Using Modeling Knowledge to Guide Design Space Search

Gelsey, Andrew; Schwabacher, Mark; Smith, Delia E.

doi:10.1007/978-94-009-0279-4_20

Cited by 16 publications

(8 citation statements)

References 15 publications

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“…We observed that the problems related to designing a hybrid propulsion system were similar for both companies, but were framed in different ways. We used the concepts of design space and degree of granularization as problem framing measures (Gelsey et al., 1998; Smith and MacLean, 2007; Stankiewicz, 2000), and to make sense of the differences between projects: Figure 1 shows that the designs for the new hybrid propulsion systems in Projects T and M were based on combinations of different sets of components and subcomponents. Project M's design involved combination of six large components; Project T's involved 15 components.…”

Section: Methodology and Data Analysismentioning

confidence: 99%

“…In this paper, we use the degree of granularization of the design space as the focal measure for problem framing. Granularization is the decomposition of a given problem into coarse or fine sub‐problems (Gelsey et al., 1998; Smith and MacLean, 2007; Stankiewicz, 2000). This variable has been shown to be a reliable lens through which to study problem framing, within a vast literature spanning technology management (see, e.g.…”

Section: Literature Review and Research Questionsmentioning

confidence: 99%

“…Stankiewicz, 2000), human–computer interaction (see, e.g. Smith and MacLean, 2007), and artificial intelligence (Gelsey et al., 1998). Granularization is a useful lens because it provides an immediate link to new product development conceived of ‘combinatory of elementary cognitive and physical components’ (Dosi and Grazzi, 2006, p. 179).…”

Section: Literature Review and Research Questionsmentioning

confidence: 99%

“…Our research identifies three organizational/strategic variables that affect problem framing and, in particular, the degree of granularization of the design space, i.e. whether the ‘problem’ is decomposed into many small or a few large sub‐problems (Gelsey et al., 1998; Smith and MacLean, 2007; Stankiewicz, 2000).…”

Section: Introductionmentioning

confidence: 99%

See 3 more Smart Citations

Virtual Design, Problem Framing, and Innovation: An Empirical Study in the Automotive Industry

Vaccaro¹,

Brusoni²,

Veloso³

2010

Journal of Management Studies

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This paper studies how problem framing by research and development groups, in particular the extent of problem decomposition, impacts knowledge replication processes conducted through the use of virtual simulation tools (VSTs). It presents the results of a comparative study of two research and development groups working on the design of hybrid propulsion systems. The research contributes to the literature on strategy and innovation in four ways. First, we identify three organizational and strategic factors affecting the problem framing decision. Second, we analyse the impact of problem framing on the use of VSTs and the related effect on knowledge replication processes. Third, we show the emergence of a new VST-driven knowledge replication process, i.e. functional replication. Fourth, we explain how VST‐driven knowledge replication processes can attenuate the dangers related to the adoption of modular design strategies and address the replication vs. imitation dilemma.

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Section: Methodology and Data Analysismentioning

confidence: 99%

Section: Literature Review and Research Questionsmentioning

confidence: 99%

Section: Literature Review and Research Questionsmentioning

confidence: 99%

Section: Introductionmentioning

confidence: 99%

See 2 more Smart Citations

Virtual Design, Problem Framing, and Innovation: An Empirical Study in the Automotive Industry

Vaccaro¹,

Brusoni²,

Veloso³

2010

Journal of Management Studies

View full text Add to dashboard Cite

show abstract

“…The development of artificial intelligence (AI) algorithms to automate design problem reformulation tasks is an enduring challenge in design automation. Existing methods either require dependence upon high levels of embedded knowledge engineering in the form of rules, heuristics, grammars, or domain/taskspecific procedures (e.g., Ellman et al, 1998;Gelsey et al, 1998;Medland & Mullineux, 2000;Campbell et al, 2003) or require a large database of training cases (e.g., Duffy & Kerr, 1993;Schwabacher et al, 1998). It would be useful to develop a method characterized by the following desirable features: a knowledge-lean method that does not need any significant design domain or task knowledge to be embedded into the system; a training-lean method that can extract design knowledge over one or very few cases; and a simple and computationally efficient method applicable over different design domains, representational forms (analytical, nonanalytical, etc.…”

Section: Introductionmentioning

confidence: 99%

Learning symbolic formulations in design: Syntax, semantics, and knowledge reification

Sarkar

Dong

Gero

2010

AIEDAM

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An artificial intelligence (AI) algorithm to automate symbolic design reformulation is an enduring challenge in design automation. Existing research shows that design tools either require high levels of knowledge engineering or large databases of training cases. To address these limitations, we present a singular value decomposition (SVD) and unsupervised clustering-based method that performs design reformulation by acquiring semantic knowledge from the syntax of design representations. The development of the method was analogically inspired by applications of SVD in statistical natural language processing and digital image processing. We demonstrate our method on an analytically formulated hydraulic cylinder design problem and an aeroengine design problem formulated using a nonanalytic design structure matrix form. Our results show that the method automates various design reformulation tasks on problems of varying sizes from different design domains, stated in analytic and nonanalytic representational forms. The behavior of the method presents observations that cannot be explained by pure symbolic AI approaches, including uncovering patterns of implicit knowledge that are not readily encoded as logical rules, and automating tasks that require the associative transformation of sets of inputs to experiences. As an explanation, we relate the structure and performance of our algorithm with findings in cognitive neuroscience, and present a set of theoretical postulates addressing an alternate perspective on how symbols may interact with each other in experiences to reify semantic knowledge in design representations.

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Automated optimal design using CFD and high performance computing

Knight

1997

Vector and Parallel Processing — VECPAR'96

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Using Modeling Knowledge to Guide Design Space Search

Cited by 16 publications

References 15 publications

Virtual Design, Problem Framing, and Innovation: An Empirical Study in the Automotive Industry

Virtual Design, Problem Framing, and Innovation: An Empirical Study in the Automotive Industry

Learning symbolic formulations in design: Syntax, semantics, and knowledge reification

Automated optimal design using CFD and high performance computing

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