Divergence Theorem and Sets of Finite Perimeter

Name: Divergence Theorem and Sets of Finite Perimeter
Brand: Taylor & Francis Ltd
SKU: 9780367381516
Price: 76.99 EUR
Availability: InStock

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Product variants

A01=Washek F. Pfeffer

Admissible Vector Fields

advanced mathematical analysis

Author_Washek F. Pfeffer

Bernstein Function

Borel Measure

Borel Set

bounded variation analysis

Bounded Vector Fields

BV Function

Bv Functions

Category=PHU

Closed Subset

coarea theorem

Compact Set

Continuous Linear Map

Continuous Vector Fields

Dyadic Cubes

Dyadic Figures

eq_bestseller

eq_isMigrated=1

eq_isMigrated=2

eq_nobargain

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eq_science

Extended Real Number

Finite Perimeter

flux of continuous vector field

geometric measure theory

Hausdorff Measures

Holomorphic Function

Lebesgue integration

Linear Space

Lipschitz Map

Locally Convex Space

Minimal Surface Equation

Negligible Set

Open Set

removable singularities

Sets Of Finite Perimeter

Singular Set

Strong Topology

The Divergence Theroem

Topological Space

Vector Field

Weak Solution

Product details

ISBN 9780367381516
Weight: 362g
Dimensions: 156 x 234mm
Publication Date: 05 Sep 2019
Publisher: Taylor & Francis Ltd
Publication City/Country: GB
Product Form: Paperback

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This book is devoted to a detailed development of the divergence theorem. The framework is that of Lebesgue integration — no generalized Riemann integrals of Henstock–Kurzweil variety are involved.

In Part I the divergence theorem is established by a combinatorial argument involving dyadic cubes. Only elementary properties of the Lebesgue integral and Hausdorff measures are used. The resulting integration by parts is sufficiently general for many applications. As an example, it is applied to removable singularities of Cauchy–Riemann, Laplace, and minimal surface equations.

The sets of finite perimeter are introduced in Part II. Both the geometric and analytic points of view are presented. The equivalence of these viewpoints is obtained via the functions of bounded variation. These functions are studied in a self-contained manner with no references to Sobolev’s spaces. The coarea theorem provides a link between the sets of finite perimeter and functions of bounded variation.

The general divergence theorem for bounded vector fields is proved in Part III. The proof consists of adapting the combinatorial argument of Part I to sets of finite perimeter. The unbounded vector fields and mean divergence are also discussed. The final chapter contains a characterization of the distributions that are equal to the flux of a continuous vector field.

Pfeffer, Washek F.