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`

.

`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