Linear Periodic Systems Over Dioids
Discrete Event Dynamic Systems
Modeling and Control of Hybrid Timed Event Graphs with Multipliers Using (Min, +) Algebra
Discrete Event Dynamic Systems
Brief paper: Input signal design for identification of max-plus-linear systems
Automatica (Journal of IFAC)
Stable Model Predictive Control for Constrained Max-Plus-Linear Systems
Discrete Event Dynamic Systems
Stabilization of max-plus-linear systems using model predictive control: The unconstrained case
Automatica (Journal of IFAC)
Kanban policy improvement thanks to a (max,+)-algebra analysis
International Journal of Systems Science - Production Coordination and Inventory Policies
Flow control with (min,+) algebra
ISoLA'10 Proceedings of the 4th international conference on Leveraging applications of formal methods, verification, and validation - Volume Part I
Brief paper: On the control of max-plus linear system subject to state restriction
Automatica (Journal of IFAC)
Modelling urban intersections in dioid algebra
ACMOS'06 Proceedings of the 8th WSEAS international conference on Automatic control, modeling & simulation
Modeling and control of high-throughput screening systems in a max-plus algebraic setting
Engineering Applications of Artificial Intelligence
Interval analysis and dioid: application to robust controller design for timed event graphs
Automatica (Journal of IFAC)
Control of (max,+)-linear systems minimizing delays
Discrete Event Dynamic Systems
Container of (min, +)-linear systems
Discrete Event Dynamic Systems
| Hi-index | 22.15 |
This paper deals with feedback controller synthesis for timed event graphs in dioids. We discuss here the existence and the computation of a controller which leads to a closed-loop system whose behavior is as close as possible to the one of a given reference model and which delays as much as possible the input of tokens inside the (controlled) system. The synthesis presented here is mainly based on residuation theory results and some Kleene star properties.