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@ -2,6 +2,7 @@ import Mathlib.Logic.Equiv.Defs
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import Mathlib.Topology.Basic
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import Mathlib.Topology.Basic
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import Mathlib.Topology.Homeomorph
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import Mathlib.Topology.Homeomorph
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import Rubin.LocallyDense
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import Rubin.Topology
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import Rubin.Topology
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import Rubin.RegularSupport
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import Rubin.RegularSupport
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@ -141,6 +142,8 @@ instance homeoGroup_mulAction₁_faithful : FaithfulSMul (HomeoGroup α) α wher
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namespace Rubin
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namespace Rubin
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section AssociatedPoset.Prelude
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variable {α : Type _}
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variable {α : Type _}
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variable [TopologicalSpace α]
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variable [TopologicalSpace α]
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variable [DecidableEq α]
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variable [DecidableEq α]
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@ -168,75 +171,9 @@ def AssociatedPosetSeed.val (S : AssociatedPosetSeed α) : Set α := AssociatedP
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theorem AssociatedPosetSeed.val_def (S : AssociatedPosetSeed α) : S.val = AssociatedPosetElem S.seed := rfl
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theorem AssociatedPosetSeed.val_def (S : AssociatedPosetSeed α) : S.val = AssociatedPosetElem S.seed := rfl
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/--
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A partially-ordered set, associated to Rubin's proof.
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Any element in that set is made up of a `seed`,
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such that `val = AssociatedPosetElem seed` and `Set.Nonempty val`.
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Actions on this set are first defined in terms of `AssociatedPosetSeed`,
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as the proofs otherwise get hairy with `Exists.choose`.
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--/
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structure AssociatedPoset (α : Type _) [TopologicalSpace α] where
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val : Set α
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val_has_seed : ∃ po_seed : AssociatedPosetSeed α, po_seed.val = val
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theorem AssociatedPoset.eq_iff_val_eq (S T : AssociatedPoset α) : S = T ↔ S.val = T.val := by
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rw [mk.injEq]
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def AssociatedPoset.fromSeed (seed : AssociatedPosetSeed α) : AssociatedPoset α := ⟨
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seed.val,
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⟨seed, seed.val_def⟩
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⟩
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noncomputable def AssociatedPoset.full_seed (S : AssociatedPoset α) : AssociatedPosetSeed α :=
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(Exists.choose S.val_has_seed)
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noncomputable def AssociatedPoset.seed (S : AssociatedPoset α) : Finset (HomeoGroup α) :=
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S.full_seed.seed
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@[simp]
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theorem AssociatedPoset.full_seed_seed (S : AssociatedPoset α) : S.full_seed.seed = S.seed := rfl
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@[simp]
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theorem AssociatedPoset.fromSeed_val (seed : AssociatedPosetSeed α) :
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(AssociatedPoset.fromSeed seed).val = seed.val :=
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by
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unfold fromSeed
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simp
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@[simp]
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theorem AssociatedPoset.val_from_seed (S : AssociatedPoset α) : AssociatedPosetElem S.seed = S.val := by
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unfold seed full_seed
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rw [<-AssociatedPosetSeed.val_def]
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rw [Exists.choose_spec S.val_has_seed]
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@[simp]
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theorem AssociatedPoset.val_from_seed₂ (S : AssociatedPoset α) : S.full_seed.val = S.val := by
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unfold full_seed
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rw [AssociatedPosetSeed.val_def]
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nth_rw 2 [<-AssociatedPoset.val_from_seed]
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unfold seed full_seed
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rfl
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-- Allows one to prove properties of AssociatedPoset without jumping through `Exists.choose`-shaped hoops
