Bailey 2F1(-1) sum

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1: 17.12 Bailey Pairs

§17.12 Bailey Pairs

►

Bailey Transform

… ►

Bailey Pairs

… ►

Weak Bailey Lemma

… ►

Strong Bailey Lemma

…

2: 32.10 Special Function Solutions

… ►For example, if

\alpha=\tfrac{1}{2}\varepsilon

, with

\varepsilon=\pm 1

, then the Riccati equation is … ►with

n\in\mathbb{Z}

, and

\varepsilon_{1}=\pm 1

\varepsilon_{2}=\pm 1

, independently. … ►with

n\in\mathbb{Z}

and

\varepsilon=\pm 1

. … ►where

n\in\mathbb{Z}

a=\varepsilon_{1}\sqrt{2\alpha}

, and

b=\varepsilon_{2}\sqrt{-2\beta}

, with

\varepsilon_{j}=\pm 1

j=1,2,3

, independently. … ►where

n\in\mathbb{Z}

a=\varepsilon_{1}\sqrt{2\alpha}

b=\varepsilon_{2}\sqrt{-2\beta}

c=\varepsilon_{3}\sqrt{2\gamma}

, and

d=\varepsilon_{4}\sqrt{1-2\delta}

, with

\varepsilon_{j}=\pm 1

j=1,2,3,4

, independently. …

3: 4.24 Inverse Trigonometric Functions: Further Properties

… ►

4.24.13

\operatorname{Arcsin}u\pm\operatorname{Arcsin}v=\operatorname{Arcsin}\left(u(1% -v^{2})^{1/2}\pm v(1-u^{2})^{1/2}\right),

ⓘ

Symbols:: $\operatorname{Arcsin}\NVar{z}$ : general arcsine function
A&S Ref:: 4.4.32
Permalink:: http://dlmf.nist.gov/4.24.E13
Encodings:: pMML, png, TeX
See also:: Annotations for §4.24(iii), §4.24 and Ch.4

►

4.24.14

\operatorname{Arccos}u\pm\operatorname{Arccos}v=\operatorname{Arccos}\left(uv% \mp((1-u^{2})(1-v^{2}))^{1/2}\right),

ⓘ

Symbols:: $\operatorname{Arccos}\NVar{z}$ : general arccosine function
A&S Ref:: 4.4.33
Permalink:: http://dlmf.nist.gov/4.24.E14
Encodings:: pMML, png, TeX
See also:: Annotations for §4.24(iii), §4.24 and Ch.4

►

4.24.15

\operatorname{Arctan}u\pm\operatorname{Arctan}v=\operatorname{Arctan}\left(% \frac{u\pm v}{1\mp uv}\right),

ⓘ

Symbols:: $\operatorname{Arctan}\NVar{z}$ : general arctangent function
A&S Ref:: 4.4.34
Referenced by:: §4.45(i)
Permalink:: http://dlmf.nist.gov/4.24.E15
Encodings:: pMML, png, TeX
See also:: Annotations for §4.24(iii), §4.24 and Ch.4

►

4.24.16

\operatorname{Arcsin}u\pm\operatorname{Arccos}v=\operatorname{Arcsin}\left(uv% \pm((1-u^{2})(1-v^{2}))^{1/2}\right)=\operatorname{Arccos}\left(v(1-u^{2})^{1/% 2}\mp u(1-v^{2})^{1/2}\right),

ⓘ

Symbols:: $\operatorname{Arccos}\NVar{z}$ : general arccosine function and $\operatorname{Arcsin}\NVar{z}$ : general arcsine function
A&S Ref:: 4.4.35
Permalink:: http://dlmf.nist.gov/4.24.E16
Encodings:: pMML, png, TeX
See also:: Annotations for §4.24(iii), §4.24 and Ch.4

►

4.24.17

\operatorname{Arctan}u\pm\operatorname{Arccot}v=\operatorname{Arctan}\left(% \frac{uv\pm 1}{v\mp u}\right)=\operatorname{Arccot}\left(\frac{v\mp u}{uv\pm 1% }\right).

