Spectral/algebra/subgroup.hlean

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/-
Copyright (c) 2015 Egbert Rijke. All rights reserved.
Released under Apache 2.0 license as described in the file LICENSE.
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Authors: Floris van Doorn, Egbert Rijke, Jeremy Avigad
Basic concepts of group theory
-/
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import algebra.group_theory ..move_to_lib ..property
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open eq algebra is_trunc sigma sigma.ops prod trunc property
namespace group
/- #Subgroups -/
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/-- Recall that a subtype of a type A is the same thing as a family
of mere propositions over A. Thus, we define a subgroup of a
group G to be a family of mere propositions over (the underlying
type of) G, closed under the constants and operations --/
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structure is_subgroup [class] (G : Group) (H : property G) : Type :=
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(one_mem : 1 ∈ H)
(mul_mem : Π{g h}, g ∈ H → h ∈ H → g * h ∈ H)
(inv_mem : Π{g}, g ∈ H → g⁻¹ ∈ H)
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definition is_prop_is_subgroup [instance] (G : Group) (H : property G) : is_prop (is_subgroup G H) :=
proof -- this results in a simpler choice of universe metavariables
have 1 ∈ H × (Π{g h}, g ∈ H → h ∈ H → g * h ∈ H) × (Π{g}, g ∈ H → g⁻¹ ∈ H) ≃ is_subgroup G H,
begin
fapply equiv.MK,
{ intro p, cases p with p1 p2, cases p2 with p2 p3, exact is_subgroup.mk p1 @p2 @p3 },
{ intro p, split, exact is_subgroup.one_mem H, split, apply @is_subgroup.mul_mem G H p, apply @is_subgroup.inv_mem G H p},
{ intro b, cases b, reflexivity },
{ intro a, cases a with a1 a2, cases a2, reflexivity }
end,
is_trunc_equiv_closed _ this
qed
/-- Every group G has at least two subgroups, the trivial subgroup containing only one, and the full subgroup. --/
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definition trivial_subgroup [instance] (G : Group) : is_subgroup G '{1} :=
begin
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fapply is_subgroup.mk,
{ esimp, apply mem_insert },
{ intros g h p q, esimp at *, apply mem_singleton_of_eq, rewrite [eq_of_mem_singleton p, eq_of_mem_singleton q, mul_one]},
{ intros g p, esimp at *, apply mem_singleton_of_eq, rewrite [eq_of_mem_singleton p, one_inv] }
end
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definition full_subgroup [instance] (G : Group) : is_subgroup G univ :=
begin
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fapply is_subgroup.mk,
{ apply logic.trivial },
{ intros, apply logic.trivial },
{ intros, apply logic.trivial }
end
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/-- Every group homomorphism f : G -> H determines a subgroup of H,
the image of f, and a subgroup of G, the kernel of f. In the
following definition we define the image of f. Since a subgroup
is required to be closed under the group operations, showing
that the image of f is closed under the group operations is part
of the definition of the image of f. --/
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definition is_subgroup_image [instance] {G : Group} {H : Group} (f : G →g H) :
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is_subgroup H (image f) :=
begin
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fapply is_subgroup.mk,
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-- subproperty contains 1
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{ fapply image.mk, exact 1, apply respect_one},
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-- subproperty is closed under multiplication
{ intro h h', intro u v,
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induction u with x p, induction v with y q,
induction p, induction q,
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apply image.mk (x * y), apply respect_mul},
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-- subproperty is closed under inverses
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{ intro g, intro t, induction t with x p, induction p,
apply image.mk x⁻¹, apply respect_inv }
end
section kernels
variables {G₁ G₂ : Group}
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-- TODO: maybe define this in more generality for pointed propertys?
