The geostan R package supports a complete spatial analysis workflow with Bayesian models for areal data, including a suite of functions for visualizing spatial data and model results. geostan models were built using Stan, a state-of-the-art platform for Bayesian modeling.
Introductions to the software can be found at r-spatial.org and in the package vignettes.
Features include:
- Disease mapping and spatial regression Statistical models for data recorded across areal units like states, counties, or census tracts.
- Spatial analysis tools Tools for visualizing and measuring spatial autocorrelation and map patterns, for exploratory analysis and model diagnostics.
- Observational uncertainty Incorporate information on data reliability, such as standard errors of American Community Survey estimates, into any geostan model.
- Missing and Censored observations Vital statistics and disease surveillance systems like CDC Wonder censor case counts that fall below a threshold number; geostan can model disease or mortality risk for small areas with censored observations or with missing observations.
- The RStan ecosystem Interfaces easily with many high-quality R packages for Bayesian modeling.
- Custom spatial models Tools for building custom spatial models in Stan.
For public health research, geostan complements the surveil R package for the study of time trends in disease incidence or mortality data.
There are two ways to install geostan: directly from the package github repository or from the Comprehensive R Archive Network (CRAN).
Using your R console, you can install geostan from CRAN:
install.packages("geostan")
You can install geostan from github:
if (!require('devtools')) install.packages('devtools')
devtools::install_github("connordonegan/geostan")
If you are using Windows and installing with install_github
, you may
need to install Rtools
first (this is not needed when installing from CRAN). To install Rtools:
- Visit the Rtools site: https://cran.r-project.org/bin/windows/Rtools/
- Select the version that corresponds to the version of R that you have installed (e.g., R 4.3).
- After selecting the correct version, look for the “Install Rtools” section (just below the introductory text) and click on the “installer” to download it. For example, for Rtools43 (for R version 4.3), click on “Rtools43 installer.”
- Go to the
.exe
file you just downloaded and double-click to begin installation of Rtools.
If you are using Mac and installing with install_github
then you may
need to install Xcode Command Line Tools first.
All functions and methods are documented (with examples) on the website reference page. See the package vignettes for more on exploratory spatial analysis, spatial measurement error models, spatial regression with raster layers, and building custom spatial model in Stan.
To ask questions, report a bug, or discuss ideas for improvements or new features please visit the issues page, start a discussion, or submit a pull request.
Load the package and the georgia
county mortality data set:
library(geostan)
data(georgia)
This has county population and mortality data by sex for ages 55-64, and for the period 2014-2018. As is common for public access data, some of the observations missing because the CDC has censored them.
The sp_diag
function provides visual summaries of spatial data,
including a histogram, Moran scatter plot, and map. Here is a visual
summary of crude female mortality rates (as deaths per 10,000):
A <- shape2mat(georgia, style = "B")
#> Contiguity condition: queen
#> Number of neighbors per unit, summary:
#> Min. 1st Qu. Median Mean 3rd Qu. Max.
#> 1.000 4.000 5.000 5.409 6.000 10.000
#>
#> Spatial weights, summary:
#> Min. 1st Qu. Median Mean 3rd Qu. Max.
#> 1 1 1 1 1 1
mortality_rate <- georgia$rate.female * 10e3
sp_diag(mortality_rate, georgia, w = A)
#> 3 NA values found in x will be dropped from data x and matrix w
#> Warning: Removed 3 rows containing non-finite outside the scale
#> range (`stat_bin()`).
The following code fits a spatial conditional autoregressive (CAR) model
to female county mortality data. These models are used for estimating
disease risk in small areas like counties, and for analyzing covariation
of health outcomes with other area qualities. The R syntax for fitting
the models is similar to using lm
or glm
. We provide the population
at risk (the denominator for mortality rates) as an offset term, using
the log-transform. In this case, three of the observations are missing
because they have been censored; per CDC criteria, this means that there
were 9 or fewer deaths in those counties. By using the censor_point
argument and setting it to censor_point = 9
, the model will account
for the censoring process when providing estimates of the mortality
rates:
cars <- prep_car_data(A)
#> Range of permissible rho values: -1.661, 1
fit <- stan_car(deaths.female ~ offset(log(pop.at.risk.female)),
censor_point = 9,
data = georgia,
car_parts = cars,
family = poisson(),
cores = 4, # for multi-core processing
refresh = 0) # to silence some printing
#> 3 NA values identified in the outcome variable
#> Found in rows: 55, 126, 157
#>
#> *Setting prior parameters for intercept
#> Distribution: normal
#> location scale
#> 1 -4.7 5
#>
#> *Setting prior for CAR scale parameter (car_scale)
#> Distribution: student_t
#> df location scale
#> 1 10 0 3
#>
#> *Setting prior for CAR spatial autocorrelation parameter (car_rho)
#> Distribution: uniform
#> lower upper
#> 1 -1.7 1
Passing a fitted model to the sp_diag
function will return a set of
diagnostics for spatial models:
sp_diag(fit, georgia, w = A)
#> Using sp_diag(y, shape, rates = TRUE, ...). To examine data as (unstandardized) counts, use rates = FALSE.
