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# If not BigO, then BigOmega?

So if a function or running time is not BigO of f(n), can we say its BigOmega of f(n)?

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BigOmega is superlative: MegaO is sufficient, no need to make it bigger... (of course, this is a joke !) – Adrien Plisson Nov 3 '10 at 17:30
I think it depends on your function - do you know the Big-O of your function? – FrustratedWithFormsDesigner Nov 3 '10 at 17:30
you may be interrested in the wikipedia article regarding BigOmega – Adrien Plisson Nov 3 '10 at 17:33
@FrustratedWithFormsDesigner: if it depends on the function, then the answer to the question is "no". At least, I interpret the question to mean, "is it true that for any two functions f, g, either f is O(g) or f is Big-Omega(g)?" – Steve Jessop Nov 3 '10 at 17:35

No. For example the function

        / n^n if 2|n
f(n) = |
\ 0   otherwise


is neither in O(n) nor in Ω(n): for any values N and c there will always be a value n > N, such that f(n) > c*n (so it can't be in O(n)) and another value m > N such that f(m) < c*m (so it can't be in Ω(n)).

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Why the downvote? – sepp2k Nov 3 '10 at 17:37
@sepp2k: could be from one of the two(!) people who upvoted ybungalobill. – Steve Jessop Nov 3 '10 at 17:38
Great counterexample. – Mark Peters Nov 3 '10 at 17:49
To complete the example, you could still say that in this case f(n) is in O(n^n) and Ω(1), correct? (Or at least if the result on odd numbers was 1 instead of 0) – Mark Peters Nov 3 '10 at 17:53
@Mark: Yes, that is correct. – sepp2k Nov 3 '10 at 17:55

No, not necessarily.

As usual, with such theoretical topics you can consider some funny functions. Let's take a function g that returns the value 1/n for all odd inputs and for an even input n it returns n*n.

This function is not in BigO of f(n)=n (the identity function). This should be clear, as you get n*n results.

It is, however, also not in BigOmega of f(n)=n, because for very large numbers you are not guaranteed that g(n) >= k*f(n).

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Even if the functions are monotone increasing, i.e., n < m -> f(n) \leq f(m), then it's still not true that f(n) \neq O(g(n) implies f(n) = \Omega(g(n)).

Consider for example f(n) = g(n)^2 for n even and g(n-1) for n odd, and g(n) = f(n)^2 for n odd and f(n-1) for n even, with f(0) = 2, g(0) = 2.

Both are monotone increasing, but neither is big-oh of the other (grow very fast).

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