Getting started with grpreg

Patrick Breheny

grpreg is an R package for fitting the regularization path of linear regression, GLM, and Cox regression models with grouped penalties. This includes group selection methods such as group lasso, group MCP, and group SCAD as well as bi-level selection methods such as the group exponential lasso, the composite MCP, and the group bridge. Utilities for carrying out cross-validation as well as post-fitting visualization, summarization, and prediction are also provided.

This vignette offers a brief introduction to the basic use of grpreg. For more details on the package, visit the grpreg website at https://pbreheny.github.io/grpreg/. For more on the algorithms used by grpreg, see the original articles:

For more information on specific penalties, see https://pbreheny.github.io/grpreg/articles/web/penalties.html.

grpreg comes with a few example data sets; we’ll look at Birthwt, which involves identifying risk factors associated with low birth weight. The outcome can either be measured continuously (bwt, the birth weight in kilograms) or dichotomized (low) with respect to the newborn having a low birth weight (under 2.5 kg).

data(Birthwt)
X <- Birthwt$X
y <- Birthwt$bwt
head(X)
#             age1         age2         age3        lwt1        lwt2         lwt3
# [1,] -0.05833434  0.011046300  0.029561818  0.12446282 -0.02133871 -0.130731102
# [2,]  0.13436561  0.055245529 -0.096907046  0.06006722 -0.06922831 -0.033348413
# [3,] -0.04457006 -0.009415469  0.045088774 -0.05918388  0.03746349  0.004618178
# [4,] -0.03080577 -0.026243567  0.052489640 -0.05202881  0.02390664  0.019034579
# [5,] -0.07209862  0.035141739  0.004821882 -0.05441384  0.02832410  0.014571538
# [6,] -0.03080577 -0.026243567  0.052489640 -0.01386846 -0.03296942  0.049559472
#      white black smoke ptl1 ptl2m ht ui ftv1 ftv2 ftv3m
# [1,]     0     1     0    0     0  0  1    0    0     0
# [2,]     0     0     0    0     0  0  0    0    0     1
# [3,]     1     0     1    0     0  0  0    1    0     0
# [4,]     1     0     1    0     0  0  1    0    1     0
# [5,]     1     0     1    0     0  0  1    0    0     0
# [6,]     0     0     0    0     0  0  0    0    0     0

The original design matrix consisted of 8 variables, which have been expanded here into 16 features. For example, there are multiple indicator functions for race (“other” being the reference group) and several continuous factors such as age have been expanded using polynomial contrasts (splines would give a similar structure). Hence, the columns of the design matrix are grouped; this is what grpreg is designed for. The grouping information is encoded as follows:

group <- Birthwt$group
group
#  [1] age   age   age   lwt   lwt   lwt   race  race  smoke ptl   ptl   ht   
# [13] ui    ftv   ftv   ftv  
# Levels: age lwt race smoke ptl ht ui ftv

Here, groups are given as a factor; unique integer codes (which are essentially unlabeled factors) and character vectors are also allowed (character vectors do have some limitations, however, as the order of the groups is left unspecified, which can lead to ambiguity if you also try to set the group.multiplier option). To fit a group lasso model to this data:

fit <- grpreg(X, y, group, penalty="grLasso")

We can then plot the coefficient paths with

plot(fit)

Notice that when a group enters the model (e.g., the green group), all of its coefficients become nonzero; this is what happens with group lasso models. To see what the coefficients are, we could use the coef function:

coef(fit, lambda=0.05)
# (Intercept)        age1        age2        age3        lwt1        lwt2 
#  3.02892181  0.14045229  0.62608119  0.37683684  0.74715315 -0.15825582 
#        lwt3       white       black       smoke        ptl1       ptl2m 
#  0.58290856  0.18344777 -0.06107624 -0.18778377 -0.17422515  0.05710668 
#          ht          ui        ftv1        ftv2       ftv3m 
# -0.29776948 -0.38050822  0.00000000  0.00000000  0.00000000

Note that the number of physician’s visits (ftv) is not included in the model at \(\lambda=0.05\).

Typically, one would carry out cross-validation for the purposes of carrying out inference on the predictive accuracy of the model at various values of \(\lambda\).

cvfit <- cv.grpreg(X, y, group, penalty="grLasso")
plot(cvfit)

The coefficients corresponding to the value of \(\lambda\) that minimizes the cross-validation error can be obtained via coef:

coef(cvfit)
# (Intercept)        age1        age2        age3        lwt1        lwt2 
#  3.04158282  0.03585964  1.31006421  0.77036812  1.56663368 -0.04705625 
#        lwt3       white       black       smoke        ptl1       ptl2m 
#  1.15399868  0.26474685 -0.12475165 -0.25602530 -0.26542118  0.16769927 
#          ht          ui        ftv1        ftv2       ftv3m 
# -0.48892550 -0.44999086  0.06039457  0.01966211 -0.09634012

Predicted values can be obtained via predict, which has a number of options:

predict(cvfit, X=head(X))                 # Predictions for new observations
# [1] 2.547122 3.006659 3.042348 2.564257 2.577717 3.083550
predict(fit, type="ngroups", lambda=0.1)  # Number of nonzero groups
# [1] 5
predict(fit, type="groups", lambda=0.1)   # Identity of nonzero groups
# [1] race  smoke ptl   ht    ui   
# Levels: age lwt race smoke ptl ht ui ftv
predict(fit, type="nvars", lambda=0.1)    # Number of nonzero coefficients
# [1] 7
predict(fit, type="vars", lambda=0.1)     # Identity of nonzero coefficients
# white black smoke  ptl1 ptl2m    ht    ui 
#     7     8     9    10    11    12    13

Note that the original fit (to the full data set) is returned as cvfit$fit; it is not necessary to call both grpreg and cv.grpreg to analyze a data set. Several other penalties are available, as are methods for logistic regression and Cox proportional hazards regression.