how do I select a subset of points at a regular density? More formally,

Given

- a set
**A**of irregularly spaced points, - a metric of distance
`dist`

(e.g., Euclidean distance), - and a target density
**d**,

how can I select a smallest subset **B** that satisfies below?

- for every point
**x**in**A**, - there exists a point
**y**in**B** - which satisfies
`dist(x,y) <= d`

My current best shot is to

- start with
**A**itself - pick out the closest (or just particularly close) couple of points
- randomly exclude one of them
- repeat as long as the condition holds

and repeat the whole procedure for best luck. But are there better ways?

I'm trying to do this with 280,000 18-D points, but my question is in general strategy. So I also wish to know how to do it with 2-D points. And I don't really need a guarantee of a smallest subset. Any useful method is welcome. Thank you.

# bottom-up method

- select a random point
- select among unselected
`y`

for which`min(d(x,y) for x in selected)`

is largest - keep going!

I'll call it bottom-up and the one I originally posted top-down. This is much faster in the beginning, so for sparse sampling this should be better?

# performance measure

If guarantee of optimality is not required, I think these two indicators could be useful:

- radius of coverage:
`max {y in unselected} min(d(x,y) for x in selected)`

- radius of economy:
`min {y in selected != x} min(d(x,y) for x in selected)`

RC is minimum allowed **d**, and there is no absolute inequality between these two. But `RC <= RE`

is more desirable.

# my little methods

For a little demonstration of that "performance measure," I generated 256 2-D points distributed uniformly or by standard normal distribution. Then I tried my top-down and bottom-up methods with them. And this is what I got:

RC is red, RE is blue. X axis is number of selected points. Did you think bottom-up could be as good? I thought so watching the animation, but it seems top-down is significantly better (look at the sparse region). Nevertheless, not too horrible given that it's much faster.

Here I packed everything.

http://www.filehosting.org/file/details/352267/density_sampling.tar.gz

`for every x in A there is an y in B such that dist(x, y) < d`

) on the code you have provided. I am unable to find the python`h2`

package you are using either. – salva Jun 18 '12 at 7:09somed. And sorry,`h2`

is my collection reusable chunks of code... I wasn't aware that I used it. – h2kyeong Jul 2 '12 at 14:22