Ellipsoid in three-dimensional Euclidean space: Difference between revisions

Revision as of 01:54, 6 August 2011

Definition

This surface type is not unique up to isometry or even up to similarity transformations, but rather, depends upon multiple nonzero parameters $a,b,c$ . If we're considering the surface up to rigid isometries, the parameters are unique up to permutations. If we're considering the surface up to similarity transformations, the parameters are unique up to the action of permutations and projective equivalence.

Implicit and parametric descriptions

Degree of generality	Implicit description	What the parameters mean	Parametric description	What the additional parameters mean	Comment
Arbitrary	Fill this in later				This version need not be centered at the origin and need not be oriented parallel to the axes.
Up to rotations	${\frac {(x-x_{0})^{2}}{a^{2}}}+{\frac {(y-y_{0})^{2}}{b^{2}}}+{\frac {(z-z_{0})^{2}}{c^{2}}}=1$		$x=x_{0}+a\cos u\sin v,y=y_{0}+b\sin u\sin v,z=z_{0}+c\cos v$		This version need not be centered along the origin but is oriented parallel to the axes.
Up to rigid motions (rotations, translations, reflections)	${\frac {x^{2}}{a^{2}}}+{\frac {y^{2}}{b^{2}}}+{\frac {z^{2}}{c^{2}}}=1$	$a$ , $b$ , $c$ are positive numbers that represent the lengths of the three ellipsoidal semi-axes. Note that because we allow rigid motions, we can permute and rearrange to force $a\geq b\geq c$ .	$x=a\cos u\sin v,y=b\sin u\sin v,z=c\cos v$	Here, $u$ and $v$ are ellipsoidal equivalents of the angles $\theta ,\phi$ used in spherical polar coordinates.	This version is centered at the origin and oriented parallel to the axes.
Up to similarity transformations	$x^{2}+{\frac {y^{2}}{q^{2}}}+{\frac {z^{2}}{r^{2}}}=1$	Here, $q=b/a,r=c/a$ . If we chose $a\geq b\geq c$ , we would get $0<q,r\leq 1$ .			For this version, we can normalize one of the three values $a,b,c$ . In the form given here, we chose to normalize $a$ .

Fundamental forms and curvatures

For the table below, we consider the parametric description that is valid for

${\frac {x^{2}}{a^{2}}}+{\frac {y^{2}}{b^{2}}}+{\frac {z^{2}}{c^{2}}}=1$

namely the description:

$x=a\cos u\sin v,b=y\sin u\sin v,c=z\cos v$

Quantity	Meaning in general	Value
$E,F,G$ for first fundamental form using this parametrization	The Riemannian metric is given by $ds^{2}=E\,du^{2}+2F\,du\,dv+G\,dv^{2}$	Fill this in later
$e,f,g$ for second fundamental form using this parametrization	Fill this in later	Fill this in later
principal curvatures using this parametrization	eigenvalues of the shape operator, which is the matrix ${\begin{pmatrix}E&F\\F&G\\\end{pmatrix}}$	Fill this in later
mean curvature	arithmetic mean of the principal curvatures = half the trace of the shape operator = $(E+G)/2$	Fill this in later
Gaussian curvature	product of the principal curvatures = determinant of shape operator = $EG-F^{2}$	Fill this in later

Verification of theorems

Gauss-Bonnet theorem

Fill this in later

@@ Line 36: / Line 36: @@
 | [[principal curvature]]s using this parametrization || eigenvalues of the shape operator, which is the matrix <math>\begin{pmatrix} E & F \\ F & G \\\end{pmatrix}</math> || {{fillin}}
 |-
-| [[mean curvature]] || arithmetic mean of the principal curvatures || {{fillin}}
+| [[mean curvature]] || arithmetic mean of the principal curvatures = half the trace of the shape operator = <math>(E + G)/2</math> || {{fillin}}
 |-
 | [[Gaussian curvature]] || product of the principal curvatures = determinant of shape operator = <math>EG - F^2</math> || {{fillin}}