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@ -17,19 +17,16 @@ import Mathlib.Topology.Separation
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import Mathlib.Topology.Homeomorph
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import Mathlib.Topology.Homeomorph
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import Rubin.Tactic
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import Rubin.Tactic
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import Rubin.MulActionExt
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import Rubin.SmulImage
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import Rubin.Support
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#align_import rubin
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#align_import rubin
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namespace Rubin
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namespace Rubin
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open Rubin.Tactic
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open Rubin.Tactic
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-- TODO: remove
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-- TODO: find a home
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--@[simp]
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theorem GroupActionExt.smul_smul' {G α : Type _} [Group G] [MulAction G α] {g h : G} {x : α} :
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g • h • x = (g * h) • x :=
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smul_smul g h x
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#align smul_smul' Rubin.GroupActionExt.smul_smul'
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theorem equiv_congr_ne {ι ι' : Type _} (e : ι ≃ ι') {x y : ι} : x ≠ y → e x ≠ e y :=
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theorem equiv_congr_ne {ι ι' : Type _} (e : ι ≃ ι') {x y : ι} : x ≠ y → e x ≠ e y :=
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by
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by
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intro x_ne_y
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intro x_ne_y
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@ -38,14 +35,6 @@ theorem equiv_congr_ne {ι ι' : Type _} (e : ι ≃ ι') {x y : ι} : x ≠ y
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convert congr_arg e.symm h <;> simp only [Equiv.symm_apply_apply]
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convert congr_arg e.symm h <;> simp only [Equiv.symm_apply_apply]
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#align equiv.congr_ne Rubin.equiv_congr_ne
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#align equiv.congr_ne Rubin.equiv_congr_ne
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-- this definitely should be added to mathlib!
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@[simp, to_additive]
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theorem GroupActionExt.subgroup_mk_smul {G α : Type _} [Group G] [MulAction G α]
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{S : Subgroup G} {g : G} (hg : g ∈ S) (a : α) : (⟨g, hg⟩ : S) • a = g • a :=
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rfl
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#align Subgroup.mk_smul Rubin.GroupActionExt.subgroup_mk_smul
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#align add_subgroup.mk_vadd AddSubgroup.mk_vadd
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----------------------------------------------------------------
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----------------------------------------------------------------
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section Rubin
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section Rubin
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@ -54,9 +43,6 @@ variable {G α β : Type _} [Group G]
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----------------------------------------------------------------
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----------------------------------------------------------------
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section Groups
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section Groups
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theorem bracket_mul {f g : G} : ⁅f, g⁆ = f * g * f⁻¹ * g⁻¹ := by tauto
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#align bracket_mul Rubin.bracket_mul
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def is_algebraically_disjoint (f g : G) :=
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def is_algebraically_disjoint (f g : G) :=
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∀ h : G,
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∀ h : G,
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¬Commute f h →
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¬Commute f h →
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@ -78,308 +64,11 @@ theorem orbit_bot (G : Type _) [Group G] [MulAction G α] (p : α) :
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rw [MulAction.mem_orbit_iff]
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rw [MulAction.mem_orbit_iff]
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constructor
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constructor
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· rintro ⟨⟨_, g_bot⟩, g_to_x⟩
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· rintro ⟨⟨_, g_bot⟩, g_to_x⟩
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rw [← g_to_x, Set.mem_singleton_iff, Rubin.GroupActionExt.subgroup_mk_smul]
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rw [← g_to_x, Set.mem_singleton_iff, Subgroup.mk_smul]
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exact (Subgroup.mem_bot.mp g_bot).symm ▸ one_smul _ _
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exact (Subgroup.mem_bot.mp g_bot).symm ▸ one_smul _ _
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exact fun h => ⟨1, Eq.trans (one_smul _ p) (Set.mem_singleton_iff.mp h).symm⟩
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exact fun h => ⟨1, Eq.trans (one_smul _ p) (Set.mem_singleton_iff.mp h).symm⟩
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#align orbit_bot Rubin.orbit_bot
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#align orbit_bot Rubin.orbit_bot
