✨ Prove that UltrafilterInBasis is a sufficient condition for convergence

10 months ago · 5fb9162950
parent 431a2931d7
commit 5fb9162950
1 changed files with 111 additions and 7 deletions
--- a/Rubin/Filter.lean
+++ b/Rubin/Filter.lean
@ -280,6 +280,14 @@ by
  rw [Set.nonempty_coe_sort]
  exact Filter.InBasis.basis_nonempty F_basis
 theorem Filter.InBasis.principal {S : Set α} (S_in_B : S ∈ B) :
  (Filter.principal S).InBasis B :=
 by
  intro T
  simp only [mem_principal]
  intro T_in_pS
  use S
 theorem Filter.InBasis.basis_hasBasis (F_basis : Filter.InBasis F B):
  F.HasBasis (fun S => S ∈ Filter.InBasis.basis F B) id :=
 by
@ -913,6 +921,10 @@ instance : CoeOut (@UltrafilterInBasis α B) (Filter α) where
 instance : Membership (Set α) (UltrafilterInBasis B) where
  mem := fun s U => s ∈ U.filter
@[simp]
 theorem UltrafilterInBasis.mem_coe (U : UltrafilterInBasis B) (S : Set α):
  S ∈ U.filter ↔ S ∈ U := by rfl
 instance (U : UltrafilterInBasis B): Filter.NeBot (U.filter) where
  ne' := U.ne_bot.ne
@ -965,13 +977,19 @@ by
 theorem UltrafilterInBasis.coe_in_basis (U : UltrafilterInBasis B) : Filter.InBasis U B := U.in_basis
-theorem UltrafilterInBasis.map_basis_ultra [Nonempty α] {β : Type _}
+theorem UltrafilterInBasis.map_basis_ultra {β : Type _}
  (empty_notin_B : ∅ ∉ B)
  (map : OrderIsoOn (Set α) (Set β) B)
  (U : UltrafilterInBasis B) :
  ∀ (F : Filter β), F.InBasis (map.toFun '' B) → F.NeBot →
  F ≤ Filter.InBasis.map_basis U B map → Filter.InBasis.map_basis U B map ≤ F :=
 by
  have α_nonempty: Nonempty α := by
    by_contra α_trivial
    rw [not_nonempty_iff] at α_trivial
    apply U.ne_bot.ne
    exact Filter.filter_eq_bot_of_isEmpty U.filter
  intro F F_in_basis F_neBot F_le_map
  intro S S_in_F
@ -1003,7 +1021,7 @@ by
  · rw [map.rightInv_on T T_in_mB]
    exact T_ss_S
-def UltrafilterInBasis.map_basis [Nonempty α] {β : Type _} [Nonempty β]
+def UltrafilterInBasis.map_basis {β : Type _}
  (empty_notin_B : ∅ ∉ B)
  (map : OrderIsoOn (Set α) (Set β) B)
  (empty_notin_mB : ∅ ∉ map.toFun '' B)
@ -1011,16 +1029,102 @@ def UltrafilterInBasis.map_basis [Nonempty α] {β : Type _} [Nonempty β]
  UltrafilterInBasis (map.toFun '' B)
 where
  filter := Filter.InBasis.map_basis U.filter B map.toFun
-  in_basis := Filter.InBasis.map_basis_inBasis' map U.in_basis
+  in_basis := U.in_basis.map_basis_inBasis' map
  ne_bot := by
    have β_nonempty : Nonempty β := by
      by_contra β_trivial
      rw [not_nonempty_iff] at β_trivial
      apply empty_notin_mB
      rw [Subsingleton.mem_iff_nonempty]
      simp
      let ⟨T, _, T_in_B, _⟩ := U.in_basis _ (Filter.univ_mem)
      use T
    apply Filter.InBasis.map_basis_neBot_of_neBot U.in_basis _ map.toFun_doubleMonotone.monotoneOn
    intro S S_in_B _
    by_contra empty
    rw [Set.not_nonempty_iff_eq_empty] at empty
