With your definition of perfectly balanced, all the variation in structure happens at the deepest level of the tree, so you only need to worry about that one level.
A maximal balanced tree with height h will have 2^(h-1) leaves - e.g. for height 1, the only leaf is the root. These are all at the deepest level.
A minimal balanced tree with height h has only one node at the deepest level.
The number of ways you can construct a perfectly balanced binary tree is therefore the same as the number of ways you can have between 1 and 2^(h-1) nodes at the deepest level.
There are 2^(h-1) nodes that may or may not be present at that level (a combinations problem, not permutations), so you get 2^(2^(h-1)) possiblilities, of which only one (the "none" case) is invalid.
So I think your answer is (2^(2^(h-1)))-1. So if you can determine the correct h...
That's assuming a binary search tree (with item values unique and in order), so the binary tree is fully determined by the choice of which deepest-level nodes are present. Otherwise, you multiply that by the number of permutations of the sequence of values.
Take care with my definition of h - a zero-height tree would have no nodes at all, and give a nonsense result - sqrt(2)-1 is an irrational answer in at least two senses.
Marcs comment made me think some more. For a particular height I think my answer is right. The problem is that a particular height allows various different numbers of total nodes, because it allows various different numbers of nodes in that deepest layer. So I can't get the correct answer for one particular node count this way. So... lets try again...
If our tree has height h, it can have at most (2^h)-1 nodes in total. Excluding the deepest level, it has (2^(h-1))-1 nodes - all of which must be present.
We have c-((2^(h-1))-1) nodes at the deepest level, and we get to choose where to put those nodes from the 2^(h-1) possible positions at the deepest level. I use c for count, because I want to define...
n = 2^(h-1)
k = c-((2^(h-1))-1)
answer = n choose k
I still haven't derived h from c - it should be the floor of the base 2 logarithm, but I have that out-by-one-somewhere feeling.