definition kernel [constructor] (φ : G₁ →g G₂) : property G₁ := { g | trunctype.mk (φ g = 1) _}
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theorem mul_mem_kernel (φ : G₁ →g G₂) (g h : G₁) (H₁ : g ∈ kernel φ) (H₂ : h ∈ kernel φ) : g * h ∈ kernel φ :=
calc
φ (g * h) = (φ g) * (φ h) : to_respect_mul
... = 1 * (φ h) : H₁
... = 1 * 1 : H₂
... = 1 : one_mul
theorem inv_mem_kernel (φ : G₁ →g G₂) (g : G₁) (H : g ∈ kernel φ) : g⁻¹ ∈ kernel φ :=
calc
φ g⁻¹ = (φ g)⁻¹ : to_respect_inv
... = 1⁻¹ : H
... = 1 : one_inv
definition is_subgroup_kernel [constructor] [instance] (φ : G₁ →g G₂) : is_subgroup G₁ (kernel φ) :=
⦃ is_subgroup,
one_mem := respect_one φ,
mul_mem := mul_mem_kernel φ,
inv_mem := inv_mem_kernel φ
end kernels
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/-- Now we should be able to show that if f is a homomorphism for which the kernel is trivial and the
image is full, then f is an isomorphism, except that no one defined the proposition that f is an
isomorphism :/ --/
/- definition is_iso_from_kertriv_imfull {G H : Group} (f : G →g H) :
is_trivial_subgroup G (kernel f) → is_full_subgroup H (image_subgroup f) → unit
/- replace unit by is_isomorphism f -/ := sorry -/
/- #Normal subgroups -/
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/-- Next, we formalize some aspects of normal subgroups. Recall that a normal subgroup H of a
group G is a subgroup which is invariant under all inner automorophisms on G. --/
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definition is_normal.{u v} [constructor] (G : Group) (N : property.{u v} G) : Prop :=
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trunctype.mk (Π{g} h, g ∈ N → h * g * h⁻¹ ∈ N) _
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structure is_normal_subgroup [class] (G : Group) (N : property G) extends is_subgroup G N :=
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(is_normal : is_normal G N)
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abbreviation subgroup_one_mem [unfold 2] := @is_subgroup.one_mem
abbreviation subgroup_mul_mem [unfold 2] := @is_subgroup.mul_mem
abbreviation subgroup_inv_mem [unfold 2] := @is_subgroup.inv_mem
abbreviation subgroup_is_normal [unfold 2] := @is_normal_subgroup.is_normal
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section
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variables {G G' G₁ G₂ G₃ : Group} {H N : property G} [is_subgroup G H]
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[is_normal_subgroup G N] {g g' h h' k : G}
{A B : AbGroup}
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theorem is_normal_subgroup' (h : G) (r : g ∈ N) : h⁻¹ * g * h ∈ N :=
inv_inv h ▸ subgroup_is_normal N h⁻¹ r
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definition is_normal_subgroup_ab [constructor] {C : property A} (subgrpA : is_subgroup A C)
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: is_normal_subgroup A C :=
⦃ is_normal_subgroup, subgrpA,
is_normal := abstract begin
intros g h r, xrewrite [mul.comm h g, mul_inv_cancel_right], exact r
end end⦄
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theorem is_normal_subgroup_rev (h : G) (r : h * g * h⁻¹ ∈ N) : g ∈ N :=
have H : h⁻¹ * (h * g * h⁻¹) * h = g, from calc
h⁻¹ * (h * g * h⁻¹) * h = h⁻¹ * (h * g) * h⁻¹ * h : by rewrite [-mul.assoc h⁻¹]
... = h⁻¹ * (h * g) : by rewrite [inv_mul_cancel_right]
... = g : inv_mul_cancel_left,
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H ▸ is_normal_subgroup' h r
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theorem is_normal_subgroup_rev' (h : G) (r : h⁻¹ * g * h ∈ N) : g ∈ N :=
is_normal_subgroup_rev h⁻¹ ((inv_inv h)⁻¹ ▸ r)
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theorem normal_subgroup_insert (r : k ∈ N) (r' : g * h ∈ N) : g * (k * h) ∈ N :=
have H1 : (g * h) * (h⁻¹ * k * h) ∈ N, from
subgroup_mul_mem r' (is_normal_subgroup' h r),
have H2 : (g * h) * (h⁻¹ * k * h) = g * (k * h), from calc
(g * h) * (h⁻¹ * k * h) = g * (h * (h⁻¹ * k * h)) : mul.assoc
... = g * (h * (h⁻¹ * (k * h))) : by rewrite [mul.assoc h⁻¹]
... = g * (k * h) : by rewrite [mul_inv_cancel_left],
show N (g * (k * h)), from H2 ▸ H1
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/-- In the following, we show that the kernel of any group homomorphism f : G₁ →g G₂ is a normal subgroup of G₁ --/
theorem is_normal_subgroup_kernel {G₁ G₂ : Group} (φ : G₁ →g G₂) (g : G₁) (h : G₁)
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: g ∈ kernel φ → h * g * h⁻¹ ∈ kernel φ :=
begin
