Applied Statistics and Probability for Engineers (Loose Leaf, 7)

· 제목 : Applied Statistics and Probability for Engineers (Loose Leaf, 7) 
· 분류 : 외국도서 > 기술공학 > 기술공학 > 산업공학
· ISBN : 9781119746355
· 쪽수 : 720쪽

1 The Role of Statistics in Engineering 1

1.1 The Engineering Method and Statistical Thinking 2

1.1.1 Variability 3

1.1.2 Populations and Samples 5

1.2 Collecting Engineering Data 5

1.2.1 Basic Principles 5

1.2.2 Retrospective Study 5

1.2.3 Observational Study 6

1.2.4 Designed Experiments 6

1.2.5 Observing Processes Over Time 9

1.3 Mechanistic and Empirical Models 12

1.4 Probability and Probability Models 15

2 Probability 17

2.1 Sample Spaces and Events 18

2.1.1 Random Experiments 18

2.1.2 Sample Spaces 19

2.1.3 Events 21

2.2 Counting Techniques 23

2.3 Interpretations and Axioms of Probability 26

2.4 Unions of Events and Addition Rules 29

2.5 Conditional Probability 31

2.6 Intersections of Events and Multiplication and Total Probability Rules 34

2.7 Independence 36

2.8 Bayes’ Theorem 39

2.9 Random Variables 40

3 Discrete Random Variables and Probability Distributions 42

3.1 Probability Distributions and Probability Mass Functions 43

3.2 Cumulative Distribution Functions 45

3.3 Mean and Variance of a Discrete Random Variable 47

3.4 Discrete Uniform Distribution 49

3.5 Binomial Distribution 51

3.6 Geometric and Negative Binomial Distributions 55

3.7 Hypergeometric Distribution 59

3.8 Poisson Distribution 63

4 Continuous Random Variables and Probability Distributions 66

4.1 Probability Distributions and Probability Density Functions 67

4.2 Cumulative Distribution Functions 70

4.3 Mean and Variance of a Continuous Random Variable 71

4.4 Continuous Uniform Distribution 72

4.5 Normal Distribution 73

4.6 Normal Approximation to the Binomial and Poisson Distributions 79

4.7 Exponential Distribution 83

4.8 Erlang and Gamma Distributions 86

4.9 Weibull Distribution 89

4.10 Lognormal Distribution 90

4.11 Beta Distribution 92

5 Joint Probability Distributions 95

5.1 Joint Probability Distributions for Two Random Variables 96

5.2 Conditional Probability Distributions and Independence 102

5.3 Joint Probability Distributions for More Than Two Random Variables 107

5.4 Covariance and Correlation 110

5.5 Common Joint Distributions 113

5.5.1 Multinomial Probability Distribution 113

5.5.2 Bivariate Normal Distribution 115

5.6 Linear Functions of Random Variables 117

5.7 General Functions of Random Variables 120

5.8 Moment-Generating Functions 121

6 Descriptive Statistics 126

6.1 Numerical Summaries of Data 127

6.2 Stem-and-Leaf Diagrams 131

6.3 Frequency Distributions and Histograms 135

6.4 Box Plots 139

6.5 Time Sequence Plots 140

6.6 Scatter Diagrams 142

6.7 Probability Plots 144

7 Point Estimation of Parameters and Sampling Distributions 148

7.1 Point Estimation 149

7.2 Sampling Distributions and the Central Limit Theorem 150

7.3 General Concepts of Point Estimation 156

7.3.1 Unbiased Estimators 156

7.3.2 Variance of a Point Estimator 157

7.3.3 Standard Error: Reporting a Point Estimate 158

7.3.4 Bootstrap Standard Error 159

7.3.5 Mean Squared Error of an Estimator 160

7.4 Methods of Point Estimation 161

7.4.1 Method of Moments 162

7.4.2 Method of Maximum Likelihood 163

7.4.3 Bayesian Estimation of Parameters 167

8 Statistical Intervals for a Single Sample 170

8.1 Confidence Interval on the Mean of a Normal Distribution, Variance Known 172

8.1.1 Development of the Confidence Interval and Its Basic Properties 172

8.1.2 Choice of Sample Size 175

8.1.3 One-Sided Confidence Bounds 176

8.1.4 General Method to Derive a Confidence Interval 176

8.1.5 Large-Sample Confidence Interval for μ 177

8.2 Confidence Interval on the Mean of a Normal Distribution, Variance Unknown 179

8.2.1 t Distribution 180

8.2.2 t Confidence Interval on μ 181

8.3 Confidence Interval on the Variance and Standard Deviation of a Normal Distribution 182

8.4 Large-Sample Confidence Interval for a Population Proportion 185

