Optimization and Computational Fluid Dynamics - Department of ...

More documents

Recommendations

Info

144 Nicolas R. Gauger optimization is about 68% and the shock completely vanished (Fig. 5.18) as expected for inviscid cases. Figure 5.18 presents the comparison of the initial and final surface pressure distributions achieved with the one-shot approach (present) and with the conventional gradient based adjoint approach (steepest descent). Altogether, the numerical cost of the one-shot optimization is of the magnitude of just 4 flow simulations, which is a dramatic reduction in computation time compared to the conventional approach. Acknowledgements The author thanks his colleagues at DLR, in particular A. Fazzolari, J. Brezillon and M. Widhalm, as well as the MEGADESIGN partners V. Schulz and S. Hazra from University of Trier for their contributions to this chapter. Furthermore, the author thanks A. Walther and C. Moldenhauer from TU Dresden for their support and contributions w.r.t. algorithmic differentiation. References 1. Brezillon, J., Dwight, R.: Discrete adjoint of the Navier-Stokes equations for aerodynamic shape optimization. In: Proceedings of EUROGEN05 (2005) 2. Brezillon, J., Gauger, N.R.: 2D and 3D aerodynamic shape optimization using the adjoint approach. Aerospace Science and Technology 8(8), 715–727 (2004) 3. Dwight, R.: Efficiency improvments of RANS-based analysis and optimization using implicit and adjoint methods on unstructured grids. Ph.D. thesis, DLR-Report No. DLR-FB–2006-11 (ISSN 1434-8454) (2006) 4. Fazzolari, A.: An aero-structure adjoint formulation for efficient multidisciplinary wing optimization. Ph.D. thesis, TU Braunschweig, Germany (2006) 5. Fazzolari, A., Gauger, N.R., Brezillon, J.: An aero-structure adjoint formulation for efficient multidisciplinary wing optimization. In: Proceedings of EUROGEN05 (2005) 6. Fazzolari, A., Gauger, N.R., Brezillon, J.: Efficient aerodynamic shape optimization in mdo context. Journal of Computational and Applied Mathematics 203, 548–560 (2007) 7. Gauger, N.R.: Aerodynamic shape optimization using the adjoint Euler equations. In: Proceedings of the GAMM Workshop on Discrete Modelling and Discrete Algorithms in Continuum Mechanics, pp. 87–96. Logos Verlag, Berlin (2001) 8. Gauger, N.R.: Das Adjungiertenverfahren in der aerodynamischen Formoptimierung. Ph.D. thesis, DLR-Report No. DLR-FB–2003-05 (ISSN 1434-8454) (2003) 9. Gauger, N.R., Brezillon, J.: Aerodynamic shape optimization using adjoint method. Journal of the Aeronautical Society of India 54(3), 247–254 (2002) 10. Gauger, N.R., Walther, A., Moldenhauer, C., Widhalm, M.: Automatic differentiation of an entire design chain for aerodynamic shape optimization. In: Notes on Numerical Fluid Mechanics and Multidisciplinary Design (to appear), vol. 96. Springer Verlag (2007) 11. Giering, R., Kaminski, T., Slawig, T.: Applying TAF to a Navier-Stokes solver that simulates an Euler flow around an airfoil. Future Generation Computer Systems 21(8) (2005) 12. Giles, M.B., Duta, M.C., Müller, J.D., Pierce, N.A.: Algorithm developments for discrete adjoint methods. AIAA Journal 41(2), 198–205 (2003)
