I am learning algorithm analysis. I am having trouble understanding the difference between O, Ω, and Θ.

The way they're defined is as follows:

`f(n) = O(g(n))`

means`c · g(n)`

is an upper bound on`f(n)`

. Thus there exists some constant`c`

such that`f(n)`

is always ≤`c · g(n)`

, for large enough`n`

(i.e.,`n ≥ n0`

for some constant`n0`

).`f(n) = Ω(g(n))`

means`c · g(n)`

is a lower bound on`f(n)`

. Thus there exists some constant`c`

such that`f(n)`

is always ≥`c · g(n)`

, for all`n ≥ n0`

.`f(n) = Θ(g(n))`

means`c1 · g(n)`

is an upper bound on`f(n)`

and`c2 · g(n)`

is a lower bound on`f(n)`

, for all`n ≥ n0`

. Thus there exist constants`c1`

and`c2`

such that`f(n) ≤ c1 ·g(n)`

and`f(n) ≥ c2 ·g(n)`

. This means that`g(n)`

provides a nice, tight bound on`f(n)`

.

The way I have understood this is:

`O(f(n))`

gives worst case complexity of given function/algorithm.`Ω(f(n))`

gives best case complexity of given function/algorithm.`Θ(f(n))`

gives average case complexity of given function/algorithm.

Please correct me if I am wrong. If it is the case, time complexity of each algorithm must be expressed in all three notations. But I observed that it's expressed as either O, Ω, or Θ; why not all three?