In sthawinke/pengls: Fit Penalised Generalised Least Squares models
Introduction
This vignette demonstrates the use of the pengls package for high-dimensional data with spatial or temporal autocorrelation. It consists of an iterative loop around the nlme \parencite{Pinheiro2021} and glmnet \parencite{Friedman2010} packages. Currently, only continuous outcomes and $R^2$ and MSE as performance measure are implemented.
\setcounter{tocdepth}{5}
\tableofcontents
Installation instuctions
The pengls package is available from BioConductor, and can be installed as follows:
library(BiocManager)
install("pengls")
Once installed, it can be loaded and version info printed.
suppressPackageStartupMessages(library(pengls))
cat("pengls package version", as.character(packageVersion("pengls")), "\n")
Illustration
Spatial autocorrelation
We first create a toy dataset with spatial coordinates.
library(nlme)
n <- 25 #Sample size
p <- 50 #Number of features
g <- 15 #Size of the grid
#Generate grid
Grid <- expand.grid("x" = seq_len(g), "y" = seq_len(g))
# Sample points from grid without replacement
GridSample <- Grid[sample(nrow(Grid), n, replace = FALSE),]
#Generate outcome and regressors
b <- matrix(rnorm(p*n), n , p)
a <- rnorm(n, mean = b %*% rbinom(p, size = 1, p = 0.25), sd = 0.1) #25% signal
#Compile to a matrix
df <- data.frame("a" = a, "b" = b, GridSample)
The pengls method requires prespecification of a functional form for the autocorrelation. This is done through the corStruct objects defined by the nlme package. We specify a correlation decaying as a Gaussian curve with distance, and with a nugget parameter. The nugget parameter is a proportion that indicates how much of the correlation structure explained by independent errors; the rest is attributed to spatial autocorrelation. The starting values are chosen as reasonable guesses; they will be overwritten in the fitting process.
# Define the correlation structure (see ?nlme::gls), with initial nugget 0.5 and range 5
corStruct <- corGaus(form = ~ x + y, nugget = TRUE, value = c("range" = 5, "nugget" = 0.5))
Finally the model is fitted with a single outcome variable and large number of regressors, with the chosen covariance structure and for a prespecified penalty parameter $\lambda=0.2$.
#Fit the pengls model, for simplicity for a simple lambda
penglsFit <- pengls(data = df, outVar = "a", xNames = grep(names(df), pattern = "b", value =TRUE), glsSt = corStruct, lambda = 0.2, verbose = TRUE)
Standard extraction functions like print(), coef() and predict() are defined for the new "pengls" object.
penglsFit
penglsCoef <- coef(penglsFit)
penglsPred <- predict(penglsFit)
Temporal autocorrelation
The method can also account for temporal autocorrelation by defining another correlation structure from the nlme package, e.g. autocorrelation structure of order 1:
set.seed(354509)
n <- 100 #Sample size
p <- 10 #Number of features
#Generate outcome and regressors
b <- matrix(rnorm(p*n), n , p)
a <- rnorm(n, mean = b %*% rbinom(p, size = 1, p = 0.25), sd = 0.1) #25% signal
#Compile to a matrix
dfTime <- data.frame("a" = a, "b" = b, "t" = seq_len(n))
corStructTime <- corAR1(form = ~ t, value = 0.5)
The fitting command is similar, this time the $\lambda$ parameter is found through cross-validation of the naive glmnet (for full cross-validation , see below). We choose $\alpha=0.5$ this time, fitting an elastic net model.
penglsFitTime <- pengls(data = dfTime, outVar = "a", verbose = TRUE,
xNames = grep(names(dfTime), pattern = "b", value =TRUE),
glsSt = corStructTime, nfolds = 5, alpha = 0.5)
Show the output
penglsFitTime
Penalty parameter and cross-validation
The pengls package also provides cross-validation for finding the optimal $\lambda$ value. If the tuning parameter $\lambda$ is not supplied, the optimal $\lambda$ according to cross-validation with the naive glmnet function (the one that ignores dependence) is used. Hence we recommend to use the following function to use cross-validation. Multithreading is supported through the BiocParallel package \parencite{Morgan2020}:
library(BiocParallel)
register(MulticoreParam(3)) #Prepare multithereading
nfolds <- 3 #Number of cross-validation folds
The function is called similarly to cv.glmnet:
penglsFitCV <- cv.pengls(data = df, outVar = "a", xNames = grep(names(df), pattern = "b", value =TRUE), glsSt = corStruct, nfolds = nfolds)
Check the result:
penglsFitCV
By default, the 1 standard error is used to determine the optimal value of $\lambda$ \parencite{Friedman2010}:
penglsFitCV$lambda.1se #Lambda for 1 standard error rule
penglsFitCV$cvOpt #Corresponding R2
Extract coefficients and fold IDs.
