Statistics and probability with applications for engineers and scientists : using MINITAB, Microsoft Excel, and JMP

Wiley is excited to provide you with a sneak preview of a ground-breaking new text for the Engineering Statistics course. All statistical concepts are supported by a large number of examples using data encountered in real life situations; and the text illustrates how the statistical packages MINITAB (R), Microsoft Excel (R), and JMP (R) may be used to aid in the analysis of various data sets. The text also covers an appropriate and understandable level of the design of experiments. This includes randomized block designs, one and two-way designs, Latin square designs, factorial designs, response surface designs, and others. This text is suitable for a one- or two-semester calculus-based undergraduate statistics course for engineers and scientists, and the presentation of material gives instructors flexibility to pick and choose topics for their particular courses.

Chapter1: Introduction Chapter2: Describing Data Graphically and Numerically 2.1 Getting Started With Statistics 2.1.1 What is Statistics? 2.1.2 Population and Sample in a Statistical Study 2.2 Classification of Various Types of Data 2.3 Frequency Distribution Tables for Qualitative and Quantitative Data 2.4 Graphical Description of Qualitative and Quantitative Data 2.4.1 Dot Plot 2.4.2 Pie Chart 2.4.3 Bar Chart 2.4.4 Histograms 2.4.5 Line Graph 2.4.6 Stem-and-Leaf Plot 2.5 Numerical Measures of Quantitative Data 2.5.1 Measures of Centrality 2.5.2 Measures of Dispersion 2.6 Numerical Measures of Grouped Data 2.7 Measures of Relative Position 2.8 Box-Whisker Plot 2.9 Measures of Association 2.10 Case Studies 2.11 Using JMP Review Practice Problems Chapter3 Elements of Probability 3.1 Random Experiments, Sample Spaces, and Events 3.2 Concepts of Probability 3.3 Techniques of Counting Sample Points 3.3.1 Tree Diagrams 3.3.2 Permutations 3.3.3 Combinations 3.3.4 Arrangements of n Objects Involving Several Kinds of Objects 3.3.5 Application of Combinations to Probability Problems 3.4 Conditional Probability 3.5 Bayes' Theorem 3.6 Introducing Random Variables Review Practice Problems Chapter 4 Discrete Random Variables and Some Important Discrete Probability Distributions 4.1 Graphical Descriptions of Discrete Distributions 4.2 Mean and Variance of a Discrete Random Variable 4.2.1 The Moment-Generating Function Expectation of a Special Function 4.3 The Discrete Uniform Distribution 4.4 The Hypergeometric Distribution 4.5 The Bernoulli Distribution 4.6 The Binomial Distribution 4.7 The Multinomial Distribution 4.8 The Poisson Distribution 4.8.1Poisson Distribution as a Limiting Form of the Binomial 4.9 The Negative Binomial Distribution 4.10 Some Derivations and Proofs (Optional) 4.10.1 Proof that the Probability Function of the Hypergeometric Distribution Sums to 1 4.10.2 Mean and the Variance of the Hypergeometric Distribution 4.10.3 Mean and the Variance of the Binomial Distribution 4.10.4 Mean and the Variance of the Poisson Distribution 4.10.5 Derivation of the Poisson Distribution 4.11 A Case Study 4.12 Using JMP Review Practice Problems Chapter 5 Continuous Random Variables and Some Important Continuous Probability Distributions 5.1 Continuous Random Variables 5.2 Mean and Variance of Continuous Random Variables 5.2.1 The Moment-Generating Function - Expectation of a Special Function 5.3 Chebychev's Inequality 5.4 The Uniform Distribution 5.5 The Normal Distribution 5.5.1 Definition and Properties 5.5.2 The Standard Normal Distribution 5.5.3 The Moment-Generating Function of the Normal Distribution 5.6 Distribution of Linear Combinations of Independent Normal Variables 5.7 Approximation of the Binomial Distribution by the Normal Distribution 5.8 A Test of Normality 5.9 The Lognormal Distribution 5.10 The Exponential Distribution 5.11 The Gamma Distribution 5.12 The Weibull Distribution 5.13 A Case Study 5.14 Using JMP Review Practice Problems Chapter 6 Distribution Functions of Random Variables 6.1 Distribution Functions of Two Random Variables 6.1.1 Case of Two Discrete Random Variables 6.1.2 Case of Two Continuous Random Variables 6.1.3 The Mean Value and Variance of Functions of Two Random Variables 6.1.4 Conditional Distributions 6.1.5 Correlation Between Two Random Variables 6.1.6 Bivariate Normal Distribution 6.2 Extension to Several Random Variables 6.3 The Moment-Generating