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Resources I've found on time complexity are unclear about when it is okay to ignore terms in a time complexity equation, specifically with non-polynomial examples.

It's clear to me that given something of the form n2 + n + 1, the last two terms are insignificant.

Specifically, given two categorizations, 2n, and n*(2n), is the second in the same order as the first? Does the additional n multiplication there matter? Usually resources just say xn is in an exponential and grows much faster... then move on.

I can understand why it wouldn't since 2n will greatly outpace n, but because they're not being added together, it would matter greatly when comparing the two equations, in fact the difference between them will always be a factor of n, which seems important to say the least.

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    In my opinion, given that NLogN is regarded strictly slower than N, but most people don't really care by how much, it is safe to say N2^N is simply slower than 2^N, but not "slower enough" for people to care..
    – Jack
    Feb 13, 2014 at 20:40
  • @tobias_k, I understand this point, but consider the example of O(n!). Would an extra n term really be different? O(n!) is to O(n*n!) as O(n!) is to O((n+1)!) aka the same graph simply shifted. The growth is the same though... In this case even though one is strictly large, is the growth different? isn't this what time complexity cares about?
    – matty-d
    Feb 13, 2014 at 20:43
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    @JackWu but most people don't really care by how much until you have to sort hundreds of millions of records with nlogn instead of n :)
    – C.B.
    Feb 13, 2014 at 20:46
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    In fact, n! = o((n+1)!), that is, it grows strictly slower asymptotically.
    – chepner
    Feb 13, 2014 at 20:47
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    Note that this has nothing to with complexity theory, it's "just" about aymptotics. Also, this kind of questions is probably better off on Computer Science.
    – Raphael
    Feb 13, 2014 at 23:33

6 Answers 6

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You will have to go to the formal definition of the big O (O) in order to answer this question.

The definition is that f(x) belongs to O(g(x)) if and only if the limit limsupx → ∞ (f(x)/g(x)) exists i.e. is not infinity. In short this means that there exists a constant M, such that value of f(x)/g(x) is never greater than M.

In the case of your question let f(n) = n ⋅ 2n and let g(n) = 2n. Then f(n)/g(n) is n which will still grow infinitely. Therefore f(n) does not belong to O(g(n)).

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    For a slightly easier to read definition, see here
    – Alden
    Feb 13, 2014 at 20:47
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    Formally speaking, you can't take the limit of O(f(x)/g(x)); big-O notification is shorthand for a set of functions, not a single function whose value you can limit. However, I think it's true that you can show that f(x) = O(g(x)) if lim(x->infinity) f(x)/g(x) exists.
    – chepner
    Feb 13, 2014 at 20:53
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    The limit does not have to exist; the ratio only has to be bounded above by a constant for sufficiently large x. For example, 2+sin(x) is in O(1), but (2+sin(x))/1 does not approach a limit as x->infinity. Feb 13, 2014 at 21:33
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    The definition would be correct with lim sup instead of lim. Feb 14, 2014 at 2:31
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    @IvayloStrandjev please note that your in short description is incorrect. This must be true for a sufficiently large x, not for all values of x.
    – K.Steff
    Feb 14, 2014 at 18:11
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A quick way to see that n⋅2ⁿ is bigger is to make a change of variable. Let m = 2ⁿ. Then n⋅2ⁿ = ( log₂m )⋅m (taking the base-2 logarithm on both sides of m = 2ⁿ gives n = log₂m ), and you can easily show that m log₂m grows faster than m.

