Description

Book Synopsis


Table of Contents

Preface xv

Introduction 1

Why Study Probability? 1

Software Use in Probability 2

Modern Application of Classic Probability Problems 2

Applications to Business 3

Applications to the Life Sciences 4

Applications to Engineering and Operations Research 4

Applications to Finance 6

Probability in Everyday Life 7

1 Introduction to Probability 13

Introduction 13

1.1 Sample Spaces and Events 13

The Sample Space of an Experiment 13

Events 15

Some Relations from Set Theory 16

Exercises Section 1.1 (1–12) 18

1.2 Axioms Interpretations and Properties of Probability 19

Interpreting Probability 21

More Probability Properties 23

Contingency Tables 25

Determining Probabilities Systematically 26

Equally Likely Outcomes 27

Exercises Section 1.2 (13–30) 28

1.3 Counting Methods 30

The Fundamental Counting Principle 31

Tree Diagrams 32

Permutations 33

Combinations 34

Partitions 38

Exercises Section 1.3 (31–50) 39

Supplementary Exercises (51–62) 42

2 Conditional Probability and Independence 45

Introduction 45

2.1 Conditional Probability 45

The Definition of Conditional Probability 46

The Multiplication Rule for P(A ∩ B) 49

2.2 The Law of Total Probability and Bayes’ Theorem 52

The Law of Total Probability 52

Bayes’ Theorem 55

Exercises Section 2.2 (17–32) 59

2.3 Independence 61

The Multiplication Rule for Independent Events 63

Independence of More Than Two Events 65

Exercises Section 2.3 (33–54) 66

2.4 Simulation of Random Events 69

The Backbone of Simulation: Random Number Generators 70

Precision of Simulation 73

Exercises Section 2.4 (55–74) 74

Supplementary Exercises (75–100) 77

3 Discrete Probability Distributions:general Properties 82

Introduction 82

3.1 Random Variables 82

Two Types of Random Variables 84

Exercises Section 3.1 (1–10) 85

3.2 Probability Distributions for Discrete Random Variables 86

Another View of Probability Mass Functions 89

Exercises Section 3.2 (11–21) 90

3.3 The Cumulative Distribution Function 91

Exercises Section 3.3 (22–30) 95

3.4 Expected Value and Standard Deviation 96

The Expected Value of X 97

The Expected Value of a Function 99

The Variance and Standard Deviation of X 102

Properties of Variance 104

Exercises Section 3.4 (31–50) 105

3.5 Moments and Moment Generating Functions 108

The Moment Generating Function 109

Obtaining Moments from the MGF 111

Exercises Section 3.5 (51–64) 113

3.6 Simulation of Discrete Random Variables 114

Simulations Implemented in R and Matlab 117

Simulation Mean Standard Deviation and Precision 117

Exercises Section 3.6 (65–74) 119

Supplementary Exercises (75–84) 120

4 Families of Discrete Distributions 122

Introduction 122

4.1 Parameters and Families of Distributions 122

Exercises Section 4.1 (1–6) 124

4.2 The Binomial Distribution 125

The Binomial Random Variable and Distribution 127

Computing Binomial Probabilities 129

The Mean Variance and Moment Generating Function 130

Binomial Calculations with Software 132

Exercises Section 4.2 (7–34) 132

4.3 The Poisson Distribution 136

The Poisson Distribution as a Limit 137

The Mean Variance and Moment Generating Function 139

The Poisson Process 140

Poisson Calculations with Software 141

Exercises Section 4.3 (35–54) 142

4.4 The Hypergeometric Distribution 145

Mean and Variance 148

Hypergeometric Calculations with Software 149

Exercises Section 4.4 (55–64) 149

4.5 The Negative Binomial and Geometric Distributions 151

The Geometric Distribution 152

Mean Variance and Moment Generating Function 152

Alternative Definitions of the Negative Binomial Distribution 153

