- Source: Absorbing set
In functional analysis and related areas of mathematics an absorbing set in a vector space is a set
S
{\displaystyle S}
which can be "inflated" or "scaled up" to eventually always include any given point of the vector space.
Alternative terms are radial or absorbent set.
Every neighborhood of the origin in every topological vector space is an absorbing subset.
Definition
Notation for scalars
Suppose that
X
{\displaystyle X}
is a vector space over the field
K
{\displaystyle \mathbb {K} }
of real numbers
R
{\displaystyle \mathbb {R} }
or complex numbers
C
,
{\displaystyle \mathbb {C} ,}
and for any
−
∞
≤
r
≤
∞
,
{\displaystyle -\infty \leq r\leq \infty ,}
let
B
r
=
{
a
∈
K
:
|
a
|
<
r
}
and
B
≤
r
=
{
a
∈
K
:
|
a
|
≤
r
}
{\displaystyle B_{r}=\{a\in \mathbb {K} :|a|
denote the open ball (respectively, the closed ball) of radius
r
{\displaystyle r}
in
K
{\displaystyle \mathbb {K} }
centered at
0.
{\displaystyle 0.}
Define the product of a set
K
⊆
K
{\displaystyle K\subseteq \mathbb {K} }
of scalars with a set
A
{\displaystyle A}
of vectors as
K
A
=
{
k
a
:
k
∈
K
,
a
∈
A
}
,
{\displaystyle KA=\{ka:k\in K,a\in A\},}
and define the product of
K
⊆
K
{\displaystyle K\subseteq \mathbb {K} }
with a single vector
x
{\displaystyle x}
as
K
x
=
{
k
x
:
k
∈
K
}
.
{\displaystyle Kx=\{kx:k\in K\}.}
= Preliminaries
=Balanced core and balanced hull
A subset
S
{\displaystyle S}
of
X
{\displaystyle X}
is said to be balanced if
a
s
∈
S
{\displaystyle as\in S}
for all
s
∈
S
{\displaystyle s\in S}
and all scalars
a
{\displaystyle a}
satisfying
|
a
|
≤
1
;
{\displaystyle |a|\leq 1;}
this condition may be written more succinctly as
B
≤
1
S
⊆
S
,
{\displaystyle B_{\leq 1}S\subseteq S,}
and it holds if and only if
B
≤
1
S
=
S
.
{\displaystyle B_{\leq 1}S=S.}
Given a set
T
,
{\displaystyle T,}
the smallest balanced set containing
T
,
{\displaystyle T,}
denoted by
bal
T
,
{\displaystyle \operatorname {bal} T,}
is called the balanced hull of
T
{\displaystyle T}
while the largest balanced set contained within
T
,
{\displaystyle T,}
denoted by
balcore
T
,
{\displaystyle \operatorname {balcore} T,}
is called the balanced core of
T
.
{\displaystyle T.}
These sets are given by the formulas
bal
T
=
⋃
|
c
|
≤
1
c
T
=
B
≤
1
T
{\displaystyle \operatorname {bal} T~=~{\textstyle \bigcup \limits _{|c|\leq 1}}c\,T=B_{\leq 1}T}
and
balcore
T
=
{
⋂
|
c
|
≥
1
c
T
if
0
∈
T
∅
if
0
∉
T
,
{\displaystyle \operatorname {balcore} T~=~{\begin{cases}{\textstyle \bigcap \limits _{|c|\geq 1}}c\,T&{\text{ if }}0\in T\\\varnothing &{\text{ if }}0\not \in T,\\\end{cases}}}
(these formulas show that the balanced hull and the balanced core always exist and are unique).
A set
T
{\displaystyle T}
is balanced if and only if it is equal to its balanced hull (
T
=
bal
T
{\displaystyle T=\operatorname {bal} T}
) or to its balanced core (
T
=
balcore
T
{\displaystyle T=\operatorname {balcore} T}
), in which case all three of these sets are equal:
T
=
bal
T
=
balcore
T
.
{\displaystyle T=\operatorname {bal} T=\operatorname {balcore} T.}
If
c
{\displaystyle c}
is any scalar then
bal
(
c
T
)
=
c
bal
T
=
|
c
|
bal
T
{\displaystyle \operatorname {bal} (c\,T)=c\,\operatorname {bal} T=|c|\,\operatorname {bal} T}
while if
c
≠
0
{\displaystyle c\neq 0}
is non-zero or if
0
∈
T
{\displaystyle 0\in T}
then also
balcore
(
c
T
)
=
c
balcore
T
=
|
c
|
balcore
T
.
{\displaystyle \operatorname {balcore} (c\,T)=c\,\operatorname {balcore} T=|c|\,\operatorname {balcore} T.}
= One set absorbing another
=If
S
{\displaystyle S}
and
A
{\displaystyle A}
are subsets of
X
,
{\displaystyle X,}
then
A
{\displaystyle A}
is said to absorb
S
{\displaystyle S}
if it satisfies any of the following equivalent conditions:
Definition: There exists a real
r
>
0
{\displaystyle r>0}
such that
S
⊆
c
A
{\displaystyle S\,\subseteq \,c\,A}
for every scalar
c
{\displaystyle c}
satisfying
|
c
|
≥
r
.
{\displaystyle |c|\geq r.}
Or stated more succinctly,
S
⊆
⋂
|
c
|
≥
r
c
A
{\displaystyle S\;\subseteq \;{\textstyle \bigcap \limits _{|c|\geq r}}c\,A}
for some
r
>
0.
{\displaystyle r>0.}
If the scalar field is
R
{\displaystyle \mathbb {R} }
then intuitively, "
A
{\displaystyle A}
absorbs
S
{\displaystyle S}
" means that if
A
{\displaystyle A}
is perpetually "scaled up" or "inflated" (referring to
t
A
{\displaystyle tA}
as
t
→
∞
{\displaystyle t\to \infty }
) then eventually (for all positive
t
>
0
{\displaystyle t>0}
sufficiently large), all
t
A
{\displaystyle tA}
will contain
S
;
{\displaystyle S;}
and similarly,
t
A
{\displaystyle tA}
must also eventually contain
S
{\displaystyle S}
for all negative
t
<
0
{\displaystyle t<0}
sufficiently large in magnitude.