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theorem AssociatedPoset.prop_from_val {p : Set α → Prop}
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(any_seed : ∀ po_seed : AssociatedPosetSeed α, p po_seed.val) :
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∀ (S : AssociatedPoset α), p S.val :=
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by
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intro S
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rw [<-AssociatedPoset.val_from_seed]
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have res := any_seed S.full_seed
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rw [AssociatedPoset.val_from_seed₂] at res
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rw [AssociatedPoset.val_from_seed]
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exact res
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@[simp]
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@[simp]
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theorem AssociatedPosetSeed.nonempty (S : AssociatedPosetSeed α) : Set.Nonempty S.val := S.val_nonempty
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theorem AssociatedPosetSeed.nonempty (S : AssociatedPosetSeed α) : Set.Nonempty S.val := S.val_nonempty
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@[simp]
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theorem AssociatedPoset.nonempty : ∀ (S : AssociatedPoset α), Set.Nonempty S.val :=
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AssociatedPoset.prop_from_val AssociatedPosetSeed.nonempty
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@[simp]
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@[simp]
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theorem AssociatedPosetSeed.regular (S : AssociatedPosetSeed α) : Regular S.val := by
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theorem AssociatedPosetSeed.regular (S : AssociatedPosetSeed α) : Regular S.val := by
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rw [S.val_def]
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rw [S.val_def]
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@ -254,10 +191,6 @@ theorem AssociatedPosetSeed.regular (S : AssociatedPosetSeed α) : Regular S.val
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rw [<-Heq]
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rw [<-Heq]
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exact regularSupport_regular α g
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exact regularSupport_regular α g
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@[simp]
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theorem AssociatedPoset.regular : ∀ (S : AssociatedPoset α), Regular S.val :=
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AssociatedPoset.prop_from_val AssociatedPosetSeed.regular
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lemma AssociatedPosetElem.mul_seed (seed : Finset (HomeoGroup α)) [DecidableEq (HomeoGroup α)] (f : HomeoGroup α):
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lemma AssociatedPosetElem.mul_seed (seed : Finset (HomeoGroup α)) [DecidableEq (HomeoGroup α)] (f : HomeoGroup α):
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AssociatedPosetElem (Finset.image (fun g => f * g * f⁻¹) seed) = f •'' AssociatedPosetElem seed :=
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AssociatedPosetElem (Finset.image (fun g => f * g * f⁻¹) seed) = f •'' AssociatedPosetElem seed :=
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by
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by
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@ -298,6 +231,7 @@ by
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rw [<-AssociatedPosetElem.mul_seed]
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rw [<-AssociatedPosetElem.mul_seed]
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rw [AssociatedPosetSeed.smul_seed]
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rw [AssociatedPosetSeed.smul_seed]
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-- We define a "preliminary" group action from `HomeoGroup α` to `AssociatedPosetSeed`
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instance homeoGroup_mulAction₂ : MulAction (HomeoGroup α) (AssociatedPosetSeed α) where
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instance homeoGroup_mulAction₂ : MulAction (HomeoGroup α) (AssociatedPosetSeed α) where
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one_smul := by
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one_smul := by
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intro S
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intro S
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@ -313,57 +247,207 @@ instance homeoGroup_mulAction₂ : MulAction (HomeoGroup α) (AssociatedPosetSee
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simp
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simp
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group
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group
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def AssociatedPoset.smul_from_seed (f : HomeoGroup α) (S : AssociatedPoset α) : AssociatedPoset α :=
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end AssociatedPoset.Prelude
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AssociatedPoset.fromSeed (f • S.full_seed)
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/--
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A partially-ordered set, associated to Rubin's proof.
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Any element in that set is made up of a `seed`,
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such that `val = AssociatedPosetElem seed` and `Set.Nonempty val`.
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Actions on this set are first defined in terms of `AssociatedPosetSeed`,
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as the proofs otherwise get hairy with a bunch of `Exists.choose` appearing.