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--------------------------------
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section SmulImage
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theorem GroupActionExt.smul_congr (g : G) {x y : α} (h : x = y) : g • x = g • y :=
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congr_arg ((· • ·) g) h
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#align smul_congr Rubin.GroupActionExt.smul_congr
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theorem GroupActionExt.smul_eq_iff_inv_smul_eq {x : α} {g : G} : g • x = x ↔ g⁻¹ • x = x :=
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⟨fun h => (Rubin.GroupActionExt.smul_congr g⁻¹ h).symm.trans (inv_smul_smul g x), fun h =>
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(Rubin.GroupActionExt.smul_congr g h).symm.trans (smul_inv_smul g x)⟩
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#align smul_eq_iff_inv_smul_eq Rubin.GroupActionExt.smul_eq_iff_inv_smul_eq
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theorem GroupActionExt.smul_pow_eq_of_smul_eq {x : α} {g : G} (n : ℕ) :
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g • x = x → g ^ n • x = x := by
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induction n with
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| zero => simp only [pow_zero, one_smul, eq_self_iff_true, imp_true_iff]
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| succ n n_ih =>
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intro h
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nth_rw 2 [← (Rubin.GroupActionExt.smul_congr g (n_ih h)).trans h]
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rw [← mul_smul, ← pow_succ]
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#align smul_pow_eq_of_smul_eq Rubin.GroupActionExt.smul_pow_eq_of_smul_eq
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theorem GroupActionExt.smul_zpow_eq_of_smul_eq {x : α} {g : G} (n : ℤ) :
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g • x = x → g ^ n • x = x := by
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intro h
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cases n with
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| ofNat n => let res := Rubin.GroupActionExt.smul_pow_eq_of_smul_eq n h; simp; exact res
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| negSucc n =>
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let res :=
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smul_eq_iff_inv_smul_eq.mp (Rubin.GroupActionExt.smul_pow_eq_of_smul_eq (1 + n) h);
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simp
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rw [add_comm]
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exact res
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#align smul_zpow_eq_of_smul_eq Rubin.GroupActionExt.smul_zpow_eq_of_smul_eq
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def GroupActionExt.is_equivariant (G : Type _) {β : Type _} [Group G] [MulAction G α]
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[MulAction G β] (f : α → β) :=
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∀ g : G, ∀ x : α, f (g • x) = g • f x
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#align is_equivariant Rubin.GroupActionExt.is_equivariant
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def SmulImage.smulImage' (g : G) (U : Set α) :=
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{x | g⁻¹ • x ∈ U}
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#align subset_img' Rubin.SmulImage.smulImage'
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def SmulImage.smul_preimage' (g : G) (U : Set α) :=
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{x | g • x ∈ U}
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#align subset_preimg' Rubin.SmulImage.smul_preimage'
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def SmulImage.SmulImage (g : G) (U : Set α) :=
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(· • ·) g '' U
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#align subset_img Rubin.SmulImage.SmulImage
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infixl:60 "•''" => Rubin.SmulImage.SmulImage
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theorem SmulImage.smulImage_def {g : G} {U : Set α} : g•''U = (· • ·) g '' U :=
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rfl
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#align subset_img_def Rubin.SmulImage.smulImage_def
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theorem SmulImage.mem_smulImage {x : α} {g : G} {U : Set α} : x ∈ g•''U ↔ g⁻¹ • x ∈ U :=
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by
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rw [Rubin.SmulImage.smulImage_def, Set.mem_image ((· • ·) g) U x]
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constructor
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· rintro ⟨y, yU, gyx⟩
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let ygx : y = g⁻¹ • x := inv_smul_smul g y ▸ Rubin.GroupActionExt.smul_congr g⁻¹ gyx
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exact ygx ▸ yU
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· intro h
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exact ⟨g⁻¹ • x, ⟨Set.mem_preimage.mp h, smul_inv_smul g x⟩⟩
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#align mem_smul'' Rubin.SmulImage.mem_smulImage
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theorem SmulImage.mem_inv_smulImage {x : α} {g : G} {U : Set α} : x ∈ g⁻¹•''U ↔ g • x ∈ U :=
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by
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let msi := @Rubin.SmulImage.mem_smulImage _ _ _ _ x g⁻¹ U
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rw [inv_inv] at msi
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exact msi
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#align mem_inv_smul'' Rubin.SmulImage.mem_inv_smulImage
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theorem SmulImage.mul_smulImage (g h : G) (U : Set α) : g * h•''U = g•''(h•''U) :=
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by
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ext
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rw [Rubin.SmulImage.mem_smulImage, Rubin.SmulImage.mem_smulImage, Rubin.SmulImage.mem_smulImage, ←
