Difference between revisions of "User:Tohline/ThreeDimensionalConfigurations/HomogeneousEllipsoids"
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This definite-integral definition of <math>~A_i</math> may also be found in: | This definite-integral definition of <math>~A_i</math> may also be found in: | ||
* | * [[User:Tohline/Appendix/References#Lamb32|Lamb32]]: as Eq. (6) in §114 (p. 153); and as Eq. (5) in §373 (p. 700). | ||
* [[User:Tohline/Appendix/References#T78|T78]]: as Eq. (5) in §10.2 (p. 234), but note that there is an error in the denominator of the right-hand-side — <math>~a_1</math> appears instead of <math>~a_i</math>. | * [[User:Tohline/Appendix/References#T78|T78]]: as Eq. (5) in §10.2 (p. 234), but note that there is an error in the denominator of the right-hand-side — <math>~a_1</math> appears instead of <math>~a_i</math>. | ||
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</div> | </div> | ||
<span id="Table1"> </span> | |||
<table align="center" cellpadding="5" border="1"> | <table align="center" cellpadding="5" border="1"> | ||
<tr> | <tr> | ||
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</div> | </div> | ||
<b>With regard to our Table 2 (immediately above):</b> Next, given each pair of axis ratios, <math>~(\tfrac{b}{a},\tfrac{c}{a})</math> — copied from Table IV of EFE (see columns 1 and 2 of our Table 2) — we used some fortran routines from [http://numerical.recipes/ Numerical Recipes] to calculate <math>~F(\theta,k)</math> and <math>~E(\theta,k)</math> (see columns 3 and 4 of our Table 2); we converted the routines to accommodate double-precision arithmetic. We subsequently evaluated the coefficients, <math>~A_1</math>, <math>~A_2</math>, and <math>~A_3</math>, (columns 5, 6, & 7 of Table 2) using the expressions given above, then demonstrated that, in each case, the three coefficients sum to 2.0 to better than twelve digits accuracy. | <b>With regard to our Table 2 (immediately above):</b> Next, given each pair of axis ratios, <math>~(\tfrac{b}{a},\tfrac{c}{a})</math> — copied from Table IV of EFE (see columns 1 and 2 of our Table 2) — we used some fortran routines from [http://numerical.recipes/ Numerical Recipes] to calculate <math>~F(\theta,k)</math> and <math>~E(\theta,k)</math> (see columns 3 and 4 of our Table 2); we converted the routines to accommodate double-precision arithmetic. We subsequently evaluated the coefficients, <math>~A_1</math>, <math>~A_2</math>, and <math>~A_3</math>, (columns 5, 6, & 7 of Table 2) using the expressions given above, then demonstrated that, in each case, the three coefficients sum to 2.0 to better than twelve digits accuracy. | ||
=Derivation of Expressions for A<sub>i</sub>= | =Derivation of Expressions for A<sub>i</sub>= | ||
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This matches the expression that we have provided for <math>~A_3</math>, [[#Triaxial_Configurations|above in the context of triaxial configurations]]. | This matches the expression that we have provided for <math>~A_3</math>, [[#Triaxial_Configurations|above in the context of triaxial configurations]]. | ||
==When a<sub> | ==When a<sub>m</sub> = a<sub>ℓ</sub>== | ||
When the length of the intermediate axis is the same as the length of the longest axis — that is, when we are dealing with | When the length of the intermediate axis is the same as the length of the longest axis — that is, when we are dealing with an oblate spheroid — the coefficient associated with the longest axis is, | ||
<table border="0" cellpadding="5" align="center"> | <table border="0" cellpadding="5" align="center"> | ||
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</table> | </table> | ||
where, <math>~e \equiv (1 - a_s^2/a_\ell^2)</math>. Similarly, the coefficient associated with the shortest axis is, | where, <math>~e \equiv (1 - a_s^2/a_\ell^2)^{1 / 2}</math>. Similarly, the coefficient associated with the shortest axis is, | ||
<table border="0" cellpadding="5" align="center"> | <table border="0" cellpadding="5" align="center"> | ||
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</table> | </table> | ||
= | Because we are evaluating the case where <math>~A_m = A_\ell</math>, we alternatively should have been able to obtain the expression for <math>~A_s</math> immediately from our derived expression for <math>~A_\ell</math> via the known relation, | ||
<table border="0" cellpadding="5" align="center"> | |||
<tr> | |||
<td align="right"> | |||
<math>~2</math> | |||
</td> | |||
<td align="center"> | |||
<math>~=</math> | |||
</td> | |||
<td align="left"> | |||
<math>~A_\ell + A_m + A_s = 2A_\ell + A_s \, .</math> | |||
</td> | |||
</tr> | |||
</table> | |||
This approach gives, | |||
<table border="0" cellpadding="5" align="center"> | |||
<tr> | |||
<td align="right"> | |||
<math>~A_s</math> | |||
</td> | |||
<td align="center"> | |||
<math>~=</math> | |||
</td> | |||
<td align="left"> | |||
<math>~2 - 2A_\ell </math> | |||
</td> | |||
</tr> | |||
<tr> | |||
<td align="right"> | |||
| |||
</td> | |||
<td align="center"> | |||
<math>~=</math> | |||
</td> | |||
<td align="left"> | |||
<math>~2 + 2\biggl\{ | |||
\frac{(1-e^2)}{e^2} - | |||
~\frac{(1-e^2)^{1 / 2}}{ e^3 } \biggl[ | |||
\sin^{-1}e | |||
\biggr] | |||
\biggr\} | |||
</math> | |||
</td> | |||
</tr> | |||
<tr> | |||
<td align="right"> | |||
| |||
</td> | |||
<td align="center"> | |||
<math>~=</math> | |||
</td> | |||
<td align="left"> | |||
<math>~ | |||
\frac{2}{e^2} - | |||
~\frac{2(1-e^2)^{1 / 2}}{ e^3 } \biggl[ | |||
\sin^{-1}e | |||
\biggr] \, , | |||
</math> | |||
</td> | |||
</tr> | |||
</table> | |||
which, indeed, matches our separately derived expression for <math>~A_s</math>. | |||
==When a<sub>m</sub> = a<sub>s</sub>== | |||
When the length of the intermediate axis is the same as the length of the shortest axis — that is, when we are dealing with a prolate spheroid — the coefficient associated with the longest axis is, | |||
<table border="0" cellpadding="5" align="center"> | |||
<tr> | |||
<td align="right"> | |||
<math>~\frac{A_\ell}{a_\ell a_s^2}</math> | |||
</td> | |||
<td align="center"> | |||
<math>~=</math> | |||
</td> | |||
<td align="left"> | |||
<math> | |||
~\int_0^\infty \frac{du}{ (a_s^2 + u)(a_\ell^2 + u)^{3 / 2} } \, . | |||
</math> | |||
</td> | |||
</tr> | |||
</table> | |||
Changing the integration variable to <math>~x \equiv (a_s^2 + u)</math>, we obtain an integral expression that appears as equation (2.229.1) in [https://www.academia.edu/36550954/I_S_Gradshteyn_and_I_M_Ryzhik_Table_of_integrals_series_and_products_Academic_Press_2007_ GR7<sup>th</sup>], namely, | |||
<table border="0" cellpadding="5" align="center"> | |||
<tr> | |||
<td align="right"> | |||
