# Finding the best matching pairwise points from 2 vectors

I have 2 lists with X,Y coordinates of points. List 1 contains more points than list 2.

The task is to find pairs of points in a way that the overall euclidean distance is minimized.

I have a working code, but i don't know if this is the best way and I would like to get hint what I can improve for result (better algorithm to find the minimum ) or speed, because the list are about 2000 elements each.

The round in the sample vectors is implemented to get also points with same distances. With the "rdist" function all distances are generated in "distances". Than the minimum in the matrix is used to link 2 point ("dist_min"). All distances of these 2 points are now replaced by NA and the loop continues by searching the next minimum until all points of list 2 have a point from list 1. At the end I have added a plot for visualization.

require(fields)

set.seed(1)
x1y1.data <- matrix(round(runif(200*2),2), ncol = 2)   # generate 1st set of points
x2y2.data <- matrix(round(runif(100*2),2), ncol = 2)   # generate 2nd set of points

distances <- rdist(x1y1.data, x2y2.data)
dist_min <- matrix(data=NA,nrow=ncol(distances),ncol=7)   # prepare resulting vector with 7 columns

for(i in 1:ncol(distances))
{
inds <- which(distances == min(distances,na.rm = TRUE), arr.ind=TRUE)

dist_min[i,1] <- inds[1,1]              # row of point(use 1st element of inds if points have same distance)
dist_min[i,2] <- inds[1,2]              # column of point (use 1st element of inds if points have same distance)
dist_min[i,3] <- distances[inds[1,1],inds[1,2]] # distance of point
dist_min[i,4] <- x1y1.data[inds[1,1],1]     # X1 ccordinate of 1st point
dist_min[i,5] <- x1y1.data[inds[1,1],2]     # Y1 coordinate of 1st point
dist_min[i,6] <- x2y2.data[inds[1,2],1]     # X2 coordinate of 2nd point
dist_min[i,7] <- x2y2.data[inds[1,2],2]     # Y2 coordinate of 2nd point

distances[inds[1,1],] <- NA # remove row (fill with NA), where minimum was found
distances[,inds[1,2]] <- NA # remove column (fill with NA), where minimum was found
}

# plot 1st set of points
# print mean distance as measure for optimization
plot(x1y1.data,col="blue",main="mean of min_distances",sub=mean(dist_min[,3],na.rm=TRUE))
points(x2y2.data,col="red")                         # plot 2nd set of points
segments(dist_min[,4],dist_min[,5],dist_min[,6],dist_min[,7])   # connect pairwise according found minimal distance

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Finding dark matter kaggle competition question, perhaps? –  Brandon Bertelsen Dec 19 '12 at 21:38
Pseudo code would be easy to write: for (i in 1st.set.points) { for (j in j 2nd.set.points){calculate: sqrt((x1st.set.ponint-x2nd.set.points)^2+(y1st.set.ponint-y2nd.set.points)^2), save every resulting value then call min() function to determine which has the lowest value } } –  java_xof Dec 19 '12 at 22:12
Hi java_xof, i think thats the way i had done.? distances <- rdist(x1y1.data, x2y2.data) delivers the matrix of all distances and which(distances == min(distances,na.rm = TRUE), arr.ind=TRUE) searches the mins in the matrix. But in case there are pairs with the same min. distance I dont know if which pair to choose. –  user1716533 Dec 19 '12 at 22:21

This is a fundamental problem in combinatorial optimization known as the assignment problem. One approach to solving the assignment problem is the Hungarian algorithm which is implemented in the R package clue:

require(clue)
sol <- solve_LSAP(t(distances))

We can verify that it outperforms the naive solution:

mean(dist_min[,3])
# [1] 0.05696033
mean(sqrt(
(x2y2.data[,1] - x1y1.data[sol, 1])^2 +
(x2y2.data[,2] - x1y1.data[sol, 2])^2))
#[1] 0.05194625

And we can construct a similar plot to the one in your question:

plot(x1y1.data,col="blue")
points(x2y2.data,col="red")
segments(x2y2.data[,1], x2y2.data[,2], x1y1.data[sol, 1], x1y1.data[sol, 2])

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thanks orizon, the plot shows a significant improvement to the "simple" algorithm, because many of the long lines could be eliminated. –  user1716533 Dec 20 '12 at 1:18
@user1716533 it was a nice question. It is interesting to see where the improvements are made. Most of the very long distance in the simple approach are assigned very late in the algorithm when all the good spots are taken. We could probably improve the simple approach by shuffling the points and running the algorithm a few times -- but there is not much reason to when there are existing implementations of efficient an optimal algorithms. –  orizon Dec 20 '12 at 1:37