Balancing Marketing and Manufacturing Objectives in Product Line Design

The product development process involves communication and compromise among interacting and often competing objectives from marketing, design, and manufacturing perspectives. Methods for negotiating these perspectives play an important role in the process. For example, design for manufacturing (DFM) analyses aim to incorporate manufacturing requirements into product design decision making to reduce product complexity and cost, which generally increases profitability. However, when design characteristics have market consequences, it is important to quantify explicitly the tradeoffs between the reduced cost and reduced revenue resulting from designs that are less expensive to manufacture but also less desirable in the marketplace. In this article we leverage existing models for coordinating marketing and design perspectives by incorporating quantitative models of manufacturing investment and production allocation. The resulting methodology allows a quantitative assessment of tradeoffs among product functionality, market performance, and manufacturing costs to achieve product line solutions with optimal profitability.

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Manufacturing Investment and Allocation in Product Line Design Decision-Making

Volume 2: 31st Design Automation Conference, Parts A and B ◽

10.1115/detc2005-84812 ◽

2005 ◽

Cited By ~ 5

Author(s):

Jeremy J. Michalek ◽

Oben Ceryan ◽

Panos Y. Papalambros ◽

Yoram Koren

Keyword(s):

Decision Making ◽

Engineering Design ◽

Product Line ◽

Manufacturing Cost ◽

Design Decision ◽

Product Line Design ◽

Product Decision ◽

Market Consequences ◽

Line Design ◽

Is Design

An important aspect of product development is design for manufacturability (DFM) analysis that aims to incorporate manufacturing requirements into early product decision-making. Existing methods in DFM seldom quantify explicitly the tradeoffs between revenues and costs generated by making design choices that may be desirable in the market but costly to manufacture. This paper builds upon previous work coordinating models for engineering design and marketing product line decision-making by incorporating quantitative models of manufacturing investment and production allocation. The result is a methodology that considers engineering design decisions quantitatively in the context of manufacturing and market consequences in order to resolve tradeoffs, not only among performance objectives, but also between market preferences and manufacturing cost.

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Concurrent Design and Manufacturing for Mechanical Systems

Volume 4: 4th Design for Manufacturing Conference ◽

10.1115/detc99/dfm-8911 ◽

1999 ◽

Author(s):

Kuang-Hua Chang ◽

Javier Silva ◽

Ira Bryant

Keyword(s):

Decision Making ◽

Product Development ◽

Product Design ◽

Development Process ◽

Product Performance ◽

Product Development Process ◽

Concurrent Design ◽

Manufacturing Cost ◽

Design Decision ◽

Design And Manufacturing

Abstract Conventional product development process employs a design-build-break philosophy. The sequentially executed product development process often results in a prolonged lead-time and an elevated product cost. The proposed concurrent design and manufacturing (CDM) process employs physics-based computational methods together with computer graphics technique for product design. This proposed approach employs Virtual Prototyping (VP) technology to support a cross-functional team analyzing product performance, reliability, and manufacturing cost early in the product development stage; and conducting quantitative trade-off for design decision making. Physical prototypes of the product design are then produced using Rapid Prototyping (RP) technique primarily for design verification purposes. The proposed CDM approach holds potential for shortening the overall product development cycle, improving product quality, and reducing product cost. A software tool environment that supports CDM for mechanical systems is being built at the Concurrent Design and Manufacturing Research Laboratory (http://cdm.ou.edu) at the University of Oklahoma. A snap shot of the environment is illustrated using a two-stroke engine example. This paper presents three unique concepts and methods for product development: (i) bringing product performance, quality, and manufacturing cost together in early design stage for design considerations, (ii) supporting design decision-making through a quantitative approach, and (iii) incorporating rapid prototyping for design verification through physical prototypes.

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