head(coef(penglsFitCV))
penglsFitCV$foldid #The folds used
By default, blocked cross-validation is used, but random cross-validation is also available (but not recommended for timecourse or spatial data). First we illustrate the different ways graphically, again using the timecourse example:
set.seed(5657)
randomFolds <- makeFolds(nfolds = nfolds, dfTime, "random", "t")
blockedFolds <- makeFolds(nfolds = nfolds, dfTime, "blocked", "t")
plot(dfTime$t, randomFolds, xlab ="Time", ylab ="Fold")
points(dfTime$t, blockedFolds, col = "red")
legend("topleft", legend = c("random", "blocked"), pch = 1, col = c("black", "red"))
To perform random cross-validation
penglsFitCVtime <- cv.pengls(data = dfTime, outVar = "a", xNames = grep(names(dfTime), pattern = "b", value =TRUE), glsSt = corStructTime, nfolds = nfolds, cvType = "random")
To negate baseline differences at different timepoints, it may be useful to center or scale the outcomes in the cross validation. For instance for centering only:
penglsFitCVtimeCenter <- cv.pengls(data = dfTime, outVar = "a", xNames = grep(names(dfTime), pattern = "b", value =TRUE), glsSt = corStructTime, nfolds = nfolds, cvType = "blocked", transFun = function(x) x-mean(x))
penglsFitCVtimeCenter$cvOpt #Better performance
Alternatively, the mean squared error (MSE) can be used as loss function, rather than the default $R^2$:
penglsFitCVtime <- cv.pengls(data = dfTime, outVar = "a", xNames = grep(names(dfTime), pattern = "b", value =TRUE), glsSt = corStructTime, nfolds = nfolds, loss = "MSE")
Session info
sessionInfo()
\clearpage
\printbibliography
sthawinke/pengls documentation built on July 2, 2023, 7:27 a.m.
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Introduction
This vignette demonstrates the use of the pengls package for high-dimensional data with spatial or temporal autocorrelation. It consists of an iterative loop around the nlme \parencite{Pinheiro2021} and glmnet \parencite{Friedman2010} packages. Currently, only continuous outcomes and $R^2$ and MSE as performance measure are implemented.
\setcounter{tocdepth}{5} \tableofcontents
Installation instuctions
The pengls package is available from BioConductor, and can be installed as follows:
library(BiocManager) install("pengls")
Once installed, it can be loaded and version info printed.
suppressPackageStartupMessages(library(pengls)) cat("pengls package version", as.character(packageVersion("pengls")), "\n")
Illustration
Spatial autocorrelation
We first create a toy dataset with spatial coordinates.
library(nlme) n <- 25 #Sample size p <- 50 #Number of features g <- 15 #Size of the grid #Generate grid Grid <- expand.grid("x" = seq_len(g), "y" = seq_len(g)) # Sample points from grid without replacement GridSample <- Grid[sample(nrow(Grid), n, replace = FALSE),] #Generate outcome and regressors b <- matrix(rnorm(p*n), n , p) a <- rnorm(n, mean = b %*% rbinom(p, size = 1, p = 0.25), sd = 0.1) #25% signal #Compile to a matrix df <- data.frame("a" = a, "b" = b, GridSample)
The pengls method requires prespecification of a functional form for the autocorrelation. This is done through the corStruct objects defined by the nlme package. We specify a correlation decaying as a Gaussian curve with distance, and with a nugget parameter. The nugget parameter is a proportion that indicates how much of the correlation structure explained by independent errors; the rest is attributed to spatial autocorrelation. The starting values are chosen as reasonable guesses; they will be overwritten in the fitting process.
# Define the correlation structure (see ?nlme::gls), with initial nugget 0.5 and range 5 corStruct <- corGaus(form = ~ x + y, nugget = TRUE, value = c("range" = 5, "nugget" = 0.5))
Finally the model is fitted with a single outcome variable and large number of regressors, with the chosen covariance structure and for a prespecified penalty parameter $\lambda=0.2$.
