# Associating nearby points with a path

Given a set of ordered points, and a path made up of ordered lat,lon points that goes near those points (in lat/lon coordinates), I want to associate the points with the path, ideally with good algorithmic complexity (n*log(n)) or better, but maybe that might not be realistic.

The below diagram illustrates my question better. The blue line is the ordered path that is provided, and the red points are in the same order as the blue line. The green path is my desired result, which merges the red points and the blue line into a new ordered path.

Some threshold would have to be set for the distance of the red points from the blue path, let's assume that the red points are at most 50 meters from the blue path.

So, this is definitely the most mathmatical and unusual question I have asked on Stack Overflow. Any ideas would be great on solving this. I am planning to use it to merge GTFS shape data with trip data which describes stop times, and build it into the open source project, Depart App.

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Do I understand this correctly; you want the green path, which is the path connecting the ordered set containing the red points and the nodes of the blue path? –  carlpett Jul 7 '11 at 5:23
That is correct, and the green line has to have all the red points and blue points in order. –  Russell Jul 8 '11 at 4:58

It seems to me, you have two sets of points, the lat/lon points, and the red points. One of the lat/lon points is your starting point. Now considering all the other points as a set, use an (approximate?) nearest neighbor algorithm to find the next point. Now repeat. The only trouble is, that nearest neighbor algorithms tend to be O(n), which makes what you want to do O(n^2).

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This seems like a good, simple idea. One important thing to note is that the resulting ordered set of points has to have all the blue points in order and all the red points in order (inter-mingled). So if the bus route went down a street, then came back up it on the same trip (unusual, but very possible), the nearest neighbour algorithm would fail, as the resultant points would be out of order. However, perhaps by just comparing the next two points from each ordered set, then a good decision could be made. –  Russell Jul 7 '11 at 5:36
A modification of this idea works great. Take the shape and the stop points, assume one is the first point in the line. Then look at the distance between the next shape point and next stop point, and pick the closer one. Repeat n times for a log(n) operation! I bet there are going to be some issues with this simple approach, but so far, it seems to be fine. –  Russell Jul 7 '11 at 6:45
That's not a minor modification, that's a major improvement. You could post this as your own answer - I'd vote for it. (since that's what I was about to suggest.) –  AShelly Jul 7 '11 at 15:23
But isn't that O(N), not lg(N)? –  AShelly Jul 7 '11 at 15:26
Yeah good catch that is O(n).. I will post a new answer. –  Russell Jul 8 '11 at 2:23

Building on the other suggestions provided here, I think I have found a O(n) algorithm that works effectively.

The idea is to first pick the first red point as the starting point (or could choose the first blue point). Then compare the distance from this point to the next red point and the next blue point, pick the closer. Repeat until both lists are depleted. This seems to be quite effective on the Translink data set. I will give an update if I make tweaks to this idea.

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Perhaps you could use a custom sweep line algorithm, this should reduce the complexity of finding the nearest line segment.

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Yes, this seems like a good idea as well. I think I may have to do something like this (limiting the search area), but for now, just looking at the next in the list and picking the closer works. Btw Maperitive is great! –  Russell Jul 8 '11 at 3:19

For each red point iterate through blue segments and find the best segment for it. What exactly "best" is depends on the task, but it looks like a good measure would be "how much longer path becomes". If A is a red point and BC is a segment, then the best segment will minimize this: f(A,BC)=(|BA|+|AC|-|BC|).

When the best segment is found, it should be replaced with BA and AC. In the same way other points should be processed.

Without optimizations this will give O(N^2).

If points are distributed more or less uniformly and segment length is significantly less than size of entire figure, some space partitioning may help.

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Good answer, though I don't completely understand what you mean by embedding the point, your idea seems pretty much the same as the first answerer, though the space partitioning is a good idea. –  Russell Jul 7 '11 at 5:38
By embedding point A I meant replacing the closest segment BC with two segments: BA and AC. Probably I misunderstood the first answer, because I thought he suggests to search for nearest points instead of segments... –  maxim1000 Jul 7 '11 at 7:34
No, actually, I meant points. (And amusingly, when I read yours I misunderstood and thought you meant points!) –  andrewdski Jul 8 '11 at 4:37
After some thinking I found that probably neither distance point-segment nor distance point-point is not a good measure. So I've a bit changed the algorithm. –  maxim1000 Jul 8 '11 at 14:19