8.5 Guidelines for Constructing Confidence Intervals 188

8.6 Bootstrap Confidence Interval 189

8.7 Tolerance and Prediction Intervals 189

8.7.1 Prediction Interval for a Future Observation 189

8.7.2 Tolerance Interval for a Normal Distribution 191

9 Tests of Hypotheses for a Single Sample 193

9.1 Hypothesis Testing 194

9.1.1 Statistical Hypotheses 194

9.1.2 Tests of Statistical Hypotheses 196

9.1.3 One-Sided and Two-Sided Hypotheses 202

9.1.4 P-Values in Hypothesis Tests 203

9.1.5 Connection between Hypothesis Tests and Confidence Intervals 206

9.1.6 General Procedure for Hypothesis Tests 206

9.2 Tests on the Mean of a Normal Distribution, Variance Known 208

9.2.1 Hypothesis Tests on the Mean 208

9.2.2 Type II Error and Choice of Sample Size 211

9.2.3 Large-Sample Test 215

9.3 Tests on the Mean of a Normal Distribution, Variance Unknown 215

9.3.1 Hypothesis Tests on the Mean 215

9.3.2 Type II Error and Choice of Sample Size 220

9.4 Tests on the Variance and Standard Deviation of a Normal Distribution 222

9.4.1 Hypothesis Tests on the Variance 222

9.4.2 Type II Error and Choice of Sample Size 224

9.5 Tests on a Population Proportion 225

9.5.1 Large-Sample Tests on a Proportion 225

9.5.2 Type II Error and Choice of Sample Size 227

9.6 Summary Table of Inference Procedures for a Single Sample 229

9.7 Testing for Goodness of Fit 229

9.8 Contingency Table Tests 232

9.9 Nonparametric Procedures 234

9.9.1 The Sign Test 235

9.9.2 The Wilcoxon Signed-Rank Test 239

9.9.3 Comparison to the t-Test 240

9.10 Equivalence Testing 240

9.11 Combining P-Values 242

10 Statistical Inference for Two Samples 244

10.1 Inference on the Difference in Means of Two Normal Distributions, Variances Known 245

10.1.1 Hypothesis Tests on the Difference in Means, Variances Known 247

10.1.2 Type II Error and Choice of Sample Size 249

10.1.3 Confidence Interval on the Difference in Means, Variances Known 251

10.2 Inference on the Difference in Means of Two Normal Distributions, Variances Unknown 253

10.2.1 Hypotheses Tests on the Difference in Means, Variances Unknown 253

10.2.2 Type II Error and Choice of Sample Size 259

10.2.3 Confidence Interval on the Difference in Means, Variances Unknown 260

10.3 A Nonparametric Test for the Difference in Two Means 261

10.3.1 Description of the Wilcoxon Rank-Sum Test 262

10.3.2 Large-Sample Approximation 263

10.3.3 Comparison to the t-Test 264

10.4 Paired t-Test 264

10.5 Inference on the Variances of Two Normal Distributions 268

10.5.1 F Distribution 268

10.5.2 Hypothesis Tests on the Equity of Two Variances 270

10.5.3 Type II Error and Choice of Sample Size 272

10.5.4 Confidence Interval on the Ratio of Two Variances 273

10.6 Inference on Two Population Proportions 273

10.6.1 Large-Sample Tests on the Difference in Population Proportions 274

10.6.2 Type II Error and Choice of Sample Size 276

10.6.3 Confidence Interval on the Difference in Population Proportions 277

10.7 Summary Table and Road Map for Inference Procedures for Two Samples 278

11 Simple Linear Regression and Correlation 280

11.1 Empirical Models 281

11.2 Simple Linear Regression 284

11.3 Properties of the Least Squares Estimators 288

11.4 Hypothesis Tests in Simple Linear Regression 288

11.4.1 Use of t-Tests 289

11.4.2 Analysis of Variance Approach to Test Significance of Regression 291

11.5 Confidence Intervals 292

11.5.1 Confidence Intervals on the Slope and Intercept 292

11.5.2 Confidence Interval on the Mean Response 293

11.6 Prediction of New Observations 295

11.7 Adequacy of the Regression Model 296

11.7.1 Residual Analysis 296

11.7.2 Coefficient of Determination (R²) 298

11.8 Correlation 299

11.9 Regression on Transformed Variables 303

11.10 Logistic Regression 305

12 Multiple Linear Regression 310

12.1 Multiple Linear Regression Model 311

12.1.1 Introduction 311

12.1.2 Least Squares Estimation of the Parameters 314

12.1.3 Matrix Approach to Multiple Linear Regression 316

