First let's understand what big O, big Theta and big Omega are. They are all sets of functions.

Big O is giving upper asymptotic bound, while big Omega is giving a lower bound. Big Theta gives both.

Everything that is `Ө(f(n))`

is also `O(f(n))`

, but not the other way around.

`T(n)`

is said to be in `Ө(f(n))`

if it is both in `O(f(n))`

and in `Omega(f(n))`

.

In sets terminology, `Ө(f(n))`

is the intersection of `O(f(n))`

and `Omega(f(n))`

For example, merge sort worst case is both `O(n*log(n))`

and `Omega(n*log(n))`

- and thus is also `Ө(n*log(n))`

, but it is also `O(n^2)`

, since `n^2`

is asymptotically "bigger" than it. However, it is **not** `Ө(n^2)`

, Since the algorithm is not `Omega(n^2)`

.

### A bit deeper mathematic explanation

`O(n)`

is asymptotic upper bound. If `T(n)`

is `O(f(n))`

, it means that from a certain `n0`

, there is a constant `C`

such that `T(n) <= C * f(n)`

. On the other hand, big-Omega says there is a constant `C2`

such that `T(n) >= C2 * f(n))`

).

### Do not confuse!

Not to be confused with worst, best and average cases analysis: all three (Omega, O, Theta) notation are **not** related to the best, worst and average cases analysis of algorithms. Each one of these can be applied to each analysis.

**We usually use it to analyze complexity of algorithms** (like the merge sort example above). When we say "Algorithm A is `O(f(n))`

", what we really mean is "The algorithms complexity under the worst^{1} case analysis is `O(f(n))`

" - meaning - it scales "similar" (or formally, not worse than) the function `f(n)`

.

### Why we care for the asymptotic bound of an algorithm?

Well, there are many reasons for it, but I believe the most important of them are:

- It is much harder to determine the
*exact* complexity function, thus we "compromise" on the big-O/big-Theta notations, which are informative enough theoretically.
- The exact number of ops is also
*platform dependent*. For example, if we have a vector (list) of 16 numbers. How much ops will it take? The answer is: it depends. Some CPUs allow vector additions, while other don't, so the answer varies between different implementations and different machines, which is an undesired property. The big-O notation however is much more constant between machines and implementations.

To demonstrate this issue, have a look at the following graphs:

It is clear that `f(n) = 2*n`

is "worse" than `f(n) = n`

. But the difference is not quite as drastic as it is from the other function. We can see that `f(n)=logn`

quickly getting much lower than the other functions, and `f(n) = n^2`

is quickly getting much higher than the others.

So - because of the reasons above, we "ignore" the constant factors (2* in the graphs example), and take only the big-O notation.

In the above example, `f(n)=n, f(n)=2*n`

will both be in `O(n)`

and in `Omega(n)`

- and thus will also be in `Theta(n)`

.

On the other hand - `f(n)=logn`

will be in `O(n)`

(it is "better" than `f(n)=n`

), but will NOT be in `Omega(n)`

- and thus will also NOT be in `Theta(n)`

.

Symmetrically, `f(n)=n^2`

will be in `Omega(n)`

, but NOT in `O(n)`

, and thus - is also NOT `Theta(n)`

.

^{1}Usually, though not always. when the analysis class (worst, average and best) is missing, we really mean **the worst case.**