Preliminary design of a complex system often involves exploring a broad design space. This may require repeated use of computationally expensive simulations. To ease the computational burden, surrogate models are built to provide rapid approximations of more expensive models. However, the surrogate models themselves are often expensive to build because they are based on repeated experiments with computationally expensive simulations. An alternative approach is to replace the detailed simulations with simplified approximate simulations, thereby sacrificing accuracy for reduced computational time. Naturally, surrogate models built from these approximate simulations are also imprecise. A strategy is needed for improving the precision of surrogate models based on approximate simulations without significantly increasing computational time. In this paper, a new approach is taken to integrate data from approximate and detailed simulations to build a surrogate model that describes the relationship between output and input parameters. Experimental results from approximate simulations form the bulk of the data, and they are used to build a model based on a Gaussian process. The fitted model is then “adjusted” by incorporating a small amount of data from detailed simulations to obtain a more accurate prediction model. The effectiveness of this approach is demonstrated with a design example involving cellular materials for an electronics cooling application. The emphasis is on the method and not on the results per se.
Issue Section:
Research Papers
1.
Wu
, C. F. J.
, and Hamada
, M.
, 2000, Experiments, Planning, Analysis and Parameter Design Optimization
, Wiley
, New York
.2.
Montgomery
, D. C.
, 1997, Design and Analysis of Experiments
, 4th ed., Wiley
, New York
.3.
Chen
, W.
, Allen
, J. K.
, Tsui
, K.-L.
, and Mistree
, F.
, 1996, “A Procedure for Robust Design
,” ASME J. Mech. Des.
1050-0472, 118
(4
), pp. 478
–485
.4.
Seepersad
, C. C.
, Dempsey
, B. M.
, Allen
, J. K.
, Mistree
, F.
, and McDowell
, D. L.
, 2004, “Design of Multifunctional Honeycomb Materials
,” AIAA J.
0001-1452, 42
(5
), pp. 1025
–1033
.5.
Michelena
, N.
, Park
, H.
, and Papalambros
, P.
, 2002, “Convergence Properties of Analytical Target Cascading
,” AIAA J.
0001-1452, 41
(5
), pp. 897
–905
.6.
Myers
, R. H.
, and Montgomery
, D. C.
, 1995, Response Surface Methodology: Process and Product Optimization Using Designed Experiments
, Wiley Series in Probability and Statistics
, Wiley
, New York
.7.
Matherton
, G.
, 1963, “Principles of Geostatistics
,” Econ. Geol.
0361-0128, 58
, pp. 1246
–1266
.8.
Cressie
, N.
, 1988, “Geostatistics
,” Am. Stat.
0003-1305, 43
(4
), pp. 197
–202
.9.
Laslett
, G. M.
, 1994, “Kriging and Splines: An Empirical Comparison of Their Predictive Performance in Some Applications
,” J. Am. Stat. Assoc.
0162-1459, 89
, pp. 391
–400
.10.
Simpson
, T. W.
, Peplinski
, J. D.
, Koch
, P. N.
, and Allen
, J. K.
, 2001, “Metamodels for Computer-Based Engineering Design
,” Eng. Comput.
0264-4401 (Special issue in honor of Professor S. J. Fenves), 17
, pp. 129
–150
.11.
Wujek
, B. A.
, and Renaud
, J. E.
, 1998, “New Adaptive Move-Limit Management Strategy for Approximate Optimization. Part 1
,” AAIAA J.
0001-1452, 36
(10
), pp. 1911
–1921
.12.
Wujek
, B. A.
, and Renaud
, J. E.
, 1998, “New Adaptive Move-Limit Management Strategy for Approximate Optimization: Part 2
,” AIAA J.
0001-1452, 36
(10
), pp. 1922
–1934
.13.
Rodriguez
, J. F.
, Perez
, V. M.
, Padmanabhan
, D.
, and Renaud
, J. E.
, 2001, “Sequential Approximate Optimization Using Variable Fidelity Response Surface Approximations
,” Struct. Multidiscip. Optim.
1615-147X, 22
, pp. 24
–34
.14.
Akexandrov
, N.
, Dennis
, J. E. J.
, Lewis
, R. M.
, and Torczon
, V.
, 1998, “A Trust Region Framework for Managing the Use of Approximation Models in Optimization
,” Struct. Optim.
