662 lines
25 KiB
Text
662 lines
25 KiB
Text
/- Exact couples of graded (left-) R-modules. This file includes:
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- Constructing exact couples from sequences of maps
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- Deriving an exact couple
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- The convergence theorem for exact couples -/
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-- Author: Floris van Doorn
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import .graded ..homotopy.spectrum .product_group
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open algebra is_trunc left_module is_equiv equiv eq function nat sigma sigma.ops set_quotient
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/- exact couples -/
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namespace left_module
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structure exact_couple (R : Ring) (I : Set) : Type :=
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(D E : graded_module R I)
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(i : D →gm D) (j : D →gm E) (k : E →gm D)
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(ij : is_exact_gmod i j)
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(jk : is_exact_gmod j k)
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(ki : is_exact_gmod k i)
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open exact_couple
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namespace derived_couple
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section
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parameters {R : Ring} {I : Set} (X : exact_couple R I)
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local abbreviation D := D X
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local abbreviation E := E X
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local abbreviation i := i X
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local abbreviation j := j X
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local abbreviation k := k X
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local abbreviation ij := ij X
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local abbreviation jk := jk X
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local abbreviation ki := ki X
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definition d : E →gm E := j ∘gm k
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definition D' : graded_module R I := graded_image i
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definition E' : graded_module R I := graded_homology d d
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definition is_contr_E' {x : I} (H : is_contr (E x)) : is_contr (E' x) :=
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!is_contr_homology
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definition is_contr_D' {x : I} (H : is_contr (D x)) : is_contr (D' x) :=
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!is_contr_image_module
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definition i' : D' →gm D' :=
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graded_image_lift i ∘gm graded_submodule_incl (λx, image_rel (i ← x))
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-- degree i + 0
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lemma is_surjective_i' {x y : I} (p : deg i' x = y)
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(H : Π⦃z⦄ (q : deg i z = x), is_surjective (i ↘ q)) : is_surjective (i' ↘ p) :=
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begin
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apply is_surjective_graded_hom_compose,
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{ intro y q, apply is_surjective_graded_image_lift },
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{ intro y q, apply is_surjective_of_is_equiv,
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induction q,
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exact to_is_equiv (equiv_of_isomorphism (image_module_isomorphism (i ← x) (H _)))
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}
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end
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lemma j_lemma1 ⦃x : I⦄ (m : D x) : d ((deg j) x) (j x m) = 0 :=
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begin
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rewrite [graded_hom_compose_fn,↑d,graded_hom_compose_fn],
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refine ap (graded_hom_fn j (deg k (deg j x))) _ ⬝
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!to_respect_zero,
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exact compose_constant.elim (gmod_im_in_ker (jk)) x m
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end
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lemma j_lemma2 : Π⦃x : I⦄ ⦃m : D x⦄ (p : i x m = 0),
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(graded_quotient_map _ ∘gm graded_hom_lift j j_lemma1) x m = 0 :> E' _ :=