Function Revisited Review Practice Problems Chapter 7 Sampling Distribution 7.1 Random Sampling 7.1.1 Random Sampling from an Infinite Population 7.1.2 Random Sampling from a Finite Population 7.2 The Sampling Distribution of the Mean 7.2.1 The Central Limit Theorem 7.3 Sampling from a Normal Population 7.3.1 The Chi-Square Distribution 7.3.2 The Student t Distribution 7.3.3 Snedecor's F Distribution 7.4 Order Statistics 7.4.1 Distribution of the Largest Element in a Sample 7.4.2 Distribution of the Smallest Element in a Sample 7.4.3 Distribution of the Median of a Sample and of the kth-Order Statistic 7.4.4 The Range as an Estimate of in Normal Samples 7.5 Using JMP Review Practice Problems Chapter 8 Estimation of Population Parameters 8.1 Introduction 8.2 Point Estimators for the Population Mean and Variance 8.2.1 Properties of Point Estimators 8.2.2 Methods of Finding Point Estimators 8.3 Interval Estimators for the Mean of a Normal Population 8.3.1 Known 8.3.2 Unknown 8.3.3 Sample Size is Large 8.4 Interval Estimators for the Difference of Means of Two Normal Populations 8.4.1. Variances are Known 8.4.2. Variances are Unknown 8.5 Interval Estimators for the Variance of a Normal Population 8.6 Interval Estimators for the Ratio of Variances of Two Normal Populations 8.7 Point and Interval Estimators for the Parameters of Binomial Populations 8.7.1 One Binomial Population 8.7.1 Two Binomial Populations 8.8 Determination of Sample Size 8.9 Some Supplemental Information (Optional) 8.9.1 Proof of 8.9.2 Predicting an Arbitrary Observation 8.10 A Case Study 8.11 Using JMP Review Practice Problems Chapter 9 Hypothesis Testing 9.1 Introduction 9.2 Basic Concepts of Testing a Statistical Hypothesis 9.3 Tests Concerning the Mean of a Normal Distribution Having Known Variance 9.4 Tests Concerning the Mean of a Normal Population Having Unknown Variance 9.5 Large Sample Theory 9.6 Tests Concerning the Difference of Means of Two Populations Having Distributions with Known Variances 9.7 Tests Concerning the Difference of Means of Two Populations Having Distributions with Unknown Variances 9.7.1 Two Population Variances Are Equal 9.7.2 Two Population Variances Are Not Equal 9.7.3 The Paired t-Test 9.8 Testing Population Proportions 9.8.1 Testing Concerning the One Population Proportion 9.8.2 Testing Concerning the Difference Between Two Population Proportions 9.9 Tests Concerning the Variance of a Normal Distribution 9.10 Tests Concerning the Ratio of Variances of Two Normal Populations 9.11 An Alternative Technique for Testing of Statistical Hypotheses: Using Confidence Intervals 9.12 Sequential Tests of Hypotheses (Optional) 9.12.1 A One-Sided Sequential Testing Procedure 9.12.2 A Two-Sided Sequential Testing Procedure 9.13 Case Studies 9.14 Using JMP Review Practice Problems Chapter 10 Elements of Reliability Theory 10.1 The Reliability Function 10.1.1 The Hazard Rate 10.1.2 Employing the Hazard Function 10.2 Estimation: Exponential Distribution 10.3 Hypothesis Testing: Exponential Distribution 10.4 Estimation: Weibull Distribution 10.5 Case Studies 10.6 Using JMP Review Practice Problems Chapter 11 Statistical Quality Control and Phase I Control Charts 11.1 Basic Concepts of Quality and Its Benefits 11.2 What Is a Process? 11.3 Common and Assignable Causes 11.4 Control Charts 11.5 Control Charts for Variables 11.5.1 Shewhart and R Control Chart 11.5.2 Shewhart and R Control Chart When Process Mean and Process Standard Deviation Are Known 11.5.3 The Shewhart and S Control Chart 11.6 Control Charts for Attributes 11.6.1 The p Chart: Control Chart for the Fraction of Nonconforming Units 11.6.2 The p Chart: Control Chart for the Fraction of Nonconforming units with Variable Sample Sizes 11.6.3 The np Control Chart: Control Chart for Number of Nonconforming Units 11.6.4 The C Control Chart 11.6.5 The U Control Chart 11.7 Process Capability 11.8 Case Studies 11.9 Using JMP Review Practice Problems Chapter12 Statistical Quality Control and Phase II Control Charts 12.1 Basic Concepts of CUSUM Control Chart 12.2 Designing a CUSUM Control Chart 12.2.1 Two-Sided CUSUM Control Chart Using a Numerical Procedure 12.2.2 The Fast Initial Response (FIR) Feature for the CUSUM Control Chart 12.2.3 The Combined Shewhart-CUSUM Control Chart 12.2.4 The CUSUM Control Chart for Controlling Process Variability 12.3 The Moving Average (MA) Control Chart 12.4 The Exponentially Weighted Moving