For linear control systems, we add a Luenberger observer to extend the state-feedback hybrid loop designs of our previous work to the output feedback case. This defines an output feedback controller. The hybrid loop consists of a continuous-time dynamics when the estimate of the state leads to a nonincrease of a suitable Lyapunov-like function and in a jump equation when this condition is not satisfied. The jump equation is defined by means of a static state-feedback law from the observed state. Four techniques based on different reset maps and flow and jump sets are proposed, all of them exploiting a suitable dwell-time logic. For the proposed designs, we prove the global exponential stability of the origin. The effectiveness of the proposed solutions is illustrated by simulation examples where we show suitable reduction of the output overshoot. Copyright © 2012 John Wiley & Sons, Ltd.
Using Luenberger Observers and Dwell-time Logic for Feedback Hybrid Loops in Continuous-time Control Systems
Zaccarian, Luca
2013-01-01
Abstract
For linear control systems, we add a Luenberger observer to extend the state-feedback hybrid loop designs of our previous work to the output feedback case. This defines an output feedback controller. The hybrid loop consists of a continuous-time dynamics when the estimate of the state leads to a nonincrease of a suitable Lyapunov-like function and in a jump equation when this condition is not satisfied. The jump equation is defined by means of a static state-feedback law from the observed state. Four techniques based on different reset maps and flow and jump sets are proposed, all of them exploiting a suitable dwell-time logic. For the proposed designs, we prove the global exponential stability of the origin. The effectiveness of the proposed solutions is illustrated by simulation examples where we show suitable reduction of the output overshoot. Copyright © 2012 John Wiley & Sons, Ltd.I documenti in IRIS sono protetti da copyright e tutti i diritti sono riservati, salvo diversa indicazione