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Introduction to Bayesian statistics / William M. Bolstad.
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View online- Format:
- Book
- Author/Creator:
- Bolstad, William M., 1943- author.
- Language:
- English
- Subjects (All):
- Bayesian statistical decision theory.
- Physical Description:
- 1 online resource (xvi, 601 pages) : illustrations
- polychrome
- Edition:
- Third edition.
- Place of Publication:
- Hoboken, N.J. : John Wiley, [2017]
- System Details:
- text file
- Contents:
- 1 Introduction to Statistical Science 1
- 1.1 The Scientific Method: A Process for Learning 3
- 1.2 The Role of Statistics in the Scientific Method 5
- 1.3 Main Approaches to Statistics 5
- 1.4 Purpose and Organization of This Text 8
- 2 Scientific Data Gathering 13
- 2.1 Sampling from a Real Population 14
- 2.2 Observational Studies and Designed Experiments 17
- Monte Carlo Exercises 23
- 3 Displaying and Summarizing Data 31
- 3.1 Graphically Displaying a Single Variable 32
- 3.2 Graphically Comparing Two Samples 39
- 3.3 Measures of Location 41
- 3.4 Measures of Spread 44
- 3.5 Displaying Relationships Between Two or More Variables 46
- 3.6 Measures of Association for Two or More Variables 49
- Exercises 52
- 4 Logic, Probability, and Uncertainty 59
- 4.1 Deductive Logic and Plausible Reasoning 60
- 4.2 Probability 62
- 4.3 Axioms of Probability 64
- 4.4 Joint Probability and Independent Events 65
- 4.5 Conditional Probability 66
- 4.6 Bayes' Theorem 68
- 4.7 Assigning Probabilities 74
- 4.8 Odds and Bayes Factor 75
- 4.9 Beat the Dealer 76
- Exercises 80
- 5 Discrete Random Variables 83
- 5.1 Discrete Random Variables 84
- 5.2 Probability Distribution of a Discrete Random Variable 86
- 5.3 Binomial Distribution 90
- 5.4 Hypergeometric Distribution 92
- 5.5 Poisson Distribution 93
- 5.6 Joint Random Variables 96
- 5.7 Conditional Probability for Joint Random Variables 100
- Exercises 104
- 6 Bayesian Inference for Discrete Random Variables 109
- 6.1 Two Equivalent Ways of Using Bayes' Theorem 114
- 6.2 Bayes' Theorem for Binomial with Discrete Prior 116
- 6.3 Important Consequences of Bayes' Theorem 119
- 6.4 Bayes' Theorem for Poisson with Discrete Prior 120
- Exercises 122
- Computer Exercises 126
- 7 Continuous Random Variables 129
- 7.1 Probability Density Function 131
- 7.2 Some Continuous Distributions 135
- 7.3 Joint Continuous Random Variables 143
- 7.4 Joint Continuous and Discrete Random Variables 144
- Exercises 147
- 8 Bayesian Inference for Binomial Proportion 149
- 8.1 Using a Uniform Prior 150
- 8.2 Using a Beta Prior 151
- 8.3 Choosing Your Prior 154
- 8.4 Summarizing the Posterior Distribution 158
- 8.5 Estimating the Proportion 161
- 5.1 Bayesian Credible Interval 162
- Exercises 164
- Computer Exercises 167
- 9 Comparing Bayesian and Frequentist Inferences for Proportion 169
- 94 Frequentist Interpretation of Probability and Parameters 170
- 9.2 Point Estimation 171
- 9.3 Comparing Estimators for Proportion 174
- 9.4 Interval Estimation 175
- 9.5 Hypothesis Testing 178
- 9.6 Testing a One-Sided Hypothesis 179
- 9.7 Testing a Two-Sided Hypothesis 182
- Exercises 187
- Monte Carlo Exercises 190
- 10 Bayesian Inference for Poisson 193
- 10.1 Some Prior Distributions for Poisson 194
- 10.2 Inference for Poisson Parameter 200
- Exercises 207
- Computer Exercises 208
- 11 Bayesian Inference for Normal Mean 211
- 11.1 Bayes' Theorem for Normal Mean with a Discrete Prior 211
- 11.2 Bayes' Theorem for Normal Mean with a Continuous Prior 218
- 11.3 Choosing Your Normal Prior 222
- 11.4 Bayesian Credible Interval for Normal Mean 224
- 11.5 Predictive Density for Next Observation 227
- Exercises 230
- Computer Exercises 232
- 12 Comparing Bayesian and Frequentist Inferences for Mean 237
