Experiments

C. F. JEFF WU, PHD, is Coca-Cola Professor in Engineering Statistics at the Georgia Institute of Technology. Dr. Wu has published more than 180 papers and is the recipient of numerous accolades, including the National Academy of Engineering membership and the COPSS Presidents' Award. MICHAEL S. HAMADA, PHD, is Senior Scientist at Los Alamos National Laboratory (LANL) in New Mexico. Dr. Hamada is a Fellow of the American Statistical Association, a LANL Fellow, and has published more than 160 papers.

Preface to the Third Edition xvii

Preface to the Second Edition xix

Preface to the First Edition xxi

Suggestions of Topics for Instructors xxv

List of Experiments and Data Sets xxvii

About the Companion Website xxxiii

1 Basic Concepts for Experimental Design and Introductory Regression Analysis 1

1.1 Introduction and Historical Perspective 1

1.2 A Systematic Approach to the Planning and Implementation of Experiments 4

1.3 Fundamental Principles: Replication, Randomization, and Blocking 8

1.4 Simple Linear Regression 11

1.5 Testing of Hypothesis and Interval Estimation 14

1.6 Multiple Linear Regression 20

1.7 Variable Selection in Regression Analysis 26

1.8 Analysis of Air Pollution Data 28

1.9 Practical Summary 34

Exercises 35

References 43

2 Experiments with a Single Factor 45

2.1 One-Way Layout 45

*2.1.1 Constraint on the Parameters 50

2.2 Multiple Comparisons 52

2.3 Quantitative Factors and Orthogonal Polynomials 56

2.4 Expected Mean Squares and Sample Size Determination 61

2.5 One-Way Random Effects Model 68

2.6 Residual Analysis: Assessment of Model Assumptions 71

2.7 Practical Summary 76

Exercises 77

References 82

3 Experiments with More than One Factor 85

3.1 Paired Comparison Designs 85

3.2 Randomized Block Designs 88

3.3 Two-Way Layout: Factors with Fixed Levels 92

3.3.1 Two Qualitative Factors: A Regression Modeling Approach 95

*3.4 Two-Way Layout: Factors with Random Levels 98

3.5 Multi-Way Layouts 105

3.6 Latin Square Designs: Two Blocking Variables 108

3.7 Graeco-Latin Square Designs 112

*3.8 Balanced Incomplete Block Designs 113

*3.9 Split-Plot Designs 118

3.10 Analysis of Covariance: Incorporating Auxiliary Information 126

*3.11 Transformation of the Response 130

3.12 Practical Summary 134

Exercises 135

Appendix 3A: Table of Latin Squares, Graeco-Latin Squares, and Hyper-Graeco-Latin Squares 147

References 148

4 Full Factorial Experiments at Two Levels 151

4.1 An Epitaxial Layer Growth Experiment 151

4.2 Full Factorial Designs at Two Levels: A General Discussion 153

4.3 Factorial Effects and Plots 157

4.3.1 Main Effects 158

4.3.2 Interaction Effects 159

4.4 Using Regression to Compute Factorial Effects 165

*4.5 ANOVA Treatment of Factorial Effects 167

4.6 Fundamental Principles for Factorial Effects: Effect Hierarchy, Effect Sparsity, and Effect Heredity 168

4.7 Comparisons with the “One-Factor-at-a-Time” Approach 169

4.8 Normal and Half-Normal Plots for Judging Effect Significance 172

4.9 Lenth’s Method: Testing Effect Significance for Experiments Without Variance Estimates 174

4.10 Nominal-the-Best Problem and Quadratic Loss Function 178

4.11 Use of Log Sample Variance for Dispersion Analysis 179

4.12 Analysis of Location and Dispersion: Revisiting the Epitaxial Layer Growth Experiment 181

*4.13 Test of Variance Homogeneity and Pooled Estimate of Variance 184

*4.14 Studentized Maximum Modulus Test: Testing Effect Significance for Experiments With Variance Estimates 185

