Abstract
Abstract This paper describes feature-based techniques for wood knot classification. For automated classification of macroscopic wood knot images, models were established using artificial neural networks with texture and local feature descriptors, and the performances of feature extraction algorithms were compared. Classification models trained with texture descriptors, gray-level co-occurrence matrix and local binary pattern, achieved better performance than those trained with local feature descriptors, scale-invariant feature transform and dense scale-invariant feature transform. Hence, it was confirmed that wood knot classification was more appropriate for texture classification rather than an approach based on morphological classification. The gray-level co-occurrence matrix produced the highest F1 score despite representing images with relatively low-dimensional feature vectors. The scale-invariant feature transform algorithm could not detect a sufficient number of features from the knot images; hence, the histogram of oriented gradients and dense scale-invariant feature transform algorithms that describe the entire image were better for wood knot classification. The artificial neural network model provided better classification performance than the support vector machine and k-nearest neighbor models, which suggests the suitability of the nonlinear classification model for wood knot classification.
Highlights
Accurate grading of lumber is a very important process for production quality control, and for securing structural stability and enhancing consumer confidence (Feio and Machado 2015)
In computer vision-based wood identification, texture features are mainly applied to macroscale images such as macroscopic images, stereograms, and computed tomography images, whereas local features are applied to microscale images such as micrographs
For the automated classification of wood knots, classification models trained with descriptors of texture and local features extracted from macroscopic images of wood knots were constructed
Summary
Accurate grading of lumber is a very important process for production quality control, and for securing structural stability and enhancing consumer confidence (Feio and Machado 2015). Lumber grading is mostly performed manually, and visual inspection by humans is subjective and time-consuming. It has a remarkable disadvantage of high accuracy over 70–80% not being guaranteed due to the fatigue of the inspector caused by repetitive work (Gu et al 2008; Lampinen et al 1998). Gray-level co-occurrence matrix (GLCM)-based Haralick texture features (hereinafter referred to as GLCM features) was preferred in studies for automated wood defect classification, and promising results were produced from models trained with GLCM features
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