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Research in Engineering Design

Erschienen in:

01.04.2012 | Original Paper

From user requirements to commonality specifications: an integrated approach to product family design

verfasst von: Timothy W. Simpson, Aaron Bobuk, Laura A. Slingerland, Sean Brennan, Drew Logan, Karl Reichard

Erschienen in: Research in Engineering Design | Ausgabe 2/2012

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Abstract

Many companies design families of products based on product platforms that enable economies of scale and scope while satisfying a variety of market applications. Product family design is a difficult and challenging task, and a variety of methods and tools have been created to support this platform-based product development. Unfortunately, many of these methods and tools have been developed—and consequently exist—in isolation from one other. In this paper, we introduce an approach to integrate several of these disparate tools into a framework to translate user needs and requirements into commonality specifications during product family design. The novelty of the approach lies in how we integrate the market segmentation grid, Generational Variety Index (GVI), Design Structure Matrix (DSM), commonality indices, mathematical modeling and optimization, and multi-dimensional data visualization tools to identify what to make common, what to make unique, and what parameter settings are best for each component and/or subsystem in the product family. The design of a family of unmanned ground vehicles (UGVs) demonstrates the proposed approach and highlights its benefits and limitations.

Vorheriger Artikel Transfer of knowledge from the service phase: a case study from the oil industry

Nächster Artikel Detecting mistakes in engineering models: the effects of experimental design

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Aboulafia R (2000) Airbus pulls closer to Boeing. Aerosp Am 38(4):16–18

Balling R (1999) Design by shopping: a new paradigm? In: Proceedings of the 3rd world congress of structural and multidisciplinary optimization (WCSMO-3), University at Buffalo, Buffalo, NY, pp 295–297

Bhandare S, Allada V (2009) Scalable product family design: case study of axial piston pumps. Int J Prod Res 47(3):585–620MATHCrossRef

Bobuk A (2010) A design method for product family trade studies utilizing GVI and PFPF metrics with application to robot ground vehicles, mechanical & nuclear engineering. M.S. Thesis, Penn State University, University Park, PA

Braha D, Maimon O (1998) The measurement of design structural and functional complexity. IEEE Trans Syst Man Cybern A Syst Hum 28(4):527–535CrossRef

Browning TR (2001) Applying the design structure matrix to system decomposition and integration problems: a review and new directions. IEEE Trans Eng Manag 48(3):292–306CrossRef

Clarkson PJ, Simons C, Eckert C (2004) Predicting change propagation in complex design. ASME J Mech Des 126(5):788–797CrossRef

Collier DA (1981) The measurement and operating benefits of component part commonality. Decis Sci 12(1):85–96CrossRef

Collier DA (1982) Aggregate safety stock levels and component part commonality. Manag Sci 28(22):1296–1303CrossRef

Dahmus JB, Gonzalez-Zugasti JP, Otto KN (2001) Modular product architecture. Des Stud 22(5):409–424CrossRef

Dai Z, Scott MJ (2007) Product platform design through sensitivity analysis and cluster analysis. J Intell Manuf 18(1):97–113CrossRef

De Lit P, Delchambre A (2003) Integrated design of a product family and its assembly system. Kluwer, BostonCrossRef

de Weck O (2005) Determining product platform extent. In: Simpson TW, Siddique Z, Jiao J (eds) Product platform and product family design: methods and applications. Springer, New York, pp 241–301

Donaldson B (2010) Application of product family design tools to unmanned ground vehicles, mechanical & nuclear engineering. M.S. Thesis, Penn State University, University Park, PA

Eckert C, Clarkson PJ, Zanker W (2004) Change and customisation in complex engineering domains. Res Eng Des 15(1):1–21CrossRef

Farrell RS, Simpson TW (2008) A method to improve platform leveraging in a market segmentation grid for an existing product line. ASME J Mech Des 130(3):031403 (11 pp)CrossRef

Fisher ML, Ramdas K, Ulrich KT (1999) Component sharing in the management of product variety: a study of automotive braking systems. Manag Sci 45(3):297–315CrossRef