#> 3 NA values found in x will be dropped from data x and matrix w
#> Warning: Removed 3 rows containing missing values or values
#> outside the scale range (`geom_pointrange()`).
The print
method returns a summary of the probability distributions
for model parameters, as well as Markov chain Monte Carlo (MCMC)
diagnostics from Stan (Monte Carlo standard errors of the mean
se_mean
, effective sample size n_eff
, and the R-hat statistic
Rhat
):
print(fit)
#> Spatial Model Results
#> Formula: deaths.female ~ offset(log(pop.at.risk.female))
#> Spatial method (outcome): CAR
#> Likelihood function: poisson
#> Link function: log
#> Residual Moran Coefficient: 0.0011525
#> WAIC: 1227.47
#> Observations: 156
#> Data models (ME): none
#> Inference for Stan model: foundation.
#> 4 chains, each with iter=2000; warmup=1000; thin=1;
#> post-warmup draws per chain=1000, total post-warmup draws=4000.
#>
#> mean se_mean sd 2.5% 20% 50% 80% 97.5% n_eff Rhat
#> intercept -4.674 0.002 0.089 -4.849 -4.730 -4.674 -4.621 -4.505 2362 1.000
#> car_rho 0.923 0.001 0.058 0.778 0.879 0.937 0.973 0.995 3319 1.000
#> car_scale 0.458 0.001 0.036 0.395 0.428 0.456 0.488 0.534 3618 0.999
#>
#> Samples were drawn using NUTS(diag_e) at Tue Sep 17 16:44:56 2024.
#> For each parameter, n_eff is a crude measure of effective sample size,
#> and Rhat is the potential scale reduction factor on split chains (at
#> convergence, Rhat=1).
Applying the fitted
method to the fitted model will return the fitted
values from the model - in this case, the fitted values are the
estimates of the county mortality rates. Multiplying them by 10,000
gives mortality rate per 10,000 at risk:
mortality_est <- fitted(fit) * 10e3
county_name <- georgia$NAME
head( cbind(county_name, mortality_est) )
#> county_name mean sd 2.5% 20% 50%
#> fitted[1] Crisp 101.48785 9.604829 83.99009 93.31163 101.17610
#> fitted[2] Candler 136.99885 15.905146 109.27395 123.11823 136.31355
#> fitted[3] Barrow 94.25470 6.071597 82.80270 89.20105 94.16678
#> fitted[4] DeKalb 59.76214 1.579194 56.72962 58.44624 59.75766
#> fitted[5] Columbia 53.33958 3.257549 47.19615 50.56654 53.28387
#> fitted[6] Cobb 54.12983 1.498260 51.24933 52.85101 54.10133
#> 80% 97.5%
#> fitted[1] 109.30723 121.16598
#> fitted[2] 150.17348 169.77611
#> fitted[3] 99.19399 106.44508
#> fitted[4] 61.07091 62.86805
#> fitted[5] 56.08790 59.78086
#> fitted[6] 55.42278 57.02966
The mortality estimates are stored in the column named “mean”, and the limits of the 95% credible interval are found in the columns “2.5%” and “97.5%”.
Details and demonstrations can be found in the package help pages and vignettes.
If you use geostan in published work, please include a citation.
Donegan, Connor (2022) “geostan: An R package for Bayesian spatial analysis” The Journal of Open Source Software. 7, no. 79: 4716. https://doi.org/10.21105/joss.04716.
@Article{,
title = {{geostan}: An {R} package for {B}ayesian spatial analysis},
author = {Connor Donegan},
journal = {The Journal of Open Source Software},
year = {2022},
volume = {7},
number = {79},
pages = {4716},
doi = {10.21105/joss.04716},
}