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Is time complexity O(n^2) or O (n(logn)^2) better?

I know that when we simplify it, it becomes

O(n) vs O((logn)^2)

and logn < n, but what about logn^2?

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up vote 13 down vote accepted

n is only less than (log n)2 for values of n less than 0.49...

So in general (log n)2 is better for large n...

But since these O(something)-notations always leave out constant factors, in your case it might not be possible to say for sure which algorithm is better...

Here's a graph:

enter image description here

(The blue line is n and the green line is (log n)2)

Notice, how the difference for small values of n isn't so big and might easily be dwarfed by the constant factors not included in the Big-O notation.

But for large n, (log n)2 wins hands down:

enter image description here

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Notice how the green line shoots up to infinity for tiny values of n asymptotics is not about whether something goes to infinity, but about how fast it approaches infinity. log(n)^2 goes to infinity as well. – phant0m Dec 5 '12 at 13:29
    
@phant0m What I was trying to point out is that (log n)^2 also goes to infinity for SMALL values of n, not just large ones. But that's more of a purely mathematical observation since n usually isn't less than 1 anyways... I'll get rid of the line. It doesn't really add anything useful... – Markus A. Sep 4 '14 at 15:52

For each constant k asymptotically log(n)^k < n.

Proof is simple, do log on both sides of the equation, and you get:

log(log(n))*k < log(n)

It is easy to see that asymptotically, this is correct.


Semantic note: Assuming here log(n)^k == log(n) * log(n) * ... * log(n) (k times) and NOT log(log(log(...log(n)))..) (k times) as it is sometimes also used.

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log(n) ^ 2 is less than n

Try to visualize it: WolframAlpha

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2  
Best answer IMHO.+1 – axiom Dec 4 '12 at 20:04
    
@axiom Thanks :) – kravemir Dec 4 '12 at 20:29
O(n^2) vs. O(n*log(n)^2)
<=> O(n) vs. O(log(n)^2) (divide by n)
<=> O(sqrt(n)) vs. O(log(n)) (square root)
<=> polynomial vs. logarithmic

Logarithmic wins.

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(Log n)^2 is better because if you do a variable change n by exp m, then m^2 is better than exp m

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(logn)^2 is also < n.

Take an example:

 n = 5
 log n = 0.6989....
 (log n)^ 2 = 0.4885..

You can see, (long n)^2 is further reduced.

Even if you take any bigger value of n e.g. 100,000,000 , then

   log n = 9
   (log n)^ 2 = 81

which is far less than n.

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log(100) < log(100)^2 (assuming ^2 means log(100)*log(100)), n==5 is a bad example. – amit Dec 4 '12 at 19:51
    
Try with a million. log n = 13.8155... , and the square of it is 190.8683... . Keep in mind that O(some function of N) deals with large values of N. – cHao Dec 4 '12 at 19:52
    
@amit I took even big number in the example. I was updating the answer already. – Yogendra Singh Dec 4 '12 at 19:53
    
@cHao I already took a bigger number which I think is good enough for example. – Yogendra Singh Dec 4 '12 at 19:54

O(n(logn)^2) is better (faster) for large n!

take log from both sides:

Log(n^2)=2log(n)

Log(n(logn)^2)=Log(n)+2log(Log(n))=Log(n)+2log(Log(n))

lim n--> infinity [(Log(n)+2log(Log(n)))/2log(n)/]=0.5 (use l'Hôpital's rule)(http://en.wikipedia.org/wiki/L'H%C3%B4pital's_rule)]

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I believe the OP is after (log(n))^2 and not log(n^2) – amit Dec 4 '12 at 19:52
    
you are rigth: log(n(log(n)^2)=log(n)+log(log(n)^2)=log(n)+2(log(log(n)) – Reza Dec 4 '12 at 19:58

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