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    Thank you! This is the best answer in my opinion. Proofs based on formal definitions are correct, but if you have a stumbling block of some sort to get over, a very comfortable and familiar analogy will do the job the best and the fastest.
    – John P
    Feb 14, 2014 at 4:00
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    Stupid question, what is lg? Logarithm in base 2? Feb 14, 2014 at 12:57
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    It's a lazy abbreviation. In computer science, it tends to mean base 2 because it mostly results from divide-and-conquer strategies. In big-O notation, it could represent anything, because the base-x logarithm of a number differs from its base-y logarithm by only a constant factor, regardless of x and y.
    – chepner
    Feb 14, 2014 at 14:12
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    I should note in retrospect that lg is the ISO notation for a base-10 logarithm, rather than the base-agnostic use most commonly used when discussing asymptotic run times. See en.wikipedia.org/wiki/Logarithm#Particular_bases
    – chepner
    Feb 14, 2014 at 20:05
  • Okay, sure, but I don't get why it's more obvious that m log m grows faster than m, than it is that n 2^n grows faster than 2^n.
    – djechlin
    Nov 23, 2015 at 21:33
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I agree that n⋅2ⁿ is not in O(2ⁿ), but I thought it should be more explicit since the limit superior usage doesn't always hold.

By the formal definition of Big-O: f(n) is in O(g(n)) if there exist constants c > 0 and n₀ ≥ 0 such that for all n ≥ n₀ we have f(n) ≤ c⋅g(n). It can easily be shown that no such constants exist for f(n) = n⋅2ⁿ and g(n) = 2ⁿ. However, it can be shown that g(n) is in O(f(n)).

In other words, n⋅2ⁿ is lower bounded by 2ⁿ. This is intuitive. Although they are both exponential and thus are equally unlikely to be used in most practical circumstances, we cannot say they are of the same order because 2ⁿ necessarily grows slower than n⋅2ⁿ.

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  • f(n) = 2*2^n I think you meant n*2^n?
    – tobias_k
    Feb 14, 2014 at 10:15
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I do not argue with other answers that say that n⋅2ⁿ grows faster than 2ⁿ. But n⋅2ⁿ grows is still only exponential.

When we talk about algorithms, we often say that time complexity grows is exponential. So, we consider to be 2ⁿ, 3ⁿ, eⁿ, 2.000001ⁿ, or our n⋅2ⁿ to be same group of complexity with exponential grows.

To give it a bit mathematical sense, we consider a function f(x) to grow (not faster than) exponentially if exists such constant c > 1, that f(x) = O(cx).

For n⋅2ⁿ the constant c can be any number greater than 2, let's take 3. Then:

n⋅2ⁿ / 3ⁿ = n ⋅ (2/3)ⁿ and this is less than 1 for any n.

So 2ⁿ grows slower than n⋅2ⁿ, the last in turn grows slower than 2.000001ⁿ. But all three of them grow exponentially.

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  • In the last example, n*2^n is greater than 2.000001^n up to n = 34,726,000. At that point 2^n is a number with more than 10 million digits, so it doesn't really matter...
    – gnasher729
    Mar 18, 2014 at 9:24
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    @gnasher729 It's just a constant which we may omit as f(n) and c*f(n) is same complexity in terms of big-O. e.g. 40'000'000*2.000001^n is greater than n*2^n right away. But you are right, it does not really matter, I would say it does not really matter once we hit exponential grows (unless we get only small values of n).
    – Andrey
    Mar 19, 2014 at 15:30
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You asked "is the second in the same order as the first? Does the additional n multiplication there matter?" These are two different questions with two different answers.

n 2^n grows asymptotically faster than 2^n. That's that question answered.

But you could ask "if algorithm A takes 2^n nanoseconds, and algorithm B takes n 2^n nanoseconds, what is the biggest n where I can find a solution in a second / minute / hour / day / month / year? And the answers are n = 29/35/41/46/51/54 vs. 25/30/36/40/45/49. Not much difference in practice.

The size of the biggest problem that can be solved in time T is O (ln T) in both cases.

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Very Simple answer is 'NO'

see 2^n and n.2^n

as seen n.2^n > 2^n for any n>0

or you can even do it by applying log on both sides then you get

 n.log(2)    <    n.log(2) + log(n) 

hence by both type of analysis that is by

  1. substituting a number

  2. using log

we see that n.2^n is greater than 2^n as visibly seen

so if you get a equation like

O ( 2^n + n.2^n ) which can be replaced as O ( n.2^n)

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