Talk:Stirling's approximation/Archive 1

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Archive 1

Convergent version

Latest comment: 17 years ago4 comments3 people in discussion

The "convergent version" section is unsatisfactory. What is the analytic value of that integral in terms of Γ(z)? What does "entails evaluating" mean? --Zero 00:53, 13 Mar 2005 (UTC)

Ok, fixed it myself. Someone might like to check. --Zero 01:22, 13 Mar 2005 (UTC)

How large is the remainder R in the Euler-Maclaurin series? It's traditional, I thought, to indicate that R = O(1/n) or somesuch. Slaniel 22:41, 28 February 2006 (UTC)

The link to Landau notation does not explain anything about what the tilde means.

See "Generalizations and related usages" there.

In the section A version suitable for calculators square brackets are referenced, but do not appear in the formula. -- Meekohi 16:09, 16 April 2007 (UTC)

Yep, would be nice if someone could fix that, especially as the reference is dead now! (thomas9987 10:53, 24 April 2007 (UTC))

I removed the external link (An overview and comparison of different approximations of the factorial function.) which isn't working at the moment, as well as the "square brackets" thing in the section A version suitable for calculators . Hope someone can put the square brackets back in the expression! --thomas9987 10:58, 24 April 2007 (UTC)

Claims about QM

Latest comment: 16 years ago1 comment1 person in discussion

I am removing the 2006 additions to the history section. It is entirely too speculative, and the discussion for small n is inappropriate. For background see Wikipedia talk:WikiProject Physics/Archive 13 and Talk:Planck's law. Melchoir (talk) 05:55, 5 April 2008 (UTC)

What about these Stirling's approximation approximation (yes, an approximation of an approximation!)?

Latest comment: 15 years ago1 comment1 person in discussion

Are these proven for n goes to infinity? If n is not high enough then the approximation of e is not good enough, so this is an approximation of Stirling's which is an approximation of n! (a double approximation so to speak, which is likely a worse approximation of n! but the last form which is a rewriting of the previous one looks so cool that I believe it to be true at the limit to infinity!) Since this will always underestimete e, it follows that it will always overestimete Stirling's approximation, so it seems that it might always be a worse approximation of n! than Stirling's, but could it be that for a very large n it would approximate n! better than Stirling's especially if Stirling's happens to be an underestimate of n! (I have to check wether Stirling's always an underestimate, an overestimate or alternates between under and overestimate of n!)

\lim _{n\rightarrow \infty }{\frac {(1+{\frac {1}{n}})^{n^{2}}\,n!}{n^{n}{\sqrt {n}}}}={\sqrt {2\pi }}.

or

\lim _{n\rightarrow \infty }{\frac {((n+1)^{n})^{n}\,n!}{((n)^{n})^{(n+1)}\ {\sqrt {n}}}}={\sqrt {2\pi }}.

—Preceding unsigned comment added by 137.82.118.137 (talk) 23:59, 2 October 2008 (UTC)

The two limit relations cited in the comment above are false

Latest comment: 15 years ago1 comment1 person in discussion

The correct value of the limits is ${\sqrt {\frac {2\pi }{e}}}$ . Indeed, these formulas are equivalent to saying that $e^{n}$ can be replaced by $(1+{\frac {1}{n}})^{n^{2}}$ in Stirling's formula; in other words, that their quotient goes to 1. But in fact the limit of their quotient is ${\sqrt {e}}.$ This can be seen by taking the logarithm of the quotient and using the power series of $\ln(1+x)$ . Lb561 (talk) 05:05, 16 October 2008 (UTC)

Speed of Convergence and Error Estimates

Latest comment: 15 years ago3 comments1 person in discussion

The text says, "It is not a convergent series; for any particular value of n there are only so many terms of the series that improve accuracy, after which point accuracy actually gets worse." This seems incorrect. The series obviously converges for any reasonably large n, and I'd guess for any n >= 1. Perhaps the author meant to say that in a floating point implementation, the terms soon get smaller than 1 unit in the least significant place (ULP), and additional terms risk adding only rounding error. But that can be avoided by adding terms in the series from right to left. —Preceding unsigned comment added by DMJ001 (talk • contribs) 20:10, 12 June 2008 (UTC)

Okay, I'm going to retract the above paragraph. Using Mathematica (in a sort of hack way), I reproduced the series out to 200 terms. I'm going to display them in floating point, but they were actually computed using exact integer arithmetic. Here are the terms out to the coefficient of 1/n^35: 1., 0.0833333, 0.00347222, -0.00268133, -0.000229472, 0.000784039, 0.0000697281, -0.000592166, -0.0000517179, 0.000839499, 0.000072049, -0.00191444, -0.000162516, 0.00640336, 0.000540165, -0.0295279, -0.00248174, 0.17954, 0.0150561, -1.3918, -0.116546, 13.398, 1.1208, -156.801, -13.1079, 2192.56, 183.191, -36101.1, -3015.08, 691346., 57721.3, -1.52358*10^7, -1.27174*10^6, 3.82848*10^8, 3.19498*10^7, -1.08809*10^10, and the coefficient of the 1/n^200 is -7.63651*10^209.

