In many cases, modeling and simulation of multi-physics systems cannot be carried out with one simulator or one class of models. Typically, for complex heterogeneous systems a combination of different modeling approaches, sometimes combined with simulator coupling, is the most appropriate method. A tool-box containing different modeling tools and software for simulator coupling is presented which could be applied successfully in the simulation of MEMS
Abstract- The advent of highly integrated technologies such as MEMS, MOEMS, nanometer scale integrat...
Modeling mechatronic multibody systems requires the same type of methodology as for designing and pr...
Abstract. Simulation of complex mechatronic systems like an automobile, involving multi-body compone...
The design and analysis process of mechatronic systems requires a wide range of different engineerin...
Mechatronic systems as well as other technical systems (microsystems, distributed automation systems...
A general approach for modelling of mechanical system co-simulations is presented that is built upon...
For MEMS devices modern technologies are used to integrate very complex components and subsystems cl...
The analysis of complex systems tends to be approached through a separation and a simplification of ...
This article presents a simulation tool for developing and characterizing microelectromechanical sys...
For MEMS devices modern technologies are used to integrate very complex components and subsystems cl...
Modeling and computer simulation play an important role in all engineering disciplines. As specializ...
Design of micro systems, MEMS or mechatronic systems is dominated by the interaction of effects from...
Modeling mechatronic multibody systems requires the same type of methodology as for designing and pr...
This paper describes, how to simulate the dynamics of multibody systems with SimMechanics, a toolbox...
This task force paper presents multi-domain tools and their interfacing issues to perform simulation...
Abstract- The advent of highly integrated technologies such as MEMS, MOEMS, nanometer scale integrat...
Modeling mechatronic multibody systems requires the same type of methodology as for designing and pr...
Abstract. Simulation of complex mechatronic systems like an automobile, involving multi-body compone...
The design and analysis process of mechatronic systems requires a wide range of different engineerin...
Mechatronic systems as well as other technical systems (microsystems, distributed automation systems...
A general approach for modelling of mechanical system co-simulations is presented that is built upon...
For MEMS devices modern technologies are used to integrate very complex components and subsystems cl...
The analysis of complex systems tends to be approached through a separation and a simplification of ...
This article presents a simulation tool for developing and characterizing microelectromechanical sys...
For MEMS devices modern technologies are used to integrate very complex components and subsystems cl...
Modeling and computer simulation play an important role in all engineering disciplines. As specializ...
Design of micro systems, MEMS or mechatronic systems is dominated by the interaction of effects from...
Modeling mechatronic multibody systems requires the same type of methodology as for designing and pr...
This paper describes, how to simulate the dynamics of multibody systems with SimMechanics, a toolbox...
This task force paper presents multi-domain tools and their interfacing issues to perform simulation...
Abstract- The advent of highly integrated technologies such as MEMS, MOEMS, nanometer scale integrat...
Modeling mechatronic multibody systems requires the same type of methodology as for designing and pr...
Abstract. Simulation of complex mechatronic systems like an automobile, involving multi-body compone...
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