Book Image

Bayesian Analysis with Python - Second Edition

By : Osvaldo Martin

4.5 (2)

Book Image

Bayesian Analysis with Python - Second Edition

4.5 (2)

By: Osvaldo Martin

Overview of this book

The second edition of Bayesian Analysis with Python is an introduction to the main concepts of applied Bayesian inference and its practical implementation in Python using PyMC3, a state-of-the-art probabilistic programming library, and ArviZ, a new library for exploratory analysis of Bayesian models. The main concepts of Bayesian statistics are covered using a practical and computational approach. Synthetic and real data sets are used to introduce several types of models, such as generalized linear models for regression and classification, mixture models, hierarchical models, and Gaussian processes, among others. By the end of the book, you will have a working knowledge of probabilistic modeling and you will be able to design and implement Bayesian models for your own data science problems. After reading the book you will be better prepared to delve into more advanced material or specialized statistical modeling if you need to.

Preface

Who this book is for

What this book covers

To get the most out of this book

Free Chapter

Thinking Probabilistically

Thinking Probabilistically

Statistics, models, and this book's approach

Probability theory

Single-parameter inference

Communicating a Bayesian analysis

Posterior predictive checks

Programming Probabilistically

Programming Probabilistically

Probabilistic programming

Summarizing the posterior

Gaussians all the way down

Groups comparison

Hierarchical models

Modeling with Linear Regression

Modeling with Linear Regression

Simple linear regression

Robust linear regression

Hierarchical linear regression

Polynomial regression

Multiple linear regression

Variable variance

Generalizing Linear Models

Generalizing Linear Models

Generalized linear models

Logistic regression

Multiple logistic regression

Poisson regression

Robust logistic regression

Model Comparison

Model Comparison

Posterior predictive checks

Occam's razor – simplicity and accuracy

Information criteria

Regularizing priors

Mixture Models

Finite mixture models

Non-finite mixture model

Continuous mixtures

Gaussian Processes

Gaussian Processes

Linear models and non-linear data

Modeling functions

Gaussian process regression

Regression with spatial autocorrelation

Gaussian process classification

Inference Engines

Inference Engines

Inference engines

Non-Markovian methods

Markovian methods

Diagnosing the samples

Where To Go Next?

Where To Go Next?

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Other Books You May Enjoy

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Exercises

Use the grid approach with other priors; for example, try with prior = (grid <= 0.5).astype(int) or prior = abs(grid - 0.5), or try defining your own crazy priors. Experiment with other data, such as increasing the total amount of data or making it more or less even in terms of the number of heads you observe.
In the code we use to estimate π, keep N fixed and re-run the code a couple of times. Notice that the results are different because we are using random numbers, but also check that the errors are more or less in the same order. Try changing the number of N points and re-run the code. Can you guesstimate how the number of N points and the error are related? For a better estimation, you may want to modify the code to compute the error as a function of N. You can also run the code a few times with the same N and compute the mean error and standard deviation...