ⓘ

Symbols:: $\operatorname{Arccot}\NVar{z}$ : general arccotangent function and $\operatorname{Arctan}\NVar{z}$ : general arctangent function
A&S Ref:: 4.4.36
Permalink:: http://dlmf.nist.gov/4.24.E17
Encodings:: pMML, png, TeX
See also:: Annotations for §4.24(iii), §4.24 and Ch.4

…

4: 4.38 Inverse Hyperbolic Functions: Further Properties

… ►

4.38.5

\operatorname{arctanh}z=z+\frac{z^{3}}{3}+\frac{z^{5}}{5}+\frac{z^{7}}{7}+\cdots,

\left|z\right|\leq 1

z\neq\pm 1

ⓘ

Symbols:: $\operatorname{arctanh}\NVar{z}$ : inverse hyperbolic tangent function and $z$ : complex variable
A&S Ref:: 4.6.33
Permalink:: http://dlmf.nist.gov/4.38.E5
Encodings:: pMML, png, TeX
See also:: Annotations for §4.38(i), §4.38 and Ch.4

… ►

4.38.15

\operatorname{Arcsinh}u\pm\operatorname{Arcsinh}v=\operatorname{Arcsinh}\left(% u(1+v^{2})^{1/2}\pm v(1+u^{2})^{1/2}\right),

ⓘ

Symbols:: $\operatorname{Arcsinh}\NVar{z}$ : general inverse hyperbolic sine function
A&S Ref:: 4.6.26
Permalink:: http://dlmf.nist.gov/4.38.E15
Encodings:: pMML, png, TeX
See also:: Annotations for §4.38(iii), §4.38 and Ch.4

… ►

4.38.17

\operatorname{Arctanh}u\pm\operatorname{Arctanh}v=\operatorname{Arctanh}\left(% \frac{u\pm v}{1\pm uv}\right),

ⓘ

Symbols:: $\operatorname{Arctanh}\NVar{z}$ : general inverse hyperbolic tangent function
A&S Ref:: 4.6.28
Permalink:: http://dlmf.nist.gov/4.38.E17
Encodings:: pMML, png, TeX
See also:: Annotations for §4.38(iii), §4.38 and Ch.4

►

4.38.18

\operatorname{Arcsinh}u\pm\operatorname{Arccosh}v=\operatorname{Arcsinh}\left(% uv\pm((1+u^{2})(v^{2}-1))^{1/2}\right)=\operatorname{Arccosh}\left(v(1+u^{2})^% {1/2}\pm u(v^{2}-1)^{1/2}\right),

ⓘ

Symbols:: $\operatorname{Arccosh}\NVar{z}$ : general inverse hyperbolic cosine function and $\operatorname{Arcsinh}\NVar{z}$ : general inverse hyperbolic sine function
A&S Ref:: 4.6.29
Permalink:: http://dlmf.nist.gov/4.38.E18
Encodings:: pMML, png, TeX
See also:: Annotations for §4.38(iii), §4.38 and Ch.4

►

4.38.19

\operatorname{Arctanh}u\pm\operatorname{Arccoth}v=\operatorname{Arctanh}\left(% \frac{uv\pm 1}{v\pm u}\right)=\operatorname{Arccoth}\left(\frac{v\pm u}{uv\pm 1% }\right).

ⓘ

Symbols:: $\operatorname{Arccoth}\NVar{z}$ : general inverse hyperbolic cotangent function and $\operatorname{Arctanh}\NVar{z}$ : general inverse hyperbolic tangent function
A&S Ref:: 4.6.30
Permalink:: http://dlmf.nist.gov/4.38.E19
Encodings:: pMML, png, TeX
See also:: Annotations for §4.38(iii), §4.38 and Ch.4

…

5: 4.13 Lambert $W$ -Function

… ►The decreasing solution can be identified as

W_{\pm 1}\left(x\mp 0\mathrm{i}\right)

. …where

{\rm ln}_{k}(z)=\ln\left(z\right)+2\pi\mathrm{i}k

W_{0}\left(z\right)

is a single-valued analytic function on

\mathbb{C}\setminus(-\infty,-{\mathrm{e}}^{-1}]

, real-valued when

z>-{\mathrm{e}}^{-1}

, and has a square root branch point at

z=-{\mathrm{e}}^{-1}

. …The other branches

W_{k}\left(z\right)

are single-valued analytic functions on

\mathbb{C}\setminus(-\infty,0]

