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:
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
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^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 :-)