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If we have an algorithm which is order N^2*logN, and if it takes 1 ms with input size 64; does it take 2^10*(11/6) ms to run this algorithm with input size 2048? I am using direct proportion here, that's why it seemed defective to me.

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closed as not a real question by larsmans, Jamey Sharp, Andy Hayden, Chris Gerken, Otávio Décio Nov 15 '12 at 14:56

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Have you tried running the algorithm with a 2048-sized input set? How long did it take? –  Dai Nov 14 '12 at 22:38
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These numbers are so small that there's a non-negligible probability that lower-order terms still have a significant impact. –  Daniel Fischer Nov 14 '12 at 22:42
    
Actually this is for time complexity issue on paper, I haven't tried writing an algorithm whose order is N^2*logN and tried inputs. –  Mert Toka Nov 14 '12 at 22:42
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Not necessarily. Time complexity is usually presented in asymptotic notation and only tells you about the limiting behavior as the inputs grow very large. It is not meant to tell you anything about "small" inputs or fixed (constant size) or lower order costs. –  A. Webb Nov 14 '12 at 22:43

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Easiest way to solve is probably to divide 2048 by 64, plug the resulting number into the complexity equation, and the result is the number of milliseconds for Input size 2048.

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It sounds very reasonable, so answer is if f(x)=x^2*logx, then f(2^11/2^6) = f(2^5), right? –  Mert Toka Nov 14 '12 at 22:45
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This is not typically how time complexity is presented / works. O(N^2 * log(N)) may mean for example that the algorithm takes 15 N^2 * log(27 N) + 573 N + 10000000000 steps for inputs of size N. –  A. Webb Nov 14 '12 at 22:52
    
If lower ordered terms are ignored? Is it this way then right? Because I wrote some simple program with 3 nested loops doing nothing, and they obeyed the rule Robert explained. –  Mert Toka Nov 14 '12 at 23:12
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Your simple program was probably exactly N^3, for example, so scales exactly like N^3. You would say it is O(N^3). However, a program that takes 10 * N^3 + 100 * N^2 + 1000 * N + 10000 steps would also be called O(N^3) but would not scale exactly like N^3. It would scale on the order of N^3 for large N, and to the constant multiple 10 attached to N^3, which is also ignored in Big-O notation. For smaller N, the other terms are much more important, and the scaling won't be obvious. –  A. Webb Nov 15 '12 at 3:25

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