Pore Segmentation in Industrial Radiographic Images Using Adaptive Thresholding and Morphological Analysis

Dayana Palma Ramírez; Bárbara Dora  Ross Veitía; Pablo  Font Ariosa; Alejandro  Espinel Hernández; Ramón  Arias Gilart; Ángel Sánchez Roca; Hipólito Domingo  Carvajal Fals

doi:10.46420/TAES.e230008

Autores/as

Dayana Palma Ramírez Centro Nacional de Electromagnetismo Aplicado. Universidad de Oriente Autor/a
Bárbara Dora Ross Veitía CNEA Autor/a https://orcid.org/0000-0002-6485-9231
Pablo Font Ariosa Defectoscopy and Welding Technical Services Company Autor/a https://orcid.org/0009-0005-8094-9201
Alejandro Espinel Hernández CNEA Autor/a https://orcid.org/0000-0003-4192-363X
Ramón Arias Gilart CNEA Autor/a https://orcid.org/0000-0003-2050-9712
Ángel Sánchez Roca University of Oriente Autor/a https://orcid.org/0000-0002-1384-0493
Hipólito Domingo Carvajal Fals Federal Technological University of Paraná Autor/a https://orcid.org/0000-0001-5061-8763

DOI:

https://doi.org/10.46420/TAES.e230008

Palabras clave:

radiographic image segmentation, adaptive thresholding, pore detection, industrial radiography, morphological analysis

Resumen

This study presents an innovative approach to segmenting pores in low-quality industrial radiographic images using advanced image processing and adaptive segmentation techniques. The process involves several steps, including conversion of the image to grayscale to simplify analysis. Gaussian and median filters are then applied to improve image quality and enable more accurate segmentation. The methodology is based on adaptive thresholding and edge detection using the Canny algorithm, achieving accurate pore area measurements, even for those unnoticed by experts, with measurement errors of less than 0.1 mm². This high accuracy supports the method's effectiveness in pore detection and measurement. The resulting tool has great potential in industrial radiography applications, from quality control to defect analysis. While recognizing the need for continued research to improve contrast and illumination, as well as to address potential sources of error, these refinements promise to further elevate an already reliable and accurate method with a wide reach in the industry.

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Pore Segmentation in Industrial Radiographic Images Using Adaptive Thresholding and Morphological Analysis

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