Surface Defect Classification for Hot-Rolled Steel Strips by Selectively Dominant Local Binary Patterns

Qiwu Luo, Xiaoxin Fang, Yichuang Sun, Li Liu, Jiaqiu Ai, Chunhua Yang, Oluyomi Simpson

Research output: Contribution to journalArticlepeer-review

13 Citations (Scopus)
75 Downloads (Pure)

Abstract

Developments in defect descriptors and computer vision-based algorithms for automatic optical inspection (AOI) allows for further development in image-based measurements. Defect classification is a vital part of an optical-imaging-based surface quality measuring instrument. The high-speed production rhythm of hot continuous rolling requires an ultra-rapid response to every component as well as algorithms in AOI instrument. In this paper, a simple, fast, yet robust texture descriptor, namely selectively dominant local binary patterns (SDLBPs), is proposed for defect classification. First, an intelligent searching algorithm with a quantitative thresholding mechanism is built to excavate the dominant non-uniform patterns (DNUPs). Second, two convertible schemes of pattern code mapping are developed for binary encoding of all uniform patterns and DNUPs. Third, feature extraction is carried out under SDLBP framework. Finally, an adaptive region weighting method is built for further strengthening the original nearest neighbor classifier in the feature matching stage. The extensive experiments carried out on an open texture database (Outex) and an actual surface defect database (Dragon) indicates that our proposed SDLBP yields promising performance on both classification accuracy and time efficiency
Original languageEnglish
Pages (from-to)23488 - 23499
Number of pages11
JournalIEEE Access
Volume7
DOIs
Publication statusPublished - 11 Feb 2019

Keywords

  • Automatic optical inspection (AOI) image classification local binary patterns (LBP) steel industry
  • surface texture

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