# Defining a function that calculates the covariance-matrix of a correlation-matrix

I have some problems with the transformation of a matrix and the names of the rows and columns.

My problem is as follows:

As input-matrix I have a (symmetric) correlation matrix like this one:

The correlation-vector is given by the values of the lower triangular matrix:

Now, I want to compute the variance-covariance-matrix of the these correlations, which are approximately normally distributed with the variance-covariance-matrix:

The variances can be approximated by

-> N is the sample size (in this example N = 66)

The covariances can be approximated by

For example the covariance between r_02 and r_13 is given by

Now, I want to define a function in R which gets the correlation matrix as input and returns the variance-covariance matrix. However, I have problems to implement the calculation of the covariances. My idea is to give names to the elements of the correlation_vector as shown above (r_01, r_02...). Then I want to create the empty variance-cocariance matrix, which has the length of the correlation_vector. The rows and the columns should have the same names as the correlation_vector, so I can call them for example by [01][03]. Then I want to implement a for-loop which sets the value of i and j as well as k and l as shown in the formula for the covariance to the columns and rows of the correlations that I need as input for the covariance-formula. These must always be six different values (ij; ik; il; jk; jl; lk). This is my idea, but I don't now how to implement this in R.

This is my code (without the calculation of the covariances):

``````require(corpcor)

correlation_matrix_input <- matrix(data=c(1.00,0.561,0.393,0.561,0.561,1.00,0.286,0.549,0.393,0.286,1.00,0.286,0.561,0.549,0.286,1.00),ncol=4,byrow=T)

N <- 66 # Sample Size

vector_of_correlations <- sm2vec(correlation_matrix_input, diag=F) # lower triangular matrix of correlation_matrix_input

variance_covariance_matrix <- matrix(nrow = length(vector_of_correlations), ncol = length(vector_of_correlations)) # creates the empty variance-covariance matrix

# function to fill the matrix by calculating the variance and the covariances

variances_covariances <- function(vector_of_correlations_input, sample_size) {

for (i in (seq(along = vector_of_correlations_input))) {
for (j in (seq(along = vector_of_correlations_input))) {

# calculate the variances for the diagonale
if (i == j) {
variance_covariance_matrix[i,j] = ((1-vector_of_correlations_input[i]**2)**2)/sample_size
}

# calculate the covariances
if (i != j) {

variance_covariance_matrix[i,j] = ???

}
}
}

return(variance_covariance_matrix);
}
``````

Does anyone have an idea, how to implement the calculation of the covariances using the formula shown above?

I would be grateful for any kind of help regarding this problem!!!

-
What is `Korrelationsmatrix_Studie_i`? I do not see where it is defined. –  Mark Miller Aug 31 '13 at 11:58
That was a mistake. It is correlation_matrix_input. –  jeffrey Aug 31 '13 at 12:42

It's easier if you keep `r` as a matrix and use this helper function to make things clearer:

``````covr <- function(r, i, j, k, l, n){
if(i==k && j==l)
return((1-r[i,j]^2)^2/n)
( 0.5 * r[i,j]*r[k,l]*(r[i,k]^2 + r[i,l]^2 + r[j,k]^2 + r[j,l]^2) +
r[i,k]*r[j,l] + r[i,l]*r[j,k] - (r[i,j]*r[i,k]*r[i,l] +
r[j,i]*r[j,k]*r[j,l] + r[k,i]*r[k,j]*r[k,l] + r[l,i]*r[l,j]*r[l,k]) )/n
}
``````

Now define this second function:

``````vcovr <- function(r, n){
p <- combn(nrow(r), 2)
q <- seq(ncol(p))
outer(q, q, Vectorize(function(x,y) covr(r, p[1,x], p[2,x], p[1,y], p[2,y], n)))
}
``````

And voila:

``````> vcovr(correlation_matrix_input, 66)
[,1]        [,2]        [,3]        [,4]        [,5]        [,6]
[1,] 0.007115262 0.001550264 0.002917481 0.003047666 0.003101602 0.001705781
[2,] 0.001550264 0.010832674 0.001550264 0.006109565 0.001127916 0.006109565
[3,] 0.002917481 0.001550264 0.007115262 0.001705781 0.003101602 0.003047666
[4,] 0.003047666 0.006109565 0.001705781 0.012774221 0.002036422 0.006625868
[5,] 0.003101602 0.001127916 0.003101602 0.002036422 0.007394554 0.002036422
[6,] 0.001705781 0.006109565 0.003047666 0.006625868 0.002036422 0.012774221
``````

EDIT:

For the transformed Z values, as in your comment, you can use this:

``````covrZ <- function(r, i, j, k, l, n){
if(i==k && j==l)
return(1/(n-3))
covr(r, i, j, k, l, n) / ((1-r[i,j]^2)*(1-r[k,l]^2))
}
``````

And simply replace it in `vcovr`:

``````vcovrZ <- function(r, n){
p <- combn(nrow(r), 2)
q <- seq(ncol(p))
outer(q, q, Vectorize(function(x,y) covrZ(r, p[1,x], p[2,x], p[1,y], p[2,y], n)))
}
``````