Negative Binomial Calculations with Software 154

Exercises Section 4.5 (65–78) 154

Supplementary Exercises (79–100) 156

5 Continuous Probability Distributions:general Properties 160

Introduction 160

5.1 Continuous Random Variables and Probability Density Functions 160

Probability Distributions for Continuous Variables 161

Exercises Section 5.1 (1–8) 165

5.2 The Cumulative Distribution Function and Percentiles 166

Using F(x) to Compute Probabilities 168

Obtaining f(x) fromF(x) 169

Percentiles of a Continuous Distribution 169

Exercises Section 5.2 (9–18) 171

5.3 Expected Values Variance and Moment Generating Functions 173

Expected Values 173

Variance and Standard Deviation 175

Properties of Expectation and Variance 176

Moment Generating Functions 177

Exercises Section 5.3 (19–38) 179

5.4 Transformation of a Random Variable 181

Exercises Section 5.4 (39–54) 185

5.5 Simulation of Continuous Random Variables 186

The Inverse CDF Method 186

The Accept–Reject Method 189

Precision of Simulation Results 191

Exercises Section 5.5 (55–63) 191

Supplementary Exercises (64–76) 193

6 Families of Continuous Distributions 196

Introduction 196

6.1 The Normal (Gaussian) Distribution 196

The Standard Normal Distribution 197

Arbitrary Normal Distributions 199

The Moment Generating Function 203

Normal Distribution Calculations with Software 204

Exercises Section 6.1 (1–27) 205

6.2 Normal Approximation of Discrete Distributions 208

Approximating the Binomial Distribution 209

Exercises Section 6.2 (28–36) 211

6.3 The Exponential and Gamma Distributions 212

The Exponential Distribution 212

The Gamma Distribution 214

The Gamma and Exponential MGFs 217

Gamma and Exponential Calculations with Software 218

Exercises Section 6.3 (37–50) 218

6.4 Other Continuous Distributions 220

The Weibull Distribution 220

The Lognormal Distribution 222

The Beta Distribution 224

Exercises Section 6.4 (51–66) 226

6.5 Probability Plots 228

Sample Percentiles 228

A Probability Plot 229

Departures from Normality 232

Beyond Normality 234

Probability Plots in Matlab and R 236

Exercises Section 6.5 (67–76) 237

Supplementary Exercises (77–96) 238

7 Joint Probability Distributions 242

Introduction 242

7.1 Joint Distributions for Discrete Random Variables 242

The Joint Probability Mass Function for Two Discrete Random Variables 242

Marginal Probability Mass Functions 244

Independent Random Variables 245

More Than Two Random Variables 246

Exercises Section 7.1 (1–12) 248

7.2 Joint Distributions for Continuous Random Variables 250

The Joint Probability Density Function for Two Continuous Random Variables 250

Marginal Probability Density Functions 252

Independence of Continuous Random Variables 254

More Than Two Random Variables 255

Exercises Section 7.2 (13–22) 257

7.3 Expected Values Covariance and Correlation 258

Properties of Expected Value 260

Covariance 261

Correlation 263

Correlation Versus Causation 265

Exercises Section 7.3 (23–42) 266

7.4 Properties of Linear Combinations 267

Expected Value and Variance of a Linear Combination 268

The PDF of a Sum 271

Moment Generating Functions of Linear Combinations 273

Exercises Section 7.4 (43–65) 275

7.5 The Central Limit Theorem and the Law of Large Numbers 278

Random Samples 278

The Central Limit Theorem 282

A More General Central Limit Theorem 286

Other Applications of the Central Limit Theorem 287

The Law of Large Numbers 288

Proof of the Central Limit Theorem 290

Exercises Section 7.5 (66–82) 290

7.6 Simulation of Joint Probability Distributions 293

Simulating Values from a Joint PMF 293

Simulating Values from a Joint PDF 295

