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Is O(n^2) is greater than O(n^2 log n) ?
If yes ? how ?
Can we have a simple example for this.
Also ,
What is complexity of the code below.

int unknown(int n){
   int i,j,k=0;
   for(i=n/2;i<=n;i++){
     for(j=2;j<=n;j=j * 2){
         k =k + n/2;
     }
  }
return k;
}

and What is complexity of return value k ?

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closed as off topic by Sindre Sorhus, Yan Sklyarenko, RB., Jan Hančič, pduersteler Feb 12 '13 at 11:47

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This might be more suited to programmers.stackexchange.com –  Brendan Bullen Feb 12 '13 at 9:29
6  
(n^2)logn or n^(2logn) ? –  Mitch Wheat Feb 12 '13 at 9:29
    
sounds like homework... –  Syjin Feb 12 '13 at 9:30
    
Mitch Wheat : (n^2)logn –  nagesh Feb 12 '13 at 9:31
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3 Answers 3

up vote 7 down vote accepted

O(n^2) is a subset of O((n^2) * log(n)), and thus the first is "better", it is easy to see that since log(n) is an increasing function, by multiplying something with it, you get a "higher" function then the original (f(n) <= f(n) * log(n) for each increasing non negative f and n>2)

The code snap you gave is O(nlog(n)), since the inner loop repeats log(n) times per outer loop iteration, and the outer loop repeats n/2 times - which gives you n/2 * log(n) which is in O(nlog(n))

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Ln(e) == 1, so anything greater than e (~2.7) will give Ln(n) > 1.

Therefore for all n where n > e, O(n^2 ln(n)) will be > O(N^2)

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I'm assuming you mean O((n^2) * log n), but the answer is the same and what you need to prove is basically the same if it's n^(2 * log n). I will also only consider non-negative functions, to save some messing about with absolute values.

The answer is that O(n^2) is a strict subset of O((n^2) * log n). It is smaller.

First prove it's a subset: Suppose f is O(n^2). Then there exist M and k such that for all n >= M, f(n) <= k(n^2).

Let L = max(M, e) (where e is the logarithmic base). Then for all n >= L, log(n) >= log(e) == 1 (since n >= 1) and f(n) <= k(n^2) (since n >= M).

Hence for all n >= L, f(n) <= k(n^2) * log(n). So f is in O((n^2) * log n).

Second, prove it's a strict subset: let g be the function g(n) = (n^2) * log n, so g is in O((n^2) * log n).

For any k, take L = e^k. Then for any n > L, log(n) > k and so g(n) > n^2 * k.

Hence g is not in O(n^2), since there cannot exist M and k such that for all n >= M, g(n) <= k * n^2.

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Surely that should be (2 + log n) rather than (2 * log n)? –  Vatine Feb 12 '13 at 10:01
    
@Vatine: what should be 2 + log n? If the question is "wrong" then you'll have to take that up with the questioner, but the question certainly doesn't say 2 + log n. –  Steve Jessop Feb 12 '13 at 10:05
    
You're saying that "(n^2) * log n" is "basically the same as n^(2 * log n)", the latter should probably be "(2 + log n)". –  Vatine Feb 12 '13 at 10:07
    
@Vatine: I'm saying that what you need to prove is basically the same. The functions are different. The form of the proof will be very similar, but with different choices of L. The reason I mention n^(2 * log n) is simply that what the question says, n^2logn, is ambiguous. For my answer I've gone with the bracketing in the title. –  Steve Jessop Feb 12 '13 at 10:07
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