289 lines
9.5 KiB
Text
289 lines
9.5 KiB
Text
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/-
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Copyright (c) 2016 Egbert Rijke. All rights reserved.
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Released under Apache 2.0 license as described in the file LICENSE.
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Authors: Egbert Rijke, Steve Awodey
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Exact couple, derived couples, and so on
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-/
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/-
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import algebra.group_theory hit.set_quotient types.sigma types.list types.sum .quotient_group .subgroup .ses
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open eq algebra is_trunc set_quotient relation sigma sigma.ops prod prod.ops sum list trunc function group trunc
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equiv is_equiv
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-- This definition needs to be moved to exactness.hlean. However we had trouble doing so. Please help.
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definition iso_ker_im_of_exact {A B C : AbGroup} (f : A →g B) (g : B →g C) (E : is_exact f g) : ab_Kernel g ≃g ab_image f :=
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begin
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fapply ab_subgroup_iso,
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intro a,
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induction E,
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exact ker_in_im a,
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intro a b, induction b with q, induction q with b p, induction p,
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induction E,
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exact im_in_ker b,
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end
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definition is_differential {B : AbGroup} (d : B →g B) := Π(b:B), d (d b) = 1
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definition image_subgroup_of_diff {B : AbGroup} (d : B →g B) (H : is_differential d) : subgroup_rel (ab_kernel d) :=
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subgroup_rel_of_subgroup (image_subgroup d) (kernel_subgroup d)
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begin
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intro g p,
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induction p with f, induction f with h p,
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rewrite [p⁻¹],
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esimp,
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exact H h
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end
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definition diff_im_in_ker {B : AbGroup} (d : B →g B) (H : is_differential d) : Π(b : B), image_subgroup d b → kernel_subgroup d b :=
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begin
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intro b p,
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induction p with q, induction q with b' p, induction p, exact H b'
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end
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definition homology {B : AbGroup} (d : B →g B) (H : is_differential d) : AbGroup :=
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@quotient_ab_group (ab_kernel d) (image_subgroup_of_diff d H)
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definition homology_ugly {B : AbGroup} (d : B →g B) (H : is_differential d) : AbGroup :=
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@quotient_ab_group (ab_kernel d) (image_subgroup (ab_subgroup_of_subgroup_incl (diff_im_in_ker d H)))
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definition homology_iso_ugly {B : AbGroup} (d : B →g B) (H : is_differential d) : (homology d H) ≃g (homology_ugly d H) :=
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begin
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fapply @iso_of_ab_qg_group (ab_kernel d),
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intro a,
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intro p, induction p with f, induction f with b p,
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fapply tr, fapply fiber.mk, fapply sigma.mk, exact d b, fapply tr, fapply fiber.mk, exact b, reflexivity,
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induction a with c q, fapply subtype_eq, refine p ⬝ _, reflexivity,
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intro b p, induction p with f, induction f with c p, induction p,
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induction c with a q, induction q with f, induction f with a' p, induction p,
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fapply tr, fapply fiber.mk, exact a', reflexivity
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end
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definition SES_iso_C {A B C C' : AbGroup} (ses : SES A B C) (k : C ≃g C') : SES A B C' :=
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begin
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fapply SES.mk,
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exact SES.f ses,
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exact k ∘g SES.g ses,
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exact SES.Hf ses,
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fapply @is_surjective_compose _ _ _ k (SES.g ses),
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exact is_surjective_of_is_equiv k,
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exact SES.Hg ses,
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fapply is_exact.mk,
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intro a,
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esimp,
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note h := SES.ex ses,
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note h2 := is_exact.im_in_ker h a,
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refine ap k h2 ⬝ _ ,
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exact to_respect_one k,
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intro b,
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intro k3,
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note h := SES.ex ses,
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note h3 := is_exact.ker_in_im h b,
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fapply is_exact.ker_in_im h,
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refine _ ⬝ ap k⁻¹ᵍ k3 ⬝ _ ,
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esimp,
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exact (to_left_inv (equiv_of_isomorphism k) ((SES.g ses) b))⁻¹,
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exact to_respect_one k⁻¹ᵍ
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end
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definition SES_of_differential_ugly {B : AbGroup} (d : B →g B) (H : is_differential d) : SES (ab_image d) (ab_kernel d) (homology_ugly d H) :=
