Advanced search
Publication Cover
Journal of Quality Technology
A Quarterly Journal of Methods, Applications and Related Topics
Volume 36, 2004 - Issue 1
Submit an article Journal homepage
1,209
Views
438
CrossRef citations to date
0
Altmetric
Articles

Response Surface Methodology: A Retrospective and Literature Survey

Raymond H. MyersVirginia Tech, Blacksburg, VA24061View further author information
,
Douglas C. MontgomeryArizona State University, Tempe, AZ85287View further author information
,
G. Geoffrey ViningVirginia Tech, Blacksburg, VA24061View further author information
,
Connie M. BorrorDrexel University, Philadelphia, PA19104View further author information
&
Scott M. KowalskiMinitab Inc., State College, PA16801View further author information
Pages 53-77 | Published online: 16 Feb 2018

References

  • Abraham, B.; Chipman, H.; and Vijayan, K. (1999). “Some Risks in the Construction and Analysis of Supersaturated Designs”. Technometrics 41, pp. 135–141.
  • Aggarwal, M. L. and Bansal, A. (1998). “Robust Response Surface Designs for Quantitative and Qualitative Factors”. Communications in Statistics—Theory and Methods 27, pp. 89–106.
  • Aggarwal, M. L.; Gupta, B. C; and Bansal, A. (2000). “Small Robust Response-Surface Designs for Quantitative and Qualitative Factors”. American Journal of Mathematical and Management Sciences 39, pp. 103–130.
  • Ames, A. E.; Mattucci, N.; MacDonald, S.; Szonyi, G.; and Hawkins, D. M. (1997). “Quality Loss Functions for Optimizations across Multiple Response Surfaces”. Journal of Quality Technology 29, pp. 339–346.
  • Andere-Rendon, J.; Montgomery, D. C.; and Rollier, D. A. (1997). “Design of Mixture Experiments Using Bayesian D-Optimality”. Journal of Quality Technology 29, pp. 451–163.
  • Ankenman, B. E. and Bisgaard, S. (1996). “Standard Errors for the Eigenvalues in Second-Order Response Surface Models”. Technometrics 38, pp. 238–246.
  • Ankenman, B. E.; Liu, H.; Karr, A. F.; and Picka, J. D. (2002). “A Class of Experimental Designs for Estimating a Response Surface and Variance Components”. Technometrics 44, pp. 45–54
  • Atkinson, A. C; Chanoler, K.; Herzberg, A. M.; and Juritz, J. (1993). “Optimum Experimental-Designs for Properties of a Compartmental Model”. Biometrics 49, pp. 325–337.
  • Atkinson, A. and Donev, A. N. (1992). Optimum Experimental Design. Clarendon Press, Oxford.
  • Atkinson, A. C. and Haines, L. M. (1996). “Designs for Nonlinear and Generalized Linear Models” in the Handbook of Statistics North Holland Publishing Co., Amsterdam, pp. 437–475.
  • Balkin, S. D. and Lin, D. K. J. (1998). “A Graphical Comparison of Supersaturated Designs”. Communications in Statistics—Theory and Practice 27, pp. 1289–1303.
  • Barnett, J.; Czitrom, V.; John, P. W. M; and Leon, R. V. (1997). “Using Fewer Wafers to Resolve Confounding in Screening Experiments” in Statistical Case Studies for Industrial Process Improvement edited by V. Czitrom and P.D. Spagon, SIAM, Philadelphia, PA., pp. 235–250.
  • Barton R. R. (1992). “Metamodels for Simulation Input-Output Relations”. Winter Simulation Conference, pp. 289–299.
  • Beattie, S. D.; Fong, D. K. H.; and Lin, D. K. J. (2002). “A Two-Stage Bayesian Model Selection Strategy for Supersaturated Designs”. Technometrics 44, pp. 55–63.
  • Bergman, B. and Hynen, A. (1997). “Dispersion Effects from Unreplicated Designs in the 2k–p Series”. Technometrics 39, pp. 191–198.
  • Berube, J. and Nair, V. N. (1998). “Exploiting the Inherent Structure in Robust Parameter Design Experiments”. Statistica Sinica 8, pp. 43–66.
  • Bingham, D. R. and Li, W. (2002). “A Class of Optimal Robust Parameter Designs”. Journal of Quality Technology 34, pp. 244–259.
  • Bingham, D. R. and Sitter, R. S. (1999a). “Minimum-Aberration Two-Level Fractional Factorial Split-Plot Designs”. Technometrics 41, pp. 62–70.
  • Bingham, D. R. and Sitter, R. S. (1999b). “Some Theoretical Results for Fractional Factorial Split-Plot Designs”. The Annals of Statistics 27, pp. 1240–1255.
  • Bingham, D. R. and Sitter, R. S. (2001). “Design Issues in Fractional Factorial Split-Plot Experiments”. Journal of Quality Technology 33, pp. 2–15.
  • Bisgaard, S. (2000). “The Design and Analysis of 2k–p × 2q–r Split Plot Experiments”. Journal of Quality Technology 32, pp. 39–56.
  • Bisgaard, S. and Kulahci, M. (2001). “Robust Product Design: Saving Trials With Split-Plot Confounding”. Quality Engineering 13, pp. 525–530.
  • Bisgaard, S. and Steinberg, D. M. (1997). “The Design and Analysis of 2k–p × s Prototype Experiments”. Technometrics 39, pp. 52–62.
  • Blomkvist, O.; Hynen, A.; and Bergman, B. (1997). “A Method to Identify Dispersion Effects from Unreplicated Multilevel Experiments”. Quality and Reliability Engineering International 13, pp. 127–138.
  • Booth, K. H. V. and Cox, D. R. (1962). “Some Systematic Saturated Designs”. Technometrics 4, pp. 489–495.
  • Borkowski, J. J. (1995). “Spherical Prediction-Variance Properties of Central Composite Designs and Box-Behnken Designs”. Technometrics 37, pp. 399–410.
  • Borkowski, J. J. (2003a). “Using a Genetic Algorithm to Generate Small Exact Response Surface Designs”. Journal of Probability and Statistical Science 1, pp. 65–88.
  • Borkowski, J. J. (2003b). “A Comparison of Prediction Variance Criteria for Response Surface Designs”. Journal of Quality Technology 35, pp. 70–77.
  • Borkowski, J. J. and Lucas, J. M. (1997). “Designs of Mixed Resolution for Process Robustness Studies”. Technometrics 37, pp. 63–70.
