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Given the following complexities list :

n^(log log(n) )  ;2^n  ;3^n  ;n! ;  n^3  ;1/n  ;(n+1)!  ;  4^log(n)   ;n^2  

n^log(n)   ;log(n!)  ;nln(n)  ;  log(2^n )=nlog2 ;(log(2) )^n  ;5n^2+6  ;  n^log(n!) 

I need to sort them by classes .

I sorted part of them by the following order , but I'm still missing a few :

(n+1)!  
n!
3^n
2^n
(3/2)^n
(log(n))^log(n) =n^log(log(n) ) 
n^3
n^2 = 4*log(n) = 4^log(n) 
5n^2+6 = Θ(n^2 )
log(n!) = Θ(n*log(n))
nlog(2) = log(2^n )

Where do I need to put the rest :

n^log(n)  ;  n*ln(n) ; (log(2))^n ; n^[log(n!)] ; 1/n ; 

?

And , how can I divide them into common classes ?

I'd appreciate any help

Regards

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1  
Is this homework? –  Shahbaz Mar 27 '12 at 15:43
2  
Off-topic: this should probably be on cs.stackexchange.com. –  Oli Charlesworth Mar 27 '12 at 15:44
    
I cannot tell you how to answer this as a homework question. That may depend on what your instructor wants. However, though computer science regrettably frequently fails to recognize it, n! is of infinite order and log(n) is of zeroth order. L'Hospital's rule governs. (I really don't think that comment this will help you on your homework, though, because the way the question is phrased suggests that your instructor disagrees with the comment's premise.) –  thb Mar 27 '12 at 15:48
1  
@thb, there are many complexities higher than n! and many lower than log(n). Calling them infinite and zeroth order doesn't make sense to me. Do you have any references? –  Shahbaz Mar 27 '12 at 15:59
    
Why off-topic ? time complexity is a very important element in Complexity , is it not ? –  ron Mar 27 '12 at 16:56

2 Answers 2

You have done well so far. Since this is a homework, I won't give an exact answer, but only hints about the ones you are missing:

  • n^log(n): this grows faster than (log(n))^(log(n)), but is not as fast as exponentials. You can confirm this by comparing logs of these three expressions together.

  • n*ln(n): ln(n) is ln(10)log(n). In general, log a in base c, is log a in base b multiplied by log b in base c.

  • (log(2))^n: This is an exponential with base log(2) which is ~ 0.3. This is almost (3.333^-n) which exponentially decreases.

  • n^[log(n!)]: log(n!) is O(nlog(n)). This means n^(log(n!)) is O(n^n * n^log(n))

  • 1/n: This is n^(-1) which decreases slowly by value.

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I've answered my question , would greatly appreciate if you could give me a feedback ...:) –  ron Mar 27 '12 at 17:12

My final answer :

n^log(n!) 
(n+1)!  
n!
3^n
2^n
(3/2)^n
n^log(n) 
(log(n) )^log(n) =n^log(log(n) ) 
n^3
n^2=4 log(n)=4^log(n)
5n^2+6=Θ(n^2 )
log(n!)=Θ(nlog(n))
n⋅ln(n)
nlog(2)=log(2^n )
(log(2))^n≈(0.3)^n
1/n=n^(-1)

What do you think ?

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1  
4^(log(n)) is n^(log(4)) which would be n^2 if your log is base 2, but how did you get 4*log(n) equal to those?! Also, if your log is base 2, then log(2) would be 1, so log(2)^n would be simply 1. –  Shahbaz Mar 27 '12 at 17:14
    
Thanks a lot !!! –  ron Mar 27 '12 at 17:29

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