Add to ORKGUsing an industrial process from the car sector, we show how dioid algebra may be used for the performance evaluation, sizing, and control of this discrete-event dynamic system. Based on a Petri net model as an event graph, max-plus algebra and min-plus algebra permit to write linear equations of the behavior. From this formalism, the cycle time is determined and an optimal sizing is characterized for a required cyclic behavior. Finally, a strict temporal constraint the system is subject to is reformulated in terms of inequalities that the (min, +) system should satisfy, and a control law is designed so that the controlled system satisfies the constraint
AbstractIn job-shop systems, each product is routed according to its own production cycle. However r...
This thesis is part of the theory of linear systems over dioids. This theory concerns the subclass o...
This book concerns the use of dioid algebra as (max, +) algebra to treat the synchronization of task...
Using an industrial process from the car sector, we show how dioid algebra may be used for the perfo...
Abstract: Using an industrial process from the car sector, we show how dioid algebra may be used for...
Discrete event systems (DES) are a special class of dynamical systems with discrete-valued state spa...
This book concerns the use of dioid algebra as (max, +) algebra to treat the synchronization of task...
The class of Timed Event Graphs (TEGs) has widely been studied for the last 30 years thanks to an al...
This paper deals with the control of discrete event systems modelled by the Max-plus algebra. This a...
Flow-shops are manufacturing deterministic systems which can be analytically modelled in a fairly ea...
26 pagesInternational audienceIn this paper, we propose a (max,+)-based method for the supervi- sion...
Various kinds of manufacturing systems can be modeled and analyzed by Timed EventGraphs (TEGs). Thes...
Abstract This paper deals with the model-reference control of timed event graphs using the dioid alg...
summary:This paper deals with output feedback synthesis for Timed Event Graphs (TEG) in dioid algebr...
In this chapter, the dynamics of manufacturing systems is characterized through the occurrence of ev...
AbstractIn job-shop systems, each product is routed according to its own production cycle. However r...
This thesis is part of the theory of linear systems over dioids. This theory concerns the subclass o...
This book concerns the use of dioid algebra as (max, +) algebra to treat the synchronization of task...
Using an industrial process from the car sector, we show how dioid algebra may be used for the perfo...
Abstract: Using an industrial process from the car sector, we show how dioid algebra may be used for...
Discrete event systems (DES) are a special class of dynamical systems with discrete-valued state spa...
This book concerns the use of dioid algebra as (max, +) algebra to treat the synchronization of task...
The class of Timed Event Graphs (TEGs) has widely been studied for the last 30 years thanks to an al...
This paper deals with the control of discrete event systems modelled by the Max-plus algebra. This a...
Flow-shops are manufacturing deterministic systems which can be analytically modelled in a fairly ea...
26 pagesInternational audienceIn this paper, we propose a (max,+)-based method for the supervi- sion...
Various kinds of manufacturing systems can be modeled and analyzed by Timed EventGraphs (TEGs). Thes...
Abstract This paper deals with the model-reference control of timed event graphs using the dioid alg...
summary:This paper deals with output feedback synthesis for Timed Event Graphs (TEG) in dioid algebr...
In this chapter, the dynamics of manufacturing systems is characterized through the occurrence of ev...
AbstractIn job-shop systems, each product is routed according to its own production cycle. However r...
This thesis is part of the theory of linear systems over dioids. This theory concerns the subclass o...
This book concerns the use of dioid algebra as (max, +) algebra to treat the synchronization of task...