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PRACTICAL BAYESIAN INFERENCE. A PRIMER FOR PHYSICAL SCIENTISTS
Título:
PRACTICAL BAYESIAN INFERENCE. A PRIMER FOR PHYSICAL SCIENTISTS
Subtítulo:
Autor:
BAILER-JONES, C
Editorial:
CAMBRIDGE UNIVERSITY PRESS
Año de edición:
2017
Materia
MATEMATICA APLICADA
ISBN:
978-1-316-64221-4
39,47 €

 

Sinopsis

Science is fundamentally about learning from data, and doing so in the presence of uncertainty. This volume is an introduction to the major concepts of probability and statistics, and the computational tools for analysing and interpreting data. It describes the Bayesian approach, and explains how this can be used to fit and compare models in a range of problems. Topics covered include regression, parameter estimation, model assessment, and Monte Carlo methods, as well as widely used classical methods such as regularization and hypothesis testing. The emphasis throughout is on the principles, the unifying probabilistic approach, and showing how the methods can be implemented in practice. R code (with explanations) is included and is available online, so readers can reproduce the plots and results for themselves. Aimed primarily at undergraduate and graduate students, these techniques can be applied to a wide range of data analysis problems beyond the scope of this work.

Written in an informal yet precise style, suitable for a wide audience from a range of backgrounds in the physical sciences
Promotes the Bayesian approach as a general framework for solving problems, but also makes comparison with frequentist methods
Describes how methods can be applied in practice to the readers´ own problems, so it is not simply a recipe book
The R code from the book is available freely online, allowing readers to see how the theory is actually implemented and reproduce the plots and results in the book`



Table of Contents
Preface
1. Probability basics
2. Estimation and uncertainty
3. Statistical models and inference
4. Linear models, least squares, and maximum likelihood
5. Parameter estimation: single parameter
6. Parameter estimation: multiple parameters
7. Approximating distributions
8. Monte Carlo methods for inference
9. Parameter estimation: Markov chain Monte Carlo
10. Frequentist hypothesis testing
11. Model comparison
12. Dealing with more complicated problems
References
Index.