Parametric identification of a servo-hydraulic actuator for real-time hybrid simulation

In a typical Real-time Hybrid Simulation (RTHS) setup, servo-hydraulic actuators serve as interfaces between the computational and physical substructures. Time delay introduced by actuator dynamics and complex interaction between the actuators and the specimen has detrimental effects on the stabilit...

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Bibliographic Details
Published in:Mechanical systems and signal processing 2014-10, Vol.48 (1-2), p.260-273
Main Authors: Qian, Yili, Ou, Ge, Maghareh, Amin, Dyke, Shirley J.
Format: Article
Language:English
Subjects:
Actuators
Computation
Computer simulation
Dynamics
Genetic algorithms
Mathematical models
Real time
Real-time hybrid simulation
Servo-hydraulic actuators
Stability
System identification
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Summary:In a typical Real-time Hybrid Simulation (RTHS) setup, servo-hydraulic actuators serve as interfaces between the computational and physical substructures. Time delay introduced by actuator dynamics and complex interaction between the actuators and the specimen has detrimental effects on the stability and accuracy of RTHS. Therefore, a good understanding of servo-hydraulic actuator dynamics is a prerequisite for controller design and computational simulation of RTHS. This paper presents an easy-to-use parametric identification procedure for RTHS users to obtain re-useable actuator parameters for a range of payloads. The critical parameters in a linearized servo-hydraulic actuator model are optimally obtained from genetic algorithms (GA) based on experimental data collected from various specimen mass/stiffness combinations loaded to the target actuator. The actuator parameters demonstrate convincing convergence trend in GA. A key feature of this parametric modeling procedure is its re-usability under different testing scenarios, including different specimen mechanical properties and actuator inner-loop control gains. The models match well with experimental results. The benefit of the proposed parametric identification procedure has been demonstrated by (1) designing an H∞ controller with the identified system parameters that significantly improves RTHS performance; and (2) establishing an analysis and computational simulation of a servo-hydraulic system that help researchers interpret system instability and improve design of experiments. •A procedure to conduct parametric identification for a servo-hydraulic actuator is proposed.•Physical system parameters are estimated using Genetic Algorithms.•Resulting parameters are applicable to a range of payload conditions and control gains.•Identified parameters are used to help controller design and stability analysis.
ISSN:0888-3270
1096-1216
DOI:10.1016/j.ymssp.2014.03.001