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Wpmh Maurice Heemels
Researcher at Eindhoven University of Technology
Publications - 458
Citations - 18915
Wpmh Maurice Heemels is an academic researcher from Eindhoven University of Technology. The author has contributed to research in topics: Linear system & Control system. The author has an hindex of 59, co-authored 427 publications receiving 16476 citations. Previous affiliations of Wpmh Maurice Heemels include University of California, Santa Barbara.
Papers
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Proceedings ArticleDOI
An introduction to event-triggered and self-triggered control
TL;DR: An introduction to event- and self-triggered control systems where sensing and actuation is performed when needed and how these control strategies can be implemented using existing wireless communication technology is shown.
Journal ArticleDOI
Periodic event-triggered control for nonlinear systems
TL;DR: The PETC strategies developed in this paper apply to both static state-feedback and dynamical output-based controllers, as well as to both centralized and decentralized (periodic) event-triggering conditions.
Journal ArticleDOI
Brief Equivalence of hybrid dynamical models
TL;DR: Equivalences among five classes of hybrid systems are established, of paramount importance for transferring theoretical properties and tools from one class to another, with the consequence that for the study of a particular hybrid system that belongs to any of these classes, one can choose the most convenient hybrid modeling framework.
Journal ArticleDOI
Output-Based Event-Triggered Control With Guaranteed ${\cal L}_{\infty}$ -Gain and Improved and Decentralized Event-Triggering
TL;DR: This paper proposes a decentralized event-triggering mechanism that will be able to guarantee stability and performance for event-triggered controllers with larger minimum inter-event times than the existing results in the literature.
Journal ArticleDOI
Analysis of event-driven controllers for linear systems
TL;DR: This paper considers an event-driven control scheme for perturbed linear systems that triggers the control update only when the tracking or stabilization error is large, so that the average processor and/or communication load can be reduced significantly.