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mul_smul, mul_inv_rev]
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#align mul_smul'' Rubin.SmulImage.mul_smulImage
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@[simp]
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theorem SmulImage.smulImage_smulImage {g h : G} {U : Set α} : g•''(h•''U) = g * h•''U :=
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(Rubin.SmulImage.mul_smulImage g h U).symm
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#align smul''_smul'' Rubin.SmulImage.smulImage_smulImage
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@[simp]
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theorem SmulImage.one_smulImage (U : Set α) : (1 : G)•''U = U :=
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by
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ext
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rw [Rubin.SmulImage.mem_smulImage, inv_one, one_smul]
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#align one_smul'' Rubin.SmulImage.one_smulImage
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theorem SmulImage.disjoint_smulImage (g : G) {U V : Set α} :
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Disjoint U V → Disjoint (g•''U) (g•''V) :=
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by
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intro disjoint_U_V
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rw [Set.disjoint_left]
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rw [Set.disjoint_left] at disjoint_U_V
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intro x x_in_gU
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by_contra h
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exact (disjoint_U_V (mem_smulImage.mp x_in_gU)) (mem_smulImage.mp h)
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#align disjoint_smul'' Rubin.SmulImage.disjoint_smulImage
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-- TODO: check if this is actually needed
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theorem SmulImage.smulImage_congr (g : G) {U V : Set α} : U = V → g•''U = g•''V :=
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congr_arg fun W : Set α => g•''W
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#align smul''_congr Rubin.SmulImage.smulImage_congr
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theorem SmulImage.smulImage_subset (g : G) {U V : Set α} : U ⊆ V → g•''U ⊆ g•''V :=
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by
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intro h1 x
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rw [Rubin.SmulImage.mem_smulImage, Rubin.SmulImage.mem_smulImage]
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exact fun h2 => h1 h2
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#align smul''_subset Rubin.SmulImage.smulImage_subset
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theorem SmulImage.smulImage_union (g : G) {U V : Set α} : g•''U ∪ V = (g•''U) ∪ (g•''V) :=
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by
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ext
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rw [Rubin.SmulImage.mem_smulImage, Set.mem_union, Set.mem_union, Rubin.SmulImage.mem_smulImage,
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Rubin.SmulImage.mem_smulImage]
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#align smul''_union Rubin.SmulImage.smulImage_union
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theorem SmulImage.smulImage_inter (g : G) {U V : Set α} : g•''U ∩ V = (g•''U) ∩ (g•''V) :=
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by
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ext
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rw [Set.mem_inter_iff, Rubin.SmulImage.mem_smulImage, Rubin.SmulImage.mem_smulImage,
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Rubin.SmulImage.mem_smulImage, Set.mem_inter_iff]
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#align smul''_inter Rubin.SmulImage.smulImage_inter
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theorem SmulImage.smulImage_eq_inv_preimage {g : G} {U : Set α} : g•''U = (· • ·) g⁻¹ ⁻¹' U :=
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by
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ext
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constructor
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· intro h; rw [Set.mem_preimage]; exact mem_smulImage.mp h
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· intro h; rw [Rubin.SmulImage.mem_smulImage]; exact Set.mem_preimage.mp h
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#align smul''_eq_inv_preimage Rubin.SmulImage.smulImage_eq_inv_preimage
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theorem SmulImage.smulImage_eq_of_smul_eq {g h : G} {U : Set α} :
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(∀ x ∈ U, g • x = h • x) → g•''U = h•''U :=
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by
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intro hU
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ext x
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rw [Rubin.SmulImage.mem_smulImage, Rubin.SmulImage.mem_smulImage]
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constructor
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· intro k; let a := congr_arg ((· • ·) h⁻¹) (hU (g⁻¹ • x) k);
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simp only [smul_inv_smul, inv_smul_smul] at a ; exact Set.mem_of_eq_of_mem a k
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· intro k; let a := congr_arg ((· • ·) g⁻¹) (hU (h⁻¹ • x) k);
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simp only [smul_inv_smul, inv_smul_smul] at a ; exact Set.mem_of_eq_of_mem a.symm k
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#align smul''_eq_of_smul_eq Rubin.SmulImage.smulImage_eq_of_smul_eq
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end SmulImage
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--------------------------------
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section Support
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def SmulSupport.Support (α : Type _) [MulAction G α] (g : G) :=
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{x : α | g • x ≠ x}