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begin
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have Π⦃x y : I⦄ (q : deg k x = y) (r : deg d x = deg j y)
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(s : ap (deg j) q = r) ⦃m : D y⦄ (p : i y m = 0), image (d ↘ r) (j y m),
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begin
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intros, induction s, induction q,
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note m_in_im_k := is_exact.ker_in_im (ki idp _) _ p,
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induction m_in_im_k with e q,
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induction q,
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apply image.mk e idp
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end,
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have Π⦃x : I⦄ ⦃m : D x⦄ (p : i x m = 0), image (d ← (deg j x)) (j x m),
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begin
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intros,
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refine this _ _ _ p,
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exact to_right_inv (deg k) _ ⬝ to_left_inv (deg j) x,
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apply is_set.elim
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-- rewrite [ap_con, -adj],
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end,
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intros,
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rewrite [graded_hom_compose_fn],
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exact quotient_map_eq_zero _ (this p)
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end
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definition j' : D' →gm E' :=
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graded_image_elim (graded_homology_intro d d ∘gm graded_hom_lift j j_lemma1) j_lemma2
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-- degree deg j - deg i
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-- mk_out_in (deg f) (deg g)
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lemma k_lemma1 ⦃x : I⦄ (m : E x) (p : d x m = 0) : image (i ← (deg k x)) (k x m) :=
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gmod_ker_in_im (exact_couple.ij X) (k x m) p
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definition k₂ : graded_kernel d →gm D' := graded_submodule_functor k k_lemma1
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lemma k_lemma2 ⦃x : I⦄ (m : E x) (h₁ : kernel_rel (d x) m) (h₂ : image (d ← x) m) :
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k₂ x ⟨m, h₁⟩ = 0 :=
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begin
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assert H₁ : Π⦃x' y z w : I⦄ (p : deg k x' = y) (q : deg j y = z) (r : deg k z = w) (n : E x'),
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k ↘ r (j ↘ q (k ↘ p n)) = 0,
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{ intros, exact gmod_im_in_ker (exact_couple.jk X) q r (k ↘ p n) },
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induction h₂ with n p,
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assert H₂ : k x m = 0,
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{ rewrite [-p], refine ap (k x) (graded_hom_compose_fn_out j k x n) ⬝ _, apply H₁ },
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exact subtype_eq H₂
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end
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definition k' : E' →gm D' :=
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graded_quotient_elim (graded_submodule_functor k k_lemma1)
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(by intro x m h; exact k_lemma2 m.1 m.2 h)
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definition i'_eq ⦃x : I⦄ (m : D x) (h : image (i ← x) m) : (i' x ⟨m, h⟩).1 = i x m :=
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by reflexivity
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definition k'_eq ⦃x : I⦄ (m : E x) (h : d x m = 0) : (k' x (class_of ⟨m, h⟩)).1 = k x m :=
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by reflexivity
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lemma j'_eq {x : I} (m : D x) : j' ↘ (ap (deg j) (left_inv (deg i) x)) (graded_image_lift i x m) =
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class_of (graded_hom_lift j proof j_lemma1 qed x m) :=
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begin
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refine graded_image_elim_destruct _ _ _ idp _ m,
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apply is_set.elim,
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end
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definition deg_i' : deg i' ~ deg i := by reflexivity
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definition deg_j' : deg j' ~ deg j ∘ (deg i)⁻¹ := by reflexivity
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definition deg_k' : deg k' ~ deg k := by reflexivity
