Patrick87's answer explains a little more about the asymptotic nature of Big-O notation. I will show you a bit more analysis of this. Let's examine `f2`

and `f3`

a bit more closely:

First, `f2(n)`

: We know that `f2(n) = O(2n + 20)`

. The 20 is a constant, so we can ignore it. So, `f2(n) = O(2n + 20) = O(2n)`

. Again, the 2 is a constant, so we can also ignore it, so: `f2(n) = O(2n + 20) = O(2n) = O(n)`

.

What this analysis means is that as `n`

increases, a function that is `2n + 20`

grows as fast as a function that is `2n`

, which grows as fast as a function that is `n`

. This makes sense if you think about it: all these functions are parallel lines. Their rate of growth is the same.

Now `f3(n)`

: We know that `f3(n) = O(n + 1)`

. The 1 is a constant, so we can ignore it. So, `f3(n) = O(n)`

.

And that is why `f3`

and `f2`

are both `O(n)`

. This doesn't mean that these functions take the *exact same time* for a given value of `n`

, or that `f2`

is as fast as `f3`

in clock time. It just means that the *complexity* (i.e. the time they take to do work) of both functions increases at the same *rate* as `n`

increases.