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 n^{log2 2}=n^{1}

Case 2: f(n) does not fit n log^{k}(n)

Case 3: f(n) is smaller than n^{1+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(n^{1} log^{1} n) thus U(n)=Θ(n log^{2} n)

Applying the master theorem for L(n), gives

Case 2: f(n)=n =Θ(n^{1} log^{0} n) thus L(n)=Θ(n log n)

Because `L(n)<=T(n)<=U(n)`

it follows that T(n)=O(n log^{2} n) and T(n)=Ω(n log n)

Also, note that O(log_{2}n)=O((log n)/log 2)=O((log n) * c)=O(log n).

dopost 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