generalize the spectral sequence of a sequence of spectrum maps
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5 changed files with 82 additions and 17 deletions
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@ -845,18 +845,18 @@ namespace spectrum
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ij_sequence jk_sequence ki_sequence
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open int
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parameters (ub : ℤ) (lb : ℤ → ℤ)
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(Aub : Π(s n : ℤ), s ≥ ub + 1 → is_equiv (f s n))
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parameters (ub : ℤ → ℤ) (lb : ℤ → ℤ)
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(Aub : Π(s n : ℤ), s ≥ ub n + 1 → is_equiv (πₛ→[n] (f s)))
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(Alb : Π(s n : ℤ), s ≤ lb n → is_contr (πₛ[n] (A s)))
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definition B : I → ℕ
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| (n, s) := max0 (s - lb n)
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definition B' : I → ℕ
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| (n, s) := max0 (ub - s)
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| (n, s) := max0 (ub n - s)
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definition B'' : I → ℕ
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| (n, s) := max0 (ub + 1 - s)
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| (n, s) := max0 (max (ub n + 1 - s) (ub (n+1) + 1 - s))
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lemma iterate_deg_i (n s : ℤ) (m : ℕ) : (deg i_sequence)^[m] (n, s) = (n, s - m) :=
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begin
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@ -884,7 +884,6 @@ namespace spectrum
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is_surjective (i_sequence ((deg i_sequence)⁻¹ᵉ^[t+1] x)) :=
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begin
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apply is_surjective_of_is_equiv,
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apply is_equiv_homotopy_group_functor,
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apply Aub, induction x with n s,
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rewrite [iterate_deg_i_inv, ▸*, of_nat_add, -add.assoc],
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apply add_le_add_right,
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@ -894,12 +893,13 @@ namespace spectrum
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lemma Elb ⦃x : I⦄ ⦃t : ℕ⦄ (h : B'' x ≤ t) : is_contr (E_sequence ((deg i_sequence)⁻¹ᵉ^[t] x)) :=
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begin
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apply is_contr_homotopy_group_of_is_contr,
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apply is_contr_fiber_of_is_equiv,
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apply Aub, induction x with n s,
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induction x with n s,
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rewrite [iterate_deg_i_inv, ▸*],
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apply le_add_of_sub_left_le,
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apply le_of_max0_le h,
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apply is_contr_shomotopy_group_sfiber_of_is_equiv,
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apply Aub, apply le_add_of_sub_left_le, apply le_of_max0_le, refine le.trans _ h,
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apply max0_monotone, apply le_max_left,
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apply Aub, apply le_add_of_sub_left_le, apply le_of_max0_le, refine le.trans _ h,
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apply max0_monotone, apply le_max_right
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end
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definition is_bounded_sequence [constructor] : is_bounded exact_couple_sequence :=
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@ -910,13 +910,13 @@ namespace spectrum
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refine !add.assoc ⬝ ap (add s) !add.comm ⬝ !add.assoc⁻¹,
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end
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definition converges_to_sequence : (λn s, πₛ[n] (sfiber (f s))) ⟹ᵍ (λn, πₛ[n] (A ub)) :=
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definition converges_to_sequence : (λn s, πₛ[n] (sfiber (f s))) ⟹ᵍ (λn, πₛ[n] (A (ub n))) :=
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begin
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fapply converges_to.mk,
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{ exact exact_couple_sequence },
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{ exact is_bounded_sequence },
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{ intro n, exact ub },
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{ intro n, change max0 (ub - ub) = 0, exact ap max0 (sub_self ub) },
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{ exact ub },
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{ intro n, change max0 (ub n - ub n) = 0, exact ap max0 (sub_self (ub n)) },
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{ intro ns, reflexivity },
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{ intro n, reflexivity },
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{ intro r, exact - 1 },
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@ -128,12 +128,13 @@ qed
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section atiyah_hirzebruch
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parameters {X : Type*} (Y : X → spectrum) (s₀ : ℤ) (H : Πx, is_strunc s₀ (Y x))
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include H
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definition atiyah_hirzebruch_exact_couple : exact_couple rℤ Z2 :=
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@exact_couple_sequence (λs, spi X (λx, strunc s (Y x)))
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(λs, spi_compose_left (λx, postnikov_smap (Y x) s))
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include H
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-- include H
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definition atiyah_hirzebruch_ub ⦃s n : ℤ⦄ (Hs : s ≤ n - 1) :
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is_contr (πₛ[n] (spi X (λx, strunc s (Y x)))) :=
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begin
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@ -141,7 +142,7 @@ section atiyah_hirzebruch
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apply is_strunc_spi, intro x, exact is_strunc_strunc _ _
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end
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definition atiyah_hirzebruch_lb ⦃s n : ℤ⦄ (Hs : s ≥ s₀ + 1) :
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definition atiyah_hirzebruch_lb' ⦃s n : ℤ⦄ (Hs : s ≥ s₀ + 1) :
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is_equiv (spi_compose_left (λx, postnikov_smap (Y x) s) n) :=
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begin
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refine is_equiv_of_equiv_of_homotopy
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@ -161,13 +162,19 @@ section atiyah_hirzebruch
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reflexivity
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end
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definition atiyah_hirzebruch_lb ⦃s n : ℤ⦄ (Hs : s ≥ s₀ + 1) :
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is_equiv (πₛ→[n] (spi_compose_left (λx, postnikov_smap (Y x) s))) :=
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begin
