Talk:Gaussian integral

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Possible mistake[edit]

I think that there is a mistake in the equations of the section 'n-dimensional and functional generalization'. If you do the integral

\int _{-\infty }^{\infty }\exp \left(-{\boldsymbol {r}}\cdot {\boldsymbol {r}}\right)d^{3}{\boldsymbol {r}}

with the first equation of this section, the obtained result is not the correct result. I think that the term ${\sqrt {\frac {(2\pi )^{n}}{\det A}}}$ must be replaced with another thing. Maybe $\left({\frac {2\pi }{\det A}}\right)^{n/2}$ ?

Formulas not rendering correctly[edit]

Hi, a number of formulas (5 as far as I can tell) in this article don't render correctly, producing latex errors displayed instead of the formulas. First occurence of these errors is under the heading By polar coordinates: On the other hand, Failed to parse(unknown function '\begin'): {\begin{aligned}\iint _{{{\mathbf {R}}^{2}}}e^{{-(x^{2}+y^{2})}}\,d(x,y)&=\int _{0}^{ {2\pi } }\int _{0}^{{\infty }}e^{{-r^{2}}}r\,dr\,d\theta \\&=2\pi \int _{0}^{\infty }re^{{-r^{2}}}\,dr\\&=2\pi \int _{{-\infty }}^{0}{\tfrac {1}{2}}e^{s}\,ds&&s=-r^{2}\\&=\pi \int _{{-\infty }}^{0}e^{s}\,ds\\&=\pi (e^{0}-e^{{-\infty }})\\&=\pi ,\end{aligned}}

In an external latex editor, the same latex source used in the Wikipedia article looks fine. Unfortunately, I'm no expert on this and cannot fix it. I hope someone with more expertise might be able to help.

Please provide references![edit]

I see many useful results and formulae in the multivariate case, but there are no references to textbooks or other published material where to find the proofs! Can someone add references?

Someone in the talk above says that some results are "standard textbook material". Well, then provide a reference to a standard textbook. Someone else says "you can easily derive such and such by...": again, give references to literature!

Remember that this is a Wikipedia article: a starting point, not a self-contained book or paper.

(Unsigned comment by Special:Contributions/87.236.195.22)

Some of the material that was in the higher-order polynomials section was included without reference and turns out to be wrong. See this math.stackexchange.com question for details. Makes it clear why references are absolutely necessary. Eigenbra (talk) 05:49, 17 June 2015 (UTC)[reply]

Is there really a proof using Cauchy's Integral Theorem?[edit]

Whereas it says under the heading Proof by complex integral that ″A proof also exists using Cauchy's integral theorem″, I haven't seen one and have read the contrary: ″On the other hand, quite simple definite integrals exist whch cannot be evaluated by Cauchy's method, $\int _{0}^{\infty }\mathrm {e} ^{-x^{2}}\;\mathrm {d} x$ being a case in point.″ ^[1]

Cauchy's integral theorem is often used to find other definite integrals knowing the Gaussian integral,^[2]^[3] but that's not quite the same thing.

GeordieMcBain (talk) 01:37, 23 April 2015 (UTC)[reply]

Proof by Risch algorithm?[edit]

The article states that there is no elementary function, proof by Risch Algorithm. The Wiki page for Risch Algorithm states that it is a semi-decision procedure, i.e. there are cases where it doesn't terminate. Has someone shown in a paper that Risch algorithm terminates on Gaussian integral with limits and that trace of the algorithm constitutes a proof that there is no elementary function? Erxnmedia (talk) 14:14, 9 August 2017 (UTC)[reply]

^ E. T. Copson 1935, An Introduction to the Theory of Functions of a Complex Variable, Oxford University Press, p. 125
^ Copson, p. 142
^ E. Goursat 1918 Cours d'analyse mathématique, Paris: Gauthier–Villars, vol. 2, p. 116

[1] E. T. Copson 1935, An Introduction to the Theory of Functions of a Complex Variable, Oxford University Press, p. 125

[2] Copson, p. 142

[3] E. Goursat 1918 Cours d'analyse mathématique, Paris: Gauthier–Villars, vol. 2, p. 116

[1]

[2]

[3]