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I would like to generate correlated variables specified by a correlation matrix.

First I generate the correlation matrix:

require(psych)
require(Matrix)

cor.table <- matrix( sample( c(0.9,-0.9) , 2500 , prob = c( 0.8 , 0.2 ) , repl = TRUE ) , 50 , 50 )
k=1
while (k<=length(cor.table[1,])){
    cor.table[1,k]<-0.55
    k=k+1
    }
k=1
while (k<=length(cor.table[,1])){
    cor.table[k,1]<-0.55
    k=k+1
    }   
ind<-lower.tri(cor.table)
cor.table[ind]<-t(cor.table)[ind]
diag(cor.table) <- 1

This correlation matrix is not consistent, therefore, eigenvalue decomposition is impossible. TO make it consistent I use nearPD:

c<-nearPD(cor.table)

Once this is done I generate the correlated variables:

fit<-principal(c, nfactors=50,rotate="none")
fit$loadings
loadings<-matrix(fit$loadings[1:50, 1:50],nrow=50,ncol=50,byrow=F)
loadings

cases <- t(replicate(50, rnorm(10)) ) 
multivar <- loadings %*% cases
T_multivar <- t(multivar)
var<-as.data.frame(T_multivar)
cor(var)

However the resulting correlations are far from anything that I specified initially.

Is it not possible to create such correlations or am I doing something wrong?

UPDATE from Greg Snow's comment it became clear that the problem is that my initial correlation matrix is unreasonable.

The question then is how can I make the matrix reasonable. The goal is:

  1. each of the 49 variables should correlate >.5 with the first variable.
  2. ~40 of the variables should have a high >.8 correlation with each other
  3. the remaining ~9 variables should have a low or negative correlation with each other.

Is this whole requirement impossible ?

share|improve this question

Some numerical experimentation based on your specifications above suggests that the generated matrix will never (what never? well, hardly ever ...) be positive definite, but it also doesn't look far from PD with these values (making lcor below negative will almost certainly make things worse ...)

rmat <- function(n=49,nhcor=40,hcor=0.8,lcor=0) {
    m <- matrix(lcor,n,n)  ## fill matrix with 'lcor'
    ## select high-cor variables
    hcorpos <- sample(n,size=nhcor,replace=FALSE)
    ## make all of these highly correlated
    m[hcorpos,hcorpos] <- hcor                
    ## compute min real part of eigenvalues
    min(Re(eigen(m,only.values=TRUE)$values))
}
set.seed(101)
r <- replicate(1000,rmat())
## NEVER pos definite
max(r)
## [1] -1.069413e-15
par(las=1,bty="l")
png("eighist.png")
hist(log10(abs(r)),breaks=50,col="gray",main="")
dev.off()

enter image description here

share|improve this answer
    
thanks for your help. so this suggests that my initial matrix won't work. is there a way to find something similar that can work? see the last few lines of my post where I specify what I'm looking for. exact correlation values are not necessary only the 3 conditions specified should be fulfilled. – user1984076 Sep 18 '13 at 8:35
    
try it out for yourself ... I wrote the function so that it would be easy to tweak. I would suggest modifying lcor so it's a little bit positive ... – Ben Bolker Sep 18 '13 at 13:15

Try using the mvrnorm function from the MASS package rather than trying to construct the variables yourself.

**Edit

Here is a matrix that is positive definite (so it works as a correlation matrix) and comes close to your criteria, you can tweak the values from there (all the Eigen values need to be positive, so you can see how changing a number affects things):

cor.mat <- matrix(0.2,nrow=50, ncol=50)
cor.mat[1,] <- cor.mat[,1] <- 0.55
cor.mat[2:41,2:41] <- 0.9
cor.mat[42:50, 42:50] <- 0.25
diag(cor.mat) <- 1

eigen(cor.mat)$values
share|improve this answer
    
rmvnorm(n=4, mean=c(rep(0,50)),cor.table, method="svd") this still doesn't produce anything near the original correlation matrix – user1723765 Sep 16 '13 at 21:34
    
@user1723765, with only 4 observations the sample correlations will be highly variable. What result do you get with a sample size of say 1,000? How are you computing the correlation and comparing? and did you try mvrnorm with empirical=TRUE? – Greg Snow Sep 16 '13 at 21:47
    
please see my edit. the correlations are still far away from the desired ones. I think nearPD already distorts the whole thing. is it not possible to create correlated variables from my initial matrix? – user1984076 Sep 17 '13 at 8:37
    
Your initial table is not reasonable as a correlation matrix, for example variables 2 and 3 both have a 0.9 correlation with variable 4, but are expected to have a -0.9 correlation with each other, so the nearPD function needs to change the values quite a bit to get something reasonable. Also note that nearPD computes covariances by default, if you have it compute correlations, pass that to mvrnorm and then compare the correlation of the result to the c matrix you should see similar values. – Greg Snow Sep 17 '13 at 18:54
    
ok, so the problem is that the initial correlation matrix is unreasonable. Now I understand. Please see my edit. – user1723765 Sep 17 '13 at 20:24

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