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 `prcomp`

function:

```
>library(ggplot2)
>data(mpg)
>data <- mpg[,c("displ", "year", "cyl", "cty", "hwy")]
# get the numeric columns only for this easy demo
>prcomp(data, scale=TRUE)
Standard deviations:
[1] 1.8758132 1.0069712 0.5971261 0.2658375 0.2002613
Rotation:
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.
For example,

```
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:

```
PC1
displ 0.49818034
year 0.06047629
cyl 0.49820578
cty -0.50575849
hwy -0.49412379
```

*We can see: *`displ`

has a positive relation with `cyl`

and negative relation with `cty`

and `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.

```
pairs(data)
```