Exercises Section 7.6 (83–90) 297

Supplementary Exercises (91–124) 298

8 Joint Probability Distributions:additional Topics 304

Introduction 304

8.1 Conditional Distributions and Expectation 304

Conditional Distributions and Independence 306

Conditional Expectation and Variance 307

The Laws of Total Expectation and Variance 308

Exercises Section 8.1 (1–18) 313

8.2 The Bivariate Normal Distribution 315

Conditional Distributions of X and Y 317

Regression to the Mean 318

The Multivariate Normal Distribution 319

Bivariate Normal Calculations with Software 319

Exercises Section 8.2 (19–30) 320

8.3 Transformations of Jointly Distributed Random Variables 321

The Joint Distribution of Two New Random Variables 322

The Distribution of a Single New RV 323

The Joint Distribution of More Than Two New Variables 325

Exercises Section 8.3 (31–38) 326

8.4 Reliability 327

The Reliability Function 327

Series and Parallel System Designs 329

Mean Time to Failure 331

The Hazard Function 332

Exercises Section 8.4 (39–50) 335

8.5 Order Statistics 337

The Distributions of Yn and Y1 337

The Distribution of the ith Order Statistic 339

The Joint Distribution of All n Order Statistics 340

Exercises Section 8.5 (51–60) 342

8.6 Further Simulation Tools for Jointly Distributed Random Variables 343

The Conditional Distribution Method of Simulation 343

Simulating a Bivariate Normal Distribution 344

Simulation Methods for Reliability 346

Exercises Section 8.6 (61–68) 347

Supplementary Exercises (69–82) 348

9 the Basics of Statistical Inference 351

Introduction 351

9.1 Point Estimation 351

Estimates and Estimators 352

Assessing Estimators: Accuracy and Precision 354

Exercises Section 9.1 (1–18) 357

9.2 Maximum Likelihood Estimation 360

Some Properties of MLEs 366

Exercises Section 9.2 (19–30) 367

9.3 Statistical Intervals 368

Constructing a Confidence Interval 369

Confidence Intervals for a Population Proportion 369

Confidence Intervals for a Population Mean 371

Further Comments on Statistical Intervals 375

Confidence Intervals with Software 375

Exercises Section 9.3 (31–48) 376

9.4 Hypothesis Tests 379

Hypotheses and Test Procedures 380

Hypothesis Testing for a Population Mean 381

Errors in Hypothesis Testing and the Power of a Test 385

Hypothesis Testing for a Population Proportion 388

Software for Hypothesis Test Calculations 389

Exercises Section 9.4 (49–71) 391

9.5 Bayesian Estimation 393

The Posterior Distribution of a Parameter 394

Inferences from the Posterior Distribution 397

Further Comments on Bayesian Inference 398

Exercises Section 9.5 (72–80) 399

9.6 Simulation-Based Inference 400

The Bootstrap Method 400

Interval Estimation Using the Bootstrap 402

Hypothesis Tests Using the Bootstrap 404

More on Simulation-Based Inference 405

Exercises Section 9.6 (81–90) 405

Supplementary Exercises (91–116) 407

10 Markov Chains 411

Introduction 411

10.1 Terminology and Basic Properties 411

The Markov Property 413

Exercises Section 10.1 (1–10) 416

10.2 The Transition Matrix and the Chapman–Kolmogorov Equations 418

The Transition Matrix 418

Computation of Multistep Transition Probabilities 419

Exercises Section 10.2 (11–22) 423

10.3 Specifying an Initial Distribution 426

A Fixed Initial State 428

Exercises Section 10.3 (23–30) 429

10.4 Regular Markov Chains and the Steady-State Theorem 430

Regular Chains 431

The Steady-State Theorem 432

Interpreting the Steady-State Distribution 433

Efficient Computation of Steady-State Probabilities 435

Irreducible and Periodic Chains 437

Exercises Section 10.4 (31–43) 438

10.5 Markov Chains with Absorbing States 440