This definition depends on the underlying scalar field's canonical norm (that is, on the absolute value
|
⋅
|
{\displaystyle |\cdot |}
), which thus ties this definition to the usual Euclidean topology on the scalar field. Consequently, the definition of an absorbing set (given below) is also tied to this topology.
There exists a real
r
>
0
{\displaystyle r>0}
such that
c
S
⊆
A
{\displaystyle c\,S\,\subseteq \,A}
for every non-zero scalar
c
≠
0
{\displaystyle c\neq 0}
satisfying
|
c
|
≤
r
.
{\displaystyle |c|\leq r.}
Or stated more succinctly,
⋃
0
<
|
c
|
≤
r
c
S
⊆
A
{\displaystyle {\textstyle \bigcup \limits _{0<|c|\leq r}}c\,S\,\subseteq \,A}
for some
r
>
0.
{\displaystyle r>0.}
Because this union is equal to
(
B
≤
r
∖
{
0
}
)
S
,
{\displaystyle \left(B_{\leq r}\setminus \{0\}\right)S,}
where
B
≤
r
∖
{
0
}
=
{
c
∈
K
:
0
<
|
c
|
≤
r
}
{\displaystyle B_{\leq r}\setminus \{0\}=\{c\in \mathbb {K} :0<|c|\leq r\}}
is the closed ball with the origin removed, this condition may be restated as:
(
B
≤
r
∖
{
0
}
)
S
⊆
A
{\displaystyle \left(B_{\leq r}\setminus \{0\}\right)S\,\subseteq \,A}
for some
r
>
0.
{\displaystyle r>0.}
The non-strict inequality
≤
{\displaystyle \,\leq \,}
can be replaced with the strict inequality
<
,
{\displaystyle \,<\,,}
which is the next characterization.
There exists a real
r
>
0
{\displaystyle r>0}
such that
c
S
⊆
A
{\displaystyle c\,S\,\subseteq \,A}
for every non-zero scalar
c
≠
0
{\displaystyle c\neq 0}
satisfying
|
c
|
<
r
.
{\displaystyle |c|
Or stated more succinctly,
(
B
r
∖
{
0
}
)
S
⊆
A
{\displaystyle \left(B_{r}\setminus \{0\}\right)S\subseteq \,A}
for some
r
>
0.
{\displaystyle r>0.}
Here
B
r
∖
{
0
}
=
{
c
∈
K
:
0
<
|
c
|
<
r
}
{\displaystyle B_{r}\setminus \{0\}=\{c\in \mathbb {K} :0<|c|
is the open ball with the origin removed and
(
B
r
∖
{
0
}
)
S
=
⋃
0
<
|
c
|
<
r
c
S
.
{\displaystyle \left(B_{r}\setminus \{0\}\right)S\,=\,{\textstyle \bigcup \limits _{0<|c|
If
A
{\displaystyle A}
is a balanced set then this list can be extended to include:
There exists a non-zero scalar
c
≠
0
{\displaystyle c\neq 0}
such that
S
⊆
c
A
.
{\displaystyle S\;\subseteq \,c\,A.}
If
0
∈
A
{\displaystyle 0\in A}
then the requirement
c
≠
0
{\displaystyle c\neq 0}
may be dropped.
There exists a non-zero scalar
c
≠
0
{\displaystyle c\neq 0}
such that
c
S
⊆
A
.
{\displaystyle c\,S\,\subseteq \,A.}
If
0
∈
A
{\displaystyle 0\in A}
(a necessary condition for
A
{\displaystyle A}
to be an absorbing set, or to be a neighborhood of the origin in a topology) then this list can be extended to include:
There exists
r
>
0
{\displaystyle r>0}
such that
c
S
⊆
A
{\displaystyle c\,S\;\subseteq \,A}
for every scalar
c
{\displaystyle c}
satisfying
|
c
|
<
r
.
{\displaystyle |c|
Or stated more succinctly,
B
r
S
⊆
A
.
{\displaystyle B_{r}\;S\,\subseteq \,A.}
There exists
r
>
0
{\displaystyle r>0}
such that
c
S
⊆
A
{\displaystyle c\,S\;\subseteq \,A}
for every scalar
c
{\displaystyle c}
satisfying
|
c
|
≤
r
.
{\displaystyle |c|\leq r.}
Or stated more succinctly,
B
≤
r
S
⊆
A
.
{\displaystyle B_{\leq r}S\,\subseteq \,A.}
The inclusion
B
≤
r
S
⊆
A
{\displaystyle B_{\leq r}S\,\subseteq \,A}
is equivalent to
B
≤
1
S
⊆
1
r
A
{\displaystyle B_{\leq 1}S\,\subseteq \,{\tfrac {1}{r}}A}
(since
B
≤
r
=
r
B
≤
1
{\displaystyle B_{\leq r}=r\,B_{\leq 1}}
). Because
B
≤
1
S
=
bal
S
,
{\displaystyle B_{\leq 1}S\,=\,\operatorname {bal} \,S,}
this may be rewritten
bal
S
⊆
1
r
A
,
{\displaystyle \operatorname {bal} \,S\,\subseteq \,{\tfrac {1}{r}}A,}
which gives the next statement.
There exists
r
>
0
{\displaystyle r>0}
such that
bal
S
⊆
r
A
.
{\displaystyle \operatorname {bal} \,S\,\subseteq \,r\,A.}
There exists
r
>
0
{\displaystyle r>0}
such that
bal
S
⊆
balcore
(
r
A
)
.
{\displaystyle \operatorname {bal} \,S\,\subseteq \,\operatorname {balcore} (r\,A).}
There exists
r
>
0
{\displaystyle r>0}
such that
S
⊆
balcore
(
r
A
)
.
