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**.

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`

.

`F(n, m) = m + 1`

It is independent of`n`

– User 104 Aug 14 '13 at 18:15