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If you were to look at a recursive implementation of calculating the nth Fibonacci number (root 100, children 99 and 98, grandchildren 98, 97, 97, and 96, etc. etc.), roughly what would be the ratio of the number of leaves to the total number of nodes in the recursive tree?

    100
   /   \
  98   97
 /  \   .
96  97  .
.    .  .
.    .  

Not homework, just academically curious about this. (And yes, I realize that a recursive implementation is a god-awful way to calculate Fibonacci numbers)

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I don't understand your definition of a "Fibonacci tree." –  Brian Gordon Jul 27 '11 at 16:38
    
Think of it as the tree of function calls in a recursive implementation of calculating the nth Fibonacci number. –  tskuzzy Jul 27 '11 at 16:56
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3 Answers 3

fib(x) consist of leaves fib(x-1) and leaves of fib(x-2). So you get the same recursive equation as you have for fibonacci numbers.

If the termination point (leaves) are Fib1 and Fib0, then

tree   numofleaves
fib2   2
fib3   3
fib4   5
fib5   8
fib6   13
...

and numofleaves(x) = fib(x+1).

For the number of nodes you get the equation numnodes(x) = 1 + numnodes(x-1) + numnodes(x-2).

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This is all correct. –  user666866 Jul 29 '11 at 16:52
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The number of leaves is simply F(n) since the F(i) is simply the number of leaves beneath that node. Do you see why? (hint: use induction)

The number of non-leaf nodes is the number of leaf nodes-1. This is a property of binary trees. So the total number of nodes is F(n) + F(n)-1 = 2F(n)-1.

The ratio thus approaches 1/2 as n grows large.

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ahh, binary tree.. actually it doesn't matter at all that it is the tree of the fibonacci recursive process. I just started to solve the recursive equation.. how silly I was –  Karoly Horvath Jul 27 '11 at 16:58
    
This is slightly off: see my proof below. The number of leaf nodes is NOT 2F(n - 1) in a fibonacci tree, if you look closely at the diagram above, it's apparent. –  user666866 Jul 29 '11 at 16:50
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I actually worked out a proof by induction that shows that the number of leaves in a Fibonacci tree always exceeds the number of internal nodes.

Proof: Let E(n) be the # of leaves of fibonacci tree for input n, and M(n) be the # of internal nodes of fibonacci tree for input n

   E(n) >= M(n) + 1

Base cases:

f(0): E(0) = 1, M(0) = 0

f(1): E(1) = 1, M(1) = 1

f(2): E(2) = 2, M(2) = 1

f(3): E(3) = 3, M(3) = 2

The leaves of a tree of size n is equal to the leaves of each sub-tree:

E(n) = E(n - 1) + E(n - 2)

The internal nodes of a tree of size n is equal to the internal nodes of each sub-tree, plus the root

M(n) = M(n - 1) + M(n - 2) + 1

E(n) >= [M(n - 1) + 1] + [M(n - 2) + 1], (by the Inductive Hypothesis)

So, E(n) = M(n - 1) + M(n - 2) + 2

So, E(n) >= M(n) + 1, QED

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Actually num_of_internal_nodes = num_of_leaves - 1 for any binary tree. Proof: for connecting two leaves you need an internal node. Now treat that internal node as if it were a leaf and keep on connecting the leaves... got it? –  Karoly Horvath Jul 29 '11 at 17:00
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