# If f(n) = O(g(n)) , then is exp(f(n)) = O(exp(g(n)))

can someone help me with the above. Please give example. Also, if you use l'Hôpital's rule, please show how you do differentiation.

Thanks folks

-
If you're Googling then you might want to get the spelling right for l'Hôpital's rule, e.g. en.wikipedia.org/wiki/L'Hôpital's_rule –  Paul R Mar 8 '11 at 17:08
Doesn't this question belong in math? –  Zeta Two Mar 8 '11 at 17:21
math.stackexchange.com –  Jacob Mar 8 '11 at 17:44
@Zeta, I don't think so, it's firmly in CS. –  ThomasMcLeod Mar 9 '11 at 4:15

This statement is wrong, for example 2n = O(n), but exp(2n) != O(exp(n)). (The latter would mean exp(2n) <= C exp(n) for sufficiently large n, i.e. exp(n) <= C which is not true.)

-
+1 for being faster than I. (Good example btw :) ) –  phimuemue Mar 8 '11 at 17:20
This is indeed a common pitfall of asymptotic analysis. Passing to the logarithm (or any function whose derivative is bounded at infinity) preserves big O though. –  Alexandre C. Mar 8 '11 at 17:20
@Alexandre: no it doesn't. $log(n^3) \in O(log(n^2))$. Also note that $3^n \notin O(2^n)$. Using a logarithm sorts your functions into two basic complexity classes: polynomial time (logarithms of all of the polynomials are all in the same big-O class), and exponential time (logarithms of all of the exponentials are all in the same big-O class). –  Ken Bloom Mar 8 '11 at 19:48
@Ken: oops... Okay, it works with equivalents: f ~ g => log f ~ log g hence my confusion! –  Alexandre C. Mar 8 '11 at 21:13

The claim is not correct.

A conterexample is the following: We have no doubt that 2n is element of O(n). But, we can prove that exp(2n) is not an element of O(exp(n)). This can be easily seen by computing the

                 exp(2n)
lim        -------- = infinity
n -> infinity     exp(n)


which implies that exp(2n) is not in O(exp(n)).

Considering your hint about L'Hospital: It is a rule for computing limits using derivatives, more precisely:

                f(x)                       f'(x)
lim       ------  =        lim     -----------
n -> infinity   g(x)      n -> infinity    g'(x)


under certain circumstances (e.g. both f and g tend towards infinity. I do not know the exact criteria to be fulfilled, so I just suggest reading this for more information.

But, what we can say about functions and their derivatives is the following:

If f'(x) is element of O(g'(x)), then we have that f(x) is element of O(g(x)). The other direction is not the case.

-
thank you, this has been most helpful :) –  stupid_idiot Aug 25 '12 at 19:09

\$\lim_{x \to a}{f(x)\over g(x)}=\lim_{x \to a}{f'(a) \over g'(a)}

We use that in order to solve inf/inf or 0/0 indetermination. But your problem is not that I think, but maybe when you try to derive the O(g(n)) or exp(f(n)) which are composite functions.

The chain rule to derive composite functions is this: (f o g)(x) = f'(g(x)).g'(x)

if you follow that, you can derive any composite function.

-