Mazen Farhood scite author profile

Summary The paper investigates the robust stability and performance of uncertain linear time‐varying (LTV) systems using an integral quadratic constraint (IQC) based analysis approach. Specifically, previous theoretical work on IQC‐based robustness analysis of linear time‐invariant (LTI) systems is extended to discrete‐time LTV systems. In the case of a general LTV nominal system, the analysis solution is provided in terms of an infinite‐dimensional convex optimization problem. This optimization problem reduces into a finite‐dimensional semidefinite program when the nominal system in question is finite horizon, periodic, or, more generally, eventually periodic. Finally, the results are applied to an unmanned aircraft control system executing an aggressive maneuver, where the developed techniques are used to find the region in which the aircraft is guaranteed to reside at the end of its planned trajectory. Copyright © 2017 John Wiley & Sons, Ltd.

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Distributed control of linear time‐varying systems interconnected over arbitrary graphs

Farhood

Dullerud

2013

Intl J Robust & Nonlinear

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SUMMARYIn this paper, we focus on designing distributed controllers for interconnected systems in situations where the controller sensing and actuation topology is inherited from that of the plant. The distributed systems considered are composed of discrete-time linear time-varying subsystems interconnected over arbitrary graph structures. The main contribution of this paper is to provide results on general graph interconnection structures in which the graphs have potentially an infinite number of vertices. This is accomplished by first extending previous machinery developed for systems with spatial dynamics on the lattice Z n . We derive convex analysis and synthesis conditions for design in this setting. These conditions reduce to finite sequences of LMIs in the case of eventually periodic subsystems interconnected over finite graphs. The paper also provides results on distributed systems with communication latency and gives an illustrative example on the distributed control of hovercrafts along eventually periodic trajectories. The methodology developed here provides a unifying viewpoint for our previous and related work on distributed control.

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LMI tools for eventually periodic systems

Farhood

Dullerud

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Model reduction of periodic systems: a lifting approach

2005

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LMI tools for eventually periodic systems

Farhood

Dullerud

2002

Systems & Control Letters

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Mazen Farhood

IQC‐based robustness analysis of discrete‐time linear time‐varying systems

Distributed control of linear time‐varying systems interconnected over arbitrary graphs

LMI tools for eventually periodic systems

Model reduction of periodic systems: a lifting approach

LMI tools for eventually periodic systems

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