# What is the difference between Θ(n) and O(n)?

Sometimes I see Θ(n) with the strange Θ symbol with something in the middle of it, and sometimes just O(n). Is it just laziness of typing because nobody knows how to type this symbol, or does it mean something different?

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It's not obvious, but this question is a duplicate of this one stackoverflow.com/questions/464078/… from yesterday. –  Bill the Lizard Jan 23 '09 at 0:03
However, this is a pet bug-bear of mine, and something people get wrong a lot! –  HenryR Jan 23 '09 at 10:14

### To explain it to your grandma:

If an algorithm is of Θ(g(n)), it means that the running time of the algorithm as n (input size) gets larger is proportional to g(n).

If an algorithm is of O(g(n)), it means that the running time of the algorithm as n gets larger is at most proportional to g(n).

Normally, even when people talk about O(g(n)) they actually mean Θ(g(n)) but technically, there is a difference.

### More technically:

O(n) represents upper bound. Θ(n) means tight bound. Ω(n) represents lower bound.

f(x) = Θ(g(x)) iff f(x) = O(g(x)) and f(x) = Ω(g(x))

For example, an upper bound for the naive recursive approach to compute Fibonacci sequence is:

Fib(x) = O(2n)

but the tight bound is

Fib(x) = Θ(Fn) where Fn is the Fibonacci sequence.

which is also a valid upper bound.

Basically when we say an algorithm is of O(n), it's also O(n2), O(n1000000), O(2n), ... but a Θ(n) algorithm is not Θ(n2).

In fact, since f(n) = Θ(g(n)) means for sufficiently large values of n, f(n) can be bound within c1g(n) and c2g(n) for some values of c1 and c2, i.e. the growth rate of f is asymptotically equal to g: g can be a lower bound and and an upper bound of f. This directly implies f can be a lower bound and an upper bound of g as well. Consequently,

f(x) = Θ(g(x)) iff g(x) = Θ(f(x))

Similarly, to show f(n) = Θ(g(n)), it's enough to show g is an upper bound of f (i.e. f(n) = O(g(n))) and f is a lower bound of g (i.e. f(n) = Ω(g(n)) which is the exact same thing as g(n) = O(f(n))). Concisely,

f(x) = Θ(g(x)) iff f(x) = O(g(x)) and g(x) = O(f(x))

There are also small-oh and small-omega (`ω`) notations representing loose upper and loose lower bounds of a function.

To summarize:

`f(x) = O(g(x))` (big-oh) means that the growth rate of `f(x)` is asymptotically less than or equal to to the growth rate of `g(x)`.

`f(x) = Ω(g(x))` (big-omega) means that the growth rate of `f(x)` is asymptotically greater than or equal to the growth rate of `g(x)`

`f(x) = o(g(x))` (small-oh) means that the growth rate of `f(x)` is asymptotically less than the growth rate of `g(x)`.

`f(x) = ω(g(x))` (small-omega) means that the growth rate of `f(x)` is asymptotically greater than the growth rate of `g(x)`

`f(x) = Θ(g(x))` (theta) means that the growth rate of `f(x)` is asymptotically equal to the growth rate of `g(x)`

For a more detailed discussion, you can read the definition on Wikipedia or consult a classic textbook like Introduction to Algorithms by Cormen et al.

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A little more information about the difference between the two would be useful –  Simucal Jan 22 '09 at 23:01
I'm impressed. Your answer is simple, clear, concise, thorough, …and completely incomprehensible (to me). :-) –  Ben Blank Jan 22 '09 at 23:31
Ben, you mean I should delete it or shouldn't ever try to teach anybody? lol –  Mehrdad Afshari Jan 22 '09 at 23:33
No, don't. It's very good. –  duffymo Jan 22 '09 at 23:40
You have very high thoughts of my grandmother, I'm sure she would have approved of you. –  unwind Jan 23 '09 at 8:17

There's a simple way (a trick, I guess) to remember which notation means what.

All of the Big-O notations can be considered to have a bar.

When looking at a Ω, the bar is at the bottom, so it is an (asymptotic) lower bound.

When looking at a Θ, the bar is obviously in the middle. So it is an (asymptotic) tight bound.

When handwriting O, you usually finish at the top, and draw a squiggle. Therefore O(n) is the upper bound of the function. To be fair, this one doesn't work with most fonts, but it is the original justification of the names.

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Could not thank you enough for that excellent method to visualize and remember which is which among the bounds! :-) –  Ashwin Nov 18 '11 at 3:09
Nice memory trick. Thank you. –  Li-aung Yip Jun 23 '12 at 5:54
its a great trick ..Thanks –  aditya Nov 30 '12 at 8:04
you have a visual mind andrei. –  ehsan Feb 6 at 21:28
Nailed It !! :) –  Yash Sharma Feb 21 at 19:51

one is Big "O"

one is Big Theta

http://en.wikipedia.org/wiki/Big_O_notation

Big O means your algorithm will execute in no more steps than in given expression(n^2)

Big Omega means your algorithm will execute in no fewer steps than in the given expression(n^2)

When both condition are true for the same expression, you can use the big theta notation....

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This actually makes sense to me. –  MattBelanger Jan 23 '09 at 0:58
But is wrong! The number of steps is bounded above by n^2 as n gets very large. However, an algorithm that runs in n^2 + c steps takes more than n^2 steps, but is still O(n^2). Big-O notation only describes asymptotic beahviour. –  HenryR Jan 23 '09 at 10:09
This is not a end all be all definition. It's just a launching point.... Since we are talking about asymptotic notations as n approaches infinity. The constant C becomes a non factor. –  l_39217_l Jan 23 '09 at 17:13

Rather than provide a theoretical definition, which are beautifully summarized here already, I'll give a simple example:

Assume the run time of `f(i)` is `O(1)`. Below is a code fragment whose asymptotic runtime is `Θ(n)`. It always calls the function `f(...)` `n` times. Both the lower and the upper bound is n.

``````for(int i=0; i<n; i++){
f(i);
}
``````

The second code fragment below has the asymptotic runtime of `O(n)`. It calls the function `f(...)` at most `n` times. The upper bound is n, but the lower bound could be `Ω(1)` or `Ω(log(n))`, depending on what happens inside `f2(n)`.

``````for(int i=0; i<n; i++){
if( f2(i) ) break;
f(i);
}
``````
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`f(n)` belongs to `O(n)` if exists positive `k` as `f(n)<=k*n`

`f(n)` belongs to `Θ(n)` if exists positive `k1`, `k2` as `k1*n<=f(n)<=k2*n`

Wikipedia article on Big O Notation

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You missed a crucial point - these are true only for all n > n1, i.e. asymptotically. –  HenryR Jan 23 '09 at 10:11

## protected by WillSep 29 '10 at 11:40

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