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open group
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lemma i'j' : is_exact_gmod i' j' :=
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begin
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intro x, refine equiv_rect (deg i) _ _,
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intros y z p q, revert z q x p,
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refine eq.rec_grading (deg i ⬝e deg j') (deg j) (ap (deg j) (left_inv (deg i) y)) _,
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intro x, revert y, refine eq.rec_equiv (deg i) _,
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apply transport (λx, is_exact_mod x _) (idpath (i' x)),
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apply transport (λx, is_exact_mod _ (j' ↘ (ap (deg j) (left_inv (deg i) x)))) (idpath x),
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apply is_exact_mod.mk,
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{ revert x, refine equiv_rect (deg i) _ _, intro x,
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refine graded_image.rec _, intro m,
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transitivity j' ↘ _ (graded_image_lift i (deg i x) (i x m)),
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apply ap (λx, j' ↘ _ x), apply subtype_eq, apply i'_eq,
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refine !j'_eq ⬝ _,
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apply ap class_of, apply subtype_eq, exact is_exact.im_in_ker (exact_couple.ij X idp idp) m },
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{ revert x, refine equiv_rect (deg k) _ _, intro x,
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refine graded_image.rec _, intro m p,
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assert q : graded_homology_intro d d (deg j (deg k x))
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(graded_hom_lift j j_lemma1 (deg k x) m) = 0,
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{ exact !j'_eq⁻¹ ⬝ p },
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note q2 := image_of_graded_homology_intro_eq_zero idp (graded_hom_lift j _ _ m) q,
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induction q2 with n r,
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assert s : j (deg k x) (m - k x n) = 0,
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{ refine respect_sub (j (deg k x)) m (k x n) ⬝ _,
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refine ap (sub _) r ⬝ _, apply sub_self },
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assert t : trunctype.carrier (image (i ← (deg k x)) (m - k x n)),
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{ exact is_exact.ker_in_im (exact_couple.ij X _ _) _ s },
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refine image.mk ⟨m - k x n, t⟩ _,
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apply subtype_eq, refine !i'_eq ⬝ !to_respect_sub ⬝ _,
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refine ap (sub _) _ ⬝ !sub_zero,
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apply is_exact.im_in_ker (exact_couple.ki X _ _) }
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end
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lemma j'k' : is_exact_gmod j' k' :=
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begin
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refine equiv_rect (deg i) _ _,
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intros x y z p, revert y p z,
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refine eq.rec_grading (deg i ⬝e deg j') (deg j) (ap (deg j) (left_inv (deg i) x)) _,
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intro z q, induction q,
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apply is_exact_mod.mk,
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{ refine graded_image.rec _, intro m,
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refine ap (k' _) (j'_eq m) ⬝ _,
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apply subtype_eq,
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refine k'_eq _ _ ⬝ _,
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exact is_exact.im_in_ker (exact_couple.jk X idp idp) m },
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{ intro m p, induction m using set_quotient.rec_prop with m,
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induction m with m h, note q := (k'_eq m h)⁻¹ ⬝ ap pr1 p,
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induction is_exact.ker_in_im (exact_couple.jk X idp idp) m q with n r,
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apply image.mk (graded_image_lift i x n),
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refine !j'_eq ⬝ _,
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apply ap class_of, apply subtype_eq, exact r }
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end
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lemma k'i' : is_exact_gmod k' i' :=
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begin
