# graph algorithm, approximation algorithm

After removing the leaves of the dfs tree of a random graph , suppose the number of edges left is |S|, can we prove that the matching for that graph will be |S|/2?

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By |S|/2 you mean floor or ceiling? – kunigami Jan 27 '11 at 12:15
@kunigami, I mean ceiling. – justin waugh Jan 27 '11 at 19:51
1)Is |S| the number of edges after removing the leaves of the DFS tree or the original random graph? 2) By matching you mean the maximum matching or any matching is ok? – kunigami Jan 27 '11 at 21:06
@kunigami 1) |S| is after removing the leaves of DFS tree 2) any matching which is maximal will do so any matching will do. To correct my question, it is ceiling(|S|/2) instead of just |S|/2. – justin waugh Jan 27 '11 at 21:46
Ok, now I understood. So I think Keith Randall answered your question :) – kunigami Jan 28 '11 at 11:34

Theorem: Let `T` be any tree with `i` leaves. There is a `(|T|-i)/2` matching in `T`.
Proof: by induction. If `T` is a tree with `i` leaves, let `T'` be the tree that results when removing all the leaves from `T`. `T'` has `j <= i` leaves. Similarly, let `T''` be the tree that results when removing all the leaves from `T'`. `T''` has `k <= j` leaves.
Apply the theorem by induction to `T''`, so there exists a matching of size `(|T''|-k)/2 = (|T|-i-j-k)/2` in `T''`. The set of edges `T-T'` contains at least `j` edges that are not incident to any edge in `T''` or to each other (pick one incident to each leaf in `T'`), so add those edges to make a matching in `T` of size `(|T|-i+j-k)/2`. Since `j >= k`, this is at least `(|T|-i)/2` edges. QED.