<math>~\frac{A_\ell}{a_\ell a_s^2}</math> | |||
</td> | |||
<td align="center"> | |||
<math>~=</math> | |||
</td> | |||
<td align="left"> | |||
<math> | |||
~\int_{a_s^2}^\infty \frac{dx}{ x^2(a_\ell^2 - a_s^2 + x)^{1 / 2} } | |||
</math> | |||
</td> | |||
</tr> | |||
<tr> | |||
<td align="right"> | |||
<math>~</math> | |||
</td> | |||
<td align="center"> | |||
<math>~=</math> | |||
</td> | |||
<td align="left"> | |||
<math>~ | |||
\biggl[ \frac{2}{(a_\ell^2 - a_s^2) (a_\ell^2 - a_s^2 + x)^{1 / 2}} \biggr]_{a_s^2}^\infty | |||
+ | |||
\frac{1}{(a_\ell^2 - a_s^2)} \int_{a_s^2}^\infty \frac{dx}{ x (a_\ell^2 - a_s^2 + x)^{1 / 2} } \, . | |||
</math> | |||
</td> | |||
</tr> | |||
</table> | |||
The remaining integral in this expression appears as equation (2.224.5) in [https://www.academia.edu/36550954/I_S_Gradshteyn_and_I_M_Ryzhik_Table_of_integrals_series_and_products_Academic_Press_2007_ GR7<sup>th</sup>]. Its resolution depends on the sign of the constant term in the denominator, <math>~(a_\ell^2 - a_s^2)</math>. Given that this term is positive, the integration gives, | |||
<table border="0" cellpadding="5" align="center"> | |||
<tr> | |||
<td align="right"> | |||
<math>~\frac{A_\ell}{a_\ell a_s^2}</math> | |||
</td> | |||
<td align="center"> | |||
<math>~=</math> | |||
</td> | |||
<td align="left"> | |||
<math>~ | |||
- \frac{2}{(a_\ell^2 - a_s^2) a_\ell} | |||
+ | |||
\frac{1}{(a_\ell^2 - a_s^2)} | |||
\biggl\{ | |||
\frac{1}{\sqrt{(a_\ell^2 - a_s^2)}} \ln \biggl[ \frac{ (a_\ell^2 - a_s^2 + x)^{1 / 2} - \sqrt{(a_\ell^2 - a_s^2)} }{(a_\ell^2 - a_s^2 + x)^{1 / 2} + \sqrt{(a_\ell^2 - a_s^2)} } \biggr] | |||
\biggr\}_{a_s^2}^\infty | |||
</math> | |||
</td> | |||
</tr> | |||
<tr> | |||
<td align="right"> | |||
<math>~\Rightarrow ~~~ A_\ell</math> | |||
</td> | |||
<td align="center"> | |||
<math>~=</math> | |||
</td> | |||
<td align="left"> | |||
<math>~ | |||
- \frac{2a_\ell a_s^2}{(a_\ell^2 - a_s^2) a_\ell} | |||
- | |||
\frac{a_\ell a_s^2}{(a_\ell^2 - a_s^2)^{3 / 2}} | |||
\biggl\{ | |||
\ln \biggl[ \frac{ 1-e }{1+e} \biggr] | |||
\biggr\} | |||
</math> | |||
</td> | |||
</tr> | |||
<tr> | |||
<td align="right"> | |||
| |||
</td> | |||
<td align="center"> | |||
<math>~=</math> | |||
</td> | |||
<td align="left"> | |||
<math>~ | |||
\frac{ (1-e^2)}{e^3} | |||
\biggl\{ | |||
\ln \biggl[ \frac{1+e}{ 1-e } \biggr] | |||
\biggr\} | |||
- \frac{2(1-e^2)}{e^2 } | |||
\, , | |||
</math> | |||
</td> | |||
</tr> | |||
</table> | |||
where, as above, <math>~e \equiv (1 - a_s^2/a_\ell^2)^{1 / 2}</math>. Now, given that <math>~A_m = A_s</math>, in this case we appreciate that, | |||
<table border="0" cellpadding="5" align="center"> | |||
<tr> | |||
<td align="right"> | |||
<math>~2</math> | |||
</td> | |||
<td align="center"> | |||
<math>~=</math> | |||
</td> | |||
<td align="left"> | |||
<math>~A_\ell + A_m + A_s = A_\ell + 2A_s</math> | |||
</td> | |||
</tr> | |||
<tr> | |||
<td align="right"> | |||
<math>~\Rightarrow ~~~ A_s</math> | |||
</td> | |||
<td align="center"> | |||
<math>~=</math> | |||
</td> | |||
<td align="left"> | |||
<math>~1 - \frac{A_\ell}{2} </math> | |||
</td> | |||
</tr> | |||
<tr> | |||
<td align="right"> | |||
| |||
</td> | |||
<td align="center"> | |||
<math>~=</math> | |||
</td> | |||
<td align="left"> | |||
<math>~1 - \frac{1}{2}\biggl[ \frac{ (1-e^2)}{e^3} | |||
\cdot | |||
\ln \biggl( \frac{1+e}{ 1-e } \biggr) | |||
- \frac{2(1-e^2)}{e^2 } | |||
\biggr] </math> | |||
</td> | |||
</tr> | |||
<tr> | |||
<td align="right"> | |||
| |||
</td> | |||
<td align="center"> | |||
<math>~=</math> | |||
</td> | |||
<td align="left"> | |||
<math>~ | |||
\frac{1}{e^2 } | |||
- \frac{ (1-e^2)}{2e^3} | |||
\cdot | |||
\ln \biggl( \frac{1+e}{ 1-e } \biggr) \, . | |||
</math> | |||
</td> | |||
</tr> | |||
</table> | |||
{{LSU_WorkInProgress}} | {{LSU_WorkInProgress}} | ||
=Work In Progress= | |||
==Derivation of Expression for Gravitational Potential== | |||
In §373 (p. 700) of his book titled, ''Hydrodynamics'', [[User:Tohline/Appendix/References#Lamb32|Lamb32]] states that, "<font color="maroon">The gravitation-potential, at internal points, of a uniform mass enclosed by the surface</font> | |||
<table border="0" cellpadding="5" align="center"> | |||
<tr> | |||
<td align="right"> | |||
<math>~ | |||
\frac{x^2}{a^2} + \frac{y^2}{b^2} + \frac{z^2}{c^2} | |||
</math> | |||
</td> | |||
<td align="center"> | |||
<math>~=</math> | |||
</td> | |||
<td align="left"> | |||
<math>~1</math> | |||
</td> | |||
</tr> | |||
<tr><td align="center" colspan="3">[ [[User:Tohline/Appendix/References#Lamb32|Lamb32]], <font color="#00CC00">§373, Eq. (1)</font> ]</td></tr> | |||
</table> | |||
<font color="maroon">… may be written</font> | |||
<table border="0" cellpadding="5" align="center"> | |||
<tr> | |||
<td align="right"> | |||
<math>~\frac{\Phi(\vec{x})}{G}</math> | |||
</td> | |||
<td align="center"> | |||
<math>~=</math> | |||
</td> | |||
<td align="left"> | |||
<math>~ | |||
\pi \rho (\alpha_0 x^2 + \beta_0 y^2 + \gamma_0 z^2 - \chi_0) \, , | |||
</math> | |||
</td> | |||
</tr> | |||
<tr><td align="center" colspan="3">[ [[User:Tohline/Appendix/References#Lamb32|Lamb32]], <font color="#00CC00">§373, Eq. (4)</font> ]</td></tr> | |||
</table> | |||
<font color="maroon">where, as in §114,</font>" | |||
<table border="0" cellpadding="5" align="center"> | |||
<tr> | |||
<td align="right"> | |||
<math>~\frac{\alpha_0}{abc} </math> | |||
</td> | |||
<td align="center"> | |||
<math>~=</math> | |||
</td> | |||
<td align="left"> | |||
<math>~\int_0^\infty \frac{d\lambda}{(a^2 + \lambda)\Delta} \, ,</math> | |||
</td> | |||
<td align="center"> </td> | |||
<td align="right"> | |||
<math>~\frac{\beta_0}{abc} </math> | |||
</td> | |||
<td align="center"> | |||
<math>~=</math> | |||
</td> | |||
<td align="left"> | |||
<math>~\int_0^\infty \frac{d\lambda}{(b^2 + \lambda)\Delta} \, ,</math> | |||
</td> | |||
</tr> | |||
<tr> | |||
<td align="right"> | |||
<math>~\frac{\gamma_0}{abc} </math> | |||
</td> | |||
<td align="center"> | |||
<math>~=</math> | |||
</td> | |||
<td align="left"> | |||
<math>~\int_0^\infty \frac{d\lambda}{(c^2 + \lambda)\Delta} \, ,</math> | |||
</td> | |||
<td align="center"> </td> | |||
<td align="right"> | |||
<math>~\frac{\chi_0}{abc} </math> | |||
</td> | |||
<td align="center"> | |||
<math>~=</math> | |||
</td> | |||
<td align="left"> | |||
<math>~\int_0^\infty \frac{d\lambda}{\Delta} \, ,</math> | |||
</td> | |||
</tr> | |||
<tr><td align="center" colspan="7">[ [[User:Tohline/Appendix/References#Lamb32|Lamb32]], <font color="#00CC00">§373, Eqs. (5) & (6)</font> ]</td></tr> | |||
</table> | |||
and, | |||
<table border="0" cellpadding="5" align="center"> | |||
<tr> | |||
<td align="right"> | |||
<math>~\Delta</math> | |||