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apply is_equiv_homotopy_group_functor, apply atiyah_hirzebruch_lb', exact Hs
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end
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definition is_bounded_atiyah_hirzebruch : is_bounded atiyah_hirzebruch_exact_couple :=
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is_bounded_sequence _ s₀ (λn, n - 1) atiyah_hirzebruch_lb atiyah_hirzebruch_ub
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is_bounded_sequence _ (λn, s₀) (λn, n - 1) atiyah_hirzebruch_lb atiyah_hirzebruch_ub
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definition atiyah_hirzebruch_convergence' :
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(λn s, πₛ[n] (sfiber (spi_compose_left (λx, postnikov_smap (Y x) s)))) ⟹ᵍ
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(λn, πₛ[n] (spi X (λx, strunc s₀ (Y x)))) :=
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converges_to_sequence _ s₀ (λn, n - 1) atiyah_hirzebruch_lb atiyah_hirzebruch_ub
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converges_to_sequence _ (λn, s₀) (λn, n - 1) atiyah_hirzebruch_lb atiyah_hirzebruch_ub
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definition atiyah_hirzebruch_convergence :
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(λn s, opH^-(n-s)[(x : X), πₛ[s] (Y x)]) ⟹ᵍ (λn, pH^-n[(x : X), Y x]) :=
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@ -59,6 +59,16 @@ namespace nat
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end nat
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definition max0_monotone {n m : ℤ} (H : n ≤ m) : max0 n ≤ max0 m :=
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begin
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induction n with n n,
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{ induction m with m m,
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{ exact le_of_of_nat_le_of_nat H },
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{ exfalso, exact not_neg_succ_le_of_nat H }},
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{ apply zero_le }
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end
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-- definition ppi_eq_equiv_internal : (k = l) ≃ (k ~* l) :=
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-- calc (k = l) ≃ ppi.sigma_char P p₀ k = ppi.sigma_char P p₀ l
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-- : eq_equiv_fn_eq (ppi.sigma_char P p₀) k l
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@ -1494,3 +1504,18 @@ namespace category
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isomorphism.mk _ (is_isomorphism_pb_Precategory_functor C f)
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end category
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namespace chain_complex
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open fin
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definition is_contr_homotopy_group_fiber {A B : pType.{u}} {f : A →* B} {n : ℕ}
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(H1 : is_embedding (π→[n] f)) (H2 : is_surjective (π→g[n+1] f)) : is_contr (π[n] (pfiber f)) :=
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begin
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apply @is_contr_of_is_embedding_of_is_surjective +3ℕ (LES_of_homotopy_groups f) (n, 0),
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exact is_exact_LES_of_homotopy_groups f (n, 1), exact H1, exact H2
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end
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definition is_contr_homotopy_group_fiber_of_is_equiv {A B : pType.{u}} {f : A →* B} {n : ℕ}
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(H1 : is_equiv (π→[n] f)) (H2 : is_equiv (π→g[n+1] f)) : is_contr (π[n] (pfiber f)) :=
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is_contr_homotopy_group_fiber (is_embedding_of_is_equiv _) (is_surjective_of_is_equiv _)
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end chain_complex
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@ -846,6 +846,22 @@ namespace pointed
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{ exact !ppi_eq_equiv_natural_gen_refl ◾ (!idp_con ⬝ !eq_of_phomotopy_refl) }
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end
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definition loopn_pppi_pequiv [constructor] (n : ℕ) {A : Type*} (B : A → Type*) :
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Ω[n] (Π*a, B a) ≃* Π*(a : A), Ω[n] (B a) :=
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begin
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induction n with n IH,
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{ reflexivity },
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{ refine loop_pequiv_loop IH ⬝e* loop_pppi_pequiv (λa, Ω[n] (B a)) }
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end
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-- definition trivial_homotopy_group_pppi {A : Type*} {B : A → Type*} {n : ℕ}
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-- (H : Πa, is_contr (Ω[n] (B a))) : is_contr (π[n] (Π*a, B a)) :=
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-- begin
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-- apply is_trunc_trunc_of_is_trunc,
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-- apply is_trunc_equiv_closed_rev,
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-- apply loopn_pppi_pequiv
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-- end
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/- below is an alternate proof strategy for the naturality of loop_pppi_pequiv_natural,
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where we define loop_pppi_pequiv as composite of pointed equivalences, and proved the
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@ -703,8 +703,25 @@ namespace spectrum
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πg_glue Y n ∘g (by reflexivity) qed
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| (n, fin.mk (k+3) H) := begin exfalso, apply lt_le_antisymm H, apply le_add_left end
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--(homomorphism_LES_of_homotopy_groups_fun (f (2 - n)) (1, 2) ∘g πg_glue Y n)
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definition is_contr_shomotopy_group_sfiber {n : ℤ}
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(H1 : is_embedding (πₛ→[n] f)) (H2 : is_surjective (πₛ→[n+1] f)) :
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is_contr (πₛ[n] (sfiber f)) :=
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begin
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apply @is_contr_of_is_embedding_of_is_surjective +3ℤ LES_of_shomotopy_groups (n, 0),
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exact is_exact_LES_of_shomotopy_groups (n, 1), exact H1, exact H2
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end
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definition is_contr_shomotopy_group_sfiber_of_is_equiv {n : ℤ}
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(H1 : is_equiv (πₛ→[n] f)) (H2 : is_equiv (πₛ→[n+1] f)) :
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is_contr (πₛ[n] (sfiber f)) :=
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proof
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is_contr_shomotopy_group_sfiber (is_embedding_of_is_equiv _) (is_surjective_of_is_equiv _)
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qed
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end LES
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/- homotopy group of a prespectrum -/
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definition pshomotopy_group_hom (n : ℤ) (E : prespectrum) (k : ℕ)
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