My solution for the third loop is

```
t(n) = [ (n-1)*n + ((n-1)*n)/2 ] *D + [ n^2 +n ] *D + [ 2n ]*I
```

so it is in `O(n^2)`

given that `doSomething()`

has a constant time
and that `i`

and `j`

are integers.

The second term ( `[ n^2 +n ] *D`

) is fairly easy.

The loop

```
for (j = n; j < 2 * n; j ++ ) doSomething();
```

gets called while `i <= n`

so it will be called `n+1`

times, since it starts from 0.

The loop `for (j = n; j < 2 * n; j ++ )`

calls `doSomething()`

`n`

times, so we have `(n+1)*n*D = [n^2+n] *D`

. I assume that `doSomething()`

has a constant time which is equal to `D`

The first term is a little bit more complex.

```
for (j = i; j < 2 * i; j ++ ) doSomething();
```

gets called when `i>n`

so it will be called `n-1`

times.
The loop calls `doSomething()`

i times.
The first time it gets called `n+1`

, the second time ´n+2´ and so on until it is `2n-1`

which is equal to `n + (n-1)`

.
So we get a sequence likes this `{n+1, n+2, n+3, ... , n+(n-1)}`

.

If we sum up the sequence we get `n-1`

times `n`

and the sum `1+2+3+...+ (n-1)`

.
The last term can be solved with the "Gaußsche Summenformel" (sorry I don't have the English name for it but you can see the formula in the German wiki link) so it is equal to `((n-1)*n)/2`

So the first term is `(n-1) * n + ((n-1)*n)/2 *D`

And the last term is therefor the if statement which is called `2*n*I`

, where `I`

is the time to execute the If statement.

`for (0 to 199) { for (0 to 200) { /* .. */ } }`

, but.. well nahh – Niklas R Jan 8 '13 at 12:51`n`

to be`200`

. – Niklas R Jan 8 '13 at 13:06