Fixson SK (2007) Modularity and commonality research: past developments and future opportunities. Concurr Eng Res Appl 15(2):85–111CrossRef

Fujita K (2002) Product variety optimization under modular architecture. Comput Aided Des 34(12):953–965CrossRef

Gershenson JK, Prasad GJ, Zhang Y (2003) Product modularity: measures and design methods. J Eng Des 15(1):33–51CrossRef

Hauser JR, Clausing D (1988) The house of quality. Harv Bus Rev 66(3):63–73

Helmer R, Yassine A, Meier C (2010) Systematic module and interface definition using component design structure matrix. J Eng Des 21(6):647–675CrossRef

Hölttä-Otto K, de Weck O (2007) Metrics for assessing coupling density and modularity in complex products and systems. ASME design engineering technical conferences—design theory & methodology conference, Las Vegas, NV, ASME, paper no. DETC2007/DTM-34871

Huang C–C, Kusiak A (1998) Modularity in design of products and systems. IEEE Trans Syst Man Cybern A Syst Hum 28(1):66–77CrossRef

Jiao R, Zhang L, Pokharel S (2005) Process Platform and Production Configuration for Product Families. In: Simpson TW, Siddique Z, Jiao J (eds) Product platform and product family design: methods and applications. Springer, New York, pp 377–402

Jiao J, Simpson TW, Siddique Z (2007a) Product family design and platform-based product development: a state-of-the-art review. J Intell Manuf 18(1):5–29CrossRef

Jiao J, Zhang Y, Wang Y (2007b) A generic genetic algorithm for product family design. J Intell Manuf 18(2):233–247CrossRef

Kalligeros KC, de Weck O, de Neufville R, Luckins A (2006) Platform identification using design structure matrices. In: 16th Annual international symposium of the international council on systems engineering (INCOSE), Orlando, FL

Khajavirad A, Michalek J (2007) An extension of the commonality index for product family optimization. In: ASME design engineering technical conferences—design automation conference, ASME, Las Vegas, NV, DETC2007/DAC-35605

Khajavirad A, Michalak JJ, Simpson TW (2009) An efficient decomposed multiobjective genetic algorithm for solving the joint product platform selection and product family design problem with generalized commonality. Struct Multidiscip Optim 39(2):187–201CrossRef

Kim K, Chhajed D (2000) Commonality in product design: cost saving, valuation change and cannibalization. Eur J Oper Res 125(3):602–621MATHCrossRef

Kota S, Sethuraman K, Miller R (2000) A metric for evaluating design commonality in product families. ASME J Mech Des 122(4):403–410CrossRef

Kumar R, Allada V (2007) Ant colony optimization methods for product platform formation. J Intell Manuf 18(1):127–142CrossRef

Kumar D, Chen W, Simpson TW (2009) A market-driven approach to product family design. Int J Prod Res 47(1):71–104CrossRef

Kusiak A, Larson N (1995) Decomposition and representation methods in mechanical design. J Mech Des (Special 50th Anniversary Design Issue) 117(2):17–24

Li H, Azarm S (2002) An approach for product line design selection under uncertainty and competition. ASME J Mech Des 124(3):385–392CrossRef

Logan D (2010) Optimization of hybrid power sources for mobile robotics through the use of allometric design principles and dynamic programming, mechanical & nuclear engineering. M.S. Thesis, Penn State University, University Park, PA

Marion TJ, Simpson TW (2005) Platform Leveraging Strategies and Market Segmentation. In: Simpson TW, Siddique Z, Jiao J (eds) Product platform and product family design: methods and applications. Springer, New York, pp 73–90

Marion TJ, Simpson TW (2009) New product development practice application to an early-stage firm: the case of the PaperPro^® Stackmaster^TM. Des Stud 30(5):561–587CrossRef

Martin MV, Ishii K (2002) Design for variety: developing standardized and modularized product platform architectures. Res Eng Des 13(4):213–235

Messac A, Martinez MP, Simpson TW (2002) A penalty function for product family design using physical programming. ASME J Mech Des 124(2):164–172CrossRef

Meyer MH, Lehnerd AP (1997) The power of product platforms: building value and cost leadership. Free Press, New York

