19 Elliptic Integrals Symmetric Integrals 19.15 Advantages of Symmetry 19.17 Graphics

§19.16 Definitions

ⓘ

Permalink:: http://dlmf.nist.gov/19.16
See also:: Annotations for Ch.19

§19.16(i) Symmetric Integrals

ⓘ

Keywords:: hyperelliptic integrals, symmetric elliptic integrals
Referenced by:: §19.20(i), §19.29(i), §20.9(i), Erratum (V1.0.7) for Usability, Erratum (V1.1.0) for Rearrangement
Permalink:: http://dlmf.nist.gov/19.16.i
Rearrangement (effective with 1.1.0):: The integral representation (19.16.2_5), which was previously (19.23.7), is a better fit here and is taken as the definition of $R_{G}\left(x,y,z\right)$ . Likewise, (19.16.3) was moved to (19.23.6_5).
Addition (effective with 1.0.7):: The cross-reference to (19.20.14) has been added into the paragraph following (19.16.4).
See also:: Annotations for §19.16 and Ch.19

19.16.1		$R_{F}\left(x,y,z\right)=\frac{1}{2}\int_{0}^{\infty}\frac{\,\mathrm{d}t}{s(t)},$
ⓘ Defines: $R_{F}\left(\NVar{x},\NVar{y},\NVar{z}\right)$ : symmetric elliptic integral of first kind Symbols: $\,\mathrm{d}\NVar{x}$ : differential of $x$ , $\int$ : integral and $s(t)$ : scaling factor Referenced by: §19.16(i), §19.16(i), §19.18(i), (19.25.35), (19.25.40), §19.25(vi) Permalink: http://dlmf.nist.gov/19.16.E1 Encodings: TeX, pMML, png See also: Annotations for §19.16(i), §19.16 and Ch.19

19.16.2		$R_{J}\left(x,y,z,p\right)=\frac{3}{2}\int_{0}^{\infty}\frac{\,\mathrm{d}t}{s(t% )(t+p)},$
ⓘ Defines: $R_{J}\left(\NVar{x},\NVar{y},\NVar{z},\NVar{p}\right)$ : symmetric elliptic integral of third kind Symbols: $\,\mathrm{d}\NVar{x}$ : differential of $x$ , $\int$ : integral and $s(t)$ : scaling factor Referenced by: §19.16(i), §19.19, §19.20(iii), §19.28 Permalink: http://dlmf.nist.gov/19.16.E2 Encodings: TeX, pMML, png See also: Annotations for §19.16(i), §19.16 and Ch.19

19.16.2_5		$R_{G}\left(x,y,z\right)=\frac{1}{4}\int_{0}^{\infty}\frac{1}{s(t)}\*\left(% \frac{x}{t+x}+\frac{y}{t+y}+\frac{z}{t+z}\right)t\,\mathrm{d}t.$
ⓘ Defines: $R_{G}\left(\NVar{x},\NVar{y},\NVar{z}\right)$ : symmetric elliptic integral of second kind Symbols: $\,\mathrm{d}\NVar{x}$ : differential of $x$ , $\int$ : integral and $s(t)$ : scaling factor Source: Carlson (1977b, (9.1-9)) Referenced by: §19.16(i), §19.16(i), §19.21(ii), (19.23.7), (19.23.7), §19.23, Erratum (V1.1.0) for Rearrangement Permalink: http://dlmf.nist.gov/19.16.E2_5 Encodings: TeX, pMML, png Rearrangement (effective with 1.1.0): This integral representation was moved from (19.23.7) and is taken as the definition of $R_{G}\left(x,y,z\right)$ . We have also employed the notation $s(t)$ for the factor of radicals. See also: Annotations for §19.16(i), §19.16 and Ch.19

