The following tree fits into your definition, although it doesn't seem very balanced to me:

**EDIT** This answer is wrong, but it has enough interesting stuff in it that I don't feel like deleting it yet. The algorithm produces a balanced tree, but not a minimal one. The number of nodes it adds is:

where `n`

ranges over all nodes in the tree, `lower(n)`

is the depth of the child of `n`

with the lower depth and `upper(n)`

is the depth of the child of `n`

with the higher depth. Using the fact that the sum of the first `k`

fibonacci numbers is `fib(k+2)-1`

, we can replace the inner sum with `fib(upper(n)) - fib(lower(n) + 2)`

.

The formula is (more or less) derived from the following algorithm to add nodes to the tree, making it balanced (in python, only showing the relevant algorithms):

```
def balance(tree, label):
if tree is None:
return (None, 0)
left, left_height = balance(tree.left_child, label)
right, right_height = balance(tree.right_child, label)
while left_height < right_height - 1:
left = Node(label(), left, balanced_tree(left_height - 1, label))
left_height += 1
while right_height < left_height - 1:
right = Node(label(), right, balanced_tree(right_height - 1, label))
right_height += 1
return (Node(tree.label, left, right), max(left_height, right_height) + 1)
def balanced_tree(depth, label):
if depth <= 0:
return None
else:
return Node(label(),
balanced_tree(depth - 1, label),
balanced_tree(depth - 2, label))
```

As requested: report the count instead of creating the tree:

```
def balance(tree):
if tree is None:
return (0, 0)
left, left_height = balance(tree.left_child)
right, right_height = balance(tree.right_child)
while left_height < right_height - 1:
left += balanced_tree(left_height - 1) + 1
left_height += 1
while right_height < left_height - 1:
right += balanced_tree(right_height - 1) + 1
right_height += 1
return (left + right, max(left_height, right_height) + 1)
def balanced_tree(depth):
if depth <= 0:
return 0
else:
return (1 + balanced_tree(depth - 1)
+ balanced_tree(depth - 2))
```

*Edit*: Actually, I think that other than computing the size of a minimum balanced tree of depth n more efficiently (i.e. memoizing it, or used the closed form: it's just `fibonacci(n+1)-1`

), that's probably as efficient as you can get, since you have to examine every node in the tree in order to test the balance condition, and that algorithm looks at every node precisely once.