{\displaystyle \;\;\;\;\;\;S\,\subseteq \,\operatorname {balcore} (r\,A).}
The next characterizations follow from those above and the fact that for every scalar
c
,
{\displaystyle c,}
the balanced hull of
A
{\displaystyle A}
satisfies
bal
(
c
A
)
=
c
bal
A
=
|
c
|
bal
A
{\displaystyle \,\operatorname {bal} (c\,A)=c\,\operatorname {bal} A=|c|\,\operatorname {bal} A\,}
and (since
0
∈
A
{\displaystyle 0\in A}
) its balanced core satisfies
balcore
(
c
A
)
=
c
balcore
A
=
|
c
|
balcore
A
.
{\displaystyle \,\operatorname {balcore} (c\,A)=c\,\operatorname {balcore} A=|c|\,\operatorname {balcore} A.}
There exists
r
>
0
{\displaystyle r>0}
such that
S
⊆
r
balcore
A
.
{\displaystyle \;\;\,S\,\subseteq \,r\,\operatorname {balcore} A.}
In words, a set is absorbed by
A
{\displaystyle A}
if it is contained in some positive scalar multiple of the balanced core of
A
.
{\displaystyle A.}
There exists
r
>
0
{\displaystyle r>0}
such that
r
S
⊆
balcore
A
.
{\displaystyle r\,S\subseteq \,\;\;\;\;\operatorname {balcore} A.}
There exists a non-zero scalar
c
≠
0
{\displaystyle c\neq 0}
such that
c
S
⊆
balcore
A
.
{\displaystyle c\,S\,\subseteq \,\operatorname {balcore} A.}
In words, the balanced core of
A
{\displaystyle A}
contains some non-zero scalar multiple of
S
.
{\displaystyle S.}
There exists a scalar
c
{\displaystyle c}
such that
bal
S
⊆
c
A
.
{\displaystyle \operatorname {bal} S\,\subseteq \,c\,A.}
In words,
A
{\displaystyle A}
can be scaled to contain the balanced hull of
S
.
{\displaystyle S.}
There exists a scalar
c
{\displaystyle c}
such that
bal
S
⊆
balcore
(
c
A
)
.
{\displaystyle \operatorname {bal} S\,\subseteq \,\operatorname {balcore} (c\,A).}
There exists a scalar
c
{\displaystyle c}
such that
S
⊆
balcore
(
c
A
)
.
{\displaystyle \;\;\;\;\;\;S\,\subseteq \,\operatorname {balcore} (c\,A).}
In words,
A
{\displaystyle A}
can be scaled so that its balanced core contains
S
.
{\displaystyle S.}
There exists a scalar
c
{\displaystyle c}
such that
S
⊆
c
balcore
A
.
{\displaystyle \;\;\;\;\;\;S\,\subseteq \,c\,\operatorname {balcore} A.}
There exists a scalar
c
{\displaystyle c}
such that
bal
S
⊆
c
balcore
(
A
)
.
{\displaystyle \operatorname {bal} S\,\subseteq \,c\,\operatorname {balcore} (A).}
In words, the balanced core of
A
{\displaystyle A}
can be scaled to contain the balanced hull of
S
.
{\displaystyle S.}
The balanced core of
A
{\displaystyle A}
absorbs the balanced hull
S
{\displaystyle S}
(according to any defining condition of "absorbs" other than this one).
If
0
∉
S
{\displaystyle 0\not \in S}
or
0
∈
A
{\displaystyle 0\in A}
then this list can be extended to include:
A
∪
{
0
}
{\displaystyle A\cup \{0\}}
absorbs
S
{\displaystyle S}
(according to any defining condition of "absorbs" other than this one).
In other words,
A
{\displaystyle A}
may be replaced by
A
∪
{
0
}
{\displaystyle A\cup \{0\}}
in the characterizations above if
0
∉
S
{\displaystyle 0\not \in S}
(or trivially, if
0
∈
A
{\displaystyle 0\in A}
).
A set absorbing a point
A set is said to absorb a point
x
{\displaystyle x}
if it absorbs the singleton set
{
x
}
.
{\displaystyle \{x\}.}
A set
A
{\displaystyle A}
absorbs the origin if and only if it contains the origin; that is, if and only if
0
∈
A
.
{\displaystyle 0\in A.}
As detailed below, a set is said to be absorbing in
X
{\displaystyle X}
if it absorbs every point of
X
.
{\displaystyle X.}
This notion of one set absorbing another is also used in other definitions:
A subset of a topological vector space
X
{\displaystyle X}
is called bounded if it is absorbed by every neighborhood of the origin.
A set is called bornivorous if it absorbs every bounded subset.
First examples
Every set absorbs the empty set but the empty set does not absorb any non-empty set. The singleton set
{
0
}
{\displaystyle \{\mathbf {0} \}}
containing the origin is the one and only singleton subset that absorbs itself.
Suppose that
X
{\displaystyle X}
is equal to either
R
2
{\displaystyle \mathbb {R} ^{2}}
or
C
.
{\displaystyle \mathbb {C} .}
If
A
:=
S
1
∪
{
0
}
{\displaystyle A:=S^{1}\cup \{\mathbf {0} \}}
is the unit circle (centered at the origin
0
{\displaystyle \mathbf {0} }
) together with the origin, then
{
0
}
{\displaystyle \{\mathbf {0} \}}
is the one and only non-empty set that
A
{\displaystyle A}
absorbs. Moreover, there does not exist any non-empty subset of
X
{\displaystyle X}
that is absorbed by the unit circle
S
1
.
{\displaystyle S^{1}.}
In contrast, every neighborhood of the origin absorbs every bounded subset of
X
{\displaystyle X}
(and so in particular, absorbs every singleton subset/point).
= Absorbing set
=A subset
A
{\displaystyle A}
of a vector space
X
{\displaystyle X}
over a field
K
{\displaystyle \mathbb {K} }
is called an absorbing (or absorbent) subset of
X
{\displaystyle X}
and is said to be absorbing in
X
{\displaystyle X}
if it satisfies any of the following equivalent conditions (here ordered so that each condition is an easy consequence of the previous one, starting with the definition):
Definition:
A
{\displaystyle A}
absorbs every point of
X
;
{\displaystyle X;}
that is, for every
x
∈
X
,
{\displaystyle x\in X,}
A
{\displaystyle A}
absorbs
{
x
}
.