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apply is_exact_gmod.mk,
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{ intro x m, induction m using set_quotient.rec_prop with m,
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cases m with m p, apply subtype_eq,
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change i (deg k x) (k x m) = 0,
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exact is_exact.im_in_ker (exact_couple.ki X idp idp) m },
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{ intro x m, induction m with m h, intro p,
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have i (deg k x) m = 0, from ap pr1 p,
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induction is_exact.ker_in_im (exact_couple.ki X idp idp) m this with n q,
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have j (deg k x) m = 0, from @(is_exact.im_in_ker2 (exact_couple.ij X _ _)) m h,
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have d x n = 0, from ap (j (deg k x)) q ⬝ this,
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exact image.mk (class_of ⟨n, this⟩) (subtype_eq q) }
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end
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end
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end derived_couple
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open derived_couple
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definition derived_couple [constructor] {R : Ring} {I : Set}
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(X : exact_couple R I) : exact_couple R I :=
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⦃exact_couple, D := D' X, E := E' X, i := i' X, j := j' X, k := k' X,
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ij := i'j' X, jk := j'k' X, ki := k'i' X⦄
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/- if an exact couple is bounded, we can prove the convergence theorem for it -/
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structure is_bounded {R : Ring} {I : Set} (X : exact_couple R I) : Type :=
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mk' :: (B B' : I → ℕ)
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(Dub : Π⦃x y⦄ ⦃s : ℕ⦄, (deg (i X))^[s] x = y → B x ≤ s → is_contr (D X y))
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(Dlb : Π⦃x y z⦄ ⦃s : ℕ⦄ (p : deg (i X) x = y), (deg (i X))^[s] y = z → B' z ≤ s → is_surjective (i X ↘ p))
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(Elb : Π⦃x y⦄ ⦃s : ℕ⦄, (deg (i X))⁻¹ᵉ^[s] x = y → B x ≤ s → is_contr (E X y))
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(deg_ik_commute : hsquare (deg (k X)) (deg (k X)) (deg (i X)) (deg (i X)))
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(deg_ij_commute : hsquare (deg (j X)) (deg (j X)) (deg (i X)) (deg (i X)))
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/- Note: Elb proves Dlb for some bound B', but we want tight control over when B' = 0 -/
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protected definition is_bounded.mk [constructor] {R : Ring} {I : Set} {X : exact_couple R I}
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(B B' B'' : I → ℕ)
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(Dub : Π⦃x : I⦄ ⦃s : ℕ⦄, B x ≤ s → is_contr (D X ((deg (i X))^[s] x)))
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(Dlb : Π⦃x : I⦄ ⦃s : ℕ⦄, B' x ≤ s → is_surjective (i X (((deg (i X))⁻¹ᵉ^[s + 1] x))))
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(Elb : Π⦃x : I⦄ ⦃s : ℕ⦄, B'' x ≤ s → is_contr (E X ((deg (i X))⁻¹ᵉ^[s] x)))
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(deg_ik_commute : hsquare (deg (k X)) (deg (k X)) (deg (i X)) (deg (i X)))
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(deg_ij_commute : hsquare (deg (j X)) (deg (j X)) (deg (i X)) (deg (i X))) : is_bounded X :=
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begin
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apply is_bounded.mk' (λx, max (B x) (B'' x)) B',
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{ intro x y s p h, induction p, exact Dub (le.trans !le_max_left h) },
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{ intro x y z s p q h, induction p, induction q,
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refine transport (λx, is_surjective (i X x)) _ (Dlb h),
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rewrite [-iterate_succ], apply iterate_left_inv },
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{ intro x y s p h, induction p, exact Elb (le.trans !le_max_right h) },
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{ assumption },
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{ assumption }
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end
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namespace convergence_theorem
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section
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open is_bounded
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parameters {R : Ring} {I : Set} (X : exact_couple R I) (HH : is_bounded X)