New result:

``````> vcovrZ(correlation_matrix_input,66)
[,1]        [,2]        [,3]        [,4]        [,5]        [,6]
[1,] 0.015873016 0.002675460 0.006212598 0.004843517 0.006478743 0.002710920
[2,] 0.002675460 0.015873016 0.002675460 0.007869213 0.001909452 0.007869213
[3,] 0.006212598 0.002675460 0.015873016 0.002710920 0.006478743 0.004843517
[4,] 0.004843517 0.007869213 0.002710920 0.015873016 0.003174685 0.007858948
[5,] 0.006478743 0.001909452 0.006478743 0.003174685 0.015873016 0.003174685
[6,] 0.002710920 0.007869213 0.004843517 0.007858948 0.003174685 0.015873016
``````
-
+1 for using `outer`. I have not thought about it. –  sgibb Aug 31 '13 at 15:05
thank you so much!!!! –  jeffrey Aug 31 '13 at 15:46
I have a further short question: in my study I need the z-transformed values of the variances and covariances. in this case the variance-formula is for all elements on the diagonal: Var(z_ij)=1/(n-3) and the denominator of the covariance-formula is not n but n[(1-r_ij^2)*(1-r_kl^2)]. I tried to type this in your code, but my result can't be right, because the diagonal-values have different results. Can you tell me how to alter your code to calculate the z-transformed var.-cov-matrix? –  jeffrey Aug 31 '13 at 17:35
@jeffrey, I have edited my answer, see if it helps. –  Ferdinand.kraft Aug 31 '13 at 18:26
@Ferdinand.kraft, the values on the diagonal should be (1/(66-3)) = 1/63 = 0.01587302. 1/66 would be 0.01515152 as in the matrix above. But I can't find why this is so. Can you help me? –  jeffrey Sep 1 '13 at 19:46
show 1 more comment

salam/hello

``````variance_covariance_matrix<- diag (variance vector, length (r),length (r))
pcomb <- combn(length(r), 2)
for (k in 1:length(r)){
i<- pcomb[1,k]
j<- pcomb[2,k]
variance_covariance_matrix[i,j]<- variance_covariance_matrix [j,i]<- genCorr[k] * sqrt (sig2g[i])  * sqrt (sig2g[j])

}
``````
-

I wrote an approach using `combn` and row/column indices to generate the different combinations of `p`.

``````variances_covariances <- function(m, n) {
r <- m[lower.tri(m)]
var <- (1-r^2)^2

## generate row/column indices
rowIdx <- rep(1:nrow(m), times=colSums(lower.tri(m)))
colIdx <- rep(1:ncol(m), times=rowSums(lower.tri(m)))

## generate combinations
cov <- combn(length(r), 2, FUN=function(i) {
## current row/column indices
cr <- rowIdx[i] ## i,k
cc <- colIdx[i] ## j,l

## define 6 cases
p.ij <- m[cr[1], cc[1]]
p.ik <- m[cr[1], cr[2]]
p.il <- m[cr[1], cc[2]]
p.jk <- m[cc[1], cr[2]]
p.jl <- m[cc[1], cc[2]]
p.kl <- m[cr[2], cc[2]]

## calculate covariance
co <- 0.5 * p.ij * p.kl * (p.ik^2 + p.il^2 + p.jk^2 + p.jl^2) +
p.ik * p.jl + p.il * p.jk -
(p.ij * p.ik * p.il + p.ij * p.jk * p.jl + p.ik * p.jk * p.kl + p.il * p.jl * p.kl)
return(co)
})

## create output matrix
com <- matrix(NA, ncol=length(r), nrow=length(r))
com[lower.tri(com)] <- cov
com[upper.tri(com)] <- t(com)[upper.tri(com)]
diag(com) <- var

return(com/n)
}
``````

Output:

``````m <- matrix(data=c(1.000, 0.561, 0.393, 0.561,
0.561, 1.000, 0.286, 0.549,
0.393, 0.286, 1.000, 0.286,
0.561, 0.549, 0.286, 1.00), ncol=4, byrow=T)

variances_covariances(m, 66)
#            [,1]        [,2]        [,3]        [,4]        [,5]        [,6]
#[1,] 0.007115262 0.001550264 0.001550264 0.003101602 0.003101602 0.001705781
#[2,] 0.001550264 0.010832674 0.010832674 0.001127916 0.001127916 0.006109565
#[3,] 0.001550264 0.010832674 0.007115262 0.001127916 0.001127916 0.006109565
#[4,] 0.003101602 0.001127916 0.001127916 0.012774221 0.007394554 0.002036422
#[5,] 0.003101602 0.001127916 0.001127916 0.007394554 0.007394554 0.002036422
#[6,] 0.001705781 0.006109565 0.006109565 0.002036422 0.002036422 0.012774221
``````

I hope, I have done everything right.

-
incredible. thank you so much!!! –  jeffrey Aug 31 '13 at 15:43