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106 Kyriakos C. Giannakoglou and Dimitrios I. Papadimitriou References 1. Alonso, J.J., Kroo, I.M., Jameson, A.: Advanced algorithms for design and optimization of quiet supersonic platform. AIAA Paper 2002-0144 (2002) 2. Anderson, W.K., Bonhaus, D.L.: Airfoil design on unstructured grids for turbulent flows. AIAA Journal 37(2), 185–191 (1999) 3. Anderson, W.K., Bonhaus, D.L., Daryl, L.: Aerodynamic design on unstructured grids for turbulent flows. NASA Technical Memorandum 112867 (1997) 4. Anderson, W.K., Venkatakrishnan, V.: Aerodynamic design optimization on unstructured grids with a continuous adjoint formulation. AIAA Paper 97-0643 (1997) 5. Anderson, W.K., Venkatakrishnan, V.: Aerodynamic design optimization on unstructured grids with a continuous adjoint formulation. Computers and Fluids 28, 443–480 (1999) 6. Arian, E., Salas, M.D.: Admitting the inadmissible: Adjoint formulation for incomplete cost functionals in aerodynamic optimization. NASA/CR-97-206269, ICASE Report No.97–69 (1997) 7. Arian, E., Taasan, S.: Analysis of the Hessian for aerodynamic optimization: Inviscid flow. Computers and Fluids 28(7), 853–877 (1999) 8. Bäck, T.: Evolutionary Algorithms in Theory and Practice. Oxford University Press (1996) 9. Baysal, O., Ghayour, K.: Continuous adjoint sensitivities for optimization with general cost functionals on unstructured meshes. AIAA Journal 39(1), 48–55 (2001) 10. Bertsekas, D.P.: Nonlinear Programming, 2nd edn. Athena Scientific (1999) 11. Campobasso, M.S., Duta, M.C., Giles, M.B.: Adjoint calculation of sensitivities of turbomachinery objective functions. AIAA Journal of Propulsion and Power 19(4), 693–703 (2003) 12. Dadone, A., Grossman, B.: Progressive optimization of inverse fluid dynamic design problems. Computers and Fluids 29, 1–32 (2000) 13. Dadone, A., Grossman, B.: Fast convergence of inviscid fluid dynamic design problems. Computers and Fluids 32, 607–627 (2003) 14. Duta, M.C., Giles, M.B., Campobasso, M.S.: The harmonic adjoint approach to unsteady turbomachinery design. International Journal for Numerical Methods in Fluids 40(3-4), 323–332 (2002) 15. Elliot, J., Peraire, J.: Aerodynamic design using unstructured meshes. AIAA Paper 96-1941 (1996) 16. Elliot, J., Peraire, J.: Aerodynamic optimization using unstructured meshes with viscous effects. AIAA Paper 97-1849 (1997) 17. Elliot, J., Peraire, J.: Practical 3d aerodynamic design and optimization using unstructured meshes. AIAA Journal 35(9), 1479–1485 (1997) 18. Elliot, J., Peraire, J.: Constrained, multipoint shape optimisation for complex 3d configurations. Aeronautical Journal 102(1017), 365–376 (1998) 19. Forest, A.R.: Interactive interpolation and approximation by Bezier polynomials. The Computer Journal 15(1), 71–79 (1972) 20. Giannakoglou, K.C.: Design of optimal aerodynamic shapes using stochastic optimization methods and computational intelligence. Progress in Aerospace Sciences 38, 43–76 (2002) 21. Giles, M.B.: Discrete adjoint approximations with shocks. In: T. Hou, E. Tadmor (eds.) Hyperbolic Problems: Theory, Numerics, Applications. Springer-Verlag (2003) 22. Giles, M.B., Duta, M.C., Muller, J.D., Pierce, N.A.: Algorithm developments for discrete adjoint methods. AIAA Journal 41(2), 198–205 (2003) 23. Giles, M.B., Pierce, N.A.: Adjoint equations in CFD: duality, boundary conditions and solution behaviour. AIAA Paper 97-1850 (1997) 24. Giles, M.B., Pierce, N.A.: On the properties of solutions of the adjoint Euler equations. In: 6th ICFD Conference on Numerical Methods for Fluid Dynamics. Oxford, UK (1998)
4 Adjoint Methods for Shape Optimization 107 25. Harbeck, M., Jameson, A.: Exploring the limits of transonic shock-free airfoil design. AIAA Paper 2005-1041 (2005) 26. Hazra, S., Schulz, V., Brezillon, J., Gauger, N.R.: Aerodynamic shape optimization using simultaneous pseudo-timestepping. Journal of Computational Physics 204(1), 46–64 (2005) 27. Hazra, S.B., Schulz, V.: Simultaneous pseudo-timestepping for aerodynamic shape optimization problems with state constraints. SIAM Journal of Scientific Computing 28(3), 1078–1099 (2006) 28. Jameson, A.: Aerodynamic design via control theory. Journal of Scientific Computing 3, 233–260 (1988) 29. Jameson, A.: Optimum aerodynamic design using CFD and control theory. AIAA Paper 95-1729 (1995) 30. Jameson, A., Alonso, J.J.: Automatic aerodynamic optimization on distributed memory architectures. AIAA Paper 96-0409 (1996) 31. Jameson, A., Kim, S.: Reduction of the adjoint gradient formula in the continous limit. AIAA Paper 2003-0040 (2003) 32. Jameson, A., Pierce, N., Martinelli, L.: Optimum aerodynamic design using the Navier- Stokes equations. Theoretical and Computational Fluid Dynamics 10, 213–237 (1998) 33. Jameson, A., Reuther, J.: Control theory based airfoil design using the Euler equations. AIAA Paper 94-4272 (1994) 34. Jameson, A., Shankaran, S., Martinelli, L., Haimes, B.: Aerodynamic shape optimization of complete aircraft configuration. AIAA