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I am using princomp in R to perform PCA. My data matrix is huge (10K x 10K with each value up to 4 decimal points). It takes ~3.5 hours and ~6.5 GB of Physical memory on a Xeon 2.27 GHz processor.

Since I only want the first two components, is there a faster way to do this?

Update :

In addition to speed, Is there a memory efficient way to do this ?

It takes ~2 hours and ~6.3 GB of physical memory for calculating first two components using svd(,2,).

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The NIPALS algorithm can be used. Search the R packages for that. – G. Grothendieck Nov 29 '11 at 13:45
up vote 15 down vote accepted

You sometimes gets access to so-called 'economical' decompositions which allow you to cap the number of eigenvalues / eigenvectors. It looks like eigen() and prcomp() do not offer this, but svd() allows you to specify the maximum number to compute.

On small matrices, the gains seem modest:

R> set.seed(42); N <- 10; M <- matrix(rnorm(N*N), N, N)
R> benchmark(eigen(M), svd(M,2,0), prcomp(M), princomp(M), order="relative")
          test replications elapsed relative user.self sys.self user.child
2 svd(M, 2, 0)          100   0.021  1.00000      0.02        0          0
3    prcomp(M)          100   0.043  2.04762      0.04        0          0
1     eigen(M)          100   0.050  2.38095      0.05        0          0
4  princomp(M)          100   0.065  3.09524      0.06        0          0

but the factor of three relative to princomp() may be worth your while reconstructing princomp() from svd() as svd() allows you to stop after two values.

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With N=200 my machine does princomp the fastest (not by much, basically equal to svd(,2,), so the results may vary with processor and with scaling. – 42- Nov 28 '11 at 21:13
Where is the "benchmark" function? – Kevin Wright Nov 28 '12 at 15:12
In the rbenchmark package. There is also a the microbenchmark package. – Dirk Eddelbuettel Nov 28 '12 at 15:14
fast.svd in the corpcor package is wicked fast. – Rnoob Jan 14 '15 at 15:07

I tried the pcaMethods package's implementation of the nipals algorithm. By default it calculates the first 2 principal components. Turns out to be slower than the other suggested methods.

set.seed(42); N <- 10; M <- matrix(rnorm(N*N), N, N)
m1 <- pca(M, method="nipals", nPcs=2)
benchmark(pca(M, method="nipals"),
          eigen(M), svd(M,2,0), prcomp(M), princomp(M), order="relative")

                       test replications elapsed relative user.self sys.self
3              svd(M, 2, 0)          100    0.02      1.0      0.02        0
2                  eigen(M)          100    0.03      1.5      0.03        0
4                 prcomp(M)          100    0.03      1.5      0.03        0
5               princomp(M)          100    0.05      2.5      0.05        0
1 pca(M, method = "nipals")          100    0.23     11.5      0.24        0
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+1 -- thanks for doing empirical comparisons. – Dirk Eddelbuettel Nov 28 '12 at 16:45

The 'svd' package provides the routines for truncated SVD / eigendecomposition via Lanczos algorithm. You can use it to calculate just first two principal components.

Here I have:

> library(svd)
> set.seed(42); N <- 1000; M <- matrix(rnorm(N*N), N, N)
> system.time(svd(M, 2, 0))
   user  system elapsed 
  7.355   0.069   7.501 
> system.time(princomp(M))
   user  system elapsed 
  5.985   0.055   6.085 
> system.time(prcomp(M))
   user  system elapsed 
  9.267   0.060   9.368 
> system.time(trlan.svd(M, neig = 2))
   user  system elapsed 
  0.606   0.004   0.614 
> system.time(trlan.svd(M, neig = 20))
   user  system elapsed 
  1.894   0.009   1.910
> system.time(propack.svd(M, neig = 20))
   user  system elapsed 
  1.072   0.011   1.087 
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As my data is square matrix, is there a hack to input only upper/lower triangular matrix to any of the functions (svd,princomp,prcomp) ? That would save memory consuming step of duplicating lower triangle as upper triangle ! – 384X21 Nov 29 '11 at 19:28
I don't think that this is possible for "usual" functions. For stuff from "svd" package you can use the so-called "external matrix interface" where you just define how to multiply matrix by a vector, and that's all. Right now this API is C-level only, but rumors are that everything will be propagated to ordinary R level soon, so one can write their own routines in R (and surely exploit the symmetry or sparseness of the matrix). – Anton Korobeynikov Nov 30 '11 at 0:24

you can use neural network approach to find the principal component. Basic description is given here.. http://www.heikohoffmann.de/htmlthesis/node26.html

First principal Component, y= w1*x1+w2*x2 and Second orthogonal Component can be calculated as q = w2*x1-w1*x2.

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The power method might be what you want. If you code it in R, which is not hard at all, I think you may find that it is no faster than the SVD approach suggested in other answer, which makes use of LAPACK compiled routines.

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I would advise against this as the power method has extremely slow convergence. – Mike Bailey Nov 29 '11 at 19:02
This is true in many cases. Speed depends on the relative magnitude of the largest eigenvalue to the next; so it will be problem dependent. Still, I think the method might be competitive if only two eigenvectors are sought and the matrix is very large. No way of knowing without trying. – F. Tusell Dec 1 '11 at 13:42

You could write the function yourself and stop at 2 components. It is not too difficult. I have it laying around somewhere, if I find it I will post it.

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May be you can give logic of function, I can try to code myself ! – 384X21 Nov 28 '11 at 17:21
As a primer to PCA, I did a blog post where I tried to explain this in terms of OLS: cerebralmastication.com/2010/09/… Down at the bottom there's a link to an article by Lindsay I Smith which I found really helpful. Link to Smith PDF: cs.otago.ac.nz/cosc453/student_tutorials/… – JD Long Nov 28 '11 at 17:34
@JD Long: That's an interesting article. Let me try ! – 384X21 Nov 28 '11 at 18:12
it might be worth looking at the pcaMethods package from the Bioc project. I have no idea how fast it is, but it's another reference point. bioconductor.org/packages/release/bioc/html/pcaMethods.html – JD Long Nov 28 '11 at 18:18

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