Building partial differential equations models using cell-devs

The study of complex systems usually requires hybrid simulations because they have components that are continuous in nature and other that are discrete. It has been proved that DEVS is s a common denominator to combine different Modeling and Simulation methodologies (such as Petri Nets, Cellular Aut...

Descripción completa

Guardado en:
Detalles Bibliográficos
Autores principales: Wainer, G., Ruiz-Martín, C., Castro, R.
Formato: CONF
Materias:
Cells
Equations of motion
Numerical methods
Petri nets
Common denominators
Heat diffusions
Hybrid simulation
Lax-Wendroff method
Method of lines
Modeling and simulation methodologies
Partial differential
Shallow water equations
Cytology
Acceso en línea:http://hdl.handle.net/20.500.12110/paper_08917736_v2018-December_n_p1382_Wainer
Aporte de:
Biblioteca Digital - Facultad de Ciencias Exactas y Naturales (UBA) de Universidad de Buenos Aires
id todo:paper_08917736_v2018-December_n_p1382_Wainer
record_format dspace
spelling todo:paper_08917736_v2018-December_n_p1382_Wainer2023-10-03T15:41:25Z Building partial differential equations models using cell-devs Wainer, G. Ruiz-Martín, C. Castro, R. Cells Equations of motion Numerical methods Petri nets Common denominators Heat diffusions Hybrid simulation Lax-Wendroff method Method of lines Modeling and simulation methodologies Partial differential Shallow water equations Cytology The study of complex systems usually requires hybrid simulations because they have components that are continuous in nature and other that are discrete. It has been proved that DEVS is s a common denominator to combine different Modeling and Simulation methodologies (such as Petri Nets, Cellular Automata, Modelica etc.). We present a cellular model solution to solve PDEs as an extension of classical numerical methods combined with the Cell-DEVS formalism. We explain how to use Cell-DEVS to solve PDEs, focusing on two examples: the PDEs of a Heat Diffusion Process solved with the Method of Lines, and the Shallow Water Equations solved using the Lax-Wendroff method. We will discuss the advantages of solving PDEs with Cell-DEVS, in particular its integration with other hybrid models. © 2018 IEEE CONF info:eu-repo/semantics/openAccess http://creativecommons.org/licenses/by/2.5/ar http://hdl.handle.net/20.500.12110/paper_08917736_v2018-December_n_p1382_Wainer
institution Universidad de Buenos Aires
institution_str I-28
repository_str R-134
collection Biblioteca Digital - Facultad de Ciencias Exactas y Naturales (UBA)
topic Cells
Equations of motion
Numerical methods
Petri nets
Common denominators
Heat diffusions
Hybrid simulation
Lax-Wendroff method
Method of lines
Modeling and simulation methodologies
Partial differential
Shallow water equations
Cytology
spellingShingle Cells
Equations of motion
Numerical methods
Petri nets
Common denominators
Heat diffusions
Hybrid simulation
Lax-Wendroff method
Method of lines
Modeling and simulation methodologies
Partial differential
Shallow water equations
Cytology
Wainer, G.
Ruiz-Martín, C.
Castro, R.
Building partial differential equations models using cell-devs
topic_facet Cells
Equations of motion
Numerical methods
Petri nets
Common denominators
Heat diffusions
Hybrid simulation
Lax-Wendroff method
Method of lines
Modeling and simulation methodologies
Partial differential
Shallow water equations
Cytology
description The study of complex systems usually requires hybrid simulations because they have components that are continuous in nature and other that are discrete. It has been proved that DEVS is s a common denominator to combine different Modeling and Simulation methodologies (such as Petri Nets, Cellular Automata, Modelica etc.). We present a cellular model solution to solve PDEs as an extension of classical numerical methods combined with the Cell-DEVS formalism. We explain how to use Cell-DEVS to solve PDEs, focusing on two examples: the PDEs of a Heat Diffusion Process solved with the Method of Lines, and the Shallow Water Equations solved using the Lax-Wendroff method. We will discuss the advantages of solving PDEs with Cell-DEVS, in particular its integration with other hybrid models. © 2018 IEEE
format CONF
author Wainer, G.
Ruiz-Martín, C.
Castro, R.
author_facet Wainer, G.
Ruiz-Martín, C.
Castro, R.
author_sort Wainer, G.
title Building partial differential equations models using cell-devs
title_short Building partial differential equations models using cell-devs
title_full Building partial differential equations models using cell-devs
title_fullStr Building partial differential equations models using cell-devs
title_full_unstemmed Building partial differential equations models using cell-devs
title_sort building partial differential equations models using cell-devs
url http://hdl.handle.net/20.500.12110/paper_08917736_v2018-December_n_p1382_Wainer
work_keys_str_mv AT wainerg buildingpartialdifferentialequationsmodelsusingcelldevs
AT ruizmartinc buildingpartialdifferentialequationsmodelsusingcelldevs
AT castror buildingpartialdifferentialequationsmodelsusingcelldevs
_version_ 1782027440110960640

Ejemplares similares