Michalek JJ, Ceryan O, Papalambros PY, Koren Y (2006) Balancing marketing and manufacturing objectives in product line design. ASME J Mech Des 128(6):1196–1204CrossRef

Moon SK, Kumara SRT, Simpson TW (2006) Data mining and fuzzy clustering to support product family design. In: ASME design engineering technical conferences—design automation conference, ASME, Philadelphia, PA, paper no. DETC2006/DAC-99287

Rai R, Allada V (2003) Modular product family design: agent-based pareto-optimization and quality loss function-based post-optimal analysis. Int J Prod Res 41(17):4075–4098CrossRef

Robertson D, Ulrich K (1998) Planning product platforms. Sloan Manag Rev 39(4):19–31

Rothwell R, Gardiner P (1990) Robustness and Product Design Families. In: Oakley M (ed) Design management: a handbook of issues and methods. Basil Blackwell Inc, Cambridge, pp 279–292

Sabbagh K (1996) Twenty-first century jet: the making and marketing of the Boeing 777. Scribner, New York

Sharman DM, Yassine AA (2004) Characterizing complex product architectures. Syst Eng 7(1):35–60CrossRef

Simpson TW (2004) Product platform design and customization: status and promise. Artif Intell Eng Des Anal Manuf 18(1):3–20

Simpson TW (2005) Methods for optimizing product platforms and product families: overview and classification. In: Simpson TW, Siddique Z, Jiao J (eds) Product platform and product family design: methods and applications. Springer, New York, pp 133–156

Simpson TW, D’Souza B (2004) Assessing variable levels of platform commonality within a product family using a multiobjective genetic algorithm. Concurr Eng Res Appl 12(2):119–130CrossRef

Simpson TW, Siddique Z, Jiao J (eds) (2005) Product platform and product family design: methods and applications. Springer, New York

Simpson TW, Marion TJ, de Weck O, Holtta-Otto K, Kokkolaras M, Shooter SB (2006) Platform-based design and development: current trends and needs in industry. In: ASME design engineering technical conferences—design automation conference, ASME, Philadelphia, PA, paper no. DETC2006/DAC-99229

Sosa ME, Eppinger SD, Rowles CM (2003) Identifying modular and integrative systems and their impact on design team interactions. ASME J Mech Des 125(2):240–252CrossRef

Steward AD (1981) The design structure system: a method for managing the design of complex systems. IEEE Trans Soft Eng 28(3):71–74

Stump G, Lego S, Yukish M, Simpson TW, Donndelinger JA (2009) Visual steering commands for trade space exploration: user-guided sampling with example. ASME J Comput Inf Sci Eng 9(4):044501 (10 pp)CrossRef

Sudjianto A, Otto KN (2001) Modularization to support multiple brand platforms. In: ASME design engineering technical conferences—design theory and methodology conference, ASME, Pittsburgh, PA, paper no. DETC2001/DTM-21695

Suh ES, de Weck OL, Kim IY, Chang D (2007) Flexible platform component design under uncertainty. J Intell Manuf 18(1):115–126CrossRef

Thevenot HJ, Simpson TW (2006) Commonality indices for product family design: a detailed comparison. J Eng Des 17(2):99–119CrossRef

Yu T-L, Yassine AA, Goldberg DE (2007) An information theoretic method for developing modular architectures using genetic algorithms. Res Eng Des 18(2):91–109MATHCrossRef

Zhang Y, Jiao J, Ma Y (2007) Market segmentation for product family positioning based on fuzzy clustering. J Eng Des 18(3):227–241CrossRef

Titel: From user requirements to commonality specifications: an integrated approach to product family design
verfasst von: Timothy W. Simpson
Aaron Bobuk
Laura A. Slingerland
Sean Brennan
Drew Logan
Karl Reichard
Publikationsdatum: 01.04.2012
Verlag: Springer-Verlag
Erschienen in: Research in Engineering Design / Ausgabe 2/2012
Print ISSN: 0934-9839
Elektronische ISSN: 1435-6066
DOI: https://doi.org/10.1007/s00163-011-0119-4

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