Hybrid Prediction Control for self-adaptive fluid-based shock-absorbers

• Published in: Journal of sound and vibration Vol. 449; pp. 427 - 446
• Main Authors: Faraj, Rami, Graczykowski, Cezary
• Format: Journal Article
• Language: English
• Published: Amsterdam Elsevier Ltd 09.06.2019; Elsevier Science Ltd
• Subjects: Adaptive control; Adaptive Impact Absorption; Control systems; Excitation; Feedback control; Feedback control systems; Hybrid Prediction Control; Impact loads; kinematic feedback control; Kinematics; Optimal control; Parameter identification; Robustness (mathematics); self-adaptive system; Shock absorbers; Stability; unknown impact mitigation; self-adaptive system; Adaptive Impact Absorption; Hybrid Prediction Control; unknown impact mitigation; kinematic feedback control
• ISSN: 0022-460X; 1095-8568
• DOI: 10.1016/j.jsv.2019.02.022

The paper covers detailed discussion on novel control system developed for adaptive fluid-based shock-absorbers serving for mitigation of unknown impact excitations. In order to provide complete independence of the control system from the loading conditions, the Hybrid Prediction Control (HPC) was elaborated. The proposed method is an extension of previously introduced kinematic feedback control which ensures optimal path finding, tracking and path update in case of high disturbance or sudden change of loading conditions. Implementation of the presented control system allows to obtain self-adaptive fluid-based absorbers providing robust impact mitigation. In contrast to previously developed methods of Adaptive Impact Absorption, the proposed control strategy does not require prior knowledge of impact excitation or its preliminary identification. The independence of applied control system from parameters of impact loading results in the capability of automatic path correction in the case of disturbance occurrence and re-adaptation to a number of subsequent impacts. The successful operation of the self-adaptive system is investigated with the use of numerical examples involving double-chamber pneumatic shock-absorber equipped with controllable valve. Efficiency of the HPC is proved by comparison with passive absorber as well as device equipped with adaptive and optimal control modules. •Novel Hybrid Prediction Control (HPC) for fluid-based shock-absorbers is proposed.•Control Mode Prediction ensures self-adaptation to changing loading conditions.•Inverse Dynamics Prediction provides optimal control of generated force.•The HPC does not require impact identification.•High robustness of the HPC is proved on various numerical examples.