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There is a unbalanced binary tree of unknown depth. The number of nodes having two child nodes is denoted by T2. The node having only one child is denoted by T1 and leaf nodes are denoted by L. If it is given that T1 = m and T2 = n nodes then can you define a mathematical function f(m, n) which gives number of leaf nodes L?

For example, in the below tree total T2 nodes are m = 3, and total T1 nodes are n = 2. The number of leaf nodes L = f(m,n) = 4. Can you find a mathematical function f(m,n) which gives number of leaf nodes for all trees?

enter image description here

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closed as off-topic by BalusC, trashgod, Michael Härtl, falsetru, talonmies Aug 15 '13 at 18:52

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This question appears to be off-topic because it belongs on – BalusC Aug 14 '13 at 17:37
F(n, m) = m + 1 It is independent of n – User 104 Aug 14 '13 at 18:15
up vote 8 down vote accepted

This is pretty easy. In a fully binary tree (that is, every non-leaf has 2 children) of m internal nodes, there are exactly m+1 leaf nodes. Every node that has only one child can be removed, and you still have a binary tree. So, the number of leaf nodes in L is simply m+1. Or answering the question: f(m, n) = m + 1.

It might be useful to give an example of what I mean by "removing T1 nodes". Consider your example. The right 5 has only one child. If we remove the 5 and put the 9 under the 2 directly, the number of leafs does not change.

If we do the same for the 9 (put the 4 directly under the 2), we have a full binary tree, that is, all non-leafs have 2 children.

See the picture for a graphic explanation of how to remove all nodes of type T1 without changing the number of leaf nodes.

enter image description here

All that remains is to prove that in a tree of m internal nodes, where every non-leaf has exactly 2 children, the number of leaf nodes is m+1:

Proof by induction. Induction hypothesis: |L| = |T2|+1

Base: the tree consists of a single node. Clearly, |L|=1 and |T2|=0, so it holds.

Step: Consider a tree with a root that is not a leaf. By the assumption, it has two children, left and right. By the induction hypothesis: |Lleft|=|T2left| + 1 and |Lright| = |T2right| + 1. For the total tree, we have |T2| = |T2left| + |T2right| + 1 and |L| = |Lleft| + |Lright|. Therefore, |L| = |T2left| + 1 + |T2right| + 1 = |T2| + 1.

Alternative proof

The property can also be proved directly, without the handwaving argument of removing the T1 nodes. Again, by induction, with the induction hypothesis |L| = |T2| + 1.

  • Base: the tree is a single node, so |L| = 1 and |T2| = 0.
  • Step case 1: the tree has a root with only 1 child, X, then |L| = |LX| and |T2| = |T2X|, so |L| = |T2| + 1 by the induction hypothesis.
  • Step case 2: the tree has a root with two children, left and right. By the induction hypothesis: |Lleft|=|T2left| + 1 and |Lright| = |T2right| + 1. For the total tree, we have |T2| = |T2left| + |T2right| + 1 and |L| = |Lleft| + |Lright|. Therefore, |L| = |T2left| + 1 + |T2right| + 1 = |T2| + 1.

Therefore, |L| = |T2| + 1 or in other words f(m, n) = m + 1.

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Its correct answer. – User 104 Aug 14 '13 at 18:16
Is there a proof to show that removing T1 nodes doesn't changes L nodes? You have provided only graphical explanation for this above. – manav m-n Aug 17 '13 at 20:56
@Manav the role of a node (T1, T2, or L) is entirely determined by its number of children. When removing a node t of type T1, only the set of children of its parent changes. Since t is replaced by child(t), parent(t) still has as many children, so its role does not change. – Vincent van der Weele Aug 18 '13 at 11:14

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