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local abbreviation B := B HH
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local abbreviation B' := B' HH
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local abbreviation Dub := Dub HH
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local abbreviation Dlb := Dlb HH
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local abbreviation Elb := Elb HH
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local abbreviation deg_ik_commute := deg_ik_commute HH
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local abbreviation deg_ij_commute := deg_ij_commute HH
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definition deg_iterate_ik_commute (n : ℕ) :
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hsquare (deg (k X)) (deg (k X)) ((deg (i X))^[n]) ((deg (i X))^[n]) :=
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iterate_commute n deg_ik_commute
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definition deg_iterate_ij_commute (n : ℕ) :
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hsquare (deg (j X)) (deg (j X)) ((deg (i X))⁻¹ᵉ^[n]) ((deg (i X))⁻¹ᵉ^[n]) :=
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iterate_commute n (hvinverse deg_ij_commute)
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definition B2 (x : I) : ℕ := max (B (deg (k X) x)) (B ((deg (j X))⁻¹ x))
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definition Eub ⦃x y : I⦄ ⦃s : ℕ⦄ (p : (deg (i X))^[s] x = y) (h : B2 x ≤ s) :
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is_contr (E X y) :=
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begin
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induction p,
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refine @(is_contr_middle_of_is_exact (exact_couple.jk X (right_inv (deg (j X)) _) idp)) _ _ _,
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exact Dub (iterate_commute s (hhinverse deg_ij_commute) x) (le.trans !le_max_right h),
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exact Dub !deg_iterate_ik_commute (le.trans !le_max_left h)
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end
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-- we start counting pages at 0
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definition page (r : ℕ) : exact_couple R I :=
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iterate derived_couple r X
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definition is_contr_E (r : ℕ) (x : I) (h : is_contr (E X x)) :
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is_contr (E (page r) x) :=
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by induction r with r IH; exact h; exact is_contr_E' (page r) IH
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definition is_contr_D (r : ℕ) (x : I) (h : is_contr (D X x)) :
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is_contr (D (page r) x) :=
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by induction r with r IH; exact h; exact is_contr_D' (page r) IH
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definition deg_i (r : ℕ) : deg (i (page r)) ~ deg (i X) :=
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begin
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induction r with r IH,
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{ reflexivity },
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{ exact IH }
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end
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definition deg_k (r : ℕ) : deg (k (page r)) ~ deg (k X) :=
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begin
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induction r with r IH,
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{ reflexivity },
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{ exact IH }
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end
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definition deg_j (r : ℕ) :
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deg (j (page r)) ~ deg (j X) ∘ iterate (deg (i X))⁻¹ r :=
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begin
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induction r with r IH,
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{ reflexivity },
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{ refine hwhisker_left (deg (j (page r)))
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(to_inv_homotopy_inv (deg_i r)) ⬝hty _,
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refine hwhisker_right _ IH ⬝hty _,
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apply hwhisker_left, symmetry, apply iterate_succ }
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end
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definition deg_j_inv (r : ℕ) :
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(deg (j (page r)))⁻¹ ~ iterate (deg (i X)) r ∘ (deg (j X))⁻¹ :=
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have H : deg (j (page r)) ~ iterate_equiv (deg (i X))⁻¹ᵉ r ⬝e deg (j X), from deg_j r,