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begin
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exact SES_of_inclusion (ab_subgroup_of_subgroup_incl (diff_im_in_ker d H)) (is_embedding_ab_subgroup_of_subgroup_incl (diff_im_in_ker d H)),
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end
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definition SES_of_differential {B : AbGroup} (d : B →g B) (H : is_differential d) : SES (ab_image d) (ab_kernel d) (homology d H) :=
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begin
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fapply SES_iso_C,
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fapply SES_of_inclusion (ab_subgroup_of_subgroup_incl (diff_im_in_ker d H)) (is_embedding_ab_subgroup_of_subgroup_incl (diff_im_in_ker d H)),
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exact (homology_iso_ugly d H)⁻¹ᵍ
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end
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structure exact_couple (A B : AbGroup) : Type :=
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( i : A →g A) (j : A →g B) (k : B →g A)
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( exact_ij : is_exact i j)
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( exact_jk : is_exact j k)
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( exact_ki : is_exact k i)
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definition differential {A B : AbGroup} (EC : exact_couple A B) : B →g B :=
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(exact_couple.j EC) ∘g (exact_couple.k EC)
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definition differential_is_differential {A B : AbGroup} (EC : exact_couple A B) : is_differential (differential EC) :=
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begin
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induction EC,
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induction exact_jk,
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intro b,
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exact (ap (group_fun j) (im_in_ker (group_fun k b))) ⬝ (respect_one j)
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end
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section derived_couple
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/-
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A - i -> A
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k ^ |
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| v j
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B ====== B
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-/
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parameters {A B : AbGroup} (EC : exact_couple A B)
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local abbreviation i := exact_couple.i EC
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local abbreviation j := exact_couple.j EC
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local abbreviation k := exact_couple.k EC
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local abbreviation d := differential EC
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local abbreviation H := differential_is_differential EC
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-- local abbreviation u := exact_couple.i (SES_of_differential d H)
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definition derived_couple_A : AbGroup :=
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ab_subgroup (image_subgroup i)
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definition derived_couple_B : AbGroup :=
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homology (differential EC) (differential_is_differential EC)
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definition derived_couple_i : derived_couple_A →g derived_couple_A :=
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(image_lift (exact_couple.i EC)) ∘g (image_incl (exact_couple.i EC))
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definition SES_of_exact_couple_at_i : SES (ab_kernel i) A (ab_image i) :=
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begin
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fapply SES_iso_C,
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fapply SES_of_subgroup (kernel_subgroup i),
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fapply ab_group_first_iso_thm i,
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end
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definition kj_zero (a : A) : k (j a) = 1 :=
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is_exact.im_in_ker (exact_couple.exact_jk EC) a
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definition j_factor : A →g (ab_kernel d) :=
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begin
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fapply ab_hom_lift j,
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intro a,
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unfold kernel_subgroup,
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exact calc
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d (j a) = j (k (j a)) : rfl
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... = j 1 : by exact ap j (kj_zero a)
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... = 1 : to_respect_one,
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end
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definition subgroup_iso_exact_at_A : ab_kernel i ≃g ab_image k :=
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begin
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fapply ab_subgroup_iso,
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intro a,
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induction EC,
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induction exact_ki,
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exact ker_in_im a,
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intro a b, induction b with f, induction f with b p, induction p,
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induction EC,
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induction exact_ki,
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exact im_in_ker b,
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end
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definition subgroup_iso_exact_at_A_triangle : ab_kernel_incl i ~ ab_image_incl k ∘g subgroup_iso_exact_at_A :=
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begin
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fapply ab_subgroup_iso_triangle,
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intro a b, induction b with f, induction f with b p, induction p,
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induction EC, induction exact_ki, exact im_in_ker b,
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end
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definition subgroup_homom_ker_to_im : ab_kernel i →g ab_image d :=
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(image_homomorphism k j) ∘g subgroup_iso_exact_at_A
