hyperbolic cases

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1—10 of 47 matching pages

2: 19.20 Special Cases

… ►where

x, y, z

may be permuted. ►When the variables are real and distinct, the various cases of

R_{J}\left(x,y,z,p\right)

are called circular (hyperbolic) cases if

(p-x)(p-y)(p-z)

is positive (negative), because they typically occur in conjunction with inverse circular (hyperbolic) functions. Cases encountered in dynamical problems are usually circular; hyperbolic cases include Cauchy principal values. … ►

19.20.17

(q+z)R_{J}\left(0,y,z,-q\right)=(p-z)R_{J}\left(0,y,z,p\right)-3R_{F}\left(0,y% ,z\right),

p=z(y+q)/(z+q)

w=z/(z+q)

ⓘ

Symbols:: $R_{F}\left(\NVar{x},\NVar{y},\NVar{z}\right)$ : symmetric elliptic integral of first kind and $R_{J}\left(\NVar{x},\NVar{y},\NVar{z},\NVar{p}\right)$ : symmetric elliptic integral of third kind
Referenced by:: §19.20(iii)
Permalink:: http://dlmf.nist.gov/19.20.E17
Encodings:: pMML, png, TeX
See also:: Annotations for §19.20(iii), §19.20 and Ch.19

…

3: 19.7 Connection Formulas

… ►

§19.7(iii) Change of Parameter of $\Pi\left(\phi,\alpha^{2},k\right)$

… ►If

k^{2}

and

\alpha^{2}

are real, then both integrals are circular cases or both are hyperbolic cases (see §19.2(ii)). ►The first of the three relations maps each circular region onto itself and each hyperbolic region onto the other; in particular, it gives the Cauchy principal value of

\Pi\left(\phi,\alpha^{2},k\right)

when

\alpha^{2}>{\csc}^{2}\phi

(see (19.6.5) for the complete case). …

4: 19.21 Connection Formulas

… ►

19.21.15

pR_{J}\left(0,y,z,p\right)+qR_{J}\left(0,y,z,q\right)=3R_{F}\left(0,y,z\right),

pq=yz

ⓘ

Symbols:: $R_{F}\left(\NVar{x},\NVar{y},\NVar{z}\right)$ : symmetric elliptic integral of first kind and $R_{J}\left(\NVar{x},\NVar{y},\NVar{z},\NVar{p}\right)$ : symmetric elliptic integral of third kind
Permalink:: http://dlmf.nist.gov/19.21.E15
Encodings:: pMML, png, TeX
See also:: Annotations for §19.21(iii), §19.21 and Ch.19

5: 19.6 Special Cases

… ►Circular and hyperbolic cases, including Cauchy principal values, are unified by using

R_{C}\left(x,y\right)

. …

6: 19.36 Methods of Computation

… ►The step from

n

n+1

is an ascending Landen transformation if

\theta=1

(leading ultimately to a hyperbolic case of

R_{C}

) or a descending Gauss transformation if

\theta=-1

(leading to a circular case of

R_{C}

). …

7: 22.5 Special Values

… ►In these cases the elliptic functions degenerate into elementary trigonometric and hyperbolic functions, respectively. …

8: 13.20 Uniform Asymptotic Approximations for Large $\mu$

… ►(a) In the case

-\mu<\kappa<\mu

►

13.20.9

\zeta\sqrt{\zeta^{2}+\alpha^{2}}+\alpha^{2}\operatorname{arcsinh}\left(\frac{% \zeta}{\alpha}\right)=\frac{X}{\mu}-\frac{2\kappa}{\mu}\ln\left(\frac{X+x-2% \kappa}{2\sqrt{\mu^{2}-\kappa^{2}}}\right)-2\ln\left(\frac{\mu X+2\mu^{2}-% \kappa x}{x\sqrt{\mu^{2}-\kappa^{2}}}\right).

ⓘ

Symbols:: $\operatorname{arcsinh}\NVar{z}$ : inverse hyperbolic sine function, $\ln\NVar{z}$ : principal branch of logarithm function, $x$ : real variable, $\alpha$ and $X$
Permalink:: http://dlmf.nist.gov/13.20.E9
Encodings:: pMML, png, TeX
See also:: Annotations for §13.20(iii), §13.20 and Ch.13

►(b) In the case

\mu=\kappa

… ►(In both cases (a) and (b) the

x

-interval

(0,\infty)

is mapped one-to-one onto the

\zeta

-interval

(-\infty,\infty)

