Robust adaptive position control of automotive electronic throttle valve using PID-type sliding mode technique

H. Wang; L. Liu; P. He; M. Yu; M.T. Do; H. Kong; Z. Man

doi:10.1007/s11071-016-2763-8

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Robust adaptive position control of automotive electronic throttle valve using PID-type sliding mode technique

Journal article

Peer reviewed

Robust adaptive position control of automotive electronic throttle valve using PID-type sliding mode technique

H. Wang, L. Liu, P. He, M. Yu, M.T. Do, H. Kong and Z. Man

Nonlinear Dynamics, Vol.85(2), pp.1331-1344

2016

DOI: https://doi.org/10.1007/s11071-016-2763-8

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Abstract

This paper proposes a robust adaptive position control scheme for automotive electronic throttle (ET) valve. Compared with the conventional throttle control systems, in this paper, a robust adaptive sliding mode (RASM) control scheme is developed in order to eliminate the effects of the parameter uncertainties and nonlinearities including friction, return-spring limp-home and gear backlash. It is shown that both the lumped uncertainty bound and the control gains are adaptively estimated by the update laws, such that not only the bound information of the lumped uncertainty and the control gains are no longer required, but also a robust tracking performance can be ensured in the presence of the parametric variations and disturbances. The comparative simulation and experimental studies are demonstrated to verify the excellent transient and steady-state tracking performance of the proposed RASM controller for ET systems.

Details

Title: Robust adaptive position control of automotive electronic throttle valve using PID-type sliding mode technique
Authors/Creators: H. Wang (Author/Creator) - Hefei University of Technology
L. Liu (Author/Creator)
P. He (Author/Creator)
M. Yu (Author/Creator) - Hefei University of Technology
M.T. Do (Author/Creator)
H. Kong (Author/Creator) - Hefei University of Technology
Z. Man (Author/Creator) - Swinburne University of Technology
Publication Details: Nonlinear Dynamics, Vol.85(2), pp.1331-1344
Publisher: Springer
Identifiers: 991005544319207891
Copyright: © Springer Science+Business Media Dordrecht 2016
Murdoch Affiliation: Murdoch University
Language: English
Resource Type: Journal article

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Collaboration types: Domestic collaboration; International collaboration
Citation topics: 4 Electrical Engineering, Electronics & Computer Science; 4.29 Automation & Control Systems; 4.29.104 Adaptive Control
Web Of Science research areas: Engineering, Mechanical; Mechanics
ESI research areas: Engineering