`T(n) = O(nlogn)`

and `W(nlogn)`

To prove that, by definition of `O`

, we need to find constants `n0`

and `c`

such that:
for every `n>=n0`

, `T(n)<=cnlogn`

.

We will use induction on `n`

to prove that `T(n)<=cnlogn`

for all `n>=n0`

Let's skip the base case for now... (we'll return later)

Hipothesis: We assume that for every `k<n`

, `T(k)<=cklogk`

Thesis: We want to prove that `T(n)<=cnlogn`

But, `T(n)=2T(n/4)+T(n/2)+n`

Using the hipothesis we get:

`T(n)<=2(c(n/4)log(n/4))+c(n/2)log(n/2)+n=cnlogn + n(1-3c/2)`

So, taking `c>=2/3`

would prove our thesis, because then `T(n)<=cnlogn`

Now we need to prove the base case:

We will take `n0=2`

because if we take `n0=1`

, the `logn`

would be `0`

and that wouldn't work with our thesis. So our base cases would be `n=2,3,4`

. We need the following propositions to be true:

`T(2) <= 2clog2`

`T(3) <= 3clog3`

`T(4) <= 4clog4`

So, by taking `c=max{2/3, T(2)/2, T(3)/3log3, T(4)/8}`

and `n0=2`

, we would be finding constants `c`

and `n0`

such that for every natural `n>=n0`

, `T(n)<=cnlogn`

The demonstration for `T(n) = W(nlogn)`

is analog.

So basically, in these cases where you can't use the Masther Theorem, you need to 'guess' the result and prove it by induction.

For more information on these kind of demonstrations, refer to 'Introduction to Algorithms'