Definitions about filters in topological spaces #
In this file we define filters in topological spaces,
as well as other definitions that rely on Filter
s.
Main Definitions #
Neighborhoods filter #
nhds x
: the filter of neighborhoods of a point in a topological space, denoted by𝓝 x
in theTopology
scope. A set is called a neighborhood ofx
, if it includes an open set aroundx
.nhdsWithin x s
: the filter of neighborhoods of a point within a set, defined as𝓝 x ⊓ 𝓟 s
and denoted by𝓝[s] x
. We also introduce notation for some special setss
, see below.nhdsSet s
: the filter of neighborhoods of a set in a topological space, denoted by𝓝ˢ s
in theTopology
scope. A sett
is called a neighborhood ofs
, if it includes an open set that includess
.
Continuity at a point #
ContinuousAt f x
: a functionf
is continuous at a pointx
, if it tends to𝓝 (f x)
along𝓝 x
.ContinuousWithinAt f s x
: a functionf
is continuous within a sets
at a pointx
, if it tends to𝓝 (f x)
along𝓝[s] x
.ContinuousOn f s
: a functionf : X → Y
is continuous on a sets
, if it is continuous withins
at every point ofs
.
Limits #
lim f
: a limit of a filterf
in a nonempty topological space. If there existsx
such thatf ≤ 𝓝 x
, thenlim f
is one of such points, otherwise it isClassical.choice _
.In a Hausdorff topological space, the limit is unique if it exists.
Ultrafilter.lim f
: a limit of an ultrafilterf
, defined as the limit of(f : Filter X)
with a proof ofNonempty X
deduced from existence of an ultrafilter onX
.limUnder f g
: a limit of a filterf
along a functiong
, defined aslim (Filter.map g f)
.
Cluster points and accumulation points #
ClusterPt x F
: a pointx
is a cluster point of a filterF
, if𝓝 x
is not disjoint withF
.MapClusterPt x F u
: a pointx
is a cluster point of a functionu
along a filterF
, if it is a cluster point of the filterFilter.map u F
.AccPt x F
: a pointx
is an accumulation point of a filterF
, if𝓝[≠] x
is not disjoint withF
. Every accumulation point of a filter is its cluster point, but not vice versa.IsCompact s
: a sets
is compact if for every nontrivial filterf
that containss
, there existsa ∈ s
such that every set off
meets every neighborhood ofa
. Equivalently, a sets
is compact if for any cover ofs
by open sets, there exists a finite subcover.CompactSpace
,NoncompactSpace
: typeclasses saying that the whole space is a compact set / is not a compact set, respectively.WeaklyLocallyCompactSpace X
: typeclass saying that every point ofX
has a compact neighborhood.LocallyCompactSpace X
: typeclass saying that every point ofX
has a basis of compact neighborhoods. Every locally compact space is a weakly locally compact space. The reverse implication is true for R₁ (preregular) spaces.LocallyCompactPair X Y
: an auxiliary typeclass saying that for any continuous functionf : X → Y
, a pointx
, and a neighborhoods
off x
, there exists a compact neighborhoodK
ofx
such thatf
mapsK
tos
.Filter.cocompact
,Filter.coclosedCompact
: filters generated by complements to compact and closed compact sets, respectively.
Notations #
𝓝 x
: the filternhds x
of neighborhoods of a pointx
;𝓟 s
: the principal filter of a sets
, defined elsewhere;𝓝[s] x
: the filternhdsWithin x s
of neighborhoods of a pointx
within a sets
;𝓝[≤] x
: the filternhdsWithin x (Set.Iic x)
of left-neighborhoods ofx
;𝓝[≥] x
: the filternhdsWithin x (Set.Ici x)
of right-neighborhoods ofx
;𝓝[<] x
: the filternhdsWithin x (Set.Iio x)
of punctured left-neighborhoods ofx
;𝓝[>] x
: the filternhdsWithin x (Set.Ioi x)
of punctured right-neighborhoods ofx
;𝓝[≠] x
: the filternhdsWithin x {x}ᶜ
of punctured neighborhoods ofx
;𝓝ˢ s
: the filternhdsSet s
of neighborhoods of a set.
A set is called a neighborhood of x
if it contains an open set around x
. The set of all
neighborhoods of x
forms a filter, the neighborhood filter at x
, is here defined as the
infimum over the principal filters of all open sets containing x
.
Instances For
A set is called a neighborhood of x
if it contains an open set around x
. The set of all
neighborhoods of x
forms a filter, the neighborhood filter at x
, is here defined as the
infimum over the principal filters of all open sets containing x
.
Equations
- Topology.term𝓝 = Lean.ParserDescr.node `Topology.term𝓝 1024 (Lean.ParserDescr.symbol "𝓝")
Instances For
The "neighborhood within" filter. Elements of 𝓝[s] x
are sets containing the
intersection of s
and a neighborhood of x
.
Equations
- nhdsWithin x s = nhds x ⊓ Filter.principal s
Instances For
The "neighborhood within" filter. Elements of 𝓝[s] x
are sets containing the
intersection of s
and a neighborhood of x
.
