Automating Embedded Analysis Capabilities and Managing Software Complexity in Multiphysics Simulation, Part II: Application to Partial Differential Equations

Automating Embedded Analysis Capabilities and Managing Software Complexity in Multiphysics Simulation, Part II: Application to Partial Differential Equations

A template-based generic programming approach was presented in Part I of this series of papers [Sci. Program. 20 (2012), 197–219] that separates the development effort of programming a physical model from that of computing additional quantities, such as derivatives, needed for embedded analysis algo...

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Veröffentlicht in:Scientific programming 2012, Vol.20 (3), p.327-345
Hauptverfasser: Pawlowski, Roger P., Phipps, Eric T., Salinger, Andrew G., Owen, Steven J., Siefert, Christopher M., Staten, Matthew L.
Format: Artikel
Sprache:eng
Schlagworte:
Computer programs
Computer simulation
Derivatives
Mathematical models
Partial differential equations
Programming
Software
Three dimensional
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Zusammenfassung:A template-based generic programming approach was presented in Part I of this series of papers [Sci. Program. 20 (2012), 197–219] that separates the development effort of programming a physical model from that of computing additional quantities, such as derivatives, needed for embedded analysis algorithms. In this paper, we describe the implementation details for using the template-based generic programming approach for simulation and analysis of partial differential equations (PDEs). We detail several of the hurdles that we have encountered, and some of the software infrastructure developed to overcome them. We end with a demonstration where we present shape optimization and uncertainty quantification results for a 3D PDE application.
ISSN:1058-9244
1875-919X
DOI:10.1155/2012/818262