Derive Schwarz-Christoffel's formula.
Answers
Answer:
constituting an integral representation for a function f(z) which defines a conformal mapping of the upper half-plane Imz>0 onto the interior of a bounded polygon with vertices Ak and vertex angles παk( 0<αk≤2, k=1…n). Moreover, z0,c,c1 are certain constants, and Ak=f(ak).
Step-by-step explanation:
Step-by-step explanation:
The formula
f(z)=c1+c∫z0z ∏k=1n(t−ak)αk−1dt,(*)
constituting an integral representation for a function f(z) which defines a conformal mapping of the upper half-plane Imz>0 onto the interior of a bounded polygon with vertices Ak and vertex angles παk( 0<αk≤2, k=1…n). Moreover, z0,c,c1 are certain constants, and Ak=f(ak). The constant z0 can be fixed arbitrarily in the upper half-plane. A triple of points in the sequence a1…an, say a1,a2,a3, can be prescribed arbitrarily; the remaining n−3 points ak and the constants c,c1 are uniquely determined if the vertices A1…An of the polygon are prescribed (see [3]). Formula (*) was established independently by E.B. Christoffel (1867, see ) and H.A. Schwarz (1869, see [2]). The integral on the right-hand side of (*) is known as a Christoffel–Schwarz integral.
The basic difficulty in using formula (*) is to find the unknown parameters. No general methods are known for n>4.
Methods have been worked out for approximating the parameters of the Christoffel–Schwarz formula (see [4], [5]).
The Christoffel–Schwarz formula remains valid for polygons with one or more vertices at infinity. In that case the angle between the sides at infinity is, by definition, the angle (with minus sign) between the relevant sides (or their continuations) at a finite point. If the pre-image ai of one of the vertices is the point at infinity, the corresponding factor (t−ai)αi−1 is dropped in formula (*).
The Christoffel–Schwarz formula is also valid for a function that maps the unit disc |z|<1 onto the above polygon. In that case |ak|=1, k=1…n, |z0|≤1. Modifications of the formula are valid for functions mapping the upper half-plane — or the interior and exterior of the unit disc — onto the exterior of a polygon (see [3]).
The Christoffel–Schwarz formula may be generalized to the case in which f(z) defines a conformal mapping of a circular annulus 0<q<|z|<1, or, in general, a multiply-connected domain defined by deleting n discs from the interior of a disc, onto a domain (multiply-connected of the same degree) bounded by polygons (see [6], [7]).
References
[1a] E.B. Christoffel, Ann. di Math. Pura Appl. (2) , 1 (1868) pp. 89–103
[1b] E.B. Christoffel, Ann. di Math. Pura Appl. (2) , 4 (1871) pp. 1–9
[2] H.A. Schwarz, "Gesamm. math. Abhandl." , 1–2 , Springer (1890)
[3] M.A. Lavrent'ev, B.V. Shabat, "Methoden der komplexen Funktionentheorie" , Deutsch. Verlag Wissenschaft. (1967) (Translated from Russian)
[4] L.V. Kantorovich, V.I. Krylov, "Approximate methods of higher analysis" , Noordhoff (1958) (Translated from Russian)
[5] W. Koppenfels, F. Stalman, "Praxis der konformen Abbildung" , Springer (1959)
[6] N.I. Akhiezer, "Elements of the theory of elliptic functions" , Amer. Math. Soc. (1990) (Translated from Russian)
[7] Yu.D. Maksimov, "Extension of the structural formula for convex univalent functions to a multiply connected circular region" Soviet Math. Dokl. , 2 pp. 55–58 Dokl. Akad. Nauk SSSR , 136 : 2 (1961) pp. 284–287
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