Title :
A Sparse Robust Model for a Linz–Donawitz Steel Converter
Author :
Valyon, Jòzsef ; Horvàth, Gàbor
Author_Institution :
Dept. of Meas. & Inf. Syst., Budapest Univ. of Technol. & Econ., Budapest, Hungary
Abstract :
Steelmaking with a Linz-Donawitz converter is a complex industrial process, where, due to the lack of exact mathematical (physical-chemical) models, the construction of a black-box model based on noisy and imprecise data is required. To construct a good model, a large number of such input-output samples should be used, which calls for a method that is sparse, in the sense that the resulting model complexity is independent of the sample number, and robust to reduce the effects of noise. Lately, support vector machines (SVMs) have successfully been applied to a number of such problems. The main problem with traditional SVM is its high algorithmic complexity, which makes it infeasible for really large databases. The least-squares SVM (LS-SVM) solves this problem, but the resulting model is not sparse. Our solution uses a sparse and robust extension of LS-SVM that leads to good results compared to other methods (such as MLPs) applied to the same problem.
Keywords :
computational complexity; least squares approximations; production engineering computing; steel industry; support vector machines; LS-SVM; Linz-Donawitz steel converter; algorithmic complexity; black-box model; complex industrial process; large databases; least-squares SVM; model complexity; noise reduction; sparse robust model; steelmaking; support vector machines; $hbox{LS}^{2} - hbox{SVM}$ ; Basic oxygen furnace (BOF); Linz–Donawitz (LD) converter; basic oxygen steelmaking (BOS); black-box modeling; least-squares support vector machine (LS-SVM); steel industry;
Journal_Title :
Instrumentation and Measurement, IEEE Transactions on
DOI :
10.1109/TIM.2009.2015638
