To solve a design problem, sometimes it is necessary to identify the feasible design space. For design spaces with implicit constraints, sampling methods are usually used. These methods typically bound the design space; that is, limit the range of design variables. But bounds that are too small will fail to cover all possible designs, while bounds that are too large will waste sampling budget. This paper tries to solve the problem of efficiently discovering (possibly disconnected) feasible domains in an unbounded design space. We propose a data-driven adaptive sampling technique—ε-margin sampling, which learns the domain boundary of feasible designs and also expands our knowledge on the design space as available budget increases. This technique is data-efficient, in that it makes principled probabilistic trade-offs between refining existing domain boundaries versus expanding the design space. We demonstrate that this method can better identify feasible domains on standard test functions compared to both random and active sampling (via uncertainty sampling). However, a fundamental problem when applying adaptive sampling to real world designs is that designs often have high dimensionality and thus require (in the worst case) exponentially more samples per dimension. We show how coupling design manifolds with ε-margin sampling allows us to actively expand high-dimensional design spaces without incurring this exponential penalty. We demonstrate this on real-world examples of glassware and bottle design, where our method discovers designs that have different appearance and functionality from its initial design set.
Issue Section:
D3 Methods
References
1.
Yannou
, B.
, Moreno
, F.
, Thevenot
, H. J.
, and Simpson
, T. W.
, 2005
, “Faster Generation of Feasible Design Points
,” ASME
Paper No. DETC2005-85449. 2.
Devanathan
, S.
, and Ramani
, K.
, 2010
, “Creating Polytope Representations of Design Spaces for Visual Exploration Using Consistency Techniques
,” ASME J. Mech. Des.
, 132
(8
), p. 081011
.3.
Larson
, B. J.
, and Mattson
, C. A.
, 2012
, “Design Space Exploration for Quantifying a System Model's Feasible Domain
,” ASME J. Mech. Des.
, 134
(4
), p. 041010
.4.
Lee
, T. H.
, and Jung
, J. J.
, 2008
, “A Sampling Technique Enhancing Accuracy and Efficiency of Metamodel-Based RBDO: Constraint Boundary Sampling
,” Comput. Struct.
, 86
(13
), pp. 1463
–1476
.5.
Zhuang
, X.
, and Pan
, R.
, 2012
, “A Sequential Sampling Strategy to Improve Reliability-Based Design Optimization With Implicit Constraint Functions
,” ASME J. Mech. Des.
, 134
(2
), p. 021002
.6.
Huang
, Y.-C.
, and Chan
, K.-Y.
, 2010
, “A Modified Efficient Global Optimization Algorithm for Maximal Reliability in a Probabilistic Constrained Space
,” ASME J. Mech. Des.
, 132
(6
), p. 061002
.7.
Ren
, Y.
, and Papalambros
, P. Y.
, 2011
, “A Design Preference Elicitation Query as an Optimization Process
,” ASME J. Mech. Des.
, 133
(11
), p. 111004
.8.
Chen
, W.
, Fuge
, M.
, and Chazan
, J.
, 2017
, “Design Manifolds Capture the Intrinsic Complexity and Dimension of Design Spaces
,” ASME J. Mech. Des.
, 139
(5
), p. 051102
.9.
Chen
, W.
, Chazan
, J.
, and Fuge
, M.
, 2016
, “How Designs Differ: Non-Linear Embeddings Illuminate Intrinsic Design Complexity
,” ASME
Paper No. DETC2016-60112. 10.
Regier
, J. C.
, and Stark
, P. B.
, 2015
, “Mini-Minimax Uncertainty Quantification for Emulators
,” SIAM/ASA J. Uncertainty Quantif.
, 3
(1
), pp. 686
–708
.11.
Rasmussen
, C.
, and Williams
, C.
, 2006
, Gaussian Processes for Machine Learning
, MIT Press
, Cambridge, MA.12.
Williams
, C. K.
, and Barber
, D.
, 1998
, “Bayesian Classification With Gaussian Processes
,” IEEE Trans. Pattern Anal. Mach. Intell.