19.16.3		Moved to (19.23.6_5).
ⓘ Referenced by: §19.16(i), (19.23.6_5), §19.23, Erratum (V1.1.0) for Rearrangement Permalink: http://dlmf.nist.gov/19.16.E3 Rearrangement (effective with 1.1.0): This equation has been moved to (19.23.6_5). See also: Annotations for §19.16(i), §19.16 and Ch.19

where $p$ ( $\neq 0$ ) is a real or complex constant, and

19.16.4		$s(t)=\sqrt{t+x}\sqrt{t+y}\sqrt{t+z}.$
ⓘ Defines: $s(t)$ : scaling factor (locally) Referenced by: §19.16(i), (19.25.35), §19.25(vi) Permalink: http://dlmf.nist.gov/19.16.E4 Encodings: TeX, pMML, png See also: Annotations for §19.16(i), §19.16 and Ch.19

In (19.16.1)–(19.16.2_5), $x,y,z\in\mathbb{C}\setminus(-\infty,0]$ except that one or more of $x, y, z$ may be 0 when the corresponding integral converges. In (19.16.2) the Cauchy principal value is taken when $p$ is real and negative. See also (19.20.14). It should be noted that the integrals (19.16.1)–(19.16.2_5) have been normalized so that $R_{F}\left(1,1,1\right)=R_{J}\left(1,1,1,1\right)=R_{G}\left(1,1,1\right)=1$ .

A fourth integral that is symmetric in only two variables is defined by

19.16.5		$R_{D}\left(x,y,z\right)=R_{J}\left(x,y,z,z\right)=\frac{3}{2}\int_{0}^{\infty}% \frac{\,\mathrm{d}t}{s(t)(t+z)},$
ⓘ Defines: $R_{D}\left(\NVar{x},\NVar{y},\NVar{z}\right)$ : elliptic integral symmetric in only two variables Symbols: $R_{J}\left(\NVar{x},\NVar{y},\NVar{z},\NVar{p}\right)$ : symmetric elliptic integral of third kind, $\,\mathrm{d}\NVar{x}$ : differential of $x$ , $\int$ : integral and $s(t)$ : scaling factor Referenced by: §19.18(i), §19.19, §19.20(iii), §19.20(iv), §19.24(ii), §19.6(iv) Permalink: http://dlmf.nist.gov/19.16.E5 Encodings: TeX, pMML, png See also: Annotations for §19.16(i), §19.16 and Ch.19

with the same conditions on $x$ , $y$ , $z$ as for (19.16.1), but now $z\neq 0$ .

Just as the elementary function $R_{C}\left(x,y\right)$ (§19.2(iv)) is the degenerate case

19.16.6		$R_{C}\left(x,y\right)=R_{F}\left(x,y,y\right),$
ⓘ Symbols: $R_{C}\left(\NVar{x},\NVar{y}\right)$ : Carlson’s combination of inverse circular and inverse hyperbolic functions and $R_{F}\left(\NVar{x},\NVar{y},\NVar{z}\right)$ : symmetric elliptic integral of first kind Referenced by: §19.19, §19.24(ii), §19.6(ii) Permalink: http://dlmf.nist.gov/19.16.E6 Encodings: TeX, pMML, png See also: Annotations for §19.16(i), §19.16 and Ch.19

and $R_{D}$ is a degenerate case of $R_{J}$ , so is $R_{J}$ a degenerate case of the hyperelliptic integral,

19.16.7		$\frac{3}{2}\int_{0}^{\infty}\frac{\,\mathrm{d}t}{\prod_{j=1}^{5}\sqrt{t+x_{j}}}.$
ⓘ Symbols: $\,\mathrm{d}\NVar{x}$ : differential of $x$ and $\int$ : integral Permalink: http://dlmf.nist.gov/19.16.E7 Encodings: TeX, pMML, png See also: Annotations for §19.16(i), §19.16 and Ch.19

