EDIT I have completely reworked the answer now that I understand which assumptions were wrong.
Before explaining what doesn't work in the OP, let me make sure we'll have the same terminology. In principal component analysis, the goal is to obtain a coordinate transformation that separates the observations well, and that may make it easy to describe the data , i.e. the different multi-dimensional observations, in a lower-dimensional space. Observations are multidimensional when they're made up from multiple measurements. If there are fewer linearly independent observations than there are measurements, we expect at least one of the eigenvalues to be zero, because e.g. two linearly independent observation vectors in a 3D space can be described by a 2D plane.
If we have an array
x = [ 1 3 4
2 4 -1
4 6 9
3 5 -2];
that consists of four observations with three measurements each,
princomp(x) will find the lower-dimensional space spanned by the four observations. Since there are two co-dependent measurements, one of the eigenvalues will be near zero, since the space of measurements is only 2D and not 3D, which is probably the result you wanted to find. Indeed, if you inspect the eigenvectors (
coeff), you find that the first two components are extremely obviously collinear
coeff = princomp(x)
0.10124 0.69982 0.70711
0.10124 0.69982 -0.70711
0.9897 -0.14317 1.1102e-16
Since the first two components are, in fact, pointing in opposite directions, the values of the first two components of the transformed observations are, on their own, meaningless:
[1 1 25] is equivalent to
[1000 1000 25].
Now, if we want to find out whether any measurements are linearly dependent, and if we really want to use principal components for this, because in real life, measurements my not be perfectly collinear and we are interested in finding good vectors of descriptors for a machine-learning application, it makes a lot more sense to consider the three measurements as "observations", and run
princomp(x'). Since there are thus three "observations" only, but four "measurements", the fourth eigenvector will be zero. However, since there are two linearly dependent observations, we're left with only two non-zero eigenvalues:
To find out which of the measurements are so highly correlated (not actually necessary if you use the eigenvector-transformed measurements as input for e.g. machine learning), the best way would be to look at the correlation between the measurements:
1 1 0.35675
1 1 0.35675
0.35675 0.35675 1
Unsurprisingly, each measurement is perfectly correlated with itself, and
v1 is perfectly correlated with
but the eigenvalues tell us which vectors in the new space are most important (cover the most of variation) and also coefficients tell us how much of each variable is in each component. so I assume we can use this data to find out which of the original variables hold the most of variance and thus are most important (and get rid of those that represent small amount)
This works if your observations show very little variance in one measurement variable (e.g. where
x = [1 2 3;1 4 22;1 25 -25;1 11 100];, and thus the first variable contributes nothing to the variance). However, with collinear measurements, both vectors hold equivalent information, and contribute equally to the variance. Thus, the eigenvectors (coefficients) are likely to be similar to one another.
In order for @agnieszka's comments to keep making sense, I have left the original points 1-4 of my answer below. Note that #3 was in response to the division of the eigenvectors by the eigenvalues, which to me didn't make a lot of sense.
- the vectors should be in rows, not columns (each vector is an
coeff returns the basis vectors of the principal
components, and its order has little to do with the original input
- To see the importance of the principal components, you use
- If you have two collinear vectors, you can't say that the first is important and the second isn't. How do you know that it shouldn't be the other way around? If you want to test for colinearity, you should check the rank of the array instead, or call
unique on normalized (i.e.
norm equal to 1) vectors.