# Random projection algorithm pseudo code

I am trying to apply Random Projections method on a very sparse dataset. I found papers and tutorials about Johnson Lindenstrauss method, but every one of them is full of equations which makes no meaningful explanation to me. For example, this document on Johnson-Lindenstrauss

Unfortunately, from this document, I can get no idea about the implementation steps of the algorithm. It's a long shot but is there anyone who can tell me the plain English version or very simple pseudo code of the algorithm? Or where can I start to dig this equations? Any suggestions?

For example, what I understand from the algorithm by reading this paper concerning Johnson-Lindenstrauss is that:

1. Assume we have a `AxB` matrix where `A` is number of samples and `B` is the number of dimensions, e.g. `100x5000`. And I want to reduce the dimension of it to `500`, which will produce a `100x500` matrix.

As far as I understand: first, I need to construct a `100x500` matrix and fill the entries randomly with `+1` and `-1` (with a 50% probability).

Edit:
Okay, I think I started to get it. So we have a matrix `A` which is `mxn`. We want to reduce it to `E` which is `mxk`.

What we need to do is, to construct a matrix `R` which has `nxk` dimension, and fill it with `0`, `-1` or `+1`, with respect to `2/3`, `1/6` and `1/6` probability.

After constructing this `R`, we'll simply do a matrix multiplication `AxR` to find our reduced matrix `E`. But we don't need to do a full matrix multiplication, because if an element of `Ri` is `0`, we don't need to do calculation. Simply skip it. But if we face with `1`, we just add the column, or if it's `-1`, just subtract it from the calculation. So we'll simply use summation rather than multiplication to find `E`. And that is what makes this method very fast.

It turned out a very neat algorithm, although I feel too stupid to get the idea.

-
. . . uh, nope. You've reminded me why I didn't continue on with grad school, and why the math majors make the big bucks. Good luck. –  Philip Sep 19 '11 at 17:00

The mapping from high-dimensional data A to low-dimensional data E is given in the statement of theorem 1.1 in the latter paper - it is simply a scalar multiplication followed by a matrix multiplication. The data vectors are the rows of the matrices A and E. As the author points out in section 7.1, you don't need to use a full matrix multiplication algorithm.

-

You have the idea right. However as I understand random project, the rows of your matrix R should have unit length. I believe that's approximately what the normalizing by 1/sqrt(k) is for, to normalize away the fact that they're not unit vectors.

It isn't a projection, but, it's nearly a projection; R's rows aren't orthonormal, but within a much higher-dimensional space, they quite nearly are. In fact the dot product of any two of those vectors you choose will be pretty close to 0. This is why it is a generally good approximation of actually finding a proper basis for projection.

-
thanks for pointing out the normalizing factor, i totally forgot about it. –  Ahmed Sep 19 '11 at 21:45
Sean: I could finally implemented it but I am facing a problem. Maybe you have an idea about it: stackoverflow.com/questions/7481339/… –  Ahmed Sep 20 '11 at 7:08