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1: 36.6 Scaling Relations

… ►

\text{cuspoids: }\mathbf{y}(k)=\left(x_{1}k^{\gamma_{1K}},x_{2}k^{\gamma_{2K}}% ,\dots,x_{K}k^{\gamma_{KK}}\right),

… ►

Indices for $k$ -Scaling of Magnitude of $\Psi_{K}$ or $\Psi^{(\mathrm{U})}$ (Singularity Index)

►

\text{cuspoids: }\beta_{K}=\dfrac{K}{2(K+2)},

… ►

\text{cuspoids: }\gamma_{mK}=1-\dfrac{m}{K+2},

… ►

\text{cuspoids: }\gamma_{K}=\sum\limits_{m=1}^{K}\gamma_{mK}=\dfrac{K(K+3)}{2(% K+2)},

…

2: 24.2 Definitions and Generating Functions

… ►

Table 24.2.1: Bernoulli and Euler numbers.

► ►►►

$n$	$B_{n}$	$E_{n}$
…
$16$	$-\tfrac{3617}{510}$	$1\;93915\;12145$

► … ►

Table 24.2.3: Bernoulli numbers

B_{n}=N/D

► ►►►►

$n$	$N$	$D$	$B_{n}$
…
$16$	$-3617$	$510$	$-7.09215\;6863$
…
$32$	$-770\;93210\;41217$	$510$	$-1.51163\;1577$	$\times 10^{10}$
…

► …

3: 29.13 Graphics

… ►

See accompanying text — Figure 29.13.5: $\mathit{uE}^{m}_{4}\left(x,0.1\right)$ for $-2K\leq x\leq 2K$ , $m=0,1,2$ . $K=1.61244\dotsc$ . Magnify

►

…

4: 29.10 Lamé Functions with Imaginary Periods

… ►

29.10.2

z^{\prime}=\mathrm{i}(z-K-\mathrm{i}{K^{\prime}}),

ⓘ

Symbols:: ${K^{\prime}}\left(\NVar{k}\right)$ : Legendre’s complementary complete elliptic integral of the first kind, $K\left(\NVar{k}\right)$ : Legendre’s complete elliptic integral of the first kind, $\mathrm{i}$ : imaginary unit, $z$ : complex variable and $k$ : real parameter
Permalink:: http://dlmf.nist.gov/29.10.E2
Encodings:: pMML, png, TeX
See also:: Annotations for §29.10 and Ch.29

… ►

\mathit{Ec}^{2m}_{\nu}\left(\mathrm{i}(z-K-\mathrm{i}{K^{\prime}}),{k^{\prime}% }^{2}\right),

►

\mathit{Ec}^{2m+1}_{\nu}\left(\mathrm{i}(z-K-\mathrm{i}{K^{\prime}}),{k^{% \prime}}^{2}\right),

►

\mathit{Es}^{2m+1}_{\nu}\left(\mathrm{i}(z-K-\mathrm{i}{K^{\prime}}),{k^{% \prime}}^{2}\right),

… ►The first and the fourth functions have period

2\mathrm{i}{K^{\prime}}

; the second and the third have period

4\mathrm{i}{K^{\prime}}

. …

5: 22.21 Tables

… ►Spenceley and Spenceley (1947) tabulates

\operatorname{sn}\left(Kx,k\right)

\operatorname{cn}\left(Kx,k\right)

\operatorname{dn}\left(Kx,k\right)

\operatorname{am}\left(Kx,k\right)

\mathcal{E}\left(Kx,k\right)

for

\operatorname{arcsin}k=1^{\circ}(1^{\circ})89^{\circ}

and

x=0\left(\tfrac{1}{90}\right)1

to 12D, or 12 decimals of a radian in the case of

\operatorname{am}\left(Kx,k\right)

. ►Curtis (1964b) tabulates

\operatorname{sn}\left(mK/n,k\right)

\operatorname{cn}\left(mK/n,k\right)

\operatorname{dn}\left(mK/n,k\right)

for

n=2(1)15

m=1(1)n-1

, and

q

(not

k

)

=0(.005)0.35

to 20D. … ►Zhang and Jin (1996, p. 678) tabulates

\operatorname{sn}\left(Kx,k\right)

\operatorname{cn}\left(Kx,k\right)

\operatorname{dn}\left(Kx,k\right)

for

k=\frac{1}{4},\frac{1}{2}

and

x=0(.1)4

to 7D. …

6: 29.14 Orthogonality

… ►

29.14.2

\langle g,h\rangle=\int_{0}^{K}\!\!\int_{0}^{{K^{\prime}}}w(s,t)g(s,t)h(s,t)\,% \mathrm{d}t\,\mathrm{d}s,

ⓘ

Symbols:: ${K^{\prime}}\left(\NVar{k}\right)$ : Legendre’s complementary complete elliptic integral of the first kind, $K\left(\NVar{k}\right)$ : Legendre’s complete elliptic integral of the first kind, $\,\mathrm{d}\NVar{x}$ : differential of $x$ , $\int$ : integral, $k$ : real parameter and $w(s,t)$ : function
Referenced by:: §29.14
Permalink:: http://dlmf.nist.gov/29.14.E2
Encodings:: pMML, png, TeX
See also:: Annotations for §29.14 and Ch.29

… ►

29.14.3

w(s,t)={\operatorname{sn}}^{2}\left(K+\mathrm{i}t,k\right)-{\operatorname{sn}}% ^{2}\left(s,k\right).

