Significant recent research has focused on the marriage of consumer preferences and engineering design in order to improve profitability. The extant literature has neglected the effects of marketing channels, which are becoming increasingly important. At the crux of the issue is the fact that channel dominating retailers, like Wal-Mart, have the ability to unilaterally control manufacturer’s design decisions as gatekeepers to the consumers or market. In this paper, we propose a new methodology that accounts for this power asymmetry. A chance constrained optimization framework is used to model retailer acceptance of possible engineering designs and accounts for the important effect on the profitability of the retailer’s assortment through a latent class estimation of demand from conjoint surveys. Our approach allows the manufacturer to optimize a product design for its own profitability while reliably ensuring that the product will make it to market by making the retailer more profitable with the addition of the new product to the assortment. As a demonstrative example, we apply the proposed approach for product design selection in the case of an angle grinder. For this example, we analyze the market and are able to improve expected manufacturer profitability while simultaneously presenting the designer with trade-offs between slotting allowances, market share, and risk of retailer acceptance.
Skip Nav Destination
e-mail: azarm@umd.edu
Article navigation
June 2008
Research Papers
Engineering Product Design Optimization for Retail Channel Acceptance
N. Williams,
N. Williams
Assistant Professor
School of Architecture and Construction Management,
Washington State University
, Pullman, WA 99164
Search for other works by this author on:
S. Azarm,
S. Azarm
Professor
Department of Mechanical Engineering, A. J. Clark School of Engineering,
e-mail: azarm@umd.edu
University of Maryland
, College Park, MD 20742
Search for other works by this author on:
P. K. Kannan
P. K. Kannan
Associate Professor
Department of Marketing, R. H. Smith School of Business,
University of Maryland
, College Park, MD 20742
Search for other works by this author on:
N. Williams
Assistant Professor
School of Architecture and Construction Management,
Washington State University
, Pullman, WA 99164
S. Azarm
Professor
Department of Mechanical Engineering, A. J. Clark School of Engineering,
University of Maryland
, College Park, MD 20742e-mail: azarm@umd.edu
P. K. Kannan
Associate Professor
Department of Marketing, R. H. Smith School of Business,
University of Maryland
, College Park, MD 20742J. Mech. Des. Jun 2008, 130(6): 061402 (10 pages)
Published Online: April 14, 2008
Article history
Received:
March 22, 2007
Revised:
September 20, 2007
Published:
April 14, 2008
Citation
Williams, N., Azarm, S., and Kannan, P. K. (April 14, 2008). "Engineering Product Design Optimization for Retail Channel Acceptance." ASME. J. Mech. Des. June 2008; 130(6): 061402. https://doi.org/10.1115/1.2898874
Download citation file:
Get Email Alerts
DeepJEB: 3D Deep Learning-Based Synthetic Jet Engine Bracket Dataset
J. Mech. Des (April 2025)
Design and Justice: A Scoping Review in Engineering Design
J. Mech. Des (May 2025)
Related Articles
Multicategory Design of Bundled Products for Retail Channels Under Uncertainty and Competition
J. Mech. Des (March,2010)
Strategic Design Decisions for Uncertain Market Systems Using an Agent Based Approach
J. Mech. Des (April,2011)
Optimal Product Portfolio Formulation by Merging Predictive Data Mining With Multilevel Optimization
J. Mech. Des (April,2008)
Should Optimal Designers Worry About Consideration?
J. Mech. Des (July,2015)
Related Proceedings Papers
Related Chapters
Matrix Organization 101
Managing Systems Development 101: A Guide to Designing Effective Commercial Products & Systems for Engineers & Their Bosses∕CEOs
Usage of Revision Control Tools in Capstone Senior Design Courses
Advances in Multidisciplinary Engineering
Preprocessing Selection of Enterprise Resource Planning Applications in Small Manufacturing Industry and Its Impact on Business Process Agility
International Conference on Computer Engineering and Technology, 3rd (ICCET 2011)