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I am having a hard time proving that n^k is O(2^n) for all k. I tried taking lg2 of both sides and have k*lgn=n, but this is wrong. I am not sure how else I can prove this.

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closed as off topic by Joe, Randy, Kirk Broadhurst, jeffamaphone, Graviton Sep 20 '11 at 7:53

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Can you give us a few more details? First, I assume you're talking about computing n^k. What's your level of abstraction for the operations? Number of multiplications? Number of additions? –  J Trana Sep 20 '11 at 1:59
    
There aren't any levels of abstraction - this is for algorithm efficiency proof. I need to prove that 'n' to the power of 'k' will always be O(2^n) - big O notation. –  user629034 Sep 20 '11 at 2:06
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Migrate to math.SE or cstheory.SE? –  Sicarius Noctis Sep 20 '11 at 2:39
    
Expressions don't have complexity - only algorithms or functions. Anyway, this is off topic for stackoverflow. –  Kirk Broadhurst Sep 20 '11 at 3:10
    
And in any case not true for k = 0,1. –  Keith Sep 20 '11 at 3:12

2 Answers 2

I can't comment yet, so I will make this an answer.

Instead of reducing the equation like you have been trying to do, you should try to find an n0 and a M that satisfy the formal definition of big O notation found here: http://en.wikipedia.org/wiki/Big_O_notation#Formal_definition

Something along the lines of n0=M=k might work (I haven't written it out so maybe that doesn't work, thats just to give you an idea)

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To show that nk is O(2n), note that

nk = (2lg n)k = 2k lg n

So now you want to find an n0 and c such that for all n ≥ n0,

2k lg n ≤ c 2n

Now, let's let c = 1 and then consider what happens when n = 2m for some m. If we do this, we get

2k lg n ≤ c 2n = 2n

2k lg 2m ≤ 22m

2km ≤ 22m

And, since 2n is a monotonically-increasing function, this is equivalent to

km ≤ 2m

Now, let's finish things off. Let's suppose that we let m = max{k, 4}, so k ≤ m. Thus we have that

km ≤ m2

We also have that

m2 ≤ 2m

Since for any m ≥ 4, m2 ≤ 2m, and we've ensured by our choice of m that m = max{k, 4}. Combining this, we get that

km ≤ 2m

Which is equivalent to what we wanted to show above. Consequently, if we pick any n ≥ 2m = 2max{4, k}, it will be true that nk ≤ 2n. Thus by the formal definition of big-O notation, we get that nk = O(2n).

I think this math is right; please let me know if I'm wrong!

Hope this helps!

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Thanks.But will this work for any k? In case of km<=m^2 - is this for any k? –  user629034 Sep 20 '11 at 4:19
    
@user629034- Yes, this works for any k. The idea is to pick the value of m (and thus of n0) based on the value of k that's picked. –  templatetypedef Sep 20 '11 at 4:36

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