, 20
(12
), pp. 1342
–1351
.13.
Minka
, T. P.
, 2001
, “A Family of Algorithms for Approximate Bayesian Inference
,” Ph.D. thesis
, Massachusetts Institute of Technology, Cambridge, MA. 14.
Hastings
, W. K.
, 1970
, “Monte Carlo Sampling Methods Using Markov Chains and Their Applications
,” Biometrika
, 57
(1
), pp. 97
–109
.15.
Settles
, B.
, 2009, “Active Learning Literature Survey
,” University of Wisconsin–Madison, Madison, WI, Report No. 1648
.16.
Lewis
, D. D.
, and Catlett
, J.
, 2012
, “Heterogeneous Uncertainty Sampling for Supervised Learning
,” 11th International Conference on Machine Learning
and Applications (ICMLA
), Boca Raton, FL, Dec. 12–15, pp. 148
–156
.17.
Lewis
, D. D.
, and Gale
, W. A.
, 1994
, “A Sequential Algorithm for Training Text Classifiers
,” 17th Annual International ACM SIGIR Conference on Research and Development in Information Retrieval
, Dublin, Ireland, July 3–6, pp. 3
–12
.18.
Bryan
, B.
, Schneider
, J.
, Nichol
, R.
, Miller
, C.
, Genovese
, C. R.
, and Wasserman
, L.
, 2005
, “Active Learning for Identifying Function Threshold Boundaries
,” Advances in Neural Information Processing Systems 18, MIT Press, Cambridge, MA, pp. 163
–170
.19.
Kapoor
, A.
, Grauman
, K.
, Urtasun
, R.
, and Darrell
, T.
, 2007
, “Active Learning With Gaussian Processes for Object Categorization
,” IEEE 11th International Conference on Computer Vision
(ICCV
), Rio de Janeiro, Brazil, Oct. 14–21, pp. 1
–8
.20.
Kapoor
, A.
, Grauman
, K.
, Urtasun
, R.
, and Darrell
, T.
, 2010
, “Gaussian Processes for Object Categorization
,” Int. J. Comput. Vision
, 88
(2
), pp. 169
–188
.21.
Gotovos
, A.
, Casati
, N.
, Hitz
, G.
, and Krause
, A.
, 2013
, “Active Learning for Level Set Estimation
,” 23rd International Joint Conference on Artificial Intelligence
(IJCAI
), Beijing, China, Aug. 3–9, pp. 1344
–1350
.22.
Hoang
, T. N.
, Low
, B.
, Jaillet
, P.
, and Kankanhalli
, M.
, 2014
, “Nonmyopic ε-Bayes-Optimal Active Learning of Gaussian Processes
,” 31st International Conference on Machine Learning (ICML
), Beijing, China, June 21–26, pp. 739
–747
.23.
Schreiter
, J.
, Nguyen-Tuong
, D.
, Eberts
, M.
, Bischoff
, B.
, Markert
, H.
, and Toussaint
, M.
, 2015
, “Safe Exploration for Active Learning With Gaussian Processes
,” Joint European Conference on Machine Learning and Knowledge Discovery in Databases
, Porto, Portugal, Sept. 7–11, pp. 133
–149
.24.
Freytag
, A.
, Rodner
, E.
, Bodesheim
, P.
, and Denzler
, J.
, 2013
, “Labeling Examples That Matter: Relevance-Based Active Learning With Gaussian Processes
,” German Conference on Pattern Recognition
(GCPR
), Hannover, Germany, Sept. 12–15, pp. 282
–291
.25.
Freytag
, A.
, Rodner
, E.
, and Denzler
, J.
, 2014
, “Selecting Influential Examples: Active Learning With Expected Model Output Changes
,” European Conference on Computer Vision
(ECCV
), Amsterdam, The Netherlands, Oct. 8–16, pp. 562
–577
.26.
Basudhar
, A.
, and Missoum
, S.
, 2010
, “An Improved Adaptive Sampling Scheme for the Construction of Explicit Boundaries
,” Struct. Multidiscip. Optim.