§19.16(ii) $R_{-a}\left(\mathbf{b};\mathbf{z}\right)$

ⓘ

Keywords:: degree, hypergeometric $R$ -function, hypergeometric function, integral representations, multivariate, multivariate hypergeometric function, permutation symmetry, symmetric elliptic integrals
Notes:: See Carlson (1977b, (6.8-6), Ex. 6.8-8, and (5.9-1)). To prove (19.16.12) put $t={\csc}^{2}\theta-{\csc}^{2}\phi$ in the first integral in (19.16.9).
Referenced by:: §20.9(i), Erratum (V1.0.1) for Clarifications, Erratum (V1.0.18) for Equation (19.16.9)
Permalink:: http://dlmf.nist.gov/19.16.ii
Clarification (effective with 1.1.0):: A reference to (19.23.6_5) was added to the first sentence for illustration.
Clarification (effective with 1.0.18):: The last sentence of this subsection was elaborated to mention that generalizations may also be found in Carlson (1977b).
Suggested 2017-07-25 by Bastien Roucariès
Clarification (effective with 1.0.1):: “unchanged” was substituted for “symmetric” in the text after (19.16.8).
See also:: Annotations for §19.16 and Ch.19

All elliptic integrals of the form (19.2.3) and many multiple integrals, including (19.23.6) and (19.23.6_5), are special cases of a multivariate hypergeometric function

19.16.8		$R_{-a}\left(\mathbf{b};\mathbf{z}\right)=R_{-a}\left(b_{1},\dots,b_{n};z_{1},% \dots,z_{n}\right),$
ⓘ Symbols: $R_{\NVar{-a}}\left(\NVar{b_{1}},\dots,\NVar{b_{n}};\NVar{z_{1}},\dots,\NVar{z_% {n}}\right)$ or $R_{\NVar{-a}}\left(\NVar{\mathbf{b}};\NVar{\mathbf{z}}\right)$ : multivariate hypergeometric function and $n$ : nonnegative integer Referenced by: §19.16(ii) Permalink: http://dlmf.nist.gov/19.16.E8 Encodings: TeX, pMML, png See also: Annotations for §19.16(ii), §19.16 and Ch.19

which is homogeneous and of degree $-a$ in the $z$ ’s, and unchanged when the same permutation is applied to both sets of subscripts $1,\dots,n$ . Thus $R_{-a}\left(\mathbf{b};\mathbf{z}\right)$ is symmetric in the variables $z_{j}$ and $z_{\ell}$ if the parameters $b_{j}$ and $b_{\ell}$ are equal. The $R$ -function is often used to make a unified statement of a property of several elliptic integrals. Before 1969 $R_{-a}\left(\mathbf{b};\mathbf{z}\right)$ was denoted by $R(a;\mathbf{b};\mathbf{z})$ .

19.16.9		$R_{-a}\left(\mathbf{b};\mathbf{z}\right)=\frac{1}{\mathrm{B}\left(a,a^{\prime}% \right)}\int_{0}^{\infty}t^{a^{\prime}-1}\prod^{n}_{j=1}(t+z_{j})^{-b_{j}}\,% \mathrm{d}t=\frac{1}{\mathrm{B}\left(a,a^{\prime}\right)}\int_{0}^{\infty}t^{a% -1}\prod^{n}_{j=1}(1+tz_{j})^{-b_{j}}\,\mathrm{d}t,$
$b_{1}+\cdots+b_{n}>a>0$ , $b_{j}\in\mathbb{R}$ , $z_{j}\in\mathbb{C}\setminus(-\infty,0]$ ,
ⓘ Defines: $R_{\NVar{-a}}\left(\NVar{b_{1}},\dots,\NVar{b_{n}};\NVar{z_{1}},\dots,\NVar{z_% {n}}\right)$ or $R_{\NVar{-a}}\left(\NVar{\mathbf{b}};\NVar{\mathbf{z}}\right)$ : multivariate hypergeometric function Symbols: $\mathrm{B}\left(\NVar{a},\NVar{b}\right)$ : beta function, $\mathbb{C}$ : complex plane, $\,\mathrm{d}\NVar{x}$ : differential of $x$ , $\in$ : element of, $\int$ : integral, $(\NVar{a},\NVar{b}]$ : half-closed interval, $\mathbb{R}$ : real line, $\setminus$ : set subtraction and $n$ : nonnegative integer Referenced by: §19.16(ii), §19.16(ii), §19.19, §19.20(iv), Erratum (V1.0.18) for Equation (19.16.9) Permalink: http://dlmf.nist.gov/19.16.E9 Encodings: TeX, pMML, png Clarification (effective with 1.0.18): The constraint $a,a^{\prime}>0$ , was replaced with $b_{1}+\cdots+b_{n}>a>0$ , $b_{j}\in\mathbb{R}$ . It therefore follows from (19.16.10) that $a^{\prime}>0$ . Suggested 2017-07-25 by Bastien Roucariès See also: Annotations for §19.16(ii), §19.16 and Ch.19

