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2^n + 6n^2 + 3n

I guess it's just O(2^n), using the highest order term, but what is the formal approach to go about proving this?

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homework? ... – Mitch Wheat Sep 13 '09 at 8:01
I miss Discrete Mathematics. I failed it the first time. – David Andres Sep 13 '09 at 8:04
nah, not homework. Just confused about various methods to get mathematical proof. – Rao Sep 13 '09 at 8:28

2 Answers 2

up vote 4 down vote accepted

You can prove that 2^n + n^2 + n = O(2^n) by using limits at infinity. Specifically, f(n) is O(g(n)) if lim (n->inf.) f(n)/g(n) is finite.

lim (n->inf.) ((2^n + n^2 + n) / 2^n)

Since you have inf/inf, an indeterminate form, you can use L'Hopital's rule and differentiate the numerator and the denominator until you get something you can work with:

lim (n->inf.) ((ln(2)*2^n + 2n + 1) / (ln(2)*2^n))
lim (n->inf.) ((ln(2)*ln(2)*2^n + 2) / (ln(2)*ln(2)*2^n))
lim (n->inf.) ((ln(2)*ln(2)*ln(2)*2^n) / (ln(2)*ln(2)*ln(2)*2^n))

The limit is 1, so 2^n + n^2 + n is indeed O(2^n).

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Is this not for finding small-oh? x__x Also, is there an alternative method that, say, uses only inequalities? – Rao Sep 13 '09 at 8:39
Little o is different; that's where lim (n->inf.) f(n)/g(n) = 0, meaning g(n) grows faster than f(n) (e.g. n is o(n^2) since n^2 grows faster than n). You could use inequalities to show that f(n) <= M*g(n) for some real number M in order to prove that f(n) is O(g(n)). – bobbymcr Sep 13 '09 at 9:29
Ah ok, ok. And in the inequality method, we can only proceed by trial and error to get the constants, since we need to get proper values for both M AND n-knot? – Rao Sep 13 '09 at 9:34
I guess it would be essentially trial and error, but it would be fairly simple to make good guesses with similar enough functions. – bobbymcr Sep 13 '09 at 10:12

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