vcovBS | R Documentation |
Object-oriented estimation of basic bootstrap covariances, using
simple (clustered) case-based resampling, plus more refined methods
for lm
and glm
models.
vcovBS(x, ...)
## Default S3 method:
vcovBS(x, cluster = NULL, R = 250, start = FALSE, type = "xy", ...,
fix = FALSE, use = "pairwise.complete.obs", applyfun = NULL, cores = NULL,
center = "mean")
## S3 method for class 'lm'
vcovBS(x, cluster = NULL, R = 250, type = "xy", ...,
fix = FALSE, use = "pairwise.complete.obs", applyfun = NULL, cores = NULL,
qrjoint = FALSE, center = "mean")
## S3 method for class 'glm'
vcovBS(x, cluster = NULL, R = 250, start = FALSE, type = "xy", ...,
fix = FALSE, use = "pairwise.complete.obs", applyfun = NULL, cores = NULL,
center = "mean")
x |
a fitted model object. |
cluster |
a variable indicating the clustering of observations,
a |
R |
integer. Number of bootstrap replications. |
start |
logical. Should |
type |
character (or function). The character string specifies the type of
bootstrap to use: In the default and |
... |
arguments passed to methods. For the default method, this is
passed to |
fix |
logical. Should the covariance matrix be fixed to be positive semi-definite in case it is not? |
use |
character. Specification passed to |
applyfun |
an optional |
cores |
numeric. If set to an integer the |
center |
character. For |
qrjoint |
logical. For residual-based and wild boostrap (i.e.,
|
Clustered sandwich estimators are used to adjust inference when errors
are correlated within (but not between) clusters. See the documentation for vcovCL
for specifics about covariance clustering. This function allows
for clustering in arbitrarily many cluster dimensions (e.g., firm, time, industry), given all
dimensions have enough clusters (for more details, see Cameron et al. 2011).
Unlike vcovCL
, vcovBS
uses a bootstrap rather than an asymptotic solution.
Basic (clustered) bootstrap covariance matrix estimation is provided by
the default vcovBS
method. It samples clusters (where each observation
is its own cluster by default), i.e., using case-based resampling. For obtaining
a covariance matrix estimate it is assumed that an update
of the model with the resampled subset
can be obtained, the coef
extracted, and finally the covariance computed with cov
.
The update
model is evaluated in the environment(terms(x))
(if available).
To speed up computations two further arguments can be leveraged.
Instead of lapply
a parallelized function such as
parLapply
or mclapply
can be specified to iterate over the bootstrap replications. For the latter,
specifying cores = ...
is a convenience shortcut.
When specifying start = TRUE
, the coef(x)
are passed to
update
as start = coef(x)
. This may not be supported by all
model fitting functions and is hence not turned on by default.
The “xy” or “pairs” bootstrap is consistent for heteroscedasticity and clustered errors,
and converges to the asymptotic solution used in vcovCL
as R
, n
, and g
become large (n
and g
are the number of
observations and the number of clusters, respectively; see Efron 1979, or Mammen 1992, for a
discussion of bootstrap asymptotics). For small g
– particularly under 30 groups – the
bootstrap will converge to a slightly different value than the asymptotic method, due to
the limited number of distinct bootstrap replications possible (see Webb 2014 for a discussion
of this phenomonon). The bootstrap will not necessarily converge to an asymptotic estimate
that has been corrected for small samples.
The xy approach to bootstrapping is generally only of interest to the
practitioner when the asymptotic solution is unavailable (this can happen when using
estimators that have no estfun
function, for example). The residual bootstrap,
by contrast, is rarely of practical interest, because while it provides consistent
inference for clustered standard errors, it is not robust to heteroscedasticity.
More generally, bootstrapping is useful when the bootstrap makes different assumptions than the asymptotic
estimator, in particular when the number of clusters is small and large n
or
g
assumptions are unreasonable. Bootstrapping is also often effective for nonlinear models,
particularly in smaller samples, where asymptotic approaches often perform relatively poorly.
See Cameron and Miller (2015) for further discussion of bootstrap techniques in practical applications,
and Zeileis et al. (2020) show simulations comparing vcovBS
to vcovCL
in several
settings.
The jackknife approach is of particular interest in practice because it can be shown to be
exactly equivalent to the HC3 (without cluster adjustment, also known as CV3)
covariance matrix estimator in linear models (see MacKinnon,
Nielsen, Webb 2022). If the number of observations per cluster is large it may become
impossible to compute this estimator via vcovCL
while using the jackknife
approach will still be feasible. In nonlinear models (including non-Gaussian GLMs) the
jackknife and the HC3 estimator do not coincide but the jackknife might still be a useful
alternative when the HC3 cannot be computed. A convenience interface vcovJK
is provided whose default method simply calls vcovBS(..., type = "jackknife")
.
The fractional-random-weight bootstrap (see Xu et al. 2020), first introduced by Rubin (1981) as Bayesian bootstrap, is an alternative to the xy bootstrap when it is computationally challenging or even impractical to reestimate the model on subsets, e.g., when "successes" in binary responses are rare or when the number of parameters is close to the sample size. In these situations excluding some observations completely is the source of the problems, i.e., giving some observations zero weight while others receive integer weights of one ore more. The fractional bootstrap mitigates this by giving every observation a positive fractional weight, drawn from a Dirichlet distribution. These may become close to zero but never exclude an observation completly, thus stabilizing the computation of the reweighted models.
The glm
method works essentially like the default method but calls
glm.fit
instead of update
.
The lm
method provides additional bootstrapping type
s
and computes the bootstrapped coefficient estimates somewhat more efficiently using
lm.fit
(for case-based resampling) or qr.coef
rather than update
. The default type
is case-based resampling
(type = "xy"
) as in the default method. Alternative type
specifications are:
"residual"
. The residual cluster bootstrap resamples the residuals (as above,
by cluster) which are subsequently added to the fitted values to obtain the bootstrapped
response variable: y^{*} = \hat{y} + e^{*}
.
