Hypergeometric Differential Equation

According to §9.151 (p. 1045) of Gradshteyn & Ryzhik (1965), "… a hypergeometric series is one of the solutions of the differential equation,

${\displaystyle 0}$

${\displaystyle =}$

${\displaystyle z(1-z)\frac{d^{2}u}{d{z}^2}+[\gamma -(\alpha +\beta +1)z]\frac{du}{dz}-\alpha \beta u,}$

which is called the hypergeometric equation. And, according to §9.10 (p. 1039) of Gradshteyn & Ryzhik (1965), "A hypergeometric series is a series of the form,

${\displaystyle F(\alpha ,\beta ;\gamma ;z)}$

${\displaystyle =}$

${\displaystyle 1+\left[\frac{\alpha \cdot \beta }{\gamma \cdot 1}\right]z+\left[\frac{\alpha (\alpha +1)\beta (\beta +1)}{\gamma (\gamma +1)\cdot 1\cdot 2}\right]z^2+\left[\frac{\alpha (\alpha +1)(\alpha +2)\beta (\beta +1)(\beta +2)}{\gamma (\gamma +1)(\gamma +2)\cdot 1\cdot 2\cdot 3}\right]z^3+\dots }$

Among other attributes, Gradshteyn & Ryzhik (1965) note that this, "… series terminates if ${\displaystyle \alpha }$ or ${\displaystyle \beta }$ is equal to a negative integer or to zero."

LAWE

Drawing from an accompanying discussion, we have the,

where,

${\displaystyle g_0}$

${\displaystyle =}$

${\displaystyle -\frac{1}{{\rho }_0}\frac{d{P}_0}{d{r}_0}.}$

Multiplying through by ${\displaystyle R^2}$, and making the variable substitutions,

${\displaystyle x}$	${\displaystyle \to }$	${\displaystyle f,}$
${\displaystyle \frac{r_0}{R}}$	${\displaystyle \to }$	${\displaystyle x,}$
${\displaystyle (4-3{\gamma }_g)}$	${\displaystyle \to }$	${\displaystyle -\alpha {\gamma }_g,}$

the LAWE may be rewritten as,

${\displaystyle 0}$	${\displaystyle =}$	${\displaystyle \frac{d^{2}f}{d{x}^2}+[\frac{4}{x}-(\frac{g_0{\rho }_{0}R}{P_0}\left)\right]\frac{df}{dx}+\left(\frac{{\rho }_0{R}^2}{{\gamma }_{\mathrm{g}}{P}_0}\right)[{\omega }^2-\frac{\alpha {\gamma }_g{g}_0}{r_0}]f}$
	${\displaystyle =}$	${\displaystyle \frac{d^{2}f}{d{x}^2}+\frac{1}{x}[4-(\frac{g_0{\rho }_0{r}_0}{P_0}\left)\right]\frac{df}{dx}+\left[\right(\frac{{\omega }^2{\rho }_0{R}^2}{{\gamma }_{\mathrm{g}}{P}_0})-\frac{\alpha {\gamma }_g{g}_0}{r_0}(\frac{{\rho }_0{R}^2}{{\gamma }_{\mathrm{g}}{P}_0}\left)\right]f}$
	${\displaystyle =}$	${\displaystyle \frac{d^{2}f}{d{x}^2}+\frac{1}{x}[4-(\frac{g_0{\rho }_0{r}_0}{P_0}\left)\right]\frac{df}{dx}+\left[\right(\frac{{\omega }^2{\rho }_0{R}^2}{{\gamma }_{\mathrm{g}}{P}_0})-\frac{\alpha }{x^2}(\frac{g_0{r}_0{\rho }_0}{P_0}\left)\right]f.}$

If we furthermore adopt the variable definition,

${\displaystyle \mu }$

${\displaystyle \equiv }$

${\displaystyle \left(\frac{g_0{\rho }_0{r}_0}{P_0}\right)=-\frac{d\ln P_0}{d\ln r_0},}$

we obtain equation (1) of 📚 R. Van der Borght (1970, Proc. Astr. Soc. Australia, Vol. 1, Issue 7, pp. 325 - 326), which we will refer to as,

