# Double centering in R [closed]

Do you know how to transform a matrix to a so-called double centering matrix in R? Such that sum(col) and sum(row) of the transformed matrix are all zero vector. Thanks.

## closed as unclear what you're asking by d.b, Keith.Abramo, McCygnus, Mark Rotteveel, Greg HewgillApr 26 '17 at 20:50

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• Do you have any example of this being done somewhere else? Any link for a tutorial or something? – Rodrigo Apr 26 '17 at 15:55
• I want to transform the matrix A into a double centering matrix | 1 4 7 | A = | 2 5 8 | | 3 6 9 | – Azizah Apr 29 '17 at 14:19
• I was expecting a more clear explanation. – Rodrigo Apr 29 '17 at 21:05
• I want to make a two way clustering in R. I have a matrix consisting of compounds (in row) and proteins (in column). Before I make a two dendograms in two way clustering, I need to make a double centering from that matrix. So, that whay I asked about double centering matrix. – Azizah May 3 '17 at 4:01
• I think that if you include a link to an on-line example, or provide a reproducible example, your question will be much better received. – Rodrigo May 3 '17 at 12:13

Double-centering a matrix M is done with the following algorithm:

1) generate two matrices of the same size than the original matrix that contain the row-wise and column-wise means. Let's call these two matrices R and C:

``````    | mean(M[1,1:3])  mean(M[1,1:3])  mean(M[1,1:3]) |
R = | mean(M[2,1:3])  mean(M[2,1:3])  mean(M[2,1:3]) |
| mean(M[3,1:3])  mean(M[3,1:3])  mean(M[3,1:3]) |
``````

and

``````    | mean(M[1:3,1])  mean(M[1:3,2])  mean(M[1:3,3]) |
C = | mean(M[1:3,1])  mean(M[1:3,2])  mean(M[1:3,3]) |
| mean(M[1:3,1])  mean(M[1:3,2])  mean(M[1:3,3]) |
``````

2) Subtract them to M and add the grand mean: `M - C - R + grand_mean(M)`.

Here is a code performing this:

``````# example data
M = matrix(runif(9),nrow=3,ncol=3)

# compute the row-wise and column-wise mean matrices
R = M*0 + rowMeans(M)  # or `do.call(cbind, rep(list(rowMeans(tst)),3))`
C = t(M*0 + colMeans(M))  # or `do.call(rbind, rep(list(colMeans(tst)),3))`

# substract them and add the grand mean
M_double_centered = M - R - C + mean(M[])
``````

You can check that this gives the right answer by computing `rowMeans(M_double_centered)` and `colMeans(M_double_centered)`.

• Thanks Jealie for your explanation. – Azizah Apr 29 '17 at 14:21