Application of texture analysis to study the relationship between surface microrelief and laser speckles
DOI:
https://doi.org/10.17721/1812-5409.2024/2.16Keywords:
laser speckles, microrelief, texture analysis, correlation analysis, fractal dimension, anisotropy, entropy, materials scienceAbstract
The aim of the study was to establish a quantitative relationship between the structural properties of metal surfaces and the properties of laser speckle patterns that arise from the reflection of laser radiation on such surfaces. A texture analysis of the surfaces of seven different metal samples with different microreliefs was carried out. Two types of images were obtained for each sample: a surface micrograph taken with a microscope and a laser speckle pattern. To quantify the textures, the following parameters were calculated: fractal dimension, anisotropy, contrast, correlation, entropy, second angular momentum and energy. To determine quantitative dependencies between the texture parameters of micrographs and speckle images, pairwise regression and correlation analysis was performed. The study found a significant correlation between structural parameters of photomicrographs and speckle patterns such as fractal dimension, anisotropy and entropy. These results open up new possibilities for non-destructive quality control of materials. In addition, analyzing speckle patterns can predict material properties such as strength, corrosion resistance and wear resistance. This opens up prospects for the development of new materials with specific properties and the optimization of technological processes.
Pages of the article in the issue: 100 - 103
Language of the article: English
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