esimp at *,
intro p,
exact calc
φ (h * g * h⁻¹) = (φ (h * g)) * φ (h⁻¹) : to_respect_mul
... = (φ h) * (φ g) * (φ h⁻¹) : to_respect_mul
... = (φ h) * 1 * (φ h⁻¹) : p
... = (φ h) * (φ h⁻¹) : mul_one
... = (φ h) * (φ h)⁻¹ : to_respect_inv
... = 1 : mul.right_inv
end
-- this is just (Σ(g : G), H g), but only defined if (H g) is a prop
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definition sg {G : Group} (H : property G) : Type := subtype (λ x, x ∈ H)
local attribute sg [reducible]
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definition subgroup_one [constructor] : sg H := ⟨one, subgroup_one_mem H⟩
definition subgroup_inv [unfold 3] : sg H → sg H :=
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λv, ⟨v.1⁻¹, subgroup_inv_mem v.2⟩
definition subgroup_mul [unfold 3 4] : sg H → sg H → sg H :=
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λv w, ⟨v.1 * w.1, subgroup_mul_mem v.2 w.2⟩
definition subgroup_elt (x : sg H) : G := x.1
section
local notation 1 := subgroup_one
local postfix ⁻¹ := subgroup_inv
local infix * := subgroup_mul
theorem subgroup_mul_assoc (g₁ g₂ g₃ : sg H) : g₁ * g₂ * g₃ = g₁ * (g₂ * g₃) :=
subtype_eq !mul.assoc
theorem subgroup_one_mul (g : sg H) : 1 * g = g :=
subtype_eq !one_mul
theorem subgroup_mul_one (g : sg H) : g * 1 = g :=
subtype_eq !mul_one
theorem subgroup_mul_left_inv (g : sg H) : g⁻¹ * g = 1 :=
subtype_eq !mul.left_inv
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theorem subgroup_mul_comm {G : AbGroup} {H : property G} [subgrpH : is_subgroup G H] (g h : sg H)
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: subgroup_mul g h = subgroup_mul h g :=
subtype_eq !mul.comm
end
variable (H)
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definition group_sg [constructor] : group (sg H) :=
group.mk _ subgroup_mul subgroup_mul_assoc subgroup_one subgroup_one_mul subgroup_mul_one
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subgroup_inv subgroup_mul_left_inv
definition subgroup [constructor] : Group :=
Group.mk _ (group_sg H)
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variable {H}
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definition ab_group_sg [constructor] {G : AbGroup} (H : property G) [is_subgroup G H]
: ab_group (sg H) :=
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⦃ab_group, (group_sg H), mul_comm := subgroup_mul_comm⦄
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definition ab_subgroup [constructor] {G : AbGroup} (H : property G) [is_subgroup G H]
: AbGroup :=
AbGroup.mk _ (ab_group_sg H)
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definition Kernel {G H : Group} (f : G →g H) : Group := subgroup (kernel f)
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definition ab_Kernel {G H : AbGroup} (f : G →g H) : AbGroup := ab_subgroup (kernel f)
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definition incl_of_subgroup [constructor] {G : Group} (H : property G) [is_subgroup G H] :
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subgroup H →g G :=
begin
fapply homomorphism.mk,
-- the underlying function
{ intro h, induction h with g, exact g},
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-- is a homomorphism
intro g h, reflexivity
end
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definition is_embedding_incl_of_subgroup {G : Group} (H : property G) [is_subgroup G H] :
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is_embedding (incl_of_subgroup H) :=
begin
fapply function.is_embedding_of_is_injective,
intro h h',
fapply subtype_eq
end
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definition ab_Kernel_incl {G H : AbGroup} (f : G →g H) : ab_Kernel f →g G :=
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begin
fapply incl_of_subgroup,
end
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definition is_embedding_ab_kernel_incl {G H : AbGroup} (f : G →g H) : is_embedding (ab_Kernel_incl f) :=
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begin
fapply is_embedding_incl_of_subgroup,
end
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definition is_subgroup_of_is_subgroup {G : Group} {H1 H2 : property G} [is_subgroup G H1]
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[is_subgroup G H2] (hyp : Π (g : G), g ∈ H1 → g ∈ H2) :
is_subgroup (subgroup H2) {h | incl_of_subgroup H2 h ∈ H1} :=
is_subgroup.mk
(subgroup_one_mem H1)
(begin
intros g h p q,
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apply mem_property_of,
apply subgroup_mul_mem (of_mem_property_of p) (of_mem_property_of q),
