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11: Bonita V. Saunders

… ►As the principal developer of graphics for the DLMF, she has collaborated with other NIST mathematicians, computer scientists, and student interns to produce informative graphs and dynamic interactive visualizations of elementary and higher mathematical functions over both simply and multiply connected domains. …

12: 14.9 Connection Formulas

§14.9 Connection Formulas

►

§14.9(i) Connections Between $\mathsf{P}^{\pm\mu}_{\nu}\left(x\right)$ , $\mathsf{P}^{\pm\mu}_{-\nu-1}\left(x\right)$ , $\mathsf{Q}^{\pm\mu}_{\nu}\left(x\right)$ , $\mathsf{Q}^{\mu}_{-\nu-1}\left(x\right)$

… ►

§14.9(ii) Connections Between $\mathsf{P}^{\pm\mu}_{\nu}\left(\pm x\right)$ , $\mathsf{Q}^{-\mu}_{\nu}\left(\pm x\right)$ , $\mathsf{Q}^{\mu}_{\nu}\left(x\right)$

… ►

§14.9(iii) Connections Between $P^{\pm\mu}_{\nu}\left(x\right)$ , $P^{\pm\mu}_{-\nu-1}\left(x\right)$ , $\boldsymbol{Q}^{\pm\mu}_{\nu}\left(x\right)$ , $\boldsymbol{Q}^{\mu}_{-\nu-1}\left(x\right)$

…

13: 10.4 Connection Formulas

§10.4 Connection Formulas

…

14: 8.22 Mathematical Applications

… ►

§8.22(ii) Riemann Zeta Function and Incomplete Riemann Zeta Function

►The function

\Gamma\left(a,z\right)

, with

|\operatorname{ph}a|\leq\tfrac{1}{2}\pi

and

\operatorname{ph}z=\tfrac{1}{2}\pi

, has an intimate connection with the Riemann zeta function

\zeta\left(s\right)

(§25.2(i)) on the critical line

\Re s=\tfrac{1}{2}

. …

15: William P. Reinhardt

… ►This is closely connected with his interests in classical dynamical “chaos,” an area where he coauthored a book, Chaos in atomic physics with Reinhold Blümel. …

16: 7.20 Mathematical Applications

… ►

§7.20(ii) Cornu’s Spiral

…

17: 25.13 Periodic Zeta Function

… ►

25.13.2

F\left(x,s\right)=\frac{\Gamma\left(1-s\right)}{(2\pi)^{1-s}}\*\left(e^{\pi i(% 1-s)/2}\zeta\left(1-s,x\right)+e^{\pi i(s-1)/2}\zeta\left(1-s,1-x\right)\right),

0<x<1

\Re s>1

ⓘ

Symbols:: $\Gamma\left(\NVar{z}\right)$ : gamma function, $\zeta\left(\NVar{s},\NVar{a}\right)$ : Hurwitz zeta function, $\pi$ : the ratio of the circumference of a circle to its diameter, $\mathrm{e}$ : base of natural logarithm, $\mathrm{i}$ : imaginary unit, $F\left(\NVar{x},\NVar{s}\right)$ : periodic zeta function, $\Re$ : real part, $x$ : real variable and $s$ : complex variable
Keywords:: connection formula
Source:: Apostol (1976, Exercise 2, p. 273)
Permalink:: http://dlmf.nist.gov/25.13.E2
Encodings:: pMML, png, TeX
See also:: Annotations for §25.13 and Ch.25

►

25.13.3

\zeta\left(1-s,x\right)=\frac{\Gamma\left(s\right)}{(2\pi)^{s}}\left(e^{-\pi is% /2}F\left(x,s\right)+e^{\pi is/2}F\left(-x,s\right)\right),

\Re s>0

0<x<1

;

