P is an n*d matrix, holding
n d-dimensional samples.
P in some areas is several times more dense than others. I want to select a subset of
P in which distance between any pairs of samples be more than
d0, and I need it to be spread all over the area. All samples have same priority and there's no need to optimize anything (e.g. covered area or sum of pairwise distances).
Here is a sample code that does so, but it's really slow. I need a more efficient code since I need to call it several times.
%% generating sample data n_4 = 1000; n_2 = n_4*2;n = n_4*4; x1=[ randn(n_4, 1)*10+30; randn(n_4, 1)*3 + 60]; y1=[ randn(n_4, 1)*5 + 35; randn(n_4, 1)*20 + 80 ]; x2 = rand(n_2, 1)*(max(x1)-min(x1)) + min(x1); y2 = rand(n_2, 1)*(max(y1)-min(y1)) + min(y1); P = [x1,y1;x2, y2]; %% eliminating close ones tic d0 = 1.5; D = pdist2(P, P);D(1:n+1:end) = inf; E = zeros(n, 1); % eliminated ones for i=1:n-1 if ~E(i) CloseOnes = (D(i,:)<d0) & ((1:n)>i) & (~E'); E(CloseOnes) = 1; end end P2 = P(~E, :); toc %% plotting samples subplot(121); scatter(P(:, 1), P(:, 2)); axis equal; subplot(122); scatter(P2(:, 1), P2(:, 2)); axis equal;
Edit: How big the subset should be?
As j_random_hacker pointed out in comments, one can say that
P(1, :) is the fastest answer if we don’t define a constraint on the number of selected samples. It delicately shows incoherence of the title! But I think the current title better describes the purpose. So let’s define a constraint: “Try to select
m samples if it’s possible”. Now with the implicit assumption of
m=n we can get the biggest possible subset. As I mentioned before a faster method excels the one that finds the optimum answer.