Spectral/algebra/submodule.hlean

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/- submodules and quotient modules -/
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-- Authors: Floris van Doorn, Jeremy Avigad
import .left_module .quotient_group .module_chain_complex
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open algebra eq group sigma sigma.ops is_trunc function trunc equiv is_equiv property
universe variable u
namespace left_module
/- submodules -/
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variables {R : Ring} {M M₁ M₁' M₂ M₂' M₃ M₃' : LeftModule R} {m m₁ m₂ : M}
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structure is_submodule [class] (M : LeftModule R) (S : property M) : Type :=
(zero_mem : 0 ∈ S)
(add_mem : Π⦃g h⦄, g ∈ S → h ∈ S → g + h ∈ S)
(smul_mem : Π⦃g⦄ (r : R), g ∈ S → r • g ∈ S)
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definition zero_mem {R : Ring} {M : LeftModule R} (S : property M) [is_submodule M S] := is_submodule.zero_mem S
definition add_mem {R : Ring} {M : LeftModule R} (S : property M) [is_submodule M S] := @is_submodule.add_mem R M S
definition smul_mem {R : Ring} {M : LeftModule R} (S : property M) [is_submodule M S] := @is_submodule.smul_mem R M S
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theorem neg_mem (S : property M) [is_submodule M S] ⦃m⦄ (H : m ∈ S) : -m ∈ S :=
transport (λx, x ∈ S) (neg_one_smul m) (smul_mem S (- 1) H)
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theorem is_normal_submodule (S : property M) [is_submodule M S] ⦃m₁ m₂⦄ (H : S m₁) : S (m₂ + m₁ + (-m₂)) :=
transport (λx, S x) (by rewrite [add.comm, neg_add_cancel_left]) H
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-- open is_submodule
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variables {S : property M} [is_submodule M S] {S₂ : property M₂} [is_submodule M₂ S₂]
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definition is_subgroup_of_is_submodule [instance] (S : property M) [is_submodule M S] :
is_subgroup (AddGroup_of_AddAbGroup M) S :=
is_subgroup.mk (zero_mem S) (add_mem S) (neg_mem S)
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definition is_subgroup_of_is_submodule' [instance] (S : property M) [is_submodule M S] : is_subgroup (Group_of_AbGroup (AddAbGroup_of_LeftModule M)) S :=
is_subgroup.mk (zero_mem S) (add_mem S) (neg_mem S)
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definition submodule' (S : property M) [is_submodule M S] : AddAbGroup :=
ab_subgroup S -- (subgroup_rel_of_submodule_rel S)
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definition submodule_smul [constructor] (S : property M) [is_submodule M S] (r : R) :
submodule' S →a submodule' S :=
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ab_subgroup_functor (smul_homomorphism M r) (λg, smul_mem S r)
definition submodule_smul_right_distrib (r s : R) (n : submodule' S) :
submodule_smul S (r + s) n = submodule_smul S r n + submodule_smul S s n :=
begin
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refine subgroup_functor_homotopy _ _ _ n ⬝ !subgroup_functor_mul⁻¹ᵖ,
intro m, exact to_smul_right_distrib r s m
end
definition submodule_mul_smul' (r s : R) (n : submodule' S) :
submodule_smul S (r * s) n = (submodule_smul S r ∘g submodule_smul S s) n :=
begin
refine subgroup_functor_homotopy _ _ _ n ⬝ (subgroup_functor_compose _ _ _ _ n)⁻¹ᵖ,
intro m, exact to_mul_smul r s m
end
definition submodule_mul_smul (r s : R) (n : submodule' S) :
submodule_smul S (r * s) n = submodule_smul S r (submodule_smul S s n) :=
by rexact submodule_mul_smul' r s n
