Coulomb functions

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11—20 of 59 matching pages

11: 33.4 Recurrence Relations and Derivatives

§33.4 Recurrence Relations and Derivatives

… ►Then, with

X_{\ell}

denoting any of

F_{\ell}\left(\eta,\rho\right)

G_{\ell}\left(\eta,\rho\right)

, or

{H^{\pm}_{\ell}}\left(\eta,\rho\right)

, ►

33.4.2

R_{\ell}X_{\ell-1}-T_{\ell}X_{\ell}+R_{\ell+1}X_{\ell+1}=0,

\ell\geq 1

ⓘ

Symbols:: $\ell$ : nonnegative integer, $R_{\ell}$ : factor, $T_{\ell}$ : factor and $X_{\ell}$ : any Coulomb function
A&S Ref:: 14.2.3
Permalink:: http://dlmf.nist.gov/33.4.E2
Encodings:: pMML, png, TeX
See also:: Annotations for §33.4 and Ch.33

►

33.4.3

X_{\ell}^{\prime}=R_{\ell}X_{\ell-1}-S_{\ell}X_{\ell},

\ell\geq 1

ⓘ

Symbols:: $\ell$ : nonnegative integer, $R_{\ell}$ : factor, $S_{\ell}$ : factor and $X_{\ell}$ : any Coulomb function
A&S Ref:: 14.2.1
Referenced by:: §33.6
Permalink:: http://dlmf.nist.gov/33.4.E3
Encodings:: pMML, png, TeX
See also:: Annotations for §33.4 and Ch.33

►

33.4.4

X_{\ell}^{\prime}=S_{\ell+1}X_{\ell}-R_{\ell+1}X_{\ell+1},

\ell\geq 0

ⓘ

Symbols:: $\ell$ : nonnegative integer, $R_{\ell}$ : factor, $S_{\ell}$ : factor and $X_{\ell}$ : any Coulomb function
A&S Ref:: 14.2.2
Referenced by:: §33.6
Permalink:: http://dlmf.nist.gov/33.4.E4
Encodings:: pMML, png, TeX
See also:: Annotations for §33.4 and Ch.33

12: 33.3 Graphics

§33.3 Graphics

►

§33.3(i) Line Graphs of the Coulomb Radial Functions $F_{\ell}\left(\eta,\rho\right)$ and $G_{\ell}\left(\eta,\rho\right)$

… ►

33.3.1

M_{\ell}\left(\eta,\rho\right)=({F_{\ell}}^{2}\left(\eta,\rho\right)+{G_{\ell}% }^{2}\left(\eta,\rho\right))^{1/2}=\left|{H^{\pm}_{\ell}}\left(\eta,\rho\right% )\right|.

ⓘ

Defines:: $M_{\NVar{\ell}}\left(\NVar{\eta},\NVar{\rho}\right)$ : envelope of Coulomb functions
Symbols:: $G_{\NVar{\ell}}\left(\NVar{\eta},\NVar{\rho}\right)$ : irregular Coulomb radial function, ${H^{\NVar{\pm}}_{\NVar{\ell}}}\left(\NVar{\eta},\NVar{\rho}\right)$ : irregular Coulomb radial functions, $F_{\NVar{\ell}}\left(\NVar{\eta},\NVar{\rho}\right)$ : regular Coulomb radial function, $\ell$ : nonnegative integer, $\rho$ : nonnegative real variable and $\eta$ : real parameter
Permalink:: http://dlmf.nist.gov/33.3.E1
Encodings:: pMML, png, TeX
See also:: Annotations for §33.3(i), §33.3 and Ch.33

… ►

§33.3(ii) Surfaces of the Coulomb Radial Functions $F_{0}\left(\eta,\rho\right)$ and $G_{0}\left(\eta,\rho\right)$

… ►

See accompanying text — Figure 33.3.8: $G_{0}\left(\eta,\rho\right)$ , $-2\leq\eta\leq 2$ , $0<\rho\leq 5$ . Magnify 3D Help

13: 17.17 Physical Applications

… ►See Kassel (1995). …

16: 30.12 Generalized and Coulomb Spheroidal Functions

§30.12 Generalized and Coulomb Spheroidal Functions

►Generalized spheroidal wave functions and Coulomb spheroidal functions are solutions of the differential equation …