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λx, to_inv_homotopy_to_inv H x ⬝ iterate_inv (deg (i X))⁻¹ᵉ r ((deg (j X))⁻¹ x)
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definition deg_d (r : ℕ) :
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deg (d (page r)) ~ deg (j X) ∘ iterate (deg (i X))⁻¹ r ∘ deg (k X) :=
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compose2 (deg_j r) (deg_k r)
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definition deg_d_inv (r : ℕ) :
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(deg (d (page r)))⁻¹ ~ (deg (k X))⁻¹ ∘ iterate (deg (i X)) r ∘ (deg (j X))⁻¹ :=
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compose2 (to_inv_homotopy_to_inv (deg_k r)) (deg_j_inv r)
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definition B3 (x : I) : ℕ :=
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max (B (deg (j X) (deg (k X) x))) (B2 ((deg (k X))⁻¹ ((deg (j X))⁻¹ x)))
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definition Estable {x : I} {r : ℕ} (H : B3 x ≤ r) :
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E (page (r + 1)) x ≃lm E (page r) x :=
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begin
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change homology (d (page r) x) (d (page r) ← x) ≃lm E (page r) x,
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apply homology_isomorphism: apply is_contr_E,
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exact Eub (hhinverse (deg_iterate_ik_commute r) _ ⬝ (deg_d_inv r x)⁻¹)
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(le.trans !le_max_right H),
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exact Elb (deg_iterate_ij_commute r _ ⬝ (deg_d r x)⁻¹)
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(le.trans !le_max_left H)
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end
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definition is_surjective_i {x y z : I} {r s : ℕ} (H : B' z ≤ s + r)
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(p : deg (i (page r)) x = y) (q : iterate (deg (i X)) s y = z) :
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is_surjective (i (page r) ↘ p) :=
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begin
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revert x y z s H p q, induction r with r IH: intro x y z s H p q,
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{ exact Dlb p q H },
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/- the following is a start of the proof that i is surjective using that E is contractible (but this
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makes the bound 1 higher than necessary -/
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-- induction p, change is_surjective (i X x),
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-- apply @(is_surjective_of_is_exact_of_is_contr (exact_couple.ij X idp idp)),
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-- refine Elb _ H,
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-- exact sorry
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{ change is_surjective (i' (page r) ↘ p),
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apply is_surjective_i', intro z' q',
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refine IH _ _ _ _ (le.trans H (le_of_eq (succ_add s r)⁻¹)) _ _,
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refine !iterate_succ ⬝ ap ((deg (i X))^[s]) _ ⬝ q,
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exact !deg_i⁻¹ ⬝ p }
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end
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definition Dstable {x : I} {r : ℕ} (H : B' x ≤ r) :
|
||
D (page (r + 1)) x ≃lm D (page r) x :=
|
||
begin
|
||
change image_module (i (page r) ← x) ≃lm D (page r) x,
|
||
refine image_module_isomorphism (i (page r) ← x)
|
||
(is_surjective_i (le.trans H (le_of_eq !zero_add⁻¹)) _ _),
|
||
reflexivity
|
||
end
|
||
|
||
/- the infinity pages of E and D -/
|
||
definition Einf : graded_module R I :=
|
||
λx, E (page (B3 x)) x
|
||
|
||
definition Dinf : graded_module R I :=
|
||
λx, D (page (B' x)) x
|
||
|
||
definition Einfstable {x y : I} {r : ℕ} (Hr : B3 y ≤ r) (p : x = y) : Einf y ≃lm E (page r) x :=
|
||
by symmetry; induction p; induction Hr with r Hr IH; reflexivity; exact Estable Hr ⬝lm IH
|
||
|
||
definition Dinfstable {x y : I} {r : ℕ} (Hr : B' y ≤ r) (p : x = y) : Dinf y ≃lm D (page r) x :=
|
||
by symmetry; induction p; induction Hr with r Hr IH; reflexivity; exact Dstable Hr ⬝lm IH
|
||
|
||
parameters {x : I}
|
||
|
||
definition r (n : ℕ) : ℕ :=
|
||
max (max (B (deg (j X) (deg (k X) x)) + n + 1) (B3 ((deg (i X))^[n] x)))
|
||
(max (B' (deg (k X) ((deg (i X))^[n] x)))
|
||
(max (B' (deg (k X) ((deg (i X))^[n+1] x))) (B ((deg (j X))⁻¹ ((deg (i X))^[n] x)))))
|
||
|
||
lemma rb0 (n : ℕ) : r n ≥ n + 1 :=
|
||
ge.trans !le_max_left (ge.trans !le_max_left !le_add_left)
|
||
lemma rb1 (n : ℕ) : B (deg (j X) (deg (k X) x)) ≤ r n - (n + 1) :=
|
||
nat.le_sub_of_add_le (le.trans !le_max_left !le_max_left)
|
||