Equations
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Instances For
Notation for the filter of punctured neighborhoods of a point.
Equations
- Topology.«term𝓝[≠]_» = Lean.ParserDescr.node `Topology.term𝓝[≠]_ 1022 (Lean.ParserDescr.binary `andthen (Lean.ParserDescr.symbol "𝓝[≠] ") (Lean.ParserDescr.cat `term 100))
Instances For
Pretty printer defined by notation3
command.
Equations
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Instances For
Pretty printer defined by notation3
command.
Equations
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Instances For
Notation for the filter of right neighborhoods of a point.
Equations
- Topology.«term𝓝[≥]_» = Lean.ParserDescr.node `Topology.term𝓝[≥]_ 1022 (Lean.ParserDescr.binary `andthen (Lean.ParserDescr.symbol "𝓝[≥] ") (Lean.ParserDescr.cat `term 100))
Instances For
Notation for the filter of left neighborhoods of a point.
Equations
- Topology.«term𝓝[≤]_» = Lean.ParserDescr.node `Topology.term𝓝[≤]_ 1022 (Lean.ParserDescr.binary `andthen (Lean.ParserDescr.symbol "𝓝[≤] ") (Lean.ParserDescr.cat `term 100))
Instances For
Pretty printer defined by notation3
command.
Equations
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Instances For
Pretty printer defined by notation3
command.
Equations
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Instances For
Notation for the filter of punctured right neighborhoods of a point.
Equations
- Topology.«term𝓝[>]_» = Lean.ParserDescr.node `Topology.term𝓝[>]_ 1022 (Lean.ParserDescr.binary `andthen (Lean.ParserDescr.symbol "𝓝[>] ") (Lean.ParserDescr.cat `term 100))
Instances For
Notation for the filter of punctured left neighborhoods of a point.
Equations
- Topology.«term𝓝[<]_» = Lean.ParserDescr.node `Topology.term𝓝[<]_ 1022 (Lean.ParserDescr.binary `andthen (Lean.ParserDescr.symbol "𝓝[<] ") (Lean.ParserDescr.cat `term 100))
Instances For
Pretty printer defined by notation3
command.
Equations
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Instances For
The filter of neighborhoods of a set in a topological space.
Equations
- Topology.«term𝓝ˢ» = Lean.ParserDescr.node `Topology.term𝓝ˢ 1024 (Lean.ParserDescr.symbol "𝓝ˢ")
Instances For
A function between topological spaces is continuous at a point x₀
if f x
tends to f x₀
when x
tends to x₀
.
Equations
- ContinuousAt f x = Filter.Tendsto f (nhds x) (nhds (f x))
Instances For
A function between topological spaces is continuous at a point x₀
within a subset s
if f x
tends to f x₀
when x
tends to x₀
while staying within s
.
Equations
- ContinuousWithinAt f s x = Filter.Tendsto f (nhdsWithin x s) (nhds (f x))
Instances For
A function between topological spaces is continuous on a subset s
when it's continuous at every point of s
within s
.
Equations
- ContinuousOn f s = ∀ x ∈ s, ContinuousWithinAt f s x
Instances For
x
specializes to y
(notation: x ⤳ y
) if either of the following equivalent properties
hold:
𝓝 x ≤ 𝓝 y
; this property is used as the definition;pure x ≤ 𝓝 y
; in other words, any neighbourhood ofy
containsx
;y ∈ closure {x}
;closure {y} ⊆ closure {x}
;- for any closed set
s
we havex ∈ s → y ∈ s
; - for any open set
s
we havey ∈ s → x ∈ s
; y
is a cluster point of the filterpure x = 𝓟 {x}
.
This relation defines a Preorder
on X
. If X
is a T₀ space, then this preorder is a partial
order. If X
is a T₁ space, then this partial order is trivial : x ⤳ y ↔ x = y
.
Instances For
x
specializes to y
(notation: x ⤳ y
) if either of the following equivalent properties
hold:
𝓝 x ≤ 𝓝 y
; this property is used as the definition;pure x ≤ 𝓝 y
; in other words, any neighbourhood ofy
containsx
;y ∈ closure {x}
;closure {y} ⊆ closure {x}
;- for any closed set
s
we havex ∈ s → y ∈ s
; - for any open set
s
we havey ∈ s → x ∈ s
; y
is a cluster point of the filterpure x = 𝓟 {x}
.
This relation defines a Preorder
on X
. If X
is a T₀ space, then this preorder is a partial
order. If X
is a T₁ space, then this partial order is trivial : x ⤳ y ↔ x = y
.
Equations
- «term_⤳_» = Lean.ParserDescr.trailingNode `term_⤳_ 300 300 (Lean.ParserDescr.binary `andthen (Lean.ParserDescr.symbol " ⤳ ") (Lean.ParserDescr.cat `term 301))
Instances For
Two points x
and y
in a topological space are Inseparable
if any of the following
equivalent properties hold:
𝓝 x = 𝓝 y
; we use this property as the definition;- for any open set
s
,x ∈ s ↔ y ∈ s
, seeinseparable_iff_open
; - for any closed set
s
,x ∈ s ↔ y ∈ s
, seeinseparable_iff_closed
; x ∈ closure {y}
andy ∈ closure {x}
, seeinseparable_iff_mem_closure
;closure {x} = closure {y}
, seeinseparable_iff_closure_eq
.
