concept and generalise the algorithm to 3D curves. In this work, we propose a 3D orientation field transform. It is a vascular structure enhancement algorithm that can cleanly enhance images having very low signal-to-noise ratio, and push the limits of 3D image quality that can be enhanced computationally. This work also utilises the benefits of modularity and offers several combinative options that each yield moderately better enhancement results in different scenarios. In principle, the proposed 3D orientation field transform can naturally tackle any number of dimensions. As a special case, it is also ideal for 2D images, owning a simpler methodology compared to the previous 2D orientation field transform. The concise structure of the proposed 3D orientation field transform also allows it to be mixed with other enhancement algorithms, and as a preliminary filter to other tasks like segmentation and detection. The effectiveness of the proposed method is demonstrated with synthetic 3D images and real-world transmission electron microscopy tomograms ranging from 2D curve enhancement to, the more important and interesting, 3D ones. Extensive experiments and comparisons with existing related methods also demonstrate the excellent performance of the proposed 3D orientation field transform.
3D, Curves, Image denoising, Image segmentation, Orientation field transform, Vascular enhancement
Yeung, Wai-Tsun
ddb2048a-9aaf-40b0-84bd-12155c1c24c5
Cai, Xiaohao
de483445-45e9-4b21-a4e8-b0427fc72cee
Liang, Zizhen
fe6700b1-6674-42b3-a14c-d582d76b94bb
Kang, Byung-Ho
edffb988-b62b-4b47-99b7-523ff5630895
March 2024
Yeung, Wai-Tsun
ddb2048a-9aaf-40b0-84bd-12155c1c24c5
Cai, Xiaohao
de483445-45e9-4b21-a4e8-b0427fc72cee
Liang, Zizhen
fe6700b1-6674-42b3-a14c-d582d76b94bb
Kang, Byung-Ho
edffb988-b62b-4b47-99b7-523ff5630895
Yeung, Wai-Tsun, Cai, Xiaohao, Liang, Zizhen and Kang, Byung-Ho
(2024)
3D orientation field transform.
Pattern Analysis and Applications, 27 (1), [6].
(doi:10.1007/s10044-024-01212-z).
Abstract
Vascular structure enhancement is very useful in image processing and computer vision. The enhancement of the presence of the structures like tubular networks in given images can improve image-dependent diagnostics and can also facilitate tasks like segmentation. The two-dimensional (2D) orientation field transform has been proved to be effective at enhancing 2D contours and curves in images by means of top-down processing. It, however, has no counterpart in 3D images due to the extremely complicated orientation in 3D against 2D. Given the rising demand and interest in handling 3D images, we experiment with modularising the concept and generalise the algorithm to 3D curves. In this work, we propose a 3D orientation field transform. It is a vascular structure enhancement algorithm that can cleanly enhance images having very low signal-to-noise ratio, and push the limits of 3D image quality that can be enhanced computationally. This work also utilises the benefits of modularity and offers several combinative options that each yield moderately better enhancement results in different scenarios. In principle, the proposed 3D orientation field transform can naturally tackle any number of dimensions. As a special case, it is also ideal for 2D images, owning a simpler methodology compared to the previous 2D orientation field transform. The concise structure of the proposed 3D orientation field transform also allows it to be mixed with other enhancement algorithms, and as a preliminary filter to other tasks like segmentation and detection. The effectiveness of the proposed method is demonstrated with synthetic 3D images and real-world transmission electron microscopy tomograms ranging from 2D curve enhancement to, the more important and interesting, 3D ones. Extensive experiments and comparisons with existing related methods also demonstrate the excellent performance of the proposed 3D orientation field transform.
Text
s10044-024-01212-z
- Version of Record
More information
Accepted/In Press date: 31 December 2023
e-pub ahead of print date: 28 February 2024
Published date: March 2024
Keywords:
3D, Curves, Image denoising, Image segmentation, Orientation field transform, Vascular enhancement
Identifiers
Local EPrints ID: 491807
URI: http://eprints.soton.ac.uk/id/eprint/491807
ISSN: 1433-7541
PURE UUID: fb7af331-7ca2-4e10-91b4-0055440bbff8
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Date deposited: 04 Jul 2024 16:47
Last modified: 12 Jul 2024 02:06
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Contributors
Author:
Wai-Tsun Yeung
Author:
Xiaohao Cai
Author:
Zizhen Liang
Author:
Byung-Ho Kang
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