Monoid actions continuous in the second variable #
In this file we define class ContinuousConstSMul
. We say ContinuousConstSMul Γ T
if
Γ
acts on T
and for each γ
, the map x ↦ γ • x
is continuous. (This differs from
ContinuousSMul
, which requires simultaneous continuity in both variables.)
Main definitions #
ContinuousConstSMul Γ T
: typeclass saying that the mapx ↦ γ • x
is continuous onT
;ProperlyDiscontinuousSMul
: says that the scalar multiplication(•) : Γ → T → T
is properly discontinuous, that is, for any pair of compact setsK, L
inT
, only finitely manyγ:Γ
moveK
to have nontrivial intersection withL
.Homeomorph.smul
: scalar multiplication by an element of a groupΓ
acting onT
is a homeomorphism ofT
.
Main results #
isOpenMap_quotient_mk'_mul
: The quotient map by a group action is open.t2Space_of_properlyDiscontinuousSMul_of_t2Space
: The quotient by a discontinuous group action of a locally compact t2 space is t2.
Tags #
Hausdorff, discrete group, properly discontinuous, quotient space
Class ContinuousConstSMul Γ T
says that the scalar multiplication (•) : Γ → T → T
is continuous in the second argument. We use the same class for all kinds of multiplicative
actions, including (semi)modules and algebras.
Note that both ContinuousConstSMul α α
and ContinuousConstSMul αᵐᵒᵖ α
are
weaker versions of ContinuousMul α
.
- continuous_const_smul : ∀ (γ : Γ), Continuous fun (x : T) => γ • x
The scalar multiplication
(•) : Γ → T → T
is continuous in the second argument.
Instances
The scalar multiplication (•) : Γ → T → T
is continuous in the second argument.
Class ContinuousConstVAdd Γ T
says that the additive action (+ᵥ) : Γ → T → T
is continuous in the second argument. We use the same class for all kinds of additive actions,
including (semi)modules and algebras.
Note that both ContinuousConstVAdd α α
and ContinuousConstVAdd αᵐᵒᵖ α
are
weaker versions of ContinuousVAdd α
.
- continuous_const_vadd : ∀ (γ : Γ), Continuous fun (x : T) => γ +ᵥ x
The additive action
(+ᵥ) : Γ → T → T
is continuous in the second argument.
Instances
The additive action (+ᵥ) : Γ → T → T
is continuous in the second argument.
Equations
- ⋯ = ⋯
Equations
- ⋯ = ⋯
If an additive action is central, then its right action is continuous when its left action is.
Equations
- ⋯ = ⋯
If a scalar is central, then its right action is continuous when its left action is.
Equations
- ⋯ = ⋯
Equations
- ⋯ = ⋯
Equations
- ⋯ = ⋯
Equations
- ⋯ = inst
Equations
- ⋯ = inst
Equations
- ⋯ = inst
Equations
- ⋯ = inst
Equations
- ⋯ = ⋯
Equations
- ⋯ = ⋯
Equations
- ⋯ = ⋯
Equations
- ⋯ = ⋯
Equations
- ⋯ = ⋯
Equations
- ⋯ = ⋯
The homeomorphism given by affine-addition by an element of an additive group Γ
acting on
T
is a homeomorphism from T
to itself.
Equations
- Homeomorph.vadd γ = { toEquiv := AddAction.toPerm γ, continuous_toFun := ⋯, continuous_invFun := ⋯ }
Instances For
The homeomorphism given by scalar multiplication by a given element of a group Γ
acting on
T
is a homeomorphism from T
to itself.
Equations
- Homeomorph.smul γ = { toEquiv := MulAction.toPerm γ, continuous_toFun := ⋯, continuous_invFun := ⋯ }
Instances For
Scalar multiplication by a non-zero element of a group with zero acting on α
is a
homeomorphism from α
onto itself.
Equations
- Homeomorph.smulOfNeZero c hc = Homeomorph.smul (Units.mk0 c hc)
Instances For
smul
is a closed map in the second argument.
The lemma that smul
is a closed map in the first argument (for a normed space over a complete
normed field) is isClosedMap_smul_left
in Analysis.NormedSpace.FiniteDimension
.
smul
is a closed map in the second argument.
The lemma that smul
is a closed map in the first argument (for a normed space over a complete
normed field) is isClosedMap_smul_left
in Analysis.NormedSpace.FiniteDimension
.
Class ProperlyDiscontinuousSMul Γ T
says that the scalar multiplication (•) : Γ → T → T
is properly discontinuous, that is, for any pair of compact sets K, L
in T
, only finitely many
γ:Γ
move K
to have nontrivial intersection with L
.
- finite_disjoint_inter_image : ∀ {K L : Set T}, IsCompact K → IsCompact L → {γ : Γ | (fun (x : T) => γ • x) '' K ∩ L ≠ ∅}.Finite
Given two compact sets
K
andL
,γ • K ∩ L
is nonempty for finitely manyγ
.
Instances
Given two compact sets K
and L
, γ • K ∩ L
is nonempty for finitely many γ
.
Class ProperlyDiscontinuousVAdd Γ T
says that the additive action (+ᵥ) : Γ → T → T
is properly discontinuous, that is, for any pair of compact sets K, L
in T
, only finitely many
γ:Γ
move K
to have nontrivial intersection with L
.
- finite_disjoint_inter_image : ∀ {K L : Set T}, IsCompact K → IsCompact L → {γ : Γ | (fun (x : T) => γ +ᵥ x) '' K ∩ L ≠ ∅}.Finite
Given two compact sets
K
andL
,γ +ᵥ K ∩ L
is nonempty for finitely manyγ
.
Instances
Given two compact sets K
and L
, γ +ᵥ K ∩ L
is nonempty for finitely many γ
.
A finite group action is always properly discontinuous.
Equations
- ⋯ = ⋯
A finite group action is always properly discontinuous.
Equations
- ⋯ = ⋯
The quotient map by a group action is open, i.e. the quotient by a group action is an open quotient.
The quotient map by a group action is open, i.e. the quotient by a group action is an open quotient.
The quotient by a discontinuous group action of a locally compact t2 space is t2.
Equations
- ⋯ = ⋯
The quotient by a discontinuous group action of a locally compact t2 space is t2.
Equations
- ⋯ = ⋯
The quotient of a second countable space by an additive group action is second countable.
The quotient of a second countable space by a group action is second countable.
Scalar multiplication preserves neighborhoods.