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I'm looking for the mathematical proof, not just the answer.

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The BigOh is kind of meaningless. Even O(n) is a correct answer for this one. You are probably interested in the Theta... –  Aryabhatta May 23 '11 at 17:26

2 Answers 2

up vote 10 down vote accepted

The recurrence relation of binary search is (in the worst case)

T(n) = T(n/2) + O(1)

Using Master's theorem

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  • n is the size of the problem.
  • a is the number of subproblems in the recursion.
  • n/b is the size of each subproblem. (Here it is assumed that all subproblems are essentially the same size.)
  • f (n) is the cost of the work done outside the recursive calls, which includes the cost of dividing the problem and the cost of merging the solutions to the subproblems.

Here a = 1, b = 2 and f(n) = O(1) [Constant]

We have f(n) = O(1) = O(nlogba)

=> T(n) = O(nlogba log2 n)) = O(log2 n)

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@cfarm54: Binary search is in O(log n). –  Gumbo May 23 '11 at 8:52
    
@cfarm54 : I was framing the answer. BTW the time complexity of binary search isn't O(nlog n), its O(log n) –  Prasoon Saurav May 23 '11 at 8:53
    
Nitpick: The recurrence relation you give is the recurrence for the worst case. –  Aryabhatta May 23 '11 at 16:41
    
@Aryabhatta : Thanks for reminding. Mentioned that in the post. :-) –  Prasoon Saurav May 23 '11 at 16:48

The proof is quite simple: With each recursion you halve the number of remaining items if you’ve not already found the item you were looking for. And as you can only divide a number n recursively into halves at most log2(n) times, this is also the boundary for the recursion:

2·2·…·2·2 = 2xn ⇒ log2(2x) = x ≤ log2(n)

Here x is also the number of recursions. And with a local cost of O(1) it’s O(log n) in total.

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