</td> | |||
<td align="center"> | |||
<math>~=</math> | |||
</td> | |||
<td align="left"> | |||
<math>~[(a^2 + \lambda)(b^2 + \lambda)(c^2 + \lambda)]^{1 / 2} \, .</math> | |||
</td> | |||
</tr> | |||
<tr><td align="center" colspan="3">[ [[User:Tohline/Appendix/References#Lamb32|Lamb32]], <font color="#00CC00">§373, Eq. (3)</font> ]</td></tr> | |||
</table> | |||
Although different variable names have been used, it is easy to see the correspondence between these expressions and the ''defining integral expressions'' that we have drawn from the more recent publications of [[User:Tohline/Appendix/References#EFE|EFE]] and [[User:Tohline/Appendix/References#BT87|BT87]] and [[#Gravitational_Potential|presented above]]. Here, we are interested in demonstrating how [[User:Tohline/Appendix/References#Lamb32|Lamb32]] derived his expression for the potential inside (and on the surface of) an homogeneous ellipsoid. | |||
==Acceleration at the Pole== | ==Acceleration at the Pole== | ||
Line 1,792: | Line 2,134: | ||
* [[User:Tohline/Apps/MaclaurinSpheroids#Maclaurin_Spheroids_.28axisymmetric_structure.29|Properties of Maclaurin Spheroids]] | * [[User:Tohline/Apps/MaclaurinSpheroids#Maclaurin_Spheroids_.28axisymmetric_structure.29|Properties of Maclaurin Spheroids]] | ||
* [[User:Tohline/Apps/MaclaurinSpheroids/GoogleBooks#Excerpts_from_A_Treatise_of_Fluxions|Excerpts from Maclaurin's (1742) ''A Treatise of Fluxions'']] | * [[User:Tohline/Apps/MaclaurinSpheroids/GoogleBooks#Excerpts_from_A_Treatise_of_Fluxions|Excerpts from Maclaurin's (1742) ''A Treatise of Fluxions'']] | ||
* [[User:Tohline/ThreeDimensionalConfigurations/FerrersPotential#Ferrers_.281877.29_Gravitational_Potential_for_Inhomogeneous_Ellipsoids|Inhomogeneous Ellipsoids Leading to Ferrers Potentials]] | |||
=Footnotes= | =Footnotes= |
Latest revision as of 03:49, 11 December 2020
Properties of Homogeneous Ellipsoids (1)
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Gravitational Potential
The Defining Integral Expressions
As has been shown in a separate discussion titled, "Origin of the Poisson Equation," the acceleration due to the gravitational attraction of a distribution of mass <math>~\rho</math><math>(\vec{x})</math> can be derived from the gradient of a scalar potential <math>~\Phi</math><math>(\vec{x})</math> defined as follows:
<math> \Phi(\vec{x}) \equiv - \int \frac{G \rho(\vec{x}')}{|\vec{x}' - \vec{x}|} d^3 x' . </math>
As has been explicitly demonstrated in Chapter 3 of EFE and summarized in Table 2-2 (p. 57) of BT87, for an homogeneous ellipsoid this volume integral can be evaluated analytically in closed form. Specifically, at an internal point or on the surface of an homogeneous ellipsoid with semi-axes <math>~(x,y,z) = (a_1,a_2,a_3)</math>,
<math>
~\Phi(\vec{x}) = -\pi G \rho \biggl[ I_\mathrm{BT} a_1^2 - \biggl(A_1 x^2 + A_2 y^2 +A_3 z^2 \biggr) \biggr],
</math>
[ EFE, Chapter 3, Eq. (40)1,2 ]
[ BT87, Chapter 2, Table 2-2 ]
where,
<math> ~A_i </math> |
<math> ~\equiv </math> |
<math> ~a_1 a_2 a_3 \int_0^\infty \frac{du}{\Delta (a_i^2 + u )} , </math> |
<math> ~I_\mathrm{BT} </math> |
<math> ~\equiv </math> |
<math> ~\frac{a_2 a_3}{a_1} \int_0^\infty \frac{du}{\Delta} = A_1 + A_2\biggl(\frac{a_2}{a_1}\biggr)^2+ A_3\biggl(\frac{a_3}{a_1}\biggr)^2 , </math> |
<math> ~\Delta </math> |
<math> ~\equiv </math> |
<math> ~\biggl[ (a_1^2 + u)(a_2^2 + u)(a_3^2 + u) \biggr]^{1/2} . </math> |
This definite-integral definition of <math>~A_i</math> may also be found in:
- Lamb32: as Eq. (6) in §114 (p. 153); and as Eq. (5) in §373 (p. 700).
- T78: as Eq. (5) in §10.2 (p. 234), but note that there is an error in the denominator of the right-hand-side — <math>~a_1</math> appears instead of <math>~a_i</math>.
Evaluation of Coefficients
As is detailed below, the integrals defining <math>~A_i</math> and <math>~I_\mathrm{BT}</math> can be evaluated in terms of the incomplete elliptic integral of the first kind,
<math> ~F(\theta,k) \equiv \int_0^\theta \frac{d\theta '}{\sqrt{1 - k^2 \sin^2\theta '}} ~~ , </math>
and/or the incomplete elliptic integral of the second kind,
<math> E(\theta,k) \equiv \int_0^\theta {\sqrt{1 - k^2 \sin^2\theta '}}~d\theta ' ~~ , </math>
where, for our particular problem,
<math>
~\theta \equiv \cos^{-1} \biggl(\frac{a_3}{a_1} \biggr) ,
</math>
<math>
~k \equiv \biggl[\frac{a_1^2 - a_2^2}{a_1^2 - a_3^2} \biggr]^{1/2} = \biggl[\frac{1 - (a_2/a_1)^2}{1 - (a_3/a_1)^2} \biggr]^{1/2},
</math>
[ EFE, Chapter 3, Eq. (32) ]
or the integrals can be evaluated in terms of more elementary functions if either <math>~a_2 = a_1</math> (oblate spheroids) or <math>~a_3 = a_2</math> (prolate spheroids).
Triaxial Configurations <math>~(a_1 > a_2 > a_3)</math>
If the three principal axes of the configuration are unequal in length and related to one another such that <math>~a_1 > a_2 > a_3 </math>,
<math> ~A_1 </math> |
<math> ~= </math> |
<math> ~\frac{2a_2 a_3}{a_1^2} \biggl[ \frac{F(\theta,k) - E(\theta,k)}{k^2 \sin^3\theta} \biggr] ~~; </math> |
<math> ~A_2 </math> |
<math> ~= </math> |
<math> ~\frac{2a_2 a_3}{a_1^2} \biggl[ \frac{E(\theta,k) - (1-k^2)F(\theta,k) - (a_3/a_2)k^2\sin\theta}{k^2 (1-k^2) \sin^3\theta}\biggr] ~~; </math> |
<math> ~A_3 </math> |
<math> ~= </math> |
<math> ~\frac{2a_2 a_3}{a_1^2} \biggl[ \frac{(a_2/a_3) \sin\theta - E(\theta,k)}{(1-k^2) \sin^3\theta} \biggr] ~~; </math> |
<math> ~I_\mathrm{BT} </math> |
<math> ~= </math> |
<math> ~\frac{2a_2 a_3}{a_1^2} \biggl[ \frac{F(\theta,k)}{\sin\theta} \biggr] ~~. </math> |
[ EFE, Chapter 3, Eqs. (33), (34) & (35) ]
Notice that there is no need to specify the actual value of <math>~a_1</math> in any of these expressions, as they each can be written in terms of the pair of axis ratios, <math>~a_2/a_1</math> and <math>~a_3/a_1</math>. As a sanity check, let's see if these three expressions can be related to one another in the manner described by equation (108) in §21 of EFE, namely,
<math>~\sum_{\ell=1}^3 A_\ell = 2 \, .</math>
<math>~\frac{a_1^2}{2a_2 a_3} \biggl[A_1 + A_3 + A_2\biggr]</math> |
<math>~=</math> |
<math>~ \frac{F(\theta,k) - E(\theta,k)}{k^2 \sin^3\theta} + \frac{(a_2/a_3) \sin\theta - E(\theta,k)}{(1-k^2) \sin^3\theta} </math> |
|
|
<math>~+ \frac{E(\theta,k) - (1-k^2)F(\theta,k) - (a_3/a_2)k^2\sin\theta}{k^2 (1-k^2) \sin^3\theta}</math> |
|
<math>~=</math> |
<math>~ \frac{1}{k^2(1-k^2)\sin^3\theta} \biggl\{(1-k^2)F(\theta,k) - (1-k^2)E(\theta,k) + k^2(a_2/a_3) \sin\theta </math> |
|
|
<math>~- k^2E(\theta,k) + E(\theta,k) - (1-k^2)F(\theta,k) - (a_3/a_2)k^2\sin\theta\biggr\}</math> |
|
<math>~=</math> |
<math>~ \frac{1}{(1-k^2)\sin^2\theta} \biggl[ \frac{a_2}{a_3} - \frac{a_3}{a_2} \biggr]</math> |
|
<math>~=</math> |
<math>~ \frac{a_1^2}{a_2 a_3} \, .</math> |
Q.E.D.