  • Borkowski, J. J. and Valeroso, E. S. (2001). “Comparison of Design Optimality Criteria of Reduced Models for Response Surface Designs in the Hypercube”. Technometrics 43, pp. 468–477.
  • Borror, C. M. (1998). “Response Surface Methods for Experiments Involving Noise Variables”. Ph.D. Dissertation, Arizona State University, Tempe, AZ.
  • Borror, C. M.; Heredia-Langner, A.; and Montgomery, D. C. 2002. “Generalized Linear Models in the Analysis of Industrial Experiments”. Journal of Propagations in Probability and Statistics (International Edition) 2, pp. 127–144.
  • Borror, C. M. and Montgomery, D. C. (2000). “Mixed Resolution Designs as Alternatives to Taguchi Inner/Outer Array Designs for Robust Design Problems”. Quality and Reliability Engineering International 16, pp. 117–127.
  • Borror, C. M.; Montgomery, D. C.; and Myers, R. H. (2002). “Evaluation of Statistical Designs for Experiments Involving Noise Variables”. Journal of Quality Technology 34, pp. 54–70.
  • Box, G. E. P. (1985). “Discussion of ‘Off-Line Quality Control, Parameter Design and the Taguchi Method”. Journal of Quality Technology 17, pp. 198–206.
  • Box, G. E. P. (1988). “Signal-to-Noise Ratios, Performance Criteria, and Transformations” (with discussion). Technometrics 30, pp. 1–41.
  • Box, G. E. P. (1996). “Split-Plot Experiments”. Quality Engineering 8, pp. 515–520.
  • Box, G. E. P. (1999). “Statistics as a Catalyst to Learning by Scientific Method Part II—A Discussion”. Journal of Quality Technology 31, pp. 16–29.
  • Box, G. E. P.; Bisgaard, S.; and Fung, C. A. (1988). “An Explanation and Critique of Taguchi's Contributions to Quality Engineering”. Quality and Reliability Engineering International 4, pp. 123–131.
  • Box, G. E. P. and Draper, N. R. (1975). “Robust Designs”. Biometrika 62, pp. 347–352.
  • Box, G. E. P. and Draper, N. R. (1987). Empirical Model Building and Response Surfaces. John Wiley & Sons, New York, NY.
  • Box, G. E. P. and Jones, S. (1992). “Split-Plot Designs for Robust Product Experimentation”. Journal of Applied Statistics 19, pp. 3–26.
  • Box, G. E. P. and Jones, S. (2001). “Split-Plots for Robust Product and Process Experimentation”. Quality Engineering 13, pp. 127–134.
  • Box, G. E. P. and Liu, P. Y. T. (1999). “Statistics as a Catalyst to Learning by Scientific Method Part I—An Example”. Journal of Quality Technology 31, pp. 1–15.
  • Box, G. E. P. and Tyssedal, J. (1996). “Projective Properties of Certain Orthogonal Arrays”. Biometrika 83, pp. 950–955.
  • Box, G. E. P. and Tyssedal, J. (2001). “Sixteen Run Designs of High Projectivity for Factor Screening”. Communications in Statistics: Simulation and Computation 30, pp. 217–228.
  • Box, G. E. P. and Wilson, K. B. (1951). “On the Experimental Attainment of Optimum Conditions”. Journal of the Royal Statistical Society B 13, pp. 1–45.
  • Brenneman, W. A. and Nair, V. N. (2001). “Methods for Identifying Dispersion Effects in Unreplicated Factorial Experiments: A Critical Analysis and Proposed Strategies”. Technometrics 43, pp. 388–405.
  • Brenneman, W. A. and Myers, W. R. (2003). “Robust Parameter Design with Categorical Noise Variables”. Journal of Quality Technology 35, pp. 335–341.
  • Brinkley, P; Meyer, K.; and Lu, J. (1996). “Combined Generalized Linear Modelling-Non-linear Programming Approach to Robust Process Design—A Case-study in Circuit Board Quality Improvement”. Journal of the Royal Statistical Society Series C 45, pp. 99–110.
  • Cantell, B. and Ramirez, J. G. (1994). “Robust Design of a Polysilicon Deposition Process Using a Split-Plot Analysis”. Quality Reliability Engineering International 10, pp. 123–132.
  • Carlyle, W. M.; Montgomery, D. C.; and Runger, G. C. (2000). “Optimization Problems and Methods in Quality Control and Improvement” (with discussion). Journal of Quality Technology 32, pp. 1–17.
  • Chanoler, K. and Verdinelli, I. (1995). “Bayesian Experimental Design: A Review”. Statistical Science 10, pp. 273–304.
  • Cheng, C. S. (1995). “Some Projection Properties of Orthogonal Arrays”. Annals of Statistics 23, pp. 1223–1233.
  • Cheng, S.-W. and Wu, C. F. J. (2001). “Factor Screening and Response Surface Exploration” (with discussion). Statistica Sinica 11, pp. 553–604.
  • Chiao, C.-H. and Hamada, M. (2001). “Analyzing Experiments with Correlated Multiple Responses”. Journal of Quality Technology 33, pp. 451–465.
  • Chipman, H. (1998). “Handling Uncertainty in Analysis of Robust Design Experiments”. Journal of Quality Technology 30, pp. 11–17.
  • Chipman, H. and Hamada, M. S. (1996). “Discussion: Factor-Based or Effect-Based Modeling? Implications for Design”. Technometrics 38, pp. 317–320.
  • Copeland, K. A. F. and Nelson, P. R. (1996). “Dual Response Optimization via Direct Function Minimization”. Journal of Quality Technology 28, pp. 331–336.
  • Cornell, J. A. (1988). “Analyzing Data from Mixture Experiments Containing Process Variables: A Split-Plot Approach”. Journal of Quality Technology 20, pp. 2–23.
  • Cornell, J. A. (2002). Experiments with Mixtures 3rd Ed. John Wiley and Sons, New York, NY.
  • Del castillo, E. (1996). “Multiresponse Process Optimization via Constrained Confidence Regions”. Journal of Quality Technology 28, pp. 61–70.
  • Del Castillo, E.; Fan, S. K.; and Semple, J. (1999). “Optimization of Dual Response Systems: A Comprehensive Procedure for Degenerate and Nondegenerate Problems”. European Journal of Operational Research 112, pp. 174–186.
