I'm assuming you mean `O((n^2) * log n)`

, but the answer is the same and what you need to prove is basically the same if it's `n^(2 * log n)`

. I will also only consider non-negative functions, to save some messing about with absolute values.

The answer is that `O(n^2)`

is a strict subset of `O((n^2) * log n)`

. It is smaller.

First prove it's a subset: Suppose `f`

is `O(n^2)`

. Then there exist `M`

and `k`

such that for all `n >= M`

, `f(n) <= k(n^2)`

.

Let `L = max(M, e)`

(where e is the logarithmic base). Then for all `n >= L`

, `log(n) >= log(e) == 1`

(since `n >= 1`

) and `f(n) <= k(n^2)`

(since `n >= M`

).

Hence for all `n >= L`

, `f(n) <= k(n^2) * log(n)`

. So `f`

is in `O((n^2) * log n)`

.

Second, prove it's a strict subset: let `g`

be the function `g(n) = (n^2) * log n`

, so `g`

is in `O((n^2) * log n)`

.

For any `k`

, take `L = e^k`

. Then for any `n > L`

, `log(n) > k`

and so `g(n) > n^2 * k`

.

Hence `g`

is not in `O(n^2)`

, since there cannot exist `M`

and `k`

such that for all `n >= M`

, `g(n) <= k * n^2`

.