Jing Yu scite author profile

Abstract-It is well known that unconstrained infinite-horizon optimal control may be used to construct a stabilizing controller for a nonlinear system. In this note, we show that similar stabilization results may be achieved using unconstrained finite horizon optimal control. The key idea is to approximate the tail of the infinite horizon cost-to-go using, as terminal cost, an appropriate control Lyapunov function. Roughly speaking, the terminal control Lyapunov function (CLF) should provide an (incremental) upper bound on the cost. In this fashion, important stability characteristics may be retained without the use of terminal constraints such as those employed by a number of other researchers. The absence of constraints allows a significant speedup in computation. Furthermore, it is shown that in order to guarantee stability, it suffices to satisfy an improvement property, thereby relaxing the requirement that truly optimal trajectories be found. We provide a complete analysis of the stability and region of attraction/operation properties of receding horizon control strategies that utilize finite horizon approximations in the proposed class. It is shown that the guaranteed region of operation contains that of the CLF controller and may be made as large as desired by increasing the optimization horizon (restricted, of course, to the infinite horizon domain). Moreover, it is easily seen that both CLF and infinite-horizon optimal control approaches are limiting cases of our receding horizon strategy.The key results are illustrated using a familiar example, the inverted pendulum, where significant improvements in guaranteed region of operation and cost are noted.Index Terms-Control Lyapunov functions (CLFs), model predictive control, nonlinear control design, optimal control, receding horizon control.

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Choosing the content of textual summaries of large time-series data sets

Yu¹,

Reiter²,

Hunter³

et al. 2006

Nat. Lang. Eng.

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Natural Language Generation (NLG) can be used to generate textual summaries of numeric data sets. In this paper we develop an architecture for generating short (a few sentences) summaries of large (100KB or more) time-series data sets. The architecture integrates pattern recognition, pattern abstraction, selection of the most significant patterns, microplanning (especially aggregation), and realisation. We also describe and evaluate SumTime-Turbine, a prototype system which uses this architecture to generate textualsummaries of sensor data from gas turbines.

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Disturbance observer-based adaptive sliding mode control for near-space vehicles

2015

Nonlinear Dyn

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H∞ control with parametric Lyapunov functions

Sideris

1997

Systems & Control Letters

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Robust adaptive tracking control for nonholonomic mobile manipulator with uncertainties

Peng

Wang

2014

ISA Transactions

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Nonlinear feedback control of a gantry crane

Lewis

Huang

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Receding horizon control of the Caltech ducted fan: a control Lyapunov function approach

Jadbabaie

Yu²,

Hauser³

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Jing Yu

Choosing words in computer-generated weather forecasts

Unconstrained receding-horizon control of nonlinear systems

Choosing the content of textual summaries of large time-series data sets

Disturbance observer-based adaptive sliding mode control for near-space vehicles

H∞ control with parametric Lyapunov functions

Robust adaptive tracking control for nonholonomic mobile manipulator with uncertainties

Nonlinear feedback control of a gantry crane

Receding horizon control of the Caltech ducted fan: a control Lyapunov function approach

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