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Is 2^(n+1) = O(2^n)? I believe that this one is correct because n+1 ~= n.

Is 2^(2n) = O(2^n)? This one seems like it would use the same logic, but I'm not sure.

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up vote 3 down vote accepted

Note that

2n+1 = 2(2n)
and
22n = (2n)2

From there, either use the rules of Big-O notation that you know, or use the definition.

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I'm assuming you just left off the O() notation on the left side.

O(2^(n+1)) is the same as O(2 * 2^n), and you can always pull out constant factors, so it is the same as O(2^n).

However, constant factors are the only thing you can pull out. 2^(2n) can be expressed as (2^n)(2^n), and 2^n isn't a constant. So, the answer to your questions are yes and no.

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2^(n+1) = O(2^n) is common, incredibly unfortunate notation for saying "The order of 2^(n+1) is Big-O (2^n)" If I had my way, instead of this terrible O, Ω, Θ notation, we'd use one symbol Θ in conjunction with ≤, ≥, and = to specify order; the above statement would then be written as Θ(2^(n+1)) ≤ Θ(2^n). Unfortunately, this is simply not the way it works :( – BlueRaja - Danny Pflughoeft Jan 31 '11 at 21:45

To answer these questions, you must pay attention to the definition of big-O notation. So you must ask:

is there any constant C such that 2^(n+1) <= C(2^n) (provided that n is big enough)?

And the same goes for the other example: is there any constant C such that 2^(2n) <= C(2^n) for all n that is big enough?

Work on those inequalities and you'll be on your way to the solution.

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