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
f3 a bit more closely:
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.
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
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