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end)
(begin
intros h p,
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apply mem_property_of,
apply subgroup_inv_mem (of_mem_property_of p)
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end)
definition Image {G H : Group} (f : G →g H) : Group :=
subgroup (image f)
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definition ab_Image {G : AbGroup} {H : Group} (f : G →g H) : AbGroup :=
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AbGroup_of_Group (Image f)
begin
intro g h,
induction g with x t, induction h with y s,
fapply subtype_eq,
induction t with g p, induction s with h q, induction p, induction q,
refine (((respect_mul f g h)⁻¹ ⬝ _) ⬝ (respect_mul f h g)),
apply (ap f),
induction G, induction struct', apply mul_comm
end
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definition image_incl {G H : Group} (f : G →g H) : Image f →g H :=
incl_of_subgroup (image f)
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definition ab_Image_incl {A B : AbGroup} (f : A →g B) : ab_Image f →g B := incl_of_subgroup (image f)
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definition is_equiv_surjection_ab_image_incl {A B : AbGroup} (f : A →g B) (H : is_surjective f) : is_equiv (ab_Image_incl f ) :=
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begin
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fapply is_equiv.adjointify (ab_Image_incl f),
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intro b,
fapply sigma.mk,
exact b,
exact H b,
intro b,
reflexivity,
intro x,
apply subtype_eq,
reflexivity
end
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definition iso_surjection_ab_image_incl [constructor] {A B : AbGroup} (f : A →g B) (H : is_surjective f) : ab_Image f ≃g B :=
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begin
fapply isomorphism.mk,
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exact (ab_Image_incl f),
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exact is_equiv_surjection_ab_image_incl f H
end
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definition hom_lift [constructor] {G H : Group} (f : G →g H) (K : property H) [is_subgroup H K] (Hyp : Π (g : G), K (f g)) : G →g subgroup K :=
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begin
fapply homomorphism.mk,
intro g,
fapply sigma.mk,
exact f g,
fapply Hyp,
intro g h, apply subtype_eq, esimp, apply respect_mul
end
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definition hom_factors_through_lift {G H : Group} (f : G →g H) (K : property H) [is_subgroup H K] (Hyp : Π (g : G), K (f g)) :
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f = incl_of_subgroup K ∘g hom_lift f K Hyp :=
begin
fapply homomorphism_eq,
reflexivity
end
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definition ab_hom_lift [constructor] {G H : AbGroup} (f : G →g H) (K : property H) [is_subgroup H K] (Hyp : Π (g : G), K (f g)) : G →g ab_subgroup K :=
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begin
fapply homomorphism.mk,
intro g,
fapply sigma.mk,
exact f g,
fapply Hyp,
intro g h, apply subtype_eq, apply respect_mul,
end
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definition ab_hom_factors_through_lift {G H : AbGroup} (f : G →g H) (K : property H) [is_subgroup H K] (Hyp : Π (g : G), K (f g)) :
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f = incl_of_subgroup K ∘g hom_lift f K Hyp :=
begin
fapply homomorphism_eq,
reflexivity
end
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definition ab_hom_lift_kernel [constructor] {A B C : AbGroup} (f : A →g B) (g : B →g C) (Hyp : Π (a : A), g (f a) = 1) : A →g ab_Kernel g :=
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begin
fapply ab_hom_lift,
exact f,
intro a,
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exact Hyp a,
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end
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definition ab_hom_lift_kernel_factors {A B C : AbGroup} (f : A →g B) (g : B →g C) (Hyp : Π (a : A), g (f a) = 1) :
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f = ab_Kernel_incl g ∘g ab_hom_lift_kernel f g Hyp :=
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begin
fapply ab_hom_factors_through_lift,
end
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definition image_lift [constructor] {G H : Group} (f : G →g H) : G →g Image f :=
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begin
fapply hom_lift f,