Oblate Spheroids <math>~(a_1 = a_2 > a_3)</math>
If the longest axis, <math>~a_1</math>, and the intermediate axis, <math>~a_2</math>, of the ellipsoid are equal to one another, then an equatorial cross-section of the object presents a circle of radius <math>~a_1</math> and the object is referred to as an oblate spheroid. For homogeneous oblate spheroids, evaluation of the integrals defining <math>~A_i</math> and <math>~I_\mathrm{BT}</math> gives,
<math> ~A_1 </math> |
<math> ~= </math> |
<math> ~\frac{1}{e^2} \biggl[ \frac{\sin^{-1}e}{e} - (1-e^2)^{1/2} \biggr] (1-e^2)^{1/2} ~~; </math> |
<math> ~A_2 </math> |
<math> ~= </math> |
<math> ~A_1 ~~; </math> |
<math> ~A_3 </math> |
<math> ~= </math> |
<math> ~\frac{2}{e^2} \biggl[ (1-e^2)^{-1/2} - \frac{\sin^{-1}e}{e} \biggr] (1-e^2)^{1/2} ~~; </math> |
<math> ~I_\mathrm{BT} </math> |
<math> ~= </math> |
<math> ~2A_1 + A_3 (1-e^2) = 2 (1-e^2)^{1/2} \biggl[ \frac{\sin^{-1}e}{e} \biggr] ~~, </math> |
where the eccentricity,
<math> ~e \equiv \biggl[1 - \biggl(\frac{a_3}{a_1}\biggr)^2 \biggr]^{1/2} ~~. </math>
Prolate Spheroids <math>~(a_1 > a_2 = a_3)</math>
If the shortest axis <math>~(a_3)</math> and the intermediate axis <math>~(a_2)</math> of the ellipsoid are equal to one another, then a cross-section in the <math>~x-y</math> plane of the object presents a circle of radius <math>~a_3</math> and the object is referred to as a prolate spheroid. For homogeneous prolate spheroids, evaluation of the integrals defining <math>~A_i</math> and <math>~I_\mathrm{BT}</math> gives,
<math> ~A_1 </math> |
<math> ~= </math> |
<math> \ln\biggl[ \frac{1+e}{1-e} \biggr] \frac{(1-e^2)}{e^3} - \frac{2(1-e^2)}{e^2} ~~; </math> |
<math> ~A_2 </math> |
<math> ~= </math> |
<math> \frac{1}{e^2} - \ln\biggl[ \frac{1+e}{1-e} \biggr]\frac{(1-e^2)}{2e^3} ~~; </math> |
<math> ~A_3 </math> |
<math> ~= </math> |
<math> A_2 ~~; </math> |
<math> ~I_\mathrm{BT} </math> |
<math> ~= </math> |
<math>~ A_1 + 2(1-e^2)A_2 = \ln\biggl[ \frac{1+e}{1-e} \biggr]\frac{(1-e^2)}{e} ~~, </math> |
[ EFE, Chapter 3, Eq. (38) ]
where, again, the eccentricity,
<math> ~e \equiv \biggl[1 - \biggl(\frac{a_3}{a_1}\biggr)^2 \biggr]^{1/2} ~~. </math>
Example Evaluations
Here we adopt the notation mapping, <math>~(a_1, a_2, a_3) ~\leftrightarrow~ (a,b,c)</math>. In general, for a given pair of axis ratios, <math>~(\tfrac{b}{a}, \tfrac{c}{a})</math>, a determination of the coefficients, <math>~A_1</math>, <math>~A_2</math>, and <math>~A_3</math>, requires evaluation of elliptic integrals. For practical applications, we have decided to evaluate these special functions using the fortran functions provided in association with the book, Numerical Recipes in Fortran; in order to obtain the results presented in our Table 2, below, we modified those default (single-precision) routines to generate results with double-precision accuracy. Along the way (see results posted in our Table 1), we pulled cruder evaluations of both elliptic integrals, <math>~F(\theta,k)</math> and <math>~E(\theta,k)</math>, from the printed special-functions table found in a CRC handbook.
As we developed/debugged the numerical tool that would allow us to determine the values of these three coefficients for arbitrary choices of the pair of axis ratios, it was important that we compare the results of our calculations to those that have appeared in the published literature. As a primary point of comparison, we chose to use The properties of the Jacobi ellipsoids as tabulated in §39 (Chapter 6) of Chandrasekhar's EFE. In particular, for twenty-six separate axis-ratio pairs, Chandrasekhar's Table IV lists the values of the square of the angular velocity, <math>~\Omega^2</math>, and the total angular momentum, <math>~L</math>, of an equilibrium Jacobi ellipsoid that is associated with each axis-ratio pair. We should be able to duplicate — or, via double-precision arithmetic, improve — Chandrasekhar's tabulated results using the expressions for "omega2",
<math>~\frac{\Omega^2}{\pi G\rho}</math> |
<math>~=</math> |
<math>~2B_{12}</math> |
[ EFE, §39, Eq. (5) ] | ||
|
<math>~=</math> |
<math>~2\biggl[\frac{A_1 - (b/a)^2A_2}{1-(b/a)^2} \biggr] \, ,</math> |
[using, EFE, §21, Eqs. (105) & (107) ] |
and, for "angmom",
<math>~\frac{L}{(GM^3)^{1/2}(abc)^{1/6}}</math> |
<math>~=</math> |
<math>~\frac{\sqrt{3}}{10}\biggl[ \frac{a^2 + b^2}{(abc)^{2/3}} \biggr]\biggl(\frac{\Omega^2}{\pi G \rho}\biggr)^{1/2} </math> |
[ EFE, §39, Eq. (16) ] | ||
|
<math>~=</math> |
<math>~\frac{\sqrt{3}}{10}\biggl[ \frac{1 + (b/a)^2}{(b/a)^{2/3}(c/a)^{2/3}} \biggr]\biggl(\frac{\Omega^2}{\pi G \rho}\biggr)^{1/2} \, .</math> |
Or, in connection with the free-energy discussion found in D. M. Christodoulou, D. Kazanas, I. Shlosman, & J. E. Tohline (1995, ApJ, 446, 472),
<math>~\frac{5L}{M}</math> |
<math>~=</math> |
<math>~a^2\biggl[ 1 + \biggl(\frac{b}{a}\biggr)^2 \biggr]\biggl[\frac{\Omega^2}{\pi G \rho}\biggr]^{1/2}</math> |
|
<math>~=</math> |
<math>~\biggl[ \frac{15}{4}\biggl(\frac{b}{a}\biggr)^{-1}\biggl(\frac{c}{a}\biggr)^{-1} \biggr]^{2/3} \biggl[ 1 + \biggl(\frac{b}{a}\biggr)^2 \biggr]\biggl[\frac{\Omega^2}{\pi G \rho}\biggr]^{1/2}</math> |
Table 1: Example Evaluations | |||||||||||
---|---|---|---|---|---|---|---|---|---|---|---|
Given | Determined using calculator and (crude) CRC tables of elliptic integrals | ||||||||||
<math>~\frac{a_2}{a_1}</math> | <math>~\frac{a_3}{a_1}</math> | <math>~\theta</math> | <math>~k</math> | <math>~\sin^{-1}k</math> | <math>~F(\theta,k)</math> | <math>~E(\theta,k)</math> | <math>~A_1</math> | <math>~A_2</math> | <math>~A_3</math> | ||
radians | degrees | radians | degrees | ||||||||
1.00 | 0.582724 | 0.94871973 | 54.3576 | 0.00000000 | 0.00000000 | 0.000000 | 0.94871973 | 0.94871973 | 0.51589042 | 0.51589042 | 0.96821916 |
0.96 | 0.570801 | 0.96331527 | 55.1939 | 0.34101077 | 0.34799191 | 19.9385 | 0.975 | 0.946 | +0.4937 | +0.5319 | +0.9744 |
0.60 | 0.433781 | 1.12211141 | 64.292 | 0.88788426 | 1.09272580 | 62.609 | 1.3375 | 0.9547 | 0.3455 | 0.6741 | 0.9803 |
With regard to our Table 1 (immediately above): To begin with, we picked three axis-ratio pairs from Table IV of EFE, and considered them to be "given." For each pair, we used a hand-held calculator to calculate the corresponding values of the two arguments of the elliptic integrals, namely, <math>~\theta</math> and <math>~k</math>, as defined above. By default, each determined value of <math>~\theta</math> is in radians. Because the published CRC special-functions tables quantify both arguments of the special functions in angular degrees, we converted <math>~\theta</math> from radians to degrees (see column 4 of Table 1) and, similarly, we converted <math>~\sin^{-1}k</math> to degrees (see column 7 of Table 1). For the axisymmetric configuration — the first row of numbers in Table 1, for which <math>~a_2/a_1 = 1</math> — the coefficients, <math>~A_1</math>, <math>~A_2</math>, and <math>~A_3</math>, were determined to eight digits of precision using the appropriate expressions for oblate spheroids. Note that, in this axisymmetric case, <math>~F(\theta,0) = E(\theta,0) = \theta</math>, but these function values are irrelevant with respect to the determination of the <math>~A_\ell</math> coefficients.