{\displaystyle \{x\}.}
So in particular,
A
{\displaystyle A}
can not be absorbing if
0
∉
A
.
{\displaystyle 0\not \in A.}
Every absorbing set must contain the origin.
A
{\displaystyle A}
absorbs every finite subset of
X
.
{\displaystyle X.}
For every
x
∈
X
,
{\displaystyle x\in X,}
there exists a real
r
>
0
{\displaystyle r>0}
such that
x
∈
c
A
{\displaystyle x\in cA}
for any scalar
c
∈
K
{\displaystyle c\in \mathbb {K} }
satisfying
|
c
|
≥
r
.
{\displaystyle |c|\geq r.}
For every
x
∈
X
,
{\displaystyle x\in X,}
there exists a real
r
>
0
{\displaystyle r>0}
such that
c
x
∈
A
{\displaystyle cx\in A}
for any scalar
c
∈
K
{\displaystyle c\in \mathbb {K} }
satisfying
|
c
|
≤
r
.
{\displaystyle |c|\leq r.}
For every
x
∈
X
,
{\displaystyle x\in X,}
there exists a real
r
>
0
{\displaystyle r>0}
such that
B
r
x
⊆
A
.
{\displaystyle B_{r}x\subseteq A.}
Here
B
r
=
{
c
∈
K
:
|
c
|
<
r
}
{\displaystyle B_{r}=\{c\in \mathbb {K} :|c|
is the open ball of radius
r
{\displaystyle r}
in the scalar field centered at the origin and
B
r
x
=
{
c
x
:
c
∈
B
r
}
=
{
c
x
:
c
∈
K
and
|
c
|
<
r
}
.
{\displaystyle B_{r}x=\left\{cx:c\in B_{r}\right\}=\{cx:c\in \mathbb {K} {\text{ and }}|c|
The closed ball can be used in place of the open ball.
Because
B
r
x
⊆
K
x
=
span
{
x
}
,
{\displaystyle B_{r}x\subseteq \mathbb {K} x=\operatorname {span} \{x\},}
the inclusion
B
r
x
⊆
A
{\displaystyle B_{r}x\subseteq A}
holds if and only if
B
r
x
⊆
A
∩
K
x
.
{\displaystyle B_{r}x\subseteq A\cap \mathbb {K} x.}
This proves the next statement.
For every
x
∈
X
,
{\displaystyle x\in X,}
there exists a real
r
>
0
{\displaystyle r>0}
such that
B
r
x
⊆
A
∩
K
x
,
{\displaystyle B_{r}x\subseteq A\cap \mathbb {K} x,}
where
K
x
=
span
{
x
}
.
{\displaystyle \mathbb {K} x=\operatorname {span} \{x\}.}
Connection to topology: If
K
x
{\displaystyle \mathbb {K} x}
is given its usual Hausdorff Euclidean topology then the set
B
r
x
{\displaystyle B_{r}x}
is a neighborhood of the origin in
K
x
;
{\displaystyle \mathbb {K} x;}
thus, there exists a real
r
>
0
{\displaystyle r>0}
such that
B
r
x
⊆
A
∩
K
x
{\displaystyle B_{r}x\subseteq A\cap \mathbb {K} x}
if and only if
A
∩
K
x
{\displaystyle A\cap \mathbb {K} x}
is a neighborhood of the origin in
K
x
.
{\displaystyle \mathbb {K} x.}
Consequently,
A
{\displaystyle A}
satisfies this condition if and only if for every
x
∈
X
,
{\displaystyle x\in X,}
A
∩
span
{
x
}
{\displaystyle A\cap \operatorname {span} \{x\}}
is a neighborhood of
0
{\displaystyle 0}
in
span
{
x
}
=
K
x
{\displaystyle \operatorname {span} \{x\}=\mathbb {K} x}
when
span
{
x
}
{\displaystyle \operatorname {span} \{x\}}
is given the Euclidean topology. This gives the next characterization.
The only TVS topologies on a 1-dimensional vector space are the (non-Hausdorff) trivial topology and the Hausdorff Euclidean topology. Every 1-dimensional vector subspace of
X
{\displaystyle X}
is of the form
K
x
=
span
{
x
}
{\displaystyle \mathbb {K} x=\operatorname {span} \{x\}}
for some non-zero
x
∈
X
{\displaystyle x\in X}
and if this 1-dimensional space
K
x
{\displaystyle \mathbb {K} x}
is endowed with the (unique) Hausdorff vector topology, then the map
K
→
K
x
{\displaystyle \mathbb {K} \to \mathbb {K} x}
defined by
c
↦
c
x
{\displaystyle c\mapsto cx}
is necessarily a TVS-isomorphism (where as usual,
K
{\displaystyle \mathbb {K} }
is endowed with its standard Euclidean topology induced by the Euclidean metric).
A
{\displaystyle A}
contains the origin and for every 1-dimensional vector subspace
Y
{\displaystyle Y}
of
X
,
{\displaystyle X,}
A
∩
Y
{\displaystyle A\cap Y}
is a neighborhood of the origin in
Y
{\displaystyle Y}
when
Y
{\displaystyle Y}
is given its unique Hausdorff vector topology (i.e. the Euclidean topology).
The reason why the Euclidean topology is distinguished in this characterization ultimately stems from the defining requirement on TVS topologies that scalar multiplication
K
×
X
→
X
{\displaystyle \mathbb {K} \times X\to X}
be continuous when the scalar field
K
{\displaystyle \mathbb {K} }
is given this (Euclidean) topology.
0
{\displaystyle 0}
-Neighborhoods are absorbing: This condition gives insight as to why every neighborhood of the origin in every topological vector space (TVS) is necessarily absorbing: If
U
{\displaystyle U}
is a neighborhood of the origin in a TVS
X
{\displaystyle X}
then for every 1-dimensional vector subspace
Y
,
{\displaystyle Y,}
U
∩
Y
{\displaystyle U\cap Y}
is a neighborhood of the origin in
Y
{\displaystyle Y}
when
Y
{\displaystyle Y}
is endowed with the subspace topology induced on it by
X
.
