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I need to solve the assignment problem (given a complete weighted bipartite graph, choose a perfect matching with maximum total weight) efficiently and I've been using the O(n^3) version from here However, a paper I read mentioned a "more efficient method" in "A shortest augmenting path algorithm for dense and sparse linear assignment problems", which is sadly behind a paywall. Are there any faster algorithms that I should be aware of (either asymptotically, or just with smaller constants/more uniform memory access or whatever else)? I'm working with floating point weights rather than integer weights, which for the Hungarian method doesn't seem to matter, but might be an issue for faster integer implementations. Any relevant links would be much appreciated.

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You can download codes, based on that article: – Evgeny Kluev Sep 16 '12 at 15:18
Thanks, that's useful. – theotherphil Sep 17 '12 at 18:44
What is the size of the problem you are trying to solve? The hungarian algorithm can be accelerated to n^2*logn with priority queues, but it might not pay off with smaller sizes. – Ants Aasma Sep 19 '12 at 6:34
A few hundred vertices. That sort of speedup would be very useful. Do you have a reference for this? – theotherphil Sep 20 '12 at 17:09

1 Answer 1

it can be equally converted to min cost max flow problem, you may check out that.

AFAIK, hungarian is the fastest.

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I think it's min cost flow, not min cost max flow. On the assignment problem you know beforehand how many "flow" you need. – Papipo Nov 28 '12 at 22:17
@codecaster right, i made the assumption because many acm/icpc problems requires that and i took it here – Topro Nov 29 '12 at 12:09

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