lemma rb2 (n : ℕ) : B3 ((deg (i X))^[n] x) ≤ r n :=
|
||
le.trans !le_max_right !le_max_left
|
||
lemma rb3 (n : ℕ) : B' (deg (k X) ((deg (i X))^[n] x)) ≤ r n :=
|
||
le.trans !le_max_left !le_max_right
|
||
lemma rb4 (n : ℕ) : B' (deg (k X) ((deg (i X))^[n+1] x)) ≤ r n :=
|
||
le.trans (le.trans !le_max_left !le_max_right) !le_max_right
|
||
lemma rb5 (n : ℕ) : B ((deg (j X))⁻¹ ((deg (i X))^[n] x)) ≤ r n :=
|
||
le.trans (le.trans !le_max_right !le_max_right) !le_max_right
|
||
|
||
definition Einfdiag : graded_module R ℕ :=
|
||
λn, Einf ((deg (i X))^[n] x)
|
||
|
||
definition Dinfdiag : graded_module R ℕ :=
|
||
λn, Dinf (deg (k X) ((deg (i X))^[n] x))
|
||
|
||
definition short_exact_mod_page_r (n : ℕ) : short_exact_mod
|
||
(E (page (r n)) ((deg (i X))^[n] x))
|
||
(D (page (r n)) (deg (k (page (r n))) ((deg (i X))^[n] x)))
|
||
(D (page (r n)) (deg (i (page (r n))) (deg (k (page (r n))) ((deg (i X))^[n] x)))) :=
|
||
begin
|
||
fapply short_exact_mod_of_is_exact,
|
||
{ exact j (page (r n)) ← ((deg (i X))^[n] x) },
|
||
{ exact k (page (r n)) ((deg (i X))^[n] x) },
|
||
{ exact i (page (r n)) (deg (k (page (r n))) ((deg (i X))^[n] x)) },
|
||
{ exact j (page (r n)) _ },
|
||
{ apply is_contr_D, refine Dub !deg_j_inv⁻¹ (rb5 n) },
|
||
{ apply is_contr_E, refine Elb _ (rb1 n),
|
||
refine !deg_iterate_ij_commute ⬝ _,
|
||
refine ap (deg (j X)) _ ⬝ !deg_j⁻¹,
|
||
refine iterate_sub _ !rb0 _ ⬝ _, apply ap (_^[r n]),
|
||
exact ap (deg (i X)) (!deg_iterate_ik_commute ⬝ !deg_k⁻¹) ⬝ !deg_i⁻¹ },
|
||
{ apply jk (page (r n)) },
|
||
{ apply ki (page (r n)) },
|
||
{ apply ij (page (r n)) }
|
||
end
|
||
|
||
/- the convergence theorem is a combination of the following three results -/
|
||
definition short_exact_mod_infpage (n : ℕ) :
|
||
short_exact_mod (Einfdiag n) (Dinfdiag n) (Dinfdiag (n+1)) :=
|
||
begin
|
||
refine short_exact_mod_isomorphism _ _ _ (short_exact_mod_page_r n),
|
||
{ exact Einfstable !rb2 idp },
|
||
{ exact Dinfstable !rb3 !deg_k },
|
||
{ exact Dinfstable !rb4 (!deg_i ⬝ ap (deg (i X)) !deg_k ⬝ !deg_ik_commute) }
|
||
end
|
||
|
||
definition Dinfdiag0 (bound_zero : B' (deg (k X) x) = 0) : Dinfdiag 0 ≃lm D X (deg (k X) x) :=
|
||
Dinfstable (le_of_eq bound_zero) idp
|
||
|
||
lemma Dinfdiag_stable {s : ℕ} (h : B (deg (k X) x) ≤ s) : is_contr (Dinfdiag s) :=
|
||
is_contr_D _ _ (Dub !deg_iterate_ik_commute h)
|
||
|
||
end
|
||
end convergence_theorem
|
||
|
||
-- open convergence_theorem
|
||
-- print axioms short_exact_mod_infpage
|
||
-- print axioms Dinfdiag0
|
||
-- print axioms Dinfdiag_stable
|
||
|
||
end left_module
|
||
open left_module
|
||
namespace pointed
|
||
|
||
open pointed int group is_trunc trunc is_conn
|
||
|
||
definition homotopy_group_conn_nat (n : ℕ) (A : Type*[1]) : AbGroup :=
|
||
AbGroup.mk (π[n] A) (ab_group_homotopy_group_of_is_conn n A)
|
||
|
||
definition homotopy_group_conn : Π(n : ℤ) (A : Type*[1]), AbGroup
|
||
| (of_nat n) A := homotopy_group_conn_nat n A
|
||
| (-[1+ n]) A := trivial_ab_group_lift
|
||
|
||
notation `πc[`:95 n:0 `]`:0 := homotopy_group_conn n
|
||
|
||
definition homotopy_group_conn_nat_functor (n : ℕ) {A B : Type*[1]} (f : A →* B) :
|
||
homotopy_group_conn_nat n A →g homotopy_group_conn_nat n B :=
|
||
begin
|
||
cases n with n, { apply homomorphism_of_is_contr_right },
|
||
cases n with n, { apply homomorphism_of_is_contr_right },
|
||
exact π→g[n+2] f
|
||
end
|
||
|
||
definition homotopy_group_conn_functor : Π(n : ℤ) {A B : Type*[1]} (f : A →* B), πc[n] A →g πc[n] B
|
||
| (of_nat n) A B f := homotopy_group_conn_nat_functor n f
|
||
| (-[1+ n]) A B f := homomorphism_of_is_contr_right _ _
|
||
|
||
notation `π→ag'[`:95 n:0 `]`:0 := homotopy_group_conn_functor n
|
||
|
||
section
|
||
open prod prod.ops fiber
|
||
parameters {A : ℤ → Type*[1]} (f : Π(n : ℤ), A n →* A (n - 1)) [Hf : Πn, is_conn_fun 1 (f n)]
|
||
include Hf
|
||
definition I [constructor] : Set := trunctype.mk (ℤ × ℤ) !is_trunc_prod
|
||
|
||
definition D_sequence : graded_module rℤ I :=
|
||
λv, LeftModule_int_of_AbGroup (πc[v.2] (A (v.1)))
|
||
|
||
definition E_sequence : graded_module rℤ I :=
|
||
λv, LeftModule_int_of_AbGroup (πc[v.2] (pconntype.mk (pfiber (f (v.1))) !Hf pt))
|
||
|
||
-- definition exact_couple_sequence : exact_couple rℤ I :=
|
||
-- exact_couple.mk D_sequence E_sequence sorry sorry sorry sorry sorry sorry
|
||
|
||
end
|
||
|
||
|
||
end pointed
|
||
|
||
namespace spectrum
|
||
open pointed int group is_trunc trunc is_conn prod prod.ops group fin chain_complex
|
||
section
|
||
|
||
parameters {A : ℤ → spectrum} (f : Π(s : ℤ), A s →ₛ A (s - 1))
|
||
|
||
definition I [constructor] : Set := trunctype.mk (gℤ ×g gℤ) !is_trunc_prod
|
||
|
||
definition D_sequence : graded_module rℤ I :=
|
||
λv, LeftModule_int_of_AbGroup (πₛ[v.1] (A (v.2)))
|
||
|
||
definition E_sequence : graded_module rℤ I :=
|
||
λv, LeftModule_int_of_AbGroup (πₛ[v.1] (sfiber (f (v.2))))
|
||
|
||
include f
|
||
definition i_sequence : D_sequence →gm D_sequence :=
|
||
begin
|
||
fapply graded_hom.mk, exact (prod_equiv_prod erfl (add_right_action (- 1))),
|
||
intro v,
|
||
apply lm_hom_int.mk, esimp,
|
||
