Revision as of 13:54, 27 October 2022

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,

$0$

$=$

$z (1 - z) \frac{d^{2} u}{d z^{2}} + [γ - (α + β + 1) z] \frac{d u}{d z} - α β u,$

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,

$F (α, β; γ; z)$

$=$

$1 + [\frac{α \cdot β}{γ \cdot 1}] z + [\frac{α (α + 1) β (β + 1)}{γ (γ + 1) \cdot 1 \cdot 2}] z^{2} + [\frac{α (α + 1) (α + 2) β (β + 1) (β + 2)}{γ (γ + 1) (γ + 2) \cdot 1 \cdot 2 \cdot 3}] z^{3} + \dots$

Among other attributes, Gradshteyn & Ryzhik (1965) note that this, "… series terminates if $α$ or $β$ is equal to a negative integer or to zero."

LAWE

Drawing from an accompanying discussion, we have the,

LAWE: Linear Adiabatic Wave (or Radial Pulsation) Equation

$\frac{d^{2} x}{d r_{0}^{2}} + [\frac{4}{r_{0}} - (\frac{g_{0} ρ_{0}}{P_{0}})] \frac{d x}{d r_{0}} + (\frac{ρ_{0}}{γ_{g} P_{0}}) [ω^{2} + (4 - 3 γ_{g}) \frac{g_{0}}{r_{0}}] x = 0$

where,

$g_{0}$

$=$

$- \frac{1}{ρ_{0}} \frac{d P_{0}}{d r_{0}} .$

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

$x$	$\to$	$f,$
$\frac{r_{0}}{R}$	$\to$	$x,$
$(4 - 3 γ_{g})$	$\to$	$- α γ_{g},$

the LAWE may be rewritten as,

$0$	$=$	$\frac{d^{2} f}{d x^{2}} + [\frac{4}{x} - (\frac{g_{0} ρ_{0} R}{P_{0}})] \frac{d f}{d x} + (\frac{ρ_{0} R^{2}}{γ_{g} P_{0}}) [ω^{2} - \frac{α γ_{g} g_{0}}{r_{0}}] f$
	$=$	$\frac{d^{2} f}{d x^{2}} + \frac{1}{x} [4 - (\frac{g_{0} ρ_{0} r_{0}}{P_{0}})] \frac{d f}{d x} + [(\frac{ω^{2} ρ_{0} R^{2}}{γ_{g} P_{0}}) - \frac{α γ_{g} g_{0}}{r_{0}} (\frac{ρ_{0} R^{2}}{γ_{g} P_{0}})] f$
	$=$	$\frac{d^{2} f}{d x^{2}} + \frac{1}{x} [4 - (\frac{g_{0} ρ_{0} r_{0}}{P_{0}})] \frac{d f}{d x} + [(\frac{ω^{2} ρ_{0} R^{2}}{γ_{g} P_{0}}) - \frac{α}{x^{2}} (\frac{g_{0} r_{0} ρ_{0}}{P_{0}})] f .$

If we furthermore adopt the variable definition,

$μ$

$\equiv$

$(\frac{g_{0} ρ_{0} r_{0}}{P_{0}}) = - \frac{d \ln P_{0}}{d \ln r_{0}},$

we obtain equation (1) of R. Van der Borght (1970), namely,

Borght's LAWE

$0$

$=$

$\frac{d^{2} f}{d x^{2}} + \frac{(4 - μ)}{x} \cdot \frac{d f}{d x} + [(\frac{ω^{2} ρ_{0} R^{2}}{γ_{g} P_{0}}) - \frac{α μ}{x^{2}}] f .$

Example Density- and Pressure-Profiles

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

Uniform Density

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

$0$	$=$	$\frac{d^{2} f}{d x^{2}} + \frac{(4 - μ)}{x} \cdot \frac{d f}{d x} + [(\frac{ω^{2} ρ_{0} R^{2}}{γ_{g} P_{0}}) - \frac{α μ}{x^{2}}] f$
	$=$	$\frac{d^{2} f}{d x^{2}} + \frac{1}{x} [4 - \frac{2 x^{2}}{(1 - x^{2})}] \frac{d f}{d x} + [(\frac{ω^{2} ρ_{c} R^{2}}{γ_{g} P_{c}}) \frac{1}{(1 - x^{2})} - (\frac{2 α}{1 - x^{2}})] f$
	$=$	$(1 - x^{2}) \cdot \frac{d^{2} f}{d x^{2}} + \frac{1}{x} [4 - 6 x^{2}] \frac{d f}{d x} + [(\frac{ω^{2} ρ_{c} R^{2}}{γ_{g} P_{c}}) - 2 α] f .$

