Predictive control for networked high-order fully actuated systems subject to communication delays and external disturbances

This research is concerned with an output tracking problem for networked high-order fully actuated (NHOFA) systems subject to communication delays and external disturbances, where communication delays occur in sensor to network node and network node to actuator. A HOFA system model, as a novel system representation, is applied to establish the dynamics of networked control systems (NCSs). Accordingly, a disturbance observer based HOFA predictive control approach is proposed to address this problem. In the proposed approach, a disturbance observer is utilized to cope with the external disturbances, and then a local HOFA feedback with disturbance compensation is designed to adjust the closed-loop system performances. Further, a Diophantine Equation is applied to establish an incremental HOFA (IHOFA) prediction model to substitute a reduced-order prediction model, such that multi-step ahead predictions are derived to minimize a cost function involving the optimization of tracking performance and the compensation of network-induced communication delays. A necessary and sufficient criterion is given to discuss the stability and tracking performance of closed-loop NHOFA systems, it is simple to use in system analysis and extend in practice. The availability of the proposed approach is demonstrated via simulated and experimental results for tracking control of air-bearing spacecraft (ABS) simulator.

Automated summary

This research focuses on addressing the output tracking problem for networked high-order fully actuated systems under communication delays and external disturbances. A novel HOFA system model is applied to establish the dynamics of networked control systems, and a disturbance observer based HOFA predictive control approach is proposed. A Diophantine Equation is applied to establish an incremental HOFA prediction model, and a necessary and sufficient criterion is given to discuss the stability and tracking performance of closed-loop NHOFA systems. The availability of the proposed approach is demonstrated through simulated and experimental results.