Table 2: Double-Precision Evaluations
Related to Table IV in EFE, Chapter 6, §39 (p. 103) |
---|
precision b/a c/a F E A1 A2 A3 [2-(A1+A2+A3)]/2 1.00 0.582724 ----- ----- 5.158904180D-01 5.158904180D-01 9.682191640D-01 0.0D+00 0.96 0.570801 9.782631357D-01 9.487496699D-01 5.024584655D-01 5.292952683D-01 9.682462661D-01 4.4D-16 0.92 0.558330 1.009516282D+00 9.489290273D-01 4.884500698D-01 5.432292722D-01 9.683206580D-01 0.0D+00 0.88 0.545263 1.042655826D+00 9.492826127D-01 4.738278227D-01 5.577100115D-01 9.684621658D-01 2.2D-16 0.84 0.531574 1.077849658D+00 9.498068890D-01 4.585648648D-01 5.727687434D-01 9.686663918D-01 2.2D-16 0.80 0.517216 1.115314984D+00 9.505192815D-01 4.426242197D-01 5.884274351D-01 9.689483451D-01 -4.4D-16 0.76 0.502147 1.155290552D+00 9.514282210D-01 4.259717080D-01 6.047127268D-01 9.693155652D-01 2.2D-16 0.72 0.486322 1.198053140D+00 9.525420558D-01 4.085724682D-01 6.216515450D-01 9.697759868D-01 -4.4D-16 0.68 0.469689 1.243931393D+00 9.538724717D-01 3.903895871D-01 6.392680107D-01 9.703424022D-01 2.2D-16 0.64 0.452194 1.293310292D+00 9.554288569D-01 3.713872890D-01 6.575860416D-01 9.710266694D-01 4.4D-16 0.60 0.433781 1.346645618D+00 9.572180643D-01 3.515319835D-01 6.766289416D-01 9.718390749D-01 -3.3D-16 0.56 0.414386 1.404492405D+00 9.592491501D-01 3.307908374D-01 6.964136019D-01 9.727955606D-01 -6.7D-16 0.52 0.393944 1.467522473D+00 9.615263122D-01 3.091371405D-01 7.169543256D-01 9.739085339D-01 4.4D-16 0.48 0.372384 1.536570313D+00 9.640523748D-01 2.865506903D-01 7.382563770D-01 9.751929327D-01 -2.2D-16 0.44 0.349632 1.612684395D+00 9.668252052D-01 2.630231082D-01 7.603153245D-01 9.766615673D-01 8.9D-16 0.40 0.325609 1.697213059D+00 9.698379297D-01 2.385623719D-01 7.831101146D-01 9.783275135D-01 0.0D+00 0.36 0.300232 1.791930117D+00 9.730763540D-01 2.132011181D-01 8.065964525D-01 9.802024294D-01 2.2D-15 0.32 0.273419 1.899227853D+00 9.765135895D-01 1.870102340D-01 8.307027033D-01 9.822870627D-01 -1.3D-15 0.28 0.245083 2.022466812D+00 9.801112910D-01 1.601127311D-01 8.553054155D-01 9.845818534D-01 -2.4D-15 0.24 0.215143 2.166555572D+00 9.838093161D-01 1.327137129D-01 8.802197538D-01 9.870665333D-01 1.4D-14 0.20 0.183524 2.339102805D+00 9.875217566D-01 1.051389104D-01 9.051602520D-01 9.897008376D-01 -1.6D-14 0.16 0.150166 2.552849055D+00 9.911267582D-01 7.790060179D-02 9.296886827D-01 9.924107155D-01 -3.4D-14 0.12 0.115038 2.831664019D+00 9.944537935D-01 5.180880535D-02 9.531203882D-01 9.950708065D-01 1.4D-13 0.08 0.078166 3.229072310D+00 9.972669475D-01 2.817821170D-02 9.743504218D-01 9.974713665D-01 3.9D-13 0.04 0.039688 3.915557866D+00 9.992484565D-01 9.281550546D-03 9.914470033D-01 9.992714461D-01 9.8D-13 |
With regard to our Table 2 (immediately above): Next, given each pair of axis ratios, <math>~(\tfrac{b}{a},\tfrac{c}{a})</math> — copied from Table IV of EFE (see columns 1 and 2 of our Table 2) — we used some fortran routines from Numerical Recipes to calculate <math>~F(\theta,k)</math> and <math>~E(\theta,k)</math> (see columns 3 and 4 of our Table 2); we converted the routines to accommodate double-precision arithmetic. We subsequently evaluated the coefficients, <math>~A_1</math>, <math>~A_2</math>, and <math>~A_3</math>, (columns 5, 6, & 7 of Table 2) using the expressions given above, then demonstrated that, in each case, the three coefficients sum to 2.0 to better than twelve digits accuracy.
Derivation of Expressions for Ai
Let's carry out the integrals that appear in the definition of the <math>~A_i</math> coefficients,
<math> ~A_i </math> |
<math> ~\equiv </math> |
<math> ~a_\ell a_m a_s \int_0^\infty \frac{du}{\Delta (a_i^2 + u )} , </math> |
where,
<math> ~\Delta </math> |
<math> ~\equiv </math> |
<math> ~\biggl[ (a_\ell^2 + u)(a_m^2 + u)(a_s^2 + u) \biggr]^{1/2} \, . </math> |
Here, we are adopting the <math>~(\ell, m, s)</math> subscript notation to identify which semi-axis length is the (largest, medium-length, smallest).
Evaluating Aℓ
First, let's focus on the coefficient associated with the longest axis <math>~(i = \ell)</math>:
<math>~\frac{A_\ell}{a_\ell a_m a_s}</math> |
<math>~=</math> |
<math> ~\int_0^\infty \biggl[ (a_\ell^2 + u)^3(a_m^2 + u)(a_s^2 + u) \biggr]^{-1 / 2} du </math> |
Changing the integration variable to <math>~x \equiv -u</math>, we obtain a definite integral expression that appears as equation (3.133.1) in I. W. Gradshteyn & I. M. Ryzhik (2007; 7th Edition), Table of Integrals, Series, and Products — hereafter, GR7th — namely,
<math>~\frac{A_\ell}{a_\ell a_m a_s}</math> |
<math>~=</math> |
<math> ~\int_{-\infty}^0 \biggl[ (a_\ell^2 - x)^3(a_m^2 - x)(a_s^2 - x) \biggr]^{-1 / 2} dx </math> |
|
|
<math>~=</math> |
<math> ~\frac{2}{(a_\ell^2 - a_m^2) \sqrt{a_\ell^2 - a_s^2}} \biggl[ F(\alpha, p) - E(\alpha, p) \biggr] </math> |
… valid for <math>[a_\ell > a_m > a_s \ge 0]</math> |
GR7th, p. 255, Eq. (3.133.1) |
where (see p. 254 of GR7th),
<math>~\sin^2\alpha</math> |
<math>~\equiv</math> |
<math>~\frac{a_\ell^2 - a_s^2}{a_\ell^2 - 0} = 1 - \frac{a_s^2}{a_\ell^2} \, ,</math> |
<math>~p</math> |
<math>~\equiv</math> |
<math>~\biggl[ \frac{a_\ell^2 - a_m^2}{a_\ell^2 - a_s^2} \biggr]^{1 / 2} \, ,</math> |
and where, <math>~E(\alpha, p)</math> and <math>~F(\alpha, p)</math> are elliptic integrals of the first and second kind, respectively. (Note that in the notation convention adopted by GR7th, the order of the argument list, <math>~(\alpha, p)</math>, is flipped relative to the convention that we have adopted above and elsewhere throughout our online, MediaWiki-based chapters.) Recognizing that,
<math>~p^2 \sin^3\alpha</math> |
<math>~=</math> |
<math>~ \biggl[\frac{a_\ell^2 - a_s^2}{a_\ell^2 }\biggr]^{3 / 2}\biggl[ \frac{a_\ell^2 - a_m^2}{a_\ell^2 - a_s^2} \biggr] = \frac{(a_\ell^2 - a_s^2)^{1 / 2}}{a_\ell^3 } \biggl[ a_\ell^2 - a_m^2 \biggr] \, , </math> |
we see that the expression for <math>~A_\ell</math> can be rewritten as,
<math>~\frac{A_\ell}{a_\ell a_m a_s}</math> |
<math>~=</math> |
<math> ~\frac{2}{a_\ell^3 ~p^2 \sin^3\alpha} \biggl[ F(\alpha, p) - E(\alpha, p) \biggr] \, . </math> |
This matches the expression that we have provided for <math>~A_1</math>, above in the context of triaxial configurations.
Evaluating Am
Next, let's evaluate the coefficient associated with the axis of intermediate length <math>~(i = m)</math>:
<math>~\frac{A_m}{a_\ell a_m a_s}</math> |
<math>~=</math> |
<math> ~\int_0^\infty \biggl[ (a_\ell^2 + u)(a_m^2 + u)^3(a_s^2 + u) \biggr]^{-1 / 2} du \, . </math> |
This time, by changing the integration variable to <math>~x \equiv -u</math>, we obtain a definite integral expression that appears as equation (3.133.7) in GR7th, namely,
<math>~\frac{A_m}{a_\ell a_m a_s}</math> |
<math>~=</math> |
<math> ~\int_{-\infty}^0 \biggl[ (a_\ell^2 - x)(a_m^2 - x)^3(a_s^2 - x) \biggr]^{-1 / 2} dx </math> |
|
|
<math>~=</math> |
<math> ~\frac{2\sqrt{a_\ell^2 - a_s^2}}{(a_\ell^2 - a_m^2) (a_m^2 - a_s^2)} E(\alpha, p) - \frac{2}{(a_\ell^2 - a_m^2) \sqrt{a_\ell^2 - a_s^2}} F(\alpha, p) - \frac{2}{a_m^2 - a_s^2} \biggl[ \frac{a_s^2}{a_\ell^2 a_m^2} \biggr]^{1 / 2} </math> |
… valid for <math>[a_\ell > a_m > a_s \ge 0]</math> |
GR7th, p. 256, Eq. (3.133.7) |
(Here, the parameters, <math>~\alpha</math> and <math>~p</math>, have the same definitions as in our above evaluation of <math>~A_\ell</math>.) This time it is useful to recognize that,
<math>~1 -p^2</math> |
<math>~=</math> |
<math>~ 1 - \frac{a_\ell^2 - a_m^2}{a_\ell^2 - a_s^2} = \frac{a_m^2 - a_s^2 }{a_\ell^2 - a_s^2} </math> |
in which case,
<math>~p^2(1-p^2) \sin^3\alpha</math> |
<math>~=</math> |
<math>~ \frac{ ( a_\ell^2 - a_m^2 )( a_m^2 - a_s^2 )}{a_\ell^3 (a_\ell^2 - a_s^2)^{1 / 2}} \, . </math> |
So the coefficient, <math>~A_m</math>, may be rewritten as,
<math>~p^2 (1-p^2) \sin^3\alpha\biggl[ \frac{A_m}{a_\ell a_m a_s} \biggr]</math> |
<math>~=</math> |
<math>~ \frac{ ( a_\ell^2 - a_m^2 )( a_m^2 - a_s^2 )}{a_\ell^3 (a_\ell^2 - a_s^2)^{1 / 2}} \biggl\{ \frac{2\sqrt{a_\ell^2 - a_s^2}}{(a_\ell^2 - a_m^2) (a_m^2 - a_s^2)} E(\alpha, p) ~-~ \frac{2}{(a_\ell^2 - a_m^2) \sqrt{a_\ell^2 - a_s^2}} F(\alpha, p) ~-~\frac{2}{a_m^2 - a_s^2} \biggl[ \frac{a_s^2}{a_\ell^2 a_m^2} \biggr]^{1 / 2} \biggr\} </math> |
|
<math>~=</math> |
<math>~ \frac{ 2}{a_\ell^3 } \biggl\{ E(\alpha, p) \biggr\} -~\frac{ 2( a_m^2 - a_s^2 )}{a_\ell^3 (a_\ell^2 - a_s^2)} \biggl\{ F(\alpha, p) \biggr\} -~\frac{ 2( a_\ell^2 - a_m^2 )}{a_\ell^3 (a_\ell^2 - a_s^2)^{1 / 2}} \biggl[ \frac{a_s}{a_\ell a_m} \biggr] </math> |
|
<math>~=</math> |
<math>~ \frac{ 2}{a_\ell^3 } \biggl\{ E(\alpha, p) -~(1-p^2) F(\alpha, p) -~p^2\sin\alpha \biggl[ \frac{a_s}{a_m} \biggr] \biggr\} </math> |
<math>~\Rightarrow ~~~ \frac{A_m}{a_\ell a_m a_s} </math> |
<math>~=</math> |
<math>~ \frac{ 2}{a_\ell^3 } \biggl[ \frac{ E(\alpha, p) -~(1-p^2) F(\alpha, p) -~(a_s/a_m)p^2\sin\alpha}{p^2 (1-p^2)\sin^3\alpha} \biggr] \, . </math> |
This matches the expression that we have provided for <math>~A_2</math>, above in the context of triaxial configurations.