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open eq
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definition left_square_derived_ses_aux : j_factor ∘g ab_image_incl k ~ (SES.f (SES_of_differential d H)) ∘g (image_homomorphism k j) :=
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begin
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intro x,
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induction x with a p, induction p with f, induction f with b p, induction p,
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fapply subtype_eq,
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reflexivity,
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end
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definition left_square_derived_ses : j_factor ∘g (ab_kernel_incl i) ~ (SES.f (SES_of_differential d H)) ∘g subgroup_homom_ker_to_im :=
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begin
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intro x,
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exact (ap j_factor (subgroup_iso_exact_at_A_triangle x)) ⬝ (left_square_derived_ses_aux (subgroup_iso_exact_at_A x)),
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end
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definition derived_couple_j_unique :
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is_contr (Σ hC, group_fun (hC ∘g SES.g SES_of_exact_couple_at_i) ~ group_fun
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(SES.g (SES_of_differential d H) ∘g j_factor)) :=
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quotient_extend_unique_SES (SES_of_exact_couple_at_i) (SES_of_differential d H) (subgroup_homom_ker_to_im) (j_factor) (left_square_derived_ses)
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definition derived_couple_j : derived_couple_A →g derived_couple_B :=
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begin
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exact pr1 (center' (derived_couple_j_unique)),
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end
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definition derived_couple_j_htpy : group_fun (derived_couple_j ∘g SES.g SES_of_exact_couple_at_i) ~ group_fun
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(SES.g (SES_of_differential d H) ∘g j_factor) :=
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begin
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exact pr2 (center' (derived_couple_j_unique)),
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end
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definition SES_im_i_trivial : SES trivial_ab_group derived_couple_A derived_couple_A :=
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begin
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fapply SES_of_isomorphism_right,
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fapply isomorphism.refl,
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end
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definition subgroup_iso_exact_kerj_imi : ab_kernel j ≃g ab_image i :=
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begin
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fapply iso_ker_im_of_exact,
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induction EC,
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exact exact_ij,
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end
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definition k_restrict_aux : ab_kernel d →g ab_kernel j :=
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begin
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fapply ab_hom_lift_kernel,
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exact k ∘g ab_kernel_incl d,
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intro p, induction p with b p, exact p,
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end
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definition k_restrict : ab_kernel d →g derived_couple_A :=
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subgroup_iso_exact_kerj_imi ∘g k_restrict_aux
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definition k_restrict_square_left : k_restrict ∘g (SES.f (SES_of_differential d H)) ~ λ x, 1 :=
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begin
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intro x,
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induction x with b' p,
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induction p with q,
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induction q with b p,
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induction p,
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fapply subtype_eq,
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induction EC,
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induction exact_jk,
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fapply im_in_ker,
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end
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definition derived_couple_k_unique : is_contr
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(Σ hC, group_fun (hC ∘g SES.g (SES_of_differential d H)) ~ group_fun
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(SES.g SES_im_i_trivial ∘g k_restrict))
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:=
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quotient_extend_unique_SES (SES_of_differential d H) (SES_im_i_trivial) (trivial_homomorphism (ab_image d) trivial_ab_group) (k_restrict) (k_restrict_square_left)
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definition derived_couple_k : derived_couple_B →g derived_couple_A :=
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begin
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exact pr1 (center' (derived_couple_k_unique)),
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end
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definition derived_couple_k_htpy : group_fun (derived_couple_k ∘g SES.g (SES_of_differential d H)) ~ group_fun
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(SES.g (SES_im_i_trivial) ∘g k_restrict) :=
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begin
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exact pr2 (center' (derived_couple_k_unique)),
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end
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definition derived_couple_exact_ij : is_exact_ag derived_couple_i derived_couple_j :=
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begin
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fapply is_exact.mk,
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intro a,
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induction a with a' t,
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induction t with q, induction q with a p, induction p,
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repeat exact sorry,
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end
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end derived_couple
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-/
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