# Is log(n!) = Θ(n·log(n))?

This is a homework question. I'm not expecting an answer, just some guidance, possibly :) I am to show that log(n!) = Θ(n·log(n)).

A hint was given that I should show the upper bound with nn and show the lower bound with (n/2)(n/2). This does not seem all that intuitive to me. Why would that be the case? I can definitely see how to convert nn to n·log(n) [log both sides of an equation], but that's kind of working backwards. What would be the correct approach to tackle this problem? Should I draw the recursion tree? There is nothing recursive about this, so that doesn't seem like a likely approach..

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+1 for honesty on homework and not asking for the 'codez' :) –  Andrew Jan 19 '10 at 17:22
MY BRAIN HURTS! –  Tad Donaghe Jan 19 '10 at 17:32
Did you want to write `O(log(n!))`? I guess you want to have the upper run-time complexity. –  Georg Schölly Jan 19 '10 at 17:53
You should really write it including the "as n -> ∞ " –  MartW Jan 19 '10 at 18:49
Fun exercise: use the similar trick to show that the harmonic series 1/1 + 1/2 + 1/3 + 1/4 + ... diverges to infinity. –  Yoo Jan 19 '10 at 22:54

Remember that

``````log(n!) = log(1) + log(2) + ... + log(n-1) + log(n)
``````

You can get the upper bound by

``````log(1) + log(2) + ... + log(n) <= log(n) + log(n) + ... + log(n)
= n*log(n)
``````

And you can get the lower bound by doing a similar thing after throwing away the first half of the sum:

``````log(1) + ... + log(n/2) + ... + log(n) >= log(n/2) + ... + log(n)
>= log(n/2) + ... + log(n/2)
= n/2 * log(n/2)
``````
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Interesting... Pushing this into a sum, there is an approximation that results in the theta notation itself (source: en.wikipedia.org/wiki/Summation) a matter of how that is derived is entirely separate. Nice lead, thanks! –  Mark Jan 19 '10 at 17:40
This is a very nice proof for the upper bound: log(n!) = log(1) + ... + log(n) <= n log(n) => log(n!) = O(n log n). However, for proving the lower bound (and consequently big-tetha), you'll probably need Stirling's Approximation. –  Mehrdad Afshari Jan 19 '10 at 20:34
You don't need Sterling's approximation for a lower bound. log(n!) = log(1) + ... + log(n) >= log(n/2) + ... + log(n) >= n/2 * log(n/2) = Omega(n log n). –  Keith Randall Jan 19 '10 at 22:40
nice trick, I think it works. –  ldog Jan 20 '10 at 2:23
@j_random_hacker: `log(n/2) + log(n/2 + 1) + ... + log(n - 1) + log(n)` (larger half of the terms of `log(n!)`). Actually, I just read the question and saw that the clue is stated in the question. Basically, `(n/2)^(n/2) <= n! <= n^n` => `log((n/2)^(n/2))<=log(n!)<=log(n^n)` => `Θ(n/2 * log(n/2))<=log(n!)<=Θ(n*log(n))` –  Mehrdad Afshari Jan 21 '10 at 14:07

This might help:

```eln(x) = x
```

and

```(lm)n = lm*n
```
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Actually, that's wrong: 1^(m^n) != 1^(mn) it must be (1^m)^n = 1^(mn) –  Pindatjuh Jan 19 '10 at 18:18
Errr I mean L instead of 1 in the above comment. –  Pindatjuh Jan 19 '10 at 18:35
He didn't write 1^(m^n) he wrote (l^m)^n –  Imray Jan 17 '13 at 20:57

ln(n!) = n*ln(n) - n + O(ln(n))

where the last 2 terms are less significant than the first one.

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While this link may answer the question, it is better to include the essential parts of the answer here and provide the link for reference. Link-only answers can become invalid if the linked page changes. –  phs Apr 29 at 20:45

Helping you further, where Mick Sharpe left you:

It's deriveration is quite simple: see http://en.wikipedia.org/wiki/Logarithm -> Group Theory

log(n!) = log(n * (n-1) * (n-2) * ... * 2 * 1) = log(n) + log(n-1) + ... + log(2) + log(1)

Think of n as infinitly big. What is infinite minus one? or minus two? etc.

log(inf) + log(inf) + log(inf) + ... = inf * log(inf)

And then think of inf as n.

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BigO is abut asymptotically. For qsort you can say that it can sort in n! order or less. That is true. But as I said BigO is about asymptotically.

In that case you should prove that some function lie between two functions and that there is lower and upper limit, and this helps you prove properties.

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How does this at all even attempt to answer the question? –  yati sagade Mar 24 '14 at 8:10

http://en.wikipedia.org/wiki/Stirling%27s_approximation Stirling approximation might help you. It is really helpful in dealing with problems on factorials related to huge numbers of the order of 10^10 and above.

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I realize this is a very old question with an accepted answer, but none of these answers actually use the approach suggested by the hint.

It is a pretty simple argument:

`n!` (= 1*2*3*...*n) is a product of `n` numbers each less than or equal to `n`. Therefore it is less than the product of `n` numbers all equal to `n`; i.e., `n^n`.

Half of the numbers -- i.e. `n/2` of them -- in the `n!` product are greater than or equal to `n/2`. Therefore their product is greater than the product of `n/2` numbers all equal to `n/2`; i.e. `(n/2)^(n/2)`.

Take logs throughout to establish the result.

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This is actually just the same as the log version in the accepted answer but taking the logarithm after instead of before. (it more clearly uses the hint though) –  hugomg Nov 3 '11 at 4:21

Thanks, I found your answers convincing but in my case, I must use the Θ properties:

``````log(n!) = Θ(n·log n) =>  log(n!) = O(n log n) and log(n!) = Ω(n log n)
``````

to verify the problem I found this web, where you have all the process explained: http://www.mcs.sdsmt.edu/ecorwin/cs372/handouts/theta_n_factorial.htm

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For lower bound,

``````lg(n!) = lg(n)+lg(n-1)+...+lg(n/2)+...+lg2+lg1
>= lg(n/2)+lg(n/2)+...+lg(n/2)+ ((n-1)/2) lg 2 (leave last term lg1(=0); replace first n/2 terms as lg(n/2); replace last (n-1)/2 terms as lg2 which will make cancellation easier later)
= n/2 lg(n/2) + (n/2) lg 2 - 1/2 lg 2
= n/2 lg n - (n/2)(lg 2) + n/2 - 1/2
= n/2 lg n - 1/2
``````

lg(n!) >= (1/2) (n lg n - 1)

Combining both bounds :

1/2 (n lg n - 1) <= lg(n!) <= n lg n

By choosing lower bound constant greater than (1/2) we can compensate for -1 inside the bracket.

Thus lg(n!) = Theta(n lg n)

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This extended derivation is needed because, "something" >= n/2 * lg(n/2) is not equal to omega(n lg n) which was mentioned in one of the previous comment. –  Vivek Anand Sampath Feb 21 at 3:13