Evaluating As
Finally, let's evaluate the coefficient associated with the shortest axis, <math>~(i = s)</math>:
<math>~\frac{A_s}{a_\ell a_m a_s}</math> |
<math>~=</math> |
<math> ~\int_0^\infty \biggl[ (a_\ell^2 + u)(a_m^2 + u)(a_s^2 + u)^3 \biggr]^{-1 / 2} du \, . </math> |
By changing the integration variable to <math>~x \equiv -u</math>, this time we obtain a definite integral expression that appears as equation (3.133.13) in GR7th, namely,
<math>~\frac{A_s}{a_\ell a_m a_s}</math> |
<math>~=</math> |
<math> ~\int_{-\infty}^0 \biggl[ (a_\ell^2 - x)(a_m^2 - x)(a_s^2 - x)^3 \biggr]^{-1 / 2} dx </math> |
|
|
<math>~=</math> |
<math> ~\frac{2}{(a_s^2 - a_m^2) \sqrt{a_\ell^2 - a_s^2}} E(\alpha, p) + \frac{2}{a_m^2 - a_s^2} \biggl[ \frac{a_m^2}{a_\ell^2 a_s^2} \biggr]^{1 / 2} </math> |
… valid for <math>[a_\ell > a_m > a_s > 0]</math> |
GR7th, p. 256, Eq. (3.133.13) |
(And, again, the parameters, <math>~\alpha</math> and <math>~p</math>, have the same definitions as in our above evaluation of <math>~A_\ell</math>.) Recognizing that,
<math>~(1-p^2) \sin^3\alpha</math> |
<math>~=</math> |
<math>~ \frac{ (a_\ell^2 - a_s^2)^{1 / 2}( a_m^2 - a_s^2 )}{a_\ell^3 } \, , </math> |
the coefficient, <math>~A_s</math>, may be rewritten as,
<math>~(1-p^2) \sin^3\alpha\biggl[ \frac{A_s}{a_\ell a_m a_s} \biggr]</math> |
<math>~=</math> |
<math>~ \frac{ (a_\ell^2 - a_s^2)^{1 / 2}( a_m^2 - a_s^2 )}{a_\ell^3 } \biggl\{ ~\frac{2}{(a_s^2 - a_m^2) \sqrt{a_\ell^2 - a_s^2}} E(\alpha, p) + \frac{2}{a_m^2 - a_s^2} \biggl[ \frac{a_m^2}{a_\ell^2 a_s^2} \biggr]^{1 / 2} \biggr\} </math> |
|
<math>~=</math> |
<math>~ \frac{ 2}{a_\ell^3 } \biggl\{ - E(\alpha, p) \biggr\} ~+~ \frac{ 2(a_\ell^2 - a_s^2)^{1 / 2}}{a_\ell^3 } \biggl[ \frac{a_m}{a_\ell a_s} \biggr] </math> |
|
<math>~=</math> |
<math>~ \frac{ 2}{a_\ell^3 } \biggl\{ \biggl(\frac{a_m}{a_s}\biggr) \sin\alpha - E(\alpha, p) \biggr\} </math> |
<math>~\Rightarrow ~~~ \frac{A_s}{a_\ell a_m a_s}</math> |
<math>~=</math> |
<math>~ \frac{ 2}{a_\ell^3 } \biggl[\frac{ (a_m/a_s) \sin\alpha - E(\alpha, p)}{ (1-p^2) \sin^3\alpha } \biggr] \, . </math> |
This matches the expression that we have provided for <math>~A_3</math>, above in the context of triaxial configurations.
When am = aℓ
When the length of the intermediate axis is the same as the length of the longest axis — that is, when we are dealing with an oblate spheroid — the coefficient associated with the longest axis is,
<math>~\frac{A_\ell}{a_\ell^2 a_s}</math> |
<math>~=</math> |
<math> ~\int_0^\infty \frac{du}{ (a_\ell^2 + u)^2(a_s^2 + u)^{1 / 2} } \, . </math> |
Changing the integration variable to <math>~x \equiv (a_\ell^2 + u)</math>, we obtain an integral expression that appears as equation (2.228.1) in GR7th, namely,
<math>~\frac{A_\ell}{a_\ell^2 a_s}</math> |
<math>~=</math> |
<math> ~\int_{a_\ell^2}^\infty \frac{dx}{ x^2(a_s^2 - a_\ell^2 + x)^{1 / 2} } </math> |
|
<math>~=</math> |
<math> - \biggl[ \frac{\sqrt{a_s^2 - a_\ell^2 + x}}{(a_s^2 - a_\ell^2) x}\biggr]_{a_\ell^2}^\infty - \frac{1}{2(a_s^2 - a_\ell^2)} ~\int_{a_\ell^2}^\infty \frac{dx}{ x(a_s^2 - a_\ell^2 + x)^{1 / 2} } </math> |
|
<math>~=</math> |
<math>- \frac{a_s}{(a_\ell^2 - a_s^2 ) a_\ell^2} + \frac{1}{2(a_\ell^2 - a_s^2)} ~\int_{a_\ell^2}^\infty \frac{dx}{ x(a_s^2 - a_\ell^2 + x)^{1 / 2} } \, . </math> |
The remaining integral in this expression appears as equation (2.224.5) in GR7th. Its resolution depends on the sign of the constant term in the denominator, <math>~(a_s^2 - a_\ell^2)</math>. Given that this term is negative, the integration gives,
<math>~\frac{A_\ell}{a_\ell^2 a_s}</math> |
<math>~=</math> |
<math>~- \frac{a_s}{(a_\ell^2 - a_s^2) a_\ell^2} + \frac{1}{2(a_\ell^2 - a_s^2)} ~\biggl\{ \frac{2}{ (a_\ell^2 - a_s^2)^{1 / 2} } \tan^{-1}\bigg[ \frac{(a_s^2 - a_\ell^2 + x)^{1 / 2} }{ (a_\ell^2 - a_s^2)^{1 / 2}} \biggr] \biggr\}_{a_\ell^2}^\infty </math> |
<math>~\Rightarrow~~~A_\ell</math> |
<math>~=</math> |
<math>~- \frac{a_s^2}{(a_\ell^2 - a_s^2) } + ~\frac{a_\ell^2 a_s}{ (a_\ell^2 - a_s^2)^{3 / 2} } \biggl\{\frac{\pi}{2} - \tan^{-1}\bigg[ \frac{a_s }{ (a_\ell^2 - a_s^2)^{1 / 2}} \biggr] \biggr\} </math> |
|
<math>~=</math> |
<math>~- \frac{(1-e^2)}{e^2} + ~\frac{(1-e^2)^{1 / 2}}{ e^3 } \biggl\{\frac{\pi}{2} - \tan^{-1}\bigg[ \frac{ (1-e^2)^{1 / 2}}{ e} \biggr] \biggr\} </math> |
|
<math>~=</math> |
<math>~- \frac{(1-e^2)}{e^2} + ~\frac{(1-e^2)^{1 / 2}}{ e^3 } \biggl\{\frac{\pi}{2} - \cos^{-1}e \biggr\} </math> |
|
<math>~=</math> |
<math>~- \frac{(1-e^2)}{e^2} + ~\frac{(1-e^2)^{1 / 2}}{ e^3 } \biggl\{ \sin^{-1}e \biggr\} \, , </math> |
where, <math>~e \equiv (1 - a_s^2/a_\ell^2)^{1 / 2}</math>. Similarly, the coefficient associated with the shortest axis is,
<math>~\frac{A_s}{a_\ell^2 a_s}</math> |
<math>~=</math> |
<math> ~\int_0^\infty \frac{du}{ (a_\ell^2 + u)(a_s^2 + u)^{3 / 2} } \, . </math> |
This time, after changing the integration variable to <math>~x \equiv (a_\ell^2 + u)</math>, we obtain an integral expression that appears as equation (2.229.1) in GR7th, namely,
<math>~\frac{A_s}{a_\ell^2 a_s}</math> |
<math>~=</math> |
<math> ~\int_{a_\ell^2}^\infty \frac{dx}{ x(a_s^2 - a_\ell^2 + x)^{3 / 2} } </math> |
|
<math>~=</math> |
<math> \biggl[ \frac{2}{(a_s^2 - a_\ell^2) \sqrt{a_s^2 - a_\ell^2 + x}}\biggr]_{a_\ell^2}^\infty + \frac{1}{(a_s^2 - a_\ell^2)} ~\int_{a_\ell^2}^\infty \frac{dx}{ x(a_s^2 - a_\ell^2 + x)^{1 / 2} } \, . </math> |
As before, the remaining integral in this expression appears as equation (2.224.5) in GR7th; and, as before, the sign of the constant term in the denominator, <math>~(a_s^2 - a_\ell^2)</math>, is negative. Hence, the integration gives,
<math>~\frac{A_s}{a_\ell^2 a_s}</math> |
<math>~=</math> |
