Quantitative towers in finite difference calculus approximating the continuum

R. Lawrence; N. Ranade; D. Sullivan

doi:10.1093/qmath/haaa060

Quantitative towers in finite difference calculus approximating the continuum

R. Lawrence
, N. Ranade
, D. Sullivan

Mathematics

Hebrew University of Jerusalem
Cold Spring Harbor Laboratory

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

Abstract

Multivector fields and differential forms at the continuum level have respectively two commutative associative products, a third composition product between them and various operators like partial, d and '∗' which are used to describe many nonlinear problems. The point of this paper is to construct consistent direct and inverse systems of finite dimensional approximations to these structures and to calculate combinatorially how these finite dimensional models differ from their continuum idealizations. In a Euclidean background, there is an explicit answer which is natural statistically.

Original language	English
Pages (from-to)	515-545
Number of pages	31
Journal	Quarterly Journal of Mathematics
Volume	72
Issue number	1-2
DOIs	https://doi.org/10.1093/qmath/haaa060
State	Published - Jun 1 2021

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abstract = "Multivector fields and differential forms at the continuum level have respectively two commutative associative products, a third composition product between them and various operators like partial, d and '∗' which are used to describe many nonlinear problems. The point of this paper is to construct consistent direct and inverse systems of finite dimensional approximations to these structures and to calculate combinatorially how these finite dimensional models differ from their continuum idealizations. In a Euclidean background, there is an explicit answer which is natural statistically.",

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AU - Sullivan, D.

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AB - Multivector fields and differential forms at the continuum level have respectively two commutative associative products, a third composition product between them and various operators like partial, d and '∗' which are used to describe many nonlinear problems. The point of this paper is to construct consistent direct and inverse systems of finite dimensional approximations to these structures and to calculate combinatorially how these finite dimensional models differ from their continuum idealizations. In a Euclidean background, there is an explicit answer which is natural statistically.

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DO - 10.1093/qmath/haaa060

M3 - Article

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JO - Quarterly Journal of Mathematics

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Quantitative towers in finite difference calculus approximating the continuum

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