Boundary variation, method of
A method of studying univalent functions (cf. Univalent function), based on the study of the variation of a function that is univalent in a domain of the -plane, the variation of the function being determined by the appropriate variations of the boundary of the image of this domain.
The fundamental lemma of the method of boundary variation. Let be a domain in the -plane and let the complement of in the extended plane consist of a number of continua. Let be a continuum in and let there exist on an analytic function such that for any point and for any function that can be represented as
(*) |
and that is univalent in , the inequality
be valid, and suppose that the estimate of the residual term in (*) is uniform in all closed subdomains of . will then be an analytic curve that may parametrically be represented by means of the function of the real parameter . This parameter may be so chosen that satisfies the differential equation
This result makes the important role played by quadratic differentials (cf. Quadratic differential) in the solution of extremal problems in the theory of univalent functions clear, since proves to be a meromorphic function in many applications. In certain cases it follows from the conditions of the problem that the appropriate poles of belong to the boundary of the extremal domain, and it is shown by the fundamental lemma of the method of boundary variation that the boundary of this domain belongs to the union of the closures of the critical trajectories of the quadratic differential
In a number of extremal problems, the fundamental lemma not only yields qualitative results, but also gives sufficient information for the determination of the boundary of the extremal domain, and hence for the complete solution of the problem.
The following results were obtained by means of the method of boundary variation: Qualitative results in the coefficient problem for the class ; in the problem of the maximum of the -th diameter in a family of continua of a given capacity; the solution of a number of extremal problems of univalent conformal mappings of doubly-connected domains; distortion theorems for multiply-connected domains, which at the same prove existence theorems of univalent conformal mappings of a given multiply-connected domain onto canonical domains, etc.
References
[1] | M. Schiffer, "A method of variation within the family of simple functions" Proc. London Math. Soc., Ser. 2 , 44 (1938) pp. 432–449 |
[2] | M. Schiffer, "Some recent developments in the theory of conformal mappings" R. Courant (ed.) , Dirichlet's principle. Conformal mapping and minimal surfaces , Interscience (1950) |
[3] | M. Schiffer, "Applications of variational methods in the theory of conformal mapping" , Calculus of variations and its applications , Proc. Symp. Appl. Math. , 8 , Amer. Math. Soc. & McGraw-Hill (1958) pp. 93–113 |
Comments
The "fundamental lemma of the method of boundary variation" is also known as Schiffer's theorem.
References
[a1] | P.L. Duren, "Univalent functions" , Springer (1983) pp. Chapt. 10 |
Boundary variation, method of. Encyclopedia of Mathematics. URL: http://encyclopediaofmath.org/index.php?title=Boundary_variation,_method_of&oldid=46138