# Big Theta Notation - what exactly does big Theta represent?

I'm really confused about the differences between big O, big Omega, and big Theta notation. I understand that big O is the upper bound and big Omega is the lower bound, but what exactly does big Theta represent? I have read that it means "tight bound", but what does that mean?

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@dplanet: These notations are widely used to design an algorithum IN computer sciences that why, –  kTiwari Sep 9 '12 at 2:58

It means that the algorithm is both big-O and big-Omega in the given function. For example, if it is Theta(n), then there is some constant K such that your function (run-time, whatever), is larger than n*K for sufficiently large n, and some other constant k such that your function is smaller than n*k for sufficiently large n. In other words, for sufficiently large n, it is sandwiched between two linear functions.

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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 `Theta(f(n))` is also `O(f(n))`, but not the other way around.
`T(n)` is said to be in `Theta(f(n))` if it is both in `O(f(n))` and in `Omega(f(n))`.
In sets terminology - `Theta(f(n))` is the intersection of `O(f(n))` and `Omega(f(n))`

For example, merge sort worst case is both `O(nlogn)` and `Omega(nlogn)` - and thus is also `Theta(nlogn)`, but it is also `O(n^2)`, since `n^2` is asymptotically "bigger" than it. However, it is NOT `Theta(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)` (Where big-Omega says there is a constant `C2` such that `T(n) >= C2 * f(n))`).

Not to be confused with worst/best/average cases analysis: All three (Omega,O,Theta) notation are NOT related to the best/worst/average case 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 worst1 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:

1. 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.
2. 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 vercotr 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 "better" 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 then the other functions, and `f(n) = n^2` is quickly getting much higher then 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" then `f(n)=n`), but will NOT be in `Omega(n)` - and thus will also NOT be in `Theta(n)`.
Symetrically, `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/...) is missing, we really mean it is the worst case.

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+1 for the nice explanation, I have a confusion ,you have written in last line that ,, f(n)=n^2 will be in Omega(n). but not in O(n) .and thus is also not Theta(n) >how? –  kTiwari Sep 10 '12 at 4:24
@krishnaChandra: `f(n) = n^2` is asymptotically stronger then `n`, and thus is Omega(n). However it is not O(n) (because for large `n` values, it is bigger then `c*n`, for all `n`). Since we said Theta(n) is the intersection of O(n) and Omega(n), since it is not O(n), it cannot be Theta(n) as well. –  amit Sep 10 '12 at 5:04
Great answer! +1 –  Burhan Khalid Sep 22 '12 at 10:33
It's great to see someone explain how big-O notation isn't related to the best/worst case running time of an algorithm. There are so many websites that come up when I google the topic that say O(T(n)) means the worse case running time. –  Fractal Feb 21 '13 at 9:46
@almel It's 2*n (2n, two times n) not 2^n –  amit Sep 8 at 22:04

Theta(n): A function `f(n)` belongs to `Theta(g(n))`, if there exists positive constants `c1` and `c2` such that `f(n)` can be sandwiched between `c1(g(n))` and `c2(g(n))`. i.e it gives both upper and as well as lower bound.

Theta(g(n)) = { f(n) : there exists positive constants c1,c2 and n1 such that 0<=c1(g(n))<=f(n)<=c2(g(n)) for all n>=n1 }

when we say `f(n)=c2(g(n))` or `f(n)=c1(g(n))` it represents asymptotically tight bound.

O(n): It gives only upper bound (may or may not be tight)

O(g(n)) = { f(n) : there exists positive constants c and n1 such that 0<=f(n)<=cg(n) for all n>=n1}

ex: The bound `2*(n^2) = O(n^2)` is asymptotically tight, whereas the bound `2*n = O(n^2)` is not asymptotically tight.

o(n): It gives only upper bound (never a tight bound)

the notable difference between O(n) & o(n) is f(n) is less than cg(n) for all n>=n1 but not equal as in O(n).

ex: `2*n = o(n^2)`, but `2*(n^2) != o(n^2)`

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You didn't mention big Omega, which refers to the lower-bound. Otherwise, very nice first answer and welcome! –  bohney Oct 6 '12 at 17:01
i liked the way he framed the definition of Theta(n). Upvoted! –  Karan Oct 20 '13 at 14:48

I just wanna give you a first impression and some basic ideas. Then you should do more research on the internet or look for some Youtube video

For big-O-notation, you just need to remember there are two functions: f(x) and g(x) and f(x) is less than g(x) when x is super large. f(x) ∈ O(g(x))

For big-omega-notation, you just need to remember that there are two functions : f(x) and k(x) and when x is a super large number, f(x) is still large than k(x) f(x) ∈ Ω (k(x))

when you have the first impression about big-o-notation and big-omega-notation then you should do search on Youtube.

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