O, Θ and Ω do not represent worst, average and best case ; although they have a similar meaning.

Big-O notation f(n) = O(g(n)) means f grows slower than g for large values of n ("n > n_{0}" means "for large values of n" in this context). This does not mean that g is the worst case: g could be worse than the worst case (quick sort is *also* O(n!) for instance). For the more complicated algorithms, there is ongoing research to determine the smallest Big-O for their actual complexity: the original author mostly finds a Big-O upper-bound.

Ω notation means the reverse (f grows faster than g), which means it could be better than the best case (all algorithms are Ω(1) for instance).

There are many algorithms for which there is no single function g such that the complexity is both O(g) and Ω(g). For instance, insertion sort has a Big-O lower bound of O(n²) (meaning you can't find anything smaller than n²) and an Ω upper bound of Ω(n).

Other algorithms do: merge sort is both O(n log n) and Ω(n log n). When this happens, it is written as Θ(n log n), which means that not all algorithms have a Θ-notation complexity (and notably, algorithms with worst cases or best cases do not have one).

To get rid of worst cases that carry a very low probability, it's fairly common to examine average-case complexity - replacing the standard "f" value on the left-hand side by a different function "f_{avg}" that only takes into account the most probable outcomes. So, for quick sort, f = O(n²) is the best you can get, but f_{avg} = O(n log n).