where $\mathrm{B}\left(x,y\right)$ is the beta function (§5.12) and

19.16.10		$a^{\prime}=-a+\sum_{j=1}^{n}b_{j}.$
ⓘ Symbols: $n$ : nonnegative integer Referenced by: (19.16.9), Erratum (V1.0.18) for Equation (19.16.9) Permalink: http://dlmf.nist.gov/19.16.E10 Encodings: TeX, pMML, png See also: Annotations for §19.16(ii), §19.16 and Ch.19

19.16.11		$\displaystyle R_{-a}\left(\mathbf{b};\lambda\mathbf{z}\right)$	$\displaystyle=\lambda^{-a}R_{-a}\left(\mathbf{b};\mathbf{z}\right),$
		$\displaystyle R_{-a}\left(\mathbf{b};x\boldsymbol{{1}}\right)$	$\displaystyle=x^{-a}$ ,
	$\boldsymbol{{1}}=(1,\dots,1)$ .
ⓘ Symbols: $R_{\NVar{-a}}\left(\NVar{b_{1}},\dots,\NVar{b_{n}};\NVar{z_{1}},\dots,\NVar{z_% {n}}\right)$ or $R_{\NVar{-a}}\left(\NVar{\mathbf{b}};\NVar{\mathbf{z}}\right)$ : multivariate hypergeometric function Referenced by: §19.19, §19.20(v) Permalink: http://dlmf.nist.gov/19.16.E11 Encodings: TeX, TeX, pMML, pMML, png, png See also: Annotations for §19.16(ii), §19.16 and Ch.19

When $n=4$ a useful version of (19.16.9) is given by

19.16.12		$R_{-a}\left(b_{1},\dots,b_{4};c-1,c-k^{2},c,c-\alpha^{2}\right)=\frac{2({\sin}% ^{2}\phi)^{1-a^{\prime}}}{\mathrm{B}\left(a,a^{\prime}\right)}\int_{0}^{\phi}(% \sin\theta)^{2a-1}{({\sin}^{2}\phi-{\sin}^{2}\theta)}^{a^{\prime}-1}\*(\cos% \theta)^{1-2b_{1}}{(1-k^{2}{\sin}^{2}\theta)}^{-b_{2}}{(1-\alpha^{2}{\sin}^{2}% \theta)}^{-b_{4}}\,\mathrm{d}\theta,$
ⓘ Symbols: $R_{\NVar{-a}}\left(\NVar{b_{1}},\dots,\NVar{b_{n}};\NVar{z_{1}},\dots,\NVar{z_% {n}}\right)$ or $R_{\NVar{-a}}\left(\NVar{\mathbf{b}};\NVar{\mathbf{z}}\right)$ : multivariate hypergeometric function, $\mathrm{B}\left(\NVar{a},\NVar{b}\right)$ : beta function, $\cos\NVar{z}$ : cosine function, $\,\mathrm{d}\NVar{x}$ : differential of $x$ , $\int$ : integral, $\sin\NVar{z}$ : sine function, $\phi$ : real or complex argument, $k$ : real or complex modulus and $\alpha^{2}$ : real or complex parameter Referenced by: §19.16(ii), §19.25(i) Permalink: http://dlmf.nist.gov/19.16.E12 Encodings: TeX, pMML, png See also: Annotations for §19.16(ii), §19.16 and Ch.19

where

19.16.13	$\displaystyle c$	$\displaystyle={\csc}^{2}\phi;$
	$\displaystyle a,a^{\prime}$	$\displaystyle>0;$
	$\displaystyle b_{3}$	$\displaystyle=a+a^{\prime}-b_{1}-b_{2}-b_{4}.$
ⓘ Symbols: $\csc\NVar{z}$ : cosecant function and $\phi$ : real or complex argument Permalink: http://dlmf.nist.gov/19.16.E13 Encodings: TeX, TeX, TeX, pMML, pMML, pMML, png, png, png See also: Annotations for §19.16(ii), §19.16 and Ch.19

For generalizations and further information, especially representation of the $R$ -function as a Dirichlet average, see Carlson (1977b).