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definition submodule_one_smul (n : submodule' S) : submodule_smul S (1 : R) n = n :=
begin
refine subgroup_functor_homotopy _ _ _ n ⬝ !subgroup_functor_gid,
intro m, exact to_one_smul m
end
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definition submodule (S : property M) [is_submodule M S] : LeftModule R :=
LeftModule_of_AddAbGroup (submodule' S) (submodule_smul S)
(λr, homomorphism.addstruct (submodule_smul S r))
submodule_smul_right_distrib
submodule_mul_smul
submodule_one_smul
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definition submodule_incl [constructor] (S : property M) [is_submodule M S] : submodule S →lm M :=
lm_homomorphism_of_group_homomorphism (incl_of_subgroup _)
begin
intro r m, induction m with m hm, reflexivity
end
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definition hom_lift [constructor] {K : property M₂} [is_submodule M₂ K] (φ : M₁ →lm M₂)
(h : Π (m : M₁), φ m ∈ K) : M₁ →lm submodule K :=
lm_homomorphism_of_group_homomorphism (hom_lift (group_homomorphism_of_lm_homomorphism φ) _ h)
begin
intro r g, exact subtype_eq (to_respect_smul φ r g)
end
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definition submodule_functor [constructor] {S : property M₁} [is_submodule M₁ S]
{K : property M₂} [is_submodule M₂ K]
(φ : M₁ →lm M₂) (h : Π (m : M₁), m ∈ S → φ m ∈ K) : submodule S →lm submodule K :=
hom_lift (φ ∘lm submodule_incl S) (by intro m; exact h m.1 m.2)
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definition hom_lift_compose {K : property M₃} [is_submodule M₃ K]
(φ : M₂ →lm M₃) (h : Π (m : M₂), φ m ∈ K) (ψ : M₁ →lm M₂) :
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hom_lift φ h ∘lm ψ ~ hom_lift (φ ∘lm ψ) proof (λm, h (ψ m)) qed :=
by reflexivity
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definition hom_lift_homotopy {K : property M₂} [is_submodule M₂ K] {φ : M₁ →lm M₂}
{h : Π (m : M₁), φ m ∈ K} {φ' : M₁ →lm M₂}
{h' : Π (m : M₁), φ' m ∈ K} (p : φ ~ φ') : hom_lift φ h ~ hom_lift φ' h' :=
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λg, subtype_eq (p g)
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definition incl_smul (S : property M) [is_submodule M S] (r : R) (m : M) (h : S m) :
r • ⟨m, h⟩ = ⟨_, smul_mem S r h⟩ :> submodule S :=
by reflexivity
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definition property_submodule (S₁ S₂ : property M) [is_submodule M S₁] [is_submodule M S₂] :
property (submodule S₁) := {m | submodule_incl S₁ m ∈ S₂}
definition is_submodule_property_submodule [instance] (S₁ S₂ : property M) [is_submodule M S₁] [is_submodule M S₂] :
is_submodule (submodule S₁) (property_submodule S₁ S₂) :=
is_submodule.mk
(mem_property_of (zero_mem S₂))
(λm n p q, mem_property_of (add_mem S₂ (of_mem_property_of p) (of_mem_property_of q)))
begin
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intro m r p, induction m with m hm, apply mem_property_of,
apply smul_mem S₂, exact (of_mem_property_of p)
end
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definition eq_zero_of_mem_property_submodule_trivial [constructor] {S₁ S₂ : property M} [is_submodule M S₁] [is_submodule M S₂]
(h : Π⦃m⦄, m ∈ S₂ → m = 0) ⦃m : submodule S₁⦄ (Sm : m ∈ property_submodule S₁ S₂) : m = 0 :=
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begin
fapply subtype_eq,
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apply h (of_mem_property_of Sm)
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end
definition is_contr_submodule (S : property M) [is_submodule M S] (H : is_contr M) :
is_contr (submodule S) :=
have is_prop M, from _,
have is_prop (submodule S), from @is_trunc_sigma _ _ _ this _,