Example Density- and Pressure-Profiles

Properties of Analytically Defined, Spherically Symmetric, Equilibrium Structures
Model	${\displaystyle \rho (x)}$	${\displaystyle P(x)}$	${\displaystyle P^{\text{'}}(x)}$	${\displaystyle \mu (x)}$	${\displaystyle \frac{\rho (x)}{P(x)}}$
Uniform-density	${\displaystyle 1}$	${\displaystyle 1-x^2}$	${\displaystyle -2x}$	${\displaystyle \frac{2x^2}{(1-x^2)}}$	${\displaystyle \frac{1}{(1-x^2)}}$
Linear	${\displaystyle 1-x}$	${\displaystyle (1-x{)}^2(1+2x-\frac{9}{5}{x}^2)}$	${\displaystyle -\frac{12}{5}x(1-x)(4-3x)}$	${\displaystyle \frac{\frac{12}{5}{x}^2(4-3x)}{(1-x)(1+2x-\frac{9}{5}{x}^2)}}$	${\displaystyle \frac{1}{(1-x)(1+2x-\frac{9}{5}{x}^2)}}$
Parabolic	${\displaystyle 1-x^2}$	${\displaystyle (1-x^2{)}^2(1-\frac{1}{2}{x}^2)}$	${\displaystyle -x(1-x^2)(5-3x^2)}$	${\displaystyle \frac{x^2(5-3x^2)}{(1-x^2)(1-\frac{1}{2}{x}^2)}}$	${\displaystyle \frac{1}{(1-x^2)(1-\frac{1}{2}{x}^2)}}$
${\displaystyle n=1}$ Polytrope	${\displaystyle \frac{\sin x}{x}}$	${\displaystyle (\frac{\sin x}{x}{)}^2}$	${\displaystyle \frac{2}{x}[\cos x-\frac{\sin x}{x}]\frac{\sin x}{x}}$	${\displaystyle 2(1-x\cot x)}$	${\displaystyle \frac{x}{\sin x}}$

Uniform Density

In the case of a uniform-density, incompressible configuration, Borght's LAWE becomes,

${\displaystyle 0}$	${\displaystyle =}$	${\displaystyle \frac{d^{2}f}{d{x}^2}+\frac{(4-\mu )}{x}\cdot \frac{df}{dx}+\left[\right(\frac{{\omega }^2{\rho }_0{R}^2}{{\gamma }_{\mathrm{g}}{P}_0})-\frac{\alpha \mu }{x^2}]f}$
	${\displaystyle =}$	${\displaystyle \frac{d^{2}f}{d{x}^2}+\frac{1}{x}[4-\frac{2x^2}{(1-x^2)}]\frac{df}{dx}+\left[\right(\frac{{\omega }^2{\rho }_c{R}^2}{{\gamma }_{\mathrm{g}}{P}_c})\frac{1}{(1-x^2)}-(\frac{2\alpha }{1-x^2}\left)\right]f}$
	${\displaystyle =}$	${\displaystyle (1-x^2)\cdot \frac{d^{2}f}{d{x}^2}+\frac{1}{x}[4-6x^2]\frac{df}{dx}+\left[\right(\frac{{\omega }^2{\rho }_c{R}^2}{{\gamma }_{\mathrm{g}}{P}_c})-2\alpha ]f.}$

Given that, in the equilibrium state,

${\displaystyle \frac{{\rho }_c{R}^2}{P_c}}$

${\displaystyle =}$

${\displaystyle \frac{6}{4\pi G{\rho }_c}}$

we obtain the LAWE derived by 📚 T. E. Sterne (1937, MNRAS, Vol. 97, pp. 582 - 593) — see his equation (1.91) on p. 585 — namely,

${\displaystyle 0}$	${\displaystyle =}$	${\displaystyle (1-x^2)\cdot \frac{d^{2}f}{d{x}^2}+\frac{1}{x}[4-6x^2]\frac{df}{dx}+\left[6\right(\frac{{\omega }^2}{4\pi {\gamma }_{\mathrm{g}}G{\rho }_c})-2\alpha ]f}$
	${\displaystyle =}$	${\displaystyle (1-x^2)\cdot \frac{d^{2}f}{d{x}^2}+\frac{1}{x}[4-6x^2]\frac{df}{dx}+\mathfrak{𝔉}f,}$

where,

${\displaystyle \mathfrak{𝔉}}$

${\displaystyle \equiv }$

${\displaystyle \left[6\right(\frac{{\omega }^2}{4\pi {\gamma }_{\mathrm{g}}G{\rho }_c})-2\alpha ].}$

This also matches equations (8) and (9) of 📚 Z. Kopal (1948, Proc. NAS, Vol. 34, Issue 8, pp.377-384), aside from what, we presume, is a type-setting error that appears in the numerator of the second term on the RHS of his equation (8):  ${\displaystyle (4-x^2)}$ appears, whereas it should be ${\displaystyle (4-6x^2)}$.

