Design and Development of Medical Image Processing Experiment System Based on IDL Language

This paper uses Interactive Data Language (IDL) as a development language to design and implement a lung tumor image processing system with a Client/Server (C/S) structure. During the development process, various business requirements related to the system have been analyzed and the system structure...

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Vydáno v:Bioautomation Ročník 23; číslo 4; s. 461 - 468
Hlavní autor: Xie, Wei
Médium: Journal Article
Jazyk:angličtina
Vydáno: Sophia Bulgarska Akademiya na Naukite / Bulgarian Academy of Sciences 01.12.2019
Bulgarian Academy of Sciences
Témata:
Algorithms
idl language
image processing
Language
Lung cancer
Magnetic resonance imaging
Medical diagnosis
medical image
Medical imaging
Methods
modular programming
Noise
Physicians
Software
Tumors
Visualization
ISSN:1314-1902, 1314-2321
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Shrnutí:This paper uses Interactive Data Language (IDL) as a development language to design and implement a lung tumor image processing system with a Client/Server (C/S) structure. During the development process, various business requirements related to the system have been analyzed and the system structure together with detailed business process were designed as a whole. In addition, we also established a database of patients’ lung tumor images to efficiently store and query Computed Tomography (CT) images of lung tumors at various stages of the patient and the images generated during the processing of the system. Finally, the paper elaborated the implementation of the IDL-based lung tumor image processing system, and conducted a performance test and experimental analysis of the system. The system consists of five functional modules: image preprocessing, image segmentation, image reconstruction, image measurement, and image management. This system can automatically calculate quantitative indicators in the delineated area. These features can be used for further tumor differentiation tests, tumor characterization, treatment monitoring, and prognosis assessment. The experimental results show that the system is effective, and also processing speed meets the real-time requirements, and has wide applicability, friendly human-computer interaction, convenient extensibility, good portability, and so on.
Bibliografie:ObjectType-Article-1
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content type line 14
ISSN:1314-1902
1314-2321
DOI:10.7546/ijba.2019.23.4.000623