<math> \frac{2}{(a_\ell^2 - a_s^2) a_s} - \frac{1}{(a_\ell^2 - a_s^2)} ~\biggl\{ \frac{2}{ (a_\ell^2 - a_s^2)^{1 / 2} } \tan^{-1}\bigg[ \frac{(a_s^2 - a_\ell^2 + x)^{1 / 2} }{ (a_\ell^2 - a_s^2)^{1 / 2}} \biggr] \biggr\}_{a_\ell^2}^\infty </math> |
<math>~\Rightarrow ~~~ A_s</math> |
<math>~=</math> |
<math> \frac{2a_\ell^2 a_s}{(a_\ell^2 - a_s^2) a_s} - \frac{2a_\ell^2 a_s}{(a_\ell^2 - a_s^2)^{3 / 2}} \biggl\{\frac{\pi}{2} - \tan^{-1}\bigg[ \frac{a_s }{ (a_\ell^2 - a_s^2)^{1 / 2}} \biggr] \biggr\} </math> |
|
<math>~=</math> |
<math> \frac{2}{e^2} - \frac{2(1-e^2)^{1 / 2}}{e^3} \biggl\{\frac{\pi}{2} - \tan^{-1}\bigg[ \frac{ (1-e^2)^{1 / 2}}{ e} \biggr] \biggr\} </math> |
|
<math>~=</math> |
<math> \frac{2}{e^2} - \frac{2(1-e^2)^{1 / 2}}{e^3} \biggl\{\sin^{-1}e \biggr\} \, . </math> |
Because we are evaluating the case where <math>~A_m = A_\ell</math>, we alternatively should have been able to obtain the expression for <math>~A_s</math> immediately from our derived expression for <math>~A_\ell</math> via the known relation,
<math>~2</math> |
<math>~=</math> |
<math>~A_\ell + A_m + A_s = 2A_\ell + A_s \, .</math> |
This approach gives,
<math>~A_s</math> |
<math>~=</math> |
<math>~2 - 2A_\ell </math> |
|
<math>~=</math> |
<math>~2 + 2\biggl\{ \frac{(1-e^2)}{e^2} - ~\frac{(1-e^2)^{1 / 2}}{ e^3 } \biggl[ \sin^{-1}e \biggr] \biggr\} </math> |
|
<math>~=</math> |
<math>~ \frac{2}{e^2} - ~\frac{2(1-e^2)^{1 / 2}}{ e^3 } \biggl[ \sin^{-1}e \biggr] \, , </math> |
which, indeed, matches our separately derived expression for <math>~A_s</math>.
When am = as
When the length of the intermediate axis is the same as the length of the shortest axis — that is, when we are dealing with a prolate spheroid — the coefficient associated with the longest axis is,
<math>~\frac{A_\ell}{a_\ell a_s^2}</math> |
<math>~=</math> |
<math> ~\int_0^\infty \frac{du}{ (a_s^2 + u)(a_\ell^2 + u)^{3 / 2} } \, . </math> |
Changing the integration variable to <math>~x \equiv (a_s^2 + u)</math>, we obtain an integral expression that appears as equation (2.229.1) in GR7th, namely,
<math>~\frac{A_\ell}{a_\ell a_s^2}</math> |
<math>~=</math> |
<math> ~\int_{a_s^2}^\infty \frac{dx}{ x^2(a_\ell^2 - a_s^2 + x)^{1 / 2} } </math> |
<math>~</math> |
<math>~=</math> |
<math>~ \biggl[ \frac{2}{(a_\ell^2 - a_s^2) (a_\ell^2 - a_s^2 + x)^{1 / 2}} \biggr]_{a_s^2}^\infty + \frac{1}{(a_\ell^2 - a_s^2)} \int_{a_s^2}^\infty \frac{dx}{ x (a_\ell^2 - a_s^2 + x)^{1 / 2} } \, . </math> |
The remaining integral in this expression appears as equation (2.224.5) in GR7th. Its resolution depends on the sign of the constant term in the denominator, <math>~(a_\ell^2 - a_s^2)</math>. Given that this term is positive, the integration gives,
<math>~\frac{A_\ell}{a_\ell a_s^2}</math> |
<math>~=</math> |
<math>~ - \frac{2}{(a_\ell^2 - a_s^2) a_\ell} + \frac{1}{(a_\ell^2 - a_s^2)} \biggl\{ \frac{1}{\sqrt{(a_\ell^2 - a_s^2)}} \ln \biggl[ \frac{ (a_\ell^2 - a_s^2 + x)^{1 / 2} - \sqrt{(a_\ell^2 - a_s^2)} }{(a_\ell^2 - a_s^2 + x)^{1 / 2} + \sqrt{(a_\ell^2 - a_s^2)} } \biggr] \biggr\}_{a_s^2}^\infty </math> |
<math>~\Rightarrow ~~~ A_\ell</math> |
<math>~=</math> |
<math>~ - \frac{2a_\ell a_s^2}{(a_\ell^2 - a_s^2) a_\ell} - \frac{a_\ell a_s^2}{(a_\ell^2 - a_s^2)^{3 / 2}} \biggl\{ \ln \biggl[ \frac{ 1-e }{1+e} \biggr] \biggr\} </math> |
|
<math>~=</math> |
<math>~ \frac{ (1-e^2)}{e^3} \biggl\{ \ln \biggl[ \frac{1+e}{ 1-e } \biggr] \biggr\} - \frac{2(1-e^2)}{e^2 } \, , </math> |
where, as above, <math>~e \equiv (1 - a_s^2/a_\ell^2)^{1 / 2}</math>. Now, given that <math>~A_m = A_s</math>, in this case we appreciate that,
<math>~2</math> |
<math>~=</math> |
<math>~A_\ell + A_m + A_s = A_\ell + 2A_s</math> |
<math>~\Rightarrow ~~~ A_s</math> |
<math>~=</math> |
<math>~1 - \frac{A_\ell}{2} </math> |
|
<math>~=</math> |
<math>~1 - \frac{1}{2}\biggl[ \frac{ (1-e^2)}{e^3} \cdot \ln \biggl( \frac{1+e}{ 1-e } \biggr) - \frac{2(1-e^2)}{e^2 } \biggr] </math> |
|
<math>~=</math> |
<math>~ \frac{1}{e^2 } - \frac{ (1-e^2)}{2e^3} \cdot \ln \biggl( \frac{1+e}{ 1-e } \biggr) \, . </math> |
Material that appears after this point in our presentation is under development and therefore
may contain incorrect mathematical equations and/or physical misinterpretations.
| Go Home |
Work In Progress
Derivation of Expression for Gravitational Potential
In §373 (p. 700) of his book titled, Hydrodynamics, Lamb32 states that, "The gravitation-potential, at internal points, of a uniform mass enclosed by the surface
<math>~ \frac{x^2}{a^2} + \frac{y^2}{b^2} + \frac{z^2}{c^2} </math> |
<math>~=</math> |
<math>~1</math> |
[ Lamb32, §373, Eq. (1) ] |
… may be written
<math>~\frac{\Phi(\vec{x})}{G}</math> |
<math>~=</math> |
<math>~ \pi \rho (\alpha_0 x^2 + \beta_0 y^2 + \gamma_0 z^2 - \chi_0) \, , </math> |
[ Lamb32, §373, Eq. (4) ] |
where, as in §114,"
<math>~\frac{\alpha_0}{abc} </math> |
<math>~=</math> |
<math>~\int_0^\infty \frac{d\lambda}{(a^2 + \lambda)\Delta} \, ,</math> |
<math>~\frac{\beta_0}{abc} </math> |
<math>~=</math> |
<math>~\int_0^\infty \frac{d\lambda}{(b^2 + \lambda)\Delta} \, ,</math> |
|
<math>~\frac{\gamma_0}{abc} </math> |
<math>~=</math> |
<math>~\int_0^\infty \frac{d\lambda}{(c^2 + \lambda)\Delta} \, ,</math> |
<math>~\frac{\chi_0}{abc} </math> |
<math>~=</math> |
<math>~\int_0^\infty \frac{d\lambda}{\Delta} \, ,</math> |
|
[ Lamb32, §373, Eqs. (5) & (6) ] |
and,
<math>~\Delta</math> |
<math>~=</math> |
<math>~[(a^2 + \lambda)(b^2 + \lambda)(c^2 + \lambda)]^{1 / 2} \, .</math> |
[ Lamb32, §373, Eq. (3) ] |
Although different variable names have been used, it is easy to see the correspondence between these expressions and the defining integral expressions that we have drawn from the more recent publications of EFE and BT87 and presented above. Here, we are interested in demonstrating how Lamb32 derived his expression for the potential inside (and on the surface of) an homogeneous ellipsoid.
