# O-notation and some math

Just started learning algorithms. So the exercise is to find if statement is always/sometimes true or false. Em, where does my logic fails here?

``````f(n) != O(g(n)) and g(n) != O(f(n))
``````

O-notation is `0 <= f(n) <= cg(n)` where `c` is some constant. So not equal here means:

``````f(n) > cg(n) and g(n) > cf(n)
``````

If `f(n) = g(n) = 1`, and let's say `c = 1/2`:

``````1 > (1/2)*1 and 1 > (1/2)*1
``````

So it is true in this case. But the book says it's false in this particular case. What part do I misunderstand?

-
I am not seeing the link between Big-O notation and trying to prove if a statement is always/sometimes true or false. Can you provide a little more information? –  Hunter McMillen Jun 21 '12 at 2:55
@HunterMcMillen Uh, not sure what else can I provide. Seem enough for me. `f(n), g(n)` - linear functions, `O(f(n))` - Big-O notation. –  Ruslan Osipov Jun 21 '12 at 3:02

Big-O is not `0 <= f(n) <= c g(n)` for some constant, per se. It's that there exists a number c such that the relation holds for "large enough" values of n. (This is the "asymptotic" that we refer to when we call Big-O an asymptotic notation, the other common ones being Big-Theta and Big-Omega.)
For example, let's say there's an algorithm that operates on some data structure with `n` elements, and takes `3n^2 + 7n + 18` steps. Call this `f(n)`. We say that the Big-O of this expression is `O(n^2)` because there exists a constant (in this case anything larger than 3) such that for all "large enough" values of `n`, `f(n) <= c n^2`.
Precisely. If there exist any positive constants `c` and `n0`. So in your example, 1/2 does not satisfy for `c`, but there exists another constant that would. –  Daniel Gallagher Jun 21 '12 at 3:03