{\displaystyle X.}
This subspace topology is always a vector topology and because
Y
{\displaystyle Y}
is 1-dimensional, the only vector topologies on it are the Hausdorff Euclidean topology and the trivial topology, which is a subset of the Euclidean topology.
So regardless of which of these vector topologies is on
Y
,
{\displaystyle Y,}
the set
U
∩
Y
{\displaystyle U\cap Y}
will be a neighborhood of the origin in
Y
{\displaystyle Y}
with respect to its unique Hausdorff vector topology (the Euclidean topology).
Thus
U
{\displaystyle U}
is absorbing.
A
{\displaystyle A}
contains the origin and for every 1-dimensional vector subspace
Y
{\displaystyle Y}
of
X
,
{\displaystyle X,}
A
∩
Y
{\displaystyle A\cap Y}
is absorbing in
Y
{\displaystyle Y}
(according to any defining condition of "absorbing" other than this one).
This characterization shows that the property of being absorbing in
X
{\displaystyle X}
depends only on how
A
{\displaystyle A}
behaves with respect to 1 (or 0) dimensional vector subspaces of
X
.
{\displaystyle X.}
In contrast, if a finite-dimensional vector subspace
Z
{\displaystyle Z}
of
X
{\displaystyle X}
has dimension
n
>
1
{\displaystyle n>1}
and is endowed with its unique Hausdorff TVS topology, then
A
∩
Z
{\displaystyle A\cap Z}
being absorbing in
Z
{\displaystyle Z}
is no longer sufficient to guarantee that
A
∩
Z
{\displaystyle A\cap Z}
is a neighborhood of the origin in
Z
{\displaystyle Z}
(although it will still be a necessary condition). For this to happen, it suffices for
A
∩
Z
{\displaystyle A\cap Z}
to be an absorbing set that is also convex, balanced, and closed in
Z
{\displaystyle Z}
(such a set is called a barrel and it will be a neighborhood of the origin in
Z
{\displaystyle Z}
because every finite-dimensional Euclidean space, including
Z
,
{\displaystyle Z,}
is a barrelled space).
If
K
=
R
{\displaystyle \mathbb {K} =\mathbb {R} }
then to this list can be appended:
The algebraic interior of
A
{\displaystyle A}
contains the origin (that is,
0
∈
i
A
{\displaystyle 0\in {}^{i}A}
).
If
A
{\displaystyle A}
is balanced then to this list can be appended:
For every
x
∈
X
,
{\displaystyle x\in X,}
there exists a scalar
c
≠
0
{\displaystyle c\neq 0}
such that
x
∈
c
A
{\displaystyle x\in cA}
(or equivalently, such that
c
x
∈
A
{\displaystyle cx\in A}
).
For every
x
∈
X
,
{\displaystyle x\in X,}
there exists a scalar
c
{\displaystyle c}
such that
x
∈
c
A
.
{\displaystyle x\in cA.}
If
A
{\displaystyle A}
is convex or balanced then to this list can be appended:
For every
x
∈
X
,
{\displaystyle x\in X,}
there exists a positive real
r
>
0
{\displaystyle r>0}
such that
r
x
∈
A
.
{\displaystyle rx\in A.}
The proof that a balanced set
A
{\displaystyle A}
satisfying this condition is necessarily absorbing in
X
{\displaystyle X}
follows immediately from condition (10) above and the fact that
c
A
=
|
c
|
A
{\displaystyle cA=|c|A}
for all scalars
c
≠
0
{\displaystyle c\neq 0}
(where
r
:=
|
c
|
>
0
{\displaystyle r:=|c|>0}
is real).
The proof that a convex set
A
{\displaystyle A}
satisfying this condition is necessarily absorbing in
X
{\displaystyle X}
is less trivial (but not difficult). A detailed proof is given in this footnote and a summary is given below.
Summary of proof: By assumption, for any non-zero
0
≠
y
∈
X
,
{\displaystyle 0\neq y\in X,}
it is possible to pick positive real
r
>
0
{\displaystyle r>0}
and
R
>
0
{\displaystyle R>0}
such that
R
y
∈
A
{\displaystyle Ry\in A}
and
r
(
−
y
)
∈
A
{\displaystyle r(-y)\in A}
so that the convex set
A
∩
R
y
{\displaystyle A\cap \mathbb {R} y}
contains the open sub-interval
(
−
r
,
R
)
y
=
def
{
t
y
:
−
r
<
t
<
R
,
t
∈
R
}
,
{\displaystyle (-r,R)y\,{\stackrel {\scriptscriptstyle {\text{def}}}{=}}\,\{ty:-r
which contains the origin (
A
∩
R
y
{\displaystyle A\cap \mathbb {R} y}
is called an interval since we identify
R
y
{\displaystyle \mathbb {R} y}
with
R
{\displaystyle \mathbb {R} }
and every non-empty convex subset of
R
{\displaystyle \mathbb {R} }
is an interval). Give
K
y
{\displaystyle \mathbb {K} y}
its unique Hausdorff vector topology so it remains to show that
A
∩
K
y
{\displaystyle A\cap \mathbb {K} y}
is a neighborhood of the origin in
K
y
.
{\displaystyle \mathbb {K} y.}
If
K
=
R
{\displaystyle \mathbb {K} =\mathbb {R} }
then we are done, so assume that
K
=
C
.
{\displaystyle \mathbb {K} =\mathbb {C} .}
The set
S
=
def
(
A
∩
R
y
)
∪
(
A
∩
R
(
i
y
)
)
⊆
A
∩
(
C
y
)
{\displaystyle S\,{\stackrel {\scriptscriptstyle {\text{def}}}{=}}\,(A\cap \mathbb {R} y)\,\cup \,(A\cap \mathbb {R} (iy))\,\subseteq \,A\cap (\mathbb {C} y)}
is a union of two intervals, each of which contains an open sub-interval that contains the origin; moreover, the intersection of these two intervals is precisely the origin. So the quadrilateral-shaped convex hull of
S
,
{\displaystyle S,}
which is contained in the convex set
A
∩
C
y
,
{\displaystyle A\cap \mathbb {C} y,}
clearly contains an open ball around the origin.