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#align support Rubin.SmulSupport.Support
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theorem SmulSupport.support_eq_not_fixed_by {g : G}:
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Rubin.SmulSupport.Support α g = (MulAction.fixedBy α g)ᶜ := by tauto
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#align support_eq_not_fixed_by Rubin.SmulSupport.support_eq_not_fixed_by
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theorem SmulSupport.mem_support {x : α} {g : G} :
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x ∈ Rubin.SmulSupport.Support α g ↔ g • x ≠ x := by tauto
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#align mem_support Rubin.SmulSupport.mem_support
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theorem SmulSupport.not_mem_support {x : α} {g : G} :
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x ∉ Rubin.SmulSupport.Support α g ↔ g • x = x := by
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rw [Rubin.SmulSupport.mem_support, Classical.not_not]
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#align mem_not_support Rubin.SmulSupport.not_mem_support
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theorem SmulSupport.smul_mem_support {g : G} {x : α} :
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x ∈ Rubin.SmulSupport.Support α g → g • x ∈ Rubin.SmulSupport.Support α g := fun h =>
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h ∘ smul_left_cancel g
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#align smul_in_support Rubin.SmulSupport.smul_mem_support
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theorem SmulSupport.inv_smul_mem_support {g : G} {x : α} :
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x ∈ Rubin.SmulSupport.Support α g → g⁻¹ • x ∈ Rubin.SmulSupport.Support α g := fun h k =>
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h (smul_inv_smul g x ▸ Rubin.GroupActionExt.smul_congr g k)
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#align inv_smul_in_support Rubin.SmulSupport.inv_smul_mem_support
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theorem SmulSupport.fixed_of_disjoint {g : G} {x : α} {U : Set α} :
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x ∈ U → Disjoint U (Rubin.SmulSupport.Support α g) → g • x = x :=
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fun x_in_U disjoint_U_support =>
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Rubin.SmulSupport.not_mem_support.mp (Set.disjoint_left.mp disjoint_U_support x_in_U)
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#align fixed_of_disjoint Rubin.SmulSupport.fixed_of_disjoint
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theorem SmulSupport.fixed_smulImage_in_support (g : G) {U : Set α} :
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Rubin.SmulSupport.Support α g ⊆ U → g•''U = U :=
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by
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intro support_in_U
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ext x
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cases' @or_not (x ∈ Rubin.SmulSupport.Support α g) with xmoved xfixed
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exact
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⟨fun _ => support_in_U xmoved, fun _ =>
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SmulImage.mem_smulImage.mpr (support_in_U (Rubin.SmulSupport.inv_smul_mem_support xmoved))⟩
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rw [Rubin.SmulImage.mem_smulImage, GroupActionExt.smul_eq_iff_inv_smul_eq.mp (not_mem_support.mp xfixed)]
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#align fixes_subset_within_support Rubin.SmulSupport.fixed_smulImage_in_support
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theorem SmulSupport.smulImage_subset_in_support (g : G) (U V : Set α) :
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U ⊆ V → Rubin.SmulSupport.Support α g ⊆ V → g•''U ⊆ V := fun U_in_V support_in_V =>
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Rubin.SmulSupport.fixed_smulImage_in_support g support_in_V ▸
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Rubin.SmulImage.smulImage_subset g U_in_V
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#align moves_subset_within_support Rubin.SmulSupport.smulImage_subset_in_support
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theorem SmulSupport.support_mul (g h : G) (α : Type _) [MulAction G α] :
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Rubin.SmulSupport.Support α (g * h) ⊆
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Rubin.SmulSupport.Support α g ∪ Rubin.SmulSupport.Support α h :=
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by
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intro x x_in_support
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by_contra h_support
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let res := not_or.mp h_support
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exact
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x_in_support
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((mul_smul g h x).trans
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((congr_arg ((· • ·) g) (not_mem_support.mp res.2)).trans <| not_mem_support.mp res.1))
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#align support_mul Rubin.SmulSupport.support_mul
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theorem SmulSupport.support_conjugate (α : Type _) [MulAction G α] (g h : G) :
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Rubin.SmulSupport.Support α (h * g * h⁻¹) = h•''Rubin.SmulSupport.Support α g :=
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by
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ext x
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rw [Rubin.SmulSupport.mem_support, Rubin.SmulImage.mem_smulImage, Rubin.SmulSupport.mem_support,
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mul_smul, mul_smul]
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constructor
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· intro h1; by_contra h2; exact h1 ((congr_arg ((· • ·) h) h2).trans (smul_inv_smul _ _))
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· intro h1; by_contra h2; exact h1 (inv_smul_smul h (g • h⁻¹ • x) ▸ congr_arg ((· • ·) h⁻¹) h2)