Average (EWMA) Control Chart 12.5 Case Studies 12.6 Using JMP Review Practice Problems Chapter 13 Analysis of Categorical Data 13.1 Introduction 13.2 The Chi-Square Goodness of Fit Test 13.3 Contingency Tables 13.3.1 The 2 2 Case Parameters Known 13.3.2 The Case Parameters Unknown 13.3.3 The Contingency Table 13.4 Chi-Square Test for Homogeneity 13.5 Comments on the Distribution of the Lack-of-Fit Statistic (optional) 13.6 Case Studies 13.7 Using JMP Review Practice Problems Chapter 14 Nonparametric Tests 14.1 Introduction 14.2 The Sign Test 14.2.1 One-Sample Test 14.2.2 The Wilcoxon Signed-Rank Test 14.2.3. Two-sample Test 14.3 The Mann-Whitney (Wilcoxon) W Test for Two Samples 14.4 Run Tests 14.4.1 Runs Above and Below the Median 14.4.2 The Wald-Wolfowitz Run Test 14.5 Spearman Rank Correlation 14.6 Using JMP Review Practice Problems Chapter 15 Simple Linear Regression Analysis 15.1 Introduction 15.2 Fitting the Simple Linear Regression Model 15.2.1 Simple Linear Regression Model 15.2.2 Fitting a Straight Line by Least Squares 15.2.3 Sampling Distributions of the Estimators of Regression Coefficients 15.3 Unbiased Estimator of 15.4 Further Inferences Concerning Regression Coefficients and 15.4.1 Confidence Interval for with Confidence Coefficient 15.4.2 Confidence Interval for with Confidence Coefficient 15.4.3 Confidence Interval for with Confidence Coefficient 15.4.4 Prediction Interval for a Future Observation with Confidence Coefficient 15.5 Test of Hypotheses for 15.6 Analysis of Variance Approach to Simple Regression Analysis 15.7 Residual Analysis 15.8 Transformations 15.9 Inference About 15.10 A Case Study 15.11 Using JMP Review Practice Problems Chapter 16 Multiple Linear Regression Analysis 16.1 Introduction 16.2 The Multiple Linear Regression Model 16.3 Estimation of Regression Coefficients 16.3.1 Estimation of Regression Coefficients Using Matrix Notation 16.3.2 Properties of the Least-Squares Estimators 16.3.3 The Analysis of Variance Table 16.3.4 More Inferences About Regression Parameters 16.4 The Multiple Linear Regression Model Using Qualitative or Categorical Predictor Variables 16.5 Standardized Regression Coefficients 16.6 Building Regression Type Prediction Models 16.7 Residual Analysis 16.7.1 Certain Criteria for Model Selection 16.8 Logistic Regression 16.9 Using JMP 16.10 Case Studies Review Practice Problems Chapter 17 Analysis of Variance 17.1 Introduction 17.2 Design Models 17.3 One-Way Experimental Layouts 17.3.1 Confidence Intervals for Treatment Means 17.3.2 Multiple Comparisons 17.3.3 Determination of Sample Size 17.3.4 The Kruskal-Wallis Test for One-Way Layouts (Nonparametric Method) 17.4 Randomized Complete Block Designs 17.4.1 The Friedman Test for Randomized Complete Block Designs 17.4.2 Experiments with One Missing Observations in a RCB Design Experiment 17.4.3 Experiments with Several Missing Observation in a RCB Design Experiment 17.5 Two-Way Experimental Design 17.5.1 Two-way Experimental Layouts with One Observation per Cell 17.5.2 Two-way Experimental Layouts with r > 1 Observations per Cell 17.5.3 Blocking in Two-Way Experimental Designs 17.5.4 Extending Two-Way Experimental Designs to n-way Experimental Designs 17.6 Latin Square Designs 17.7 Random Effects Model 17.7.1 Mixed Effects Model 17.7.2 Nested (Hierarchical) Designs 17.8 Case Study 17.9 Using JMP Review Practice Problems Chapter 18 The 2k Factorial Designs 18.1 The Factorial Designs 18.2 The 2k Factorial Design 18.3 Unreplicated 2k Factorial Designs 18.4 Blocking the 2k Factorial Design 18.4.1 Confounding in the 2k Factorial Design 18.4.2 Yates' Algorithm for the 2k Factorial Designs 18.5 The Fractional Factorial Designs 18.5.1 One-Half Replicate of a Factorial Design 18.5.2 One-Quarter Replicate of a Factorial Design 18.6 Case Studies 18.7 Using JMP Review Practice Problems Chapter 19 Response Surfaces 19.1 Basic Concepts of Response Surface Methodology 19.2 First Order Designs 19.3 Second Order Designs 19.3.1 Central Composite Designs (CCD) 19.3.2 Some Other First-Order and Second-Order Designs 19.4 Determination of the Optimum or Near-Optimum Point 19.4.1 The Method of Steepest Ascent 19.4.2 Analysis of a Fitted Second-Order Response Surface 19.5 ANOVA Table for a Second-order Model 19.6 Case Studies 19.7 Using JMP Review Practice Problems Appendix A: Statistical Tables and Charts Appendix B: Answers to Selected Problems Appendix C: Bibliography Index