, with

x=0

and

\infty

corresponding to

\zeta=-\infty

and

\infty

, respectively.) … ►

13.20.13

\zeta\sqrt{\zeta^{2}-\alpha^{2}}-\alpha^{2}\operatorname{arccosh}\left(\frac{% \zeta}{\alpha}\right)=\frac{X}{\mu}-\frac{2\kappa}{\mu}\ln\left(\frac{X+x-2% \kappa}{2\sqrt{\kappa^{2}-\mu^{2}}}\right)-2\ln\left(\frac{\kappa x-\mu X-2\mu% ^{2}}{x\sqrt{\kappa^{2}-\mu^{2}}}\right),

x\geq 2\kappa+2\sqrt{\kappa^{2}-\mu^{2}}

ⓘ

Symbols:: $\operatorname{arccosh}\NVar{z}$ : inverse hyperbolic cosine function, $\ln\NVar{z}$ : principal branch of logarithm function, $x$ : real variable, $\alpha$ and $X$
Permalink:: http://dlmf.nist.gov/13.20.E13
Encodings:: pMML, png, TeX
See also:: Annotations for §13.20(iv), §13.20 and Ch.13

…

9: 28.23 Expansions in Series of Bessel Functions

… ►

28.23.3

\operatorname{me}_{\nu}'\left(0,h^{2}\right){\operatorname{M}^{(j)}_{\nu}}% \left(z,h\right)=\mathrm{i}\tanh z\sum_{n=-\infty}^{\infty}(-1)^{n}(\nu+2n)c_{% 2n}^{\nu}(h^{2}){\cal C}_{\nu+2n}^{(j)}(2h\cosh z),

ⓘ

Symbols:: $\operatorname{me}_{\NVar{n}}\left(\NVar{z},\NVar{q}\right)$ : Mathieu function, $\cosh\NVar{z}$ : hyperbolic cosine function, $\tanh\NVar{z}$ : hyperbolic tangent function, $\mathrm{i}$ : imaginary unit, ${\operatorname{M}^{(\NVar{j})}_{\NVar{\nu}}}\left(\NVar{z},\NVar{h}\right)$ : modified Mathieu function, $h$ : parameter, $n$ : integer, $j$ : integer, $z$ : complex variable, $\nu$ : complex parameter, $c_{2m}(q)$ : coefficients and $\mathcal{C}_{\mu}^{(j)}$ : cylinder functions
Permalink:: http://dlmf.nist.gov/28.23.E3
Encodings:: pMML, png, TeX
See also:: Annotations for §28.23 and Ch.28

►valid for all

z

when

j=1

, and for

\Re z>0

and

|\cosh z|>1

when

j=2,3,4

. …valid for all

z

when

j=1

, and for

\Re z>0

and

|\sinh z|>1

when

j=2,3,4

. ►In the case when

\nu

is an integer …When

j=2,3,4

the series in the even-numbered equations converge for

\Re z>0

and

|\cosh z|>1

, and the series in the odd-numbered equations converge for

\Re z>0

and

|\sinh z|>1

. …

10: 4.43 Cubic Equations

… ►

4.43.2

z^{3}+pz+q=0

ⓘ

Symbols:

\pi

: the ratio of the circumference of a circle to its diameter,

\cosh\NVar{z}

: hyperbolic cosine function,

\sinh\NVar{z}

: hyperbolic sine function,

\mathrm{i}

: imaginary unit,

\sin\NVar{z}

: sine function,

a

: real or complex constant,

z

: complex variable,

p

: real constant and

q

: real constant

Referenced by:

(4.43.1), §4.43

Permalink:

http://dlmf.nist.gov/4.43.E2

Encodings:

pMML, png, TeX

Errata (effective with 1.0.10):

Cases (a), (b), and (c) of of this equation have been corrected. Formerly, with constants

C

and

D

given in Eq. (4.43.1), they read

(a)

$A\sin a$ , $A\sin\left(a+\frac{2}{3}\pi\right)$ , and $A\sin\left(a+\frac{4}{3}\pi\right)$ , with $\sin\left(3a\right)=C$ , when $p<0$ and $C\leq 1$ .
(b)

$A\cosh a$ , $A\cosh\left(a+\frac{2}{3}\pi i\right)$ , and $A\cosh\left(a+\frac{4}{3}\pi i\right)$ , with $\cosh\left(3a\right)=C$ , when $p<0$ and $C>1$ .
(c)

$B\sinh a$ , $B\sinh\left(a+\frac{2}{3}\pi i\right)$ , and $B\sinh\left(a+\frac{4}{3}\pi i\right)$ , with $\sinh\left(3a\right)=D$ , when $p>0$ .

Reported 2014-10-31 by Masataka Urago

See also:

Annotations for §4.43 and Ch.4

…

hyperbolic cases

1—10 of 47 matching pages

1: 19.2 Definitions

2: 19.20 Special Cases

3: 19.7 Connection Formulas

§19.7(iii) Change of Parameter of Π ⁡ ( ϕ , α 2 , k )

4: 19.21 Connection Formulas

5: 19.6 Special Cases

6: 19.36 Methods of Computation

7: 22.5 Special Values

8: 13.20 Uniform Asymptotic Approximations for Large μ

9: 28.23 Expansions in Series of Bessel Functions

10: 4.43 Cubic Equations

§19.7(iii) Change of Parameter of $\Pi\left(\phi,\alpha^{2},k\right)$

8: 13.20 Uniform Asymptotic Approximations for Large $\mu$