In order to see if this differential equation is of the same form as the hypergeometric expression, we'll make the substitution,

${\displaystyle z}$	${\displaystyle \equiv }$	${\displaystyle x^2}$
${\displaystyle \Rightarrow dz}$	${\displaystyle =}$	${\displaystyle 2xdx}$
${\displaystyle \Rightarrow \frac{df}{dx}}$	${\displaystyle =}$	${\displaystyle \frac{dz}{dx}\cdot \frac{df}{dz}=2x\cdot \frac{df}{dz}=2z^{1/2}\cdot \frac{df}{dz}}$
${\displaystyle \Rightarrow \frac{d^{2}f}{d{x}^2}}$	${\displaystyle =}$	${\displaystyle 2z^{1/2}\cdot \frac{d}{dz}[2z^{1/2}\cdot \frac{df}{dz}]=2z^{1/2}[z^{-1/2}\cdot \frac{df}{dz}+2z^{1/2}\cdot \frac{d^{2}f}{d{z}^2}]=[2\cdot \frac{df}{dz}+4z\cdot \frac{d^{2}f}{d{z}^2}],}$

in which case the 📚 Sterne (1937) LAWE may be rewritten as,

${\displaystyle 0}$	${\displaystyle =}$	${\displaystyle (1-z)[2\cdot \frac{df}{dz}+4z\cdot \frac{d^{2}f}{d{z}^2}]+\frac{1}{z^{1/2}}[4-6z]2z^{1/2}\frac{df}{dz}+\mathfrak{𝔉}f}$
	${\displaystyle =}$	${\displaystyle (1-z)[4z\cdot \frac{d^{2}f}{d{z}^2}]+(1-z)[2\cdot \frac{df}{dz}]+2[4-6z]\frac{df}{dz}+\mathfrak{𝔉}f}$
	${\displaystyle =}$	${\displaystyle 4z(1-z)\cdot \frac{d^{2}f}{d{z}^2}+2[5-7z]\frac{df}{dz}+\mathfrak{𝔉}f.}$

This is, indeed, of the hypergeometric form if we set ${\displaystyle (\alpha ,\beta ;\gamma ;z)}$

${\displaystyle \gamma }$	${\displaystyle =}$	${\displaystyle \frac{5}{2},}$
${\displaystyle (\alpha +\beta +1)}$	${\displaystyle =}$	${\displaystyle \frac{7}{2},}$
${\displaystyle \alpha \beta }$	${\displaystyle =}$	${\displaystyle -\frac{\mathfrak{𝔉}}{4}.}$

Combining this last pair of expressions gives,

${\displaystyle 0}$	${\displaystyle =}$	${\displaystyle -\frac{\mathfrak{𝔉}}{4}-\alpha [\frac{5}{2}-\alpha ]}$
	${\displaystyle =}$	${\displaystyle {\alpha }^2-\left(\frac{5}{2}\right)\alpha -\frac{\mathfrak{𝔉}}{4}}$
${\displaystyle \Rightarrow \alpha }$	${\displaystyle =}$	${\displaystyle \frac{1}{2}\{\frac{5}{2}\pm [(\frac{5}{2}{)}^2-\mathfrak{𝔉}{]}^{1/2}\}}$
	${\displaystyle =}$	${\displaystyle \frac{5}{4}\{1\pm [1-\left(\frac{4}{25}\right)\mathfrak{𝔉}{]}^{1/2}\};}$

and,

${\displaystyle \beta }$

${\displaystyle =}$

${\displaystyle \frac{5}{2}-\frac{5}{4}\{1\pm [1-\left(\frac{4}{25}\right)\mathfrak{𝔉}{]}^{1/2}\}.}$

