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Update: Sorry I forgot to put n^n inside the O()

My attempt was to solve this recurrence relation:

T(n) = nT(n-1) +1
T(0) = 1;

Using the iteration method I got the n^n but Im not sure if this is the way to prove it.

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Are you trying to prove that O(n!) and O(n^n) are equivalent? That's not the case. –  Nikita Rybak Feb 15 '11 at 2:46
What? (n!) != (n^n). Not only that, but your first line should read T(n) = n T(n-1) -- i.e., drop the +1. –  Dan Breslau Feb 15 '11 at 2:47
I hope he isn't trying to prove that O(n!) and O(n^n) are equivalent, because they aren't. (n^n is bigger by a factor that can be crudely approximated as e^n.) –  Gareth McCaughan Feb 15 '11 at 2:49
They are not equivalent, nor are O(n!) and O(n^n). n! is O(n^n) (almost trivially, by the definition), but not the other way around. Is this what you are trying to show? –  BlueRaja - Danny Pflughoeft Feb 15 '11 at 2:49
T(n) = nT(n-1) +1 would not be n!. n! would be T(n) = nT(n-1) –  user470379 Feb 15 '11 at 3:33

5 Answers 5

I assume that you want to prove that the function n! is an element of the set O(n^n). This can be proven quite easily:

Definition: A function f(n) is element of the set O(g(n)) if there exists a c>0 such that there exists a m such that for all k>m we have that f(k)<=c*g(k).

So, we have to compare n! against n^n. Let's write them one under another:

n!  = n * (n-1) * (n-2) * (n-3) * ... * 3 * 2 * 1
n^n = n *  n    *  n    *  n    * ... * n * n * n

As you can see, the first line (n!) and the second line (n^n) have both exactly n items on the right side. If we compare these items, we see that every item is at most as large as it's corresponding item in the second line. Thus n! <= n^n (at least for n>5).

So, we can - look at the definition - say, that there exists c=1 such that there exists m=5 such that for all k>5 we have that k! < k^k, which proves that n! is indeed an element of O(n^n).

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To formalize this, you could easily turn it into induction. –  Thomas Ahle Dec 22 '11 at 12:10

Remark: The following is an answer to the original Question which was: "Prove that n! = n^n"

I can prove that it's not true pretty easily: take n = 5.

n! = 120
n^n = 3125
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Too literal, I guess. I think the failure is the way the OP worded the question, not my answer. –  duffymo Feb 15 '11 at 3:03
NO idea why one would downvote this. +1. –  Aryabhatta Feb 15 '11 at 3:10
Have an upvote. GIGO. –  dkamins Feb 15 '11 at 3:12
Thank you both. It's very generous of you, but I'm not too worried about it. –  duffymo Feb 15 '11 at 3:18
I hope so. That was my point. –  duffymo Nov 3 '13 at 18:13

It is not true that n! = n^n, and therefore you will not be able to prove that. Furthermore, the solution to your recurrence relation is neither n! or n^n. (It satisfies T(1) = 1*1+1 = 2, which is neither 1! nor 1^1.)

What exactly are you trying to do, and why?

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he's going to do about the estimation of algorithm complexity. It's not n! = n^n as the usual meaning. –  Hoàng Long Feb 15 '11 at 2:51

n! != n^n. However, the T(n) sequence defined above is not n!. But does it equal n^n? For n=1, T(1) = 1*T(0) + 1 = 1*1 + 1 = 2 but n^n = 1^1 = 1. However, assuming you also meant T(1) = 1, then they're equal for n=1. Going a step further, for n=2, then T(2) = 2*T(1) + 1 = 2*1 + 1 = 3 != 2^2. So I'm honestly not sure what you're trying to ask.

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Obviously, this notation is abusing the equality symbol, since it violates the axiom of equality: "things equal to the same thing are equal to each other". To be more formally correct, some people (mostly mathematicians, as opposed to computer scientists) prefer to define O(g(x)) as a set-valued function, whose value is all functions that do not grow faster then g(x), and use set membership notation to indicate that a specific function is a member of the set thus defined. Both forms are in common use, but the sloppier equality notation is more common at present –  rick112358 Nov 9 '14 at 18:23

for n==2, n! = 2 != 4 = n^n.
for n!=2, (n-1) divides n! but n-1 does not divide n^n (n^n mod n-1 == 1)

The actual stirling approximation is n! ~ sqrt(2 Pi n) (n/e)^n

What is your mathematical background? Do you want a complex analytic proof or something more combinatorial in nature?

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thanks for giving me an opportunity to reminisce about college :) –  Foo Bah Feb 15 '11 at 3:04
@Moron that's a crappy proof. There's a much more general form of the stirling approximation that involves the gamma function [which you prove via calculus of residues] –  Foo Bah Feb 15 '11 at 3:12
@Moron I'm a math guy at heart, and its been years since i last thought about hard math. And yes, real math classes are nitpicky :) –  Foo Bah Feb 15 '11 at 3:52
@Foo: Yes, math classes are nitpicky :-) btw, you do know one can undo downvotes? Once you edit your answer to include that case, I will remove the downvote. btw, do you really think someone who posts such a question will know complex analysis? Also, Euler McLaurin Summation formula is a very useful tool. Pity that you think it is crappy. Anyway... –  Aryabhatta Feb 15 '11 at 4:48
@Moron I dont think its a crappy tool in general; its a crappy tool in this case because, as far as i could follow the proof in my head, you couldnt get that extra sqrt(n) term –  Foo Bah Feb 15 '11 at 5:21

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