\Re s>1

x=1

ⓘ

Symbols:: $\Gamma\left(\NVar{z}\right)$ : gamma function, $\zeta\left(\NVar{s},\NVar{a}\right)$ : Hurwitz zeta function, $\pi$ : the ratio of the circumference of a circle to its diameter, $\mathrm{e}$ : base of natural logarithm, $\mathrm{i}$ : imaginary unit, $F\left(\NVar{x},\NVar{s}\right)$ : periodic zeta function, $\Re$ : real part, $x$ : real variable and $s$ : complex variable
Keywords:: connection formula
Source:: Apostol (1976, (10), p. 257)
Notes:: This formula is equivalent to (25.11.9).
Referenced by:: Erratum (V1.1.4) for Equation (25.13.3)
Permalink:: http://dlmf.nist.gov/25.13.E3
Encodings:: pMML, png, TeX
See also:: Annotations for §25.13 and Ch.25

18: 36.5 Stokes Sets

… ►The Stokes set is itself a cusped curve, connected to the cusp of the bifurcation set: … ►They generate a pair of cusp-edged sheets connected to the cusped sheets of the swallowtail bifurcation set (§36.4). … ►This consists of a cusp-edged sheet connected to the cusp-edged sheet of the bifurcation set and intersecting the smooth sheet of the bifurcation set. … ►This part of the Stokes set connects two complex saddles. … ►In Figure 36.5.4 the part of the Stokes surface inside the bifurcation set connects two complex saddles. …

19: 14.21 Definitions and Basic Properties

… ►

§14.21(iii) Properties

… ►This includes, for example, the Wronskian relations (14.2.7)–(14.2.11); hypergeometric representations (14.3.6)–(14.3.10) and (14.3.15)–(14.3.20); results for integer orders (14.6.3)–(14.6.5), (14.6.7), (14.6.8), (14.7.6), (14.7.7), and (14.7.11)–(14.7.16); behavior at singularities (14.8.7)–(14.8.16); connection formulas (14.9.11)–(14.9.16); recurrence relations (14.10.3)–(14.10.7). …

20: 30.11 Radial Spheroidal Wave Functions

… ►

Connection Formulas

… ►

§30.11(v) Connection with the $\mathit{Ps}$ and $\mathit{Qs}$ Functions

►

30.11.8

S^{m(1)}_{n}\left(z,\gamma\right)=K_{n}^{m}(\gamma)\mathit{Ps}^{m}_{n}\left(z,% \gamma^{2}\right),

ⓘ

Symbols:: $S^{\NVar{m}(\NVar{j})}_{\NVar{n}}\left(\NVar{z},\NVar{\gamma}\right)$ : radial spheroidal wave function, $\mathit{Ps}^{\NVar{m}}_{\NVar{n}}\left(\NVar{z},\NVar{\gamma^{2}}\right)$ : spheroidal wave function of complex argument, $z$ : complex variable, $m$ : nonnegative integer, $n\geq m$ : integer degree, $K_{n}^{m}(\gamma)$ : connection coefficient and $\gamma^{2}$ : real parameter
A&S Ref:: 21.10.1 (in different form)
Permalink:: http://dlmf.nist.gov/30.11.E8
Encodings:: pMML, png, TeX
See also:: Annotations for §30.11(v), §30.11 and Ch.30

►

30.11.9

S^{m(2)}_{n}\left(z,\gamma\right)=\frac{(n-m)!}{(n+m)!}\frac{(-1)^{m+1}\mathit% {Qs}^{m}_{n}\left(z,\gamma^{2}\right)}{\gamma K_{n}^{m}(\gamma)A_{n}^{m}(% \gamma^{2})A_{n}^{-m}(\gamma^{2})},

ⓘ

Symbols:: $!$ : factorial (as in $n!$ ), $S^{\NVar{m}(\NVar{j})}_{\NVar{n}}\left(\NVar{z},\NVar{\gamma}\right)$ : radial spheroidal wave function, $\mathit{Qs}^{\NVar{m}}_{\NVar{n}}\left(\NVar{z},\NVar{\gamma^{2}}\right)$ : spheroidal wave function of complex argument, $z$ : complex variable, $m$ : nonnegative integer, $n\geq m$ : integer degree, $A_{n}^{m}(\gamma^{2})$ , $K_{n}^{m}(\gamma)$ : connection coefficient and $\gamma^{2}$ : real parameter
A&S Ref:: 21.10.2 (in different form)
Permalink:: http://dlmf.nist.gov/30.11.E9
Encodings:: pMML, png, TeX
See also:: Annotations for §30.11(v), §30.11 and Ch.30

►where …