# Worst case in Max-Heapify - How do you get 2n/3?

In CLRS, third Edition, on page 155, it is given that in MAX-HEAPIFY,

The children’s subtrees each have size at most 2n/3—the worst case occurs when the bottom level of the tree is exactly half full.

I understand why it is worst when the bottom level of the tree is exactly half full. And it is also answered in this question worst case in MAX-HEAPIFY

My question is how to get 2n/3?

Why if the bottom level is half full, then the size of the child tree is up to 2n/3?

How to calculate that?

Thanks

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A simple calculation is provided at this blog: bit.ly/138f43F. –  sleekFish Jun 26 at 12:28

In a tree where each node has exactly either 0 or 2 children, the number of nodes with 0 children is one more than the number of nodes with 2 children.{Explanation: number of nodes at height h is 2^h, which by the summation formula of a geometric series equals (sum of nodes from height 0 to h-1) + 1; and all the nodes from height 0 to h-1 are the nodes with exactly 2 children}

``````    ROOT
L      R
/ \    / \
/   \  /   \
-----  -----
*****
``````

Let k be the number of nodes in R. The number of nodes in L is k + (k + 1) = 2k + 1. The total number of nodes is n = 1 + (2k + 1) + k = 3k + 2 (root plus L plus R). The ratio is (2k + 1)/(3k + 2), which is bounded above by 2/3. No constant less than 2/3 works, because the limit as k goes to infinity is 2/3.

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yeah, i get it, you mean L / n = 2/3 –  Jackson Tale Feb 1 '12 at 16:42
Wow. That was deep. How did you figure it out by yourself? –  Programming Noob Oct 15 '12 at 7:33

For a complete binary tree of height `h`, number of nodes is `f(h) = 2^h - 1`. In above case we have nearly complete binary tree with bottom half full. We can visualize this as collection of `root + left complete tree + right complete tree`. If height of original tree is `h`, then height of left is `h - 1` and right is `h - 2`. So equation becomes

`n = 1 + f(h-1) + f(h-2)` (1)

We want to solve above for `f(h-1)` expressed as in terms of `n`

`f(h-2) = 2^(h-2) - 1 = (2^(h-1)-1+1)/2 - 1 = (f(h-1) - 1)/2` (2)

Using above in (1) we have

`n = 1 + f(h-1) + (f(h-1) - 1)/2 = 1/2 + 3*f(h-1)/2`

`=> f(h-1) = 2*(n-1/2)/3`

Hence O(2n/3)

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Isn't it that f(h) = 2^(h+1) - 1? –  Affan Sep 17 at 10:52