17: 13.28 Physical Applications

… ►

§13.28(ii) Coulomb Functions

…

18: 33.13 Complex Variable and Parameters

§33.13 Complex Variable and Parameters

►The functions

F_{\ell}\left(\eta,\rho\right)

G_{\ell}\left(\eta,\rho\right)

, and

{H^{\pm}_{\ell}}\left(\eta,\rho\right)

may be extended to noninteger values of

\ell

by generalizing

(2\ell+1)!=\Gamma\left(2\ell+2\right)

, and supplementing (33.6.5) by a formula derived from (33.2.8) with

U\left(a,b,z\right)

expanded via (13.2.42). … ►

33.13.1

C_{\ell}\left(\eta\right)=2^{\ell}e^{\mathrm{i}{\sigma_{\ell}}\left(\eta\right% )-(\pi\eta/2)}\Gamma\left(\ell+1-\mathrm{i}\eta\right)/\Gamma\left(2\ell+2% \right),

ⓘ

Symbols:: $C_{\NVar{\ell}}\left(\NVar{\eta}\right)$ : normalizing constant for Coulomb radial functions, ${\sigma_{\NVar{\ell}}}\left(\NVar{\eta}\right)$ : Coulomb phase shift, $\Gamma\left(\NVar{z}\right)$ : gamma function, $\pi$ : the ratio of the circumference of a circle to its diameter, $\mathrm{e}$ : base of natural logarithm, $\mathrm{i}$ : imaginary unit, $\ell$ : nonnegative integer and $\eta$ : real parameter
Permalink:: http://dlmf.nist.gov/33.13.E1
Encodings:: pMML, png, TeX
See also:: Annotations for §33.13 and Ch.33

… ►

33.13.2

R_{\ell}=(2\ell+1)C_{\ell}\left(\eta\right)/C_{\ell-1}\left(\eta\right).

ⓘ

Symbols:: $C_{\NVar{\ell}}\left(\NVar{\eta}\right)$ : normalizing constant for Coulomb radial functions, $\ell$ : nonnegative integer, $\eta$ : real parameter and $R_{\ell}$ : factor
Permalink:: http://dlmf.nist.gov/33.13.E2
Encodings:: pMML, png, TeX
See also:: Annotations for §33.13 and Ch.33

…

19: 33.5 Limiting Forms for Small $\rho$ , Small $|\eta|$ , or Large $\ell$

… ►

§33.5(i) Small $\rho$

… ►

§33.5(ii) $\eta=0$

… ►

33.5.6

C_{\ell}\left(0\right)=\frac{2^{\ell}\ell!}{(2\ell+1)!}=\frac{1}{(2\ell+1)!!}.

ⓘ

Symbols:: $C_{\NVar{\ell}}\left(\NVar{\eta}\right)$ : normalizing constant for Coulomb radial functions, $!!$ : double factorial, $!$ : factorial (as in $n!$ ) and $\ell$ : nonnegative integer
Permalink:: http://dlmf.nist.gov/33.5.E6
Encodings:: pMML, png, TeX
See also:: Annotations for §33.5(ii), §33.5 and Ch.33

►

§33.5(iii) Small $|\eta|$

… ►

§33.5(iv) Large $\ell$

…

20: 33.23 Methods of Computation

§33.23 Methods of Computation

… ►The methods used for computing the Coulomb functions described below are similar to those in §13.29. … ►When numerical values of the Coulomb functions are available for some radii, their values for other radii may be obtained by direct numerical integration of equations (33.2.1) or (33.14.1), provided that the integration is carried out in a stable direction (§3.7). … ►Thompson and Barnett (1985, 1986) and Thompson (2004) use combinations of series, continued fractions, and Padé-accelerated asymptotic expansions (§3.11(iv)) for the analytic continuations of Coulomb functions. … ►

§33.23(vii) WKBJ Approximations

…

Coulomb functions

11—20 of 59 matching pages

11: 33.4 Recurrence Relations and Derivatives

§33.4 Recurrence Relations and Derivatives

12: 33.3 Graphics

§33.3 Graphics

§33.3(i) Line Graphs of the Coulomb Radial Functions $F_{\ell}\left(\eta,\rho\right)$ and $G_{\ell}\left(\eta,\rho\right)$

§33.3(ii) Surfaces of the Coulomb Radial Functions $F_{0}\left(\eta,\rho\right)$ and $G_{0}\left(\eta,\rho\right)$