- 12.1 Comparing Frequentist and Bayesian Point Estimators 238
- 12.2 Comparing Confidence and Credible Intervals for Mean 241
- 12.3 Testing a One-Sided Hypothesis about a Normal Mean 243
- 12.4 Testing a Two-Sided Hypothesis about a Normal Mean 247
- Exercises 251
- 13 Bayesian Inference for Difference Between Means 255
- 13.1 Independent Random Samples from Two Normal Distributions 256
- 13.2 Case 1: Equal Variances 257
- 13.3 Case 2: Unequal Variances 262
- 13.4 Bayesian Inference for Difference Between Two Proportions Using Normal Approximation 265
- 13.5 Normal Random Samples from Paired Experiments 266
- Exercises 272
- 14 Bayesian Inference for Simple Linear Regression 283
- 14.1 Least Squares Regression 284
- 14.2 Exponential Growth Model 288
- 14.3 Simple Linear Regression Assumptions 290
- 14.4 Baycs' Theorem for the Regression Model 292
- 14.5 Predictive Distribution for Future Observation 298
- Exercises 303
- Computer Exercises 312
- 15 Bayesian Inference for Standard Deviation 315
- 15.1 Bayes' Theorem for Normal Variance with a Continuous Prior 316
- 15.2 Some Specific Prior Distributions and the Resulting Posteriors 318
- 15.3 Bayesian Inference for Normal Standard Deviation 326
- Exercises 332
- Computer Exercises 335
- 16 Robust Bayesian Methods 337
- 16.1 Effect of Misspecified Prior 338
- 16.2 Bayes: Theorem with Mixture Priors 340
- Exercises 349
- Computer Exercises 351
- 17 Bayesian Inference for Normal with Unknown Mean and Variance 355
- 17.1 The Joint Likelihood Function 358
- 17.2 Finding the Posterior when Independent Jeffreys' Priors for μ, and σ² Are Used 359
- 17.3 Finding the Posterior when a Joint Conjugate Prior for μ and σ² Is Used 361
- 17.4 Difference Between Normal Means with Equal Unknown Variance 367
- 17.5 Difference Between Normal Means with Unequal Unknown Variances 377
- Computer Exercises 383
- Appendix: Proof that the Exact Marginal Posterior Distribution of μ is Student's t 385
- 18 Bayesian Inference for Multivariate Normal Mean Vector 393
- 18.1 Bivariate Normal Density 394
- 18.2 Multivariate Normal Distribution 397
- 18.3 The Posterior Distribution of the Multivariate Normal Mean Vector when Covarianec Matrix Is Known 398
- 18.4 Credible Region for Multivariate Normal Mean Vector when Co variance Matrix Is Known 400
- 18.5 Multivariate Normal Distribution with Unknown Covariance Matrix 402
- Computer Exercises 406
- 19 Bayesian Inference for the Multiple Linear Regression Model 411
- 19.1 Least Squares Regression for Multiple Linear Regression Model 412
- 19.2 Assumptions of Normal Multiple Linear Regression Model 414
- 19.3 Bayes' Theorem for Normal Multiple Linear Regression Model 415
- 19.4 Inference in the Multivariate Normal Linear Regression Model 419
- 19.5 The Predictive Distribution for a Future Observation 425
- Computer Exercises 428
- 20 Computational Bayesian Statistics including Markov Chain Monte Carlo 431
- 20.1 Direct Methods for Sampling from the Posterior 436
- 20.2 Sampling-Importance Resampling 450
- 20.3 Markov Chain Monte Carlo Methods 454
- 20.4 Slice Sampling 470
- 20.5 Inference from a Posterior Random Sample 473
- 20.6 Where to Next? 475.
- Notes:
- Includes bibliographical references and index.
- Electronic reproduction. Hoboken, N.J. Available via World Wide Web.
- Print version record.
- Local Notes:
- Acquired for the Penn Libraries with assistance from the William Pepper Medical Library Fund.
- Other Format:
- Print version: Bolstad, William M., 1943- Introduction to Bayesian statistics.
- ISBN:
- 9781118593165
- 1118593162
- 9781118593158
- 1118593154
- Publisher Number:
- 99970107537
- Access Restriction:
- Restricted for use by site license.
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