§19.16(iii) Various Cases of $R_{-a}\left(\mathbf{b};\mathbf{z}\right)$

ⓘ

Keywords:: elliptic cases, elliptic cases of $R_{-a}(\mathbf{b};\mathbf{z})$ , hypergeometric $R$ -function, symmetric elliptic integrals
Notes:: For (19.16.19) and (19.16.23) see Carlson (1977b, (5.9-19) and (8.3-4)). To derive (19.16.24) exchange subscripts 1 and $n$ in Carlson (1963, (7.4)), put $t=s/z_{1}$ , and use (19.16.19).
Referenced by:: §19.2(iv), §19.23, §19.28, §19.31, §20.9(i), Erratum (V1.0.1) for Subsection 19.16(iii), Erratum (V1.0.1) for Clarifications
Permalink:: http://dlmf.nist.gov/19.16.iii
Errata (effective with 1.0.1):: Originally it was implied that $R_{C}\left(x,y\right)$ is an elliptic integral. It was clarified that $R_{-a}\left(\mathbf{b};\mathbf{z}\right)$ is an elliptic integral iff the stated conditions hold; originally these conditions were stated as sufficient but not necessary. In particular, $R_{C}\left(x,y\right)$ does not satisfy these conditions.
See also:: Annotations for §19.16 and Ch.19

$R_{-a}\left(\mathbf{b};\mathbf{z}\right)$ is an elliptic integral iff the $z$ ’s are distinct and exactly four of the parameters $a,a^{\prime},b_{1},\dots,b_{n}$ are half-odd-integers, the rest are integers, and none of $a$ , $a^{\prime}$ , $a+a^{\prime}$ is zero or a negative integer. The only cases that are integrals of the first kind are the four in which each of $a$ and $a^{\prime}$ is either $\frac{1}{2}$ or 1 and each $b_{j}$ is $\frac{1}{2}$ . The only cases that are integrals of the third kind are those in which at least one $b_{j}$ is a positive integer. All other elliptic cases are integrals of the second kind.

