Design and experimental validation of an adaptive fast-finite-time observer on uncertain electro-hydraulic systems
This paper presents the design of an adaptive fast-finite-time extended state observer for electro-hydraulic actuator systems. First, the system model is divided into three parts, and fast-finite-time state observers are designed independently for each part. This guarantees the fast-finite-time unif...
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| Published in | Control engineering practice Vol. 131; p. 105391 |
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| Main Authors | , , , , |
| Format | Journal Article |
| Language | English |
| Published |
Elsevier Ltd
01.02.2023
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| Subjects | |
| Online Access | Get full text |
| ISSN | 0967-0661 1873-6939 |
| DOI | 10.1016/j.conengprac.2022.105391 |
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| Abstract | This paper presents the design of an adaptive fast-finite-time extended state observer for electro-hydraulic actuator systems. First, the system model is divided into three parts, and fast-finite-time state observers are designed independently for each part. This guarantees the fast-finite-time uniform ultimate boundedness of the estimation errors. Then, based on the designed state observers and without neither any knowledge about the upper bounds of the uncertainties nor their derivative, supplementary observers are presented to estimate the unknown terms. Rigorous analyses of the proposed strategy are provided through the Lyapunov approach. The suggested adaptive framework can improve the convergence rate for zones both far from the equilibrium points and around them. The adaptive gains are computed based on the straightforward evaluation of the absolute value of the observation errors, thus their values are valid in real life applications, achieving finite-time estimate of both the full state variables as well as uncertainties. Comparative simulations are presented to analyze the effectiveness of the proposed observers with and without unknown measurement noise. Finally, the effectiveness of the proposed approach in real-life conditions is demonstrated through experimental studies.
•An adaptive fast-finite-time extended state observer (A-FFT-ESO) is designed.•The proposed A-FFT-ESO is possible to estimate without neither any knowledge about the upper bound of uncertainties nor its derivative, achieving convergence of the observation error to a neighborhood of zero.•Adaptive gains are computed based on straightforward evaluation of the absolute value of the observation errors.•The suggested adaptive framework can improve the convergence rate for zones both far from the equilibrium points and around them. |
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| AbstractList | This paper presents the design of an adaptive fast-finite-time extended state observer for electro-hydraulic actuator systems. First, the system model is divided into three parts, and fast-finite-time state observers are designed independently for each part. This guarantees the fast-finite-time uniform ultimate boundedness of the estimation errors. Then, based on the designed state observers and without neither any knowledge about the upper bounds of the uncertainties nor their derivative, supplementary observers are presented to estimate the unknown terms. Rigorous analyses of the proposed strategy are provided through the Lyapunov approach. The suggested adaptive framework can improve the convergence rate for zones both far from the equilibrium points and around them. The adaptive gains are computed based on the straightforward evaluation of the absolute value of the observation errors, thus their values are valid in real life applications, achieving finite-time estimate of both the full state variables as well as uncertainties. Comparative simulations are presented to analyze the effectiveness of the proposed observers with and without unknown measurement noise. Finally, the effectiveness of the proposed approach in real-life conditions is demonstrated through experimental studies.
•An adaptive fast-finite-time extended state observer (A-FFT-ESO) is designed.•The proposed A-FFT-ESO is possible to estimate without neither any knowledge about the upper bound of uncertainties nor its derivative, achieving convergence of the observation error to a neighborhood of zero.•Adaptive gains are computed based on straightforward evaluation of the absolute value of the observation errors.•The suggested adaptive framework can improve the convergence rate for zones both far from the equilibrium points and around them. |
| ArticleNumber | 105391 |
| Author | Razmjooei, Hamid Terzo, Mario Palli, Gianluca Strano, Salvatore Abdi, Elahe |
| Author_xml | – sequence: 1 givenname: Hamid orcidid: 0000-0002-6894-2446 surname: Razmjooei fullname: Razmjooei, Hamid email: hamid.razmjooei@unibo.it organization: Department of Electrical, Electronic, and Information Engineering, University of Bologna, Bologna, Italy – sequence: 2 givenname: Gianluca surname: Palli fullname: Palli, Gianluca email: gianluca.palli@unibo.it organization: Department of Electrical, Electronic, and Information Engineering, University of Bologna, Bologna, Italy – sequence: 3 givenname: Elahe surname: Abdi fullname: Abdi, Elahe email: elahe.abdi@monash.edu organization: Department of Mechanical and Aerospace Engineering, Monash University, Melbourne, Australia – sequence: 4 givenname: Mario surname: Terzo fullname: Terzo, Mario email: mario.terzo@unina.it organization: Department of Industrial Engineering, University of Naples Federico II, Naples, Italy – sequence: 5 givenname: Salvatore surname: Strano fullname: Strano, Salvatore email: salvatore.strano@unina.it organization: Department of Industrial Engineering, University of Naples Federico II, Naples, Italy |
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| Keywords | Nonlinear observer Adaptive fast-finite-time extended state observer Electro-hydraulic actuator systems Uniform ultimate boundedness |
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| SubjectTerms | Adaptive fast-finite-time extended state observer Electro-hydraulic actuator systems Nonlinear observer Uniform ultimate boundedness |
| Title | Design and experimental validation of an adaptive fast-finite-time observer on uncertain electro-hydraulic systems |
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