Reading 2015, Day 4: Bayesian Model Specification

DEPARTMENT OF
APPLIED MATHEMATICS & STATISTICS (AMS)

Reading 2015, Day 4: Bayesian Model Specification

Instructor: David Draper (draper@ams.ucsc.edu, (+1) (831) 459-1295)
Venue: Fourth day of a five-day short course sponsored by the Statistical Services Centre at the University of Reading (UK)
Date: Thursday 26 November 2015
Location: Please see this page for details (if you have questions, please click on the Contact us link)
To register for the course please go here

Summary of Short Course Contents: This is an award-winning one-day course on Bayesian model specification, based on a series of case studies and assuming familiarity with Bayesian analysis equivalent to the content of day 3 of this five-day course.
Topics will include the big picture in Bayesian model specification; five foundational principles for specifying Bayesian models: the Calibration Principle, the Modeling-As-Decision Principle, the Prediction Principle, the Inference-Versus-Decision Principle and parts 1 and 2 of Cromwell's Rule; model expansion as a tool for improving Bayesian models: embedding a deficient model M in a larger class of models, of which M is a special case; methods for finding good Bayesian models: Calibration Cross-Validation, Bayes factors, BIC, DIC and log scores; a generic Bayesian model-search algorithm; and false-positive/false-negative tradeoffs in comparing {Bayes factors, BIC} and {DIC, log scores} on their ability to correctly discriminate between models
The case studies will be drawn from gerontology (analysis of a randomized controlled experiment to measure the effect of a health intervention on hospitalization rates for elderly non-institutionalized people), health policy (assessing hospital quality of care by monitoring the rate of unplanned transfer to the Intensive Care Unit); measurement of physical constants, and medicine (randomized controlled trials of drugs to lower blood pressure in hypertensive patients, to (a) estimate improvement of one drug over another and (b) establish bio-equivalence of two drugs).
Through a series of practicals (computer labs), the course will liberally illustrate user-friendly implementations of MCMC sampling via the freeware programs WinBUGS (for Windows platforms) and rjags (for all platforms) when closed-form solutions are not possible.
The course is intended mainly for people who often use statistics in their research or other work in academia, government or industry; as noted above, a first and second course in Bayesian analysis equivalent to the content of day 3 of this five-day course will provide sufficient background for participants.

