Title :
H∞-based LPV model identification from local experiments with a gap metric-based operating point selection
Author :
Vizer, Daniel ; Mercere, G.
Author_Institution :
Dept. of Control Eng. & Inf., Control & Robot. Group, Univ. of Technol. & Econ. of Budapest, Budapest, Hungary
Abstract :
When the identification of linear parameter-varying (LPV) models from local experiments is considered, the question of the necessary number of local operating points usually arises. In this work, this challenging problem is tackled by proposing a method which is able to optimize on-line the number of local operating points required by the local technique used to identify the LPV model parameters. This goal is achieved by developing an algorithm which takes the advantage of the gap metric-based non-linearity measure [1]. The proposed method is then embedded to an H∞-based technique and tested by identifying a fully-parameterized and a physically-structured LPV model written as a linear fractional representation (LFR).
Keywords :
H∞ control; linear systems; parameter estimation; H∞-based LPV model identification; LFR; LPV model parameter identification; fully-parameterized LPV model; gap metric-based nonlinearity measure; gap metric-based operating point selection; linear fractional representation; linear parameter-varying models; local operating points; physically-structured LPV model; Interpolation; Mathematical model; Measurement; Optimization; State-space methods; Vectors; Vehicles;
Conference_Titel :
Control Conference (ECC), 2014 European
Conference_Location :
Strasbourg
Print_ISBN :
978-3-9524269-1-3
DOI :
10.1109/ECC.2014.6862462