0934-4373, 15
(1
), pp. 16
–23
.15.
Chen
, W.
, Allen
, J. K.
, Schrage
, D. P.
, and Mistree
, F.
, 1997, “Statistical Experimentation Methods for Achieving Affordable Concurrent Systems Design
,” AIAA J.
0001-1452, 35
(5
), pp. 893
–900
.16.
Toropov
, V.
, van Keulen
, F.
, Markine
, V.
, and de Doer
, H.
, 1996, “Refinements in the Multi-Point Approximation Method to Reduce the Effects of Noisy Structural Response
,” in 6th AIAA/USAF/NASA/ISSMO Symposium on Multidisciplinary Analysis and Optimization
, Bellevue, WA, AIAA J.0001-1452, 2
, pp. 941
–951
.17.
Wang
, G.
, Dong
, Z.
, and Atchison
, P.
, 2001, “Adaptive Response Surface Method—a Global Optimization Scheme for Computation-Intensive Design Problems
,” Eng. Optimiz.
0305-215X, 33
(6
), pp. 707
–734
.18.
Wang
, G.
, 2003, “Adaptive Response Surface Method Using Inherited Latin Hypercube Designs
,” ASME J. Mech. Des.
1050-0472, 125
(2
), pp. 210
–220
.19.
Farhang-Mehr
, A.
, and Azarm
, S.
, 2003, “An Information-Theoretic Entropy Metric for Assessing Multiobjective Optimization Solution Set Quality
,” ASME J. Mech. Des.
1050-0472, 125
(4
), pp. 655
–663
.20.
Lin
, Y.
, Mistree
, F.
, and Allen
, J. K.
, 2004, “A Sequential Exploratory Experimental Design Method: Development of Appropriate Empirical Models in Design
,” in ASME Design Engineering Technical Conferences—Advances in Design Automation Conference
, Salt Lake City, UT
, ASME, Paper No. DETC2004/DAC-57527, (September 28 to October 2, 2004).21.
Wang
, G. G.
, and Simpson
, T. W.
, 2004, “Fuzzy Clustering Based Hierarchical Metamodeling for Design Space Reduction and Optimization
,” Eng. Optimiz.
0305-215X, 36
(3
), pp. 313
–335
.22.
Box
, G. E. P.
, and Draper
, N. R.
, 1969, Evolutionary Operation: A Statistical Method for Process Management
, Wiley
, New York
.23.
Koch
, P. N.
, Simpson
, T. W.
, Allen
, J. K.
, and Mistree
, F.
, 1999, “Statistical Approximations for Multidisciplinary Optimization: The Problem of Size
,” J. Aircr.
0021-8669, 36
(1
), pp. 275
–286
.24.
Watson
, G. S.
, 1961, “A Study of the Group Screening Method
,” Technometrics
0040-1706, 3
(3
), pp. 371
–388
.25.
Bettonvil
, B.
, 1990, Detection of Important Factors by Sequential Bifurcation
, Tilburg University Press
, Tilburg, The Netherlands
.26.
Bettonvil
, B.
, and Kleijnen
, J. J. C.
, 1996, “Searching for Important Factors in Simulation Models With Many Factors: Sequential Bifurcation
,” Eur. J. Oper. Res.
0377-2217, 96
(1
), pp. 180
–194
.27.
Wu
, C. F. J.
, 1993, “Construction of Supersaturated Designs through Partially Aliased Interactions
,” Biometrika
0006-3444, 80
(3
), pp. 661
–669
.28.
Holcomb
, D. R.
, Montgomery
, D. C.
, and Carlyle
, W. M.
, 2003, “Analysis of Supersaturated Designs
,” J. Quality Technol.
0022-4065, 35
(1
), pp. 13
–27
.29.
Qian
, A.
, Seepersad
, C. C.
, Joseph
, V. R.
, Wu
, C. F. J.
, and Allen
, J. K.
, 2004, “Building Surrogate Models Based on Detailed and Approximate Simulations
,” in ASME Design Engineering Technical Conferences—Advances in Design Automation Conference
, Salt Lake City, UT
, ASME, Paper No. DETC2004/57486.30.
Osio
, I. C.
, and Amon
, C. H.