Acceleration at the Pole
Prolate Spheroids
In our above review, for consistency, we assumed that the longest axis of the ellipsoid was aligned with the <math>~x</math>-axis in all cases — for prolate spheroids as well as for oblate spheroids and for the more generic, triaxial ellipsoids. In this discussion, in order to better align with the operational features of a standard cylindrical coordinate system, we will orient the prolate-spheroidal configuration such that its major axis and, hence, its axis of symmetry aligns with the <math>~z</math>-axis while the center of the spheroid remains at the center of the (cylindrical) coordinate grid. In this case, the surface will be defined by the ellipse,
<math>~\frac{\varpi^2}{a_3^2} + \frac{z^2}{a_1^2} = 1 ~~~~\Rightarrow ~~~~ \varpi = a_3\sqrt{1-z^2/a_1^2} \, ,</math>
and the gravitational potential will be given by the expression,
<math> ~\Phi(\vec{x}) = -\pi G \rho \biggl[ I_\mathrm{BT} a_1^2 - \biggl(A_1 z^2 + A_3 \varpi^2 \biggr) \biggr]. </math>
The magnitude of the gravitational acceleration at the pole <math>~(\varpi, z) = (0, a_1)</math> of this prolate spheroid can be obtained from the gravitational potential via the expression,
<math>~\mathcal{A} \equiv \biggl|- \frac{\partial \Phi}{\partial z}\biggr|_{a_1}</math> |
<math>~=</math> |
<math>~2\pi G \rho A_1 a_1 \, ,</math> |
where, as above,
<math> ~A_1 </math> |
<math> ~= </math> |
<math> \ln\biggl[ \frac{1+e}{1-e} \biggr] \frac{(1-e^2)}{e^3} - \frac{2(1-e^2)}{e^2} \, . </math> |
We should also be able to derive this expression for <math>~\mathcal{A}</math> by integrating the <math>~z</math>-component of the differential acceleration over the mass distribution, that is,
<math>~\mathcal{A}</math> |
<math>~=</math> |
<math>~\int \biggl[ \frac{G }{r^2} \cdot \frac{(a_1-z)}{r} \biggr] dm = \int \biggl[ \frac{(a_1-z)G }{r^3} \biggr] 2\pi \varpi d\varpi dz</math> |
|
<math>~=</math> |
<math>~2\pi G\rho \int^{a_1}_{-a_1} (a_1-z)dz \int_0^{a_3\sqrt{1-z^2/a_1^2}} [\varpi^2+(z-a_1)^2]^{-3/2}\varpi d\varpi \, ,</math> |
where the distance, <math>~r</math>, has been measured from the pole, that is,
<math>~r^2 = \varpi^2 + (z-a_1)^2 \, .</math>
Performing the integral over <math>~\varpi</math> gives,
<math>~\mathcal{A}</math> |
<math>~=</math> |
<math>~2\pi G\rho \int^{a_1}_{-a_1} (a_1-z)dz \biggl\{ -[\varpi^2+(z-a_1)^2]^{-1/2} \biggr\}_0^{a_3\sqrt{1-z^2/a_1^2}} </math> |
|
<math>~=</math> |
<math>~2\pi G\rho \int^{a_1}_{-a_1} (a_1-z)dz \biggl\{ \frac{1}{z - a_1} -\biggl[ a_3^2 \biggl(1-\frac{z^2}{a_1^2} \biggr) + a_1^2\biggl(1-\frac{z}{a_1}\biggr)^2 \biggr]^{-1/2} \biggr\} </math> |
|
<math>~=</math> |
<math>~ - 2\pi G\rho a_1 \int^{1}_{-1} d\zeta \biggl\{ \frac{1-\zeta}{1-\zeta } - (1-\zeta)\biggl[ \biggl(\frac{a_3}{a_1}\biggr)^2 \biggl(1-\zeta^2 \biggr) + \biggl(1-\zeta\biggr)^2 \biggr]^{-1/2} \biggr\} </math> |
|
<math>~=</math> |
<math>~ 2\pi G\rho a_1 \int^{1}_{-1} d\zeta \biggl\{ (1-\zeta) [ (2-e^2) - 2\zeta + e^2\zeta^2 ]^{-1/2} -1 \biggr\} \, , </math> |
where, <math>~\zeta\equiv z/a_1</math>. For later reference, we will identify the expression inside the curly braces as the function, <math>~\mathcal{Z}</math>; specifically,
<math>~\mathcal{Z}</math> |
<math>~\equiv</math> |
<math>~(1-\zeta) [ (2-e^2) - 2\zeta + e^2\zeta^2 ]^{-1/2} -1</math> |
|
<math>~=</math> |
<math>~- 1 - \frac{\zeta}{\sqrt{X}} + \frac{1}{\sqrt{X}} \, ,</math> |
where, in an effort to line up with notation found in integral tables, in this last expression we have used the notation, <math>~X \equiv a + b\zeta + c\zeta^2</math> and, in our case,
<math>a \equiv (2-e^2)\, ,</math> <math>b \equiv -2\, ,</math> and <math>c \equiv e^2\, .</math>
We find that,
<math>~\int_{-1}^1 \mathcal{Z} d\zeta</math> |
<math>~=</math> |
<math>~- \zeta\biggr|_{-1}^{1} - \biggl\{ \frac{\sqrt{X}}{c} \biggr\}_{-1}^1 +\biggl[1 + \frac{b}{2c} \biggr]\int_{-1}^1 \frac{d\zeta}{\sqrt{X}} </math> |
|
<math>~=</math> |
<math>~- 2 - \biggl\{ \frac{\sqrt{(2-e^2) -2\zeta + e^2\zeta^2}}{e^2} \biggr\}_{-1}^1 +\biggl[1 - \frac{1}{e^2} \biggr] \biggl\{ \frac{1}{\sqrt{c}} \ln \biggl[2\sqrt{cX} + 2c\zeta + b \biggr] \biggr\}_{-1}^1 </math> |
|
<math>~=</math> |
<math>~- 2 - \biggl\{ \frac{\sqrt{(2-e^2) -2 + e^2}}{e^2} \biggr\} + \biggl\{ \frac{\sqrt{(2-e^2) +2 + e^2}}{e^2} \biggr\} + \biggl[1 - \frac{1}{e^2} \biggr] \biggl\{ \frac{1}{e} \ln \biggl[2\sqrt{e^2[(2-e^2) -2\zeta + e^2\zeta^2]} + 2e^2\zeta - 2 \biggr] \biggr\}_{-1}^1 </math> |
|
<math>~=</math> |
<math>~- 2 + \frac{2}{e^2} +\biggl[\frac{e^2-1}{e^3} \biggr] \biggl\{ \ln \biggl[2e^2 - 2 \biggr] - \ln \biggl[4e - 2e^2 - 2 \biggr] \biggr\} </math> |
|
<math>~=</math> |
<math>~- 2\biggl[\frac{e^2 - 1}{e^2}\biggr] +\biggl[\frac{e^2-1}{e^3} \biggr] \biggl\{ \ln \biggl[-2(1-e^2) \biggr] - \ln \biggl[-2(1-e)^2\biggr] \biggr\} </math> |
|
<math>~=</math> |
<math>~\biggl[\frac{1-e^2}{e^3} \biggr] \ln \biggl[\frac{1+e}{1-e} \biggr] -2\biggl[\frac{1-e^2 }{e^2}\biggr] </math> |
|
<math>~=</math> |
<math>~A_1 \, . </math> |
Hence, we have,
<math>~\mathcal{A} = 2\pi G\rho a_1 \biggl[ \int_{-1}^1 \mathcal{Z} d\zeta\biggr]= 2\pi G \rho A_1 a_1 \, ,</math>
which exactly matches the result obtained, above, by taking the derivative of the potential.
See Also
- Properties of Maclaurin Spheroids
- Excerpts from Maclaurin's (1742) A Treatise of Fluxions
- Inhomogeneous Ellipsoids Leading to Ferrers Potentials
Footnotes
- In EFE this equation is written in terms of a variable <math>~I</math> instead of <math>~I_\mathrm{BT}</math> as defined here. The two variables are related to one another straightforwardly through the expression, <math>~I = I_\mathrm{BT} a_1^2</math>.
- Throughout EFE, Chandrasekhar adopts a sign convention for the scalar gravitational potential that is opposite to the sign convention being used here.
© 2014 - 2021 by Joel E. Tohline |