Abstract
Strip steel surface defect recognition is a pattern recognition problem with wide applications. Previous works on strip surface defect recognition mainly focus on feature selection and dimension reduction. There are also approaches on real-time systems that mainly exploit the autocorrection within some given picture. However, the instances cannot be used in practical applications because of a bad recognition rate and low efficiency. In this paper, we study the intelligent algorithm of strip steel surface defect recognition, where the goal is to improve the accuracy and save running time. This problem is very important in various applications, especially the process testing of steel manufacturing. We propose an approach called the second-order cone programming (SOCP) optimized multiple kernel relevance vector machine (MKRVM), which can recognize strip surface defects much better than other methods. The method includes the model parameter estimation, training, and optimization of the model based on SOCP and the classification test. We compare our approach with existing methods on strip surface defect recognition. The results demonstrate that our proposed approach can improve the recognition accuracy and reduce the time costs of the strip surface defect.
Highlights
There are different types of defects in strip steel production due to various causes
We study the intelligent algorithm of strip steel surface defect recognition, where the goal is to improve the accuracy and save running time
We propose an approach called the second-order cone programming (SOCP) optimized multiple kernel relevance vector machine (MKRVM), which can recognize strip surface defects much better than other methods
Summary
There are different types of defects in strip steel production due to various causes These defects affect the appearances of the products and cause concentrated stress and weak spots. If we want to improve the strip surface quality, detection and classification problems must be solved for the strip surface quality. The Particle Swarm Optimization algorithm is an efficient optimization method, but its complex genetic operations make it difficult to meet the expected recognition speed and accuracy. These algorithms cannot take into account defects recognition
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