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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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 Something along the lines of 


To show that n^{k} is O(2^{n}), note that
So now you want to find an n_{0} and c such that for all n ≥ n_{0},
Now, let's let c = 1 and then consider what happens when n = 2^{m} for some m. If we do this, we get
And, since 2^{n} is a monotonicallyincreasing function, this is equivalent to
Now, let's finish things off. Let's suppose that we let m = max{k, 4}, so k ≤ m. Thus we have that
We also have that
Since for any m ≥ 4, m^{2} ≤ 2^{m}, and we've ensured by our choice of m that m = max{k, 4}. Combining this, we get that
Which is equivalent to what we wanted to show above. Consequently, if we pick any n ≥ 2^{m} = 2^{max{4, k}}, it will be true that n^{k} ≤ 2^{n}. Thus by the formal definition of bigO notation, we get that n^{k} = O(2^{n}). I think this math is right; please let me know if I'm wrong! Hope this helps! 


k = 0,1
. – Keith Sep 20 '11 at 3:12