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Maintainer: | Martin Maechler |
Contact: | Martin.Maechler at R-project.org |
Version: | 2023-07-01 |
URL: | https://CRAN.R-project.org/view=Robust |
Source: | https://github.com/cran-task-views/Robust/ |
Contributions: | Suggestions and improvements for this task view are very welcome and can be made through issues or pull requests on GitHub or via e-mail to the maintainer address. For further details see the Contributing guide. |
Citation: | Martin Maechler (2023). CRAN Task View: Robust Statistical Methods. Version 2023-07-01. URL https://CRAN.R-project.org/view=Robust. |
Installation: | The packages from this task view can be installed automatically using the ctv package. For example, ctv::install.views("Robust", coreOnly = TRUE) installs all the core packages or ctv::update.views("Robust") installs all packages that are not yet installed and up-to-date. See the CRAN Task View Initiative for more details. |
Robust (or “resistant”) methods for statistics modelling have been available in S from the very beginning in the 1980s; and then in R in package stats
. Examples are median()
, mean(*, trim =. )
, mad()
, IQR()
, or also fivenum()
, the statistic behind boxplot()
in package graphics
) or lowess()
(and loess()
) for robust nonparametric regression, which had been complemented by runmed()
in 2003. Much further important functionality has been made available in recommended (and hence present in all R versions) package MASS (by Bill Venables and Brian Ripley, see the book Modern Applied Statistics with S). Most importantly, they provide rlm()
for robust regression and cov.rob()
for robust multivariate scatter and covariance.
This task view is about R add-on packages providing newer or faster, more efficient algorithms and notably for (robustification of) new models.
Please send suggestions for additions and extensions via e-mail to the maintainer or submit an issue or pull request in the GitHub repository linked above.
An international group of scientists working in the field of robust statistics has made efforts (since October 2005) to coordinate several of the scattered developments and make the important ones available through a set of R packages complementing each other. These should build on a basic package with “Essentials”, coined robustbase with (potentially many) other packages building on top and extending the essential functionality to particular models or applications. Since 2020 and the 2nd edition of Robust Statistics: Theory and Methods , RobStatTM covers its estimators and examples, notably by importing from robustbase and rrcov. Further, there is the quite comprehensive package robust, a version of the robust library of S-PLUS, as an R package now GPLicensed thanks to Insightful and Kjell Konis. Originally, there has been much overlap between robustbase and robust, now robust depends on robustbase and rrcov, where robust provides convenient routines for the casual user while robustbase and rrcov contain the underlying functionality, and provide the more advanced statistician with a large range of options for robust modeling.
We structure the packages roughly into the following topics, and typically will first mention functionality in packages robustbase, rrcov and robust.
Linear Regression:
lmrob()
(robustbase) and lmRob()
(robust) where the former uses the latest of the fast-S algorithms and heteroscedasticity and autocorrelation corrected (HAC) standard errors, the latter makes use of the M-S algorithm of Maronna and Yohai (2000), automatically when there are factors among the predictors (where S-estimators (and hence MM-estimators) based on resampling typically badly fail). The ltsReg()
and lmrob.S()
functions are available in robustbase, but rather for comparison purposes. rlm()
from MASS had been the first widely available implementation for robust linear models, and also one of the very first MM-estimation implementations. robustreg provides very simple M-estimates for linear regression (in pure R). Note that Koenker’s quantile regression package quantreg contains L1 (aka LAD, least absolute deviations)-regression as a special case, doing so also for nonparametric regression via splines. Package mblm’s function mblm()
fits median-based (Theil-Sen or Siegel’s repeated) simple linear models.
Note that a location (and scale) model is a regression with only an intercept and may be approached by e.g., lmrob(y ~ 1)
. For very small samples, location robLoc()
and scale robScale()
are also provided by revss.
Generalized Linear Models ( GLM s) for Regression:
GLMs are provided both via glmrob()
(robustbase) and glmRob()
(robust). drgee fits “Doubly Robust” Generalized Estimating Equations (GEEs), complmrob does robust linear regression with compositional data as covariates.
Generalized Smooth/Additive (GAM-like) Regression:
Package GJRM’s gamlss()
function with option gamlss(*, robust = TRUE)
allows fitting many model families robustly (wrapped inside the LSS “location-scale-shape” transformation scope).
Nonlinear / Smooth (Nonparametric Function) Regression:
Robust Nonlinear model fitting is available through robustbase’s nlrob()
.
Mixed-Effects (Linear and Nonlinear) Regression:
Quantile regression (and hence L1 or LAD) for mixed effect models, is available in package lqmm. Rank-based mixed effect fitting from package rlme, whereas an MM-like approach for robust linear mixed effects modeling is available from package robustlmm. More recently, skewlmm provides robust linear mixed-effects models LMM via scale mixtures of skew-normal distributions.
Depends
) on robustbase provides nice S4 class based methods, more methods for robust multivariate variance-covariance estimation, and adds robust PCA methodology.NA
) data, and by rrcovHD, providing robust multivariate methods for High Dimensional data.princomp()
, e.g., X <- stackloss; pc.rob <- princomp(X, covmat= MASS::cov.rob(X))
covMcd()
than robust’s fastmcd()
, and similarly for covOGK()
. On the other hand, robust’s covRob()
has automatically chosen methods, notably pairwiseQC()
for large dimensionality p. Package robustX for experimental, or other not yet established procedures, contains BACON()
and covNCC()
, the latter providing the neighbor variance estimation (NNVE) method of Wang and Raftery (2002), also available (slightly less optimized) in covRobust.FastQn()
.pam()
implementing “partioning around medians” is partly robust (medians instead of very unrobust k-means) but is not good enough, as e.g., the k clusters could consist of k-1 outliers one cluster for the bulk of the remaining data.BACON()
(in robustX) should be applicable for larger (n,p) than traditional robust covariance based outlier detectors.boxplot.stats()
, etc mentioned aboverunmed()
provides most robust running median filtering.vcov(lmrob())
also uses a version of HAC standard errors for its robustly estimated linear models. See also the CRAN task view EconometricsCore: | MASS, robust, robustbase, rrcov. |
Regular: | clubSandwich, cluster, clusterSEs, complmrob, covRobust, coxrobust, distr, drgee, genie, GJRM, Gmedian, GSE, lqmm, mblm, metaplus, mvoutlier, otrimle, pcaPP, quantreg, RandVar, revss, rlme, RobAStBase, robcor, robfilter, RobLox, RobLoxBioC, RobPer, RobStatTM, robsurvey, robumeta, RobustAFT, robustDA, robustlmm, robustreg, robustX, ROptEst, rospca, rpca, rrcovHD, rrcovNA, RSKC, sandwich, skewlmm, ssmrob, tclust, walrus, WRS2. |
Archived: | robeth, RobRex, ROptRegTS. |
These binaries (installable software) and packages are in development.
They may not be fully stable and should be used with caution. We make no claims about them.