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I am doing a unique form of Huffman encoding, and am constructing a k-ary (in this particular case, 3-ary) tree that is full (every node will have 0 or k children), and I know how many leaves it will have before I construct it. How do I calculate the total number of nodes in the tree in terms of the number of leaves?

I know that in the case of a full binary tree (2-ary), the formula for this is 2L - 1, where L is the number of leaves. I would like to extend this principle to the case of a k-ary tree.

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Is this homework? If so, please tag accordingly. –  PengOne Oct 20 '11 at 21:21
No, it's not homework. Thanks for the -2 vote, that was nice. –  Andrew Oct 20 '11 at 23:59
Though no one but those who voted can know for certain, the down votes are most likely due to the fact that you showed no research effort on this problem, or perhaps because it is not directly related to coding. –  PengOne Oct 21 '11 at 0:02
oh, ok, got it. –  Andrew Oct 21 '11 at 0:30

2 Answers 2

up vote 8 down vote accepted

Think about how to prove the result for a full binary tree, and you'll see how to do it in general. For the full binary tree, say of height h, the number of nodes N is

N = 2^{h+1} - 1

Why? Because the first level has 2^0 nodes, the second level has 2^1 nodes, and, in general, the kth level has 2^{k-1} nodes. Adding these up for a total of h+1 levels (so height h) gives

N = 1 + 2 + 2^2 + 2^3 + ... + 2^h = (2^{h+1} - 1) / (2 - 1) = 2^{h+1} - 1

The total number of leaves L is just the number of nodes at the last level, so L = 2^h. Therefore, by substitution, we get

N = 2*L - 1

For a k-ary tree, nothing changes but the 2. So

N = 1 + k + k^2 + k^3 + ... + k^h = (k^{h+1} - 1) / (k - 1)

L = k^h

and so a bit of algebra can take you the final step to get

N = (k*L - 1) / (k-1)
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great answer, thanks! –  Andrew Oct 21 '11 at 0:31

The formula for 2L-1 that you mentioned comes from looking on a full, complete and balanced binary tree: on the last level you have 2^h leafs, and on the other levels: 1+2+4+....+2^(h-1) = 2^h -1 leafs. When you "mess" levels in the tree and create an unbalanced one, then the number of internal nodes that you have doesn't change.

In 3-ary tree its the same logic: on the last level you have 3^h leafs, and on the other levels: 1+3+9+....+3^(h-1)= (3^h -1 )/2, that means that on a 3-ary tree you have 1.5*L - 0.5 leafs (and this make sence- because the degree is larger you need less internal nodes). I thing that also here, when you mess up levels in the tree you will still need the same number of internal nodes.

Hope that it helps you

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