mathematics Mathematics is an area of knowledge that includes the topics of numbers, formulas and related structures, shapes and the spaces in which they are contained, and quantities and their changes. These topics are represented in modern mathematics ...

, conformal welding (sewing or gluing) is a process in geometric function theory for producing a

Riemann surface In mathematics, particularly in complex analysis, a Riemann surface is a connected one-dimensional complex manifold. These surfaces were first studied by and are named after Bernhard Riemann. Riemann surfaces can be thought of as deformed vers ...

by joining together two Riemann surfaces, each with a disk removed, along their boundary circles. This problem can be reduced to that of finding univalent holomorphic maps ''f'', ''g'' of the unit disk and its complement into the extended complex plane, both admitting continuous extensions to the closure of their domains, such that the images are complementary Jordan domains and such that on the unit circle they differ by a given quasisymmetric homeomorphism. Several proofs are known using a variety of techniques, including the

Beltrami equation In mathematics, the Beltrami equation, named after Eugenio Beltrami, is the partial differential equation : = \mu . for ''w'' a complex distribution of the complex variable ''z'' in some open set ''U'', with derivatives that are locally ''L''2 ...

, the Hilbert transform on the circle and elementary approximation techniques. describe the first two methods of conformal welding as well as providing numerical computations and applications to the analysis of shapes in the plane.

Welding using the Beltrami equation

This method was first proposed by . If ''f'' is a diffeomorphism of the circle, the Alexander extension gives a way of extending ''f'' to a diffeomorphism of the unit disk ''D'': :

\displaystyle

where ψ is a smooth function with values in ,1 equal to 0 near 0 and 1 near 1, and :

\displaystyle

with ''g''(θ + 2π) = ''g''(θ) + 2π. The extension ''F'' can be continued to any larger disk , ''z'', < ''R'' with ''R'' > 1. Accordingly in the unit disc :

\displaystyle

Now extend μ to a Beltrami coefficient on the whole of C by setting it equal to 0 for , ''z'', ≥ 1. Let ''G'' be the corresponding solution of the Beltrami equation: :

\displaystyle

Let ''F''₁(''z'') = ''G'' ∘ ''F''⁻¹(''z'') for , ''z'', ≤ 1 and ''F''₂(''z'') = ''G'' (''z'') for , ''z'', ≥ 1. Thus ''F''₁ and ''F''₂ are univalent holomorphic maps of , ''z'', < 1 and , ''z'', > 1 onto the inside and outside of a Jordan curve. They extend continuously to homeomorphisms ''f''_''i'' of the unit circle onto the Jordan curve on the boundary. By construction they satisfy the conformal welding condition: :

\displaystyle

Welding using the Hilbert transform on the circle

The use of the Hilbert transform to establish conformal welding was first suggested by the Georgian mathematicians D.G. Mandzhavidze and B.V. Khvedelidze in 1958. A detailed account was given at the same time by F.D. Gakhov and presented in his classic monograph (). Let ''e''_''n''(θ) = ''e''^''in''θ be the standard orthonormal basis of L²(T). Let H²(T) be Hardy space, the closed subspace spanned by the ''e''_''n'' with ''n'' ≥ 0. Let ''P'' be the orthogonal projection onto Hardy space and set ''T'' = 2''P'' - ''I''. The operator ''H'' = ''iT'' is the Hilbert transform on the circle and can be written as a singular integral operator. Given a diffeomorphism ''f'' of the unit circle, the task is to determine two univalent holomorphic functions :

\displaystyle

defined in , z, < 1 and , z, > 1 and both extending smoothly to the unit circle, mapping onto a Jordan domain and its complement, such that :

\displaystyle

Let ''F'' be the restriction of ''f''₊ to the unit circle. Then :

\displaystyle

and :

\displaystyle

Hence :

\displaystyle

If ''V''(''f'') denotes the bounded invertible operator on L² induced by the diffeomorphism ''f'', then the operator :

\displaystyle

is compact, indeed it is given by an operator with smooth kernel because ''P'' and ''T'' are given by singular integral operators. The equation above then reduces to :

\displaystyle

The operator ''I'' − ''K''_''f'' is a Fredholm operator of index zero. It has zero kernel and is therefore invertible. In fact an element in the kernel would consist of a pair of holomorphic functions on ''D'' and ''D''^''c'' which have smooth boundary values on the circle related by ''f''. Since the holomorphic function on ''D''^''c'' vanishes at ∞, the positive powers of this pair also provide solutions, which are linearly independent, contradicting the fact that ''I'' − ''K''_''f'' is a Fredholm operator. The above equation therefore has a unique solution ''F'' which is smooth and from which ''f''_± can be reconstructed by reversing the steps above. Indeed, by looking at the equation satisfied by the logarithm of the derivative of ''F'', it follows that ''F'' has nowhere vanishing derivative on the unit circle. Moreover ''F'' is one-to-one on the circle since if it assumes the value ''a'' at different points ''z''₁ and ''z''₂ then the logarithm of ''R''(''z'') = (''F''(''z'') − ''a'')/(''z'' - ''z''₁)(''z'' − ''z''₂) would satisfy an integral equation known to have no non-zero solutions. Given these properties on the unit circle, the required properties of ''f''_± then follow from the argument principle.See: * *

Notes

References

* * * * * *{{citation, title=The Theory of Functions, first=E. C., last= Titchmarsh, authorlink=Edward Charles Titchmarsh, edition=2nd, publisher=Oxford University Press, year= 1939, isbn=0198533497 Theorems in analysis Complex analysis Riemann surfaces