You can not select more than 25 topics Topics must start with a letter or number, can include dashes ('-') and can be up to 35 characters long.
rubin-lean4/Rubin/HomeoGroup.lean

258 lines
7.6 KiB

This file contains ambiguous Unicode characters!

This file contains ambiguous Unicode characters that may be confused with others in your current locale. If your use case is intentional and legitimate, you can safely ignore this warning. Use the Escape button to highlight these characters.

import Mathlib.Logic.Equiv.Defs
import Mathlib.Topology.Basic
import Mathlib.Topology.Homeomorph
import Mathlib.Topology.Algebra.ConstMulAction
import Rubin.LocallyDense
import Rubin.Topology
import Rubin.Support
import Rubin.RegularSupport
structure HomeoGroup (α : Type _) [TopologicalSpace α] extends Homeomorph α α
variable {α : Type _}
variable [TopologicalSpace α]
def HomeoGroup.coe : HomeoGroup α -> Homeomorph α α := HomeoGroup.toHomeomorph
def HomeoGroup.from : Homeomorph α α -> HomeoGroup α := HomeoGroup.mk
instance homeoGroup_coe : Coe (HomeoGroup α) (Homeomorph α α) where
coe := HomeoGroup.coe
instance homeoGroup_coe₂ : Coe (Homeomorph α α) (HomeoGroup α) where
coe := HomeoGroup.from
def HomeoGroup.toPerm : HomeoGroup α → Equiv.Perm α := fun g => g.coe.toEquiv
instance homeoGroup_coe_perm : Coe (HomeoGroup α) (Equiv.Perm α) where
coe := HomeoGroup.toPerm
@[simp]
theorem HomeoGroup.toPerm_def (g : HomeoGroup α) : g.coe.toEquiv = (g : Equiv.Perm α) := rfl
@[simp]
theorem HomeoGroup.mk_coe (g : HomeoGroup α) : HomeoGroup.mk (g.coe) = g := rfl
@[simp]
theorem HomeoGroup.eq_iff_coe_eq {f g : HomeoGroup α} : f.coe = g.coe ↔ f = g := by
constructor
{
intro f_eq_g
rw [<-HomeoGroup.mk_coe f]
rw [f_eq_g]
simp
}
{
intro f_eq_g
unfold HomeoGroup.coe
rw [f_eq_g]
}
@[simp]
theorem HomeoGroup.from_toHomeomorph (m : Homeomorph α α) : (HomeoGroup.from m).toHomeomorph = m := rfl
instance homeoGroup_one : One (HomeoGroup α) where
one := HomeoGroup.from (Homeomorph.refl α)
theorem HomeoGroup.one_def : (1 : HomeoGroup α) = (Homeomorph.refl α : HomeoGroup α) := rfl
instance homeoGroup_inv : Inv (HomeoGroup α) where
inv := fun g => HomeoGroup.from (g.coe.symm)
@[simp]
theorem HomeoGroup.inv_def (g : HomeoGroup α) : (Homeomorph.symm g.coe : HomeoGroup α) = g⁻¹ := rfl
theorem HomeoGroup.coe_inv {g : HomeoGroup α} : HomeoGroup.coe (g⁻¹) = (HomeoGroup.coe g).symm := rfl
instance homeoGroup_mul : Mul (HomeoGroup α) where
mul := fun a b => ⟨b.toHomeomorph.trans a.toHomeomorph⟩
theorem HomeoGroup.coe_mul {f g : HomeoGroup α} : HomeoGroup.coe (f * g) = (HomeoGroup.coe g).trans (HomeoGroup.coe f) := rfl
@[simp]
theorem HomeoGroup.mul_def (f g : HomeoGroup α) : HomeoGroup.from ((HomeoGroup.coe g).trans (HomeoGroup.coe f)) = f * g := rfl
instance homeoGroup_group : Group (HomeoGroup α) where
mul_assoc := by
intro a b c
rw [<-HomeoGroup.eq_iff_coe_eq]
repeat rw [HomeoGroup_coe_mul]
rfl
mul_one := by
intro a
rw [<-HomeoGroup.eq_iff_coe_eq]
rw [HomeoGroup.coe_mul]
rfl
one_mul := by
intro a
rw [<-HomeoGroup.eq_iff_coe_eq]
rw [HomeoGroup.coe_mul]
rfl
mul_left_inv := by
intro a
rw [<-HomeoGroup.eq_iff_coe_eq]
rw [HomeoGroup.coe_mul]
rw [HomeoGroup.coe_inv]
simp
rfl
/--
The HomeoGroup trivially has a continuous and faithful `MulAction` on the underlying topology `α`.
--/
instance homeoGroup_smul₁ : SMul (HomeoGroup α) α where
smul := fun g x => g.toFun x
@[simp]
theorem HomeoGroup.smul₁_def (f : HomeoGroup α) (x : α) : f.toFun x = f • x := rfl
@[simp]
theorem HomeoGroup.smul₁_def' (f : HomeoGroup α) (x : α) : f.toHomeomorph x = f • x := rfl
@[simp]
theorem HomeoGroup.coe_toFun_eq_smul₁ (f : HomeoGroup α) (x : α) : FunLike.coe (HomeoGroup.coe f) x = f • x := rfl
instance homeoGroup_mulAction₁ : MulAction (HomeoGroup α) α where
one_smul := by
intro x
rfl
mul_smul := by
intro f g x
rfl