Time to Absorption 441

Mean Time to Absorption 444

Mean First Passage Times 448

Probabilities of Eventual Absorption 449

Exercises Section 10.5 (44–58) 451

10.6 Simulation of Markov Chains 453

Exercises Section 10.6 (59–66) 459

Supplementary Exercises (67–82) 461

11 Random Processes 465

Introduction 465

11.1 Types of Random Processes 465

Classification of Processes 468

Random Processes and Their Associated Random Variables 469

Exercises Section 11.1 (1–10) 470

11.2 Properties of the Ensemble: Mean and Autocorrelation Functions 471

Mean and Variance Functions 471

Autocovariance and Autocorrelation Functions 475

The Joint Distribution of Two Random Processes 477

Exercises Section 11.2 (11–24) 478

11.3 Stationary and Wide-Sense Stationary Processes 479

Properties of WSS Processes 483

Ergodic Processes 486

Exercises Section 11.3 (25–40) 488

11.4 Discrete-Time Random Processes 489

Special Discrete Sequences 491

Exercises Section 11.4 (41–52) 493

Supplementary Exercises (53–64) 494

12 Families of Random Processes 497

Introduction 497

12.1 Poisson Processes 497

Relation to Exponential and Gamma Distributions 499

Combining and Decomposing Poisson Processes 502

Alternative Definition of a Poisson Process 504

Nonhomogeneous Poisson Processes 505

The Poisson Telegraphic Process 506

Exercises Section 12.1 (1–18) 507

12.2 Gaussian Processes 509

Brownian Motion 510

Brownian Motion as a Limit 512

Further Properties of Brownian Motion 512

Variations on Brownian Motion 514

Exercises Section 12.2 (19–28) 515

12.3 Continuous-Time Markov Chains 516

Infinitesimal Parameters and Instantaneous Transition Rates 518

Sojourn Times and Transitions 520

Long-Run Behavior of Continuous-Time Markov Chains 523

Explicit Form of the Transition Matrix 526

Exercises Section 12.3 (29–40) 527

Supplementary Exercises (41–51) 529

13 Introduction to Signal Processing 532

Introduction 532

13.1 Power Spectral Density 532

Expected Power and the Power Spectral Density 532

Properties of the Power Spectral Density 535

Power in a Frequency Band 538

White Noise Processes 539

Cross-Power Spectral Density for Two Processes 541

Exercises Section 13.1 (1–21) 542

13.2 Random Processes and LTI Systems 544

Properties of the LTI System Output 545

Ideal Filters 548

Signal Plus Noise 551

Exercises Section 13.2 (22–38) 554

13.3 Discrete-Time Signal Processing 556

Random Sequences and LTI Systems 558

Sampling Random Sequences 560

Exercises Section 13.3 (39–50) 562

A Statistical Tables A- 1

A. 1 Binomial CDF A- 1

A. 2 Poisson CDF A- 4

A. 3 Standard Normal CDF A- 5

A. 4 Incomplete Gamma Function A- 7

A. 5 Critical Values for t Distributions A- 7

A. 6 Tail Areas of t Distributions A- 9

B Background Mathematics A- 13

B. 1 Trigonometric Identities A- 13

B. 2 Special Engineering Functions A- 13

B. 3 o(h) Notation A- 14

B. 4 The Delta Function A- 14

B. 5 Fourier Transforms A- 15

B. 6 Discrete-Time Fourier Transforms A- 16

C Important Probability Distributions A- 18

C. 1 Discrete Distributions A- 18

C. 2 Continuous Distributions A- 20

C. 3 Matlab and R Commands A- 23

Bibliography B- 1

Answers to Odd-numbered Exercises S- 1

Index I- 1

Probability with STEM Applications

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    A Paperback / softback by Matthew A. Carlton, Jay L. Devore

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      View other formats and editions of Probability with STEM Applications by Matthew A. Carlton

      Publisher: John Wiley & Sons Inc
      Publication Date: 04/03/2021
      ISBN13: 9781119717867, 978-1119717867
      ISBN10: 1119717868

