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56 Gábor Janiga References 1. Ali, N., Behdinan, K.: Optimal geometrical design of aircraft using genetic algorithms. Transactions of the Canadian Society for Mechanical Engineering 26(4), 373–388 (2003) 2. Antonov, I.A., Saleev, V.M.: An economic method of computing LPτ-sequences. U.S.S.R. Computational Mathematics and Mathematical Physics 19, 252–256 (1979) 3. Balagangadhar, D., Roy, S.: Design sensitivity analysis of steady fluid-thermal systems. Computer Methods in Applied Mechanics and Engineering 190, 5465–5479 (2001) 4. Barkley, D.: Linear analysis of the cylinder wake mean flow. Europhysics Letters 75(5), 750–756 (2006) 5. Barkley, D., Henderson, R.D.: Three-dimensional Floquet stability analysis of the wake of a circular cylinder. Journal of Fluid Mechanics 322, 215–241 (1996) 6. Baron, R.: Calcul et optimisation de brûleurs laminaires industriels. Ph.D. thesis, École Centrale Paris, 2002-37 (2002) 7. Baron, R., Paxion, S., Gicquel, O., Simous, N., Bastian, P., Thévenin, D.: Development of a 3D parallel multigrid solver for fast and accurate laminar steady flame computations. In: E.H. Hirschel (ed.) Numerical Flow Simulation III, pp. 115–128. Springer-Verlag (2003) 8. Bastian, P., Birken, K., Johannsen, K., Lang, S., Neuß, N., Rentz-Reichert, H., Wieners, C.: UG - A flexible software toolbox for solving partial differential equations. Computing and Visualization in Science 1, 27–40 (1997) 9. Bejan, A.: Entropy Generation Minimization. CRC Press, Boca Raton, Florida (1996) 10. Bello-Ochende, T., Bejan, A.: Constructal multi-scale cylinders in cross-flow. International Journal of Heat and Mass Transfer 48(7), 1373–1383 (2005) 11. Bongers, H., van Oijen, J.A., Somers, L.M.T., de Goey, L.P.H.: The flamelet-generated manifold method applied to steady planar partially premixed counterflow flames. Combustion Science and Technology 177(12), 2373–2393 (2005) 12. Bonjour, J., Rocha, L.A.O., Bejan, A., Meunier, F.: Dendritic fins optimization for a coaxial two-stream heat exchanger. International Journal of Heat and Mass Transfer 47(1), 111–124 (2004) 13. Büche, D., Stoll, P., Dornberger, R., Koumoutsakos, P.: Multiobjective evolutionary algorithm for the optimization of noisy combustion processes. IEEE Transactions on Systems, Man and Cybernetics Part C: Applications and Reviews 32(4), 460–473 (2002) 14. Büche, D., Stoll, P., Koumoutsakos, P.: An evolutionary algorithm for multi-objective optimization of combustion processes. Center for Turbulence Research Annual Research Briefs 2001 pp. 231–239 (2001) 15. Cheng, C.H., Chang, M.H.: Shape design for a cylinder with uniform temperature distribution on the outer surface by inverse heat transfer method. International Journal of Heat and Mass Transfer 46(1), 101–111 (2003) 16. Deb, K.: Multi-Objective Optimization using Evolutionary Algorithms. Wiley, London (2001) 17. Dias Jr., T., Milanez, L.: Optimal location of heat sources on a vertical wall with natural convection through genetic algorithms. International Journal of Heat and Mass Transfer 49(13-14), 2090–2096 (2006) 18. Edwards, K., Edgar, T., Manousiouthakis, V.: Kinetic model reduction using genetic algorithms. Computers and Chemical Engineering 22(1-2), 239–246 (1998) 19. Elliott, L., Ingham, D., Kyne, A., Mera, N., Pourkashanian, M., Wilson, C.: Multiobjective genetic algorithm optimization for calculating the reaction rate coefficients for hydrogen combustion. Industrial and Engineering Chemistry Research 42(6), 1215– 1224 (2003) 20. Elliott, L., Ingham, D., Kyne, A., Mera, N., Pourkashanian, M., Wilson, C.: Reaction mechanism reduction and optimization using genetic algorithms. Industrial and Engineering Chemistry Research 44(4), 658–667 (2005)
2 A Few Illustrative Examples of CFD-based Optimization 57 21. Fabbri, G.: Heat transfer optimization in internally finned tubes under laminar flow conditions. International Journal of Heat and Mass Transfer 41(10), 1243–1253 (1998) 22. Fabbri, G.: Heat transfer optimization in corrugated wall channels. International Journal of Heat and Mass Transfer 43(23), 4299–4310 (2000) 23. Fabbri, G.: Effect of viscous dissipation on the optimization of the heat transfer in internally finned tubes. International Journal of Heat and Mass Transfer 47(14–16), 3003–3015 (2004) 24. Falco, I.D.: An introduction to Evolutionary Algorithms and their application to the aerofoil design problem – Part I: the Algorithms. von Kármán Lecture Series on Fluid Dynamics, Bruxelles, Belgium, April 1997. (1997) 25. Fiorina, B., Baron, R., Gicquel, O., Thévenin, D., Carpentier, S., Darabiha, N.: Modelling non-adiabatic partially premixed flames using flame-prolongation of ILDM. Combustion Theory and Modelling 7(3), 449–470 (2003) 26. Fiorina, B., Gicquel, O., Carpentier, S., Darabiha, N.: Validation of the FPI chemistry reduction method for diluted nonadiabatic premixed flames. Combustion Science and Technology 176(5-6), 785–797 (2004) 27. Fiorina, B., Gicquel, O., Vervisch, L., Carpentier, S., Darabiha, N.: Approximating the chemical structure of partially premixed and diffusion counterflow flames using FPI flamelet tabulation. Combustion and Flame 140(3), 147–160 (2005) 28. Fletcher, R.: Practical Methods of Optimization. John Wiley & Sons, New York (1987) 29. Fluent Inc.: GAMBIT 2.3 User’s Guide. Lebanon, New Hampshire (2005) 30. Fluent Inc.: FLUENT 6.3 User’s Guide. Lebanon, New Hampshire (2006) 31. Foli, K., Okabe, T., Olhofer, M., Jin, Y., Sendhoff, B.: Optimization of micro heat exchanger: CFD, analytical approach and multi-objective evolutionary algorithms. International Journal of Heat and Mass Transfer 49(5-6), 1090–1099 (2006) 32. Fonseca, C.M., Fleming, P.J.: Genetic algorithms for multiobjective optimization: formulation, discussion and generalization. In: S. Forest (ed.) Genetic Algorithms: Proceedings of the Fifth International Conference, pp. 