Appendix/Ramblings/T6CoordinatesPt2: Difference between revisions
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<font color="red">'''Q. E. D.'''</font> | <font color="red">'''Q. E. D.'''</font> | ||
<!-- TEST --> | |||
====Search for <i>Third</i> Coordinate Expression==== | |||
Let's try … | |||
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<math>~\lambda_3</math> | |||
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<math>~=</math> | |||
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<math>~\mathcal{D}^n \ell_{3D}^m </math> | |||
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<math>~=</math> | |||
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<math>~ | |||
(q^4 y^2 p^4 z^2 + x^2 p^4 z^2 + 4x^2q^4y^2)^{n / 2} (x^2 + q^4y^2 + p^4 z^2 )^{- m / 2} | |||
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<math>~\Rightarrow ~~~ \frac{\partial \lambda_3}{\partial x_i}</math> | |||
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<math>~=</math> | |||
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<math>~ | |||
\ell_{3D}^m \biggl[ \frac{n}{2} \biggl(q^4 y^2 p^4 z^2 + x^2 p^4 z^2 + 4x^2q^4y^2 \biggr)^{n / 2 - 1} \biggr] \frac{\partial}{\partial x_i} \biggl[(q^4 y^2 p^4 z^2 + x^2 p^4 z^2 + 4x^2q^4y^2)\biggr] | |||
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<math>~ | |||
+ \mathcal{D}^n \biggl[ - \frac{m}{2} (x^2 + q^4y^2 + p^4 z^2 )^{- m / 2 - 1} \biggr] \frac{\partial}{\partial x_i} \biggl[(x^2 + q^4y^2 + p^4 z^2 )\biggr] | |||
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<math>~=</math> | |||
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<math>~ | |||
\mathcal{D}^n \ell_{3D}^m \biggl[ \frac{n}{2} \biggl(q^4 y^2 p^4 z^2 + x^2 p^4 z^2 + 4x^2q^4y^2 \biggr)^{- 1} \biggr] \frac{\partial}{\partial x_i} \biggl[(q^4 y^2 p^4 z^2 + x^2 p^4 z^2 + 4x^2q^4y^2)\biggr] | |||
</math> | |||
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+ \mathcal{D}^n \ell_{3D}^m \biggl[ - \frac{m}{2} (x^2 + q^4y^2 + p^4 z^2 )^{- 1} \biggr] \frac{\partial}{\partial x_i} \biggl[(x^2 + q^4y^2 + p^4 z^2 )\biggr] \, . | |||
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{{ SGFfooter }} | {{ SGFfooter }} | ||
Revision as of 17:44, 23 July 2021
Concentric Ellipsoidal (T6) Coordinates (Part 2)
Orthogonal Coordinates
Speculation5
Spherical Coordinates
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Use λ1 Instead of r
Here, as above, we define,
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Using this expression to eliminate "x" (in favor of λ1) in each of the three spherical-coordinate definitions, we obtain,
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After a bit of additional algebraic manipulation, we find that,
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where,
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As a check, let's set , which should reduce to the normal spherical coordinate system.
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Relationship To T3 Coordinates
If we set, , but continue to assume that , we expect to see a representation that resembles our previously discussed, T3 Coordinates. Note, for example, that the new "radial" coordinate is,
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and, |
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We also see that,
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Again Consider Full 3D Ellipsoid
Let's try to replace everywhere, with . This gives,
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which means that,
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Now, notice that,
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and,
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Hence,
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where,
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Solving the quadratic equation, we have,
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Tentative Summary
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Partial Derivatives & Scale Factors
First Coordinate
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where,
As a result, the associated unit vector is,
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Notice that,
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Second Coordinate (1st Try)
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As a result, the associated unit vector is,
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Notice that,
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Let's check to see if this "second" unit vector is orthogonal to the "first."
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Second Coordinate (2nd Try)
Let's try,
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Hence,
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So, the associated unit vector is,
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Checking orthogonality …
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If , we have …
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which, in turn, means …
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and,
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Speculation6
Determine λ2
This is very similar to the above, Speculation2. Try,
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in which case,
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The associated scale factor is, then,
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where,
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The associated unit vector is, then,
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Recalling that the unit vector associated with the "first" coordinate is,
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where,
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let's check to see whether the "second" unit vector is orthogonal to the "first."
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Hooray!
Direction Cosines for Third Unit Vector
Now, what is the unit vector, , that is simultaneously orthogonal to both these "first" and the "second" unit vectors?
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Is this a valid unit vector? First, note that …
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Then we have,
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which means that, . Hooray! Again (11/11/2020)!
| Direction Cosine Components for T6 Coordinates | ||||||||||||||
| --- | --- | --- | --- | --- | ||||||||||
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Let's double-check whether this "third" unit vector is orthogonal to both the "first" and the "second" unit vectors.
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and,
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Q. E. D.
Search for Third Coordinate Expression
Let's try …
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Appendices: | VisTrailsEquations | VisTrailsVariables | References | Ramblings | VisTrailsImages | myphys.lsu | ADS | |