control(boot.out, L = NULL, distn = NULL, index = 1, t0 = NULL, t = NULL, bias.adj = FALSE, alpha = NULL, ...)boot. The bootstrap
replicates must have been generated using the usual nonparametric
bootstrap.
L is not supplied then empinf is called to calculate
them from boot.out.
smooth.spline giving
the distribution function of the linear approximation. This is used
only if bias.adj is FALSE. Normally this would be
found using a saddlepoint approximation. If it is not supplied in
that case then it is calculated by saddle.distn.
boot.out$statistic.
boot.out$data. This argument is used only if
bias.adj is FALSE. The input value is ignored if
t is not also supplied. The default value is is
boot.out$t0[index].
bias.adj is FALSE. The input
is ignored if t0 is not supplied also. The default value is
boot.out$t[,index].
TRUE specifies that the adjusted
bias estimate using post-simulation balance is all that is required.
If bias.adj is FALSE (default) then the linear
approximation to the statistic is calculated and used as a control
variate in estimates of the bias, variance and third cumulant as
well as quantiles.
bias.adj is
FALSE.
boot.out$statistic requires.
These are passed unchanged every time boot.out$statistic is
called. boot.out$statistic is called once if bias.adj
is TRUE, otherwise it may be called by empinf for
empirical influence calculations if L is not supplied.
bias.adj is TRUE then the returned value is the
adjusted bias estimate.If bias.adj is FALSE then the returned value is a list
with the following componentsempinf.
t of
the statistic of interest.
t as a control variate.
t as a control variate.
t as a control variate.
t as a control variate.
smooth.spline describing the
saddlepoint approximation to the bootstrap distribution of the
linear approximation to t. If distn was supplied on
input then this is the same as the input otherwise it is calculated
by a call to saddle.distn.
bias.adj is FALSE then the linear approximation to
the statistic is found and evaluated at each bootstrap replicate.
Then using the equation T* = Tl*+(T*-Tl*), moment estimates can
be found. For quantile estimation the distribution of the linear
approximation to t is approximated very accurately by
saddlepoint methods, this is then combined with the bootstrap
replicates to approximate the bootstrap distribution of t and
hence to estimate the bootstrap quantiles of t.
Efron, B. (1990) More efficient bootstrap computations. Journal of the American Statistical Association, 55, 79--89.
boot, empinf, k3.linear, linear.approx, saddle.distn, smooth.spline, var.linear
# Use of control variates for the variance of the air-conditioning data
mean.fun <- function(d, i)
{ m <- mean(d$hours[i])
n <- nrow(d)
v <- (n-1)*var(d$hours[i])/n^2
c(m, v)
}
air.boot <- boot(aircondit, mean.fun, R = 999)
control(air.boot, index = 2, bias.adj = TRUE)
air.cont <- control(air.boot, index = 2)
# Now let us try the variance on the log scale.
air.cont1 <- control(air.boot, t0 = log(air.boot$t0[2]),
t = log(air.boot$t[, 2]))
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