ⓘ

Symbols:: $\operatorname{sn}\left(\NVar{z},\NVar{k}\right)$ : Jacobian elliptic function, $K\left(\NVar{k}\right)$ : Legendre’s complete elliptic integral of the first kind, $\mathrm{i}$ : imaginary unit, $k$ : real parameter and $w(s,t)$ : function
Referenced by:: §29.14
Permalink:: http://dlmf.nist.gov/29.14.E3
Encodings:: pMML, png, TeX
See also:: Annotations for §29.14 and Ch.29

… ►

29.14.4

\mathit{sE}^{m}_{2n+1}\left(s,k^{2}\right)\mathit{sE}^{m}_{2n+1}\left(K+% \mathrm{i}t,k^{2}\right),

ⓘ

Symbols:: $\mathit{sE}^{\NVar{m}}_{2\NVar{n}+1}\left(\NVar{z},\NVar{k^{2}}\right)$ : Lamé polynomial, $K\left(\NVar{k}\right)$ : Legendre’s complete elliptic integral of the first kind, $\mathrm{i}$ : imaginary unit, $m$ : nonnegative integer, $n$ : nonnegative integer and $k$ : real parameter
Referenced by:: §29.14
Permalink:: http://dlmf.nist.gov/29.14.E4
Encodings:: pMML, png, TeX
See also:: Annotations for §29.14 and Ch.29

►

29.14.5

\mathit{cE}^{m}_{2n+1}\left(s,k^{2}\right)\mathit{cE}^{m}_{2n+1}\left(K+% \mathrm{i}t,k^{2}\right),

ⓘ

Symbols:: $\mathit{cE}^{\NVar{m}}_{2\NVar{n}+1}\left(\NVar{z},\NVar{k^{2}}\right)$ : Lamé polynomial, $K\left(\NVar{k}\right)$ : Legendre’s complete elliptic integral of the first kind, $\mathrm{i}$ : imaginary unit, $m$ : nonnegative integer, $n$ : nonnegative integer and $k$ : real parameter
Permalink:: http://dlmf.nist.gov/29.14.E5
Encodings:: pMML, png, TeX
See also:: Annotations for §29.14 and Ch.29

… ►

29.14.11

\langle g,h\rangle=\int_{0}^{4K}\!\!\int_{0}^{2{K^{\prime}}}w(s,t)g(s,t)h(s,t)% \,\mathrm{d}t\,\mathrm{d}s,

ⓘ

Symbols:: ${K^{\prime}}\left(\NVar{k}\right)$ : Legendre’s complementary complete elliptic integral of the first kind, $K\left(\NVar{k}\right)$ : Legendre’s complete elliptic integral of the first kind, $\,\mathrm{d}\NVar{x}$ : differential of $x$ , $\int$ : integral, $k$ : real parameter and $w(s,t)$ : function
Permalink:: http://dlmf.nist.gov/29.14.E11
Encodings:: pMML, png, TeX
See also:: Annotations for §29.14 and Ch.29

…

7: 32.5 Integral Equations

… ►Let

K(z,\zeta)

be the solution of ►

32.5.1

K(z,\zeta)=k\operatorname{Ai}\left(\frac{z+\zeta}{2}\right)+\frac{k^{2}}{4}\*% \int_{z}^{\infty}\!\!\!\int_{z}^{\infty}K(z,s)\operatorname{Ai}\left(\frac{s+t% }{2}\right)\operatorname{Ai}\left(\frac{t+\zeta}{2}\right)\,\mathrm{d}s\,% \mathrm{d}t,

ⓘ

Symbols:: $\operatorname{Ai}\left(\NVar{z}\right)$ : Airy function, $\,\mathrm{d}\NVar{x}$ : differential of $x$ , $\int$ : integral, $z$ : real, $k$ : real and $K(z,\zeta)$ : solution
Permalink:: http://dlmf.nist.gov/32.5.E1
Encodings:: pMML, png, TeX
See also:: Annotations for §32.5 and Ch.32

… ►

32.5.2

w(z)=K(z,z),

ⓘ

Symbols:: $z$ : real and $K(z,\zeta)$ : solution
Permalink:: http://dlmf.nist.gov/32.5.E2
Encodings:: pMML, png, TeX
See also:: Annotations for §32.5 and Ch.32

…

8: 22.3 Graphics

… ►

►

…

9: 22.4 Periods, Poles, and Zeros

… ►Figure 22.4.1 illustrates the locations in the

z

-plane of the poles and zeros of the three principal Jacobian functions in the rectangle with vertices

0

2K

2K+2iK^{\prime}

2iK^{\prime}

. … ►Figure 22.4.2 depicts the fundamental unit cell in the

z

-plane, with vertices

\mbox{s}=0

\mbox{c}=K

\mbox{d}=K+iK^{\prime}

\mbox{n}=iK^{\prime}

. The set of points

z=mK+niK^{\prime}

m,n\in\mathbb{Z}

, comprise the lattice for the 12 Jacobian functions; all other lattice unit cells are generated by translation of the fundamental unit cell by

mK+niK^{\prime}

, where again

m,n\in\mathbb{Z}

. … ►This half-period will be plus or minus a member of the triple

{K,iK^{\prime},K+iK^{\prime}}

; the other two members of this triple are quarter periods of

\operatorname{pq}\left(z,k\right)

. … ►For example,

\operatorname{sn}\left(z+K,k\right)=\operatorname{cd}\left(z,k\right)

. …

10: 29.4 Graphics

… ►

►

…