Example α = -1

If we set ${\displaystyle \alpha =-1}$, then the eigenvector is,

${\displaystyle u_1=F(-1,\frac{7}{2};\frac{5}{2};x^2)}$

${\displaystyle =}$

${\displaystyle 1-\left[\frac{\beta }{\gamma }\right]x^2=1-\left(\frac{7}{5}\right)x^2;}$

and the corresponding eigenfrequency is obtained from the expression,

${\displaystyle -1}$	${\displaystyle =}$	${\displaystyle \frac{5}{4}\{1\pm [1-\left(\frac{4}{25}\right)\mathfrak{𝔉}{]}^{1/2}\}}$
${\displaystyle \Rightarrow -\frac{9}{5}}$	${\displaystyle =}$	${\displaystyle \pm [1-(\frac{4}{25})\mathfrak{𝔉}{]}^{1/2}}$
${\displaystyle \Rightarrow \frac{3^4}{5^2}}$	${\displaystyle =}$	${\displaystyle 1-\left(\frac{4}{25}\right)\mathfrak{𝔉}}$
${\displaystyle \Rightarrow \mathfrak{𝔉}}$	${\displaystyle =}$	${\displaystyle \left(\frac{5^2}{4}\right)[1-\frac{3^4}{5^2}]=\frac{1}{4}[5^2-3^4]=14.}$

As we have reviewed in a separate discussion, this is identical to the eigenvector identified by 📚 Sterne (1937) as mode "${\displaystyle j=1}$".

More Generally

More generally, in agreement with 📚 Sterne (1937), for any (positive integer) mode number, ${\displaystyle 0\le j\le \mathrm{\infty }}$, we find,

${\displaystyle {\alpha }_j}$

${\displaystyle =}$

${\displaystyle -j;}$       ${\displaystyle {\beta }_j=\frac{5}{2}+j;}$       ${\displaystyle \gamma =\frac{5}{2};}$       ${\displaystyle \mathfrak{𝔉}=2j(2j+5).}$

And, in terms of the hypergeometric function series, the corresponding eigenfunction is,

${\displaystyle u_j=}$

${\displaystyle =}$

${\displaystyle F({\alpha }_j,{\beta }_j;\frac{5}{2};x^2).}$

See Also

• 📚 T. E. Sterne (1937, MNRAS, Vol. 97, pp. 582 - 593): Models of Radial Oscillation
• 📚 C. Prasad (1948, MNRAS, Vol. 108, pp. 414 - 416): Radial Oscillations of a Particular Stellar Model
• 📚 Z. Kopal (1948, Proc. NAS, Vol. 34, Issue 8, pp.377-384), Radial Oscillations of the Limiting Models of Polytropic Gas Spheres.
• In an article titled, "Radial Oscillations of a Stellar Model," 📚 C. Prasad (1949, MNRAS, Vol 109, pp. 103 - 107) investigated the properties of an equilibrium configuration with a prescribed density distribution given by the expression,

  ${\displaystyle \rho (r)={\rho }_c[1-(\frac{r}{R}{)}^2],}$

  where, ${\displaystyle {\rho }_c}$ is the central density and, ${\displaystyle R}$ is the radius of the star.

• R. Van der Borght (1970, Proceedings of the Astronomical Society of Australia, Vol. 1, Issue 7, pp. 325 - 326), Adiabatic Oscillations of Stars.
• MathProjects/EigenvalueProblemN1:   In the most general context, the LAWE takes the form,

  ${\displaystyle \left[P\right]\frac{d^2{{𝒢}}_{\sigma }}{d{x}^2}+[\frac{4P}{x}+P^{\text{'}}]\frac{d{{𝒢}}_{\sigma }}{dx}+[{\sigma }^2\rho +\frac{\alpha P^{\text{'}}}{x}]{{𝒢}}_{\sigma }}$

  ${\displaystyle =}$

  ${\displaystyle 0.}$

  Properties of Analytically Defined Astrophysical Structures
  Model	${\displaystyle \rho (x)}$	${\displaystyle P(x)}$	${\displaystyle P^{\text{'}}(x)}$
  Uniform-density	${\displaystyle 1}$	${\displaystyle 1-x^2}$	${\displaystyle -2x}$
  Linear	${\displaystyle 1-x}$	${\displaystyle (1-x{)}^2(1+2x-\frac{9}{5}{x}^2)}$	${\displaystyle -\frac{12}{5}x(1-x)(4-3x)}$
  Parabolic	${\displaystyle 1-x^2}$	${\displaystyle (1-x^2{)}^2(1-\frac{1}{2}{x}^2)}$	${\displaystyle -x(1-x^2)(5-3x^2)}$
  ${\displaystyle n=1}$ Polytrope	${\displaystyle \frac{\sin x}{x}}$	${\displaystyle [\frac{\sin x}{x}{]}^2}$	${\displaystyle \frac{2}{x}[\cos x-\frac{\sin x}{x}]\frac{\sin x}{x}}$

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