I have a dataset of 2D points (~500k of them) on which I'd like to perform some kind of quadrat count analysis. The basics of quadrat count is to split your 2D space into a regular grid (each cell has size
SxS) and count the number of points in each cell.
For some reason, I'd like to do a slight variation of that : instead of using a regular grid, I want to build the grid such that each cell contains at most
What I did is the following: I start with the whole space, and divide it in 4 cells (by "cutting" each dimension in half). Then, I count the number of points in each cell. For those that contain more than
K points, I divide them again, etc., until I'm done.
I tried both recursive and iterative implementations of this simple algorithm, but none performed well when applied to the whole dataset. The main bottleneck is the counting part, obviously, so I was wondering what kind of datastructure would allow me to do this efficiently ?
(For now, I'm just using "conditional indexing" in Python :
points = points[points[,1] > x1 and points[,1] <= x2 and points[,2] > y1 and points[,2] <= y2,])
Also, do you have maybe another idea on how I could build my grid ?
EDIT: In other words, what kind of data structure could I use to quickly count (and retrieve) the points that fall within a given rectangle
((x1, y1), (x2, y2))?