Equations
- Inseparable x y = (nhds x = nhds y)
Instances For
Specialization forms a preorder on the topological space.
Equations
- specializationPreorder X = Preorder.mk ⋯ ⋯ ⋯
Instances For
A setoid
version of Inseparable
, used to define the SeparationQuotient
.
Equations
- inseparableSetoid X = { r := Inseparable, iseqv := ⋯ }
Instances For
The quotient of a topological space by its inseparableSetoid
.
This quotient is guaranteed to be a T₀ space.
Equations
Instances For
If f
is a filter, then Filter.lim f
is a limit of the filter, if it exists.
Equations
- lim f = Classical.epsilon fun (x : X) => f ≤ nhds x
Instances For
If F
is an ultrafilter, then Filter.Ultrafilter.lim F
is a limit of the filter, if it exists.
Note that dot notation F.lim
can be used for F : Filter.Ultrafilter X
.
Instances For
A point x
is a cluster point of a filter F
if 𝓝 x ⊓ F ≠ ⊥
.
Also known as an accumulation point or a limit point, but beware that terminology varies.
This is not the same as asking 𝓝[≠] x ⊓ F ≠ ⊥
, which is called AccPt
in Mathlib.
See mem_closure_iff_clusterPt
in particular.
Instances For
A point x
is a cluster point of a sequence u
along a filter F
if it is a cluster point
of map u F
.
Equations
- MapClusterPt x F u = ClusterPt x (Filter.map u F)
Instances For
A set s
is compact if for every nontrivial filter f
that contains s
,
there exists a ∈ s
such that every set of f
meets every neighborhood of a
.
Equations
Instances For
Type class for compact spaces. Separation is sometimes included in the definition, especially in the French literature, but we do not include it here.
Instances
In a compact space, Set.univ
is a compact set.
X
is a noncompact topological space if it is not a compact space.
In a noncompact space,
Set.univ
is not a compact set.
Instances
In a noncompact space, Set.univ
is not a compact set.
We say that a topological space is a weakly locally compact space, if each point of this space admits a compact neighborhood.
Every point of a weakly locally compact space admits a compact neighborhood.
Instances
Every point of a weakly locally compact space admits a compact neighborhood.
There are various definitions of "locally compact space" in the literature,
which agree for Hausdorff spaces but not in general.
This one is the precise condition on X needed
for the evaluation map C(X, Y) × X → Y
to be continuous for all Y
when C(X, Y)
is given the compact-open topology.
See also WeaklyLocallyCompactSpace
, a typeclass that only assumes
that each point has a compact neighborhood.
In a locally compact space, every neighbourhood of every point contains a compact neighbourhood of that same point.
Instances
In a locally compact space, every neighbourhood of every point contains a compact neighbourhood of that same point.
We say that X
and Y
are a locally compact pair of topological spaces,
if for any continuous map f : X → Y
, a point x : X
, and a neighbourhood s ∈ 𝓝 (f x)
,
there exists a compact neighbourhood K ∈ 𝓝 x
such that f
maps K
to s
.
This is a technical assumption that appears in several theorems,
most notably in ContinuousMap.continuous_comp'
and ContinuousMap.continuous_eval
.
It is satisfied in two cases:
- if
X
is a locally compact topological space, for obvious reasons; - if
X
is a weakly locally compact topological space andY
is an R₁ space; this fact is a simple generalization of the theorem saying that a weakly locally compact R₁ topological space is locally compact.
- exists_mem_nhds_isCompact_mapsTo : ∀ {f : X → Y} {x : X} {s : Set Y}, Continuous f → s ∈ nhds (f x) → ∃ K ∈ nhds x, IsCompact K ∧ Set.MapsTo f K s
If
f : X → Y
is a continuous map in a locally compact pair of topological spaces ands : Set Y
is a neighbourhood off x
,x : X
, then there exists a compact neighbourhoodK
ofx
such thatf
mapsK
tos
.
Instances
If f : X → Y
is a continuous map in a locally compact pair of topological spaces
and s : Set Y
is a neighbourhood of f x
, x : X
,
then there exists a compact neighbourhood K
of x
such that f
maps K
to s
.
Filter.cocompact
is the filter generated by complements to compact sets.
Equations
- Filter.cocompact X = ⨅ (s : Set X), ⨅ (_ : IsCompact s), Filter.principal sᶜ
Instances For
Filter.coclosedCompact
is the filter generated by complements to closed compact sets.
In a Hausdorff space, this is the same as Filter.cocompact
.
Equations
- Filter.coclosedCompact X = ⨅ (s : Set X), ⨅ (_ : IsClosed s), ⨅ (_ : IsCompact s), Filter.principal sᶜ