I am not sure that I understood your question 100%, but I am guessing you have a dataset with missing names, and you want to quickly identify the relation(linear maybe) between variables, identify the 'Principle Components'?
Here is a very awesome
cross validated post showing you some knowledge of the PCA and SVD.
And here is a very simple example showing you how it works using
>data <- mpg[,c("displ", "year", "cyl", "cty", "hwy")]
# get the numeric columns only for this easy demo
 1.8758132 1.0069712 0.5971261 0.2658375 0.2002613
PC1 PC2 PC3 PC4 PC5
displ 0.49818034 -0.07540283 0.4897111 0.70386376 -0.10435326
year 0.06047629 -0.98055060 -0.1846807 -0.01604536 0.02233245
cyl 0.49820578 -0.04868461 0.5028416 -0.68062021 0.18255766
cty -0.50575849 -0.09911736 0.4348234 0.15195854 0.72264881
hwy -0.49412379 -0.14366800 0.5330619 -0.13410105 -0.65807527
Here is how you interpret the result:
(1) The standard deviations, which is the diagonal matrix in the middle when you apply the singular value decomposition. Explains how much variance each 'Principle Component'? / layer / transparency explains in the whole variance in the matrix.
70 % = 1.8758132^2 / (1.8758132^2 + 1.0069712^2 + 0.5971261^2 + 0.2658375^2 + 0.2002613^2)
Which indicates the first column itself already explains 70% of the variance in the whole matrix.
(2) Now let's look at the first column in the rotation matrix / V:
We can see:
displ has a positive relation with
cyl and negative relation with
hwy. And in this dominant layer,
year is not that obvious.
The makes sense, the more displacement or cylinders you have in your car, it probably has a very high MPG.
Here is the plot between the variables just for you information.