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#align support_conjugate Rubin.SmulSupport.support_conjugate
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theorem SmulSupport.support_inv (α : Type _) [MulAction G α] (g : G) :
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Rubin.SmulSupport.Support α g⁻¹ = Rubin.SmulSupport.Support α g :=
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by
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ext x
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rw [Rubin.SmulSupport.mem_support, Rubin.SmulSupport.mem_support]
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constructor
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· intro h1; by_contra h2; exact h1 (GroupActionExt.smul_eq_iff_inv_smul_eq.mp h2)
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· intro h1; by_contra h2; exact h1 (GroupActionExt.smul_eq_iff_inv_smul_eq.mpr h2)
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#align support_inv Rubin.SmulSupport.support_inv
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theorem SmulSupport.support_pow (α : Type _) [MulAction G α] (g : G) (j : ℕ) :
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Rubin.SmulSupport.Support α (g ^ j) ⊆ Rubin.SmulSupport.Support α g :=
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by
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intro x xmoved
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by_contra xfixed
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rw [Rubin.SmulSupport.mem_support] at xmoved
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induction j with
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| zero => apply xmoved; rw [pow_zero g, one_smul]
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| succ j j_ih =>
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apply xmoved
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let j_ih := (congr_arg ((· • ·) g) (not_not.mp j_ih)).trans (not_mem_support.mp xfixed)
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simp at j_ih
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rw [← mul_smul, ← pow_succ] at j_ih
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exact j_ih
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#align support_pow Rubin.SmulSupport.support_pow
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theorem SmulSupport.support_comm (α : Type _) [MulAction G α] (g h : G) :
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Rubin.SmulSupport.Support α ⁅g, h⁆ ⊆
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Rubin.SmulSupport.Support α h ∪ (g•''Rubin.SmulSupport.Support α h) :=
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by
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intro x x_in_support
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by_contra all_fixed
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rw [Set.mem_union] at all_fixed
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cases' @or_not (h • x = x) with xfixed xmoved
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· rw [Rubin.SmulSupport.mem_support, Rubin.bracket_mul, mul_smul,
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GroupActionExt.smul_eq_iff_inv_smul_eq.mp xfixed, ← Rubin.SmulSupport.mem_support] at x_in_support
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exact
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((Rubin.SmulSupport.support_conjugate α h g).symm ▸ (not_or.mp all_fixed).2)
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x_in_support
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· exact all_fixed (Or.inl xmoved)
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#align support_comm Rubin.SmulSupport.support_comm
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theorem SmulSupport.disjoint_support_comm (f g : G) {U : Set α} :
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Rubin.SmulSupport.Support α f ⊆ U → Disjoint U (g•''U) → ∀ x ∈ U, ⁅f, g⁆ • x = f • x :=
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by
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intro support_in_U disjoint_U x x_in_U
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have support_conj : Rubin.SmulSupport.Support α (g * f⁻¹ * g⁻¹) ⊆ g•''U :=
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((Rubin.SmulSupport.support_conjugate α f⁻¹ g).trans
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(Rubin.SmulImage.smulImage_congr g (Rubin.SmulSupport.support_inv α f))).symm ▸
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Rubin.SmulImage.smulImage_subset g support_in_U
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have goal :=
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(congr_arg ((· • ·) f)
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(Rubin.SmulSupport.fixed_of_disjoint x_in_U
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(Set.disjoint_of_subset_right support_conj disjoint_U))).symm
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simp at goal
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sorry
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-- rw [mul_smul, mul_smul] at goal
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-- exact goal.symm
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#align disjoint_support_comm Rubin.SmulSupport.disjoint_support_comm
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end Support
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-- comment by Cedric: would be nicer to define just a subset, and then show it is a subgroup
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-- comment by Cedric: would be nicer to define just a subset, and then show it is a subgroup
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def rigidStabilizer' (G : Type _) [Group G] [MulAction G α] (U : Set α) : Set G :=
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def rigidStabilizer' (G : Type _) [Group G] [MulAction G α] (U : Set α) : Set G :=
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{g : G | ∀ x : α, g • x = x ∨ x ∈ U}
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{g : G | ∀ x : α, g • x = x ∨ x ∈ U}
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@ -390,12 +79,12 @@ def rigidStabilizer (G : Type _) [Group G] [MulAction G α] (U : Set α) : Subgr
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where
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where