is_contr_of_inhabited_prop 0 this
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definition submodule_isomorphism [constructor] (S : property M) [is_submodule M S] (h : Πg, g ∈ S) :
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submodule S ≃lm M :=
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isomorphism.mk (submodule_incl S) (is_equiv_incl_of_subgroup S h)
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definition submodule_isomorphism_submodule [constructor] {S : property M₁} [is_submodule M₁ S]
{K : property M₂} [is_submodule M₂ K]
(φ : M₁ ≃lm M₂) (h : Π (m : M₁), m ∈ S ↔ φ m ∈ K) : submodule S ≃lm submodule K :=
lm_isomorphism_of_group_isomorphism
(subgroup_isomorphism_subgroup (group_isomorphism_of_lm_isomorphism φ) h)
(by rexact to_respect_smul (submodule_functor φ (λg, iff.mp (h g))))
/- quotient modules -/
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definition quotient_module' (S : property M) [is_submodule M S] : AddAbGroup :=
quotient_ab_group S -- (subgroup_rel_of_submodule_rel S)
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definition quotient_module_smul [constructor] (S : property M) [is_submodule M S] (r : R) :
quotient_module' S →a quotient_module' S :=
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quotient_ab_group_functor (smul_homomorphism M r) (λg, smul_mem S r)
definition quotient_module_smul_right_distrib (r s : R) (n : quotient_module' S) :
quotient_module_smul S (r + s) n = quotient_module_smul S r n + quotient_module_smul S s n :=
begin
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refine quotient_ab_group_functor_homotopy _ _ _ n ⬝ !quotient_ab_group_functor_mul⁻¹,
intro m, exact to_smul_right_distrib r s m
end
definition quotient_module_mul_smul' (r s : R) (n : quotient_module' S) :
quotient_module_smul S (r * s) n = (quotient_module_smul S r ∘g quotient_module_smul S s) n :=
begin
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apply eq.symm,
apply eq.trans (quotient_ab_group_functor_compose _ _ _ _ n),
apply quotient_ab_group_functor_homotopy,
intro m, exact eq.symm (to_mul_smul r s m)
end
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-- previous proof:
-- refine quotient_ab_group_functor_homotopy _ _ _ n ⬝
-- (quotient_ab_group_functor_compose (quotient_module_smul S r) (quotient_module_smul S s) _ _ n)⁻¹ᵖ,
-- intro m, to_mul_smul r s m
definition quotient_module_mul_smul (r s : R) (n : quotient_module' S) :
quotient_module_smul S (r * s) n = quotient_module_smul S r (quotient_module_smul S s n) :=
by rexact quotient_module_mul_smul' r s n
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definition quotient_module_one_smul (n : quotient_module' S) : quotient_module_smul S (1 : R) n = n :=
begin
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refine quotient_ab_group_functor_homotopy _ _ _ n ⬝ !quotient_ab_group_functor_gid,
intro m, exact to_one_smul m
end
variable (S)
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definition quotient_module (S : property M) [is_submodule M S] : LeftModule R :=
LeftModule_of_AddAbGroup (quotient_module' S) (quotient_module_smul S)
(λr, homomorphism.addstruct (quotient_module_smul S r))
quotient_module_smul_right_distrib
quotient_module_mul_smul
quotient_module_one_smul
definition quotient_map [constructor] : M →lm quotient_module S :=
lm_homomorphism_of_group_homomorphism (ab_qg_map _) (λr g, idp)
definition quotient_map_eq_zero (m : M) (H : S m) : quotient_map S m = 0 :=
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@ab_qg_map_eq_one _ _ _ _ H
definition rel_of_quotient_map_eq_zero (m : M) (H : quotient_map S m = 0) : S m :=
