In mathematics, a Lipschitz domain (or domain with Lipschitz boundary) is a domain in

Euclidean space Euclidean space is the fundamental space of geometry, intended to represent physical space. Originally, that is, in Euclid's ''Elements'', it was the three-dimensional space of Euclidean geometry, but in modern mathematics there are Euclidean ...

whose boundary is "sufficiently regular" in the sense that it can be thought of as locally being the graph of a Lipschitz continuous function. The term is named after the German

mathematician A mathematician is someone who uses an extensive knowledge of mathematics in their work, typically to solve mathematical problems. Mathematicians are concerned with numbers, data, quantity, structure, space, models, and change. History On ...

Rudolf Lipschitz Rudolf Otto Sigismund Lipschitz (14 May 1832 – 7 October 1903) was a German mathematician who made contributions to mathematical analysis (where he gave his name to the Lipschitz continuity condition) and differential geometry, as well as numbe ...

Definition

Let

n \in \mathbb N

. Let

\Omega

be a domain of

\mathbb R^n

and let

\partial\Omega

denote the

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\Omega

. Then

\Omega

is called a Lipschitz domain if for every point

p \in \partial\Omega

there exists a hyperplane

H

of dimension

n-1

through

p

, a Lipschitz-continuous function

g : H \rightarrow \mathbb R

over that hyperplane, and reals

r > 0

and

h > 0

such that *

\Omega \cap C = \left\

(\partial\Omega) \cap C = \left\

where :

\vec

is a unit vector that is normal to

H,

B_ (p) := \

is the open ball of radius

r

, :

C := \left\.

In other words, at each point of its boundary,

\Omega

is locally the set of points located above the graph of some Lipschitz function.

Generalization

A more general notion is that of weakly Lipschitz domains, which are domains whose boundary is locally flattable by a bilipschitz mapping. Lipschitz domains in the sense above are sometimes called strongly Lipschitz by contrast with weakly Lipschitz domains. A domain

\Omega

is weakly Lipschitz if for every point

p \in \partial\Omega,

there exists a radius

r > 0

and a map

l_p : B_r(p) \rightarrow Q

such that *

l_p

is a bijection; *

l_p

and

l_p^

are both Lipschitz continuous functions; *

l_p\left( \partial\Omega \cap B_r(p) \right) = Q_0;

l_p\left( \Omega \cap B_r(p) \right) = Q_+;

where

Q

denotes the unit ball

B_1(0)

\mathbb^

and :

Q_ := \;

Q_ := \.

A (strongly) Lipschitz domain is always a weakly Lipschitz domain but the converse is not true. An example of weakly Lipschitz domains that fails to be a strongly Lipschitz domain is given by the two-bricks domain Werner Licht, M
"Smoothed Projections over Weakly Lipschitz Domains"
''

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'', 2016.

Applications of Lipschitz domains

Many of the Sobolev embedding theorems require that the domain of study be a Lipschitz domain. Consequently, many partial differential equations and variational problems are defined on Lipschitz domains.

References

* {{cite book , author=Dacorogna, B. , title=Introduction to the Calculus of Variations , publisher=Imperial College Press, London , year=2004 , isbn=1-86094-508-2 Geometry Lipschitz maps Sobolev spaces