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How do I determine the order between these two functions: n^(2.5) & 100n^(2/3) Additionally, for log(n!).

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pick really big numbers? –  qwertymk Mar 21 '12 at 4:57
is this rigorous proof-based math homework, or something less precise? @qwertymk's suggestion is probably good for the second, but not the first –  mfrankli Mar 21 '12 at 5:00
This may help. Assuming that what you're actually trying to do is order these functions from least complex to most complex. –  aroth Mar 21 '12 at 5:01

2 Answers 2

[Edit] Big-O is used for comparing algorithms, and is used to describe the limiting behavior of a function.

So, if you are given 3 algorithms with complexity O(n^2.5), O(n^(2/3)) and O(log n!), to compare these, you see how they will behave for very large values of n. In this case, n^2.5 is greater than n^(2/3). So, O(n^(2/3)) is better than O(n^2.5) algorithm. For third one, we know that n! < n^n [1*2*..*n < n*n*..*n], so logn! < nlogn. For very large values of n, logn! will get closer to nlogn, so it can be inferred that logn! > n^2/3.

So, the final order will be O(n^2/3) < O(logn!) < O(n^2.5).

PS: All comparisons are made for very large values of n.

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Big-O is for functions ( ). And can be used for algorithms. –  Karoly Horvath Mar 21 '12 at 9:05
@KarolyHorvath: ah, yes! I meant to say that functions don't have big-o complexity. Thanks. –  Priyank Bhatnagar Mar 21 '12 at 9:11
So if given 4n^2, log3(n), 20n, n^2.5, log(n!), n^n, 3^n, n log (n), 100n^(2/3), 2^n, 2^(n+1), n!, (n-1)!, 2^2n The order (increasing order of their big O complexity) would be log3(n) < 20n < n logn < 4n^2 < 100n^(2/3) < log(n!) < n^(2.5) < 2^n < 2^(n+1) < 3^n < 2^(2n) < (n-1)! < n^n < n! ? Is that right? –  Rachel Mar 21 '12 at 13:34
See… for the answer. –  Franck Dernoncourt Mar 21 '12 at 15:33
@Rachel: You should be able to figure out this answer by yourself. Also, don't be fooled by constants, for very large values of n, they disappear in comparisons. In my post I have clearly shown that n! < n^n, still you have made a mistake there. See Franck's answer for correct order. –  Priyank Bhatnagar Mar 21 '12 at 16:54

Functions don't have big-O complexity. Big-O complexity measures are for algorithms that implement functions.

To illustrate, each one of those functions could (in theory) be implemented as a giant lookup table, and that would give O(1) performance. Not exactly practical ... but that's not the point.

Note for people who don't "get it". You can use big-O notation to characterize a function, but that is not a measure of the complexity of the function. It is simply a way of saying something about how the function behaves for large (enough) parameters. Complexity is about characterizing computational processes, and functions are agnostic of how they are computed. Indeed, they don't even need to be computable.

On the other hand, if those functions are functions of performance depending on some parameter n, and you are asking how turn them into big-O complexity measures ...

The best answer is to Do The Math. Take the formal definition of big-O complexity (which can be found here), plug in your function f and solve for g.

If your mathematical skills are not up to that, then another alternative is to get some graph paper and a calculator, and plot how those functions grow as n gets very large. But you need to be careful that you are looking at the rate of growth (not the absolute values) and that you consider values of n that are large enough.

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Big-O is for functions ( ). And can be used for algorithms. –  Karoly Horvath Mar 21 '12 at 9:07
You can't measure the complexity of a function. That's the point I'm trying to make. You can take the big-O of a function, but it doesn't measure the complexity of the function. It just measures the limiting behavior of the function's range. –  Stephen C Mar 21 '12 at 10:54
I'm just saying there is nothing wrong with his question. –  Karoly Horvath Mar 21 '12 at 10:56
I'm saying there is. The terminology is broken. If I was marking an exam, and some student wrote that in their answer, they would lose marks for abusing the terminology. And since Rachel is a student, it is important to point this out to her and others reading her questions. Now you may think that correct use of terminology is unimportant, but her examiners won't agree. –  Stephen C Mar 21 '12 at 10:56
O() is defined for functions and its purest form has nothing to do with algorithms (see the definition...). I agree that the word complexity is not used in the function context, but your answer gives the misleading idea that there's no Big-O for functions. –  Karoly Horvath Mar 21 '12 at 11:08

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