Coefficients can then be estimated using qr.coef()
, reusing the
QR decomposition from the original fit. As Cameron et al. (2008) point out,
the residual cluster bootstrap is not well-defined when the clusters are unbalanced as
residuals from one cluster cannot be easily assigned to another cluster with different size.
Hence a warning is issued in that case.
"wild"
(or equivalently "wild-rademacher"
or "rademacher"
).
The wild cluster bootstrap does not actually resample the residuals but instead reforms the
dependent variable by multiplying the residual by a randomly drawn value and adding the
result to the fitted value: y^{*} = \hat{y} + e \cdot w
(see Cameron et al. 2008). By default, the factors are drawn from the Rademacher distribution:
function(n) sample(c(-1, 1), n, replace = TRUE)
.
"mammen"
(or "wild-mammen"
). This draws the wild bootstrap factors as
suggested by Mammen (1993):
sample(c(-1, 1) * (sqrt(5) + c(-1, 1))/2, n, replace = TRUE, prob = (sqrt(5) + c(1, -1))/(2 * sqrt(5)))
.
"webb"
(or "wild-webb"
). This implements the six-point distribution
suggested by Webb (2014), which may improve inference when the number of clusters is small:
sample(c(-sqrt((3:1)/2), sqrt((1:3)/2)), n, replace = TRUE)
.
"norm"
(or "wild-norm"
). The standard normal/Gaussian distribution
is used for drawing the wild bootstrap factors: function(n) rnorm(n)
.
User-defined function. This needs of the form as above, i.e., a function(n)
returning a vector of random wild bootstrap factors of corresponding length.
A matrix containing the covariance matrix estimate.
Cameron AC, Gelbach JB, Miller DL (2008). “Bootstrap-Based Improvements for Inference with Clustered Errors”, The Review of Economics and Statistics, 90(3), 414–427. \Sexpr[results=rd]{tools:::Rd_expr_doi("10.3386/t0344")}
Cameron AC, Gelbach JB, Miller DL (2011). “Robust Inference with Multiway Clustering”, Journal of Business & Economic Statistics, 29(2), 238–249. \Sexpr[results=rd]{tools:::Rd_expr_doi("10.1198/jbes.2010.07136")}
Cameron AC, Miller DL (2015). “A Practitioner's Guide to Cluster-Robust Inference”, Journal of Human Resources, 50(2), 317–372. \Sexpr[results=rd]{tools:::Rd_expr_doi("10.3368/jhr.50.2.317")}
Efron B (1979). “Bootstrap Methods: Another Look at the Jackknife”, The Annals of Statistics, 7(1), 1–26. \Sexpr[results=rd]{tools:::Rd_expr_doi("10.1214/aos/1176344552")}
MacKinnon JG, Nielsen MØ, Webb MD (2022). “Cluster-Robust Inference: A Guide to Empirical Practice”, Journal of Econometrics, Forthcoming. \Sexpr[results=rd]{tools:::Rd_expr_doi("10.1016/j.jeconom.2022.04.001")}
Mammen E (1992). “When Does Bootstrap Work?: Asymptotic Results and Simulations”, Lecture Notes in Statistics, 77. Springer Science & Business Media.
Mammen E (1993). “Bootstrap and Wild Bootstrap for High Dimensional Linear Models”, The Annals of Statistics, 21(1), 255–285. \Sexpr[results=rd]{tools:::Rd_expr_doi("10.1214/aos/1176349025")}
Rubin DB (1981). “The Bayesian Bootstrap”, The Annals of Statistics, 9(1), 130–134. \Sexpr[results=rd]{tools:::Rd_expr_doi("10.1214/aos/1176345338")}
Webb MD (2014). “Reworking Wild Bootstrap Based Inference for Clustered Errors”, Working Paper 1315, Queen's Economics Department. https://www.econ.queensu.ca/sites/econ.queensu.ca/files/qed_wp_1315.pdf.
Xu L, Gotwalt C, Hong Y, King CB, Meeker WQ (2020). “Applications of the Fractional-Random-Weight Bootstrap”, The American Statistician, 74(4), 345–358. \Sexpr[results=rd]{tools:::Rd_expr_doi("10.1080/00031305.2020.1731599")}
Zeileis A, Köll S, Graham N (2020). “Various Versatile Variances: An Object-Oriented Implementation of Clustered Covariances in R.” Journal of Statistical Software, 95(1), 1–36. \Sexpr[results=rd]{tools:::Rd_expr_doi("10.18637/jss.v095.i01")}
vcovCL
, vcovJK
## Petersen's data
data("PetersenCL", package = "sandwich")
m <- lm(y ~ x, data = PetersenCL)
## comparison of different standard errors
suppressWarnings(RNGversion("3.5.0"))
set.seed(1)
cbind(
"classical" = sqrt(diag(vcov(m))),
"HC-cluster" = sqrt(diag(vcovCL(m, cluster = ~ firm))),
"BS-cluster" = sqrt(diag(vcovBS(m, cluster = ~ firm))),
"FW-cluster" = sqrt(diag(vcovBS(m, cluster = ~ firm, type = "fractional")))
)
## two-way wild cluster bootstrap with Mammen distribution
vcovBS(m, cluster = ~ firm + year, type = "wild-mammen")
## jackknife estimator coincides with HC3 (aka CV3)
all.equal(
vcovBS(m, cluster = ~ firm, type = "jackknife"),
vcovCL(m, cluster = ~ firm, type = "HC3", cadjust = FALSE),
tolerance = 1e-7
)
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