19.16.14	$\displaystyle R_{F}\left(x,y,z\right)$	$\displaystyle=R_{-\frac{1}{2}}\left(\tfrac{1}{2},\tfrac{1}{2},\tfrac{1}{2};x,y% ,z\right),$
ⓘ Symbols: $R_{\NVar{-a}}\left(\NVar{b_{1}},\dots,\NVar{b_{n}};\NVar{z_{1}},\dots,\NVar{z_% {n}}\right)$ or $R_{\NVar{-a}}\left(\NVar{\mathbf{b}};\NVar{\mathbf{z}}\right)$ : multivariate hypergeometric function and $R_{F}\left(\NVar{x},\NVar{y},\NVar{z}\right)$ : symmetric elliptic integral of first kind Referenced by: §19.16(iii), §19.18(i), §19.18(ii), §19.19, §19.19, §19.24(ii) Permalink: http://dlmf.nist.gov/19.16.E14 Encodings: TeX, pMML, png See also: Annotations for §19.16(iii), §19.16 and Ch.19
19.16.15	$\displaystyle R_{D}\left(x,y,z\right)$	$\displaystyle=R_{-\frac{3}{2}}\left(\tfrac{1}{2},\tfrac{1}{2},\tfrac{3}{2};x,y% ,z\right),$
ⓘ Symbols: $R_{\NVar{-a}}\left(\NVar{b_{1}},\dots,\NVar{b_{n}};\NVar{z_{1}},\dots,\NVar{z_% {n}}\right)$ or $R_{\NVar{-a}}\left(\NVar{\mathbf{b}};\NVar{\mathbf{z}}\right)$ : multivariate hypergeometric function and $R_{D}\left(\NVar{x},\NVar{y},\NVar{z}\right)$ : elliptic integral symmetric in only two variables Referenced by: §19.20(iv) Permalink: http://dlmf.nist.gov/19.16.E15 Encodings: TeX, pMML, png See also: Annotations for §19.16(iii), §19.16 and Ch.19
19.16.16	$\displaystyle R_{J}\left(x,y,z,p\right)$	$\displaystyle=R_{-\frac{3}{2}}\left(\tfrac{1}{2},\tfrac{1}{2},\tfrac{1}{2},1;x% ,y,z,p\right),$
ⓘ Symbols: $R_{\NVar{-a}}\left(\NVar{b_{1}},\dots,\NVar{b_{n}};\NVar{z_{1}},\dots,\NVar{z_% {n}}\right)$ or $R_{\NVar{-a}}\left(\NVar{\mathbf{b}};\NVar{\mathbf{z}}\right)$ : multivariate hypergeometric function and $R_{J}\left(\NVar{x},\NVar{y},\NVar{z},\NVar{p}\right)$ : symmetric elliptic integral of third kind Permalink: http://dlmf.nist.gov/19.16.E16 Encodings: TeX, pMML, png See also: Annotations for §19.16(iii), §19.16 and Ch.19
19.16.17	$\displaystyle R_{G}\left(x,y,z\right)$	$\displaystyle=R_{\frac{1}{2}}\left(\tfrac{1}{2},\tfrac{1}{2},\tfrac{1}{2};x,y,% z\right),$
ⓘ Symbols: $R_{\NVar{-a}}\left(\NVar{b_{1}},\dots,\NVar{b_{n}};\NVar{z_{1}},\dots,\NVar{z_% {n}}\right)$ or $R_{\NVar{-a}}\left(\NVar{\mathbf{b}};\NVar{\mathbf{z}}\right)$ : multivariate hypergeometric function and $R_{G}\left(\NVar{x},\NVar{y},\NVar{z}\right)$ : symmetric elliptic integral of second kind Referenced by: §19.16(iii), §19.24(ii) Permalink: http://dlmf.nist.gov/19.16.E17 Encodings: TeX, pMML, png See also: Annotations for §19.16(iii), §19.16 and Ch.19
19.16.18	$\displaystyle R_{C}\left(x,y\right)$	$\displaystyle=R_{-\frac{1}{2}}\left(\tfrac{1}{2},1;x,y\right).$
ⓘ Symbols: $R_{\NVar{-a}}\left(\NVar{b_{1}},\dots,\NVar{b_{n}};\NVar{z_{1}},\dots,\NVar{z_% {n}}\right)$ or $R_{\NVar{-a}}\left(\NVar{\mathbf{b}};\NVar{\mathbf{z}}\right)$ : multivariate hypergeometric function and $R_{C}\left(\NVar{x},\NVar{y}\right)$ : Carlson’s combination of inverse circular and inverse hyperbolic functions Referenced by: §19.18(i), §19.18(ii), §19.19, §19.19, §19.2(iv) Permalink: http://dlmf.nist.gov/19.16.E18 Encodings: TeX, pMML, png See also: Annotations for §19.16(iii), §19.16 and Ch.19

(Note that $R_{C}\left(x,y\right)$ is not an elliptic integral.)

When one variable is 0 without destroying convergence, any one of (19.16.14)–(19.16.17) is said to be complete and can be written as an $R$ -function with one less variable:

