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I am currently studying for my final in algorithms. This is not a homework problem and comes from an old final exam.

Show that f(n) = 4logn + log log n is big theta of logn. 

It is obvious that log log n is considerably smaller than log n and thus insignificant. But how can I show it formally? I'm familiar with limits and L'hopital so I would appreciate it if you can show me how to do it with that method.

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closed as off topic by luke, Raghunandan, Laurent Etiemble, Brett Hale, alroc Apr 12 '13 at 13:08

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I don't think de l'hopital helps, since (log n)' = 0. –  duedl0r Apr 12 '13 at 10:04
    
@duedl0r: unless I'm missing something, (log n)' = 1/n. –  blubb Apr 12 '13 at 10:24
    
@blubb I suppose a limit n -> +inf is implied, considering @duedl0r was talking about l'Hôpital's rule. –  Carsten Apr 12 '13 at 10:30
4  
@Carsten: In that case I was missing something, and my statement is trivially correct ;) –  blubb Apr 12 '13 at 10:32

2 Answers 2

up vote 6 down vote accepted

Remember the definition of big theta. A function f(x) is in Theta(g(x)) if requirement for big theta

You have f(x) = 4*log(x) + log(log(x)) and g(x) = log(x). Now we have to show that there are values for c_0, c_1 and x_0 that satisfy the condition.

If we take c_0 = 1 and x_0 large enough that log(log(x_0)) > 0 (the exact number depends on the base of your logarithm, but there is always such a number, and we don't really need to know it), then it's quite easy to show that the first inequality is true for all x > x_0: log(x) <= 4*log(x) + log(log(x)) (hint: log(log(x)) is already > 0 and the logarithm function is monotonically increasing.

Now let's choose c_1 = 5. The second inequality now becomes 4*log(x) + log(log(x)) <= 5*log(x), which simplifies to

log(log(x)) <= log(x)

for all x > x_0. I'll leave that proof to you as an exercise. :-)

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+1, even though using image hosting to get latex on SO is kind of cheating :P –  G. Bach Apr 12 '13 at 11:20
    
The information you provided here is great for refreshing my memory. Thank you for the detailed solution. One more question though, when you say c_1 = 5 (or whenever you choose the constant for solving the inequalities) is it done arbitrarily? –  TheSunken Apr 12 '13 at 23:09
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Yes, quite arbitrarily. You just have to show that one such number exists; technically, you don't even have to know it. I chose c_1 = 5 because you have 4log(x) in the function and it's quite easy to prove log(x) > log(log(x)). –  Carsten Apr 13 '13 at 8:34

Easy way of finding c1 , c2 and no.

Finding upper bound :

 f(n) = 4logn+loglogn


    For all sufficience value of n>=2

        4logn <= 4 logn   
        loglogn <= logn 

    Thus , 

     f(n) = 4logn+loglogn <= 4logn+logn
                          <= 5logn
                           = O(logn)       // where c1 can be 5 and n0 =2

Finding lower bound :

   f(n) = 4logn+loglogn

   For all sufficience value of n>=2

      f(n) = 4logn+loglogn >= logn
    Thus,              f(n) =  Ω(logn)   // where c2 can be 1 and n0=2


  so , 
                        f(n) = Ɵ(logn)     
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Why didn't I think of this before? That is a very simple solution. Thank you :) –  TheSunken Apr 12 '13 at 23:07

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