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@rel_of_qg_map_eq_one _ _ _ m H
variable {S}
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definition respect_smul_quotient_elim [constructor] (φ : M →lm M₂) (H : Π⦃m⦄, m ∈ S → φ m = 0)
(r : R) (m : quotient_module S) :
quotient_ab_group_elim (group_homomorphism_of_lm_homomorphism φ) H
(@has_scalar.smul _ (quotient_module S) _ r m) =
r • quotient_ab_group_elim (group_homomorphism_of_lm_homomorphism φ) H m :=
begin
revert m,
refine @set_quotient.rec_prop _ _ _ (λ x, !is_trunc_eq) _,
intro m,
exact to_respect_smul φ r m
end
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definition quotient_elim [constructor] (φ : M →lm M₂) (H : Π⦃m⦄, m ∈ S → φ m = 0) :
quotient_module S →lm M₂ :=
lm_homomorphism_of_group_homomorphism
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(quotient_ab_group_elim (group_homomorphism_of_lm_homomorphism φ) H)
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(respect_smul_quotient_elim φ H)
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definition is_prop_quotient_module (S : property M) [is_submodule M S] [H : is_prop M] : is_prop (quotient_module S) :=
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begin apply @set_quotient.is_trunc_set_quotient, exact H end
definition is_contr_quotient_module [instance] (S : property M) [is_submodule M S]
(H : is_contr M) : is_contr (quotient_module S) :=
have is_prop M, from _,
have is_prop (quotient_module S), from @set_quotient.is_trunc_set_quotient _ _ _ this,
is_contr_of_inhabited_prop 0 this
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definition rel_of_is_contr_quotient_module (S : property M) [is_submodule M S]
(H : is_contr (quotient_module S)) (m : M) : S m :=
rel_of_quotient_map_eq_zero S m (@eq_of_is_contr _ H _ _)
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definition quotient_module_isomorphism [constructor] (S : property M) [is_submodule M S] (h : Π⦃m⦄, S m → m = 0) :
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quotient_module S ≃lm M :=
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(isomorphism.mk (quotient_map S) (is_equiv_ab_qg_map S h))⁻¹ˡᵐ
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definition quotient_module_functor [constructor] (φ : M →lm M₂) (h : Πg, g ∈ S → φ g ∈ S₂) :
quotient_module S →lm quotient_module S₂ :=
quotient_elim (quotient_map S₂ ∘lm φ)
begin intros m Hm, rexact quotient_map_eq_zero S₂ (φ m) (h m Hm) end
definition quotient_module_isomorphism_quotient_module [constructor] (φ : M ≃lm M₂)
(h : Πm, m ∈ S ↔ φ m ∈ S₂) : quotient_module S ≃lm quotient_module S₂ :=
lm_isomorphism_of_group_isomorphism
(quotient_ab_group_isomorphism_quotient_ab_group (group_isomorphism_of_lm_isomorphism φ) h)
(to_respect_smul (quotient_module_functor φ (λg, iff.mp (h g))))
/- specific submodules -/
definition has_scalar_image (φ : M₁ →lm M₂) ⦃m : M₂⦄ (r : R)
(h : image φ m) : image φ (r • m) :=
begin
induction h with m' p,
apply image.mk (r • m'),
refine to_respect_smul φ r m' ⬝ ap (λx, r • x) p,
end
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definition is_submodule_image [instance] (φ : M₁ →lm M₂) : is_submodule M₂ (image φ) :=
is_submodule.mk
(show 0 ∈ image (group_homomorphism_of_lm_homomorphism φ),
begin apply is_subgroup.one_mem, apply is_subgroup_image end)
(λ g₁ g₂ hg₁ hg₂,
show g₁ + g₂ ∈ image (group_homomorphism_of_lm_homomorphism φ),
begin
apply @is_subgroup.mul_mem,
apply is_subgroup_image, exact hg₁, exact hg₂
end)
(has_scalar_image φ)
/-
definition image_rel [constructor] (φ : M₁ →lm M₂) : submodule_rel M₂ :=
submodule_rel_of_subgroup_rel
(image_subgroup (group_homomorphism_of_lm_homomorphism φ))