  • Del Castillo, E. and Montgomery, D. C. (1993). “A Nonlinear Programming Solution to the Dual Response Problem”. Journal of Quality Technology 25, pp. 199–204.
  • Del Castillo, E.; Montgomery, D. C.; and McCarville, D. (1996). “Modified Desirability Functions for Multiple Response Optimization”. Journal of Quality Technology 28, pp. 337–345.
  • Deng, L. Y.; Lin, D. K. J.; and Wang, J. N. (1996a). “Marginally Oversaturated Designs”. Communications in Statistics 25, pp. 2557–2573.
  • Deng, L. Y.; Lin, D. K. J.; and Wang, J. N. (1996b). “A Measure of Multifactor Nonorthogonality”. Statistics and Probability Letters 28, pp. 203–209.
  • Derringer, G. C. and Suich, R. (1980). “Simultaneous Optimization of Several Response Variables”. Journal of Quality Technology 12, pp. 214–219.
  • Donohue, J. M. (1994). “Experimental Designs for Simulation”. Winter Simulation Conference pp. 200–206.
  • Draper, N. R. (1985). “Small Composite Designs”. Technometrics 27, pp. 173–180.
  • Draper, N. R.; Davis, T. P.; Pozueta, L.; and Grove, D. (1994). “Isolation of Degrees of Freedom for Box-Behnken Designs”. Technometrics 36, pp. 283–291.
  • Draper, N.; Gaffke, N.; and Pukelsheim, F. (1991). “First and Second Order Rotatability of Experimental Designs, Moment Matrices, and Information Surfaces”. Metrika 38, pp. 129–161.
  • Draper, N.; Gaffke, N.; and Pukelsheim, F. (1993). “Rotatability of Variance Surfaces and Moment Matrices”. Journal of Statistical Planning and Inference 36, pp. 347–356.
  • Draper, N.; Heiligers, B; and Pukelsheim, F. (1996). “An Optimal Third-Order Rotatable Designs”. Annals of Institute of Statistical Mathematics 48, pp. 395–402.
  • Draper, N. and John, J. A. (1988). “Response Surface Designs for Quantitative and Qualitative Variables”. Technometrics 30, pp. 423–428.
  • Draper, N. and John, J. A. (1998). “Response Surface Designs where levels of Some Factors Are Difficult to Change”. Australian and New Zealand Journal of Statistics 40, pp. 487–495.
  • Draper, N. and Lin, D. K. J. (1990). “Small Response Surface Designs”. Technometrics 32, pp. 187–194.
  • Draper, N. and Lin, D. K. J. (1995). “Characterizing Projected Designs- Repeat and Mirror Image Runs”. Communications in Statistics—Theory and Methods 24, pp. 775–795.
  • Draper, N. and Lin, D. K. J. (1996). “Response Surface Designs”. Chapter 11 in Handbook of Statistics, Vol. 13, Design and Analysis of Experiments edited by S. Ghosh and C.R. Rao. Elsevier Science, Amsterdam, pp. 343–375.
  • Draper, N. and Pukelsheim, F. (1990). “Another Look at Rotatability”. Technometrics 32, pp. 195–202.
  • Draper, N. and Pukelsheim, F. (1994). “On Third-Order Rotatability”. Metrika 41, pp. 137–161.
  • Draper, N. and Pukelsheim, F. (1996). “An Overview of Design of Experiments”. Statistical Papers 37, pp. 1–32.
  • Draper, N. and Pukelsheim, F. (1998). “Polynomial Representations for Response Surface Modeling”. New Developments and Applications in Experimental Designs. IMS Lecture Notes—Monograph Series 34, pp. 199–212.
  • Draper, N. and Ying, L. H. (1994). “A Note on Slope Rotatability over all Directions”. Journal of Statistical Planning and Inference 41, pp. 113–119.
  • DuMochel, W. and Jones, B. (1994). “A Simple Bayesian Modification of D-optimal Designs to Reduce Dependence on an Assumed Model”. Technometrics 13, pp. 682–688.
  • Engel, J. (1992). “Modelling Variation in Industrial Experiments”. Applied Statistics 41, pp. 579–593.
  • Engel, J. and Huele, A. F. (1996). “Taguchi Parameter Design by Second-Order Response Surfaces”. Quality and Reliability Engineering International 12, pp. 95–100.
  • Fan, S.-K. S. (2000). “A Generalized Global Optimization Algorithm for Dual Response Systems”. Journal of Quality Technology 32, pp. 444–456.
  • Fang, K.-T.; Lin, D. K. J.; Winker, P.; and Zhang, Y. (2000). “Uniform Design: Theory and Applications”. Technometrics 42, pp. 237–248.
  • Federer, W. T. and Meredith, M. P. (1992). “Covariance Analysis for Split-Plot and Split-Block Designs”. The American Statistician 46, pp. 155–162.
  • Ferrer, A. J. and Romero, R. (1993). “Small Samples Estimation of Dispersion Effects from Unreplicated Data”. Communications in Statistics—Simulation and Computation 22, pp. 975–995.
  • Ferrer, A. J. and Romero, R. (1995). “A Simple Method to Study Dispersion Effects from Non-necessary Replicated Data in Industrial Context”. Quality Engineering 7, pp. 747–755.
  • Ford, I.; Torsney, B.; and Wu, C. F. (1992). “The Use of a Canonical Form in the Construction of Locally Optimal Designs for Nonlinear Problems”. Journal of the Royal Statistical Society Series B 54, pp. 569–583.
  • Freeny, A. E. and Landwehr, J. M. (1995). “Graphical Analysis for a Large Designed Experiment”. Technometrics 37, pp. 1–14.
  • Ganju, J. and Lucas, J. M. (1997). “Bias in Test Statistics When Restrictions in Randomization are Caused by Factors”. Communications in Statistics—Theory and Methods 26, pp. 47–63.
  • Ganju, J. and Lucas, J. M. (1999). “Detecting Randomization Restrictions Caused by Factors”. Journal of Statistical Planning and Inference 81, pp. 129–140.
  • Ghosh, S. and Duh, Y.-J. (1992). “Determination of Optimum Experimental Conditions using Dispersion Main Effects and Interactions of Factors in Replicated Factorial Experiments”. Journal of Applied Statistics 19, pp. 367–378.
