Big O notation is about how algorithm characteristics (clock time taken, memory use, processing time) grow with the size of the problem.

Constant factors get discarded because they don't affect *how* the value scales.

Minor terms also get discarded because they end up having next to no effect.

So your original equation

```
sqrt(31n + 12nlogn + 57)
```

immediately simplifies to

```
sqrt(n log n)
```

Square roots distribute, like other kinds of multiplication and division, so this can be straightforwardedly converted to:

```
sqrt(n) sqrt(log n)
```

Since logs convert multiplication into addition (this is why slide rules work), this becomes:

```
sqrt(n) log (n/2)
```

Again, we discard constants, because we're interested in the class of behaviour

```
sqrt(n) log n
```

And, we have the answer.

**Update**

As has been correctly pointed out,

```
sqrt(n) sqrt(log n)
```

does not become

```
sqrt(n) log (n/2)
```

So the end of my derivation is wrong.