13: 17.17 Physical Applications

14: 33.25 Approximations

§33.25 Approximations

15: 33.16 Connection Formulas

§33.16(i) $F_{\ell}$ and $G_{\ell}$ in Terms of $f$ and $h$

§33.16(ii) $f$ and $h$ in Terms of $F_{\ell}$ and $G_{\ell}$ when $\epsilon>0$

§33.16(iii) $f$ and $h$ in Terms of $W_{\kappa,\mu}\left(z\right)$ when $\epsilon<0$

§33.16(iv) $s$ and $c$ in Terms of $F_{\ell}$ and $G_{\ell}$ when $\epsilon>0$

§33.16(v) $s$ and $c$ in Terms of $W_{\kappa,\mu}\left(z\right)$ when $\epsilon<0$

16: 30.12 Generalized and Coulomb Spheroidal Functions

§30.12 Generalized and Coulomb Spheroidal Functions

17: 13.28 Physical Applications

§13.28(ii) Coulomb Functions

18: 33.13 Complex Variable and Parameters

§33.13 Complex Variable and Parameters

19: 33.5 Limiting Forms for Small $\rho$ , Small $|\eta|$ , or Large $\ell$

§33.5(i) Small $\rho$

§33.5(ii) $\eta=0$

§33.5(iii) Small $|\eta|$

§33.5(iv) Large $\ell$

20: 33.23 Methods of Computation

§33.23 Methods of Computation

§33.23(vii) WKBJ Approximations

Coulomb functions

11—20 of 59 matching pages

11: 33.4 Recurrence Relations and Derivatives

§33.4 Recurrence Relations and Derivatives

12: 33.3 Graphics

§33.3 Graphics

§33.3(i) Line Graphs of the Coulomb Radial Functions F ℓ ⁡ ( η , ρ ) and G ℓ ⁡ ( η , ρ )

§33.3(ii) Surfaces of the Coulomb Radial Functions F 0 ⁡ ( η , ρ ) and G 0 ⁡ ( η , ρ )

13: 17.17 Physical Applications

14: 33.25 Approximations

§33.25 Approximations

15: 33.16 Connection Formulas

§33.16(i) F ℓ and G ℓ in Terms of f and h

§33.16(ii) f and h in Terms of F ℓ and G ℓ when ϵ > 0

§33.16(iii) f and h in Terms of W κ , μ ⁡ ( z ) when ϵ < 0

§33.16(iv) s and c in Terms of F ℓ and G ℓ when ϵ > 0

§33.16(v) s and c in Terms of W κ , μ ⁡ ( z ) when ϵ < 0

16: 30.12 Generalized and Coulomb Spheroidal Functions

§30.12 Generalized and Coulomb Spheroidal Functions

17: 13.28 Physical Applications

§13.28(ii) Coulomb Functions

18: 33.13 Complex Variable and Parameters

§33.13 Complex Variable and Parameters

19: 33.5 Limiting Forms for Small ρ , Small | η | , or Large ℓ

§33.5(i) Small ρ

§33.5(ii) η = 0

§33.5(iii) Small | η |

§33.5(iv) Large ℓ

20: 33.23 Methods of Computation

§33.23 Methods of Computation

§33.23(vii) WKBJ Approximations

§33.3(i) Line Graphs of the Coulomb Radial Functions $F_{\ell}\left(\eta,\rho\right)$ and $G_{\ell}\left(\eta,\rho\right)$

§33.3(ii) Surfaces of the Coulomb Radial Functions $F_{0}\left(\eta,\rho\right)$ and $G_{0}\left(\eta,\rho\right)$

§33.16(i) $F_{\ell}$ and $G_{\ell}$ in Terms of $f$ and $h$

§33.16(ii) $f$ and $h$ in Terms of $F_{\ell}$ and $G_{\ell}$ when $\epsilon>0$

§33.16(iii) $f$ and $h$ in Terms of $W_{\kappa,\mu}\left(z\right)$ when $\epsilon<0$

§33.16(iv) $s$ and $c$ in Terms of $F_{\ell}$ and $G_{\ell}$ when $\epsilon>0$

§33.16(v) $s$ and $c$ in Terms of $W_{\kappa,\mu}\left(z\right)$ when $\epsilon<0$

19: 33.5 Limiting Forms for Small $\rho$ , Small $|\eta|$ , or Large $\ell$

§33.5(i) Small $\rho$

§33.5(ii) $\eta=0$

§33.5(iii) Small $|\eta|$

§33.5(iv) Large $\ell$