  • Giovannitti-Jensen, A. and Myers, R. H. (1989). “Graphical Assessment of the Prediction Capability of Response Surface Designs”. Technometrics 31, pp. 159–171.
  • Galdfarb, H. B.; Borror, C. M.; and Montgomery, D. C. (2003). “Mixture Process Experiments with Noise Variables”. Journal of Quality Technology 35, pp. 393–405.
  • Goos, P. and Vandebroek, M. (2001). “Optimal Split-Plot Designs”. Journal of Quality Technology 33, pp. 436–450.
  • Grego, J. M. (1993). “Generalized Linear Models and Process Variation”. Journal of Quality Technology 25, pp. 288–295.
  • Haaland, P.; McMillan, N.; Nycha, D.; and Welch, W. (1994). “Analysis of Space-Filling Designs,” Computing Science and Statistics, Computationally Intensive Statistical Methods. Proceedings of the 26th Symposium on the Interface. Interface Foundation of North America, Fairfax Station, VA, pp. 111–120.
  • Hader, R. and Park, S. H. (1978). “Slope-Rotatable Central Composite Designs”. Technometrics 20, pp. 413–417.
  • Haines, L. M. (1987). “The Application of the Annealing Algorithm to the Construction of the Exact Optimal Designs for Linear-Regresison Models”. Technometrics 29, pp. 4394–437.
  • Hamada, M.; Martz, H. F.; Reese, C. S.; and Wilson, A. G. (2001). “Finding Near-Optimal Bayesian Experimental Designs via Genetic Algorithms”. The American Statistician 55, pp. 175–181.
  • Heise, M. A. and Myers, R. H. (1996). “Optimal Designs for Bivariate Logistic Regression”. Biometrics 52, pp. 613–624.
  • Heredia-Langner, A; Carlyle, W. M.; Montgomery, D. C.; Borror, C. M.; and Runger, G. C. (2003) “Genetic Algorithms for the Construction of D-Optimal Designs”. Journal of Quality Technology 35, pp. 28–46.
  • Heredia-Langner, A.; Carlyle, W. M.; Montgomery, D. C.; and Borror, C. M. (2004). “Model-Robust Optimal Designs: A Genetic Algorithm Approach”. To appear in the Journal of Quality Technology
  • Heredia-Langner, A.; Loredo, E. N.; Montgomery, D. C.; and Gritton, A. H. (2000). “Optimization of a Bonded Leads Process Using Statistically Designed Experiments”. Robotics and Computer Integrated Manufacturing 16, pp. 377–382.
  • Hill, W. J. and Hunter, W. G. (1966). “A Review of Response Surface Methodology: A Literature Review”. Technometrics 8, pp. 571–590.
  • Holcomb, D. R. and Carlyle, W. M. (2002). “Some Notes on the Construction and Evaluation of Supersaturated Designs”. Quality and Reliability Engineering International 18, pp. 299–304.
  • Holcomb, D. R.; Montgomery, D. C.; and Carlyle, W. M. (2003). “Analysis of Supersaturated Designs”. Journal of Quality Technology 35, pp. 13–27.
  • Hooke, R. and Jeeves, T. A. (1961). “Direct Search Solution of Numerical and Statistical Problems”. Journal of the Association of Computing Machinery 8, pp. 212–229.
  • Huang, P.; Chen, D.; and Voelkel, J. O. (1998). “Minimum-Aberration Two-Level Split-Plot Designs”. Technometrics 40, pp. 314–326.
  • Jia, Y. and Myers, R. H. (2001). “Experimental Designs for Logistic Models in Two Design Variables”. Technical Report number 01–9, Department of Statistics, Virginia Tech, Blacksburg, VA.
  • Johnson, M. E.; Moore, L. M.; and Ylvisaker, D. (1990). “Minimax and Maximin Distance Designs”. Journal of Statistical Planning and Inference 36, pp. 131–148.
  • Kackar, R. (1985). “Off-Line Quality Control, Parameter Designs, and the Taguchi Methods” (with discussion). Journal of Quality Technology 17, pp. 176–188.
  • Kalish, L. A. (1990). “Efficient Design for Estimation of Median Lethal Dose and Quantal Dose-Response Curves”. Biometrics 46, pp. 737–748.
  • Khattree, R. (1996). “Robust Parameter Design: A Response Surface Approach”. Journal of Quality Technology 28, pp. 187–198.
  • Khuri, A. I. (1988). “A Measure of Rotatability for Response Surface Designs”. Technometrics 30, pp. 95–104.
  • Khuri, A. I. (1990). “Analysis of Multiresponse Experiments: A Review” in Statistical Design and Analysis of Industrial Experiments edited by S. Ghosh, Marcel Dekker, New York, NY, pp. 231–246.
  • Khuri, A. I. (1992). “Diagnostic Results Concerning a Measure of Rotatability”. Journal of the Royal Statistical Society Series B 54, pp. 253–267.
  • Khuri, A. I. and Conlon, M. (1981). “Simultaneous-Optimization of Multiple Responses Represented by Polynomial Regression-Functions”. Technometrics 23, pp. 363–375.
  • Khuri, A. I. and Cornell, J. A. (1996). Response Surfaces: Designs and Analyses 2nd ed. Marcel Dekker, New York.
  • Khuri, A. I.; Harrison, J. M.; and Cornell, J. A. (1999). “Using Quantile Plots of the Prediction Variance for Comparing Designs for a Constrained Mixture Region: An Application Involving a Fertilizer Experiment”. Journal of the Royal Statistical Society Series C 48, pp. 521–532.
  • Khuri, A. I.; Kim, H. J.; and Um, Y. (1996). “Quantile Plots of the Prediction Variance for Response Surface Designs”. Computational Statistics and Data Analysis 22, pp. 395–407.
  • Kim, W. B. and Draper, N. R. (1994). “Choosing a Design for Straight Line Fits to Two Correlated Responses”. Statistica Sinica 4, pp. 275–280.
  • Kim, K-J. and Lin, D. K. J. (1998). “Dual Response Surface Optimization: A Fuzzy Modeling Approach”. Journal of Quality Technology 1, pp. 1–10.
  • Kim, K-J. and Lin, D. K. J. (2000). “Simultaneous Optimization of Mechanical Properties of Steel by Maximizing Experimental Desirability Functions”. Journal of the Royal Statistical Society Series C 49, pp. 311–325.
  • Kowalski, S. M. (1999). “The Design and Analysis of Split-Plot Experiments in Industry”. Ph.D. Dissertation, University of Florida, Gainesville, FL.