, 1996, “An Engineering Design Methodology With Multistage Bayesian Surrogates and Optimal Sampling
,” Res. Eng. Des.
0934-9839, 8
, pp. 189
–206
.31.
Pacheco
, J. E.
, Amon
, C. H.
, and Finger
, S.
, 2003, “Bayesian Surrogates Applied to Conceptual Stages of the Engineering Design Process
,” ASME J. Mech. Des.
1050-0472, 125
, pp. 664
–672
.32.
Bandler
, J.
, Cheng
, Q.
, Dakroury
, S.
, Mohamed
, A.
, Bakr
, M.
, Madsen
, K.
, and Sndergaard
, J.
, 2004, “Space Mapping: The State of The Art
,” IEEE Trans. Microwave Theory Tech.
0018-9480, 52
, pp. 337
–361
.33.
Bakr
, M. H.
, Bandler
, J. W.
, Madsen
, K.
, and Sndergaard
, J.
, 2000, “Review of the Space Mapping Approach to Engineering Optimization and Modeling
,” Optim. Eng.
1389-4420, 1
, pp. 241
–276
.34.
Santner
, T. J.
, Williams
, B. J.
, and Notz
, W. I.
, 2003, The Design and Analysis of Computer Experiments
, Springer
, New York
.35.
Simpson
, T. W.
, Mauery
, T. M.
, Korte
, J. J.
, and Mistree
, F.
, 2001, “Kriging Models for Global Approximation in Simulation-Based Multidisciplinary Design Optimization
,” AIAA J.
0001-1452, 39
(12
), pp. 2233
–2241
.36.
Welch
, W. J.
, Buck
, R. J.
, Sacks
, J.
, Wynn
, H. P.
, Mitchell
, T. J.
, and Morris
, M. D.
, 1992, “Screening, Predicting and Computer Experiments
,” Technometrics
0040-1706, 34
, pp. 15
–25
.37.
Byrd
, R. H.
, Lu
, P.
, Nocedal
, J.
, and Zhu
, C.
, 1995, “A Limited Memory Algorithm for Bound Constrained Optimization
,” SIAM J. Sci. Comput. (USA)
1064-8275, 16
, pp. 1190
–1208
.38.
R Development Core Team
, 2004, “R: A Language and Environment for Statistical Computing
,” http://www.Rproject.orghttp://www.Rproject.org.39.
Handcock
, M. S.
, and Stein
, M. L.
, 1993, “A Bayesian Analysis of Kriging
,” Technometrics
0040-1706, 35
(4
), pp. 403
–410
.40.
Handcock
, M. S.
, and Wallis
, J. R.
, 1994, “An Approach to Statistical Spatial-Temporal Modeling of Meteorological Fields
,” J. Am. Stat. Assoc.
0162-1459, 89
, pp. 386
–378
.41.
Cochran
, J. K.
, Lee
, K. J.
, McDowell
, D. L.
, and Sanders
, T. H.
, 2000, “Low Density Monolithic Honeycombs by Thermal Chemical Processing
,” in Proceedings of the 4th Conference on Aerospace Materials, Processes, and Environmental Technology
, Huntsville, AL
, (September 18-20, 2000, NASA
, Washington, DC
).42.
Gibson
, L. J.
, and Ashby
, M. F.
, 1997, Cellular Solids: Structure and Properties
, Cambridge University Press
, Cambridge, UK
.43.
Hayes
, A. M.
, Wang
, A.
, Dempsey
, B. M.
, and McDowell
, D. L.
, 2001, “Mechanics of Linear Cellular Alloys
,” Mech. Mater.
0167-6636, 36
, pp. 691
–713
.44.
Evans
, A. G.
, Hutchinson
, J. W.
, Fleck
, N. A.
, Ashby
, M. F.
, and Wadley
, H. N. G.
, 2001, “The Topological Design of Multifunctional Cellular Materials
,” Prog. Mater. Sci.
0079-6425, 46
(3,4
), pp. 309
–327
.45.
FLUENT, 1998,
Fluent, Inc.
, Release 5.5.14 (3d, segregated, laminar).46.
Incropera
, F. P.
, and DeWitt
, D. P.
, 1996, Fundamentals of Heat and Mass Transfer
, 3rd ed., Wiley
, New York
.Copyright © 2006
by American Society of Mechanical Engineers
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