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Modeling the Temperature of Hot Rolled Steel Plate with Semi-supervised Learning Methods

  • Henna Tiensuu
  • Ilmari Juutilainen
  • Juha Röning
Part of the Lecture Notes in Computer Science book series (LNCS, volume 6926)

Abstract

The semi-supervised learning methods utilize both the labeled and unlabeled data to produce better learners than the usual methods using only the labeled data. In this study, semi-supervised learning is applied to the modeling of the rolling temperature of steel plate. Measurement of the rolling temperature in the extreme conditions of rolling mill is difficult and thus there is a large amount of missing response measurements. Previous research mainly focuses on semi-supervised classification. Application of semi-supervised learning to regression problems is largely understudied. Co-training is a semi-supervised method, which is promising in the semi-supervised regression setting. In this paper, we used COREG algorithm [10] to a data set collected from steel plate rolling. Our results show that COREG can effectively exploit unlabeled data and improves the prediction accuracy. The achieved prediction accuracy 16°C is a major improvement in comparison to the earlier approach in which temperature is predicted using physical-mathematical models. In addition, features that describe the rolling process and are applicable to input variables of learning methods are presented. The results can be utilized to develop statistical models for temperature prediction for other rolling processes as well.

Keywords

semi-supervised learning methods COREG-algorithm hot plate rolling process rolling temperature model 

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Copyright information

© Springer-Verlag Berlin Heidelberg 2011

Authors and Affiliations

  • Henna Tiensuu
    • 1
  • Ilmari Juutilainen
    • 1
  • Juha Röning
    • 1
  1. 1.Computer Science and Engineering LaboratoryUniversity of OuluOuluFinland

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