Big O is giving only upper asymptotic bound, while big Theta is also giving a lower bound.
Everything that is
Theta(f(n)) is also
O(f(n)), but not the other way around.
T(n) is said to be
Theta(f(n)), if it is both
For this reason big-Theta is more informative then big-O notation, so if we can say something is big-Theta, it's usually preferred. However, it is harder to prove something is big Theta, than to prove it is big-O.
For example, merge sort is both
Theta(n*log(n)), but it is also O(n2), since n2 is asymptotically "bigger" than it. However, it is NOT Theta(n2), Since the algorithm is NOT Omega(n2).
Omega(n) is asymptotic lower bound. If
Omega(f(n)), it means that from a certain
n0, there is a constant
C1 such that
T(n) >= C1 * f(n). Whereas big-O says there is a constant
C2 such that
T(n) <= C2 * f(n)).
All three (Omega, O, Theta) give only asymptotic information ("for large input"):
- Big O gives upper bound
- Big Omega gives lower bound and
- Big Theta gives both lower and upper bounds
Note that this notation is not related to the best, worst and average cases analysis of algorithms. Each one of these can be applied to each analysis.