, have a logarithmic branch point at

z=0

, and, in the case

k=\pm 1

, have a square root branch point at

z=-{\mathrm{e}}^{-1}\mp 0\mathrm{i}

respectively. … ►where

t\geq 0

for

W_{0}

t\leq 0

for

W_{\pm 1}

on the relevant branch cuts, …

6: 5.5 Functional Relations

… ►

5.5.3

\Gamma\left(z\right)\Gamma\left(1-z\right)=\pi/\sin\left(\pi z\right),

z\neq 0,\pm 1,\dots

ⓘ

Symbols:: $\Gamma\left(\NVar{z}\right)$ : gamma function, $\pi$ : the ratio of the circumference of a circle to its diameter, $\sin\NVar{z}$ : sine function and $z$ : complex variable
A&S Ref:: 6.1.17 (without the condition on $z$ .)
Referenced by:: §10.19(i), §15.4(ii), §15.8(ii), (25.9.2), §5.21, (9.10.18), (9.12.15)
Permalink:: http://dlmf.nist.gov/5.5.E3
Encodings:: pMML, png, TeX
See also:: Annotations for §5.5(ii), §5.5 and Ch.5

►

5.5.4

\psi\left(z\right)-\psi\left(1-z\right)=-\pi/\tan\left(\pi z\right),

z\neq 0,\pm 1,\dots

ⓘ

Symbols:: $\pi$ : the ratio of the circumference of a circle to its diameter, $\psi\left(\NVar{z}\right)$ : psi (or digamma) function, $\tan\NVar{z}$ : tangent function and $z$ : complex variable
A&S Ref:: 6.3.7 (without the condition on $z$ .)
Permalink:: http://dlmf.nist.gov/5.5.E4
Encodings:: pMML, png, TeX
See also:: Annotations for §5.5(ii), §5.5 and Ch.5

… ►For

2z\neq 0,-1,-2,\dots

, … ►For

nz\neq 0,-1,-2,\dots

, … ►

5.5.8

\psi\left(2z\right)=\tfrac{1}{2}\left(\psi\left(z\right)+\psi\left(z+\tfrac{1}% {2}\right)\right)+\ln 2,

ⓘ

Symbols:: $\psi\left(\NVar{z}\right)$ : psi (or digamma) function, $\ln\NVar{z}$ : principal branch of logarithm function and $z$ : complex variable
A&S Ref:: 6.3.8
Referenced by:: §5.5(iii)
Permalink:: http://dlmf.nist.gov/5.5.E8
Encodings:: pMML, png, TeX
See also:: Annotations for §5.5(iii), §5.5(iii), §5.5 and Ch.5

…

7: 32.8 Rational Solutions

… ►Then for

n\geq 2

… ►Then

\mbox{P}_{\mbox{\scriptsize V}}

has a rational solution iff one of the following holds with

m,n\in\mathbb{Z}

and

\varepsilon=\pm 1

: … ►

(c)

$\alpha=\tfrac{1}{2}a^{2}$ , $\beta=-\tfrac{1}{2}(a+n)^{2}$ , and $\gamma=m$ , with $m+n$ even.

►

(d)

$\alpha=\tfrac{1}{2}(b+n)^{2}$ , $\beta=-\tfrac{1}{2}b^{2}$ , and $\gamma=m$ , with $m+n$ even.

… ►where

n\in\mathbb{Z}

a=\varepsilon_{1}\sqrt{2\alpha}

b=\varepsilon_{2}\sqrt{-2\beta}

c=\varepsilon_{3}\sqrt{2\gamma}

, and

d=\varepsilon_{4}\sqrt{1-2\delta}

, with

\varepsilon_{j}=\pm 1

j=1,2,3,4

, independently, and at least one of

a

b

c

d

is an integer. …

8: 10.38 Derivatives with Respect to Order

… ►

10.38.1

\frac{\partial I_{\pm\nu}\left(z\right)}{\partial\nu}=\pm I_{\pm\nu}\left(z% \right)\ln\left(\tfrac{1}{2}z\right)\mp(\tfrac{1}{2}z)^{\pm\nu}\sum_{k=0}^{% \infty}\frac{\psi\left(k+1\pm\nu\right)}{\Gamma\left(k+1\pm\nu\right)}\frac{(% \frac{1}{4}z^{2})^{k}}{k!},