Given that, in the equilibrium state,

$\frac{ρ_{c} R^{2}}{P_{c}}$

$=$

$\frac{6}{4 π G ρ_{c}}$

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,

$0$	$=$	$(1 - x^{2}) \cdot \frac{d^{2} f}{d x^{2}} + \frac{1}{x} [4 - 6 x^{2}] \frac{d f}{d x} + [6 (\frac{ω^{2}}{4 π γ_{g} G ρ_{c}}) - 2 α] f$
	$=$	$(1 - x^{2}) \cdot \frac{d^{2} f}{d x^{2}} + \frac{1}{x} [4 - 6 x^{2}] \frac{d f}{d x} + 𝔉 f,$

where,

$𝔉$

$\equiv$

$[6 (\frac{ω^{2}}{4 π γ_{g} G ρ_{c}}) - 2 α] .$

This also matches equations (8) and (9) of Kopal (1948), 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) — $(4 - x^{2})$ appears, whereas it should be $(4 - 6 x^{2})$ .

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

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

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

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

This is, indeed, of the hypergeometric form if we set $(α, β; γ; z)$

$γ$	$=$	$\frac{5}{2},$
$(α + β + 1)$	$=$	$\frac{7}{2},$
$α β$	$=$	$- \frac{𝔉}{4} .$

Combining this last pair of expressions gives,

$0$	$=$	$- \frac{𝔉}{4} - α [\frac{5}{2} - α]$
	$=$	$α^{2} - (\frac{5}{2}) α - \frac{𝔉}{4}$
$\Rightarrow α$	$=$	$\frac{1}{2} {\frac{5}{2} \pm [(\frac{5}{2})^{2} - 𝔉]^{1 / 2}}$
	$=$	$\frac{5}{4} {1 \pm [1 - (\frac{4}{25}) 𝔉]^{1 / 2}};$

and,

$β$

$=$

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

Example α = -1

If we set $α = - 1$ , then the eigenvector is,

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

$=$

$1 - [\frac{β}{γ}] x^{2} = 1 - (\frac{7}{5}) x^{2};$

and the corresponding eigenfrequency is obtained from the expression,

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

@@ Line 654: / Line 654: @@
 \frac{5}{4}\biggl\{
 \pm \biggl[1 - \biggl(\frac{4}{25}\biggr)\mathfrak{F} \biggr]^{1 / 2}
-\biggr\} \, ;
+\biggr\}
+</math>
+  </td>
+</tr>
+<tr>
+  <td align="right">
+<math>\Rightarrow ~~~-\frac{9}{5}</math>
+  </td>
+  <td align="center">
+<math>=</math>
+  </td>
+  <td align="left">
+<math>
+\pm \biggl[1 - \biggl(\frac{4}{25}\biggr)\mathfrak{F} \biggr]^{1 / 2}
+</math>
+  </td>
+</tr>
+<tr>
+  <td align="right">
+<math>\Rightarrow ~~~\frac{3^4}{5^2}</math>
+  </td>
+  <td align="center">
+<math>=</math>
+  </td>
+  <td align="left">
+<math>
+- \biggl(\frac{4}{25}\biggr)\mathfrak{F}
+</math>
+  </td>
+</tr>
+<tr>
+  <td align="right">
+<math>\Rightarrow ~~~\mathfrak{F} </math>
+  </td>
+  <td align="center">
+<math>=</math>
+  </td>
+  <td align="left">
+<math>
+\biggl(\frac{5^2}{4}\biggr)\biggl[ 1 -  \frac{3^4}{5^2} \biggr]
+=
+\frac{1}{4}\biggl[ 5^2 -  3^4 \biggr]
+=
+\, .
 </math>
    </td>
 </tr>
 </table>
 =See Also=

Appendix/Mathematics/Hypergeometric: Difference between revisions

Revision as of 13:54, 27 October 2022

Contents

Hypergeometric Differential Equation

LAWE

Example Density- and Pressure-Profiles

Uniform Density

Example α = -1

See Also

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Appendix/Mathematics/Hypergeometric: Difference between revisions

Revision as of 13:54, 27 October 2022

Hypergeometric Differential Equation

LAWE

Example Density- and Pressure-Profiles

Uniform Density

Example α = -1

See Also

Navigation menu

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