# one-pass force-directed graph drawing algorithm

I'm looking for a one-pass algorithm (or ideas of how to write it myself) that can calculate the two or three dimensional coordinates for a directed, unweighted graph. The only metadata the vertices have are title and category.

I need to implement this algorithm in a way that vertices can be added/removed without recalculating the entire graph structure.

This algorithm has to be applied to a large (5gb) dataset which is constantly changing.

My Google skills have led me to n-pass algorithms which are not what what I am looking for.

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I am a bit confused - are you talking about layout algorithms such as these? en.wikipedia.org/wiki/Force-directed_graph_drawing –  Ziyao Wei Jun 24 '13 at 23:43
Well, calculating some coordinates (which should not repeat) is not that difficult. What are you looking for, a visualisation of clustered nodes? How should title and category be considered by the algorithm? –  Bergi Jun 24 '13 at 23:45
Actually I do. But I was not able to find a one-pass variant of a Force-directed graph drawing algorithm. –  Joren Jun 24 '13 at 23:48
I think what you're describing is an oxymoron. Force-directed algorithms simulate a physical system that represents the graph as masses subject to forces over time. Because computers can only operate on discrete values, time must be split into steps as in numerical integration. The resulting algorithms are inherently iterative. For big, dynamically changing graphs there are "local update" variants. These limit the parts of the graph touched by iteration to improve performance, but they still require iteration. –  Gene Aug 15 '13 at 23:16
How is the graph stored (adjacency list, matrix, ...)? How do 'change' events look like? –  Michael Franzen Aug 17 '13 at 8:04
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I guess your question might still be an open issue. I know a research project called Tulip (http://tulip.labri.fr/TulipDrupal/) which is a (large-scale) graph viewer. A paper on the method is available at http://dept-info.labri.fr/~auber/documents/publi/auberChapterTulipGDSBook.pdf and surely you can find more algorithms browsing the personal web page of D. Auber and his colleagues.

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