Big-O, Big-Θ, Big-Ω are independent from worst-case, average-case, and best-case.

The notation f(n) = O(g(n)) means f(n) grows *no more quickly than some constant multiple of g(n)*.

The notation f(n) = Ω(g(n)) means f(n) grows *no more slowly than some constant multiple of g(n)*.

The notation f(n) = Θ(g(n)) means both of the above are true.

Note that f(n) here may represent the best-case, worst-case, or "average"-case running time of a program with input size n.

Furthermore, "average" can have many meanings: it can mean the *average input* or the *average input size* ("expected" time), or it can mean *in the long run* (amortized time), or both, or something else.

Often, people are interested in the *worst-case* running time of a program, *amortized over the running time of the entire program* (so if something costs *n* initially but only costs 1 time for the next *n* elements, it averages out to a cost of 2 per element). The most useful thing to measure here is the *least upper bound* on the worst-case time; so, typically, when you see someone asking for the Big-O of a program, this is what they're looking for.

Similarly, to prove a problem is inherently difficult, people might try to show that the *worst-case* (or perhaps average-case) running time is *at least* a certain amount (for example, exponential).

You'd use Big-Ω notation for these, because you're looking for lower bounds on these.

However, there is no special relationship between worst-case and Big-O, or best-case and Big-Ω.

Both can be used for either, it's just that one of them is more typical than the other.

So, upper-bounding the *best* case isn't terribly useful. Yes, if the algorithm *always* takes O(n) time, then you can say it's O(n) in the best case, as well as on average, as well as the worst case. That's a perfectly fine statement, except *the best case* is usually very trivial and hence not interesting in itself.

Furthermore, note that f(n) = n = O(n^{2}) -- this is technically correct, because f grows more slowly than n^{2}, but it is *not useful* because it is not the *least* upper bound -- there's a very obvious upper bound that's more useful than this one, namely O(n). So yes, you're perfectly welcome to say the best/worst/average-case running time of a program is O(n!). That's mathematically perfectly correct. It's just useless, because when people ask for Big-O they're interested in the *least* upper bound, not just a random upper bound.

It's also worth noting that *it may simply be insufficient* to describe the running-time of a program as f(n). *The running time often depends on the input itself, not just its size*. For example, it may be that *even* queries are trivially easy to answer, whereas *odd* queries take a long time to answer.

In that case, you can't just give *f* as a function of *n* -- it would depend on other variables as well. In the end, remember that this is just a set of mathematical tools; it's your job to figure out how to apply it to your program and to figure out *what's an interesting thing to measure*. Using tools in a useful manner needs some creativity, and math is no exception.

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curves. Extend it out to about x=1000 for a better view... – twalberg Jan 20 at 21:53functions.Youget to decide what function you're describing: worst case, average case, amortized, etc. and also of what: comparisons, run time on a specific machcine model (real RAM, etc.), storage space. It's all about assumptions and definitions. Lot's of material on the web omits these, which is no doubt what's causing your confusion. – Gene Jan 20 at 22:37