    apply empty_notin_mB
    use S
-  ultra := by
+  ultra := U.map_basis_ultra empty_notin_B map
-    apply map_basis_ultra
+
-    exact empty_notin_B
+/-
 theorem compl_not_mem_iff : sᶜ ∉ f ↔ s ∈ f :=
  ⟨fun hsc =>
    le_principal_iff.1 <|
      f.le_of_inf_neBot ⟨fun h => hsc <| mem_of_eq_bot <| by rwa [compl_compl]⟩,
    compl_not_mem⟩
 -/
 theorem UltrafilterInBasis.unique (U : UltrafilterInBasis B) {F : Filter α} [Filter.NeBot F] (F_in_basis : F.InBasis B) :
  F ≤ U.filter → U.filter = F :=
 by
  intro F_le_U
  apply le_antisymm
  apply U.ultra
  all_goals assumption
-- TODO: show that clusterpt iff le nhds if B is a topological basis
+theorem UltrafilterInBasis.le_of_inf_neBot (U : UltrafilterInBasis B)
  (B_closed : ∀ (b1 b2 : Set α), b1 ∈ B → b2 ∈ B → Set.Nonempty (b1 ∩ b2) → b1 ∩ b2 ∈ B)
  {F : Filter α} (F_in_basis : F.InBasis B)
  (inf_neBot : Filter.NeBot (U.filter ⊓ F)) : U.filter ≤ F :=
 by
  apply le_of_inf_eq
  symm
  apply U.unique
  · exact Filter.InBasis.inf B_closed U.in_basis F_in_basis inf_neBot
  · exact inf_le_left
 theorem UltrafilterInBasis.mem_of_compl_not_mem (U : UltrafilterInBasis B)
  (B_closed : ∀ (b1 b2 : Set α), b1 ∈ B → b2 ∈ B → Set.Nonempty (b1 ∩ b2) → b1 ∩ b2 ∈ B)
  {S : Set α} (S_in_B : S ∈ B):
  Sᶜ ∉ U → S ∈ U :=
 by
  intro sc_notin_U
  rw [<-mem_coe, <-Filter.le_principal_iff]
  apply le_of_inf_neBot U B_closed
  · exact Filter.InBasis.principal S_in_B
  · constructor
    intro eq_bot
    apply sc_notin_U
    apply Filter.mem_of_eq_bot
    rwa [compl_compl]
 theorem UltrafilterInBasis.mem_or_compl_mem (U : UltrafilterInBasis B)
  (B_closed : ∀ (b1 b2 : Set α), b1 ∈ B → b2 ∈ B → Set.Nonempty (b1 ∩ b2) → b1 ∩ b2 ∈ B)
  {S : Set α} (S_in_B : S ∈ B):
  Sᶜ ∈ U ∨ S ∈ U :=
 by
  by_cases S_in_U? : S ∈ U
  right; exact S_in_U?
  left
  by_contra Sc_notin_U
  apply (U.mem_of_compl_not_mem B_closed S_in_B) at Sc_notin_U
  exact S_in_U? Sc_notin_U
 theorem UltrafilterInBasis.clusterPt_iff_le_nhds [TopologicalSpace α]
  (U : UltrafilterInBasis B)
  (B_basis : TopologicalSpace.IsTopologicalBasis B)
  (B_closed : ∀ (b1 b2 : Set α), b1 ∈ B → b2 ∈ B → Set.Nonempty (b1 ∩ b2) → b1 ∩ b2 ∈ B)
  (p : α) :
  ClusterPt p U.filter ↔ U.filter ≤ nhds p :=
 by
  constructor
  swap
  exact fun h => ClusterPt.of_le_nhds h
  intro p_clusterPt
  intro S S_in_nhds
  let ⟨T, T_in_B, p_in_T, T_ss_S⟩ := B_basis.mem_nhds_iff.mp S_in_nhds
  have T_in_nhds : T ∈ nhds p := by
    rw [B_basis.mem_nhds_iff]
    use T
  apply Filter.mem_of_superset _ T_ss_S
  cases U.mem_or_compl_mem B_closed T_in_B with
  | inr res => exact res
  | inl Tc_in_U =>
    exfalso
    rw [clusterPt_iff] at p_clusterPt
    specialize p_clusterPt T_in_nhds Tc_in_U
    rw [Set.inter_compl_self] at p_clusterPt
    exact Set.not_nonempty_empty p_clusterPt