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carrier := {g : G | ∀ (x) (_ : x ∉ U), g • x = x}
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carrier := {g : G | ∀ (x) (_ : x ∉ U), g • x = x}
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mul_mem' ha hb x x_notin_U := by rw [mul_smul, hb x x_notin_U, ha x x_notin_U]
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mul_mem' ha hb x x_notin_U := by rw [mul_smul, hb x x_notin_U, ha x x_notin_U]
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inv_mem' hg x x_notin_U := Rubin.GroupActionExt.smul_eq_iff_inv_smul_eq.mp (hg x x_notin_U)
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inv_mem' hg x x_notin_U := smul_eq_iff_inv_smul_eq.mp (hg x x_notin_U)
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one_mem' x _ := one_smul G x
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one_mem' x _ := one_smul G x
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#align rigid_stabilizer Rubin.rigidStabilizer
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#align rigid_stabilizer Rubin.rigidStabilizer
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theorem rist_supported_in_set {g : G} {U : Set α} :
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theorem rist_supported_in_set {g : G} {U : Set α} :
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g ∈ rigidStabilizer G U → Rubin.SmulSupport.Support α g ⊆ U := fun h x x_in_support =>
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g ∈ rigidStabilizer G U → Support α g ⊆ U := fun h x x_in_support =>
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by_contradiction (x_in_support ∘ h x)
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by_contradiction (x_in_support ∘ h x)
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#align rist_supported_in_set Rubin.rist_supported_in_set
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#align rist_supported_in_set Rubin.rist_supported_in_set
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@ -421,18 +110,18 @@ class Topological.ContinuousMulAction (G α : Type _) [Group G] [TopologicalSpac
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structure Topological.equivariant_homeomorph (G α β : Type _) [Group G] [TopologicalSpace α]
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structure Topological.equivariant_homeomorph (G α β : Type _) [Group G] [TopologicalSpace α]
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[TopologicalSpace β] [MulAction G α] [MulAction G β] extends Homeomorph α β where
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[TopologicalSpace β] [MulAction G α] [MulAction G β] extends Homeomorph α β where
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equivariant : GroupActionExt.is_equivariant G toFun
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equivariant : is_equivariant G toFun
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#align equivariant_homeomorph Rubin.Topological.equivariant_homeomorph
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#align equivariant_homeomorph Rubin.Topological.equivariant_homeomorph
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theorem Topological.equivariant_fun [MulAction G α] [MulAction G β]
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theorem Topological.equivariant_fun [MulAction G α] [MulAction G β]
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(h : Rubin.Topological.equivariant_homeomorph G α β) :
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(h : Rubin.Topological.equivariant_homeomorph G α β) :
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Rubin.GroupActionExt.is_equivariant G h.toFun :=
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is_equivariant G h.toFun :=
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h.equivariant
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h.equivariant
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#align equivariant_fun Rubin.Topological.equivariant_fun
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#align equivariant_fun Rubin.Topological.equivariant_fun
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theorem Topological.equivariant_inv [MulAction G α] [MulAction G β]
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theorem Topological.equivariant_inv [MulAction G α] [MulAction G β]
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(h : Rubin.Topological.equivariant_homeomorph G α β) :
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(h : Rubin.Topological.equivariant_homeomorph G α β) :
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Rubin.GroupActionExt.is_equivariant G h.invFun :=
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is_equivariant G h.invFun :=
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by
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by
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intro g x
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intro g x
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symm
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symm
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@ -446,12 +135,12 @@ variable [Rubin.Topological.ContinuousMulAction G α]
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theorem Topological.img_open_open (g : G) (U : Set α) (h : IsOpen U)
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theorem Topological.img_open_open (g : G) (U : Set α) (h : IsOpen U)
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[Rubin.Topological.ContinuousMulAction G α] : IsOpen (g •'' U) :=
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[Rubin.Topological.ContinuousMulAction G α] : IsOpen (g •'' U) :=
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by
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by
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rw [Rubin.SmulImage.smulImage_eq_inv_preimage]
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rw [Rubin.smulImage_eq_inv_preimage]
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exact Continuous.isOpen_preimage (Rubin.Topological.ContinuousMulAction.continuous g⁻¹) U h
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exact Continuous.isOpen_preimage (Rubin.Topological.ContinuousMulAction.continuous g⁻¹) U h
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#align img_open_open Rubin.Topological.img_open_open