4.15 Blocking and Optimal Arrangement of 2k Factorial Designs in 2q Blocks 188

4.16 Practical Summary 193

Exercises 195

Appendix 4A: Table of 2k Factorial Designs in 2q Blocks 201

References 203

5 Fractional Factorial Experiments at Two Levels 205

5.1 A Leaf Spring Experiment 205

5.2 Fractional Factorial Designs: Effect Aliasing and the Criteria of Resolution and Minimum Aberration 206

5.3 Analysis of Fractional Factorial Experiments 212

5.4 Techniques for Resolving the Ambiguities in Aliased Effects 217

5.4.1 Fold-Over Technique for Follow-Up Experiments 218

5.4.2 Optimal Design Approach for Follow-Up Experiments 222

5.5 Conditional Main Effect (CME) Analysis: A Method to Unravel Aliased Interactions 227

5.6 Selection of 2k−p Designs Using Minimum Aberration and Related Criteria 232

5.7 Blocking in Fractional Factorial Designs 236

5.8 Practical Summary 238

Exercises 240

Appendix 5A: Tables of 2k−p Fractional Factorial Designs 252

Appendix 5B: Tables of 2k−p Fractional Factorial Designs in 2q Blocks 258

References 262

6 Full Factorial and Fractional Factorial Experiments at Three Levels 265

6.1 A Seat-Belt Experiment 265

6.2 Larger-the-Better and Smaller-the-Better Problems 267

6.3 3k Full Factorial Designs 268

6.4 3k−pFractional Factorial Designs 273

6.5 Simple Analysis Methods: Plots and Analysis of Variance 277

6.6 An Alternative Analysis Method 282

6.7 Analysis Strategies for Multiple Responses I: Out-Of-Spec Probabilities 291

6.8 Blocking in 3k and 3k−p Designs 299

6.9 Practical Summary 301

Exercises 303

Appendix 6A: Tables of 3k−p Fractional Factorial Designs 309

Appendix 6B: Tables of 3k−p Fractional Factorial Designs in 3q Blocks 310

References 314

7 Other Design and Analysis Techniques for Experiments at More than Two Levels 315

7.1 A Router Bit Experiment Based on a Mixed Two-Level and Four-Level Design 315

7.2 Method of Replacement and Construction of 2m4n Designs 318

7.3 Minimum Aberration 2m4n Designs with n = 1, 2, 321

7.4 An Analysis Strategy for 2m4n Experiments 324

7.5 Analysis of the Router Bit Experiment 326

7.6 A Paint Experiment Based on a Mixed Two-Level and Three-Level Design 329

7.7 Design and Analysis of 36-Run Experiments at Two And Three Levels 332

7.8 rk−pFractional Factorial Designs for any Prime Number r 337

7.8.1 25-Run Fractional Factorial Designs at Five Levels 337

7.8.2 49-Run Fractional Factorial Designs at Seven Levels 340

7.8.3 General Construction 340

7.9 Definitive Screening Designs 341

*7.10 Related Factors: Method of Sliding Levels, Nested Effects Analysis, and Response Surface Modeling 343

7.10.1 Nested Effects Modeling 346

7.10.2 Analysis of Light Bulb Experiment 347

7.10.3 Response Surface Modeling 349

7.10.4 Symmetric and Asymmetric Relationships Between Related Factors 352

7.11 Practical Summary 352

Exercises 353

Appendix 7A: Tables of 2m41 Minimum Aberration Designs 361

Appendix 7B: Tables of 2m42 Minimum Aberration Designs 362

Appendix 7C: OA(25, 56) 364

Appendix 7D: OA(49, 78) 364

Appendix 7E: Conference Matrices C6 C8 C10 C12 C14 and C16 366

References 368

8 Nonregular Designs: Construction and Properties 369

8.1 Two Experiments: Weld-Repaired Castings and Blood Glucose Testing 369

8.2 Some Advantages of Nonregular Designs Over the 2k−p AND 3k−p Series of Designs 370

8.3 A Lemma on Orthogonal Arrays 372

8.4 Plackett–Burman Designs and Hall’s Designs 373

8.5 A Collection of Useful Mixed-Level Orthogonal Arrays 377

*8.6 Construction of Mixed-Level Orthogonal Arrays Based on Difference Matrices 379