◼
{\displaystyle \blacksquare }
For every
x
∈
X
,
{\displaystyle x\in X,}
there exists a positive real
r
>
0
{\displaystyle r>0}
such that
x
∈
r
A
.
{\displaystyle x\in rA.}
This condition is equivalent to: every
x
∈
X
{\displaystyle x\in X}
belongs to the set
⋃
0
<
r
<
∞
r
A
=
{
r
a
:
0
<
r
<
∞
,
a
∈
A
}
=
(
0
,
∞
)
A
.
{\displaystyle {\textstyle \bigcup \limits _{0
This happens if and only if
X
=
(
0
,
∞
)
A
,
{\displaystyle X=(0,\infty )A,}
which gives the next characterization.
(
0
,
∞
)
A
=
X
.
{\displaystyle (0,\infty )A=X.}
It can be shown that for any subset
T
{\displaystyle T}
of
X
,
{\displaystyle X,}
(
0
,
∞
)
T
=
X
{\displaystyle (0,\infty )T=X}
if and only if
T
∩
(
0
,
∞
)
x
≠
∅
{\displaystyle T\cap (0,\infty )x\neq \varnothing }
for every
x
∈
X
,
{\displaystyle x\in X,}
where
(
0
,
∞
)
x
=
def
{
r
x
:
0
<
r
<
∞
}
.
{\displaystyle (0,\infty )x\,{\stackrel {\scriptscriptstyle {\text{def}}}{=}}\,\{rx:0
For every
x
∈
X
,
{\displaystyle x\in X,}
A
∩
(
0
,
∞
)
x
≠
∅
.
{\displaystyle A\cap (0,\infty )x\neq \varnothing .}
If
0
∈
A
{\displaystyle 0\in A}
(which is necessary for
A
{\displaystyle A}
to be absorbing) then it suffices to check any of the above conditions for all non-zero
x
∈
X
,
{\displaystyle x\in X,}
rather than all
x
∈
X
.
{\displaystyle x\in X.}
Examples and sufficient conditions
= For one set to absorb another
=Let
F
:
X
→
Y
{\displaystyle F:X\to Y}
be a linear map between vector spaces and let
B
⊆
X
{\displaystyle B\subseteq X}
and
C
⊆
Y
{\displaystyle C\subseteq Y}
be balanced sets. Then
C
{\displaystyle C}
absorbs
F
(
B
)
{\displaystyle F(B)}
if and only if
F
−
1
(
C
)
{\displaystyle F^{-1}(C)}
absorbs
B
.
{\displaystyle B.}
If a set
A
{\displaystyle A}
absorbs another set
B
{\displaystyle B}
then any superset of
A
{\displaystyle A}
also absorbs
B
.
{\displaystyle B.}
A set
A
{\displaystyle A}
absorbs the origin if and only if the origin is an element of
A
.
{\displaystyle A.}
A set
A
{\displaystyle A}
absorbs a finite union
B
1
∪
⋯
∪
B
n
{\displaystyle B_{1}\cup \cdots \cup B_{n}}
of sets if and only it absorbs each set individuality (that is, if and only if
A
{\displaystyle A}
absorbs
B
i
{\displaystyle B_{i}}
for every
i
=
1
,
…
,
n
{\displaystyle i=1,\ldots ,n}
). In particular, a set
A
{\displaystyle A}
is an absorbing subset of
X
{\displaystyle X}
if and only if it absorbs every finite subset of
X
.
{\displaystyle X.}
= For a set to be absorbing
=The unit ball of any normed vector space (or seminormed vector space) is absorbing.
More generally, if
X
{\displaystyle X}
is a topological vector space (TVS) then any neighborhood of the origin in
X
{\displaystyle X}
is absorbing in
X
.
{\displaystyle X.}
This fact is one of the primary motivations for defining the property "absorbing in
X
.
{\displaystyle X.}
"
Every superset of an absorbing set is absorbing. Consequently, the union of any family of (one or more) absorbing sets is absorbing. The intersection of finitely many absorbing subsets is once again an absorbing subset. However, the open balls
(
−
r
n
,
−
r
n
)
{\displaystyle (-r_{n},-r_{n})}
of radius
r
n
=
1
,
1
/
2
,
1
/
3
,
…
{\displaystyle r_{n}=1,1/2,1/3,\ldots }
are all absorbing in
X
:=
R
{\displaystyle X:=\mathbb {R} }
although their intersection
⋂
n
∈
N
(
−
1
/
n
,
1
/
n
)
=
{
0
}
{\displaystyle \bigcap _{n\in \mathbb {N} }(-1/n,1/n)=\{0\}}
is not absorbing.
If
D
≠
∅
{\displaystyle D\neq \varnothing }
is a disk (a convex and balanced subset) then
span
D
=
⋃
n
=
1
∞
n
D
;
{\displaystyle \operatorname {span} D={\textstyle \bigcup \limits _{n=1}^{\infty }}nD;}
and so in particular, a disk
D
≠
∅
{\displaystyle D\neq \varnothing }
is always an absorbing subset of
span
D
.
{\displaystyle \operatorname {span} D.}
Thus if
D
{\displaystyle D}
is a disk in
X
,
{\displaystyle X,}
then
D
{\displaystyle D}
is absorbing in
X
{\displaystyle X}
if and only if
span
D
=
X
.
{\displaystyle \operatorname {span} D=X.}
This conclusion is not guaranteed if the set
D
≠
∅
{\displaystyle D\neq \varnothing }
is balanced but not convex; for example, the union
D
{\displaystyle D}
of the
x
{\displaystyle x}
and
y
{\displaystyle y}
axes in
X
=
R
2
{\displaystyle X=\mathbb {R} ^{2}}
is a non-convex balanced set that is not absorbing in
span
D
=
R
2
.
{\displaystyle \operatorname {span} D=\mathbb {R} ^{2}.}
The image of an absorbing set under a surjective linear operator is again absorbing. The inverse image of an absorbing subset (of the codomain) under a linear operator is again absorbing (in the domain).
If
A
{\displaystyle A}
absorbing then the same is true of the symmetric set
⋂
|
u
|
=
1
u
A
⊆
A
.