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#align img_open_open Rubin.Topological.img_open_open
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theorem Topological.support_open (g : G) [TopologicalSpace α] [T2Space α]
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theorem Topological.support_open (g : G) [TopologicalSpace α] [T2Space α]
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[Rubin.Topological.ContinuousMulAction G α] : IsOpen (Rubin.SmulSupport.Support α g) :=
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[Rubin.Topological.ContinuousMulAction G α] : IsOpen (Support α g) :=
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by
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by
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apply isOpen_iff_forall_mem_open.mpr
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apply isOpen_iff_forall_mem_open.mpr
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intro x xmoved
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intro x xmoved
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@ -460,11 +149,11 @@ theorem Topological.support_open (g : G) [TopologicalSpace α] [T2Space α]
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⟨V ∩ (g⁻¹ •'' U), fun y yW =>
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⟨V ∩ (g⁻¹ •'' U), fun y yW =>
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-- TODO: don't use @-notation here
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-- TODO: don't use @-notation here
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@Disjoint.ne_of_mem α U V disjoint_U_V (g • y)
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@Disjoint.ne_of_mem α U V disjoint_U_V (g • y)
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(SmulImage.mem_inv_smulImage.mp (Set.mem_of_mem_inter_right yW))
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(mem_inv_smulImage.mp (Set.mem_of_mem_inter_right yW))
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y
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y
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(Set.mem_of_mem_inter_left yW),
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(Set.mem_of_mem_inter_left yW),
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IsOpen.inter open_V (Rubin.Topological.img_open_open g⁻¹ U open_U),
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IsOpen.inter open_V (Rubin.Topological.img_open_open g⁻¹ U open_U),
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⟨x_in_V, SmulImage.mem_inv_smulImage.mpr gx_in_U⟩⟩
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⟨x_in_V, mem_inv_smulImage.mpr gx_in_U⟩⟩
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#align support_open Rubin.Topological.support_open
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#align support_open Rubin.Topological.support_open
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end TopologicalActions
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end TopologicalActions
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@ -492,7 +181,7 @@ theorem faithful_rigid_stabilizer_moves_point {g : G} {U : Set α} :
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exact ⟨x, rist_supported_in_set g_rigid xmoved, xmoved⟩
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exact ⟨x, rist_supported_in_set g_rigid xmoved, xmoved⟩
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#align faithful_rist_moves_point Rubin.faithful_rigid_stabilizer_moves_point
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#align faithful_rist_moves_point Rubin.faithful_rigid_stabilizer_moves_point
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theorem ne_one_support_nonempty {g : G} : g ≠ 1 → (Rubin.SmulSupport.Support α g).Nonempty :=
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theorem ne_one_support_nonempty {g : G} : g ≠ 1 → (Support α g).Nonempty :=
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by
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by
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intro h1
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intro h1
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cases' Rubin.faithful_moves_point'₁ α h1 with x h
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cases' Rubin.faithful_moves_point'₁ α h1 with x h
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@ -500,35 +189,31 @@ theorem ne_one_support_nonempty {g : G} : g ≠ 1 → (Rubin.SmulSupport.Support
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exact h
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exact h
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#align ne_one_support_nempty Rubin.ne_one_support_nonempty
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#align ne_one_support_nempty Rubin.ne_one_support_nonempty
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-- FIXME: somehow clashes with another definition
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theorem disjoint_commute {f g : G} :
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theorem disjoint_commute₁ {f g : G} :
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Disjoint (Support α f) (Support α g) → Commute f g :=
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Disjoint (Rubin.SmulSupport.Support α f) (Rubin.SmulSupport.Support α g) → Commute f g :=
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by
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by
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intro hdisjoint
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intro hdisjoint
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rw [← commutatorElement_eq_one_iff_commute]
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rw [← commutatorElement_eq_one_iff_commute]
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apply @Rubin.faithful_moves_point₁ _ α
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apply @Rubin.faithful_moves_point₁ _ α
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intro x
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intro x
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rw [Rubin.bracket_mul, mul_smul, mul_smul, mul_smul]
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rw [commutatorElement_def, mul_smul, mul_smul, mul_smul]
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cases' @or_not (x ∈ Rubin.SmulSupport.Support α f) with hfmoved hffixed