      Description

      Book Synopsis


      Table of Contents

      Preface xv

      Introduction 1

      Why Study Probability? 1

      Software Use in Probability 2

      Modern Application of Classic Probability Problems 2

      Applications to Business 3

      Applications to the Life Sciences 4

      Applications to Engineering and Operations Research 4

      Applications to Finance 6

      Probability in Everyday Life 7

      1 Introduction to Probability 13

      Introduction 13

      1.1 Sample Spaces and Events 13

      The Sample Space of an Experiment 13

      Events 15

      Some Relations from Set Theory 16

      Exercises Section 1.1 (1–12) 18

      1.2 Axioms Interpretations and Properties of Probability 19

      Interpreting Probability 21

      More Probability Properties 23

      Contingency Tables 25

      Determining Probabilities Systematically 26

      Equally Likely Outcomes 27

      Exercises Section 1.2 (13–30) 28

      1.3 Counting Methods 30

      The Fundamental Counting Principle 31

      Tree Diagrams 32

      Permutations 33

      Combinations 34

      Partitions 38

      Exercises Section 1.3 (31–50) 39

      Supplementary Exercises (51–62) 42

      2 Conditional Probability and Independence 45

      Introduction 45

      2.1 Conditional Probability 45

      The Definition of Conditional Probability 46

      The Multiplication Rule for P(A ∩ B) 49

      2.2 The Law of Total Probability and Bayes’ Theorem 52

      The Law of Total Probability 52

      Bayes’ Theorem 55

      Exercises Section 2.2 (17–32) 59

      2.3 Independence 61

      The Multiplication Rule for Independent Events 63

      Independence of More Than Two Events 65

      Exercises Section 2.3 (33–54) 66

      2.4 Simulation of Random Events 69

      The Backbone of Simulation: Random Number Generators 70

      Precision of Simulation 73

      Exercises Section 2.4 (55–74) 74

      Supplementary Exercises (75–100) 77

      3 Discrete Probability Distributions:general Properties 82

      Introduction 82

      3.1 Random Variables 82

      Two Types of Random Variables 84

      Exercises Section 3.1 (1–10) 85

      3.2 Probability Distributions for Discrete Random Variables 86

      Another View of Probability Mass Functions 89

      Exercises Section 3.2 (11–21) 90

      3.3 The Cumulative Distribution Function 91

      Exercises Section 3.3 (22–30) 95

      3.4 Expected Value and Standard Deviation 96

      The Expected Value of X 97

      The Expected Value of a Function 99

      The Variance and Standard Deviation of X 102

      Properties of Variance 104

      Exercises Section 3.4 (31–50) 105

      3.5 Moments and Moment Generating Functions 108

      The Moment Generating Function 109

      Obtaining Moments from the MGF 111

      Exercises Section 3.5 (51–64) 113

      3.6 Simulation of Discrete Random Variables 114

      Simulations Implemented in R and Matlab 117

      Simulation Mean Standard Deviation and Precision 117

      Exercises Section 3.6 (65–74) 119

      Supplementary Exercises (75–84) 120

      4 Families of Discrete Distributions 122

      Introduction 122

      4.1 Parameters and Families of Distributions 122

      Exercises Section 4.1 (1–6) 124

      4.2 The Binomial Distribution 125

      The Binomial Random Variable and Distribution 127

      Computing Binomial Probabilities 129

      The Mean Variance and Moment Generating Function 130

      Binomial Calculations with Software 132

      Exercises Section 4.2 (7–34) 132

      4.3 The Poisson Distribution 136

      The Poisson Distribution as a Limit 137

      The Mean Variance and Moment Generating Function 139

      The Poisson Process 140

      Poisson Calculations with Software 141

      Exercises Section 4.3 (35–54) 142

      4.4 The Hypergeometric Distribution 145

      Mean and Variance 148

      Hypergeometric Calculations with Software 149

      Exercises Section 4.4 (55–64) 149

      4.5 The Negative Binomial and Geometric Distributions 151

      The Geometric Distribution 152

