\name{structureSim} \alias{structureSim} \title{ Population or Simulated Sample Correlation Matrix from a Given Factor Structure Matrix} \description{ The \code{structureSim} function returns a population and a sample correlation matrices from a predefined congeneric factor structure. } \usage{ structureSim(fload, reppar=30, repsim=100, N, quantile=0.95, model="components", adequacy=FALSE, details=TRUE, r2limen=0.75, all=FALSE) } \arguments{ \item{fload}{ matrix: loadings of the factor structure} \item{reppar}{ numeric: number of replications for the parallel analysis} \item{repsim}{ numeric: number of replications of the matrix correlation simulation} \item{N}{ numeric: number of subjects} \item{quantile}{ numeric: quantile for the parallel analysis} \item{model}{ character: \code{"components"} or \code{"factors"} } \item{adequacy}{ logical: if \code{TRUE} prints the recovered population matrix from the factor structure} \item{details}{ logical: if \code{TRUE} outputs details of the \code{repsim} simulations } \item{r2limen}{ numeric: R2 limen value for the R2 Nelson index } \item{all}{ logical: if \code{TRUE} computes the Bentler and Yuan index (very long computing time to consider)} } \value{ \item{values}{ the output depends of the logical value of details. If \code{FALSE}, returns only statistics about the eigenvalues: mean, median, quantile, standard deviation, minimum and maximum. If \code{TRUE}, returns also details about the \code{repsim} simulations. If \code{adequacy} = \code{TRUE} returns the recovered factor structure} } \seealso{ \code{\link{principalComponents}}, \code{\link{iterativePrincipalAxis}}, \code{\link{rRecovery}} } \references{ Zwick, W. R. and Velicer, W. F. (1986). Comparison of five rules for determining the number of components to retain. \emph{Psychological Bulletin, 99}, 432-442. } \author{ Gilles Raiche \cr Centre sur les Applications des Modeles de Reponses aux Items (CAMRI) \cr Universite du Quebec a Montreal\cr \email{raiche.gilles@uqam.ca}, \url{http://www.er.uqam.ca/nobel/r17165/} } \examples{ \dontrun{ # ....................................................... # Example inspired from Zwick and Velicer (1986, table 2, p. 437) ## ................................................................... nFactors <- 3 unique <- 0.2 loadings <- 0.5 nsubjects <- 180 repsim <- 30 zwick <- generateStructure(var=36, mjc=nFactors, pmjc=12, loadings=loadings, unique=unique) ## ................................................................... # Produce statistics about a replication of a parallel analysis on # 30 sampled correlation matrices mzwick.fa <- structureSim(fload=as.matrix(zwick), reppar=30, repsim=repsim, N=nsubjects, quantile=0.5, model="factors") mzwick <- structureSim(fload=as.matrix(zwick), reppar=30, repsim=repsim, N=nsubjects, quantile=0.5, all=TRUE) # Very long execution time that could be used only with model="components" # mzwick <- structureSim(fload=as.matrix(zwick), reppar=30, # repsim=repsim, N=nsubjects, quantile=0.5, all=TRUE) par(mfrow=c(2,1)) plot(x=mzwick, nFactors=nFactors, index=c(1:14), cex.axis=0.7, col="red") plot(x=mzwick.fa, nFactors=nFactors, index=c(1:11), cex.axis=0.7, col="red") par(mfrow=c(1,1)) par(mfrow=c(2,1)) boxplot(x=mzwick, nFactors=3, cex.axis=0.8, vLine="blue", col="red") boxplot(x=mzwick.fa, nFactors=3, cex.axis=0.8, vLine="blue", col="red", xlab="Components") par(mfrow=c(1,1)) # ...................................................... } } \keyword{ multivariate }