A model-based approach to associate complexity and robustness in engineering systems

Author(s)

Göhler, Simon Moritz; Howard, Thomas J.; Frey, Daniel

Abstract

Ever increasing functionality and complexity of products and systems challenge development companies in achieving high and consistent quality. A model-based approach is used to investigate the relationship between system complexity and system robustness. The measure for complexity is based on the degree of functional coupling and the level of contradiction in the couplings. Whilst Suh’s independence axiom states that functional independence (uncoupled designs) produces more robust designs, this study proves this not to be the case for max-/min-is-best requirements, and only to be true in the general sense for nominal-is-best requirements. In specific cases, the independence axiom has exceptions as illustrated with a machining example, showing how a coupled solution is more robust than its uncoupled counterpart. This study also shows with statistical significance, that for max- and min-is-best requirements, the robustness is most affected by the level of contradiction between coupled functional requirements (p = 1.4e−36). In practice, the results imply that if the main influencing factors for each function in a system are known in the concept phase, an evaluation of the contradiction level can be used to evaluate concept robustness.

Date issued

2016-08

URI

http://hdl.handle.net/1721.1/107683

Department

Massachusetts Institute of Technology. Department of Mechanical Engineering

Journal

Research in Engineering Design

Publisher

Springer London

Citation

Göhler, Simon Moritz, Daniel D. Frey, and Thomas J. Howard. “A Model-Based Approach to Associate Complexity and Robustness in Engineering Systems.” Research in Engineering Design 28, no. 2 (August 27, 2016): 223–234.

Version: Author's final manuscript

ISSN

0934-9839

1435-6066