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If there are 2 algorthims that calculate the same result with different complexities, will O(log n) always be faster? If so please explain. BTW this is not an assignment question.

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It will always be faster for large enough n. –  Phonon Feb 8 '12 at 20:56

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No. If one algorithm runs in N/100 and the other one in (log N)*100, then the second one will be slower for smaller input sizes. Asymptotic complexities are about the behavior of the running time as the input sizes go to infinity.

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so O(n) can be faster that O(log n) for extremely small input? –  Varkolyn Feb 8 '12 at 21:02
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1*n is O(n). 10000000000000000000000000000000*(log n) is O(log n). In such a case, O(n) will not just be faster on extremely small input. But as "n" grows toward infinity, eventually O(log n) will be faster. –  Alex D Feb 8 '12 at 21:10
    
@Varkolyn: Not necessarily extremely. Depending on algorithm, the crosspoint can be very large in n! –  kkm Feb 8 '12 at 21:11
    
Got it. Thanks a ton guys. –  Varkolyn Feb 8 '12 at 21:13

No, it will not always be faster. BUT, as the problem size grows larger and larger, eventually you will always reach a point where the O(log n) algorithm is faster than the O(n) one.

In real-world situations, usually the point where the O(log n) algorithm would overtake the O(n) algorithm would come very quickly. There is a big difference between O(log n) and O(n), just like there is a big difference between O(n) and O(n^2).

If you ever have the chance to read Programming Pearls by Jon Bentley, there is an awesome chapter in there where he pits a O(n) algorithm against a O(n^2) one, doing everything possible to give O(n^2) the advantage. (He codes the O(n^2) algorithm in C on an Alpha, and the O(n) algorithm in interpreted BASIC on an old Z80 or something, running at about 1MHz.) It is surprising how fast the O(n) algorithm overtakes the O(n^2) one.

Occasionally, though, you may find a very complex algorithm which has complexity just slightly better than a simpler one. In such a case, don't blindly choose the algorithm with a better big-O -- you may find that it is only faster on extremely large problems.

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