(has_scalar_image φ)
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-/
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definition image_trivial (φ : M₁ →lm M₂) [H : is_contr M₁] ⦃m : M₂⦄ (h : m ∈ image φ) : m = 0 :=
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begin
refine image.rec _ h,
intro x p,
refine p⁻¹ ⬝ ap φ _ ⬝ to_respect_zero φ,
apply @is_prop.elim, apply is_trunc_succ, exact H
end
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definition image_module [constructor] (φ : M₁ →lm M₂) : LeftModule R := submodule (image φ)
-- unfortunately this is note definitionally equal:
-- definition foo (φ : M₁ →lm M₂) :
-- (image_module φ : AddAbGroup) = image (group_homomorphism_of_lm_homomorphism φ) :=
-- by reflexivity
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definition image_lift [constructor] (φ : M₁ →lm M₂) : M₁ →lm image_module φ :=
hom_lift φ (λm, image.mk m idp)
definition is_surjective_image_lift (φ : M₁ →lm M₂) : is_surjective (image_lift φ) :=
begin
refine total_image.rec _, intro m, exact image.mk m (subtype_eq idp)
end
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variables {ψ : M₂ →lm M₃} {φ : M₁ →lm M₂} {θ : M₁ →lm M₃} {ψ' : M₂' →lm M₃'} {φ' : M₁' →lm M₂'}
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definition image_elim [constructor] (θ : M₁ →lm M₃) (h : Π⦃g⦄, φ g = 0 → θ g = 0) :
image_module φ →lm M₃ :=
begin
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fapply homomorphism.mk,
change Image (group_homomorphism_of_lm_homomorphism φ) → M₃,
exact image_elim (group_homomorphism_of_lm_homomorphism θ) h,
split,
{ exact homomorphism.struct (image_elim (group_homomorphism_of_lm_homomorphism θ) _) },
{ intro r, refine @total_image.rec _ _ _ _ (λx, !is_trunc_eq) _, intro g,
apply to_respect_smul }
end
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definition image_elim_compute (h : Π⦃g⦄, φ g = 0 → θ g = 0) :
image_elim θ h ∘lm image_lift φ ~ θ :=
begin
reflexivity
end
-- definition image_elim_hom_lift (ψ : M →lm M₂) (h : Π⦃g⦄, φ g = 0 → θ g = 0) :
-- image_elim θ h ∘lm hom_lift ψ _ ~ _ :=
-- begin
-- reflexivity
-- end
definition is_contr_image_module [instance] (φ : M₁ →lm M₂) (H : is_contr M₂) :
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is_contr (image_module φ) :=
is_contr_submodule _ _
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definition is_contr_image_module_of_is_contr_dom (φ : M₁ →lm M₂) (H : is_contr M₁) :
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is_contr (image_module φ) :=
is_contr.mk 0
begin
have Π(x : image_module φ), is_prop (0 = x), from _,
apply @total_image.rec,
exact this,
intro m,
have h : is_contr (LeftModule.carrier M₁), from H,
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induction (eq_of_is_contr 0 m), apply subtype_eq,
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exact (to_respect_zero φ)⁻¹
end
definition image_module_isomorphism [constructor] (φ : M₁ →lm M₂)
(H : is_surjective φ) : image_module φ ≃lm M₂ :=
submodule_isomorphism _ H
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definition has_scalar_kernel (φ : M₁ →lm M₂) ⦃m : M₁⦄ (r : R)
(p : φ m = 0) : φ (r • m) = 0 :=
begin
refine to_respect_smul φ r m ⬝ ap (λx, r • x) p ⬝ smul_zero r,
end
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definition lm_kernel [reducible] (φ : M₁ →lm M₂) : property M₁ := kernel (group_homomorphism_of_lm_homomorphism φ)
definition is_submodule_kernel [instance] (φ : M₁ →lm M₂) : is_submodule M₁ (lm_kernel φ) :=
is_submodule.mk
(show 0 ∈ kernel (group_homomorphism_of_lm_homomorphism φ),
begin apply is_subgroup.one_mem, apply is_subgroup_kernel end)