19.16.19		$R_{-a}\left(b_{1},\dots,b_{n};0,z_{2},\dots,z_{n}\right)=\frac{\mathrm{B}\left% (a,a^{\prime}-b_{1}\right)}{\mathrm{B}\left(a,a^{\prime}\right)}R_{-a}\left(b_% {2},\dots,b_{n};z_{2},\dots,z_{n}\right),$
$a+a^{\prime}>0$ , $a^{\prime}>b_{1}$ .
ⓘ Symbols: $R_{\NVar{-a}}\left(\NVar{b_{1}},\dots,\NVar{b_{n}};\NVar{z_{1}},\dots,\NVar{z_% {n}}\right)$ or $R_{\NVar{-a}}\left(\NVar{\mathbf{b}};\NVar{\mathbf{z}}\right)$ : multivariate hypergeometric function, $\mathrm{B}\left(\NVar{a},\NVar{b}\right)$ : beta function and $n$ : nonnegative integer Referenced by: §19.16(iii), §19.20(v) Permalink: http://dlmf.nist.gov/19.16.E19 Encodings: TeX, pMML, png See also: Annotations for §19.16(iii), §19.16 and Ch.19

Thus

19.16.20	$\displaystyle R_{F}\left(0,y,z\right)$	$\displaystyle=\tfrac{1}{2}\pi R_{-\frac{1}{2}}\left(\tfrac{1}{2},\tfrac{1}{2};% y,z\right),$
ⓘ Symbols: $R_{\NVar{-a}}\left(\NVar{b_{1}},\dots,\NVar{b_{n}};\NVar{z_{1}},\dots,\NVar{z_% {n}}\right)$ or $R_{\NVar{-a}}\left(\NVar{\mathbf{b}};\NVar{\mathbf{z}}\right)$ : multivariate hypergeometric function, $R_{F}\left(\NVar{x},\NVar{y},\NVar{z}\right)$ : symmetric elliptic integral of first kind and $\pi$ : the ratio of the circumference of a circle to its diameter Referenced by: §19.16(iii), §19.18(i), §19.18(ii), §19.18(ii), §19.19, §19.19, §19.22(ii), §19.24(ii), §19.24(i), §19.28 Permalink: http://dlmf.nist.gov/19.16.E20 Encodings: TeX, pMML, png See also: Annotations for §19.16(iii), §19.16 and Ch.19
19.16.21	$\displaystyle R_{D}\left(0,y,z\right)$	$\displaystyle=\tfrac{3}{4}\pi R_{-\frac{3}{2}}\left(\tfrac{1}{2},\tfrac{3}{2};% y,z\right),$
ⓘ Symbols: $R_{\NVar{-a}}\left(\NVar{b_{1}},\dots,\NVar{b_{n}};\NVar{z_{1}},\dots,\NVar{z_% {n}}\right)$ or $R_{\NVar{-a}}\left(\NVar{\mathbf{b}};\NVar{\mathbf{z}}\right)$ : multivariate hypergeometric function, $R_{D}\left(\NVar{x},\NVar{y},\NVar{z}\right)$ : elliptic integral symmetric in only two variables and $\pi$ : the ratio of the circumference of a circle to its diameter Referenced by: §19.9(i) Permalink: http://dlmf.nist.gov/19.16.E21 Encodings: TeX, pMML, png See also: Annotations for §19.16(iii), §19.16 and Ch.19
19.16.22	$\displaystyle R_{J}\left(0,y,z,p\right)$	$\displaystyle=\tfrac{3}{4}\pi R_{-\frac{3}{2}}\left(\tfrac{1}{2},\tfrac{1}{2},% 1;y,z,p\right),$
ⓘ Symbols: $R_{\NVar{-a}}\left(\NVar{b_{1}},\dots,\NVar{b_{n}};\NVar{z_{1}},\dots,\NVar{z_% {n}}\right)$ or $R_{\NVar{-a}}\left(\NVar{\mathbf{b}};\NVar{\mathbf{z}}\right)$ : multivariate hypergeometric function, $R_{J}\left(\NVar{x},\NVar{y},\NVar{z},\NVar{p}\right)$ : symmetric elliptic integral of third kind and $\pi$ : the ratio of the circumference of a circle to its diameter Referenced by: §19.24(i) Permalink: http://dlmf.nist.gov/19.16.E22 Encodings: TeX, pMML, png See also: Annotations for §19.16(iii), §19.16 and Ch.19
19.16.23	$\displaystyle R_{G}\left(0,y,z\right)$	$\displaystyle=\tfrac{1}{4}\pi R_{\frac{1}{2}}\left(\tfrac{1}{2},\tfrac{1}{2};y% ,z\right)=\tfrac{1}{4}\pi zR_{-\frac{1}{2}}\left(-\tfrac{1}{2},\tfrac{3}{2};y,% z\right).$
ⓘ Symbols: $R_{\NVar{-a}}\left(\NVar{b_{1}},\dots,\NVar{b_{n}};\NVar{z_{1}},\dots,\NVar{z_% {n}}\right)$ or $R_{\NVar{-a}}\left(\NVar{\mathbf{b}};\NVar{\mathbf{z}}\right)$ : multivariate hypergeometric function, $R_{G}\left(\NVar{x},\NVar{y},\NVar{z}\right)$ : symmetric elliptic integral of second kind and $\pi$ : the ratio of the circumference of a circle to its diameter Referenced by: §19.16(iii), §19.16(iii), §19.18(i), §19.18(ii), §19.18(ii), §19.19, §19.19, §19.22(ii), §19.24(ii), §19.24(i), §19.33(i) Permalink: http://dlmf.nist.gov/19.16.E23 Encodings: TeX, pMML, png See also: Annotations for §19.16(iii), §19.16 and Ch.19