  • Kowalski, S. M. (2002). “24 Run Split-Plot Experiments for Robust Parameter Design”. Journal of Quality Technology 34, pp. 399–410.
  • Kowalski, S. M., Cornell, J. A.; and Vining, G. G. (2002). “Split-Plot Designs and Estimation Methods for Mixture Experiments with Process Variables”. Technometrics 44, pp. 72–79.
  • Kraft, O. and Schaefer, M. (1992). “D-Optimal Designs for a Multivariate Regression Model”. Journal of Multivariate Analysis 42, pp. 130–140.
  • Kuhn, A. M.; Carter, W. H.; and Myers, R. H. (2000). “Incorporating Noise Factors into Experiments with Censored Data”. Technometrics V42, pp. 376–383.
  • Langsrud, O. (2001). “Identifying Significant Effects in Fractional Factorial Multiresponse Experiments”. Technometrics 43, pp. 415–424.
  • Lasdon, L.; Fox, R.; and Ratner, M. (1974). “Nonlinear Optimization Using Generalized Reduced Gradient Method”. Revue Francaise D Automatique Informatique Recherche Operationnelle 8, pp. 73–103.
  • Lawson, J. (2003). “One-Step Screening and Process optimization Experiments”. The American Statistician 57, pp. 15–20.
  • Lee, Y. and Nelder, J. A. (1998). “Joint Modeling of Mean and Dispersion”. Technometrics 40, pp. 168–171.
  • Lee, Y. and Nelder, J. A. (2003). “Robust Designs via Generalized Linear Models”. Journal of Quality Technology 35, pp. 2–12.
  • Letsinger, J. D.; Myers, R. H.; and Lentner, M. (1996). “Response Surface Methods for Bi-Randomization Structures”. Journal of Quality Technology 28, pp. 381–397.
  • Lewis, S. L.; Montgomery, D. C.; and Myers, R. H. (1999–2000). “The Analysis of Designed Experiments with Nonnormal Responses”. Quality Engineering 12, pp. 225–244.
  • Lewis, S. L.; Montgomery, D. C.; and Myers, R. H. (2001a). “Examples of Designed Experiments with Nonnormal Responses”. Journal of Quality Technology 33, pp. 265–278.
  • Lewis, S. L.; Montgomery, D. C.; and Myers, R. H. (2001b). “Confidence Interval Coverage for Designed Experiments Analyzed with Generalized Linear Models”. Journal of Quality Technology 33, pp. 279–292.
  • Lewis, S. M. and Dean, A. M. (2001). “Detection of Interactions in Experiments on Large Numbers of Factors”. Journal of the Royal Statistical Society Series B 63, pp. 633–672.
  • Li, H. and Mee, R. W. (2002). “Better Foldover Fractions for Resolution III 2k∼p Designs”. Technometrics 44, pp. 278–283.
  • Li, W. and Nachtsheim, C. J. (2000). “Model-Robust Factorial Designs”. Technometrics 42, pp. 345–352.
  • Li, W. W. and Wu, C. F. J. (1997). “Columnwise-Pairwise Algorithms with Applications to the Construction of Supersaturated Designs”. Technometrics 39, pp. 171–179.
  • Lin, D. K. J. (1993a). “A New Class of Supersaturated Designs”. Technometrics 35, pp. 28–31.
  • Lin, D. K. J. (1993b), “Another Look at First-Order Saturated Designs: The p-Efficient Designs”. Technometrics 35, pp. 284–292.
  • Lin, D. K. J. (1995). “Generating Systematic Supersaturated Designs”. Technometrics 37, pp. 255–264.
  • Lin, D. K. J. (2000). “Recent Developments in Supersaturated Designs” in Statistical Process Monitoring and Optimization edited by S. H. Park and G. G. Vining, Marcel Dekker, New York, NY, pp. 305–320.
  • Lin, D. K. J. and Draper, N. (1992). “Projection Properties of Plackett and Burman Designs”. Technometrics 34, pp. 423–428.
  • Lin, D. K. J. and Draper, N. (1993). “Generating Alias Relationships for Two-Level Plackett-Burman Designs”. Computational Statistics and Data Analysis 15, pp. 147–157.
  • Lin, D. K. J. and Tu, W. (1995). “Dual Response Surface Optimization”. Journal of Quality Technology 27, pp. 248–260.
  • Lin, H. F.; Myers, R. H.; and Ye, K. Y. (2000). “Bayesian Two-stage Optimal Design for Mixture Models”. Journal of Statistical Computation and Simulation 66, pp. 209–231.
  • Lind, E. E.; Goldin, J.; and Hickman, J. B. (1960). “Fitting Yield and Cost Response Surfaces”. Chemical Engineering Progress 56, p. 62.
  • Lucas, J. M. (1989). “Achieving a Robust Process Using Response Surface Methodology”. Paper presented at American Statistical Association Conference, Washington, D.C.
  • Lucas, J. M. (1994). “How to Achieve a Robust Process Using Response Surface Methodology”. Journal of Quality Technology 26, pp. 248–260.
  • Lucas, J. M. and Hazel, M. C. (1997). “Running Experiments With Multiple Error Terms: How an Experiment is Run is Important”. ASQC Technical Conference Transactions, American Society for Quality Control, Milwaukee, WI, pp. 283–296.
  • Lucas, J. M. and Ju, H. L. (1992). “Split Plotting and Randomization in Industrial Experiments”. ASQC Quality Congress Transactions, American Society for Quality Control, Nashville, TN, pp. 374–382.
  • Lunani, M.; Nair, V. N.; and Wasserman, G. S. (1997). “Graphical Methods for Robust Parameter Design with Dynamic Characteristics”. Journal of Quality Technology 29, pp. 327–338
  • Mathew, T. and Sinha, B. K. (1992). “Exact and Optimum Tests in Unbalanced Split-Plot Designs Under Mixed and Random Models”. Journal of the American Statistical Association 87, pp. 192–200.
  • Mays, D. P. and Myers, R. H. (1996). “Bayesian Approach for the Design and Analysis of a Two Level Factorial Experiment in the Presence of Dispersion Effects”. Communications in Statistics—Theory and Methods 25, pp. 1409–1428.
  • McCullough, C. and Nelder, J. A. (1989). Generalized Linear Models 2nd ed. Chapman and Hall, New York, NY.