exact πₛ→[v.1] (f v.2)
|
||
end
|
||
|
||
definition deg_j_seq_inv [constructor] : I ≃ I :=
|
||
prod_equiv_prod (add_right_action 1) (add_right_action (- 1))
|
||
|
||
definition fn_j_sequence [unfold 3] (x : I) :
|
||
D_sequence (deg_j_seq_inv x) →lm E_sequence x :=
|
||
begin
|
||
induction x with n s,
|
||
apply lm_hom_int.mk, esimp,
|
||
rexact shomotopy_groups_fun (f s) (n, 2)
|
||
end
|
||
|
||
definition j_sequence : D_sequence →gm E_sequence :=
|
||
graded_hom.mk_out deg_j_seq_inv⁻¹ᵉ fn_j_sequence
|
||
|
||
definition k_sequence : E_sequence →gm D_sequence :=
|
||
begin
|
||
fapply graded_hom.mk erfl,
|
||
intro v, induction v with n s,
|
||
apply lm_hom_int.mk, esimp,
|
||
exact πₛ→[n] (spoint (f s))
|
||
end
|
||
|
||
lemma ij_sequence : is_exact_gmod i_sequence j_sequence :=
|
||
begin
|
||
intro x y z p q,
|
||
revert y z q p,
|
||
refine eq.rec_right_inv (deg j_sequence) _,
|
||
intro y, induction x with n s, induction y with m t,
|
||
refine equiv_rect !pair_eq_pair_equiv⁻¹ᵉ _ _,
|
||
intro pq, esimp at pq, induction pq with p q,
|
||
revert t q, refine eq.rec_equiv (add_right_action (- 1)) _,
|
||
induction p using eq.rec_symm,
|
||
apply is_exact_homotopy homotopy.rfl,
|
||
{ symmetry, exact graded_hom_mk_out_destruct deg_j_seq_inv⁻¹ᵉ fn_j_sequence },
|
||
rexact is_exact_of_is_exact_at (is_exact_LES_of_shomotopy_groups (f s) (m, 2)),
|
||
end
|
||
|
||
lemma jk_sequence : is_exact_gmod j_sequence k_sequence :=
|
||
begin
|
||
intro x y z p q, induction q,
|
||
revert x y p, refine eq.rec_right_inv (deg j_sequence) _,
|
||
intro x, induction x with n s,
|
||
apply is_exact_homotopy,
|
||
{ symmetry, exact graded_hom_mk_out_destruct deg_j_seq_inv⁻¹ᵉ fn_j_sequence },
|
||
{ reflexivity },
|
||
rexact is_exact_of_is_exact_at (is_exact_LES_of_shomotopy_groups (f s) (n, 1)),
|
||
end
|
||
|
||
lemma ki_sequence : is_exact_gmod k_sequence i_sequence :=
|
||
begin
|
||
intro i j k p q, induction p, induction q, induction i with n s,
|
||
rexact is_exact_of_is_exact_at (is_exact_LES_of_shomotopy_groups (f s) (n, 0)),
|
||
end
|
||
|
||
definition exact_couple_sequence [constructor] : exact_couple rℤ I :=
|
||
exact_couple.mk D_sequence E_sequence i_sequence j_sequence k_sequence
|
||
ij_sequence jk_sequence ki_sequence
|
||
|
||
open int
|
||
parameters (ub : ℤ) (lb : ℤ → ℤ)
|
||
(Aub : Πs n, s ≥ ub + 1 → is_equiv (f s n))
|
||
(Alb : Πs n, s ≤ lb n → is_contr (πₛ[n] (A s)))
|
||
|
||
definition B : I → ℕ
|
||
| (n, s) := max0 (s - lb n)
|
||
|
||
definition B' : I → ℕ
|
||
| (n, s) := max0 (ub - s)
|
||
|
||
definition B'' : I → ℕ
|
||
| (n, s) := max0 (ub + 1 - s)
|
||
|
||
lemma iterate_deg_i (n s : ℤ) (m : ℕ) : (deg i_sequence)^[m] (n, s) = (n, s - m) :=
|
||
begin
|
||
induction m with m IH,
|
||
{ exact prod_eq idp !sub_zero⁻¹ },
|
||
{ exact ap (deg i_sequence) IH ⬝ (prod_eq idp !sub_sub) }
|
||
end
|
||
|
||
lemma iterate_deg_i_inv (n s : ℤ) (m : ℕ) : (deg i_sequence)⁻¹ᵉ^[m] (n, s) = (n, s + m) :=
|
||
begin
|
||
induction m with m IH,
|
||
{ exact prod_eq idp !add_zero⁻¹ },
|
||
{ exact ap (deg i_sequence)⁻¹ᵉ IH ⬝ (prod_eq idp !add.assoc) }
|
||
end
|
||
|
||
include Aub Alb
|
||
lemma Dub ⦃x : I⦄ ⦃t : ℕ⦄ (h : B x ≤ t) : is_contr (D_sequence ((deg i_sequence)^[t] x)) :=
|
||
begin
|
||
apply Alb, induction x with n s, rewrite [iterate_deg_i],
|
||
apply sub_le_of_sub_le,
|
||
exact le_of_max0_le h,
|
||
end
|
||
|
||
lemma Dlb ⦃x : I⦄ ⦃t : ℕ⦄ (h : B' x ≤ t) :
|
||
is_surjective (i_sequence ((deg i_sequence)⁻¹ᵉ^[t+1] x)) :=
|
||
begin
|
||
apply is_surjective_of_is_equiv,
|
||
apply is_equiv_homotopy_group_functor,
|
||
apply Aub, induction x with n s,
|
||
rewrite [iterate_deg_i_inv, ▸*, of_nat_add, -add.assoc],
|
||
apply add_le_add_right,
|
||
apply le_add_of_sub_left_le,
|
||
exact le_of_max0_le h
|
||
end
|
||
|
||
lemma Elb ⦃x : I⦄ ⦃t : ℕ⦄ (h : B'' x ≤ t) : is_contr (E_sequence ((deg i_sequence)⁻¹ᵉ^[t] x)) :=
|
||
begin
|
||
apply is_contr_homotopy_group_of_is_contr,
|
||
apply is_contr_fiber_of_is_equiv,
|
||
apply Aub, induction x with n s,
|
||
rewrite [iterate_deg_i_inv, ▸*],
|
||
apply le_add_of_sub_left_le,
|
||
apply le_of_max0_le h,
|
||
end
|
||
|
||
definition is_bounded_sequence [constructor] : is_bounded exact_couple_sequence :=
|
||
is_bounded.mk B B' B'' Dub Dlb Elb
|
||
(by intro x; reflexivity)
|
||
begin
|
||
intro x, induction x with n s, apply pair_eq, esimp, esimp, esimp [j_sequence, i_sequence],
|
||
refine !add.assoc ⬝ ap (add s) !add.comm ⬝ !add.assoc⁻¹,
|
||
end
|
||
|
||
end
|
||
|
||
-- Uncomment the next line to see that the proof uses univalence, but that there are no holes
|
||
--('sorry') in the proof:
|
||
|
||
-- print axioms is_bounded_sequence
|
||
|
||
-- I think it depends on univalence in an essential way. The reason is that the long exact sequence
|
||
-- of homotopy groups already depends on univalence. Namely, in that proof we need to show that if f
|
||
-- : A → B and g : B → C are exact at B, then ∥A∥₀ → ∥B∥₀ → ∥C∥₀ is exact at ∥B∥₀. For this we need
|
||
-- that the equality |b|₀ = |b'|₀ is equivalent to ∥b = b'∥₋₁, which requires univalence.
|
||
end spectrum
|