Title :
Mode transition behavior in hybrid dynamic systems
Author :
Mosterman, Pieter J.
Author_Institution :
MatWworks Inc., Natick, MA, USA
Abstract :
Physical system modeling benefits from the use of implicit equations because it is often an intuitive way to describe physics. Model abstraction may lead to efficient models with idealized component behavior that switches between modes (e.g., a diode may be on or off) based on inequalities (e.g., voltage > 0). In an explicit representation, the combination of these local mode switches leads to a combinatorial explosion of the number of global modes. It is shown how an implicit formulation of these mode switches circumvents the combinatorial problem. This leads to the use of differential and algebraic equations (DAE) for each of the modes. In case these DAEs are of high index, jumps in generalized state variables may occur. In combination with the inequalities that define mode switching, this leads to rich and complex mode transition behavior. An overview of this mode switching behavior and an ontology is presented.
Keywords :
algebra; combinatorial mathematics; control system analysis; difference equations; algebraic equations; combinatorial explosion; differential equations; explicit representation; hybrid dynamic systems; idealized component behavior; implicit equations; implicit formulation; mode switches; mode switching; mode transition behavior; model abstraction; ontology; physical system modeling; state variables; Control system synthesis; Control systems; Diodes; Equations; Explosions; Gold; Modeling; Ontologies; Switches; Voltage;
Conference_Titel :
Simulation Conference, 2003. Proceedings of the 2003 Winter
Print_ISBN :
0-7803-8131-9
DOI :
10.1109/WSC.2003.1261477