The last $R$ -function has $a=a^{\prime}=\frac{1}{2}$ .

Each of the four complete integrals (19.16.20)–(19.16.23) can be integrated to recover the incomplete integral:

19.16.24		$R_{-a}\left(\mathbf{b};\mathbf{z}\right)=\frac{z_{1}^{a^{\prime}-b_{1}}}{% \mathrm{B}\left(b_{1},a^{\prime}-b_{1}\right)}\int_{0}^{\infty}t^{b_{1}-1}(t+z% _{1})^{-a^{\prime}}\*R_{-a}\left(\mathbf{b};0,t+z_{2},\dots,t+z_{n}\right)\,% \mathrm{d}t,$
$a^{\prime}>b_{1}$ , $a+a^{\prime}>b_{1}>0$ .
ⓘ Symbols: $R_{\NVar{-a}}\left(\NVar{b_{1}},\dots,\NVar{b_{n}};\NVar{z_{1}},\dots,\NVar{z_% {n}}\right)$ or $R_{\NVar{-a}}\left(\NVar{\mathbf{b}};\NVar{\mathbf{z}}\right)$ : multivariate hypergeometric function, $\mathrm{B}\left(\NVar{a},\NVar{b}\right)$ : beta function, $\,\mathrm{d}\NVar{x}$ : differential of $x$ , $\int$ : integral and $n$ : nonnegative integer Referenced by: §19.16(iii), §19.28 Permalink: http://dlmf.nist.gov/19.16.E24 Encodings: TeX, pMML, png See also: Annotations for §19.16(iii), §19.16 and Ch.19

19.15 Advantages of Symmetry 19.17 Graphics

Site Privacy Accessibility Privacy Program Copyrights Vulnerability Disclosure No Fear Act Policy FOIA Environmental Policy Scientific Integrity Information Quality Standards Commerce.gov Science.gov USA.gov

Note: This service is not intended for secure transactions such as banking, social media, email, or purchasing. Use at your own risk. We assume no liability whatsoever for broken pages.

§19.16 Definitions

Contents

§19.16(i) Symmetric Integrals

§19.16(ii) $R_{-a}\left(\mathbf{b};\mathbf{z}\right)$

§19.16(iii) Various Cases of $R_{-a}\left(\mathbf{b};\mathbf{z}\right)$

Pfad - The Proxy pFad of © 2024 Garber Painting. All rights reserved.

§19.16 Definitions

Contents

§19.16(i) Symmetric Integrals

§19.16(ii) R−a⁡(𝐛;𝐳)

§19.16(iii) Various Cases of R−a⁡(𝐛;𝐳)

Pfad - The Proxy pFad of © 2024 Garber Painting. All rights reserved.

§19.16(ii) $R_{-a}\left(\mathbf{b};\mathbf{z}\right)$

§19.16(iii) Various Cases of $R_{-a}\left(\mathbf{b};\mathbf{z}\right)$