Title :
Process Capability Sensitivity Analysis for Design Evaluation of Multistage Assembly Processes
Author :
Huang, Wenzhen ; Kong, Zhenyu
Author_Institution :
Mech. Eng. Dept., Univ. of Massachusetts Dartmouth, North Dartmouth, MA, USA
Abstract :
Yield-based sensitivity analysis methods and algorithms are developed for process capability evaluation in this paper. Yield, the conformity to product specifications, is subject to critical design parameters such as dimensions, tolerances, and specification limits. The uncertainties in determining these parameters in design and manufacturing affect the process capability of producing high-quality products. Yield is a transparent and thus a desirable index, especially for multivariate process capability evaluation. Thus, yield sensitivity with respect to these design parameters indicates key contributors to final product quality, providing valuable information in design for quality control. Yield is formulated as a high dimension probability integral over a specification region. In multistage assembly processes, an assembly variation model links the quality characteristics to design parameters. This model is adopted in yield sensitivity analysis. Derivatives of yield with respect to the design parameters are developed using matrix calculus. Three sensitivity analysis algorithms, i.e., finite difference, yield derivative, and regression modeling, are implemented. Monte Carlo simulation is used for yield estimation in the three algorithms. A case study using floor pan assembly in automotive body manufacturing is presented for the validation of the proposed methodology.
Keywords :
Monte Carlo methods; assembling; calculus; design engineering; finite difference methods; matrix algebra; probability; quality control; regression analysis; sensitivity analysis; Monte Carlo simulation; automotive body manufacturing; design evaluation; design parameters; finite difference; floor pan assembly; matrix calculus; multistage assembly processes; multivariate process capability evaluation; process capability sensitivity analysis; product quality; product specifications; quality characteristics; quality control; regression modeling; uncertainties; yield derivative; yield estimation; yield-based sensitivity analysis; Algorithm design and analysis; Assembly; Automotive engineering; Calculus; Design for quality; Finite difference methods; Manufacturing processes; Sensitivity analysis; Uncertainty; Yield estimation; Assembly; process capability; sensitivity; tolerance;
Journal_Title :
Automation Science and Engineering, IEEE Transactions on
DOI :
10.1109/TASE.2009.2034633