  • McGrath, R. N. and Lin, D. K. J. (2001a). “Confounding of Location and Dispersion Effects in Unreplicated Fractional Factorials”. Journal of Quality Technology 33, pp. 129–139.
  • McGrath, R. N. and Lin, D. K. J. (2001b). “Testing Multiple Dispersion Effects in Unreplicated Fractional Factorial Designs”. Technometrics 43, pp. 406–414.
  • McKay M. D.; Beckman, R. J.; and Conover, W. J. (1979). “A Comparison of Three Methods for selecting Values of Input Variables in the Analysis of Output from a Computer Code”. Technometrics 21, pp. 239–245.
  • Mead, R. and Pike, D. J. (1975). “A Review of Response Surface Methodology from a Biometrics Viewpoint”. Biometrics 31, pp. 803–851.
  • Mee, R. W. (2001). “Noncentral Composite Designs”. Technometrics 43, pp. 34–43.
  • Mee, R. W. (2002). “Three-Level Simplex Designs and Their Use in Sequential Experimentation”. Journal of Quality Technology 34, pp. 152–164.
  • Mee, R. W. and Bates, R. L. (1998). “Split-Lot Designs: Experiments for Multistage Batch Processes”. Technometrics 40, pp. 127–140.
  • Mee, R. W. and Peralta, M. (2000). “Semifolding 2k–p Designs”. Technometrics 42, pp. 122–134.
  • Meyer, R. D.; Steinberg, D. M.; and Box, G. E. P. (1996). “Follow-Up Designs to Resolve the Confounding in Multifactor Experiments”. Technometrics 38, pp. 303–313.
  • Miller, A. (1997). “Strip-Plot Configurations of Fractional-Factorials”. Technometrics 39, pp. 153–161.
  • Miller, A. (2002). “Analysis of Parameter Design Experiments for Signal-Response Systems”. Journal of Quality Technology 34, pp. 139–151.
  • Miller, A. and Wu, C. F. J. (1996). “Parameter Design for Signal-Response Systems: A Different Look at Taguchi's Dynamic Parameter Design”. Statistical Science 11, pp. 122–136.
  • Montepiedra, G.; Myers, D.; and Yeh, A. B. (1998). “Application of Genetic Algorithms to the Construction of Exact D-Optimal Designs”. Journal of Applied Statistics 25, pp. 817–826.
  • Montgomery, D. C. (1990–91). “Using Fractional Factorial Designs for Robust Process Development”. Quality Engineering 3, pp. 193–205.
  • Montgomery, D. C. (1992). “The Use of Statistical Process Control and Design of Experiments in Product and Process Improvement”. IIE Transactions 24, pp. 4–17.
  • Montgomery, D. C. (1999). “Experimental Design for Product and Process Design and Development” (with Commentary). Journal of the Royal Statistical Society Series D 48, pp. 159–177.
  • Montgomery, D. C. (2001). Design and Analysis of Experiments 5th ed. John Wiley & Sons, Inc., New York, NY.
  • Montgomery, D. C. and Borror, C. M. (2001). “Discussion of ‘Factor Screening and Response Surface Exploration’ by Cheng and Wu”. Statistica Sinica 11, pp. 591–595.
  • Montgomery, D. C. and Runger, G. C. (1996). “Foldovers of 2k–p Resolution IV Experimental Designs”. Journal of Quality Technology 28, pp. 446–450.
  • Morris, M. (2000). “A Class of Three-Level Experimental Designs for Response Surface Modeling”. Technometrics 42 pp. 111–121.
  • Mukerjee, R. and Huda, S. (1985). “Minimax Second and Third-Order Designs to Estimate the Slope of a Response Surface”. Biometrika 72, pp. 173–178.
  • Murty, V. N. and Studden, W. J. (1972). “Optimal Designs for Estimating the Slope of a Polynomial Regression”. Journal of the American Statistical Association 67, pp. 869–873.
  • Myers, R. H. (1991). “Response Surface Methodology in Quality Improvement”. Communications in Statistics—Theory and Methods 20, pp. 457–476.
  • Myers, R. H. (1999). “Response Surface Methodology—Current Status and Future Directions” (with discussion). Journal of Quality Technology 31, pp. 30–44.
  • Myers, R. H. and Carter, W. H. (1973). “Response Surface Techniques for Dual Response Systems”. Technometrics 15. pp. 301–317.
  • Myers, R. H.; Khuri, A. I.; and Carter, W. H. (1989). “Response Surface Methodology: 1966–1988”. Technometrics 31, pp. 137–157.
  • Myers, R. H.; Khuri, A. I.; and Vining, G. G. (1992). “Response Surface Alternatives to the Taguchi Robust Parameter Design Approach”. American Statistician 46, pp. 131–139.
  • Myers, R. H.; Kim, Y.; and Griffiths, K. (1997). “Response Surface Methods and the Use of Noise Variables”. Journal of Quality Technology 29, pp. 429–441.
  • Myers, R. H. and Lahoda, S. J. (1975). “A Generalization of the Response Surface Mean Square Error Criterion with a Specific Application to the Slope”. Technometrics 17, pp. 481–486.
  • Myers, R. H. and Montgomery, D. C. (2002). Response Surface Methodology, Process and Product Optimization Using Designed Experiments 2nd ed. John Wiley & Sons, New York, NY.
  • Myers, R. H.; Montgomery, D. C.; and Vining, G. G. (2002). Generalized Linear Models with Applications in Engineering and the Sciences. John Wiley and Sons, Inc., New York, NY.
  • Myers, W. R.; Myers, R. H.; and Carter, W. H. (1994). “Some Alphabetic Optimal Designs for the Logistic Regression Model”. Journal of Statistical Planning and Inference 42, pp. 57–77.
  • Myers, R. H.; Vining, G. G.; Giovannitti-Jensen, A.; and Myers, S. L. (1992). “Variance Dispersion Properties of Second-Order Response Surface Designs”. Journal of Quality Technology 24, pp. 1–11.
  • Nair, V. N. et al (Editors) (1992). “Taguchi's Parameter Design: A Panel Discussion”. Technometrics 34, pp. 127–161.
  • Nelder, J. A. and Lee, Y. (1991). “Generalized Linear Models for the Analysis of Taguchi-Type Experiments”. Applied Stochastic Models and Data Analysis 7, pp. 107–120.