12.1.4 Properties of the Least Squares Estimators 321

12.2 Hypothesis Tests in Multiple Linear Regression 322

12.2.1 Test for Significance of Regression 322

12.2.2 Tests on Individual Regression Coefficients and Subsets of Coefficients 325

12.3 Confidence Intervals in Multiple Linear Regression 329

12.3.1 Confidence Intervals on Individual Regression Coefficients 329

12.3.2 Confidence Interval on the Mean Response 330

12.4 Prediction of New Observations 331

12.5 Model Adequacy Checking 333

12.5.1 Residual Analysis 333

12.5.2 Influential Observations 335

12.6 Aspects of Multiple Regression Modeling 337

12.6.1 Polynomial Regression Models 337

12.6.2 Categorical Regressors and Indicator Variables 339

12.6.3 Selection of Variables and Model Building 341

12.6.4 Multicollinearity 349

13 Design and Analysis of Single-Factor Experiments: The Analysis of Variance 351

13.1 Designing Engineering Experiments 352

13.2 Completely Randomized Single-Factor Experiment 353

13.2.1 Example: Tensile Strength 353

13.2.2 Analysis of Variance 354

13.2.3 Multiple Comparisons Following the ANOVA 359

13.2.4 Residual Analysis and Model Checking 361

13.2.5 Determining Sample Size 363

13.3 The Random-Effects Model 365

13.3.1 Fixed Versus Random Factors 365

13.3.2 ANOVA and Variance Components 365

13.4 Randomized Complete Block Design 368

13.4.1 Design and Statistical Analysis 368

13.4.2 Multiple Comparisons 372

13.4.3 Residual Analysis and Model Checking 373

14 Design of Experiments with Several Factors 375

14.1 Introduction 376

14.2 Factorial Experiments 378

14.3 Two-Factor Factorial Experiments 382

14.3.1 Statistical Analysis 382

14.3.2 Model Adequacy Checking 386

14.3.3 One Observation per Cell 387

14.4 General Factorial Experiments 388

14.5 2^k Factorial Designs 390

14.5.1 2² Design 390

14.5.2 2^k Design for k ≥ 3 Factors 396

14.6 Single Replicate of the 2^k Design 402

14.7 Addition of Center Points to a 2^k Design 405

14.8 Blocking and Confounding in the 2^k Design 408

14.9 One-Half Fraction of the 2^k Design 413

14.10 Smaller Fractions: The 2^k−p Fractional Factorial 418

14.11 Response Surface Methods and Designs 425

15 Statistical Quality Control 434

15.1 Quality Improvement and Statistics 435

15.1.1 Statistical Quality Control 436

15.1.2 Statistical Process Control 436

15.2 Introduction to Control Charts 436

15.2.1 Basic Principles 436

15.2.2 Design of a Control Chart 440

15.2.3 Rational Subgroups 441

15.2.4 Analysis of Patterns on Control Charts 442

15.3 X and R or S Control Charts 444

15.4 Control Charts for Individual Measurements 450

15.5 Process Capability 452

15.6 Attribute Control Charts 456

15.6.1 P Chart (Control Chart for Proportions) 456

15.6.2 U Chart (Control Chart for Defects per Unit) 458

15.7 Control Chart Performance 460

15.8 Time-Weighted Charts 462

15.8.1 Exponentially Weighted Moving-Average Control Chart 462

15.8.2 Cumulative Sum Control Chart 465

15.9 Other SPC Problem-Solving Tools 471

15.10 Decision Theory 473

15.10.1 Decision Models 473

15.10.2 Decision Criteria 474

15.11 Implementing SPC 476

Appendix A Statistical Tables and Charts A-3

Table I Summary of Common Probability Distributions A-4

Table II Cumulative Binomial Probabilities P(X ≤ x) A-5

Table III Cumulative Standard Normal Distribution A-8

Table IV Percentage Points χ²_α,v of the Chi-Squared Distribution A-10

Table V Percentage Points t_α,v of the t Distribution A-11

Table VI Percentage Points f_α,v1,v2 of the F Distribution A-12

Chart VII Operating Characteristic Curves A-17

Table VIII Critical Values for the Sign Test A-26

Table IX Critical Values for the Wilcoxon Signed-Rank Test A-26

Table X Critical Values for the Wilcoxon Rank-Sum Test A-27

Table XI Factors for Constructing Variables Control Charts A-28

Table XII Factors for Tolerance Intervals A-29

Appendix B Bibliography A-31

Appendix C Summary of Confidence Intervals and Hypothesis Testing Equations for One and Two Sample Applications A-33

Glossary G-1

Exercises P-1

Index I-1