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--/
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structure AssociatedPoset (α : Type _) [TopologicalSpace α] where
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val : Set α
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val_has_seed : ∃ po_seed : AssociatedPosetSeed α, po_seed.val = val
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namespace AssociatedPoset
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variable {α : Type _}
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variable [TopologicalSpace α]
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variable [DecidableEq α]
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theorem eq_iff_val_eq (S T : AssociatedPoset α) : S = T ↔ S.val = T.val := by
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rw [mk.injEq]
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def fromSeed (seed : AssociatedPosetSeed α) : AssociatedPoset α := ⟨
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seed.val,
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⟨seed, seed.val_def⟩
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⟩
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noncomputable def full_seed (S : AssociatedPoset α) : AssociatedPosetSeed α :=
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(Exists.choose S.val_has_seed)
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noncomputable def seed (S : AssociatedPoset α) : Finset (HomeoGroup α) :=
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S.full_seed.seed
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@[simp]
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theorem full_seed_seed (S : AssociatedPoset α) : S.full_seed.seed = S.seed := rfl
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@[simp]
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theorem fromSeed_val (seed : AssociatedPosetSeed α) :
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(fromSeed seed).val = seed.val :=
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by
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unfold fromSeed
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simp
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@[simp]
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theorem val_from_seed (S : AssociatedPoset α) : AssociatedPosetElem S.seed = S.val := by
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unfold seed full_seed
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rw [<-AssociatedPosetSeed.val_def]
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rw [Exists.choose_spec S.val_has_seed]
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@[simp]
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theorem val_from_seed₂ (S : AssociatedPoset α) : S.full_seed.val = S.val := by
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unfold full_seed
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rw [AssociatedPosetSeed.val_def]
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nth_rw 2 [<-val_from_seed]
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unfold seed full_seed
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rfl
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-- Allows one to prove properties of AssociatedPoset without jumping through `Exists.choose`-shaped hoops
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theorem prop_from_val {p : Set α → Prop}
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(any_seed : ∀ po_seed : AssociatedPosetSeed α, p po_seed.val) :
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∀ (S : AssociatedPoset α), p S.val :=
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by
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intro S
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rw [<-val_from_seed]
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have res := any_seed S.full_seed
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rw [val_from_seed₂] at res
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rw [val_from_seed]
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exact res
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@[simp]
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theorem nonempty : ∀ (S : AssociatedPoset α), Set.Nonempty S.val :=
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prop_from_val AssociatedPosetSeed.nonempty
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@[simp]
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theorem regular : ∀ (S : AssociatedPoset α), Regular S.val :=
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prop_from_val AssociatedPosetSeed.regular
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variable [DecidableEq (HomeoGroup α)]
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-- TODO: use smulImage instead?
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instance homeoGroup_smul₃ : SMul (HomeoGroup α) (AssociatedPoset α) where
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instance homeoGroup_smul₃ : SMul (HomeoGroup α) (AssociatedPoset α) where
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smul := AssociatedPoset.smul_from_seed
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smul := fun f S => ⟨
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f •'' S.val,
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by
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use f • S.full_seed
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rw [AssociatedPosetSeed.smul_val']
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simp
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⟩
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theorem AssociatedPoset.smul_fromSeed (f : HomeoGroup α) (S : AssociatedPoset α) :
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theorem smul_val (f : HomeoGroup α) (S : AssociatedPoset α) :
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f • S = AssociatedPoset.fromSeed (f • S.full_seed) := rfl
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(f • S).val = f •'' S.val := rfl
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theorem AssociatedPoset.smul_seed' (f : HomeoGroup α) (S : AssociatedPoset α) (seed : Finset (HomeoGroup α)) :
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theorem smul_seed' (f : HomeoGroup α) (S : AssociatedPoset α) (seed : Finset (HomeoGroup α)) :
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S.val = AssociatedPosetElem seed →
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S.val = AssociatedPosetElem seed →
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(f • S).val = AssociatedPosetElem (Finset.image (fun g => f * g * f⁻¹) seed) :=
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(f • S).val = AssociatedPosetElem (Finset.image (fun g => f * g * f⁻¹) seed) :=
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by
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by
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intro S_val_eq
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intro S_val_eq
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rw [smul_val]
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rw [AssociatedPosetElem.mul_seed]
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rw [S_val_eq]
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rw [AssociatedPoset.smul_fromSeed]
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theorem smul_seed (f : HomeoGroup α) (S : AssociatedPoset α) :
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rw [AssociatedPoset.fromSeed_val]
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rw [AssociatedPosetSeed.smul_val]
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repeat rw [AssociatedPosetElem.mul_seed]
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rw [<-S_val_eq]
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rw [AssociatedPoset.full_seed_seed]
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rw [<-AssociatedPoset.val_from_seed]
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theorem AssociatedPoset.smul_seed (f : HomeoGroup α) (S : AssociatedPoset α) :
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(f • S).val = AssociatedPosetElem (Finset.image (fun g => f * g * f⁻¹) S.seed) :=
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(f • S).val = AssociatedPosetElem (Finset.image (fun g => f * g * f⁻¹) S.seed) :=
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by
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by