At first the terms are small, then for a little while every other term seems to be large, and then they all get large, and yet larger the farther out you go. I also computed the ratio of adjacent coefficients and also the ratios of coefficients at distance two apart. Here are ratios of coefficients 2 apart, where the last one is the coefficient of 1/n^200 divided by the coefficient of 1/n^198. -928.912, -948.417, -948.416, -968.124, -968.123, -988.034, -988.033. You can see this is wildly diverging, and getting worse the farther out you got. So it appears that for any n, there is a point in the series beyond which the series will diverge. DMJ001 (talk) 23:40, 11 July 2008 (UTC)

Over the last several months, I've added two graphs. The first is intended to be informative of how accurate Stirling's approximation is. The second is intended to graphically demonstrate the non-convergence. DMJ001 (talk) 05:13, 18 February 2009 (UTC)

Error?

Latest comment: 15 years ago1 comment1 person in discussion

I guess the correct formula for the Gamma function should be

\ln \Gamma (z)=\left(z-{\frac {1}{2}}\right)\ln z-z+{\frac {\ln {2\pi }}{2}}+\sum _{n=1}^{\infty }{\frac {B_{2n}}{2n(2n-1)z^{2n-1}}}

--Sandrobt (talk) 16:44, 9 March 2009 (UTC)

History: First appeared in de Moivre's or Stirling's book?

Latest comment: 15 years ago1 comment1 person in discussion

I put a "verify credibility" template behind a quote stating that Stirling's formula originally appeared in de Moivre's book. This quote is actually in Le Cam's article. Yet, it fails to proof the claim: Stirling's book appeared in 1730, *before* the edition of de Moivre's book mentioned in the quote. Stirling's book contains the formula in its first edition. Yet, there *are* editions of de Moivre's book even before 1730. So the correct thing to do would be to read an *early* edition of de Moivres book and verify that the formula appears therein. I won't do this, but if somebody volunteers that would be nice! :-) --Thomas Bliem (talk) 11:21, 10 May 2009 (UTC)

Error?

Latest comment: 11 years ago1 comment1 person in discussion

I think it should be $Gamma(z+1)=\sqrt(2\pi z)(z/e)^z(1+O(s))$ instead of $Gamma(z)$. — Preceding unsigned comment added by 131.179.36.54 (talk) 04:45, 9 May 2013 (UTC)

Clarifying a revised equation

Latest comment: 10 years ago1 comment1 person in discussion

In the section of the article headed “Speed of Convergence and Error Estimates”, following the text "Stirling's formula is in fact the first approximation to the following series (now called the Stirling series):", an equation with the factor (1 + 1/(12n) +•••) is presented.

Shortly after this equation, the a rewritten version is presented prefaced by the text: "Writing Stirling's series in the form:".

I think that the derivation of the rewritten equation would be clearer if the line,"Writing Stirling's series in the form:", were changed to the following: “Stirling’s series can be rewritten in the form below, where the approximation that ln(1 ± |x|) ≈ ±|x| for the series ln(1 + 1/(12n) + •••) is used.” — Preceding unsigned comment added by Lcaretto (talk • contribs) 16:44, 20 June 2013 (UTC)

Wrong equation - what was intended ?

Latest comment: 10 years ago2 comments2 people in discussion

The equation following the words "computing two-order expansion using Laplace's method yields" currently reads

\int _{0}^{\infty }e^{-n(y+\ln y)}dy\sim {\sqrt {\frac {2\pi }{n}}}e^{-n}\left(1+{\frac {1}{12n}}\right)

but the integral on the left is infinite for positive $n$ , and it is unclear what is meant by "computing two-order expansion using Laplace's method". Might it be possible for whoever put this up to check and clarify ? Thank you. Rfs2 (talk) 15:19, 17 December 2013 (UTC)

- thanks for noticing! i fixed the typo, should be correct now. Asympt (talk) 16:01, 17 December 2013 (UTC)

Deriving n! from log(n!)

Latest comment: 9 years ago3 comments2 people in discussion

Could please someone clarify on why is the "next term in the O(ln(n)) is (1/2)ln(2πn)"? If that is the case, then, trivially, the stated equivalence can be obtained by taking the exponential of both sides of the equation, but why do we choose this particular term, (1/2)ln(2πn), out of the O(ln(n)) class? — DmitriyZotikov (talk) 15:18, 22 January 2015 (UTC)

The line you quoted is in the lead section article, which is supposed to be a concise summary of things explained in more detail later in the article. Your question is answered in the "Derivation" section which immediately follows the lead. —David Eppstein (talk) 17:41, 22 January 2015 (UTC)

Oh, I see, thank you. The derivation looked a little dense so I didn't read it at first. — DmitriyZotikov (talk) 18:40, 22 January 2015 (UTC)