  • Nelder, J. A. and Wedderburn, R. W. M. (1972). “Generalized Linear Models”. Journal of the Royal Statistical Society A 135, pp. 370–384.
  • Nelson, B. J.; Montgomery, D. C.; Elias, R. J.; and Maass, E. (2000). “A Comparison of Several Design Augmentation Strategies”. Quality and Reliability Engineering International 16, pp. 435–449.
  • Nelson, L. S. (1985). “What Do Low F Ratios Tell You?” Journal of Quality Technology 17, pp. 237–238.
  • Nesterov, Y. and Nemirovskii, A. (1994). Interior-Point Polynomial Algorithms in Convex Programming. Society for Industrial and Applied Mathematics, Philadelphia, PA.
  • Nguyen, N.-K. (1996). “An Algorithmic Approach to Generating Supersaturated Designs”. Technometrics 38, pp. 69–73.
  • O'Connell, M.; Haaland, P.; Hardy, S.; and Nychka, D. (1995). “Nonparametric Regression, Kriging, and Process Optimization” in Statistical Modeling Springer Verlag, NY, pp. 207–214.
  • O'Neill, J. C; Borror, C. M.; Eastman, P. Y.; Fradkin, D. G.; James, M. P.; Marks, A. P.; and Montgomery, D. C. (2000). “Optimal Assignment of Samples to Treatments for Robust Design”. Quality and Reliability Engineering International 16, pp. 417–22.
  • Pan, G. and Santner, T. J. (1998). “Selection and Screening Procedures to Determine Optimal Product Designs”. Journal of Statistical Planning and Inference 67, pp. 311–330.
  • Park, S. H. (1987). “A Class of Multifactor Designs for Estimating the Slope of Response Surfaces”. Technometrics 29, pp. 449–453.
  • Peipel, G. and anderson, C. M. (1992). “Variance Dispersion Graphs for Designs on Polyhedral Regions”. Proceedings of the Section on Physical and Engineering Sciences American Statistical Association, Alexandria, VA. pp. 111–117.
  • Peipel, G.; Anderson, C. M.; and Redgate, P. E. (1993a). “Variance Dispersion Graphs for Designs on Polyhedral Regions—Revisited”. Proceedings of the Section on Physical and Engineering Sciences American Statistical Association, Alexandria, VA, pp. 102–107.
  • Peipel, G.; Anderson, C. M.; and Redgate, P. E. (1993b). “Response Surface Designs for Irregularly-Shaped Regions (Parts 1, 2, and 3)”. Proceedings of the Section on Physical and Engineering Sciences American Statistical Association, Alexandria, VA, pp. 205–227.
  • Phadke, M. S. (1989). Quality Engineering Using Robust Design. Prentice Hall, Englewood Cliffs, NJ.
  • Pignatiello, J. J., Jr. (1993). “Strategies for Robust Multiresponse Quality Engineering”. IIE Transactions 25, pp. 5–15.
  • Pignatiello, J. J., Jr. and Ramberg, J. S. (1991). “Top Ten Triumphs and Tragedies of Genichi Taguchi”. Quality Engineering 4, pp. 211–225.
  • Pledger, M. (1996). “Observable Uncontrollable Factors in Parameter Design”. Journal of Quality Technology 28, pp. 153–162.
  • Remmenga, M. D. and Johnson, D. E. (1995). “A Comparison of Inference Procedures in Unbalanced Split-Plot Designs”. Journal of Statistical Computation and Simulation 51, pp. 353–367.
  • Rice, J. (1995). Mathematical Statistics and Data Analysis 2nd ed. Wadsworth & Brooks/Cole, Pacific Grove, CA.
  • Rosenbaum, P. R. (1994). “Dispersion Effects from Fractional Factorials in Taguchi's Method of Quality Design”. Journal of the Royal Statistical Society B 56, pp. 641–652.
  • Rosenbaum, P. R. (1996). “Some Useful Compound Dispersion Experiments in Quality Design”. Technometrics 38, pp. 354–364.
  • Rosenberger, J. and Kalish, L. (1978). “Optimal Designs for Estimation of Parameters of Logistic Function”. Biometrics 34, pp. 746–756.
  • Sacks, J.; Schiller, S. B.; and Welch, W. J. (1989). “Designs for Computer Experiments”. Technometrics 31, pp. 41–47.
  • Sacks, J.; Welch, W. J.; Mitchell, T. J.; and Wynn, H. P. (1989). “Design and Analysis of Computer Experiments” (with discussion). Statistical Science 4, pp. 409–435.
  • Satterthwaite, F. E. (1959). “Random Balance Experimentation” (with Discussion). Technometrics 1, pp. 111–137.
  • Schoen, E. D. (1999). “Designing Fractional Two-Level Experiments With Nested Error Structures”. Journal of Applied Statistics 26, pp. 495–508.
  • Schoen, E. D. and Wolff, K. (1997). “Design and Analysis of a Fractional 413125 Split-Plot Experiment”. Journal of Applied Statistics 24, pp. 409–419.
  • Shoemaker, A. C. and Tsui, K.-L. (1993). “Response Model Analysis for Robust Design Experiments”. Communications in Statistics—Series A 22, pp. 1037–1064.
  • Shoemaker, A. C; Tsui, K.-L.; and Wu, C. F. J. (1991). “Economical Experimentation Methods for Robust Design”. Technometrics 33, pp. 415–427.
  • Sitter, R. R. (1992). “Robust Designs for Binary Data”. Biometrics 48, pp. 1145–1155.
  • Sitter, R. R. and Torsney, B. (1995). “Optimal Designs for Binary Response Experiments with 2 Design Variables”. Statistica Sinica 5, pp. 405–419.
  • Sitter, R. R. and Wu, C. F. W. (1993). “Optimal Designs for Binary Response Experiments—Fieller, D, and A Criteria”. Scandinavian Journal of Statistics 20, pp. 329–341.
  • Spargo, C. A.; Haaland, P. D.; Jurgensen, S. R.; Shank, D. D.; and Walker, G. T. (1993). “Chemiluminescent Detection of Strand Displacement Amplified DNA From Species Comprising the Microbacterium Tuberculosis Complex”. Molecular and Cellular Probes 7, pp. 395–404.
  • Steinberg, D. M. and Bursztyn (1994). “Dispersion Effects in Robust-Design Experiments with Noise Factors”. Journal of Quality Technology 26, pp. 12–20.
  • Steinberg, D. M. and Bursztyn (1998). “Noise Factors, Dispersion Effects, and Robust Design”. Statistica Sinica 8, pp. 67–85.