8.6.1 General Method for Constructing Asymmetrical Orthogonal Arrays 380

*8.7 Construction of Mixed-Level Orthogonal Arrays Through the Method of Replacement 382

8.8 Orthogonal Main-Effect Plans Through Collapsing Factors 384

8.9 Practical Summary 388

Exercises 389

Appendix 8A: Plackett–Burman Designs OA(N, 2N−1) with 12 ≤ N ≤ 48 and N = 4 k but not a Power of 2 394

Appendix 8B: Hall’S 16-Run Orthogonal Arrays of Types II to V 397

Appendix 8C: Some Useful Mixed-Level Orthogonal Arrays 399

Appendix 8D: Some Useful Difference Matrices 411

Appendix 8E: Some Useful Orthogonal Main-Effect Plans 413

References 414

9 Experiments with Complex Aliasing 417

9.1 Partial Aliasing of Effects and the Alias Matrix 417

9.2 Traditional Analysis Strategy: Screening Design and Main Effect Analysis 420

9.3 Simplification of Complex Aliasing via Effect Sparsity 421

9.4 An Analysis Strategy for Designs with Complex Aliasing 422

9.4.1 Some Limitations 428

*9.5 A Bayesian Variable Selection Strategy for Designs with Complex Aliasing 429

9.5.1 Bayesian Model Priors 431

9.5.2 Gibbs Sampling 432

9.5.3 Choice of Prior Tuning Constants 434

9.5.4 Blood Glucose Experiment Revisited 435

9.5.5 Other Applications 437

*9.6 Supersaturated Designs: Design Construction and Analysis 437

9.7 Practical Summary 441

Exercises 442

Appendix 9A: Further Details for the Full Conditional Distributions 451

References 453

10 Response Surface Methodology 455

10.1 A Ranitidine Separation Experiment 455

10.2 Sequential Nature of Response Surface Methodology 457

10.3 From First-Order Experiments to Second-Order Experiments: Steepest Ascent Search and Rectangular Grid Search 460

10.3.1 Curvature Check 460

10.3.2 Steepest Ascent Search 461

10.3.3 Rectangular Grid Search 466

10.4 Analysis of Second-Order Response Surfaces 469

10.4.1 Ridge Systems 470

10.5 Analysis of the Ranitidine Experiment 472

10.6 Analysis Strategies for Multiple Responses II: Contour Plots and the Use of Desirability Functions 475

10.7 Central Composite Designs 478

10.8 Box–Behnken Designs and Uniform Shell Designs 483

10.9 Practical Summary 486

Exercises 488

Appendix 10A: Table of Central Composite Designs 498

Appendix 10B: Table of Box–Behnken Designs 500

Appendix 10C: Table of Uniform Shell Designs 501

References 502

11 Introduction to Robust Parameter Design 503

11.1 A Robust Parameter Design Perspective of the Layer Growth and Leaf Spring Experiments 503

11.1.1 Layer Growth Experiment Revisited 503

11.1.2 Leaf Spring Experiment Revisited 504

11.2 Strategies for Reducing Variation 506

11.3 Noise (Hard-to-Control) Factors 508

11.4 Variation Reduction Through Robust Parameter Design 510

11.5 Experimentation and Modeling Strategies I: Cross Array 512

11.5.1 Location and Dispersion Modeling 513

11.5.2 Response Modeling 518

11.6 Experimentation and Modeling Strategies II: Single Array and Response Modeling 523

11.7 Cross Arrays: Estimation Capacity and Optimal Selection 526

11.8 Choosing Between Cross Arrays and Single Arrays 529

*11.8.1 Compound Noise Factor 533

11.9 Signal-to-Noise Ratio and Its Limitations for Parameter Design Optimization 534

11.9.1 SN Ratio Analysis of Layer Growth Experiment 536

*11.10 Further Topics 537

