# How to remove cycles in an unweighted directed graph, such that the number of edges is maximised?

Let G be an unweighted directed graph containing cycles. I'm looking for an algorithm which finds/creates all acyclic graphs G', composed of all vertices in G and a subset of edges of G, just small enough to make G' acyclic.

More formal: The desired algorithm consumes G and creates a set of acyclic graphs S, where each graph G' in S satisfies following properties:

1. G' contains all vertices of G.
2. G' contains a subset of edges of G, such that G' is acyclic.
3. The number of edges of G' is maximised. Which means: There is no G'' satisfying properties 1 and 2, such that G'' contains more edges then G' and G'' is acyclic.

Background: The original graph G models a pairwise ordering between elements. This can't be exploited as an ordering over all elements due to cycles in the graph. The maximal acyclic graphs G' therefore should model a best-possible approximation to this ordering, trying to respect as much of the pairwise ordering relation as possible.

In a naive approach, one could remove all possible combinations of edges and check for acyclicity after each removal. In this case there is a strongly branching tree of variations meaning bad time and space complexity.

Note: The problem may be related to a spanning tree, and you could define the G' graphs as a kind of directed spanning tree. But keep in mind that in my scenario a pair of edges in G' may have the same starting or the same ending vertex. This conflicts with some definitions of directed spanning trees used in literature.

EDIT: Added intuitive description, background information and note related to spanning trees.

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Are you looking to enumerate all the spanning trees of G? en.wikipedia.org/wiki/Spanning_tree – mhum Jun 9 '11 at 3:48
@mhum: The problem is related, but spanning trees are undirected graphs, whereas i need a solution for directed graphs. But thanks to your hint, i googled "directed spanning tree" and found this paper. It will be a new starting point. – mtsz Jun 9 '11 at 4:01
At least the linked wikipedia article restricts spanning trees as to undirected graphs. But you could define "directed spanning tree" as a connected directed graph composed of all vertices - seems like a valid naming to me. – mtsz Jun 9 '11 at 4:13
The wiki article only talks about undirected graphs but the generalization to directed graphs is straightforward. Also, be careful with the paper you linked to; they're talking about a very particular restriction of the problem that's probably not relevant to your situation. In any case, I think I've found a more applicable reference (posted as an answer). – mhum Jun 9 '11 at 5:06