      Mean Variance and Moment Generating Function 152

      Alternative Definitions of the Negative Binomial Distribution 153

      Negative Binomial Calculations with Software 154

      Exercises Section 4.5 (65–78) 154

      Supplementary Exercises (79–100) 156

      5 Continuous Probability Distributions:general Properties 160

      Introduction 160

      5.1 Continuous Random Variables and Probability Density Functions 160

      Probability Distributions for Continuous Variables 161

      Exercises Section 5.1 (1–8) 165

      5.2 The Cumulative Distribution Function and Percentiles 166

      Using F(x) to Compute Probabilities 168

      Obtaining f(x) fromF(x) 169

      Percentiles of a Continuous Distribution 169

      Exercises Section 5.2 (9–18) 171

      5.3 Expected Values Variance and Moment Generating Functions 173

      Expected Values 173

      Variance and Standard Deviation 175

      Properties of Expectation and Variance 176

      Moment Generating Functions 177

      Exercises Section 5.3 (19–38) 179

      5.4 Transformation of a Random Variable 181

      Exercises Section 5.4 (39–54) 185

      5.5 Simulation of Continuous Random Variables 186

      The Inverse CDF Method 186

      The Accept–Reject Method 189

      Precision of Simulation Results 191

      Exercises Section 5.5 (55–63) 191

      Supplementary Exercises (64–76) 193

      6 Families of Continuous Distributions 196

      Introduction 196

      6.1 The Normal (Gaussian) Distribution 196

      The Standard Normal Distribution 197

      Arbitrary Normal Distributions 199

      The Moment Generating Function 203

      Normal Distribution Calculations with Software 204

      Exercises Section 6.1 (1–27) 205

      6.2 Normal Approximation of Discrete Distributions 208

      Approximating the Binomial Distribution 209

      Exercises Section 6.2 (28–36) 211

      6.3 The Exponential and Gamma Distributions 212

      The Exponential Distribution 212

      The Gamma Distribution 214

      The Gamma and Exponential MGFs 217

      Gamma and Exponential Calculations with Software 218

      Exercises Section 6.3 (37–50) 218

      6.4 Other Continuous Distributions 220

      The Weibull Distribution 220

      The Lognormal Distribution 222

      The Beta Distribution 224

      Exercises Section 6.4 (51–66) 226

      6.5 Probability Plots 228

      Sample Percentiles 228

      A Probability Plot 229

      Departures from Normality 232

      Beyond Normality 234

      Probability Plots in Matlab and R 236

      Exercises Section 6.5 (67–76) 237

      Supplementary Exercises (77–96) 238

      7 Joint Probability Distributions 242

      Introduction 242

      7.1 Joint Distributions for Discrete Random Variables 242

      The Joint Probability Mass Function for Two Discrete Random Variables 242

      Marginal Probability Mass Functions 244

      Independent Random Variables 245

      More Than Two Random Variables 246

      Exercises Section 7.1 (1–12) 248

      7.2 Joint Distributions for Continuous Random Variables 250

      The Joint Probability Density Function for Two Continuous Random Variables 250

      Marginal Probability Density Functions 252

      Independence of Continuous Random Variables 254

      More Than Two Random Variables 255

      Exercises Section 7.2 (13–22) 257

      7.3 Expected Values Covariance and Correlation 258

      Properties of Expected Value 260

      Covariance 261

      Correlation 263

      Correlation Versus Causation 265

      Exercises Section 7.3 (23–42) 266

      7.4 Properties of Linear Combinations 267

      Expected Value and Variance of a Linear Combination 268

      The PDF of a Sum 271

      Moment Generating Functions of Linear Combinations 273

      Exercises Section 7.4 (43–65) 275

      7.5 The Central Limit Theorem and the Law of Large Numbers 278

      Random Samples 278

      The Central Limit Theorem 282

      A More General Central Limit Theorem 286

      Other Applications of the Central Limit Theorem 287

      The Law of Large Numbers 288

