Algebraic solvability tests for linear matrix inequalities

In this paper, a new method for designing controller for linear switching systems with varying delay is presented concerning the Hurwitz-Convex combination. For stability analysis the Lyapunov-Krasovskii function is used. The stability analysis results are given based on the linear matrix inequalities (LMIs), and it is possible to obtain upper delay bound that guarantees the stability of system by solving the linear matrix inequalities. Compared with the other methods, the proposed controller can be used to get a less conservative criterion and ensures the stability of linear switching systems with time-varying delay in which delay has way larger upper bound in comparison with the delay bounds that are considered in other methods. Numerical examples are given to demonstrate the effectiveness of proposed method.

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Feedback Control of Dynamic Artificial Neural Networks Using Linear Matrix Inequalities

2020 59th IEEE Conference on Decision and Control (CDC) ◽

10.1109/cdc42340.2020.9303770 ◽

2020 ◽

Author(s):

Anastasia Nikolakopoulou ◽

Moo Sun Hong ◽

Richard D. Braatz

Keyword(s):

Neural Networks ◽

Artificial Neural Networks ◽

Feedback Control ◽

Linear Matrix Inequalities ◽

Linear Matrix ◽

Matrix Inequalities ◽

Artificial Neural

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Linear matrix inequalities‐based adaptive time‐delayed sliding mode control for ships considering ship–bank interaction effect and shallow water effect

Asian Journal of Control ◽

10.1002/asjc.2572 ◽

2021 ◽

Author(s):

Han Xue

Keyword(s):

Sliding Mode Control ◽

Shallow Water ◽

Linear Matrix Inequalities ◽

Interaction Effect ◽

Sliding Mode ◽

Linear Matrix ◽

Matrix Inequalities ◽

Water Effect ◽

Adaptive Time ◽

Shallow Water Effect

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Discrete-time output feedback sliding-mode control design for uncertain systems using linear matrix inequalities

International Journal of Control ◽

10.1080/00207179.2011.583683 ◽

2011 ◽

Vol 84 (5) ◽

pp. 916-930 ◽

Cited By ~ 9

Author(s):

Srinath Govindaswamy ◽

Sarah K. Spurgeon ◽

Thierry Floquet

Keyword(s):

Sliding Mode Control ◽

Linear Matrix Inequalities ◽

Discrete Time ◽

Output Feedback ◽

Uncertain Systems ◽

Sliding Mode ◽

Control Design ◽

Linear Matrix ◽

Matrix Inequalities ◽

Mode Control

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Contractors and Linear Matrix Inequalities

ASCE-ASME J Risk and Uncert in Engrg Sys Part B Mech Engrg ◽

10.1115/1.4030781 ◽

2015 ◽

Vol 1 (3) ◽

Author(s):

Jeremy Nicola ◽

Luc Jaulin

Keyword(s):

Fixed Point ◽

Large Class ◽

Linear Matrix Inequalities ◽

Interior Point ◽

Interior Point Methods ◽

Linear Constraints ◽

Linear Matrix ◽

Nonlinear Constraints ◽

Matrix Inequalities ◽

Convex Constraints

Linear matrix inequalities (LMIs) comprise a large class of convex constraints. Boxes, ellipsoids, and linear constraints can be represented by LMIs. The intersection of LMIs are also classified as LMIs. Interior-point methods are able to minimize or maximize any linear criterion of LMIs with complexity, which is polynomial regarding to the number of variables. As a consequence, as shown in this paper, it is possible to build optimal contractors for sets represented by LMIs. When solving a set of nonlinear constraints, one may extract from all constraints that are LMIs in order to build a single optimal LMI contractor. A combination of all contractors obtained for other non-LMI constraints can thus be performed up to the fixed point. The resulting propogation is shown to be more efficient than other conventional contractor-based approaches.

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