Paper 2004-0533 (2004) 35. Kim, S.K., Alonso, J.J., Jameson, A.: Two-dimensional high-lift aerodynamic optimization using the continuous adjoint method. AIAA Paper 2000-4741 (2000) 36. Kim, S.K., Alonso, J.J., Jameson, A.: Design optimization of high-lift configurations using a viscous continuous adjoint method. AIAA Paper 2002-0844 (2002) 37. Kuruvila, G., Taasan, S., Salas, M.D.: Airfoil design and optimization by the one-shot method. AIAA Paper 95-0478 (1995) 38. Leoviriyakit, K., Jameson, A.: Aero-structural wing planform optimization. AIAA Paper 2004-0029 (2004) 39. Leoviriyakit, K., Jameson, A.: Multi-point wing planform optimization via control theory. AIAA Paper 2005-0450 (2005) 40. Leoviriyakit, K., Kim, S., Jameson, A.: Aero-structural wing planform optimization using the Navier-Stokes equations. AIAA Paper 2004-4479 (2004) 41. Mavriplis, D.J.: A discrete adjoint-based approach for optimization problems on threedimensional unstructured meshes. AIAA Paper 2006-50 (2006) 42. Mohammadi, B., Pironneau, O.: Shape optimization in fluid mechanics. Annual Review of Fluid Mechanics 36, 255–279 (2004) 43. Nadarajah, S., Jameson, A.: A comparison of the continuous and discrete adjoint approach to automatic aerodynamic optimization. AIAA Paper 2000-0667 (2000) 44. Nadarajah, S., Jameson, A.: Studies of the continuous and discrete adjoint approaches to viscous automatic aerodynamic shape optimization. AIAA Paper 2001-2530 (2001) 45. Nadarajah, S., Jameson, A.: Optimum shape design for unsteady three-dimensional viscous flows using a non-linear frequency domain method. AIAA Paper 2002-2838 (2002) 46. Nadarajah, S., Jameson, A., Alonso, J.J.: An adjoint method for the calculation of remote sensitivities in supersonic flow. AIAA Paper 2002-0261 (2002) 47. Nadarajah, S., McMullen, M., Jameson, A.: Non-linear frequency domain based optimum shape design for unsteady three-dimensional flow. AIAA Paper 2002-2838 (2002) 48. Newman, J.C., Anderson, W.K., Whitfield, D.L.: Multidisciplinary sensitivity derivatives using complex variables. Tech. Rep. MSSU-COE-ERC-98-08, Mississippi State University (1998) 49. Nielsen, E.J., Anderson, W.K.: Recent improvements in aerodynamic design optimization on unstructured meshes. AIAA Paper 2001-0596 (2001)
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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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6 Dominique Thévenin Objective 10
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8 Dominique Thévenin Objective 10
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10 Dominique Thévenin Parameter 2
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12 Dominique Thévenin three-dimens
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14 Dominique Thévenin Let us come
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16 Dominique Thévenin References 1
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18 Gábor Janiga 2.1 Introduction D
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20 Gábor Janiga y Tinlet = 293 K 0
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22 Gábor Janiga y [mm] 25 20 15 10
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24 Gábor Janiga Table 2.1 Number o
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26 Gábor Janiga A dominates the in
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28 Gábor Janiga be shown later, th
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30 Gábor Janiga INPUT FILE Gambit
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34 Gábor Janiga ∆T ∆P Position
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36 Gábor Janiga ∆P [mPa] 2.2 2.0
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38 Gábor Janiga Table 2.3 Speed-up
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40 Gábor Janiga For all computatio
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42 Gábor Janiga y [mm] 4 2 0 -1 0
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44 Gábor Janiga Air mass flow-rate
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46 Gábor Janiga Temperature variat
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50 Gábor Janiga The modified k-ω
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52 Gábor Janiga Error for Re∗ =
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54 Gábor Janiga Error for Re∗ 20
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Page 132 and 133: 118 Nicolas R. Gauger CL := 1 � C
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Page 156 and 157: 142 Nicolas R. Gauger Fig. 5.16 Con
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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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Chapter 9 CFD-based Optimization fo
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9 CFD-based optimization for paperm
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292 Index heat exchanger, 222, 224,
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