(λ g₁ g₂ hg₁ hg₂,
show g₁ + g₂ ∈ kernel (group_homomorphism_of_lm_homomorphism φ),
begin apply @is_subgroup.mul_mem, apply is_subgroup_kernel, exact hg₁, exact hg₂ end)
(has_scalar_kernel φ)
definition kernel_full (φ : M₁ →lm M₂) (H : is_contr M₂) (m : M₁) : m ∈ lm_kernel φ :=
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!is_prop.elim
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definition kernel_module [reducible] (φ : M₁ →lm M₂) : LeftModule R := submodule (lm_kernel φ)
definition is_contr_kernel_module [instance] (φ : M₁ →lm M₂) (H : is_contr M₁) :
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is_contr (kernel_module φ) :=
is_contr_submodule _ _
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definition kernel_module_isomorphism [constructor] (φ : M₁ →lm M₂) (H : is_contr M₂) :
kernel_module φ ≃lm M₁ :=
submodule_isomorphism _ (kernel_full φ _)
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definition homology_quotient_property (ψ : M₂ →lm M₃) (φ : M₁ →lm M₂) :
property (kernel_module ψ) :=
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property_submodule (lm_kernel ψ) (image (homomorphism_fn φ))
definition is_submodule_homology_property [instance] (ψ : M₂ →lm M₃) (φ : M₁ →lm M₂) :
is_submodule (kernel_module ψ) (homology_quotient_property ψ φ) :=
(is_submodule_property_submodule _ (image φ))
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definition homology (ψ : M₂ →lm M₃) (φ : M₁ →lm M₂) : LeftModule R :=
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quotient_module (homology_quotient_property ψ φ)
definition homology.mk (φ : M₁ →lm M₂) (m : M₂) (h : ψ m = 0) : homology ψ φ :=
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quotient_map (homology_quotient_property ψ φ) ⟨m, h⟩
definition homology_eq0 {m : M₂} {hm : ψ m = 0} (h : image φ m) :
homology.mk φ m hm = 0 :=
ab_qg_map_eq_one _ h
definition homology_eq0' {m : M₂} {hm : ψ m = 0} (h : image φ m):
homology.mk φ m hm = homology.mk φ 0 (to_respect_zero ψ) :=
ab_qg_map_eq_one _ h
definition homology_eq {m n : M₂} {hm : ψ m = 0} {hn : ψ n = 0} (h : image φ (m - n)) :
homology.mk φ m hm = homology.mk φ n hn :=
eq_of_sub_eq_zero (homology_eq0 h)
definition homology_elim [constructor] (θ : M₂ →lm M) (H : Πm, θ (φ m) = 0) :
homology ψ φ →lm M :=
quotient_elim (θ ∘lm submodule_incl _)
begin
intro m x,
induction m with m h,
esimp at *,
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induction x with v,
exact ap θ p⁻¹ ⬝ H v -- m'
end
definition is_contr_homology [instance] (ψ : M₂ →lm M₃) (φ : M₁ →lm M₂) (H : is_contr M₂) :
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is_contr (homology ψ φ) :=
is_contr_quotient_module _ (is_contr_kernel_module _ _)
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definition homology_isomorphism [constructor] (ψ : M₂ →lm M₃) (φ : M₁ →lm M₂)
(H₁ : is_contr M₁) (H₃ : is_contr M₃) : homology ψ φ ≃lm M₂ :=
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(quotient_module_isomorphism (homology_quotient_property ψ φ)
(eq_zero_of_mem_property_submodule_trivial (image_trivial _))) ⬝lm (kernel_module_isomorphism ψ _)
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definition homology_functor [constructor] (α₁ : M₁ →lm M₁') (α₂ : M₂ →lm M₂') (α₃ : M₃ →lm M₃')
(p : hsquare ψ ψ' α₂ α₃) (q : hsquare φ φ' α₁ α₂) : homology ψ φ →lm homology ψ' φ' :=
begin
fapply quotient_module_functor,
{ apply submodule_functor α₂, intro m pm, refine (p m)⁻¹ ⬝ ap α₃ pm ⬝ to_respect_zero α₃ },
{ intro m pm, induction pm with m' pm',
refine image.mk (α₁ m') ((q m')⁻¹ ⬝ _), exact ap α₂ pm' }
end