instance homeoGroup_mulAction₁_continuous : ContinuousConstSMul (HomeoGroup α) α where
continuous_const_smul := by
intro h
constructor
intro S S_open
conv => {
congr; ext
congr; ext
rw [<-HomeoGroup.smul₁_def']
}
simp only [Homeomorph.isOpen_preimage]
exact S_open
instance homeoGroup_mulAction₁_faithful : FaithfulSMul (HomeoGroup α) α where
eq_of_smul_eq_smul := by
intro f g hyp
rw [<-HomeoGroup.eq_iff_coe_eq]
ext x
simp
exact hyp x
theorem HomeoGroup.smulImage_eq_image (g : HomeoGroup α) (S : Set α) :
g •'' S = ⇑g.toHomeomorph '' S := rfl
section FromContinuousConstSMul
variable {G : Type _} [Group G]
variable [MulAction G α] [ContinuousConstSMul G α]
/--
`fromContinuous` is a structure-preserving transformation from a continuous `MulAction` to a `HomeoGroup`
--/
def HomeoGroup.fromContinuous (α : Type _) [TopologicalSpace α] [MulAction G α] [ContinuousConstSMul G α]
(g : G) : HomeoGroup α :=
HomeoGroup.from (Homeomorph.smul g)
@[simp]
theorem HomeoGroup.fromContinuous_def (g : G) :
HomeoGroup.from (Homeomorph.smul g) = HomeoGroup.fromContinuous α g := rfl
@[simp]
theorem HomeoGroup.fromContinuous_smul (g : G) :
∀ x : α, (HomeoGroup.fromContinuous α g) • x = g • x :=
by
intro x
unfold fromContinuous
rw [<-HomeoGroup.smul₁_def', HomeoGroup.from_toHomeomorph]
unfold Homeomorph.smul
simp
theorem HomeoGroup.fromContinuous_one :
HomeoGroup.fromContinuous α (1 : G) = (1 : HomeoGroup α) :=
by
apply FaithfulSMul.eq_of_smul_eq_smul (α := α)
simp
theorem HomeoGroup.fromContinuous_mul (g h : G):
(HomeoGroup.fromContinuous α g) * (HomeoGroup.fromContinuous α h) = (HomeoGroup.fromContinuous α (g * h)) :=
by
apply FaithfulSMul.eq_of_smul_eq_smul (α := α)
intro x
rw [mul_smul]
simp
rw [mul_smul]
theorem HomeoGroup.fromContinuous_inv (g : G):
HomeoGroup.fromContinuous α g⁻¹ = (HomeoGroup.fromContinuous α g)⁻¹ :=
by
apply FaithfulSMul.eq_of_smul_eq_smul (α := α)
intro x
group_action
rw [mul_smul]
simp
theorem HomeoGroup.fromContinuous_eq_iff [FaithfulSMul G α] (g h : G):
(HomeoGroup.fromContinuous α g) = (HomeoGroup.fromContinuous α h) ↔ g = h :=
by
constructor
· intro cont_eq
apply FaithfulSMul.eq_of_smul_eq_smul (α := α)
intro x
rw [<-HomeoGroup.fromContinuous_smul g]
rw [cont_eq]
simp
· tauto
@[simp]
theorem HomeoGroup.fromContinuous_support (g : G) :
Rubin.Support α (HomeoGroup.fromContinuous α g) = Rubin.Support α g :=
by
ext x
repeat rw [Rubin.mem_support]
rw [<-HomeoGroup.smul₁_def, <-HomeoGroup.fromContinuous_def]
rw [HomeoGroup.from_toHomeomorph]
rw [Homeomorph.smul]
simp only [Equiv.toFun_as_coe, MulAction.toPerm_apply]
@[simp]
theorem HomeoGroup.fromContinuous_regularSupport (g : G) :
Rubin.RegularSupport α (HomeoGroup.fromContinuous α g) = Rubin.RegularSupport α g :=
by
unfold Rubin.RegularSupport
rw [HomeoGroup.fromContinuous_support]
@[simp]
theorem HomeoGroup.fromContinuous_smulImage (g : G) (V : Set α) :
(HomeoGroup.fromContinuous α g) •'' V = g •'' V :=
by
repeat rw [Rubin.smulImage_def]
simp
def HomeoGroup.fromContinuous_embedding (α : Type _) [TopologicalSpace α] [MulAction G α] [ContinuousConstSMul G α] [FaithfulSMul G α]: G ↪ (HomeoGroup α) where
toFun := fun (g : G) => HomeoGroup.fromContinuous α g
inj' := by
intro g h fromCont_eq
simp at fromCont_eq
apply FaithfulSMul.eq_of_smul_eq_smul (α := α)
intro x
rw [<-fromContinuous_smul, fromCont_eq, fromContinuous_smul]
@[simp]
theorem HomeoGroup.fromContinuous_embedding_toFun [FaithfulSMul G α] (g : G):
HomeoGroup.fromContinuous_embedding α g = HomeoGroup.fromContinuous α g := rfl
def HomeoGroup.fromContinuous_monoidHom (α : Type _) [TopologicalSpace α] [MulAction G α] [ContinuousConstSMul G α] [FaithfulSMul G α]: G →* (HomeoGroup α) where
toFun := fun (g : G) => HomeoGroup.fromContinuous α g
map_one' := by
simp
rw [fromContinuous_one]
map_mul' := by
simp
intros
rw [fromContinuous_mul]
end FromContinuousConstSMul