|
|
Line 1: |
Line 1: |
| In [[complex analysis]], a '''Schwarz–Christoffel mapping''' is a [[conformal transformation]] of the [[upper half-plane]] onto the interior of a simple [[polygon]]. Schwarz–Christoffel mappings are used in [[potential theory]] and some of its applications, including [[minimal surface]]s and [[fluid dynamics]]. They are named after [[Elwin Bruno Christoffel]] and [[Hermann Amandus Schwarz]].
| | Hi there, I am Leo Oakes. I am currently a medical worker having said that i plan on changing this kind of. Her friends say it's not good for her but what she loves doing is magic and she'd never stop. Oklahoma is his birth setting. His wife and he maintain web site. You might wish to check it out: https://vimeo.com/91906345<br><br>Here is my webpage ... April Flowers Porn ([https://vimeo.com/91906345 https://vimeo.com/91906345]) |
| | |
| ==Definition==
| |
| Consider a polygon in the complex plane. The [[Riemann mapping theorem]] implies that there is a [[bijective]] [[biholomorphic]] mapping ''f'' from the upper half-plane
| |
| :<math> \{ \zeta \in \mathbb{C}: \operatorname{Im}\,\zeta > 0 \} </math>
| |
| to the interior of the polygon. The function ''f'' maps the real axis to the edges of the polygon. If the polygon has interior [[angle]]s <math>\alpha,\beta,\gamma, \ldots</math>, then this mapping is given by
| |
| :<math>
| |
| f(\zeta) = \int^\zeta \frac{K}{(w-a)^{1-(\alpha/\pi)}(w-b)^{1-(\beta/\pi)}(w-c)^{1-(\gamma/\pi)} \cdots} \,\mbox{d}w
| |
| </math>
| |
| where <math>K</math> is a [[Constant (mathematics)|constant]], and <math>a < b < c < ...</math> are the values, along the real axis of the <math>\zeta</math> plane, of points corresponding to the vertices of the polygon in the <math>z</math> plane. A transformation of this form is called a ''Schwarz–Christoffel mapping''.
| |
| | |
| It is often convenient to consider the case in which the [[point at infinity]] of the <math>\zeta</math> plane maps to one of the vertices of the <math>z</math> plane polygon (conventionally the vertex with angle <math>\alpha</math>). If this is done, the first factor in the formula is effectively a constant and may be regarded as being absorbed into the constant <math>K</math>.
| |
| | |
| ==Example==
| |
| | |
| Consider a semi-infinite strip in the {{math|<VAR >z</VAR >}} [[complex plane|plane]]. This may be regarded as a limiting form of a [[triangle]] with vertices {{math|<VAR >P</VAR > {{=}} 0}}, {{math|<VAR >Q</VAR > {{=}} π ''i''}}, and {{math|<VAR >R</VAR >}} (with {{math|<VAR >R</VAR >}} real), as {{math|<VAR >R</VAR >}} tends to infinity. Now {{math|α {{=}} 0}} and {{math|β {{=}} γ {{=}} {{frac|π|2}}}} in the limit. Suppose we are looking for the mapping {{math|<VAR >f</VAR >}} with {{math|<VAR >f</VAR >(−1) {{=}} <VAR >Q</VAR >}}, {{math|<VAR >f</VAR >(1) {{=}} <VAR >P</VAR >}}, and {{math|<VAR >f</VAR >(∞) {{=}} <VAR >R</VAR >}}. Then {{math|<VAR >f</VAR >}} is given by
| |
| | |
| :<math> f(\zeta) = \int^\zeta | |
| \frac{K}{(w-1)^{1/2}(w+1)^{1/2}} \,\mbox{d}w. \, </math>
| |
| | |
| Evaluation of this integral yields
| |
| | |
| <!-- :<math> z = f(\zeta) = C + K \operatorname{arccosh}\,\zeta, </math>-->
| |
| :{{math|''z'' {{=}} ''f''(''ζ'') {{=}} ''C'' + ''K'' arccosh ''ζ''}}
| |
| | |
| where {{math|<VAR >C</VAR >}} is a (complex) constant of integration. Requiring that {{math|<VAR >f</VAR >(−1) {{=}} <VAR >Q</VAR >}} and {{math|<VAR >f</VAR >(1) {{=}} <VAR >P</VAR >}} gives {{math|<VAR >C</VAR > {{=}} 0}} and {{math|<VAR >K</VAR > {{=}} 1}}. Hence the Schwarz–Christoffel mapping is given by
| |
| <!--:<math> z = \operatorname{arccosh}\,\zeta. </math>-->
| |
| :{{math|''z'' {{=}} arccosh ''ζ''}}
| |
| This transformation is sketched below.