definition homology_isomorphism_homology [constructor] (α₁ : M₁ ≃lm M₁') (α₂ : M₂ ≃lm M₂') (α₃ : M₃ ≃lm M₃')
(p : hsquare ψ ψ' α₂ α₃) (q : hsquare φ φ' α₁ α₂) : homology ψ φ ≃lm homology ψ' φ' :=
begin
fapply quotient_module_isomorphism_quotient_module,
{ fapply submodule_isomorphism_submodule α₂, intro m,
exact iff.intro (λpm, (p m)⁻¹ ⬝ ap α₃ pm ⬝ to_respect_zero α₃)
(λpm, inj (equiv_of_isomorphism α₃) (p m ⬝ pm ⬝ (to_respect_zero α₃)⁻¹)) },
{ intro m, apply iff.intro,
{ intro pm, induction pm with m' pm', refine image.mk (α₁ m') ((q m')⁻¹ ⬝ _), exact ap α₂ pm' },
{ intro pm, induction pm with m' pm', refine image.mk (α₁⁻¹ˡᵐ m') _,
refine (hvinverse' (equiv_of_isomorphism α₁) (equiv_of_isomorphism α₂) q m')⁻¹ ⬝ _,
exact ap α₂⁻¹ˡᵐ pm' ⬝ to_left_inv (equiv_of_isomorphism α₂) m.1 }}
end
definition ker_in_im_of_is_contr_homology (ψ : M₂ →lm M₃) {φ : M₁ →lm M₂}
(H₁ : is_contr (homology ψ φ)) {m : M₂} (p : ψ m = 0) : image φ m :=
rel_of_is_contr_quotient_module _ H₁ ⟨m, p⟩
definition is_embedding_of_is_contr_homology_of_constant {ψ : M₂ →lm M₃} (φ : M₁ →lm M₂)
(H₁ : is_contr (homology ψ φ)) (H₂ : Πm, φ m = 0) : is_embedding ψ :=
begin
apply to_is_embedding_homomorphism (group_homomorphism_of_lm_homomorphism ψ),
intro m p, note H := rel_of_is_contr_quotient_module _ H₁ ⟨m, p⟩,
induction H with n q,
exact q⁻¹ ⬝ H₂ n
end
definition is_embedding_of_is_contr_homology_of_is_contr {ψ : M₂ →lm M₃} (φ : M₁ →lm M₂)
(H₁ : is_contr (homology ψ φ)) (H₂ : is_contr M₁) : is_embedding ψ :=
is_embedding_of_is_contr_homology_of_constant φ H₁
(λm, ap φ (@eq_of_is_contr _ H₂ _ _) ⬝ respect_zero φ)
definition is_surjective_of_is_contr_homology_of_constant (ψ : M₂ →lm M₃) {φ : M₁ →lm M₂}
(H₁ : is_contr (homology ψ φ)) (H₂ : Πm, ψ m = 0) : is_surjective φ :=
λm, ker_in_im_of_is_contr_homology ψ H₁ (H₂ m)
definition is_surjective_of_is_contr_homology_of_is_contr (ψ : M₂ →lm M₃) {φ : M₁ →lm M₂}
(H₁ : is_contr (homology ψ φ)) (H₂ : is_contr M₃) : is_surjective φ :=
is_surjective_of_is_contr_homology_of_constant ψ H₁ (λm, @eq_of_is_contr _ H₂ _ _)
definition homology_isomorphism_kernel_module (ψ : M₂ →lm M₃) (φ : M₁ →lm M₂)
(H : Πm, image φ m → m = 0) : homology ψ φ ≃lm kernel_module ψ :=
begin
apply quotient_module_isomorphism, intro m h, apply subtype_eq, apply H, exact h
end
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definition cokernel_module (φ : M₁ →lm M₂) : LeftModule R :=
quotient_module (image φ)
definition homology_isomorphism_cokernel_module (ψ : M₂ →lm M₃) (φ : M₁ →lm M₂) (H : Πm, ψ m = 0) :
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homology ψ φ ≃lm cokernel_module φ :=
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quotient_module_isomorphism_quotient_module
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(submodule_isomorphism _ H)
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begin intro m, reflexivity end
open chain_complex fin nat
definition LES_of_SESs {N : succ_str} (A B C : N → LeftModule.{_ u} R) (φ : Πn, A n →lm B n)
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(ses : Πn : N, short_exact_mod (cokernel_module (φ (succ_str.S n))) (C n) (kernel_module (φ n))) :
module_chain_complex.{_ _ u} R (stratified N 2) :=
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begin
fapply module_chain_complex.mk,
{ intro x, induction x with n k, induction k with k H, do 3 (cases k with k; rotate 1),
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{ /-k≥3-/ exfalso, apply lt_le_antisymm H, apply le_add_left},
{ /-k=0-/ exact B n },
{ /-k=1-/ exact A n },
{ /-k=2-/ exact C n }},
{ intro x, induction x with n k, induction k with k H, do 3 (cases k with k; rotate 1),
