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Given two polygons:

POLYGON((1 0, 1 8, 6 4, 1 0))
POLYGON((4 1, 3 5, 4 9, 9 5, 4 1),(4 5, 5 7, 6 7, 4 4, 4 5))

How can I calculate the union (combined polygon)?

alt text

Dave's example uses SQL server to produce the union, but I need to accomplish the same in code. I'm looking for a mathematical formula or code example in any language that exposes the actual math. I am attempting to produce maps that combine countries dynamically into regions. I asked a related question here: http://stackoverflow.com/questions/2653812/grouping-geographical-shapes

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6 Answers 6

You need to determine which points lie inside. After removing these points, you can insert one set of "outside" points into the other. Your insertion points (e.g. where you have the arrow in the picture on the right) are where you had to remove points from the input sets.

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1  
+1 for linking to Bourke. Thirty seconds slower and I'd've beaten you to it :) –  David Seiler Apr 19 '10 at 13:37
    
Link is broken atm. –  Sadly Not Mar 12 '13 at 22:50
    
@SadlyNot: Thanks, I updated with a link to the web archive. –  Benjamin Bannier Mar 13 '13 at 14:05

This is a very good question. I implemented the same algorithm on c# any time ago. Algorithm constructs common contour two polygons (i.e. constructs a union without holes). Here it is.


Goal

Step 1. Create graph that describes polygons.

Input: first polygon (n points), second polygon (m points). Output: graph. Vertex - polygon point of intersection point.

We should to find intersections. I iterate through all polygon sides in first and second polygons [O(n*m)] and find intersections.

  • If intersection does not found, simply add vertexes and connect them to the edge.

  • If intersections found, sort them by length to start point, add all
    vertexes (start, end and intersections) and connect them (already in sorted order) to the edge. Graph

Step 2. Check constructed graph

If we did not find any intersection points while graph was builded, we have one of the following conditions:

  1. Polygon1 contains polygon2 - return polygon1
  2. Polygon2 contains polygon1 - return polygon2
  3. Polygon1 and polygon2 do not intersect. Return polygon1 AND polygon2.

Step 3. Find left-bottom vertex.

I find a minimum x and y coordinates (minx, miny). Then I find minimum distance between (minx,miny) and polygon's points. This point will be the left-bottom point.

Left-bottom point

Step 4. Construct common contour.

We start to traverse the graph from left-bottom point and continue until you get back into it. At the beginning we mark all edges as unvisited. On every iteration you should select a next point and mark it as visited.

When I want select next point, I choose an edge with a maximum internal angle in counter-clockwise direction. I calculate two vectors: vector1 for current edge and vector2 for an each next unvisited edge (as presented on the picture).

For vectors I calculate:

  1. Scalar product. It gives me angle between vectors.
  2. Vector product. It gives me a new vector. If z-coodrinate of this vector is positive, scalar product gives me right angle in counter-clockwise direction. Else (z-coordinate is negative), I calculate get angle between vectors as 360 - angle from scalar product.

As a result I get an edge (and a correspond next vertex) what has maximum angle.

I add to result list each passed vertex. Result list is the union polygon. Vectors

Remarks

  1. It is allow to use this algorithm to merge a lots of polygons - to apply iteratively with polygon's pairs.
  2. If you have a path consists of many bezier curves and lines, you should flatten this path at first.

p.s. Sorry for my not ideal english. I gladly accept all the comments on the algorithm and language!

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Try gpc.

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That looks promising. I've emailed the authors as their download links are all returning 403's. –  grenade Apr 20 '10 at 7:59
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The link to the source code works for me: ftp.cs.man.ac.uk/pub/toby/gpc/gpc232-release.zip –  lhf Apr 20 '10 at 11:21

Good question! I've never attempted this before, but I'll take a crack at it now.

First: You need to know where these two shapes overlap. To do this, you could look at every edge in Polygon A and see where it intersects and edge in Polygon B. In this example, there should be two points of intersection.

Then: Make the union shape. You can take all of the vertices in A and B, and also the points of intersection, and then exclude the vertices that contained by the final shape. To find these points, it looks like you could just find any vertex of A that is inside B, and any vertext of B that is inside A.

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Yes the real question is how do we calculate that two added points of intersection? –  Pacerier Mar 30 '13 at 18:22

A solution I've seen using BSP trees is described here.

Basically, it describes intersection in terms of a union of the edges of polygon A that are inside polygon B (including partial edges, and calculated using a BSP tree). Then, you can define A \/ B as ~(~A /\ ~B), where ~ denotes reversing the winding of the polygon, \/ denotes union and /\ denotes intersection.

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When grouping countries, I'd hope there be no overlap -- you could take a fairly naive algorithm that looks for shared vertices - a simple view would be to iterate through the points on one polygon, see if it's on any of your other polygons, and shares the same next or previous point to see if there is a match. Then just remove the shared vertex to create your union

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"When grouping countries, I'd hope there be no overlap"... not all countries agree on their own or their neighbours borders, though it would be nice if they did. –  FrustratedWithFormsDesigner Apr 19 '10 at 13:40
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@FrustratedWithFormsDesigner indeed, but most cartographers will either assign the disputed region to their political ally or as a separate entity in its own right -- that's also why I describe my algorithm as naive... –  Rowland Shaw Apr 19 '10 at 14:17

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