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Predictor-Feedback Prescribed-Time Stabilization of LTI Systems With Input Delay

Nicolás Espitia, Wilfrid Perruquetti

2021IEEE Transactions on Automatic Control57 citationsDOIOpen Access PDF

Abstract

This article first deals with the problem of prescribed-time stability of linear systems without delay. The analysis and design involve the <i>Bell polynomials</i>, <i>the generalized Laguerre polynomials</i>, <i>the Lah numbers</i>, and a suitable <i>polynomial-based Vandermonde matrix</i>. The results can be used to design a new controller&#x2014;with time-varying gains&#x2014;ensuring prescribed-time stabilization of controllable linear time-invariant (LTI) systems. The approach leads to similar results compared to Holloway <i>et al.</i> 2019, but offers an alternative and compact control design (especially for the choice of the time-varying gains). Based on the preliminary results for the delay-free case, we then study controllable LTI systems with single input and subject to a constant input delay. We design a predictor feedback with time-varying gains. To achieve this, we model the input delay as a transport partial differential equation (PDE) and build on the cascade PDE&#x2013;ordinary differential equation setting (inspired by Krstic 2009) so as the design of the prescribed-time predictor feedback is carried out based on the backstepping approach, which makes use of <i>time-varying kernels</i>. We guarantee the bounded invertibility of the backstepping transformation, and we prove that the closed-loop solution converges to the equilibrium in a prescribed time. A simulation example illustrates the results.

Topics & Concepts

BacksteppingControl theory (sociology)MathematicsLTI system theoryController (irrigation)Delay differential equationSmith predictorApplied mathematicsComputer scienceLinear systemDifferential equationPID controllerControl (management)Adaptive controlControl engineeringMathematical analysisBiologyAgronomyArtificial intelligenceEngineeringTemperature controlStability and Control of Uncertain SystemsStability and Controllability of Differential EquationsNumerical methods for differential equations
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