CONFIDENCE REGIONS FOR OPTIMAL CONTROLLABLE VARIABLES FOR THE ROBUST PARAMETER DESIGN PROBLEM

Cheng, Aili

January 2012

In robust parameter design it is often possible to set the levels of the controllable factors to produce a zero gradient for the transmission of variability from the noise variables. If the number of control variables is greater than the number of noise variables, a continuum of zero-gradient solutions exists. This situation is useful as it provides the experimenter with multiple conditions under which to configure a zero gradient for noise variable transmission. However, this situation requires a confidence region for the multiple-solution factor levels that provides proper simultaneous coverage. This requirement has not been previously recognized in the literature. In the case where the number of control variables is greater than the number of noise variables, we show how to construct critical values needed to maintain the simultaneous coverage rate. Two examples are provided as a demonstration of the practical need to adjust the critical values for simultaneous coverage. The zero-gradient confidence region only focuses on the variance, and there are in fact many such situations in which focus is or could be placed entirely on the process variance. In the situation where both mean and variance need to be considered, a general confidence region in control variables is developed by minimizing weighted mean square error. This general method is applicable to many situations including mixture experiments which have an inherit constraint on the control factors. It also gives the user the flexibility to put different weights on the mean and variance parts for simultaneous optimization. It turns out that the same computational algorithm can be used to compute the dual confidence region in both control factors and the response variable. / Statistics

Statistics

Confidence Region

Noise Variables

Response Surface

Robust Parameter Design

Sequential Design of Computer Experiments for Robust Parameter Design

Lehman, Jeffrey S.

11 September 2002

No description available.

Statistics

computer experiments

control variables

expected improvement

noise variables

sequential design

Sequential Adaptive Designs In Computer Experiments For Response Surface Model Fit

LAM, CHEN QUIN

29 July 2008

No description available.

Statistics

Cross validation

Gaussian stochastic process model

Kriging

Non-stationary response surfaces

Sequential designs

Adaptive designs

Control and noise variables.