5 Efficient Deterministic Approaches for Aerodynamic Shape Optimization 145 13. Griewank, A.: Evaluating Derivatives, Principles and Techniques of Algorithmic Differentiation. Society for Industrial and Applied Mathematics, Philadelphia (2000) 14. Griewank, A., Juedes, D., Mitev, H., Utke, J., Vogel, O., Walther, A.: ADOL-C: A package for the automatic differentiation of algorithms written in C/C++. Tech. rep., Technical University of Dresden, Institute of Scientific Computing and Institute of Geometry (1999) 15. Hazra, S.B., Schulz, V.: Simultaneous pseudo-timestepping for PDE-model based optimization problems. Bit Numerical Mathematics 44(3), 457–472 (2004) 16. Hazra, S.B., Schulz, V., Brezillon, J., Gauger, N.R.: Aerodynamic shape optimization using simultaneous pseudo-timestepping. Journal of Computational Physics 204(1), 46–64 (2005) 17. Heinrich, R.: Implementation and usage of structured algorithms within an unstructured CFD-code. In: Notes on Numerical Fluid Mechanics and Multidisciplinary Design, vol. 92. Springer Verlag (2006) 18. Hounjet, M.H.L., Prananta, B.B., Zwaan, R.: A thin layer Navier Stokes solver and its application for aeroelastic analysis of an airfoil in transonic flow. Netherlands, DLR-Publication (1995) 19. Jameson, A.: Aerodynamic design via control theory. Journal of Scientific Computing 3, 233–260 (1988) 20. Jameson, A., Martinelli, L., Pierce, N.A.: Optimum aerodynamic design using the navier-stokes equations. Theoretical and Computational Fluid Dynamics 10, 213–237 (1998) 21. Jameson, A., Reuther, J.: Control theory based on airfoil design using the Euler equations. AIAA Proceedings 94-4272-CP (1994) 22. Kroll,N.,Rossow,C.C.,Schwamborn,D.,Becker,K.,Heller,G.:MEGAFLOW-A numerical flow simulation tool for transport aircraft design (2002) 23. Martins, J.R., Alonso, J.J., Reuther, J.J.: Complete configuration aero-structural optimization using a coupled sensitivity analysis method. AIAA Paper 2002-5402 (2002) 24. Martins, J.R., Alonso, J.J., Reuther, J.J.: High-fidelity aero-structural design optimization of a supersonic business jet. AIAA Paper 2002-1483 (2002) 25. Nocedal, J., Wright, S.J.: Numerical Optimization. Springer Series in Operations Research. Springer (1999) 26. Rossow, C.C.: A flux splitting scheme for compressible and incompressible flows. Journal of Computational Physics 164, 104–122 (2000) 27. Schlenkrich, S., Walther, A., Gauger, N.R., Heinrich, R.: Differentiating fixed point iterations with ADOL-C: Gradient calculation for fluid dynamics. In: Proceedings of the International Conference on High Performance Scientific Computing (2006) 28. Widhalm, M., Gauger, N.R., Brezillon, J.: Implementation of a continuous adjoint solver in TAU. DLR-Report (in press) (2007) 29. Widhalm, M., Rossow, C.C.: Improvement of upwind schemes with the least square method in the DLR TAU code. In: Notes on Numerical Fluid Mechanics, vol. 87, pp. 398–406. Springer Verlag (2004)
Page 1 and 2:
Optimization and Computational Flui
Page 3 and 4:
Editors: Prof. Dr.-Ing. Dominique T
Page 5 and 6:
vi Preface Our first research proje
Page 7 and 8:
viii Contents 2.4.1 GoverningEquati
Page 9 and 10:
x Contents 6.2.3 Parameterization..
Page 11 and 12:
xii Contents 9.4.1 Multi-objectiveO
Page 13 and 14:
xiv List of Contributors Gábor JAN
Page 15:
Part I Generalities and methods
Page 18 and 19:
4 Dominique Thévenin 12 10 8 6 4 2
Page 20 and 21:
6 Dominique Thévenin Objective 10
Page 22 and 23:
8 Dominique Thévenin Objective 10
Page 24 and 25:
10 Dominique Thévenin Parameter 2
Page 26 and 27:
12 Dominique Thévenin three-dimens
Page 28 and 29:
14 Dominique Thévenin Let us come
Page 30 and 31:
16 Dominique Thévenin References 1
Page 32 and 33:
18 Gábor Janiga 2.1 Introduction D
Page 34 and 35:
20 Gábor Janiga y Tinlet = 293 K 0
Page 36 and 37:
22 Gábor Janiga y [mm] 25 20 15 10
Page 38 and 39:
24 Gábor Janiga Table 2.1 Number o
Page 40 and 41:
26 Gábor Janiga A dominates the in
Page 42 and 43:
28 Gábor Janiga be shown later, th
Page 44 and 45:
30 Gábor Janiga INPUT FILE Gambit
Page 46 and 47:
Page 48 and 49:
34 Gábor Janiga ∆T ∆P Position
Page 50 and 51:
