Xiaomei Lu
Guangxi University
55 Papers
283 Citations
Xiaomei Lu is an academic researcher from Guangxi University. The author has contributed to research in topics: Exponential stability & Lyapunov function. The author has an hindex of 18, co-authored 34 publications.
Chat about Author
Papers
Delay-dependent exponential stability of uncertain stochastic systems with multiple delays: an LMI approach
TL;DR: A delay-dependent sufficient condition is derived in terms of linear matrix inequalities (LMIs) by using a descriptor model transformation of the system and by applying Moon's inequality for bounding cross terms.
282
Impulsive Stabilization and Impulsive Synchronization of Discrete-Time Delayed Neural Networks
TL;DR: By introducing the time-varying Lyapunov functional to capture the dynamical characteristics of discrete-time impulsive delayed neural networks (DIDNNs) and by using a convex combination technique, new exponential stability criteria are derived in terms of linear matrix inequalities.
185
Mean square exponential stability of uncertain stochastic delayed neural networks
Wu-Hua Chen,Xiaomei Lu +1 more
TL;DR: In this article, the mean square exponential stability of uncertain stochastic delayed neural networks has been investigated by applying Lyapunov functional method, and new delay-dependent/independent MSE stability criteria are derived in terms of linear matrix inequalities.
147
Technical Communique: Delay-dependent output feedback guaranteed cost control for uncertain time-delay systems
TL;DR: A numerical algorithm is proposed to construct a full order output feedback controller achieving a suboptimal guaranteed cost such that the system can be stabilized for all admissible uncertainties.
124
On Sampled-Data Control for Master-Slave Synchronization of Chaotic Lur'e Systems
TL;DR: This brief presents a new method for master-slave synchronization of chaotic Lur'e systems with sampled-data control based on a novel construction of piecewise differentiable Lyapunov functionals in the framework of the input delay approach.
104