      Proof of the Central Limit Theorem 290

      Exercises Section 7.5 (66–82) 290

      7.6 Simulation of Joint Probability Distributions 293

      Simulating Values from a Joint PMF 293

      Simulating Values from a Joint PDF 295

      Exercises Section 7.6 (83–90) 297

      Supplementary Exercises (91–124) 298

      8 Joint Probability Distributions:additional Topics 304

      Introduction 304

      8.1 Conditional Distributions and Expectation 304

      Conditional Distributions and Independence 306

      Conditional Expectation and Variance 307

      The Laws of Total Expectation and Variance 308

      Exercises Section 8.1 (1–18) 313

      8.2 The Bivariate Normal Distribution 315

      Conditional Distributions of X and Y 317

      Regression to the Mean 318

      The Multivariate Normal Distribution 319

      Bivariate Normal Calculations with Software 319

      Exercises Section 8.2 (19–30) 320

      8.3 Transformations of Jointly Distributed Random Variables 321

      The Joint Distribution of Two New Random Variables 322

      The Distribution of a Single New RV 323

      The Joint Distribution of More Than Two New Variables 325

      Exercises Section 8.3 (31–38) 326

      8.4 Reliability 327

      The Reliability Function 327

      Series and Parallel System Designs 329

      Mean Time to Failure 331

      The Hazard Function 332

      Exercises Section 8.4 (39–50) 335

      8.5 Order Statistics 337

      The Distributions of Yn and Y1 337

      The Distribution of the ith Order Statistic 339

      The Joint Distribution of All n Order Statistics 340

      Exercises Section 8.5 (51–60) 342

      8.6 Further Simulation Tools for Jointly Distributed Random Variables 343

      The Conditional Distribution Method of Simulation 343

      Simulating a Bivariate Normal Distribution 344

      Simulation Methods for Reliability 346

      Exercises Section 8.6 (61–68) 347

      Supplementary Exercises (69–82) 348

      9 the Basics of Statistical Inference 351

      Introduction 351

      9.1 Point Estimation 351

      Estimates and Estimators 352

      Assessing Estimators: Accuracy and Precision 354

      Exercises Section 9.1 (1–18) 357

      9.2 Maximum Likelihood Estimation 360

      Some Properties of MLEs 366

      Exercises Section 9.2 (19–30) 367

      9.3 Statistical Intervals 368

      Constructing a Confidence Interval 369

      Confidence Intervals for a Population Proportion 369

      Confidence Intervals for a Population Mean 371

      Further Comments on Statistical Intervals 375

      Confidence Intervals with Software 375

      Exercises Section 9.3 (31–48) 376

      9.4 Hypothesis Tests 379

      Hypotheses and Test Procedures 380

      Hypothesis Testing for a Population Mean 381

      Errors in Hypothesis Testing and the Power of a Test 385

      Hypothesis Testing for a Population Proportion 388

      Software for Hypothesis Test Calculations 389

      Exercises Section 9.4 (49–71) 391

      9.5 Bayesian Estimation 393

      The Posterior Distribution of a Parameter 394

      Inferences from the Posterior Distribution 397

      Further Comments on Bayesian Inference 398

      Exercises Section 9.5 (72–80) 399

      9.6 Simulation-Based Inference 400

      The Bootstrap Method 400

      Interval Estimation Using the Bootstrap 402

      Hypothesis Tests Using the Bootstrap 404

      More on Simulation-Based Inference 405

      Exercises Section 9.6 (81–90) 405

      Supplementary Exercises (91–116) 407

      10 Markov Chains 411

      Introduction 411

      10.1 Terminology and Basic Properties 411

      The Markov Property 413

      Exercises Section 10.1 (1–10) 416

      10.2 The Transition Matrix and the Chapman–Kolmogorov Equations 418

      The Transition Matrix 418

      Computation of Multistep Transition Probabilities 419

      Exercises Section 10.2 (11–22) 423

      10.3 Specifying an Initial Distribution 426

      A Fixed Initial State 428

      Exercises Section 10.3 (23–30) 429

      10.4 Regular Markov Chains and the Steady-State Theorem 430