intro g,
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apply tr,
fapply fiber.mk,
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exact g, reflexivity
end
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definition ab_image_lift [constructor] {G H : AbGroup} (f : G →g H) : G →g Image f :=
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begin
fapply hom_lift f,
intro g,
apply tr,
fapply fiber.mk,
exact g, reflexivity
end
definition is_surjective_image_lift {G H : Group} (f : G →g H) : is_surjective (image_lift f) :=
begin
intro h,
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induction h with h p, induction p with g,
fapply image.mk,
exact g, induction p, reflexivity
end
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definition image_factor {G H : Group} (f : G →g H) : f = (image_incl f) ∘g (image_lift f) :=
begin
fapply homomorphism_eq,
reflexivity
end
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definition image_incl_injective {G H : Group} (f : G →g H) : Π (x y : Image f),
(image_incl f x = image_incl f y) → (x = y) :=
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begin
intro x y,
intro p,
fapply subtype_eq,
exact p
end
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definition image_incl_eq_one {G H : Group} (f : G →g H) :
Π (x : Image f), (image_incl f x = 1) → x = 1 :=
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begin
intro x,
fapply image_incl_injective f x 1,
end
definition image_elim_lemma {f₁ : G₁ →g G₂} {f₂ : G₁ →g G₃} (h : Π⦃g⦄, f₁ g = 1 → f₂ g = 1)
(g g' : G₁) (p : f₁ g = f₁ g') : f₂ g = f₂ g' :=
have f₁ (g * g'⁻¹) = 1, from !to_respect_mul ⬝ ap (mul _) !to_respect_inv ⬝
mul_inv_eq_of_eq_mul (p ⬝ !one_mul⁻¹),
have f₂ (g * g'⁻¹) = 1, from h this,
eq_of_mul_inv_eq_one (ap (mul _) !to_respect_inv⁻¹ ⬝ !to_respect_mul⁻¹ ⬝ this)
open image
definition image_elim {f₁ : G₁ →g G₂} (f₂ : G₁ →g G₃) (h : Π⦃g⦄, f₁ g = 1 → f₂ g = 1) :
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Image f₁ →g G₃ :=
homomorphism.mk (total_image.elim_set f₂ (image_elim_lemma h))
begin
refine total_image.rec _, intro g,
refine total_image.rec _, intro g',
exact to_respect_mul f₂ g g'
end
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end
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definition image_homomorphism {A B C : AbGroup} (f : A →g B) (g : B →g C) :
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ab_Image f →g ab_Image (g ∘g f) :=
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begin
fapply image_elim,
exact image_lift (g ∘g f),
intro a p,
fapply subtype_eq, unfold image_lift,
exact calc
g (f a) = g 1 : by exact ap g p
... = 1 : to_respect_one,
end
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definition image_homomorphism_square {A B C : AbGroup} (f : A →g B) (g : B →g C) :
g ∘g image_incl f ~ image_incl (g ∘g f ) ∘g image_homomorphism f g :=
begin
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intro x, induction x with b p, induction p with x, induction p, reflexivity
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end
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variables {G H K : Group} {R : property G} [is_subgroup G R]
{S : property H} [is_subgroup H S] {T : property K} [is_subgroup K T]
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open function
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definition subgroup_functor_fun [unfold 7] (φ : G →g H) (h : Πg, g ∈ R → φ g ∈ S)
(x : subgroup R) :
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subgroup S :=
begin
induction x with g hg,
exact ⟨φ g, h g hg⟩
end
definition subgroup_functor [constructor] (φ : G →g H)
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(h : Πg, g ∈ R → φ g ∈ S) : subgroup R →g subgroup S :=
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begin
fapply homomorphism.mk,
{ exact subgroup_functor_fun φ h },
{ intro x₁ x₂, induction x₁ with g₁ hg₁, induction x₂ with g₂ hg₂,
exact sigma_eq !to_respect_mul !is_prop.elimo }
end
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definition ab_subgroup_functor [constructor] {G H : AbGroup}
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{R : property G} [is_subgroup G R]
{S : property H} [is_subgroup H S]
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(φ : G →g H)
(h : Πg, g ∈ R → φ g ∈ S) : ab_subgroup R →g ab_subgroup S :=
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subgroup_functor φ h
theorem subgroup_functor_compose (ψ : H →g K) (φ : G →g H)