11.11 Practical Summary 539

Exercises 541

References 550

12 Analysis of Experiments with Nonnormal Data 553

12.1 A Wave Soldering Experiment with Count Data 553

12.2 Generalized Linear Models 554

12.2.1 The Distribution of the Response 555

12.2.2 The Form of the Systematic Effects 557

12.2.3 GLM versus Transforming the Response 558

12.3 Likelihood-Based Analysis of Generalized Linear Models 558

12.4 Likelihood-Based Analysis of theWave Soldering Experiment 562

12.5 Bayesian Analysis of Generalized Linear Models 564

12.6 Bayesian Analysis of the Wave Soldering Experiment 565

12.7 Other Uses and Extensions of Generalized Linear Models and Regression Models for Nonnormal Data 567

*12.8 Modeling and Analysis for Ordinal Data 567

12.8.1 The Gibbs Sampler for Ordinal Data 569

*12.9 Analysis of Foam Molding Experiment 572

12.10 Scoring: A Simple Method for Analyzing Ordinal Data 575

12.11 Practical Summary 576

Exercises 577

References 587

13 Practical Optimal Design 589

13.1 Introduction 589

13.2 A Design Criterion 590

13.3 Continuous and Exact Design 590

13.4 Some Design Criteria 592

13.4.1 Nonlinear Regression Model, Generalized Linear Model, and Bayesian Criteria 593

13.5 Design Algorithms 595

13.5.1 Point Exchange Algorithm 595

13.5.2 Coordinate Exchange Algorithm 596

13.5.3 Point and Coordinate Exchange Algorithms for Bayesian Designs 596

13.5.4 Some Design Software 597

13.5.5 Some Practical Considerations 597

13.6 Examples 598

13.6.1 A Quadratic Regression Model in One Factor 598

13.6.2 Handling a Constrained Design Region 598

13.6.3 Augmenting an Existing Design 598

13.6.4 Handling an Odd-Sized Run Size 600

13.6.5 Blocking from Initially Running a Subset of a Designed Experiment 601

13.6.6 A Nonlinear Regression Model 605

13.6.7 A Generalized Linear Model 605

13.7 Practical Summary 606

Exercises 607

References 608

14 Computer Experiments 611

14.1 An Airfoil Simulation Experiment 611

14.2 Latin Hypercube Designs (LHDs) 613

14.2.1 Orthogonal Array-Based Latin Hypercube Designs 617

14.3 Latin Hypercube Designs with Maximin Distance or Maximum Projection Properties 619

14.4 Kriging: The Gaussian Process Model 622

14.5 Kriging: Prediction and Uncertainty Quantification 625

14.5.1 Known Model Parameters 626

14.5.2 Unknown Model Parameters 627

14.5.3 Analysis of Airfoil Simulation Experiment 629

14.6 Expected Improvement 631

14.6.1 Optimization of Airfoil Simulation Experiment 633

14.7 Further Topics 634

14.8 Practical Summary 636

Exercises 637

Appendix 14A: Derivation of the Kriging Equations (14.10) and (14.11) 643

Appendix 14B: Derivation of the EI Criterion (14.22) 644 References 645

Appendix A Upper Tail Probabilities of the Standard Normal Distribution ∫ ∞z 1/√2𝜋e−u2∕2du 647

Appendix B Upper Percentiles of the t Distribution 649

Appendix C Upper Percentiles of the 𝜒 2 Distribution 651

Appendix D Upper Percentiles of the F Distribution 653

Appendix E Upper Percentiles of the Studentized Range Distribution 661

Appendix F Upper Percentiles of the Studentized Maximum Modulus Distribution 669

Appendix G Coefficients of Orthogonal Contrast Vectors 683

Appendix H Critical Values for Lenth’s Method 685

Author Index 689

Subject Index 693