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apply AssociatedPoset.smul_seed'
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apply smul_seed'
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symm
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symm
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exact AssociatedPoset.val_from_seed S
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exact val_from_seed S
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theorem AssociatedPoset.smul_val (f : HomeoGroup α) (S : AssociatedPoset α) :
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(f • S).val = f •'' S.val :=
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by
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rw [AssociatedPoset.smul_fromSeed]
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rw [AssociatedPoset.fromSeed_val]
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rw [<-AssociatedPoset.val_from_seed₂]
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exact AssociatedPosetSeed.smul_val' _ _
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-- Note: we could potentially implement MulActionHom
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instance homeoGroup_mulAction₃ : MulAction (HomeoGroup α) (AssociatedPoset α) where
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instance homeoGroup_mulAction₃ : MulAction (HomeoGroup α) (AssociatedPoset α) where
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one_smul := by
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one_smul := by
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intro S
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intro S
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rw [AssociatedPoset.eq_iff_val_eq]
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rw [eq_iff_val_eq]
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repeat rw [AssociatedPoset.smul_val]
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repeat rw [smul_val]
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rw [one_smulImage]
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rw [one_smulImage]
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mul_smul := by
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mul_smul := by
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intro S f g
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intro S f g
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rw [AssociatedPoset.eq_iff_val_eq]
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rw [eq_iff_val_eq]
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repeat rw [AssociatedPoset.smul_val]
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repeat rw [smul_val]
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rw [smulImage_mul]
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rw [smulImage_mul]
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instance associatedPoset_le : LE (AssociatedPoset α) where
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le := fun S T => S.val ⊆ T.val
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theorem le_def (S T : AssociatedPoset α) : S ≤ T ↔ S.val ⊆ T.val := by
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rw [iff_eq_eq]
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rfl
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instance associatedPoset_partialOrder : PartialOrder (AssociatedPoset α) where
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le_refl := fun S => (le_def S S).mpr (le_refl S.val)
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le_trans := fun S T U S_le_T S_le_U => (le_def S U).mpr (le_trans
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((le_def _ _).mp S_le_T)
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((le_def _ _).mp S_le_U)
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)
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le_antisymm := by
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intro S T S_le_T T_le_S
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rw [le_def] at S_le_T
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rw [le_def] at T_le_S
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rw [eq_iff_val_eq]
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apply le_antisymm <;> assumption
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theorem smul_mono {S T : AssociatedPoset α} (f : HomeoGroup α) (S_le_T : S ≤ T) :
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f • S ≤ f • T :=
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by
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rw [le_def]
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repeat rw [smul_val]
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apply smulImage_mono
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assumption
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end AssociatedPoset
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section Other
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theorem homeoGroup_rigidStabilizer_subset_iff {α : Type _} [TopologicalSpace α]
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[h_lm : LocallyMoving (HomeoGroup α) α]
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{U V : Set α} (U_reg : Regular U) (V_reg : Regular V):
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U ⊆ V ↔ RigidStabilizer (HomeoGroup α) U ≤ RigidStabilizer (HomeoGroup α) V :=
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by
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constructor
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exact rigidStabilizer_mono
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intro rist_ss
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by_contra U_not_ss_V
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let W := U \ closure V
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have W_nonempty : Set.Nonempty W := by
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by_contra W_empty
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apply U_not_ss_V
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apply subset_from_diff_closure_eq_empty
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· assumption
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· exact U_reg.isOpen
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· rw [Set.not_nonempty_iff_eq_empty] at W_empty
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exact W_empty
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have W_ss_U : W ⊆ U := by
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simp
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exact Set.diff_subset _ _
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have W_open : IsOpen W := by
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unfold_let
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rw [Set.diff_eq_compl_inter]
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apply IsOpen.inter
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simp
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exact U_reg.isOpen
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have ⟨f, f_in_ristW, f_ne_one⟩ := h_lm.get_nontrivial_rist_elem W_open W_nonempty
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have f_in_ristU : f ∈ RigidStabilizer (HomeoGroup α) U := by
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exact rigidStabilizer_mono W_ss_U f_in_ristW
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have f_notin_ristV : f ∉ RigidStabilizer (HomeoGroup α) V := by
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apply rigidStabilizer_compl f_ne_one
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apply rigidStabilizer_mono _ f_in_ristW
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calc
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W = U ∩ (closure V)ᶜ := by unfold_let; rw [Set.diff_eq_compl_inter, Set.inter_comm]
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_ ⊆ (closure V)ᶜ := Set.inter_subset_right _ _
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_ ⊆ Vᶜ := by
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rw [Set.compl_subset_compl]
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exact subset_closure
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exact f_notin_ristV (rist_ss f_in_ristU)
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end Other
|
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end Rubin
|
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end Rubin
|
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