  • Steiner, S. H. and Hamada, M. (1997). “Making Mixtures Robust to Noise and Mixing Measurement Errors”. Journal of Quality Technology 29, pp. 441–450.
  • Taguchi, G. (1987). System of Experimental Design: Engineering Methods to Optimize Quality and Minimize Cost. Quality Resources, White Plains, NJ.
  • Taguchi, G. (1991). Introduction to Quality Engineering. UNIPUB/Kraus International, White Plains, New York (Originally published by the Asian Productivity Organization).
  • Taguchi, G. and Wu, Y. (1985). Introduction to Off-Line Quality Control. Central Japan Quality Control Association (available from American Supplier Institute, Dearborn, MI).
  • Trinca, L. A. and Gilmour, S. G. (1998). “Variance Dispersion Graphs for Comparing Blocked Response Surface Designs”. Journal of Quality Technology 30, pp. 314–327.
  • Trinca, L. A. and Gilmour, S. G. (2001). “Multistratum Response Surface Designs”. Technometrics 43, pp. 25–33.
  • Tsui, K.-L. (1996). “A Critical Look at Taguchi's Modelling Approach for Robust Design”. Journal of Applied Statistics 23, pp. 81–95.
  • Vining, G. G. (1993). “A Computer Program for Generating Variance Dispersion Graphs”. Journal of Quality Technology 25, pp. 45–58.
  • Vining, G. G. (1998). “A Compromise Approach to Multiresponse Optimization”. Journal of Quality Technology 30, pp. 309–313.
  • Vining, G. G. and Bohn, L. L. (1998). “Response Surfaces for the Mean and Variance Using a Nonparametric Approach”. Journal of Quality Technology 30, pp. 282–291.
  • Vining, G. G.; Cornell, J.; and Myers, R. H. (1993). “A Graphical Approach for Evaluating Mixture Designs”. Journal of the Royal Statistical Society Series C 42, pp. 127–138.
  • Vining, G. G. and Myers, R. H. (1990). “Combining Taguchi and Response Surface Philosophies: A Dual Response Approach”. Journal of Quality Technology 22, pp. 38–45.
  • Vining, G. G. and Schaub, D. (1996). “Experimental Designs for Estimating Both Mean and Variance Functions”. Journal of Quality Technology 29, pp. 135–147.
  • Vuchkov, I. N. and Boyadjieva, L. N. (1992). “Quality Improvement Through Design of Experiments with Both Product Parameters and External Noise Factors” in Model Oriented Data Analysis edited by V. Fedorov, W. G. Muller, I. N. Vuchkov. Physica-Verlag, Heidelberg, pp. 195–212.
  • Wang, J. C. and Wu, C. F. J. (1995). “A Hidden Projection Property of Plackett-Burman and Related Designs”. Statistica Sinica 5, pp. 235–250.
  • Welch, W. J. (1982). “Branch and Bound Search for Experimental Designs Based on D-Optimality and Other Criteria”. Technometrics 24, pp. 41–18.
  • Welch, W. J.; Buck, R. J.; Sacks, J.; Wynn, H. P.; Mitchell, T. J.; and Morris, M. D. (1992). “Screening, Predicting, and Computer Experiments”. Technometrics 34, pp. 15–25.
  • Welch, W. J.; Yu, T. K.; Kang, S. M.; and Sacks, J. (1990). “Computer Experiments for Quality Control by Parameter Design”. Journal of Quality Technology 22, pp. 15–22.
  • Westfall, P. H.; Young, S. S.; and Lin, D. K. J. (1998). “Forward Selection Error Control in the Analysis of Supersaturated Designs”. Statistica Sinica 8, pp. 101–117.
  • Wolfinger, R. D. and Tobias, R. D. (1998). “Joint Estimation of Location, Dispersion, and Random Effects in Robust Design”. Technometrics 40, pp. 62–71.
  • Wu, C. F. J. (1993). “Construction of Supersaturated Designs Through Partially Aliased Interactions”. Biometrika 80, pp. 661–369.
  • Wu, C. F. J. and Ding, Y. (1998). “Construction of Response Surface Designs for Qualitative and Quantitative Factors”. Journal of Statistical Planning Inference 71, pp. 331–348.
  • Yamada, S. and Lin, D. K. J. (1997). “Supersaturated Designs Including an Orthogonal Base”. Canadian Journal of Statistics 25, pp. 203–213.
  • Ying, L. A.; Pukelsheim, F.; and Draper, N. R. (1995a). “Slope Rotatability over all Directions Designs”. Journal of Applied Statistics 22, pp. 331–341.
  • Ying, L. A.; Pukelsheim, F.; and Draper, N. R. (1995b). “Slope Rotatability over all Directions Designs for k > 4”. Journal of Applied Statistics 22, pp. 343–354.
  • Zahran, A.; Anderson-Cook, C. M.; and Myers, R. H. (2003). “Fraction of Design Space to Assess Prediction Capability of Response Surface Designs”. Journal of Quality Technology 35, pp. 377–386.
  • Zhou, J. (2001). “A Robust Criterion for Experimental Designs for Serially Correlated Observations”. Technometrics 43, pp. 462–467.

Reprints and Corporate Permissions

Please note: Selecting permissions does not provide access to the full text of the article, please see our help page How do I view content?

To request a reprint or corporate permissions for this article, please click on the relevant link below:

Order Reprints Request Corporate Permissions

Academic Permissions

Please note: Selecting permissions does not provide access to the full text of the article, please see our help page How do I view content?

Obtain permissions instantly via Rightslink by clicking on the button below:

Request Academic Permissions

If you are unable to obtain permissions via Rightslink, please complete and submit this Permissions form. For more information, please visit our Permissions help page.

Related research

People also read lists articles that other readers of this article have read.

Recommended articles lists articles that we recommend and is powered by our AI driven recommendation engine.

Cited by lists all citing articles based on Crossref citations.
Articles with the Crossref icon will open in a new tab.