# Analysis of internal path length in binary search tree

I am reading a chapter on trees in book on Data structures and Algorithms by Mark Allen Weiss. Here is text snippet.

Let D(n) be the internal path length for some tree T of n nodes. D(1) = 0. An n-node tree consists of an i-node left subtree and an (n - i - 1)-node right subtree, plus a root at depth zero for 0<= i < n. D(i) is the internal path length of the left subtree with respect to its root. In the main tree, all these nodes are one level deeper. The same holds for the right subtree. Thus, we get the recurrence

D(n) = D(i) + D(n - i -1) + n -1

If all subtree sizes are equally likely, which is true for binary search trees (since the subtree size depends only on the relative rank of the first element inserted into the tree), but not binary trees, then the average value of both D(i) and D(n - i -1) is (1/n) sum from j =0 to n-1 of D(j). This yields

D(n) = (2/n)(sum from j = 0 to n-1 of D(j)) + (n-1).

The above recurrence obtains an average values of D(n) = O(nlogn).

Following are my questions on above text snippet.

1. What does author mean "since subtree size depends only on the relative rank of the first element inserted into the tree" ?
2. How author achieved average value O(nlogn) from D(n)? Can any one please show me steps involved in achieving the mentioned result?

Thanks!

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In a binary tree the size of the left subtree correspond to the number of element smaller than the root and the size of the right subtree to the element larger than the root.

Therefore the subtree size deponds only on the relative rank of the first element inserted.

About your second point I don't have the solution but I would start this way:

You can first transfor the sum :

you know that `sum(j=0 to n, of j ) = n*(n-1)/2`

then `n-1 = 2/n*sum(j=0 to n-1, of 1 ) +2/n*n = 2/n*sum(j=0 to n-1, of j ) + 2`

Since `D(n) = (2/n)(sum from j = 0 to n-1 of D(j)) + (n-1)`, you get the new formula

``````D(n) = (2/n)(sum from j = 0 to n-1 of (D(j) + j)) + 2 (1)
``````

now you can express Dn in term of Dn-1

you would find (if i'm right):

``````D(n)= (n+1)/n*D(n-1) + 2  (2)
``````

Then try to express Dn as n*Sum(1/k) which is equivalent to nln(n)...

from the above formula (2) you get (you can try to write it):

``````D(n) = n+1 * SUM( 2 /k for k=1 to n) +2 ... which is a O(n ln(n))
``````

tell me if you have more questions on this proof

Hope it helps

EDIT: details on (2)

``````D(n) = (2/n)(sum from j = 0 to n-1 of (D(j) + j)) + 2

=> D(n) = (2/n)(sum from j = 0 to n-2 of (D(j) + j)) + 2 + (2/n)*(D(n-1)+n-1)

=> D(n) = ((n-1)/n)* [ 2/(n-1) *(sum from j = 0 to n-2 of (D(j) + j)) + 2]  + 2 + (2/n)*D(n-1)

note: the +2 between the brackets comes  from (2/n)*(D(n-1)+n-1) =  (2/n)*D(n-1) + 2 *(n-1)/n

between the brackets [] you have D(n-1) then :

=>  D(n) = ((n-1)/n)* D(n-1)  + 2 + (2/n)*D(n-1)

=> D(n) = (n+1)/n*D(n-1) + 2
``````
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how do we get expression 2, when we are calculating we are getting D(n) = ((n+1)/n )*D(n-1) + ((2n-6)/n) +2, how do we got expression 2 – venkysmarty Aug 29 '11 at 11:55
@venkysmarty updated it, I added the detailed proof of (2), I don't know where your ((2n-6)/n) comes from. But even with it I guess the final proof should work. – Ricky Bobby Aug 29 '11 at 12:05
@venkysmarty, are you okay with it ? does it help ? – Ricky Bobby Aug 29 '11 at 13:24
Hi Ricky Bobby, thanks for clarification, got it. – venkysmarty Aug 30 '11 at 4:02