Distortion theorems
under conformal mapping of planar domains
Theorems characterizing the distortion of line elements at a given point of a domain, as well as the distortion of the domain and its subsets, and the distortion of the boundary of the domain under a conformal mapping. Estimates of the modulus of the derivatives of an analytic function at a point of a domain belong first of all to distortion theorems. The statement, for functions in the class 
of functions
 |
meromorphic and univalent in 
, that for all 
, 
, the inequality
 | (1) |
holds, is a distortion theorem.
Equality at the left-hand side of (1) holds only for the functions
 |
while at the right-hand side equality holds only for the functions
 |
Here 
and 
are two arbitrary fixed numbers. The functions 
map the domain 
onto the 
-plane with slit along the interval connecting the points 
and 
. The functions 
map the domain 
onto the 
-plane with slit along an arc of the circle 
with mid-point 
. Inequality (1) is easily obtained from the Grunsky inequality
 |
which determines the range of values of the functional 
on the class 
. On the other hand, inequality (1) is a direct consequence of Goluzin's theorem: If 
, then for any two points 
with 
, 
, the sharp inequality
 | (2) |
holds, where, moreover, the equality sign is attained for the functions 
, where 
is a real constant. Inequality (2) also implies the chord-distortion theorem (cf. [1]). If 
, then for any two points 
on the circle 
the sharp inequality
 |
holds. Equality in this case is only attained for the functions
 |
where 
is a constant and 
. Various generalizations of (2) are known. These give the ranges of values of corresponding functionals and are sharpened versions of distortion theorems for 
or its subclasses (cf., e.g., [1]).
In the class 
of functions
 |
that are regular and univalent in the disc 
, the following sharp inequalities are valid for 
:
 | (3) |
 | (4) |
 | (5) |
The estimates (4) and (5) follow from (3). The inequalities (3)–(5) are called the distortion theorems for 
. The lower bounds are realized only by the functions
 |
while the upper bounds are realized only by the functions
 |
where 
. The functions 
, 
, known as the Koebe functions, map the disc 
onto the 
-plane with slit along the ray 
, 
. They are extremal in a number of problems in the theory of univalent functions. Koebe's 
-theorem holds: The domain that is the image of the disc 
under a mapping 
, 
, always contains the disc 
, and the point 
lies on the boundary of this domain only for 
.
The estimates (3)–(5) are simple consequences of results on the ranges of the functionals
 |
on 
(cf. [2]).
Let 
be the class of functions 
with 
for 
. Between functions in 
and 
there is the following relation: If 
, then 
, and, conversely, if 
, then 
. Hence, the range of some functional (or system of functionals) on 
is determined by the range of the corresponding functional (system of functionals) on 
, vice versa. E.g., the range of 
, 
, on 
is easily obtained from that of 
, 
, on 
.
For functions that are regular and bounded in a disc, the Schwarz lemma (cf. [1]) and its generalizations, as well as the following boundary-distortion theorem of Löwner are examples of distortion theorems. Löwner's theorem: For a function 
that is regular in 
with 
, 
in 
and 
on an arc 
of 
, the length of the image of 
is not smaller than the length of 
itself, and equality only holds for the functions 
, with 
a real number.
In the class of functions that are univalent in a given multiply-connected domain, the minimum (respectively, maximum) modulus of the derivative at a given point of the domain is attained only for mappings of this domain onto a domain with radial (resp. circular concentric) slits. For unbounded mappings the following theorem holds: Let 
be a finitely-connected domain in the 
-plane containing the point at infinity, let 
be the class of univalent functions 
in 
that have in a neighbourhood of 
the expansion
 |
and let 
be a point in 
. Let 
, 
, be a function in 
mapping 
onto the plane with slits along the arcs of the logarithmic spirals that make an angle 
with rays emanating from the origin (it is a sufficient to take 
; for 
the logarithmic spiral degenerates into a ray emanating from the origin, while for 
it degenerates into a circle with centre at the origin). Let
 |
where those branches of the square root are taken that give first coefficients 1 in the Laurent expansions of 
and 
in a neighbourhood of 
. Then the range of 
on 
is the disc defined by
 |
where to each boundary point only the functions 
with suitable 
, and 
a constant, correspond. In particular, one has the sharp inequalities
 |
 |
References
| [1] | G.M. Goluzin, "Geometric theory of functions of a complex variable" , Transl. Math. Monogr. , 26 , Amer. Math. Soc. (1969) (Translated from Russian) |
| [2] | J.A. Jenkins, "Univalent functions and conformal mapping" , Springer (1958) |
| [3] | V.V. Chernikov, "Extremal properties of univalent conformal mappings" , Results of investigation in mathematics and mechanics during 50 years: 1917–1967 , Tomsk (1967) pp. 23–51 (In Russian) |
| [4] | I.E. Bazilevich, , Mathematics in the USSR during 40 years: 1917–1957 , 1 , Moscow (1959) pp. 444–472 (In Russian) |
| [5] | P.P. Belinskii, "General properties of quasi-conformal mappings" , Novosibirsk (1974) (In Russian) |
| [6] | R. Kühnau, "Verzerrungssätze und Koeffizientenbedingungen vom Grunskyschen Typ für quasikonforme Abbildungen" Math. Nachrichten , 48 (1971) pp. 77–105 |
Comments
Other distortion theorems are, e.g., Landau's theorems (cf. Landau theorems), Bloch's theorem (cf. Bloch constant) and the Pick theorem.
References
| [a1] | P.L. Duren, "Univalent functions" , Springer (1983) pp. Chapt. 3 |
| [a2] | C. Pommerenke, "Univalent functions" , Vandenhoeck & Ruprecht (1975) |
Distortion theorems. Encyclopedia of Mathematics. URL: http://encyclopediaofmath.org/index.php?title=Distortion_theorems&oldid=14492