{\displaystyle {\textstyle \bigcap \limits _{|u|=1}}uA\subseteq A.}
Auxiliary normed spaces
If
W
{\displaystyle W}
is convex and absorbing in
X
{\displaystyle X}
then the symmetric set
D
:=
⋂
|
u
|
=
1
u
W
{\displaystyle D:={\textstyle \bigcap \limits _{|u|=1}}uW}
will be convex and balanced (also known as an absolutely convex set or a disk) in addition to being absorbing in
X
.
{\displaystyle X.}
This guarantees that the Minkowski functional
p
D
:
X
→
R
{\displaystyle p_{D}:X\to \mathbb {R} }
of
D
{\displaystyle D}
will be a seminorm on
X
,
{\displaystyle X,}
thereby making
(
X
,
p
D
)
{\displaystyle \left(X,p_{D}\right)}
into a seminormed space that carries its canonical pseduometrizable topology. The set of scalar multiples
r
D
{\displaystyle rD}
as
r
{\displaystyle r}
ranges over
{
1
2
,
1
3
,
1
4
,
…
}
{\displaystyle \left\{{\tfrac {1}{2}},{\tfrac {1}{3}},{\tfrac {1}{4}},\ldots \right\}}
(or over any other set of non-zero scalars having
0
{\displaystyle 0}
as a limit point) forms a neighborhood basis of absorbing disks at the origin for this locally convex topology. If
X
{\displaystyle X}
is a topological vector space and if this convex absorbing subset
W
{\displaystyle W}
is also a bounded subset of
X
,
{\displaystyle X,}
then all this will also be true of the absorbing disk
D
:=
⋂
|
u
|
=
1
u
W
;
{\displaystyle D:={\textstyle \bigcap \limits _{|u|=1}}uW;}
if in addition
D
{\displaystyle D}
does not contain any non-trivial vector subspace then
p
D
{\displaystyle p_{D}}
will be a norm and
(
X
,
p
D
)
{\displaystyle \left(X,p_{D}\right)}
will form what is known as an auxiliary normed space. If this normed space is a Banach space then
D
{\displaystyle D}
is called a Banach disk.
Properties
Every absorbing set contains the origin.
If
D
{\displaystyle D}
is an absorbing disk in a vector space
X
{\displaystyle X}
then there exists an absorbing disk
E
{\displaystyle E}
in
X
{\displaystyle X}
such that
E
+
E
⊆
D
.
{\displaystyle E+E\subseteq D.}
If
A
{\displaystyle A}
is an absorbing subset of
X
{\displaystyle X}
then
X
=
⋃
n
=
1
∞
n
A
{\displaystyle X={\textstyle \bigcup \limits _{n=1}^{\infty }}nA}
and more generally,
X
=
⋃
n
=
1
∞
s
n
A
{\displaystyle X={\textstyle \bigcup \limits _{n=1}^{\infty }}s_{n}A}
for any sequence of scalars
s
1
,
s
2
,
…
{\displaystyle s_{1},s_{2},\ldots }
such that
|
s
n
|
→
∞
.
{\displaystyle \left|s_{n}\right|\to \infty .}
Consequently, if a topological vector space
X
{\displaystyle X}
is a non-meager subset of itself (or equivalently for TVSs, if it is a Baire space) and if
A
{\displaystyle A}
is a closed absorbing subset of
X
{\displaystyle X}
then
A
{\displaystyle A}
necessarily contains a non-empty open subset of
X
{\displaystyle X}
(in other words,
A
{\displaystyle A}
's topological interior will not be empty), which guarantees that
A
−
A
{\displaystyle A-A}
is a neighborhood of the origin in
X
.
{\displaystyle X.}
Every absorbing set is a total set, meaning that every absorbing subspace is dense.
See also
Algebraic interior – Generalization of topological interior
Absolutely convex set – Convex and balanced set
Balanced set – Construct in functional analysis
Bornivorous set – A set that can absorb any bounded subset
Bounded set (topological vector space) – Generalization of boundedness
Convex set – In geometry, set whose intersection with every line is a single line segment
Locally convex topological vector space – A vector space with a topology defined by convex open sets
Radial set
Star domain – Property of point sets in Euclidean spaces
Symmetric set – Property of group subsets (mathematics)
Topological vector space – Vector space with a notion of nearness
Notes
Proofs
Citations
References
Berberian, Sterling K. (1974). Lectures in Functional Analysis and Operator Theory. Graduate Texts in Mathematics. Vol. 15. New York: Springer. ISBN 978-0-387-90081-0. OCLC 878109401.
Bourbaki, Nicolas (1987) [1981]. Topological Vector Spaces: Chapters 1–5. Éléments de mathématique. Translated by Eggleston, H.G.; Madan, S. Berlin New York: Springer-Verlag. ISBN 3-540-13627-4. OCLC 17499190.
Nicolas, Bourbaki (2003). Topological vector spaces Chapter 1-5 (English Translation). New York: Springer-Verlag. p. I.7. ISBN 3-540-42338-9.
Conway, John (1990). A course in functional analysis. Graduate Texts in Mathematics. Vol. 96 (2nd ed.). New York: Springer-Verlag. ISBN 978-0-387-97245-9. OCLC 21195908.
Diestel, Joe (2008). The Metric Theory of Tensor Products: Grothendieck's Résumé Revisited. Vol. 16. Providence, R.I.: American Mathematical Society. ISBN 9781470424831. OCLC 185095773.
Dineen, Seán (1981). Complex Analysis in Locally Convex Spaces. North-Holland Mathematics Studies. Vol. 57. Amsterdam New York New York: North-Holland Pub. Co., Elsevier Science Pub. Co. ISBN 978-0-08-087168-4. OCLC 16549589.
Dunford, Nelson; Schwartz, Jacob T. (1988). Linear Operators. Pure and applied mathematics. Vol. 1. New York: Wiley-Interscience. ISBN 978-0-471-60848-6. OCLC 18412261.
Edwards, Robert E. (1995). Functional Analysis: Theory and Applications. New York: Dover Publications. ISBN 978-0-486-68143-6. OCLC 30593138.
