For those who want to know the details or need some help with this, I'm going expand on Recurse's answer and follow-up comment

- We only need
`k-1`

merges because the last array is not merged with anything
- The formula for summing the terms of an arithmetic sequence is helpful;
`Sn=n(a1 + an)2`

Stepping through the first 4 merges of `k`

arrays with `n`

elements

```
+-------+-------------------+-------------+
| Merge | Size of new array | Note |
+-------+-------------------+-------------+
| 1 | n+n = 2n | first merge |
| 2 | 2n+n = 3n | |
| 3 | 3n+n = 4n | |
| 4 | 4n+n = 5n | |
| k-1 | (k-1)n+n = kn | last merge |
+-------+-------------------+-------------+
```

To find the average size, we need to sum all the sizes and divide by the number of merges (`k-1`

). Using the formula for summing the first `n`

terms, `Sn=n(a1 + an)2`

, we only need the **first** and **last** terms:

**a1**=`2n`

(first term)
**an**=`kn`

(last term)

We want to sum all the terms so `n=k-1`

(the number of terms we have). Plugging in the numbers we get a formula for the sum of all terms

`Sn = ( (k-1)(2n+kn) )/2`

However, to find the *average* size we must divide by the number of terms (`k-1`

). This cancels out the `k-1`

in the numerator and we're left with an average of size of

`(2n + kn)/2`

Now we have the average size, we can multiply it by the number of merges, which is `k-1`

. To make the multiplication easier, ignore the `/2`

, and just multiply the numerators:

```
(k-1)(2n+kn)
= (k^2)n + kn - 2n
```

At this point you could reintroduce the `/2`

, but there shouldn't be any need since it's clear the dominant term is `(k^2)*n`