ⓘ

Symbols:: $\Gamma\left(\NVar{z}\right)$ : gamma function, $\psi\left(\NVar{z}\right)$ : psi (or digamma) function, $!$ : factorial (as in $n!$ ), $I_{\NVar{\nu}}\left(\NVar{z}\right)$ : modified Bessel function of the first kind, $\ln\NVar{z}$ : principal branch of logarithm function, $\frac{\partial\NVar{f}}{\partial\NVar{x}}$ : partial derivative of $f$ with respect to $x$ , $\,\partial\NVar{x}$ : partial differential of $x$ , $k$ : nonnegative integer, $z$ : complex variable and $\nu$ : complex parameter
A&S Ref:: 9.6.42
Referenced by:: §10.38, §10.38, Erratum (V1.0.17) for Equations (10.15.1), (10.38.1)
Permalink:: http://dlmf.nist.gov/10.38.E1
Encodings:: pMML, png, TeX
Addition (effective with 1.0.17):: This equation has been generalized to include the additional case of $\ifrac{\partial I_{-\nu}\left(z\right)}{\partial\nu}$ because it will help the user who wants to combine it with (10.38.2).
See also:: Annotations for §10.38 and Ch.10

… ►

10.38.3

\left.(-1)^{n}\frac{\partial I_{\nu}\left(z\right)}{\partial\nu}\right|_{\nu=n% }=-K_{n}\left(z\right)+\frac{n!}{2(\frac{1}{2}z)^{n}}\sum_{k=0}^{n-1}(-1)^{k}% \frac{(\frac{1}{2}z)^{k}I_{k}\left(z\right)}{k!(n-k)},

ⓘ

Symbols:: $!$ : factorial (as in $n!$ ), $I_{\NVar{\nu}}\left(\NVar{z}\right)$ : modified Bessel function of the first kind, $K_{\NVar{\nu}}\left(\NVar{z}\right)$ : modified Bessel function of the second kind, $\frac{\partial\NVar{f}}{\partial\NVar{x}}$ : partial derivative of $f$ with respect to $x$ , $\,\partial\NVar{x}$ : partial differential of $x$ , $n$ : integer, $k$ : nonnegative integer, $z$ : complex variable and $\nu$ : complex parameter
A&S Ref:: 9.6.44
Referenced by:: §10.38
Permalink:: http://dlmf.nist.gov/10.38.E3
Encodings:: pMML, png, TeX
See also:: Annotations for §10.38, §10.38 and Ch.10

… ►

10.38.4

\left.\frac{\partial K_{\nu}\left(z\right)}{\partial\nu}\right|_{\nu=n}=\frac{% n!}{2(\frac{1}{2}z)^{n}}\sum_{k=0}^{n-1}\frac{(\frac{1}{2}z)^{k}K_{k}\left(z% \right)}{k!(n-k)}.

ⓘ

Symbols:: $!$ : factorial (as in $n!$ ), $K_{\NVar{\nu}}\left(\NVar{z}\right)$ : modified Bessel function of the second kind, $\frac{\partial\NVar{f}}{\partial\NVar{x}}$ : partial derivative of $f$ with respect to $x$ , $\,\partial\NVar{x}$ : partial differential of $x$ , $n$ : integer, $k$ : nonnegative integer, $z$ : complex variable and $\nu$ : complex parameter
A&S Ref:: 9.6.45
Referenced by:: §10.38
Permalink:: http://dlmf.nist.gov/10.38.E4
Encodings:: pMML, png, TeX
See also:: Annotations for §10.38, §10.38 and Ch.10

… ►

10.38.6

\left.\frac{\partial I_{\nu}\left(x\right)}{\partial\nu}\right|_{\nu=\pm\frac{% 1}{2}}=-\frac{1}{\sqrt{2\pi x}}\left(E_{1}\left(2x\right)e^{x}\pm\operatorname% {Ei}\left(2x\right)e^{-x}\right),

