# How calculate Big Oh notation

Please can someone tell me how `2n = O(3n)` is calculated?

Here's some other examples:

`2^4 = O(1)`
`10n = O(n)`
`n log2(n) = O(n log n)`

-
This question doesn't make much sense. Please could you elaborate. –  David Heffernan Jan 30 '12 at 19:30
n log^2(n) = O(n log n) is wrong. Do you mean n log_2(n)? –  KennyTM Jan 30 '12 at 19:31
Are you sure that `n log^2(n) = O(n log n)` is really truth? I think it is not. –  Gaim Jan 30 '12 at 19:31
@Gaim: You inserted a `^` where there was not one. That notation means base-2 `log`. –  Jason Jan 30 '12 at 19:35

There is a rigorous mathematical definition of big-O:

f(x) is O(g(x)) if there exist values x0 >= 0 and k > 0 such that for all x > x0, f(x) <= k*g(x).

To prove statements about the big-O classification of functions, you must show how to find the x0 and k values.

-
+1 for giving a correct answer. Knowing the definition is the first step to answering a question like this. –  Patrick87 Jan 30 '12 at 19:50
``````2^4 = 2^4 * 1 <= 2^4 * 1
``````

so `2^4` is `O(1)` with constant `2^4`.

``````10 * n = 10 * n <= 10 * n
``````

so `10 * n` is `O(n)` with constant `10`.

``````n log2 n = n log n / log 2 <= (1 / log 2) * n log n
``````

so `n log2 n` is `O(n log n)` with constant `1 / log 2`.

-

Generally speaking, use the definition of the asymptotic notation, then produce a proof that f(n) = O(g(n)), where f(n) is your function and g(n) is the bound you are trying to prove.

``````2n =? O(3n)
f(n) = 2n, g(n) = 3n
need c such that for n > n0, f(n) <= c*g(n); guess c = 1
We have f(n) = 2n <= 3n = c*g(n) for n >= 0, so
2n = f(n) = O(g(n)) = O(3n)
``````

``````2^4 =? O(1)?
f(n) = 2^4, g(n) = 1
need c such that for n > n0, f(n) <= c*g(n); guess c = 2^4 + 1
We have f(n) = 2^4 <= 2^4 + 1 = c*g(n), so
2^4 = f(n) = O(g(n)) = O(1)
``````

Your third example is practically equivalent to the first.

Your fourth example is wrong; it is false that

``````n log^2(n) = O(n log n)
``````

It is true that

``````n log(n^2) = O(n log n)
``````

But that's a different expression. To see that n log^2(n) is not O(n log n), we can argue thusly: let c be an arbitary fixed constant. We can find an n such that c*n*log(n) < n*log^2(n). We get

``````c*n*log(n) < n*log^2(n)
c < log(n)
``````

So choose n = 2^(c+1). Therefore, there is no n0 such that, for n > n0, f(n) <= c*g(n).

EDIT: In the fourth example, if you mean by "log2(n)" the log-base-two of n, then yes, nlog2(n) = O(nlogn). Typically, in doing algorithmic complexities, the logarithm is understood to be to base two, unless otherwise specified. Sorry for the confusion.

-

There are multiple ways of proving this:

One could be the use of the limit:

f(n) = O(g(n)) iff the following holds:

``````                f(n)
limsup    ----------  < infinity
x->infinity     g(n)
``````

So, if you take `2n/(3n)` in the limit, this is `1.5`.

-
Cool ascii art which remembers me that tomorrow I've got a test about it, -1 (just kidding ;) ) –  BlackBear Jan 30 '12 at 19:45
-1. Not a bad answer, but I will point out that this is less complete than the other up-voted answers. For instance, this technique cannot classify f(n) = n*cos(n) as O(n), nor can it classify f(n) for which no known closed-form expression exists. Acknowledge the limitations and I'll be happy to delete the comment and remove the downvote. –  Patrick87 Jan 30 '12 at 19:58
@Patrick87 I think it can classify f(n)=n*cos(n) in O(n), because `n*cos(n)/n=cos(n)<=1`, thus in `O(n)`. Moreover, things like these are rarely useful in the context of runtime analysis which is what I supposed the OP wants the O-notation use for. –  phimuemue Jan 30 '12 at 20:00
@phimuemue Well, at best, you would have to be giving a fairly non-intuitive interpretation to your method to argue that it says unambiguously that f(n) = n*cos(n) is O(n)... the limit isn't defined, at least not in the usual elementary sense. To make your post more palatable would basically be saying that f(n)/g(n) is bounded by a constant as n approaches infinity, which is equivalent to the definition of the big-Oh notation used in the other answers. Also, what about the point about closed-form expressions for f(n) and g(n)? –  Patrick87 Jan 30 '12 at 20:06