#Fit the pengls model, for simplicity for a simple lambda penglsFit <- pengls(data = df, outVar = "a", xNames = grep(names(df), pattern = "b", value =TRUE), glsSt = corStruct, lambda = 0.2, verbose = TRUE)
Standard extraction functions like print(), coef() and predict() are defined for the new "pengls" object.
penglsFit penglsCoef <- coef(penglsFit) penglsPred <- predict(penglsFit)
Temporal autocorrelation
The method can also account for temporal autocorrelation by defining another correlation structure from the nlme package, e.g. autocorrelation structure of order 1:
set.seed(354509) n <- 100 #Sample size p <- 10 #Number of features #Generate outcome and regressors b <- matrix(rnorm(p*n), n , p) a <- rnorm(n, mean = b %*% rbinom(p, size = 1, p = 0.25), sd = 0.1) #25% signal #Compile to a matrix dfTime <- data.frame("a" = a, "b" = b, "t" = seq_len(n)) corStructTime <- corAR1(form = ~ t, value = 0.5)
The fitting command is similar, this time the $\lambda$ parameter is found through cross-validation of the naive glmnet (for full cross-validation , see below). We choose $\alpha=0.5$ this time, fitting an elastic net model.
penglsFitTime <- pengls(data = dfTime, outVar = "a", verbose = TRUE, xNames = grep(names(dfTime), pattern = "b", value =TRUE), glsSt = corStructTime, nfolds = 5, alpha = 0.5)
Show the output
penglsFitTime
Penalty parameter and cross-validation
The pengls package also provides cross-validation for finding the optimal $\lambda$ value. If the tuning parameter $\lambda$ is not supplied, the optimal $\lambda$ according to cross-validation with the naive glmnet function (the one that ignores dependence) is used. Hence we recommend to use the following function to use cross-validation. Multithreading is supported through the BiocParallel package \parencite{Morgan2020}:
library(BiocParallel) register(MulticoreParam(3)) #Prepare multithereading
nfolds <- 3 #Number of cross-validation folds
The function is called similarly to cv.glmnet:
penglsFitCV <- cv.pengls(data = df, outVar = "a", xNames = grep(names(df), pattern = "b", value =TRUE), glsSt = corStruct, nfolds = nfolds)
Check the result:
penglsFitCV
By default, the 1 standard error is used to determine the optimal value of $\lambda$ \parencite{Friedman2010}:
penglsFitCV$lambda.1se #Lambda for 1 standard error rule penglsFitCV$cvOpt #Corresponding R2
Extract coefficients and fold IDs.
head(coef(penglsFitCV)) penglsFitCV$foldid #The folds used
By default, blocked cross-validation is used, but random cross-validation is also available (but not recommended for timecourse or spatial data). First we illustrate the different ways graphically, again using the timecourse example:
set.seed(5657) randomFolds <- makeFolds(nfolds = nfolds, dfTime, "random", "t") blockedFolds <- makeFolds(nfolds = nfolds, dfTime, "blocked", "t") plot(dfTime$t, randomFolds, xlab ="Time", ylab ="Fold") points(dfTime$t, blockedFolds, col = "red") legend("topleft", legend = c("random", "blocked"), pch = 1, col = c("black", "red"))
To perform random cross-validation
penglsFitCVtime <- cv.pengls(data = dfTime, outVar = "a", xNames = grep(names(dfTime), pattern = "b", value =TRUE), glsSt = corStructTime, nfolds = nfolds, cvType = "random")
To negate baseline differences at different timepoints, it may be useful to center or scale the outcomes in the cross validation. For instance for centering only:
penglsFitCVtimeCenter <- cv.pengls(data = dfTime, outVar = "a", xNames = grep(names(dfTime), pattern = "b", value =TRUE), glsSt = corStructTime, nfolds = nfolds, cvType = "blocked", transFun = function(x) x-mean(x)) penglsFitCVtimeCenter$cvOpt #Better performance
Alternatively, the mean squared error (MSE) can be used as loss function, rather than the default $R^2$:
penglsFitCVtime <- cv.pengls(data = dfTime, outVar = "a", xNames = grep(names(dfTime), pattern = "b", value =TRUE), glsSt = corStructTime, nfolds = nfolds, loss = "MSE")
Session info
sessionInfo()
\clearpage
\printbibliography
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