Computability in Harmonic Analysis

Ilia Binder; Adi Glucksam; Cristobal Rojas; Michael Yampolsky

doi:10.1007/s10208-021-09524-w

Computability in Harmonic Analysis

Ilia Binder
, Adi Glucksam
, Cristobal Rojas^*
, Michael Yampolsky

^*Corresponding author for this work

Research output: Contribution to journal › Article › peer-review

Abstract

We study the question of constructive approximation of the harmonic measure ωxΩ of a bounded domain Ω with respect to a point x∈ Ω. In particular, using a new notion of computable harmonic approximation, we show that for an arbitrary such Ω, computability of the harmonic measure ωxΩ for a single point x∈ Ω implies computability of ωyΩ for any y∈ Ω. This may require a different algorithm for different points y, which leads us to the construction of surprising natural examples of continuous functions that arise as solutions to a Dirichlet problem, whose values can be computed at any point, but cannot be computed with the use of the same algorithm on all of their domains. We further study the conditions under which the harmonic measure is computable uniformly, that is by a single algorithm, and characterize them for regular domains with computable boundaries.

Original language	English
Pages (from-to)	849-873
Number of pages	25
Journal	Foundations of Computational Mathematics
Volume	22
Issue number	3
DOIs	https://doi.org/10.1007/s10208-021-09524-w
State	Published - Jun 2022
Externally published	Yes

Bibliographical note

Publisher Copyright:
© 2021, SFoCM.

Keywords

Computable analysis
Harmonic measure
Piece-wise computable non-computable functions

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10.1007/s10208-021-09524-w

Cite this

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AU - Glucksam, Adi

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N2 - We study the question of constructive approximation of the harmonic measure ωxΩ of a bounded domain Ω with respect to a point x∈ Ω. In particular, using a new notion of computable harmonic approximation, we show that for an arbitrary such Ω, computability of the harmonic measure ωxΩ for a single point x∈ Ω implies computability of ωyΩ for any y∈ Ω. This may require a different algorithm for different points y, which leads us to the construction of surprising natural examples of continuous functions that arise as solutions to a Dirichlet problem, whose values can be computed at any point, but cannot be computed with the use of the same algorithm on all of their domains. We further study the conditions under which the harmonic measure is computable uniformly, that is by a single algorithm, and characterize them for regular domains with computable boundaries.

AB - We study the question of constructive approximation of the harmonic measure ωxΩ of a bounded domain Ω with respect to a point x∈ Ω. In particular, using a new notion of computable harmonic approximation, we show that for an arbitrary such Ω, computability of the harmonic measure ωxΩ for a single point x∈ Ω implies computability of ωyΩ for any y∈ Ω. This may require a different algorithm for different points y, which leads us to the construction of surprising natural examples of continuous functions that arise as solutions to a Dirichlet problem, whose values can be computed at any point, but cannot be computed with the use of the same algorithm on all of their domains. We further study the conditions under which the harmonic measure is computable uniformly, that is by a single algorithm, and characterize them for regular domains with computable boundaries.

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Computability in Harmonic Analysis

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