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Given longitudinal data, how can I compute a matrix where each column represents the weighted group-wise mean of a given variable?

I've developed an approach that requires a loop, and it's too slow. I think that this could probably be vectorized, but the solution is eluding me.

Here's my current approach:

library(foreach)

# N is sample size
# g is the number of groups
# p is the number of variables
get_group_mean_matrix <- function(N, g, p){
  X <- matrix(rbinom(N*p, 10, .5), N)
  f <- sort((1:(N)) %% g + 1)
  w <- runif(N)
  dmmat <- foreach(i = unique(f), .combine = rbind) %do% {
    idx <- which(f == i)
    ws <- w[idx]/sum(w[idx])
    t((t(X[idx,]) %*% ws)) %x% rep(1, length(idx))
  }
  dmmat
}

> set.seed(666)
> get_group_mean_matrix(12, 3, 5)
          [,1]     [,2]     [,3]     [,4]     [,5]
 [1,] 5.261103 4.074266 5.828070 4.452703 5.990165
 [2,] 5.261103 4.074266 5.828070 4.452703 5.990165
 [3,] 5.261103 4.074266 5.828070 4.452703 5.990165
 [4,] 5.261103 4.074266 5.828070 4.452703 5.990165
 [5,] 5.560556 4.241942 3.698828 5.572523 4.212532
 [6,] 5.560556 4.241942 3.698828 5.572523 4.212532
 [7,] 5.560556 4.241942 3.698828 5.572523 4.212532
 [8,] 5.560556 4.241942 3.698828 5.572523 4.212532
 [9,] 4.289029 4.771115 5.150607 4.424339 6.346775
[10,] 4.289029 4.771115 5.150607 4.424339 6.346775
[11,] 4.289029 4.771115 5.150607 4.424339 6.346775
[12,] 4.289029 4.771115 5.150607 4.424339 6.346775
> library(microbenchmark)
> microbenchmark(get_group_mean_matrix(1200, 300, 50))
Unit: milliseconds
                                 expr      min       lq     mean   median       uq      max neval
 get_group_mean_matrix(1200, 300, 50) 76.33337 77.39607 80.76586 78.39808 84.46984 93.40047   100

Originally, I tried doing this using lfe::demeanlist, but it gives me the wrong output!

library(lfe)
get_group_mean_matrix_lfe <- function(N, g, p){
  X <- matrix(rbinom(N*p, 10, .5), N)
  f <- sort((1:(N)) %% g + 1)
  w <- runif(N)
  X - demeanlist(X, list(factor(f)), weights = w)
}
> set.seed(666)
> get_group_mean_matrix_lfe(12, 3, 5)
          [,1]     [,2]     [,3]     [,4]     [,5]
 [1,] 5.138068 4.001781 5.415467 4.722947 5.999827
 [2,] 5.138068 4.001781 5.415467 4.722947 5.999827
 [3,] 5.138068 4.001781 5.415467 4.722947 5.999827
 [4,] 5.138068 4.001781 5.415467 4.722947 5.999827
 [5,] 5.197308 4.067657 3.202478 5.866451 4.066385
 [6,] 5.197308 4.067657 3.202478 5.866451 4.066385
 [7,] 5.197308 4.067657 3.202478 5.866451 4.066385
 [8,] 5.197308 4.067657 3.202478 5.866451 4.066385
 [9,] 4.189951 4.887720 4.953305 4.501874 6.385846
[10,] 4.189951 4.887720 4.953305 4.501874 6.385846
[11,] 4.189951 4.887720 4.953305 4.501874 6.385846
[12,] 4.189951 4.887720 4.953305 4.501874 6.385846
> library(microbenchmark)
> microbenchmark(get_group_mean_matrix_lfe(1200, 300, 50))
Unit: milliseconds
                                     expr      min       lq     mean   median       uq      max neval
 get_group_mean_matrix_lfe(1200, 300, 50) 6.107421 6.202426 6.500411 6.293648 6.582943 8.350876   100

Though it's a lot faster...

I'll accept either of two sorts of answers:

  1. Explanations of what lfe::demeanlist is doing in the weighted case. Shouldn't I get the weighted mean when I subtract the weighted deviation from the mean? And knowing this, how can I compute the matrix of weighted group-wise means?
  2. Ways not involving demeanlist to compute the matrix of weighted group-wise means.

NB: replacing %*% with a matrix multiplication function using RcppEigen speeds things up, but not enough. The problem is the loop, I think.

Here's some example input:

   f X1 X2 X3 X4 X5
1  1  6  5  7  3  6
2  1  6  4  5  5  6
3  1  5  6  3  6  6
4  1  3  5  4  3  5
5  2  5  4  7  7  7
6  2  4  1  4  2  6
7  2  5  6  6  6  5
8  2  6  7  2  5  4
9  3  5  3  4  6  9
10 3  6  6  5  5  6
11 3  5  7  4  6  8
12 3  5  3  7  8  6

where f is the grouping factor.

  • @Gregor the function provides sample input. Just set N, p and g in global and run it line by line. I'll paste some example input however, just for clarity. – generic_user Aug 29 '18 at 19:24
  • I see that now - I'd just move the input generation out of the function and give it a comment like # x: values, f: groups, w: weights. – Gregor - reinstate Monica Aug 29 '18 at 19:26
  • Yeah, that's what I did originally, but I wanted to see how the speed scales with size. – generic_user Aug 29 '18 at 19:27
  • But you (presumably) don't care about the speed of the data generation, so you shouldn't be including that in the function that you're timing. Semi-related, I'd suggest f <- rep(1:N, each = g) instead of your sort method, as sort will have a bit of time cost as the vector gets long. – Gregor - reinstate Monica Aug 29 '18 at 19:32
  • Yeah that's right I suppose. But it's fairly marginal compared to everything else going on. – generic_user Aug 29 '18 at 19:33
1

Hurr durr all I had to do was squareroot the weights going into demeanlist hurr durr

library(foreach)
get_group_mean_matrix <- function(N, g, p){
  X <- matrix(rbinom(N*p, 10, .5), N)
  f <- sort((1:(N)) %% g + 1)
  w <- runif(N)
  dmmat <- foreach(i = unique(f), .combine = rbind) %do% {
    idx <- which(f == i)
    ws <- w[idx]/sum(w[idx])
    t((t(X[idx,]) %*% ws)) %x% rep(1, length(idx))
  }
  dmmat
}

set.seed(666)
A <- get_group_mean_matrix(12, 3, 5)

library(lfe)
get_group_mean_matrix_lfe <- function(N, g, p){
  X <- matrix(rbinom(N*p, 10, .5), N)
  f <- sort((1:(N)) %% g + 1)
  w <- runif(N)
  X - demeanlist(X, list(factor(f)), weights = w^.5)
}

set.seed(666)
B <- get_group_mean_matrix_lfe(12, 3, 5)

> all.equal(A, B)
[1] TRUE

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