https://www.physalia-courses.org/
Most of the statistical methods you are likely to have encountered will have specified fixed functional forms for the relationships between covariates and the response, either implicitly or explicitly. These might be linear effects or involve polynomials, such as x + x2 + x3. Generalised additive models (GAMs) are different; they build upon the generalised linear model by allowing the shapes of the relationships between response and covariates to be learned from the data using splines. Modern GAMs, it turns out, are a very general framework for data analysis, encompassing many models as special cases, including GLMs and GLMMs, and the variety of types of splines available to users allows GAMs to be used in a surprisingly large number of situations. In this course we’ll show you how to leverage the power and flexibility of splines to go beyond parametric modelling techniques like GLMs.
The course is aimed at graduate students and researchers with limited statistical knowledge; ideally you’d know something about generalised linear models. But we’ll recap what GLMs are so if you’re a little rusty or not everything mentioned in the GLM course makes sense, we have you covered. From running the course previously, knowing the difference between "fixed" and "random" effects, and what the terms "random intercepts" and "random slopes" are, will be helpful for the Hierarchical GAM topic, but we don't expect you to be an expert in mixed effects or hierarchical models to take this course.
Participants should be familiar with RStudio and have some fluency in programming R code, including being able to import, manipulate (e.g. modify variables) and visualise data. There will be a mix of lectures, in-class discussion, and hands-on practical exercises along the course.
- Understand how GAMs work from a practical view point to learn relationships between covariates and response from the data
- Be able to fit GAMs in R using the mgcv and brms packages
- Know the differences between the types of splines and when to use them in your models
- Know how to visualise fitted GAMs and to check the assumptions of the model
Please be sure to have at least version 4.3.0 of R installed (the version of my gratia package we will be using depends on you having at least version 4.1.0 installed and some slides might contain code that requires version 4.3.x). Note that R and RStudio are two different things: it is not sufficient to just update RStudio, you also need to update R by installing new versions as they are release.
To download R go to the CRAN Download page and follow the links to download R for your operating system:
To check what version of R you have installed, from within R, you can run
version
then look at the version.string
entry (or the major
and minor
entries). For example, on my system I see:
# ... output not shown ...
major 4
minor 3.3
# ... output not shown ...
R version 4.3.3 (2024-02-29)
# ... output not shown ...
We will make use of several R packages that you'll need to have installed. Prior to the start of the course, please run the following code to update your installed packages and then install the required packages:
# update any installed R packages
update.packages(ask = FALSE, checkBuilt = TRUE)
# packages to install
pkgs <- c("mgcv", "brms", "qgam", "gamm4", "tidyverse", "readxl",
"rstan", "mgcViz", "DHARMa", "gratia")
# install those packages
install.packages(pkgs, Ncpus = 4) # set Ncpus to # of *physical* CPU cores you have
Now we must check that we actually do have recent versions of the packages installed; if your R is not reasonably new (gratia requires R>= 4.1.0, but some of the tidyverse packages may need an R that is newer than this) then you may be stuck on out-dated versions of the packages listed above. This is why I recommend that you install the latest version of R. If you choose to use an older version of R than version 4.3.x (where x is 0, 1, 2, or 3, currently) then you do so at your own risk and you cannot expect support with setup problems during the course.
vapply(pkgs, packageDescription, character(1), drop = TRUE, fields = "Version")
On my system I see:
> vapply(head(pkgs, -1), packageDescription, character(1), drop = TRUE, fields
= "Version")
mgcv brms qgam gamm4 tidyverse readxl rstan mgcViz
"1.9-1" "2.21.0" "1.3.4" "0.2-6" "2.0.0" "1.4.3" "2.32.6" "0.1.11"
DHARMa gratia
"0.4.6" "0.9.0"
The key ones are to be sure that gratia is version "0.9.0", mgcv is at least "1.9-0" (preferably "0.9-1"), and tidyverse is "2.0.0".
Fitting GAMs with Stan is quite time consuming if we use the standard rstan interface. To speed things up significantly, we can use the cmdstan backend, however this requires a little more setup. If you can't get this to work don't worry, it's not an integral part of the course, as you can still use the rstan backend with brm()
.
cmdstan requires a working C++ compiler on your system. Typically, Windows and MacOS X machines do not come with one installed by default. To install the C++ toolchain required you should follow the instructions here, only the bits in the C++ Toolchain section that is linked to. If you're on a recent MacOS X system, installation of the required toolchain is relatively simple, requiring only installation of some parts of xcode. On Windows, things are slightly more complicated as you need to install the version of RTools for your version of R and then add some details to your PATH
to allow the toolchain to be run from the command line. There are slightly different instructions (versions of RTools) to install depending on your version of R. If any of this sounds too complicated for you, just stop here and don't proceed; you don't need to run the brm()
code when I am working through some examples and we won't spend a lot of time on fully Bayesian GAMs anyway.
Once you have the toolchain installed, to do the actual installation of the cmdstan backend we need to load the cmndstanr package and complete some steps. Give yourself some time to do this as the options below will download the backend and start to compile it for your computer.
# install cmdstanr
install.packages("cmdstanr",
repos = c("https://mc-stan.org/r-packages/", getOption("repos")))
# load the R package interface to cmdstan
library(cmdstanr)
# check the your toolchain is configured correctly and working
check_cmdstan_toolchain()
# if this says anything other than that the toolchain is configured properly
# stop(!) and go back to the C++ Toolchain instructions and make sure you
# have completed all the steps for your OS
# install cmndstan backend
# You can increase `cores` if you have more cores available on your system
# if in doubt, just leave it as shown below
install_cmdstan(cores = 2)
# wait for some time...
# you can confirm that cmndstan is installed and what version you have with
cmdstan_path()
cmdstan_version()
Sessions from 14:00 to 20:00 (Monday to Thursday), 14:00 to 19:00 on Friday (Berlin time). From Tuesday to Friday, the first hour will be dedicated to Q&A and working through practical exercises or students’ own analyses over Slack and Zoom. Sessions will interweave mix lectures, in-class discussion/ Q&A, and practical exercises.
- Brief overview of R and the Tidyverse packages we’ll encounter throughout the course
- Recap generalised linear models
- Fitting your first GAM
- How do GAMs work?
- What are splines?
- How do GAMs learn from data without overfitting?
We’ll dig under the hood a bit to understand how GAMs work at a practical level and how to use the mgcv and gratia packages to estimate GAMs and visualise them.
- Model checking, selection, and visualisation.
- How do we do inference with GAMs?
- Go beyond simple GAMs to include smooth interactions and models with multiples smooths.
- Hierarchical GAMs; introducing random smooths and how to model data with both group and individual smooth effects.
- Doing more with your models; introducing posterior simulation.
- Going beyond the mean; fitting distributional models and quantile GAMs
- Fitting Bayesian GAMs with brms