36 Gábor Janiga ∆P [mPa] 2.2 2.0
Page 52 and 53:
38 Gábor Janiga Table 2.3 Speed-up
Page 54 and 55:
40 Gábor Janiga For all computatio
Page 56 and 57:
42 Gábor Janiga y [mm] 4 2 0 -1 0
Page 58 and 59:
44 Gábor Janiga Air mass flow-rate
Page 60 and 61:
46 Gábor Janiga Temperature variat
Page 62 and 63:
Page 64 and 65:
50 Gábor Janiga The modified k-ω
Page 66 and 67:
52 Gábor Janiga Error for Re∗ =
Page 68 and 69:
54 Gábor Janiga Error for Re∗ 20
Page 70 and 71:
56 Gábor Janiga References 1. Ali,
Page 72 and 73:
58 Gábor Janiga 43. Janiga, G., Th
Page 75 and 76:
Chapter 3 Mathematical Aspects of C
Page 77 and 78:
3 Mathematical Aspects of CFD-based
Page 79 and 80:
Page 81 and 82:
Page 83 and 84:
Page 85 and 86:
Page 87 and 88:
Page 89 and 90:
Page 91 and 92:
Page 93 and 94:
Chapter 4 Adjoint Methods for Shape
Page 95 and 96:
4 Adjoint Methods for Shape Optimiz
Page 97 and 98:
Page 99 and 100:
Page 101 and 102:
Page 103 and 104:
Page 105 and 106:
Page 107 and 108: 4 Adjoint Methods for Shape Optimiz
Page 123: Part II Specific Applications of CF
Page 126 and 127: 112 Nicolas R. Gauger Nomenclature
Page 128 and 129: 114 Nicolas R. Gauger Fig. 5.1 Cost
Page 130 and 131: 116 Nicolas R. Gauger and the four
Page 132 and 133: 118 Nicolas R. Gauger CL := 1 � C
Page 134 and 135: 120 Nicolas R. Gauger the cost func
Page 136 and 137: 122 Nicolas R. Gauger Table 5.1 An
Page 138 and 139: 124 Nicolas R. Gauger The main adva
Page 140 and 141: 126 Nicolas R. Gauger Spalart-Allma
Page 142 and 143: 128 Nicolas R. Gauger (a) (b) Fig.
Page 148 and 149: 134 Nicolas R. Gauger Fig. 5.10 Plo
Page 150 and 151: 136 Nicolas R. Gauger drag, lift, s
Page 152 and 153: 138 Nicolas R. Gauger solution of t
Page 154 and 155: 140 Nicolas R. Gauger the presence
Page 156 and 157: 142 Nicolas R. Gauger Fig. 5.16 Con
Page 161 and 162: Chapter 6 Numerical Optimization fo
Page 163 and 164: 6 Numerical Optimization for Advanc
Page 203: 6 Numerical Optimization for Advanc
Page 206 and 207: 192 Laurent Dumas 7.1 Introducing A
Page 208 and 209:
194 Laurent Dumas C Fig. 7.2 Wake f
Page 210 and 211:
196 Laurent Dumas Table 7.1 Example
Page 212 and 213:
198 Laurent Dumas Fig. 7.5 Numerica
Page 214 and 215:
200 Laurent Dumas 7.3.1.1 Genetic A
Page 216 and 217:
202 Laurent Dumas START Random init
Page 218 and 219:
204 Laurent Dumas • if ˜ J(x ng
Page 220 and 221:
206 Laurent Dumas Table 7.3 Compari
Page 222 and 223:
208 Laurent Dumas Fig. 7.9 General
Page 224 and 225:
210 Laurent Dumas Table 7.4 Four ex
Page 226 and 227:
212 Laurent Dumas Fig. 7.13 Blades
Page 228 and 229:
214 Laurent Dumas Table 7.5 Converg
Page 231 and 232:
Chapter 8 Multi-objective Optimizat
Page 233 and 234:
8 Multi-objective Optimization in C
Page 235 and 236:
Page 237 and 238:
8 Multi-objective Optimizatio Fig.
Page 239 and 240:
Page 241 and 242:
Page 243 and 244:
Page 245 and 246:
Page 247 and 248:
Page 249 and 250:
Page 251 and 252:
Page 253 and 254:
Page 255 and 256:
Page 257 and 258:
Page 259 and 260:
Page 261 and 262:
Page 263 and 264:
Page 265 and 266:
Page 267 and 268:
Page 269 and 270:
Page 271 and 272:
Page 273 and 274:
Page 275 and 276:
Page 277 and 278:
Page 279 and 280:
Page 281 and 282:
Chapter 9 CFD-based Optimization fo
Page 283 and 284:
9 CFD-based optimization for paperm
Page 285 and 286:
Page 287 and 288:
Page 289 and 290:
Page 291 and 292:
Page 293 and 294:
Page 295 and 296:
Page 297 and 298:
Page 299 and 300:
Page 301 and 302:
Page 303:
Page 306 and 307:
292 Index heat exchanger, 222, 224,
show all

Optimization and Computational Fluid Dynamics - Department of ...

You also want an ePaper? Increase the reach of your titles

Delete template?

Save as template?