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{ /-k≥3-/ exfalso, apply lt_le_antisymm H, apply le_add_left},
{ /-k=0-/ exact φ n },
{ /-k=1-/ exact submodule_incl _ ∘lm short_exact_mod.g (ses n) },
{ /-k=2-/ change B (succ_str.S n) →lm C n, exact short_exact_mod.f (ses n) ∘lm !quotient_map }},
{ intros x m, induction x with n k, induction k with k H, do 3 (cases k with k; rotate 1),
{ exfalso, apply lt_le_antisymm H, apply le_add_left},
{ exact (short_exact_mod.g (ses n) m).2 },
{ note h := is_short_exact.im_in_ker (short_exact_mod.h (ses n)) (quotient_map _ m),
exact ap pr1 h },
{ refine _ ⬝ to_respect_zero (short_exact_mod.f (ses n)),
rexact ap (short_exact_mod.f (ses n)) (quotient_map_eq_zero _ _ (image.mk m idp)) }}
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end
open prod
definition LES_of_SESs_zero {N : succ_str} {A B C : N → LeftModule.{_ u} R} (φ : Πn, A n →lm B n)
(ses : Πn : N, short_exact_mod (cokernel_module (φ (succ_str.S n))) (C n) (kernel_module (φ n)))
(n : N) : LES_of_SESs A B C φ ses (n, 0) ≃lm B n :=
by reflexivity
definition LES_of_SESs_one {N : succ_str} {A B C : N → LeftModule.{_ u} R} (φ : Πn, A n →lm B n)
(ses : Πn : N, short_exact_mod (cokernel_module (φ (succ_str.S n))) (C n) (kernel_module (φ n)))
(n : N) : LES_of_SESs A B C φ ses (n, 1) ≃lm A n :=
by reflexivity
definition LES_of_SESs_two {N : succ_str} {A B C : N → LeftModule.{_ u} R} (φ : Πn, A n →lm B n)
(ses : Πn : N, short_exact_mod (cokernel_module (φ (succ_str.S n))) (C n) (kernel_module (φ n)))
(n : N) : LES_of_SESs A B C φ ses (n, 2) ≃lm C n :=
by reflexivity
definition is_exact_LES_of_SESs {N : succ_str} {A B C : N → LeftModule.{_ u} R}
(φ : Πn, A n →lm B n)
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(ses : Πn : N, short_exact_mod (cokernel_module (φ (succ_str.S n))) (C n) (kernel_module (φ n))) :
is_exact_m (LES_of_SESs A B C φ ses) :=
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begin
intros x m p, induction x with n k, induction k with k H, do 3 (cases k with k; rotate 1),
{ exfalso, apply lt_le_antisymm H, apply le_add_left},
{ induction is_short_exact.is_surj (short_exact_mod.h (ses n)) ⟨m, p⟩ with m' q,
exact image.mk m' (ap pr1 q) },
{ induction is_short_exact.ker_in_im (short_exact_mod.h (ses n)) m (subtype_eq p) with m' q,
induction m' using set_quotient.rec_prop with m',
exact image.mk m' q },
{ apply rel_of_quotient_map_eq_zero (image (φ (succ_str.S n))) m,
apply @is_injective_of_is_embedding _ _ _ (is_short_exact.is_emb (short_exact_mod.h (ses n))),
exact p ⬝ (to_respect_zero (short_exact_mod.f (ses n)))⁻¹ }
end
-- remove:
-- definition homology.rec (P : homology ψ φ → Type)
-- [H : Πx, is_set (P x)] (h₀ : Π(m : M₂) (h : ψ m = 0), P (homology.mk m h))
-- (h₁ : Π(m : M₂) (h : ψ m = 0) (k : image φ m), h₀ m h =[homology_eq0' k] h₀ 0 (to_respect_zero ψ))
-- : Πx, P x :=
-- begin
-- refine @set_quotient.rec _ _ _ H _ _,
-- { intro v, induction v with m h, exact h₀ m h },
-- { intro v v', induction v with m hm, induction v' with n hn,
-- intro h,
-- note x := h₁ (m - n) _ h,
-- esimp,
-- exact change_path _ _,
-- }
-- end
-- definition quotient.rec (P : quotient_group N → Type)
-- [H : Πx, is_set (P x)] (h₀ : Π(g : G), P (qg_map N g))
-- -- (h₀_mul : Π(g h : G), h₀ (g * h))
-- (h₁ : Π(g : G) (h : N g), h₀ g =[qg_map_eq_one g h] h₀ 1)
-- : Πx, P x :=
-- begin
-- refine @set_quotient.rec _ _ _ H _ _,
-- { intro g, exact h₀ g },
-- { intro g g' h,
-- note x := h₁ (g * g'⁻¹) h,
-- }
-- -- { intro v, induction },
-- -- { intro v v', induction v with m hm, induction v' with n hn,
-- -- intro h,
-- -- note x := h₁ (m - n) _ h,
-- -- esimp,
-- -- exact change_path _ _,
-- -- }
-- end
end left_module