416–423. Morgan Kaufmann, San Mateo, California (1993) 33. Giovangigli, V.: Multicomponent flow modeling. Birkhäuser, Boston (1999) 34. Goldberg, D.E.: Genetic Algorithms in Search, Optimization and Machine Learning. Addison-Wesley, Reading, Massachusetts (1989) 35. Gordner, A.: Numerische Simulation nichtlinearer Aeroakustik bei kleinen Machzahlen. Ph.D. thesis, Universität Heidelberg, Germany (2005) 36. Gropp, W., Lusk, E.: User’s guide for MPICH, a portable implementation of MPI. Tech. Rep. ANL-96/6, Argonne National Laboratory (1994) 37. Guo, Y.Y., He, G., Hsu, A.: Application of genetic algorithms to the development of a variable Schmidt number model for jet-in-crossflows. International Journal of Numerical Methods for Heat & Fluid Flow 11, 744–760 (2001) 38. Hilbert, R., Janiga, G., Baron, R., Thévenin, D.: Multiobjective shape optimization of a heat exchanger using parallel genetic algorithms. International Journal of Heat and Mass Transfer 49(15-16), 2567–2577 (2006) 39. Hilbert, R., Tap, F., El-Rabii, H., Thévenin, D.: Impact of detailed chemistry and transport models on turbulent combustion simulations. Progress in Energy and Combustion Science 30, 61–117 (2004) 40. Hoyas, S., Jiménez, J.: Scaling of the velocity fluctuations in turbulent channels up to Reτ=2003. Physics of Fluids 18, 011,702 (2006) 41. Janiga, G., Gicquel, O., Thévenin, D.: High-resolution simulation of three-dimensional laminar burners using tabulated chemistry on parallel computers. In: 2nd ECCOMAS Thematic Conference on Computational Combustion, pp. 1–15. Delft, The Netherlands (2007) 42. Janiga, G., Gordner, A., Shalaby, H., Thévenin, D.: Simulation of laminar burners using detailed chemistry on parallel computers. In: P. Wesseling, E. Onate, J. Périaux (eds.) European Conference on Computational Fluid Dynamics, ECCOMAS CFD 2006, pp. 210/1–210/14. Egmond aan Zee, The Netherlands (2006)
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Optimization and Computational Flui
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Editors: Prof. Dr.-Ing. Dominique T
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vi Preface Our first research proje
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viii Contents 2.4.1 GoverningEquati
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x Contents 6.2.3 Parameterization..
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xii Contents 9.4.1 Multi-objectiveO
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xiv List of Contributors Gábor JAN
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Part I Generalities and methods
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4 Dominique Thévenin 12 10 8 6 4 2
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Page 50 and 51: 36 Gábor Janiga ∆P [mPa] 2.2 2.0
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4 Adjoint Methods for Shape Optimiz
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Part II Specific Applications of CF
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112 Nicolas R. Gauger Nomenclature
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114 Nicolas R. Gauger Fig. 5.1 Cost
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116 Nicolas R. Gauger and the four
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118 Nicolas R. Gauger CL := 1 � C
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120 Nicolas R. Gauger the cost func
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122 Nicolas R. Gauger Table 5.1 An
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124 Nicolas R. Gauger The main adva
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126 Nicolas R. Gauger Spalart-Allma
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128 Nicolas R. Gauger (a) (b) Fig.
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134 Nicolas R. Gauger Fig. 5.10 Plo
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136 Nicolas R. Gauger drag, lift, s
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138 Nicolas R. Gauger solution of t
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140 Nicolas R. Gauger the presence
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142 Nicolas R. Gauger Fig. 5.16 Con
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144 Nicolas R. Gauger optimization
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Chapter 6 Numerical Optimization fo
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6 Numerical Optimization for Advanc
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192 Laurent Dumas 7.1 Introducing A
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194 Laurent Dumas C Fig. 7.2 Wake f
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196 Laurent Dumas Table 7.1 Example
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198 Laurent Dumas Fig. 7.5 Numerica
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200 Laurent Dumas 7.3.1.1 Genetic A
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202 Laurent Dumas START Random init
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204 Laurent Dumas • if ˜ J(x ng
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206 Laurent Dumas Table 7.3 Compari
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208 Laurent Dumas Fig. 7.9 General
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210 Laurent Dumas Table 7.4 Four ex
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212 Laurent Dumas Fig. 7.13 Blades
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214 Laurent Dumas Table 7.5 Converg
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Chapter 8 Multi-objective Optimizat
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8 Multi-objective Optimization in C
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8 Multi-objective Optimizatio Fig.
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292 Index heat exchanger, 222, 224,
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