      Regular Chains 431

      The Steady-State Theorem 432

      Interpreting the Steady-State Distribution 433

      Efficient Computation of Steady-State Probabilities 435

      Irreducible and Periodic Chains 437

      Exercises Section 10.4 (31–43) 438

      10.5 Markov Chains with Absorbing States 440

      Time to Absorption 441

      Mean Time to Absorption 444

      Mean First Passage Times 448

      Probabilities of Eventual Absorption 449

      Exercises Section 10.5 (44–58) 451

      10.6 Simulation of Markov Chains 453

      Exercises Section 10.6 (59–66) 459

      Supplementary Exercises (67–82) 461

      11 Random Processes 465

      Introduction 465

      11.1 Types of Random Processes 465

      Classification of Processes 468

      Random Processes and Their Associated Random Variables 469

      Exercises Section 11.1 (1–10) 470

      11.2 Properties of the Ensemble: Mean and Autocorrelation Functions 471

      Mean and Variance Functions 471

      Autocovariance and Autocorrelation Functions 475

      The Joint Distribution of Two Random Processes 477

      Exercises Section 11.2 (11–24) 478

      11.3 Stationary and Wide-Sense Stationary Processes 479

      Properties of WSS Processes 483

      Ergodic Processes 486

      Exercises Section 11.3 (25–40) 488

      11.4 Discrete-Time Random Processes 489

      Special Discrete Sequences 491

      Exercises Section 11.4 (41–52) 493

      Supplementary Exercises (53–64) 494

      12 Families of Random Processes 497

      Introduction 497

      12.1 Poisson Processes 497

      Relation to Exponential and Gamma Distributions 499

      Combining and Decomposing Poisson Processes 502

      Alternative Definition of a Poisson Process 504

      Nonhomogeneous Poisson Processes 505

      The Poisson Telegraphic Process 506

      Exercises Section 12.1 (1–18) 507

      12.2 Gaussian Processes 509

      Brownian Motion 510

      Brownian Motion as a Limit 512

      Further Properties of Brownian Motion 512

      Variations on Brownian Motion 514

      Exercises Section 12.2 (19–28) 515

      12.3 Continuous-Time Markov Chains 516

      Infinitesimal Parameters and Instantaneous Transition Rates 518

      Sojourn Times and Transitions 520

      Long-Run Behavior of Continuous-Time Markov Chains 523

      Explicit Form of the Transition Matrix 526

      Exercises Section 12.3 (29–40) 527

      Supplementary Exercises (41–51) 529

      13 Introduction to Signal Processing 532

      Introduction 532

      13.1 Power Spectral Density 532

      Expected Power and the Power Spectral Density 532

      Properties of the Power Spectral Density 535

      Power in a Frequency Band 538

      White Noise Processes 539

      Cross-Power Spectral Density for Two Processes 541

      Exercises Section 13.1 (1–21) 542

      13.2 Random Processes and LTI Systems 544

      Properties of the LTI System Output 545

      Ideal Filters 548

      Signal Plus Noise 551

      Exercises Section 13.2 (22–38) 554

      13.3 Discrete-Time Signal Processing 556

      Random Sequences and LTI Systems 558

      Sampling Random Sequences 560

      Exercises Section 13.3 (39–50) 562

      A Statistical Tables A- 1

      A. 1 Binomial CDF A- 1

      A. 2 Poisson CDF A- 4

      A. 3 Standard Normal CDF A- 5

      A. 4 Incomplete Gamma Function A- 7

      A. 5 Critical Values for t Distributions A- 7

      A. 6 Tail Areas of t Distributions A- 9

      B Background Mathematics A- 13

      B. 1 Trigonometric Identities A- 13

      B. 2 Special Engineering Functions A- 13

      B. 3 o(h) Notation A- 14

      B. 4 The Delta Function A- 14

      B. 5 Fourier Transforms A- 15

      B. 6 Discrete-Time Fourier Transforms A- 16

      C Important Probability Distributions A- 18

      C. 1 Discrete Distributions A- 18

      C. 2 Continuous Distributions A- 20

      C. 3 Matlab and R Commands A- 23

      Bibliography B- 1

      Answers to Odd-numbered Exercises S- 1

      Index I- 1

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