Since the naive approach doesn't work because of new edges and vertexes appearing in the union (see the old answer and comments), we will need to employ a more complicated data structure.
The idea is to identify an edge in the input set that contains the edge of the output set. By "contains" I mean both vertexes of the edge from the output set needs to be on the edge from the input set. So, we need to search the input edge set for one that contains a line segment that passes through both vertexes of the edge we are considering.
A simple way to filter out a large number of the edge set for the search is to use bounding boxes: if the vertex we are checking doesn't lie inside the bounding box formed by the two vertexes of an edge, then we can rule it out. The main algorithm, then is:
INPUT: An edge from the output polygon, E1, with V1 and V2 as the end points.
OUTPUT: An edge from the input polygons where both V1 and V2 are on the edge.
- Get the set of edges from input set whose bounding boxes contain both V1 and V2 (or in other words, the bounding box formed by V1, V2)
- Brute force search for the edge which both V1 and V2 lie on.
Second step is obvious. There are a few places to look at for the first one. A K-D tree (the volumetric object) looks like it would solve the problem. Or maybe an R-tree. Also check stackoverflow for similar questions. Unfortunately, I am not very well-versed in the spatial algorithms to suggest a suitable one.
I don't think you need any fancy data structures to handle the case. I am assuming that the coordinates of the vertexes in the union are identical to the ones in your original set. So you can do something like: create a list of vertexes for your input data, where each vertex records the polygon(s) it belongs to. Make these easily searchable: a naive approach would be to sort them by one coordinate first, and then the other. You can find any vertex in O(log n) that way.
Now, for any given edge of the union polygon, search for the first vertex of the edge, then search the other. Take the set intersection of the polygons they belong to, and you get the original polygon. To speed up the searching for second vertex, you can also add a list of connected vertexes to the original list, so that you don't do a full search again.
A final optimization is pre-calculation: just run the above algorithm, and record the results for each edge, then get rid of all the vertex and edge tables. If you don't need a pre-calculated table, you can filter out the original vertex set for vertexes that don't appear in the union.