| |
| | |
| [[Image:Schwarz-Christoffel transformation.png|frame|center|Schwarz–Christoffel mapping of the upper half-plane to the semi-infinite strip]]
| |
| | |
| ==Other simple mappings==
| |
| | |
| ===Triangle===
| |
| A mapping to a plane [[triangle]] with angles <math>\pi a,\, \pi b</math> and <math>\pi(1-a-b)</math> is given by
| |
| | |
| :<math>z=f(\zeta)=\int^\zeta \frac{dw}{(w-1)^{1-a} (w+1)^{1-b}}.</math>
| |
| | |
| ===Square===
| |
| The upper half-plane is mapped to the square by
| |
| :<math>z=f(\zeta) = \int^\zeta \frac {\mbox{d}w}{\sqrt{w(w^2-1)}}
| |
| =\sqrt{2} \, F\left(\sqrt{\zeta+1};\sqrt{2}/2\right),
| |
| </math>
| |
| where F is the incomplete [[elliptic integral]] of the first kind.
| |
| | |
| ===General triangle===
| |
| The upper half-plane is mapped to a triangle with circular arcs for edges by the [[Schwarz triangle map]].
| |
| | |
| ==See also==
| |
| * The [[Schwarzian derivative]] appears in the theory of Schwarz–Christoffel mappings.
| |
| | |
| ==References==
| |
| | |
| *{{Citation | last1=Driscoll | first1=Tobin A. | last2=Trefethen | first2=Lloyd N. | author2-link=Lloyd N. Trefethen | title=Schwarz-Christoffel mapping | url=http://www.cambridge.org/us/catalogue/catalogue.asp?isbn=9780521807265 | publisher=Cambridge University Press | series=Cambridge Monographs on Applied and Computational Mathematics | isbn=978-0-521-80726-5 | id={{MathSciNet | id = 1908657}} | year=2002 | volume=8}}
| |
| *{{Citation | last1=Nehari | first1=Zeev | title=Conformal mapping | origyear=1952 | publisher=[[Dover Publications]] | location=New York | isbn=978-0-486-61137-2 | id={{MathSciNet | id = 0045823}} | year=1982}}
| |
| | |
| ==Further reading==
| |
| * {{Citation | last1=Case | first1=James | title=Breakthrough in Conformal Mapping | url=http://siam.org/pdf/news/1297.pdf | year=2008 | journal=SIAM News | volume=41 | issue=1}}.
| |
| | |
| ==External links==
| |
| * {{planetmath reference|id=6289|title=Schwarz-Christoffel transformation}}
| |
| * [http://math.fullerton.edu/mathews/c2003/SchwarzChristoffelMod.html Schwarz–Christoffel Module by John H. Mathews]
| |
| * [http://www.math.udel.edu/~driscoll/SC Schwarz–Christoffel toolbox] (software for [[MATLAB]])
| |
| | |
| {{DEFAULTSORT:Schwarz-Christoffel mapping}}
| |
| [[Category:Conformal mapping]]
| |
Hi there, I am Leo Oakes. I am currently a medical worker having said that i plan on changing this kind of. Her friends say it's not good for her but what she loves doing is magic and she'd never stop. Oklahoma is his birth setting. His wife and he maintain web site. You might wish to check it out: https://vimeo.com/91906345
Here is my webpage ... April Flowers Porn (https://vimeo.com/91906345)