# Prove for any a > b >0, b^n in Big-O a^n

Prove that for any real numbers, a, b such that a > b > 0, b^n is O(a^n), n >=1.

I have searched several textbooks I own on Discrete Mathematics as well as several online searches for any examples that are similar or theorems that related to this proof. I am not looking for a direct solution, but perhaps being shown the right methods or paradigms to solve the proof.

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Homework? If so, thats fine, but please properly tag. – Richard J. Ross III Jan 15 '12 at 18:49
I might be wrong, but doesn't this belong on the math stack exchange site? – Josh Sherick Jan 15 '12 at 21:02
Wow nevermind I'm an idiot – Josh Sherick Jan 15 '12 at 21:03
@Isthan -- actually, you use `ABS(b) / ABS(a) <= M` to choose M...so for x_0 = 1, `M = ABS(b) / ABS(a)`...now all you have to do is show that `b^x / a^x < 1 for all x > x_0` ...effectively you have to provide reasoning why `(b/a)^x is monotonically decreasing`... – Skyrim Jan 15 '12 at 23:44

If you mean

``````Prove that for any real numbers, a, b such that a > b > 0, b^n is O(a^n)
``````

Then, think about the definition of `O(a^n)`

From wiki,

``````1) For f(x), g(x) defined on a subset of reals
2) if there exists some positive **constant** M and real number x_0, such that
3) if ABS(f(x)) <= M * ABS(g(x)) for all x > x_0
``````

In this case `f(x) = b^x` and `g(x) = a^x`. I'm going to treat this question as if it's a homework question, even though it isn't tagged as one...please correct me if I'm wrong!

Consider plugging the funciton into the steps (especially 3) and see if you can figure out any x_0, M pair for which it is true. Good luck!

EDIT I changed `f(x) = b^n` and `g(x) = a^n` to `f(x) = b^x` and `g(x) = a^x`

EDIT - HINT

Step 3) can be interpreted as:

``````ABS(f(x)) / ABS(g(x)) <= M for all x > x_0
``````

Choose your favorite constant `M` and then see if you can find some `x_0` which works `for all x`.

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@Isthan -- I have edited the post so that `n` becomes `x` when plugged into `f(x),g(x)` – Skyrim Jan 15 '12 at 19:42