Elementary Substructures #
Main Definitions #
- A
FirstOrder.Language.ElementarySubstructure
is a substructure where the realization of each formula agrees with the realization in the larger model.
Main Results #
- The Tarski-Vaught Test for substructures:
FirstOrder.Language.Substructure.isElementary_of_exists
gives a simple criterion for a substructure to be elementary.
def
FirstOrder.Language.Substructure.IsElementary
{L : FirstOrder.Language}
{M : Type u_1}
[L.Structure M]
(S : L.Substructure M)
:
A substructure is elementary when every formula applied to a tuple in the substructure agrees with its value in the overall structure.
Equations
Instances For
structure
FirstOrder.Language.ElementarySubstructure
(L : FirstOrder.Language)
(M : Type u_1)
[L.Structure M]
:
Type u_1
An elementary substructure is one in which every formula applied to a tuple in the substructure agrees with its value in the overall structure.
- toSubstructure : L.Substructure M
- isElementary' : (↑self).IsElementary
Instances For
theorem
FirstOrder.Language.ElementarySubstructure.isElementary'
{L : FirstOrder.Language}
{M : Type u_1}
[L.Structure M]
(self : L.ElementarySubstructure M)
:
(↑self).IsElementary
instance
FirstOrder.Language.ElementarySubstructure.instCoe
{L : FirstOrder.Language}
{M : Type u_1}
[L.Structure M]
:
Coe (L.ElementarySubstructure M) (L.Substructure M)
Equations
- FirstOrder.Language.ElementarySubstructure.instCoe = { coe := FirstOrder.Language.ElementarySubstructure.toSubstructure }
instance
FirstOrder.Language.ElementarySubstructure.instSetLike
{L : FirstOrder.Language}
{M : Type u_1}
[L.Structure M]
:
SetLike (L.ElementarySubstructure M) M
Equations
- FirstOrder.Language.ElementarySubstructure.instSetLike = { coe := fun (x : L.ElementarySubstructure M) => ↑↑x, coe_injective' := ⋯ }
instance
FirstOrder.Language.ElementarySubstructure.inducedStructure
{L : FirstOrder.Language}
{M : Type u_1}
[L.Structure M]
(S : L.ElementarySubstructure M)
:
L.Structure ↥S
Equations
- S.inducedStructure = FirstOrder.Language.Substructure.inducedStructure
@[simp]
theorem
FirstOrder.Language.ElementarySubstructure.isElementary
{L : FirstOrder.Language}
{M : Type u_1}
[L.Structure M]
(S : L.ElementarySubstructure M)
:
(↑S).IsElementary
def
FirstOrder.Language.ElementarySubstructure.subtype
{L : FirstOrder.Language}
{M : Type u_1}
[L.Structure M]
(S : L.ElementarySubstructure M)
:
L.ElementaryEmbedding (↥S) M
The natural embedding of an L.Substructure
of M
into M
.
Equations
- S.subtype = { toFun := Subtype.val, map_formula' := ⋯ }
Instances For
@[simp]
theorem
FirstOrder.Language.ElementarySubstructure.coeSubtype
{L : FirstOrder.Language}
{M : Type u_1}
[L.Structure M]
{S : L.ElementarySubstructure M}
:
⇑S.subtype = Subtype.val
instance
FirstOrder.Language.ElementarySubstructure.instTop
{L : FirstOrder.Language}
{M : Type u_1}
[L.Structure M]
:
Top (L.ElementarySubstructure M)
The substructure M
of the structure M
is elementary.
instance
FirstOrder.Language.ElementarySubstructure.instInhabited
{L : FirstOrder.Language}
{M : Type u_1}
[L.Structure M]
:
Inhabited (L.ElementarySubstructure M)
@[simp]
theorem
FirstOrder.Language.ElementarySubstructure.mem_top
{L : FirstOrder.Language}
{M : Type u_1}
[L.Structure M]
(x : M)
:
@[simp]
theorem
FirstOrder.Language.ElementarySubstructure.coe_top
{L : FirstOrder.Language}
{M : Type u_1}
[L.Structure M]
:
@[simp]
theorem
FirstOrder.Language.ElementarySubstructure.realize_sentence
{L : FirstOrder.Language}
{M : Type u_1}
[L.Structure M]
(S : L.ElementarySubstructure M)
(φ : L.Sentence)
:
@[simp]
theorem
FirstOrder.Language.ElementarySubstructure.theory_model_iff
{L : FirstOrder.Language}
{M : Type u_1}
[L.Structure M]
(S : L.ElementarySubstructure M)
(T : L.Theory)
:
instance
FirstOrder.Language.ElementarySubstructure.theory_model
{L : FirstOrder.Language}
{M : Type u_1}
[L.Structure M]
{T : L.Theory}
[h : M ⊨ T]
{S : L.ElementarySubstructure M}
:
↥S ⊨ T
Equations
- ⋯ = ⋯
instance
FirstOrder.Language.ElementarySubstructure.instNonempty
{L : FirstOrder.Language}
{M : Type u_1}
[L.Structure M]
[Nonempty M]
{S : L.ElementarySubstructure M}
:
Nonempty ↥S
Equations
- ⋯ = ⋯
theorem
FirstOrder.Language.ElementarySubstructure.elementarilyEquivalent
{L : FirstOrder.Language}
{M : Type u_1}
[L.Structure M]
(S : L.ElementarySubstructure M)
:
L.ElementarilyEquivalent (↥S) M
theorem
FirstOrder.Language.Substructure.isElementary_of_exists
{L : FirstOrder.Language}
{M : Type u_1}
[L.Structure M]
(S : L.Substructure M)
(htv : ∀ (n : ℕ) (φ : L.BoundedFormula Empty (n + 1)) (x : Fin n → ↥S) (a : M),
φ.Realize default (Fin.snoc (Subtype.val ∘ x) a) → ∃ (b : ↥S), φ.Realize default (Fin.snoc (Subtype.val ∘ x) ↑b))
:
S.IsElementary
The Tarski-Vaught test for elementarity of a substructure.
@[simp]
theorem
FirstOrder.Language.Substructure.toElementarySubstructure_toSubstructure
{L : FirstOrder.Language}
{M : Type u_1}
[L.Structure M]
(S : L.Substructure M)
(htv : ∀ (n : ℕ) (φ : L.BoundedFormula Empty (n + 1)) (x : Fin n → ↥S) (a : M),
φ.Realize default (Fin.snoc (Subtype.val ∘ x) a) → ∃ (b : ↥S), φ.Realize default (Fin.snoc (Subtype.val ∘ x) ↑b))
:
↑(S.toElementarySubstructure htv) = S
def
FirstOrder.Language.Substructure.toElementarySubstructure
{L : FirstOrder.Language}
{M : Type u_1}
[L.Structure M]
(S : L.Substructure M)
(htv : ∀ (n : ℕ) (φ : L.BoundedFormula Empty (n + 1)) (x : Fin n → ↥S) (a : M),
φ.Realize default (Fin.snoc (Subtype.val ∘ x) a) → ∃ (b : ↥S), φ.Realize default (Fin.snoc (Subtype.val ∘ x) ↑b))
:
L.ElementarySubstructure M
Bundles a substructure satisfying the Tarski-Vaught test as an elementary substructure.
Equations
- S.toElementarySubstructure htv = { toSubstructure := S, isElementary' := ⋯ }