% File src/library/stats/man/fligner.test.Rd % Part of the R package, https://www.R-project.org % Copyright 1995-2018 R Core Team % Distributed under GPL 2 or later \name{fligner.test} \alias{fligner.test} \alias{fligner.test.default} \alias{fligner.test.formula} \title{\I{Fligner}-\I{Killeen} Test of Homogeneity of Variances} \description{ Performs a \I{Fligner}-\I{Killeen} (median) test of the null that the variances in each of the groups (samples) are the same. } \usage{ fligner.test(x, \dots) \method{fligner.test}{default}(x, g, \dots) \method{fligner.test}{formula}(formula, data, subset, na.action, \dots) } \arguments{ \item{x}{a numeric vector of data values, or a list of numeric data vectors.} \item{g}{a vector or factor object giving the group for the corresponding elements of \code{x}. Ignored if \code{x} is a list.} \item{formula}{a formula of the form \code{lhs ~ rhs} where \code{lhs} gives the data values and \code{rhs} the corresponding groups.} \item{data}{an optional matrix or data frame (or similar: see \code{\link{model.frame}}) containing the variables in the formula \code{formula}. By default the variables are taken from \code{environment(formula)}.} \item{subset}{an optional vector specifying a subset of observations to be used.} \item{na.action}{a function which indicates what should happen when the data contain \code{NA}s. Defaults to \code{getOption("na.action")}.} \item{\dots}{further arguments to be passed to or from methods.} } \details{ If \code{x} is a list, its elements are taken as the samples to be compared for homogeneity of variances, and hence have to be numeric data vectors. In this case, \code{g} is ignored, and one can simply use \code{fligner.test(x)} to perform the test. If the samples are not yet contained in a list, use \code{fligner.test(list(x, ...))}. Otherwise, \code{x} must be a numeric data vector, and \code{g} must be a vector or factor object of the same length as \code{x} giving the group for the corresponding elements of \code{x}. The \I{Fligner}-\I{Killeen} (median) test has been determined in a simulation study as one of the many tests for homogeneity of variances which is most robust against departures from normality, see \bibcite{Conover, Johnson & Johnson (1981)}. It is a \eqn{k}-sample simple linear rank which uses the ranks of the absolute values of the centered samples and weights \eqn{a(i) = \mathrm{qnorm}((1 + i/(n+1))/2)}{a(i) = qnorm((1 + i/(n+1))/2)}. The version implemented here uses median centering in each of the samples (F-K:med \eqn{X^2} in the reference). } \value{ A list of class \code{"htest"} containing the following components: \item{statistic}{the \I{Fligner}-\I{Killeen}:med \eqn{X^2} test statistic.} \item{parameter}{the degrees of freedom of the approximate chi-squared distribution of the test statistic.} \item{p.value}{the p-value of the test.} \item{method}{the character string \code{"Fligner-Killeen test of homogeneity of variances"}.} \item{data.name}{a character string giving the names of the data.} } \references{ William J. Conover, Mark E. Johnson and Myrle M. Johnson (1981). A comparative study of tests for homogeneity of variances, with applications to the outer continental shelf bidding data. \emph{Technometrics}, \bold{23}, 351--361. \doi{10.2307/1268225}. } \seealso{ \code{\link{ansari.test}} and \code{\link{mood.test}} for rank-based two-sample test for a difference in scale parameters; \code{\link{var.test}} and \code{\link{bartlett.test}} for parametric tests for the homogeneity of variances. } % FIXME: could use something more interesting here \examples{ require(graphics) plot(count ~ spray, data = InsectSprays) fligner.test(InsectSprays$count, InsectSprays$spray) fligner.test(count ~ spray, data = InsectSprays) ## Compare this to bartlett.test() } \keyword{htest}