Blaschke product

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In complex analysis, the Blaschke product is a bounded analytic function in the open unit disc constructed to have zeros at a (finite or infinite) sequence of prescribed complex numbers

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inside the unit disc, with the property that the magnitude of the function is constant along the boundary of the disc.

Blaschke product,
B
(
z
)
{\displaystyle B(z)}
, associated to 50 randomly chosen points in the unit disk. B(z) is represented as a Matplotlib plot, using a version of the Domain coloring method. Blaschke-product.png
Blaschke product, , associated to 50 randomly chosen points in the unit disk. B(z) is represented as a Matplotlib plot, using a version of the Domain coloring method.

Blaschke products were introduced by WilhelmBlaschke  ( 1915 ). They are related to Hardy spaces.

Definition

A sequence of points inside the unit disk is said to satisfy the Blaschke condition when

Given a sequence obeying the Blaschke condition, the Blaschke product is defined as

with factors

provided . Here is the complex conjugate of . When take .

The Blaschke product defines a function analytic in the open unit disc, and zero exactly at the (with multiplicity counted): furthermore it is in the Hardy class . [1]

The sequence of satisfying the convergence criterion above is sometimes called a Blaschke sequence.

Szegő theorem

A theorem of Gábor Szegő states that if , the Hardy space with integrable norm, and if is not identically zero, then the zeroes of (certainly countable in number) satisfy the Blaschke condition.

Finite Blaschke products

Finite Blaschke products can be characterized (as analytic functions on the unit disc) in the following way: Assume that is an analytic function on the open unit disc such that can be extended to a continuous function on the closed unit disc

that maps the unit circle to itself. Then is equal to a finite Blaschke product

where lies on the unit circle and is the multiplicity of the zero , . In particular, if satisfies the condition above and has no zeros inside the unit circle, then is constant (this fact is also a consequence of the maximum principle for harmonic functions, applied to the harmonic function .

See also

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References

  1. Conway (1996) 274