`O((n^3)/4)`

makes no sense in terms of big-O notation since it's meant to measure the complexity as a ratio of the argument. Dividing by 4 has no effect since that changes the value of the ratio but not its nature.

All of these are equivalent:

```
O(n^3)
O(n^3/4)
O(n^3*1e6)
```

Other terms only make sense when they include an `n`

term, such as:

```
O(n^3 / log(n))
O(n^3 * 10^n)
```

As Anthony Kanago rightly points out, it's convention to:

- only keep the term with the highest growth rate for sums:
`O(n^2+n) = O(n^2)`

.
- get rid of constants for products:
`O(n^2/4) = O(n^2)`

.

As an aside, I don't always agree with that first rule in all cases. It's a good rule for deciding the maximal growth rate of a function but, for things like algorithm comparison^{(a)} where you can intelligently put a limit on the input parameter, something like `O(n^4+n^3+n^2+n)`

is markedly worse than just `O(n^4)`

.

In that case, *any* term that depends on the input parameter should be included. In fact, even constant terms may be useful there. Compare for example `O(n+1e100)`

against `O(n^2)`

- the latter will outperform the former for quite a while, until `n`

becomes large enough to have an effect on the constatnt term.

^{(a)} There are, of course, those who would say it shouldn't be used in such a way but pragmatism often overcomes dogmatism in the real world :-)