# why E dominates v?

I analyzed the running time for Kruskal algorithm and I come up with O(ElogE+Elogv+v)

I asked my prof and he said that if the graph is very sparse with many isolated vertices V dominates E which makes sense if not then E dominates V and I can not understand why? I can give an example where graph is not sparse but still V is greater than E

Can anyone help me to clear this confusion?

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How do you define sparse? My guess is your prof's definition of sparse is that V dominates E. –  erikkallen Mar 3 '14 at 22:33
Actually he believes if I dont make-set for isolated vertices in kruskal alg then E dominates V –  Hamed Minaee Mar 3 '14 at 22:36
The number of edges can be anywhere from 0 to `V choose 2 = (V(V-1))/2`. –  dfb Mar 3 '14 at 22:51

A tree in a undirectional graph has `|V|-1` edges.

Since a tree is the connected component with least edges as possible - it basically means that for each connected undirectional graph, |E| is in `Omega(|V|)`, so |V| is dominated by |E|.

This basically means that if `|E| < |V|-1` - the graph is not connected.

Now, since Kruskal algorithm is designed to find a spanning tree, you can abort the algorithm once you have found `|E| < |V|-1` - there is no spanning tree at all, no point to look for one.

From this we conclude that when `|E| < |V|-1`, there is no point in discussing complexity of Kruskal Algorithm, and we can safely assume that `|E| >= |V| -1`, so `|V|` is dominated by `|E|`.

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Awesome thanks:) –  Hamed Minaee Mar 4 '14 at 3:56

Density = number of edges / number of possible edges = E / (V(V-1))/2

Let the graph be a tree E = V - 1

So V = (E + 1)

And Kruskal's complexity is

O(E log E + E log V + V) = O(E log E + E log (E + 1) + (E + 1)) = O( E log E )

So E dominates. E will dominate as long as E = O(V).

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`V dominates iff E = O(1).` No. what if for example `E=O(logV)`? V still dominates E, so the claim is obviously wrong. –  amit Mar 3 '14 at 23:06
@amit Oops! Thanks for catching that! –  Pratik Deoghare Mar 4 '14 at 2:01