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(hψ : Πg, g ∈ S → ψ g ∈ T) (hφ : Πg, g ∈ R → φ g ∈ S) :
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subgroup_functor ψ hψ ∘g subgroup_functor φ hφ ~
subgroup_functor (ψ ∘g φ) (λg, proof hψ (φ g) qed ∘ hφ g) :=
begin
intro g, induction g with g hg, reflexivity
end
definition subgroup_functor_gid : subgroup_functor (gid G) (λg, id) ~ gid (subgroup R) :=
begin
intro g, induction g with g hg, reflexivity
end
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definition subgroup_functor_mul {G H : AbGroup} {R : property G} [subgroupR : is_subgroup G R]
{S : property H} [subgroupS : is_subgroup H S]
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(ψ φ : G →g H) (hψ : Πg, g ∈ R → ψ g ∈ S) (hφ : Πg, g ∈ R → φ g ∈ S) :
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homomorphism_mul (ab_subgroup_functor ψ hψ) (ab_subgroup_functor φ hφ) ~
ab_subgroup_functor (homomorphism_mul ψ φ)
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(λg hg, subgroup_mul_mem (hψ g hg) (hφ g hg)) :=
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begin
intro g, induction g with g hg, reflexivity
end
definition subgroup_functor_homotopy {ψ φ : G →g H} (hψ : Πg, R g → S (ψ g))
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(hφ : Πg, g ∈ R → φ g ∈ S) (p : φ ~ ψ) :
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subgroup_functor φ hφ ~ subgroup_functor ψ hψ :=
begin
intro g, induction g with g hg,
exact subtype_eq (p g)
end
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definition subgroup_of_subgroup_incl {R S : property G} [is_subgroup G R] [is_subgroup G S]
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(H : Π (g : G), g ∈ R → g ∈ S) : subgroup R →g subgroup S
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:=
subgroup_functor (gid G) H
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definition is_embedding_subgroup_of_subgroup_incl {R S : property G} [is_subgroup G R] [is_subgroup G S]
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(H : Π (g : G), g ∈ R -> g ∈ S) : is_embedding (subgroup_of_subgroup_incl H) :=
begin
fapply is_embedding_of_is_injective,
intro x y p,
induction x with x r, induction y with y s,
fapply subtype_eq, esimp,
unfold subgroup_of_subgroup_incl at p, exact ap pr1 p,
end
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definition ab_subgroup_of_subgroup_incl {A : AbGroup} {R S : property A} [is_subgroup A R] [is_subgroup A S]
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(H : Π (a : A), a ∈ R → a ∈ S) : ab_subgroup R →g ab_subgroup S
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:=
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ab_subgroup_functor (gid A) H
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definition is_embedding_ab_subgroup_of_subgroup_incl {A : AbGroup} {R S : property A} [is_subgroup A R] [is_subgroup A S]
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(H : Π (a : A), a ∈ R → a ∈ S) : is_embedding (ab_subgroup_of_subgroup_incl H) :=
begin
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fapply is_embedding_subgroup_of_subgroup_incl
end
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definition ab_subgroup_iso {A : AbGroup} {R S : property A} [is_subgroup A R] [is_subgroup A S]
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(H : Π (a : A), a ∈ R → a ∈ S) (K : Π (a : A), a ∈ S → a ∈ R) :
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ab_subgroup R ≃g ab_subgroup S :=
begin
fapply isomorphism.mk,
exact subgroup_of_subgroup_incl H,
fapply is_equiv.adjointify,
exact subgroup_of_subgroup_incl K,
intro s, induction s with a p, fapply subtype_eq, reflexivity,
intro r, induction r with a p, fapply subtype_eq, reflexivity
end
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definition ab_subgroup_iso_triangle {A : AbGroup} {R S : property A} [is_subgroup A R] [is_subgroup A S]
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(H : Π (a : A), a ∈ R → a ∈ S) (K : Π (a : A), a ∈ S → a ∈ R) :
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incl_of_subgroup R ~ incl_of_subgroup S ∘g ab_subgroup_iso H K :=
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begin
intro r, induction r, reflexivity
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end
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end group
open group
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attribute is_subgroup_image [constructor]
attribute is_subgroup_kernel [constructor]