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cases' @or_not (x ∈ Support α f) with hfmoved hffixed
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·
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· rw [smul_eq_iff_inv_smul_eq.mp (not_mem_support.mp (Set.disjoint_left.mp hdisjoint hfmoved)),
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rw [GroupActionExt.smul_eq_iff_inv_smul_eq.mp (SmulSupport.not_mem_support.mp (Set.disjoint_left.mp hdisjoint hfmoved)),
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not_mem_support.mp
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SmulSupport.not_mem_support.mp
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(Set.disjoint_left.mp hdisjoint (inv_smul_mem_support hfmoved)),
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(Set.disjoint_left.mp hdisjoint (Rubin.SmulSupport.inv_smul_mem_support hfmoved)),
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smul_inv_smul]
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smul_inv_smul]
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cases' @or_not (x ∈ Rubin.SmulSupport.Support α g) with hgmoved hgfixed
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cases' @or_not (x ∈ Support α g) with hgmoved hgfixed
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·
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· rw [smul_eq_iff_inv_smul_eq.mp
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rw [GroupActionExt.smul_eq_iff_inv_smul_eq.mp
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(not_mem_support.mp <|
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(SmulSupport.not_mem_support.mp <|
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Set.disjoint_right.mp hdisjoint (inv_smul_mem_support hgmoved)),
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Set.disjoint_right.mp hdisjoint (Rubin.SmulSupport.inv_smul_mem_support hgmoved)),
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smul_inv_smul, not_mem_support.mp hffixed]
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smul_inv_smul, SmulSupport.not_mem_support.mp hffixed]
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· rw [
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·
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smul_eq_iff_inv_smul_eq.mp (not_mem_support.mp hgfixed),
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rw [
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smul_eq_iff_inv_smul_eq.mp (not_mem_support.mp hffixed),
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GroupActionExt.smul_eq_iff_inv_smul_eq.mp (SmulSupport.not_mem_support.mp hgfixed),
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not_mem_support.mp hgfixed,
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GroupActionExt.smul_eq_iff_inv_smul_eq.mp (SmulSupport.not_mem_support.mp hffixed),
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not_mem_support.mp hffixed
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SmulSupport.not_mem_support.mp hgfixed,
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SmulSupport.not_mem_support.mp hffixed
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]
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]
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#align disjoint_commute Rubin.disjoint_commute₁
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#align disjoint_commute Rubin.disjoint_commute
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end FaithfulActions
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end FaithfulActions
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@ -1003,7 +688,7 @@ theorem RegularSupport.regular_interior_closure (U : Set α) :
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#align regular_interior_closure Rubin.RegularSupport.regular_interior_closure
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#align regular_interior_closure Rubin.RegularSupport.regular_interior_closure
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def RegularSupport.RegularSupport (α : Type _) [TopologicalSpace α] [MulAction G α] (g : G) :=
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def RegularSupport.RegularSupport (α : Type _) [TopologicalSpace α] [MulAction G α] (g : G) :=
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Rubin.RegularSupport.InteriorClosure (Rubin.SmulSupport.Support α g)
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Rubin.RegularSupport.InteriorClosure (Support α g)
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#align regular_support Rubin.RegularSupport.RegularSupport
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#align regular_support Rubin.RegularSupport.RegularSupport
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theorem RegularSupport.regularSupport_regular {g : G} :
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theorem RegularSupport.regularSupport_regular {g : G} :
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@ -1012,7 +697,7 @@ theorem RegularSupport.regularSupport_regular {g : G} :
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#align regular_regular_support Rubin.RegularSupport.regularSupport_regular
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#align regular_regular_support Rubin.RegularSupport.regularSupport_regular
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theorem RegularSupport.support_subset_regularSupport [T2Space α] (g : G) :
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theorem RegularSupport.support_subset_regularSupport [T2Space α] (g : G) :
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Rubin.SmulSupport.Support α g ⊆ Rubin.RegularSupport.RegularSupport α g :=
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Support α g ⊆ Rubin.RegularSupport.RegularSupport α g :=
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Rubin.RegularSupport.IsOpen.interiorClosure_subset (Rubin.Topological.support_open g)
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Rubin.RegularSupport.IsOpen.interiorClosure_subset (Rubin.Topological.support_open g)
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#align support_in_regular_support Rubin.RegularSupport.support_subset_regularSupport
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#align support_in_regular_support Rubin.RegularSupport.support_subset_regularSupport
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