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Need a little help! This is what I have so far using backward substitution:

T(n) = 2T(n/2) + sqrt(n), where T(1) = 1, and n = 2^k
T(n) = 2[2T(n/4) + sqrt(n/2)] + sqrt(n) = 2^2T(n/4) + 2sqrt(n/2) + sqrt(n)
T(n) = 2^2[2T(n/8) + sqrt(n/4)] + 2sqrt(n/2) + sqrt(n)
     = 2^3T(n/8) + 2^2sqrt(n/4) + 2sqrt(n/2) + sqrt(n)

In general

T(n) = 2^kT(1) + 2^(k-1) x sqrt(2^1) + 2^(k-2) x sqrt(2^2) + ... + 2^1 x sqrt(2^(k-1)) + sqrt(2^k)

Is this right so far? If it is, I can not figure out how to simplify it and reduce it down to a general formula.

I'm guessing something like this? Combining the terms

= 1 + 2^(k-(1/2)) + 2^(k-(2/2)) + 2^(k-(3/2)) + ... + 2^((k-1)/2) + 2^(k/2)

And this is where I'm stuck. Maybe a way to factor out a 2^k? Any help would be great, thanks!

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closed as off topic by Michael Petrotta, Lion, Mark, Ben Carey, Tim Bish Apr 28 '13 at 12:58

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Master Theorem could do this if you are looking for a big-O solution. –  gongzhitaao Apr 28 '13 at 4:23
Replace n with 2^k, at each iteration you get first 2^(k-1), then 2^(k-2) and eventually 2^0. You have k calls, k being log2(n)... thus complexity of T(n) is O(log(n)). –  ring0 Apr 28 '13 at 5:04

2 Answers 2

up vote 3 down vote accepted

You're half way there. The expression can be simplified to this:

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Ah ha, so n + n/sqrt(2) + n/sqrt(4) + .. + 1 = sqrt(n)*(sqrt(2n)-1)*(sqrt(2)+1)? Do you know if there is a general summation formula used to generate that? –  user1201359 Apr 28 '13 at 5:31
@user1201359 look for sum of geometric series –  icepack Apr 28 '13 at 6:34
Okay, I'll try to work out the general formula, thanks! –  user1201359 Apr 28 '13 at 7:00

If you want just a big-O solution, then Master Theorem is just fine.

If you want a exact equation for this, a recursion tree is good. like this:

enter image description here

The right hand-side is cost for every level, it's easy to find a general form for the cost, which is sqrt((2^h) * n). Then, sum up the cost you could get T(n).

  1. According to Master Theorem, it's case 1, so O(n).
  2. According to Recursion Tree, the exact form should be sqrt(n)*(sqrt(2n)-1)*(sqrt(2)+1), which corresponds with the big-O notation.


The recursion tree is just a visualized form of the so called backward substitution. If you sum up the right hand side, i.e. the cost, you could get the generalized form of T(n). All these methods could found in introduction to algorithm

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Isn't it rather O(log(n))? –  ring0 Apr 28 '13 at 4:59
I do need an exact formula, but the teacher is expecting it to be worked out like above using backward substitution. I think I'm on the right track, I just need to figure out how to factor and simplify it. –  user1201359 Apr 28 '13 at 5:01
@ring0 Why O(log(n))? According to Master Theorem, this satisfies the case 1, so it should be O(n). –  gongzhitaao Apr 28 '13 at 5:03
@user1201359 the substitution is just another version of the recursion tree, basically they share the same idea. Recursion tree is just a visualized representation. You could actually get the substitution form from the recursion tree. –  gongzhitaao Apr 28 '13 at 5:05
@user1201359 Sorry, a factor is missing. see the updated. –  gongzhitaao Apr 28 '13 at 5:10

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