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I have a little list descending into faster asymptotic growth:


O(log log n)

O(log n)

O(n^x), where 0 <= x <= 1


O(n log n)

O(n^x), where x>1



Im just curious as to where natural logs (ln) fit into this list in terms of their asymptotic growth rate. For example (ln n)^2

Thank you for your time.

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closed as off topic by Mitch Wheat, alfasin, razlebe, Michal Borek, Ken Fyrstenberg Jun 15 '13 at 8:14

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log ~ ln ..... a log is a log is a log... –  Mitch Wheat Jun 15 '13 at 6:51
Im sorry I dont understand, have I stupidly missed something here? –  Ogen Jun 15 '13 at 6:53
OT: what sound does a drowning number theorist make? ...log log log ... –  Mitch Wheat Jun 15 '13 at 6:55

2 Answers 2

up vote 5 down vote accepted

Logarithms of all bases (bigger than 1) grow at the same rate.

We can show this by using the formula:

Logx(a)/Logx(b) =Logb(a)

So, since Ln(x) is just Loge(x):

Loge(n)/Loge(10) =Log10(n)

Since Loge(10) is a constant they have the same runtime complexity.

Let us elaborate: the fact two functions are both Big O of each other (meaning they are big theta of each other) means that they are the equal to each other up to a multiplicative constant.

Since we have shown that there is such a constant (in our case Loge(10)) we are done.

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Just out of curiosity. Where abouts would n^x for x < 0 fit in this list? Or even (log n)^2? –  Ogen Jun 15 '13 at 7:06
For x<0, n^x is the same as n^-y for y>0 which is the same as 1/(n^y) for some y>0. It's really small :) Consider that for n=10 we get 1/10^y which is smaller than 1. In practice in computer science we almost never have this sort of run time complexity since we're reliably able to say what a basic action is (log on the other hand appears when splitting stuff, like in binary search or merge sort). (Log n)^2 is still smaller than O(n). One way to see this is to apply L'Hôpital's_rule. You can see the graph yourself in wolframalpha.com –  Benjamin Gruenbaum Jun 15 '13 at 7:11
Here is the said graph: wolframalpha.com/input/… –  Benjamin Gruenbaum Jun 15 '13 at 7:13
This has been very informative, thanks for the time and effort. –  Ogen Jun 15 '13 at 7:35

The base of a logarithm does not matter in asymptotic complexity. log10 is the same as log2 and ln for this purpose.

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which is what I said in the comment. –  Mitch Wheat Jun 15 '13 at 6:54
@MitchWheat Yes, and now what? –  user529758 Jun 15 '13 at 6:54
simply pointing out I already told the poster that. –  Mitch Wheat Jun 15 '13 at 6:55
@MitchWheat Ah, OK, I see. –  user529758 Jun 15 '13 at 6:55
@Clay To be fair, the other answer explains the cause pretty well :) –  user529758 Jun 15 '13 at 6:59

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