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The recurrence relation

T(n) = 2T(n/2) + n lg lg n

(where lg is logarithm to base 2) can be solved using the master theorem but I am not very sure about the answer. I have found my answer but am not mentioning it here in order to prevent information cascades. Please help me find the big O and Ω for above.

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I think it's better you do post your own thoughts, now it just looks like you've just posed your homework verbatim without doing anything yourself. Btw, what's nlglgn supposed to be? – Bart Kiers Jan 24 '11 at 13:27
And what @Bart mentions means "post not only the result, but also your reasoning". Don't be afraid to err, as that is much better than laziness, and also don't care about influencing others, as a lot of people here are champions influencing their bosses, and know that trade. – Dr. belisarius Jan 24 '11 at 13:45
At a guess, nlglgn is supposed to be n * log (log(n)) – borrible Jan 24 '11 at 13:51
@borrible, yes, you're most probably correct, but it doesn't hurt if the OP expresses him/herself more clearly. – Bart Kiers Jan 24 '11 at 14:06
Hi, Sorry for the ambiguity. lg n means the base is 2. Moreover, I got the following: big O (n^2) and omega is nlog(base10)n . – Programmer Jan 24 '11 at 14:11
up vote 2 down vote accepted

None of the 3 cases in the master theorem apply for

T(n)=2 T(n/2) + n log(log n)

(With arbitrary base, it doesn't really matter)

Case 1: f(n)=n log(log n) is 'bigger' than nlog2 2=n1

Case 2: f(n) does not fit n logk(n)

Case 3: f(n) is smaller than n1+e

U(n)=2 U(n/2) + n log n
L(n)=2 L(n/2) + n

You can show that: U(n) >= T(n) and L(n) <= T(n). So U gives a upper bound, and L a lower bound for T.

Applying the master theorem for U(n), gives

Case 2: f(n)=n log n=Θ(n1 log1 n) thus U(n)=Θ(n log2 n)

Applying the master theorem for L(n), gives

Case 2: f(n)=n =Θ(n1 log0 n) thus L(n)=Θ(n log n)

Because L(n)<=T(n)<=U(n) it follows that T(n)=O(n log2 n) and T(n)=Ω(n log n)

Also, note that O(log2n)=O((log n)/log 2)=O((log n) * c)=O(log n).

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