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I want to understand how to compute big-O for a dense versus sparse graph. "Algorithms in a nutshell" says that for sparse graph, O(E) is O(V) and for dense graph O(E) is closer to O(V^2). Does anyone know how is that derived?

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It's not derived, it's a definition. In a fully connected (directed) graph with self-loops, the number of edges |E| = |V|² so the definition of a dense graph is reasonable. The definition of a sparse graph is one where O(|E|) = O(|V|), so there's a constant maximum number of edges per vertex.

Note that if the number of edges is much smaller, e.g. O(lg |V|), then it's still O(|V|) as well. One could imagine a "semi-sparse" class of graphs with |E| = O(|V| lg |V|) or something like that, but I personally have never encountered such a class in practice.

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Thanks, I forgot the self-loops! Makes sense now:) –  iralight Feb 20 '12 at 17:23
    
@iralight: thanks for accepting, but the self-loops aren't the issue. Even in a complete undirected graph without self-loops, the number of edges is |V|×(|V|-1)/2 which is O(|V|²). –  larsmans Feb 20 '12 at 22:20
    
Understood...just conceptually it made sense to me that with self-loops I was able to populate a V^2 adjacency matrix completely. Thanks for clarifying –  iralight Feb 21 '12 at 17:05
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Assuming the graph is simple - at the worst case every node can be connected to all |V|-1 other nodes, resulting in [in not directed graph:] |E| = (|V|-1) + (|V| -2) + ... + 1 <= |V| * (|V| -1) = O(|V|^2). And in directed graph: |E| = |V| * (|V|-1) = O(|V|^2).

A good example for a dense graph is a clique - which have all the edges.

For sparsed graph - we assume the number of edges connected to each vertex is bounded by a constant. Let this constant be k. Thus: |E| <= k* |V|, and we get |E| = O(|V|)

A good example for a sparsed graph is the internet, where every URL is a node and every link is an edge.

Note that if the graph is not simple, you cannot bound |E| with any function of |V|.

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I'm having problem understanding the formula for the dense graph: |E| = (|V|-1) + (|V| -2) + ... + 1 <= |V| * (|V| -1) = O(|V|^2). Is this based on some mathematical formula that simplifies sum of (x-i) to x^2? –  iralight Feb 21 '12 at 17:09
    
@iralight: yes, it is sum of arithmetic progression. Have a look at the attached link. –  amit Feb 21 '12 at 22:16
    
thanks, this explains it –  iralight Feb 22 '12 at 2:19
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