% File src/library/graphics/man/assocplot.Rd
% Part of the R package, http://www.R-project.org
% Copyright 1995-2007 R Core Team
% Distributed under GPL 2 or later

\newcommand{\CRANpkg}{\href{http://CRAN.R-project.org/package=#1}{\pkg{#1}}}

\name{assocplot}
\alias{assocplot}
\encoding{UTF-8}
\title{Association Plots}
\description{
  Produce a Cohen-Friendly association plot indicating deviations from
  independence of rows and columns in a 2-dimensional contingency
  table.
}
\usage{
assocplot(x, col = c("black", "red"), space = 0.3,
          main = NULL, xlab = NULL, ylab = NULL)
}
\arguments{
  \item{x}{a two-dimensional contingency table in matrix form.}
  \item{col}{a character vector of length two giving the colors used for
    drawing positive and negative Pearson residuals, respectively.}
  \item{space}{the amount of space (as a fraction of the average
    rectangle width and height) left between each rectangle.}
  \item{main}{overall title for the plot.}
  \item{xlab}{a label for the x axis.  Defaults to the name (if any) of
    the row dimension in \code{x}.}
  \item{ylab}{a label for the y axis.  Defaults to the name (if any) of
    the column dimension in \code{x}.}
}
\details{
  For a two-way contingency table, the signed contribution to Pearson's
  \eqn{\chi^2}{chi^2} for cell \eqn{i, j} is \eqn{d_{ij} = (f_{ij} -
    e_{ij}) / \sqrt{e_{ij}}}{d_{ij} = (f_{ij} - e_{ij}) / sqrt(e_{ij})},
  where \eqn{f_{ij}} and \eqn{e_{ij}} are the observed and expected
  counts corresponding to the cell.  In the Cohen-Friendly association
  plot, each cell is represented by a rectangle that has (signed) height
  proportional to \eqn{d_{ij}} and width proportional to
  \eqn{\sqrt{e_{ij}}}{sqrt(e_{ij})}, so that the area of the box is
  proportional to the difference in observed and expected frequencies.
  The rectangles in each row are positioned relative to a baseline
  indicating independence (\eqn{d_{ij} = 0}).  If the observed frequency
  of a cell is greater than the expected one, the box rises above the
  baseline and is shaded in the color specified by the first element of
  \code{col}, which defaults to black; otherwise, the box falls below
  the baseline and is shaded in the color specified by the second
  element of \code{col}, which defaults to red.

  A more flexible and extensible implementation of association plots
  written in the grid graphics system is provided in the function
  \code{\link[vcd]{assoc}} in the contributed package \CRANpkg{vcd}
  (Meyer, Zeileis and Hornik, 2005).
}
\seealso{
  \code{\link{mosaicplot}}, \code{\link{chisq.test}}.
}
\references{
  Cohen, A. (1980),
  On the graphical display of the significant components in a two-way
  contingency table.
  \emph{Communications in Statistics---Theory and Methods}, \bold{A9},
  1025--1041.

  Friendly, M. (1992),
  Graphical methods for categorical data.
  \emph{SAS User Group International Conference Proceedings}, \bold{17},
  190--200.
  \url{http://www.math.yorku.ca/SCS/sugi/sugi17-paper.html}

  Meyer, D., Zeileis, A., and Hornik, K. (2005)
  The strucplot framework: Visualizing multi-way contingency tables with vcd.
  \emph{Report 22}, Department of Statistics and Mathematics,
  \enc{Wirtschaftsuniversität}{Wirtschaftsuniversitaet} Wien, Research Report Series.
  \url{http://epub.wu.ac.at/dyn/openURL?id=oai:epub.wu-wien.ac.at:epub-wu-01_8a1}
}
\examples{
## Aggregate over sex:
x <- margin.table(HairEyeColor, c(1, 2))
x
assocplot(x, main = "Relation between hair and eye color")
}
\keyword{hplot}