Fission gas bubble identification using MATLAB's image processing toolbox

Automated image processing routines have the potential to aid in the fuel performance evaluation process by eliminating bias in human judgment that may vary from person-to-person or sample-to-sample. This study presents several MATLAB based image analysis routines designed for fission gas void ident...

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Bibliographic Details
Published in:Materials characterization 2016-08, Vol.118
Main Author: Collette, R.
Format: Article
Language:English
Subjects:
ALGORITHMS
BUBBLES
CURTAINS
EXTRACTION
FILTRATION
FISSION PRODUCTS
FUEL PLATES
IMAGE PROCESSING
INSTRUMENTATION RELATED TO NUCLEAR SCIENCE AND TECHNOLOGY
IRRADIATION
M CODES
MATERIALS SCIENCE
MICROSTRUCTURE
NOISE
POST-IRRADIATION EXAMINATION
REMOVAL
URANIUM-MOLYBDENUM FUELS
VOIDS
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Summary:Automated image processing routines have the potential to aid in the fuel performance evaluation process by eliminating bias in human judgment that may vary from person-to-person or sample-to-sample. This study presents several MATLAB based image analysis routines designed for fission gas void identification in post-irradiation examination of uranium molybdenum (U–Mo) monolithic-type plate fuels. Frequency domain filtration, enlisted as a pre-processing technique, can eliminate artifacts from the image without compromising the critical features of interest. This process is coupled with a bilateral filter, an edge-preserving noise removal technique aimed at preparing the image for optimal segmentation. Adaptive thresholding proved to be the most consistent gray-level feature segmentation technique for U–Mo fuel microstructures. The Sauvola adaptive threshold technique segments the image based on histogram weighting factors in stable contrast regions and local statistics in variable contrast regions. Once all processing is complete, the algorithm outputs the total fission gas void count, the mean void size, and the average porosity. The final results demonstrate an ability to extract fission gas void morphological data faster, more consistently, and at least as accurately as manual segmentation methods. - Highlights: •Automated image processing can aid in the fuel qualification process. •Routines are developed to characterize fission gas bubbles in irradiated U–Mo fuel. •Frequency domain filtration effectively eliminates FIB curtaining artifacts. •Adaptive thresholding proved to be the most accurate segmentation method. •The techniques established are ready to be applied to large scale data extraction testing.
ISSN:1044-5803
1873-4189
DOI:10.1016/J.MATCHAR.2016.06.010