Zolotarev's lemma: Difference between revisions

Revision as of 20:32, 14 March 2013

In mathematics, the Weierstrass–Enneper parameterization of minimal surfaces is a classical piece of differential geometry.

Alfred Enneper and Karl Weierstrass studied minimal surfaces as far back as 1863.

Let ƒ and g be functions on either the entire complex plane or the unit disk, where g is meromorphic and ƒ is analytic, such that wherever g has a pole of order m, f has a zero of order 2m (or equivalently, such that the product ƒg² is holomorphic), and let c₁, c₂, c₃ be constants. Then the surface with coordinates (x₁,x₂,x₃) is minimal, where the x_k are defined using the real part of a complex integral, as follows:

\begin{aligned} x_{k} (ζ) & = ℜ {\int_{0}^{ζ} φ_{k} (z) d z} + c_{k}, k = 1, 2, 3 \\ φ_{1} & = f (1 - g^{2}) / 2 \\ φ_{2} & = i f (1 + g^{2}) / 2 \\ φ_{3} & = f g \end{aligned}

The converse is also true: every nonplanar minimal surface defined over a simply connected domain can be given a parametrization of this type.^[1]

For example, Enneper's surface has ƒ(z) = 1, g(z) = z.

References

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Template:Differential-geometry-stub

↑ Dierkes, U., Hildebrandt, S., Küster, A., Wohlrab, O. Minimal surfaces, vol. I, p. 108. Springer 1992. ISBN 3-540-53169-6

[DHWK-1] Dierkes, U., Hildebrandt, S., Küster, A., Wohlrab, O. Minimal surfaces, vol. I, p. 108. Springer 1992. ISBN 3-540-53169-6

[1]

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+In [[mathematics]], the '''Weierstrass–Enneper parameterization''' of [[minimal surface]]s is a classical piece of [[differential geometry]].
+[[Alfred Enneper]] and [[Karl Weierstrass]] studied minimal surfaces as far back as 1863.
+Let &fnof; and ''g'' be functions on either the entire complex plane or the unit disk, where ''g'' is [[meromorphic function|meromorphic]] and &fnof; is [[analytic function|analytic]], such that wherever ''g'' has a pole of order ''m'', ''f'' has a zero of order 2''m'' (or equivalently, such that the product &fnof;''g''<sup>2</sup> is holomorphic), and let ''c''<sub>1</sub>, ''c''<sub>2</sub>, ''c''<sub>3</sub> be constants.  Then the surface with coordinates (''x''<sub>1</sub>,''x''<sub>2</sub>,''x''<sub>3</sub>) is minimal, where the ''x''<sub>''k''</sub> are defined using the real part of a complex integral, as follows:
+:<math>\begin{align}
+ x_k(\zeta) &{}= \Re \left\{ \int_{0}^{\zeta} \varphi_{k}(z) \, dz \right\} + c_k , \qquad k=1,2,3 \\
+ \varphi_1 &{}= f(1-g^2)/2 \\
+ \varphi_2 &{}= \bold{i} f(1+g^2)/2 \\
+ \varphi_3 &{}= fg
+\end{align}</math>
+The converse is also true: every nonplanar minimal surface defined over a simply connected domain can be given a parametrization of this type.<ref name="DHWK">Dierkes, U., Hildebrandt, S., Küster, A., Wohlrab, O. ''Minimal surfaces'', vol. I, p. 108. Springer 1992. ISBN 3-540-53169-6</ref>
+For example, [[Enneper's surface]] has &fnof;(''z'') = 1, ''g''(''z'') = ''z''.
+==See also==
+* [[Associate family]]
+* [[Bryant surface]], found by an analogous parameterization in [[hyperbolic space]]
+==References==
+{{reflist}}
+{{DEFAULTSORT:Weierstrass-Enneper parameterization}}
+[[Category:Differential geometry]]
+[[Category:Surfaces]]
+[[Category:Minimal surfaces]]
+{{differential-geometry-stub}}

Zolotarev's lemma: Difference between revisions

Revision as of 20:32, 14 March 2013

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