Grothendieck, Alexander (1973). Topological Vector Spaces. Translated by Chaljub, Orlando. New York: Gordon and Breach Science Publishers. ISBN 978-0-677-30020-7. OCLC 886098.
Hogbe-Nlend, Henri (1977). Bornologies and Functional Analysis: Introductory Course on the Theory of Duality Topology-Bornology and its use in Functional Analysis. North-Holland Mathematics Studies. Vol. 26. Amsterdam New York New York: North Holland. ISBN 978-0-08-087137-0. MR 0500064. OCLC 316549583.
Hogbe-Nlend, Henri; Moscatelli, V. B. (1981). Nuclear and Conuclear Spaces: Introductory Course on Nuclear and Conuclear Spaces in the Light of the Duality "topology-bornology". North-Holland Mathematics Studies. Vol. 52. Amsterdam New York New York: North Holland. ISBN 978-0-08-087163-9. OCLC 316564345.
Husain, Taqdir; Khaleelulla, S. M. (1978). Barrelledness in Topological and Ordered Vector Spaces. Lecture Notes in Mathematics. Vol. 692. Berlin, New York, Heidelberg: Springer-Verlag. ISBN 978-3-540-09096-0. OCLC 4493665.
Jarchow, Hans (1981). Locally convex spaces. Stuttgart: B.G. Teubner. ISBN 978-3-519-02224-4. OCLC 8210342.
Keller, Hans (1974). Differential Calculus in Locally Convex Spaces. Lecture Notes in Mathematics. Vol. 417. Berlin New York: Springer-Verlag. ISBN 978-3-540-06962-1. OCLC 1103033.
Khaleelulla, S. M. (1982). Counterexamples in Topological Vector Spaces. Lecture Notes in Mathematics. Vol. 936. Berlin, Heidelberg, New York: Springer-Verlag. ISBN 978-3-540-11565-6. OCLC 8588370.
Jarchow, Hans (1981). Locally convex spaces. Stuttgart: B.G. Teubner. ISBN 978-3-519-02224-4. OCLC 8210342.
Köthe, Gottfried (1983) [1969]. Topological Vector Spaces I. Grundlehren der mathematischen Wissenschaften. Vol. 159. Translated by Garling, D.J.H. New York: Springer Science & Business Media. ISBN 978-3-642-64988-2. MR 0248498. OCLC 840293704.
Köthe, Gottfried (1979). Topological Vector Spaces II. Grundlehren der mathematischen Wissenschaften. Vol. 237. New York: Springer Science & Business Media. ISBN 978-0-387-90400-9. OCLC 180577972.
Narici, Lawrence; Beckenstein, Edward (2011). Topological Vector Spaces. Pure and applied mathematics (Second ed.). Boca Raton, FL: CRC Press. ISBN 978-1584888666. OCLC 144216834.
Pietsch, Albrecht (1979). Nuclear Locally Convex Spaces. Ergebnisse der Mathematik und ihrer Grenzgebiete. Vol. 66 (Second ed.). Berlin, New York: Springer-Verlag. ISBN 978-0-387-05644-9. OCLC 539541.
Robertson, Alex P.; Robertson, Wendy J. (1980). Topological Vector Spaces. Cambridge Tracts in Mathematics. Vol. 53. Cambridge England: Cambridge University Press. ISBN 978-0-521-29882-7. OCLC 589250.
Robertson, A.P.; W.J. Robertson (1964). Topological vector spaces. Cambridge Tracts in Mathematics. Vol. 53. Cambridge University Press. p. 4.
Rudin, Walter (1991). Functional Analysis. International Series in Pure and Applied Mathematics. Vol. 8 (Second ed.). New York, NY: McGraw-Hill Science/Engineering/Math. ISBN 978-0-07-054236-5. OCLC 21163277.
Thompson, Anthony C. (1996). Minkowski Geometry. Encyclopedia of Mathematics and Its Applications. Cambridge University Press. ISBN 0-521-40472-X.
Schaefer, Helmut H. (1971). Topological vector spaces. GTM. Vol. 3. New York: Springer-Verlag. p. 11. ISBN 0-387-98726-6.
Schaefer, Helmut H.; Wolff, Manfred P. (1999). Topological Vector Spaces. GTM. Vol. 8 (Second ed.). New York, NY: Springer New York Imprint Springer. ISBN 978-1-4612-7155-0. OCLC 840278135.
Schechter, Eric (1996). Handbook of Analysis and Its Foundations. San Diego, CA: Academic Press. ISBN 978-0-12-622760-4. OCLC 175294365.
Schaefer, H. H. (1999). Topological Vector Spaces. New York, NY: Springer New York Imprint Springer. ISBN 978-1-4612-7155-0. OCLC 840278135.
Swartz, Charles (1992). An introduction to Functional Analysis. New York: M. Dekker. ISBN 978-0-8247-8643-4. OCLC 24909067.
Trèves, François (2006) [1967]. Topological Vector Spaces, Distributions and Kernels. Mineola, N.Y.: Dover Publications. ISBN 978-0-486-45352-1. OCLC 853623322.
Wilansky, Albert (2013). Modern Methods in Topological Vector Spaces. Mineola, New York: Dover Publications, Inc. ISBN 978-0-486-49353-4. OCLC 849801114.
Wong, Yau-Chuen (1979). Schwartz Spaces, Nuclear Spaces, and Tensor Products. Lecture Notes in Mathematics. Vol. 726. Berlin New York: Springer-Verlag. ISBN 978-3-540-09513-2. OCLC 5126158.
Kata Kunci Pencarian:
- Kung Fu Panda 4
- The White Tiger (film 2021)
- The SpongeBob SquarePants Movie
- Ruang vektor topologis
- Saoirse Ronan
- Alpha (film)
- Filmografi Nicole Kidman
- Aria (manga)
- Sejarah Sarawak
- Undang-undang federal anti-propaganda homoseksual Rusia 2013
- Absorbing set
- Absorbing element
- Convex set
- Absorbing set (random dynamical systems)
- Bounded set (topological vector space)
- Balanced set
- Absorbing Markov chain
- Norm (mathematics)
- Topological vector space
- Absorbing Man