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LEFT : Three dimensional simulation of a propane/air stoichiometric expanding flame. Iso-contours of vorticity (blue to red) and of reaction rate (green). Physical times range here from 0.49 to 7.28 ms. | LEFT : Three dimensional simulation of a propane/air stoichiometric expanding flame. Iso-contours of vorticity (blue to red) and of reaction rate (green). Physical times range here from 0.49 to 7.28 ms. | ||
RIGHT : results obtained with FLAMEX, pseudo-spectral/ETDRK solver for a Sivashinsky-type Evolution Equation (written for the whole front surface). 2.36 M colocation points; Fourier-Legendre decomposition. 3 CPU hours... | RIGHT : results obtained with FLAMEX, pseudo-spectral/ETDRK solver for a Sivashinsky-type Evolution Equation (written for the whole front surface). 2.36 M colocation points; Fourier-Legendre decomposition. 3 CPU hours... | ||
Revision as of 20:38, 28 March 2016
The DYCO Team
Modeling, SImulating & Analyzing Coupled Dynamics !
The Team Members:
- Christophe Goupil, Full Professor of Physics - Paris Diderot University
- Eric Herbert, Associate Professor of Physics - Paris Diderot University
- Yves D'Angelo, Full Professor of Applied Mathematics & Fluid Dynamics - INSA Rouen
| 450 px | 
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LEFT : Three dimensional simulation of a propane/air stoichiometric expanding flame. Iso-contours of vorticity (blue to red) and of reaction rate (green). Physical times range here from 0.49 to 7.28 ms.
RIGHT : results obtained with FLAMEX, pseudo-spectral/ETDRK solver for a Sivashinsky-type Evolution Equation (written for the whole front surface). 2.36 M colocation points; Fourier-Legendre decomposition. 3 CPU hours...