Strict lyapunov functions for the super-twisting algorithm

Jaime A. Moreno; Marisol Osorio

doi:10.1109/TAC.2012.2186179

Strict lyapunov functions for the super-twisting algorithm

Jaime A. Moreno
, Marisol Osorio

Research output: Contribution to scientific journal › Article in an indexed scientific journal › peer-review

1338 Scopus citations

Abstract

A method to construct a family of strict Lyapunov functions, i.e., with negative definite derivative, for the super-twisting algorithm, without or with perturbations, is provided. This second order sliding modes algorithm is widely used to design controllers, observers and exact differentiators. The proposed Lyapunov functions ascertain finite time convergence, provide an estimate of the convergence time, and ensure the robustness of the finite-time or ultimate boundedness for a class of perturbations wider than the classical ones for this algorithm. Since the Lyapunov functions and their derivatives are quadratic forms, the operation with them is as simple as for linear time invariant systems.

Original language	English
Article number	6144710
Pages (from-to)	1035-1040
Number of pages	6
Journal	IEEE Transactions on Automatic Control
Volume	57
Issue number	4
DOIs	https://doi.org/10.1109/TAC.2012.2186179
State	Published - Apr 2012

Keywords

Discontinuous systems
Lyapunov functions
robust observers
second order sliding modes (SOSM)

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10.1109/TAC.2012.2186179

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AB - A method to construct a family of strict Lyapunov functions, i.e., with negative definite derivative, for the super-twisting algorithm, without or with perturbations, is provided. This second order sliding modes algorithm is widely used to design controllers, observers and exact differentiators. The proposed Lyapunov functions ascertain finite time convergence, provide an estimate of the convergence time, and ensure the robustness of the finite-time or ultimate boundedness for a class of perturbations wider than the classical ones for this algorithm. Since the Lyapunov functions and their derivatives are quadratic forms, the operation with them is as simple as for linear time invariant systems.

KW - Discontinuous systems

KW - Lyapunov functions

KW - robust observers

KW - second order sliding modes (SOSM)

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JO - IEEE Transactions on Automatic Control

JF - IEEE Transactions on Automatic Control

IS - 4

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Strict lyapunov functions for the super-twisting algorithm

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Keywords

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