, 42
(4
), pp. 517
–529
.27.
Basudhar
, A.
, Dribusch
, C.
, Lacaze
, S.
, and Missoum
, S.
, 2012
, “Constrained Efficient Global Optimization With Support Vector Machines
,” Struct. Multidiscip. Optim.
, 46
(2
), pp. 201
–221
.28.
Singh
, P.
, van der Herten
, J.
, Deschrijver
, D.
, Couckuyt
, I.
, and Dhaene
, T.
, 2017
, “A Sequential Sampling Strategy for Adaptive Classification of Computationally Expensive Data
,” Struct. Multidiscip. Optim.
, 55
(4
), pp. 1425
–1438
.29.
Bouneffouf
, D.
, Laroche
, R.
, Urvoy
, T.
, Féraud
, R.
, and Allesiardo
, R.
, 2014
, “Contextual Bandit for Active Learning: Active Thompson Sampling
,” International Conference on Neural Information Processing
(ICONIP
), Kyoto, Japan, Oct. 16–21, pp. 405
–412
.30.
Hsu
, W.-N.
, and Lin
, H.-T.
, 2015
, “Active Learning by Learning
,” 29th Conference on Association for the Advancement of Artificial Intelligence (AAAI
), Austin, TX, Jan. 25–30, pp. 2659
–2665
.31.
Bellman
, R.
, 1957
, Dynamic Programming
, Princeton University Press
, Princeton, NJ.32.
Averkiou
, M.
, Kim
, V. G.
, Zheng
, Y.
, and Mitra
, N. J.
, 2014
, “ShapeSynth: Parameterizing Model Collections for Coupled Shape Exploration and Synthesis
,” Comput. Graphics Forum
, 33
(2
), pp. 125
–134
.33.
Yumer
, M. E.
, Asente
, P.
, Mech
, R.
, and Kara
, L. B.
, 2015
, “Procedural Modeling Using Autoencoder Networks
,” 28th Annual ACM Symposium on User Interface Software & Technology
(UIST
), Charlotte, NC, Nov. 11–15, pp. 109
–118
.34.
Burnap
, A.
, Liu
, Y.
, Pan
, Y.
, Lee
, H.
, Gonzalez
, R.
, and Papalambros
, P. Y.
, 2016
, “Estimating and Exploring the Product Form Design Space Using Deep Generative Models
,” ASME
Paper No. DETC2016-60091. 35.
Yumer
, M. E.
, Chaudhuri
, S.
, Hodgins
, J. K.
, and Kara
, L. B.
, 2015
, “Semantic Shape Editing Using Deformation Handles
,” ACM Trans. Graphics
, 34
(4
), pp. 86:1
–86:12
.36.
Van Der Maaten
, L.
, Postma
, E.
, and Van den Herik
, J.
, 2009
, “Dimensionality Reduction: A Comparative
Review,” Tilburg University, Tilburg, The Netherlands, Technical Report No. TiCC-TR 2009-005
.37.
Bengio
, Y.
, Courville
, A.
, and Vincent
, P.
, 2013
, “Representation Learning: A Review and New Perspectives
,” IEEE Trans. Pattern Anal. Mach. Intell.
, 35
(8
), pp. 1798
–1828
.38.
Rodrigues
, F.
, Pereira
, F.
, and Ribeiro
, B.
, 2014
, “Gaussian Process Classification and Active Learning With Multiple Annotators
,” 31st International Conference on Machine Learning
(ICML
), Beijing, China, June 21–26, pp. 433
–441
. 39.
Sharmanska
, V.
, Hernández-Lobato
, D.
, Miguel Hernandez-Lobato
, J.
, and Quadrianto
, N.
, 2016
, “Ambiguity Helps: Classification With Disagreements in Crowdsourced Annotations
,” IEEE Conference on Computer Vision and Pattern Recognition
(CVPR
), Las Vegas, NV, June 27–30, pp. 2194
–2202
. Copyright © 2017 by ASME
You do not currently have access to this content.