Biography of Instructor: David Draper is a Professor of Statistics in the Department of Applied Mathematics and Statistics at the University of California, Santa Cruz (USA); in the period Jul 2012-Feb 2015 he was also a Distinguished Statistical Scientist, Visiting Professor and Director of the new Center of Excellence in Statistical Research (CESR) at eBay Research Labs in San Jose, CA (he foundded CESR in 2013).
He is a Fellow of the American Association for the Advancement of Science, the American Statistical Association (ASA), the Institute of Mathematical Statistics, and the Royal Statistical Society; from 2001 to 2003 he served as the President-Elect, President, and Past President of the International Society for Bayesian Analysis (ISBA).
He is the author or co-author of about 150 contributions to the methodological and applied statistical literature, including articles in the Journal of the Royal Statistical Society (Series A, B and C), the Journal of the American Statistical Association, the Annals of Applied Statistics, Bayesian Analysis, Statistical Science, the New England Journal of Medicine, and the Journal of the American Medical Association; his 1995 JRSS-B article on assessment and propagation of model uncertainty has been cited more than 1,400 times, and taken together his publications have been cited about 13,000 times.
His research is in the areas of Bayesian inference and prediction, model uncertainty and empirical model-building, hierarchical modeling, Markov Chain Monte Carlo methods, and Bayesian nonparametric methods, with applications mainly in medicine, health policy, education, environmental risk assessment and data science.
His short courses have received Excellence in Continuing Education Awards from the American Statistical Association on two occasions. He has won or been nominated for major teaching awards everywhere he has taught (the University of Chicago; the RAND Graduate School of Public Policy Studies; the University of California, Los Angeles; the University of Bath (UK); and the University of California, Santa Cruz).
He has a particular interest in the exposition of complex statistical methods and ideas in the context of real-world applications.
Approximate Structure of the Short Course:
- 9.00-9.10: Registration and coffee
- 9.10-9.25: Introductions
- 9.25-10.25: Lecture 1: The big picture in Bayesian model specification
- 10.25-10.40: Short break
- 10.40-11.40: Lecture 2: The Calibration Principle, the Modeling-As-Decision Principle, the Prediction Principle, the Inference-Versus-Decision Principle and parts 1 and 2 of Cromwell's Rule
- 11.40-11.55: Coffee break
- 11.55-12.55 Lecture 3: Model expansion as a tool for improving Bayesian models: embedding a deficient model M in a larger class of models, of which M is a special case
- 12.55-13.40: Lunch
- 13.40-14.40 Lecture 4: Methods for finding good Bayesian models: Calibration Cross-Validation, Bayes factors, BIC, DIC and log scores; a generic Bayesian model-search algorithm
- 14.40-14.55: Short break
- 14.55-15.55: Practical 1: Applying the ideas in Lectures 1-4 to examples from days 1 and 2 of the course
- 15.55-16.10: Tea break
- 16.10-17.10: Lecture 5: False-positive/false-negative tradeoffs in comparing {Bayes factors, BIC} and {DIC, log scores} on their ability to correctly discriminate between models
- 17.10-17.40: Overview and summary (of the entire 4-day course)
- 17.40: Close of day
Lecture notes, journal articles and book excerpts: (PDF format)
- Lecture notes: Part 1 (Foundations) (27 pages)
- Lecture notes: Part 2 (Settings With No Model Uncertainty) (12 pages)
- Lecture notes: Part 3 (Bayesian Qualitative/Quantitative Inference) (12 pages)
- Lecture notes: Part 4 (Dealing With Model Uncertainty) (89 pages)
- Singpurwalla ND (2006). Reliability and Risk: A Bayesian Perspective (Chapter 3 [Exchangeability and Indifference], pages 45-57: enumerates and discusses all known results generalizing de Finetti's representation theorem for binary outcomes to other sampling distributions).
- Rubin DB (1981). The Bayesian bootstrap. Annals of Statistics, 9, 130-134 (Examines the modeling assumptions underlying the Bayesian qualitative/quantitative inferential approach, and points out that conclusions may be sensitive to those assumptions).
- Draper D (2013). Bayesian model specification: heuristics and examples, in Damien P, Dellaportas P, Polson NG, Stephens DA (2013, editors): Bayesian Theory and Applications, Oxford: University Press, 409-431 (gives a worked example of Calibration Cross Validation and shows that Bayesian nonparametric analyses with fully diffuse priors can lead to some surprises)
- Draper D, Krnjajic M (2013). Calibration results for Bayesian model comparison (draft; compares DIC and log scores as Bayesian model-choice criteria, using the Calibration Principle to decide between them).
- BMS tutorial (one implementation of Bayesian model averaging in R for regression models)
- BMA tutorial and BMA user guide (another implementation of Bayesian model averaging in R for regression and generalized linear models)
Code and data sets:
- R code for the prior-distribution calibration experiment in the In-Home Geriatric Assessment (IHGA) case study
- R code for the prior-distribution calibration experiment in the aspirin meta-analysis case study
- In-home geriatric assessment (IHGA) case study:
- Aspirin meta-analysis case study:
  - R code for maximum-likelihood empirical Bayes (MLEB) calculations
  - R code to do Gibbs sampling
  - aspirin-model-1.txt
  - aspirin-data-1.txt
  - aspirin-inits-1.txt
- R code to do Bayesian model averaging in multiple linear regression:
  - the attitude example with the CRAN packages BMA and BMS
  - the ozone example with BMA and BMS; the data set for this example is here
- Bayesian nonparametric modeling R code: part 1 (Dirichlet process (DP) priors), part 2 (Polya tree (PT) priors), part 3 (fitting BNP models to the NB10 data set), part 4 (Tim Hanson's WinBUGS Polya tree code for monitoring the population median), part 5 (ditto Tim Hanson but monitoring the population mean), part 6 (Thanasis Kottas's R code for fitting location-normal Dirichlet-process mixture models), part 7 (information about how to use Thanasis's code), part 8 (a simulated data set for testing Thanasis's code), part 8 (R code to run Thanasis's example)
- NB10 case study:
  - nb10-model-1.txt
  - nb10-data.txt
  - nb10-initial-values-1.txt
  - nb10-model-2.txt
  - nb10-initial-values-2.txt
  - nb10-model-1-mu.txt
  - nb10-model-1-sigma.txt
  - nb10-model-2-mu.txt
  - nb10-model-2-sigma.txt
  - nb10-model-2-nu.txt
  - R code for the log score calculations
  - WinBUGS model 1 with code to compute an approximate version of LS.FS
  - WinBUGS model 2 with code to compute an approximate version of LS.FS
- Example in which DIC badly misbehaves: WinBUGS model 1 file, data file, and initial values 1 file
- Chris Severs (csevers@ebay.com) has figured out how to run WinBUGS under Mac OS X: his comments on how to do this are here
- How to run rjags in parallel-processing mode: code for doing so with the NB10 case study is here

(last modified: 26 November 2015)