ⓘ

Symbols:: $\pi$ : the ratio of the circumference of a circle to its diameter, $\mathrm{e}$ : base of natural logarithm, $E_{1}\left(\NVar{z}\right)$ : exponential integral, $\operatorname{Ei}\left(\NVar{x}\right)$ : exponential integral, $I_{\NVar{\nu}}\left(\NVar{z}\right)$ : modified Bessel function of the first kind, $\frac{\partial\NVar{f}}{\partial\NVar{x}}$ : partial derivative of $f$ with respect to $x$ , $\,\partial\NVar{x}$ : partial differential of $x$ , $x$ : real variable and $\nu$ : complex parameter
A&S Ref:: 10.2.32 and 10.2.33 (both corrected)
Referenced by:: §10.38, Ch.10
Permalink:: http://dlmf.nist.gov/10.38.E6
Encodings:: pMML, png, TeX
See also:: Annotations for §10.38, §10.38 and Ch.10

►

10.38.7

\left.\frac{\partial K_{\nu}\left(x\right)}{\partial\nu}\right|_{\nu=\pm\frac{% 1}{2}}=\pm\sqrt{\frac{\pi}{2x}}E_{1}\left(2x\right)e^{x}.

ⓘ

Symbols:: $\pi$ : the ratio of the circumference of a circle to its diameter, $\mathrm{e}$ : base of natural logarithm, $E_{1}\left(\NVar{z}\right)$ : exponential integral, $K_{\NVar{\nu}}\left(\NVar{z}\right)$ : modified Bessel function of the second kind, $\frac{\partial\NVar{f}}{\partial\NVar{x}}$ : partial derivative of $f$ with respect to $x$ , $\,\partial\NVar{x}$ : partial differential of $x$ , $x$ : real variable and $\nu$ : complex parameter
A&S Ref:: 10.2.34 (corrected)
Referenced by:: §10.38, Ch.10
Permalink:: http://dlmf.nist.gov/10.38.E7
Encodings:: pMML, png, TeX
See also:: Annotations for §10.38, §10.38 and Ch.10

…

9: 14.28 Sums

§14.28 Sums

… ►where the branches of the square roots have their principal values when

z_{1},z_{2}\in(1,\infty)

and are continuous when

z_{1},z_{2}\in\mathbb{C}\setminus(0,1]

. … ►where

\mathcal{E}_{1}

and

\mathcal{E}_{2}

are ellipses with foci at

\pm 1

\mathcal{E}_{2}

being properly interior to

\mathcal{E}_{1}

. The series converges uniformly for

z_{1}

outside or on

\mathcal{E}_{1}

, and

z_{2}

within or on

\mathcal{E}_{2}

. … ►

§14.28(iii) Other Sums

…

10: 18.18 Sums

… ►Let

f(z)

be analytic within an ellipse

E

with foci

z=\pm 1

, and … ►See §3.11(ii), or set

\alpha=\beta=\pm\tfrac{1}{2}

in the above results for Jacobi and refer to (18.7.3)–(18.7.6). … ►In all three cases of Jacobi, Laguerre and Hermite, if

f(x)

L^{2}

on the corresponding interval with respect to the corresponding weight function and if

a_{n},b_{n},d_{n}

are given by (18.18.1), (18.18.5), (18.18.7), respectively, then the respective series expansions (18.18.2), (18.18.4), (18.18.6) are valid with the sums converging in

L^{2}

sense. … ►For the Poisson kernel of Jacobi polynomials (the Bailey formula) see Bailey (1938). ►

§18.18(viii) Other Sums

…

Bailey 2F1(-1) sum

1—10 of 817 matching pages

1: 17.12 Bailey Pairs

§17.12 Bailey Pairs

Bailey Transform

Bailey Pairs

Weak Bailey Lemma

Strong Bailey Lemma

2: 32.10 Special Function Solutions

3: 4.24 Inverse Trigonometric Functions: Further Properties

4: 4.38 Inverse Hyperbolic Functions: Further Properties

5: 4.13 Lambert W -Function

6: 5.5 Functional Relations

7: 32.8 Rational Solutions

8: 10.38 Derivatives with Respect to Order

9: 14.28 Sums

§14.28 Sums

§14.28(iii) Other Sums

10: 18.18 Sums

§18.18(viii) Other Sums

5: 4.13 Lambert $W$ -Function