compute unreduced cohomology of spheres

This commit is contained in:
Floris van Doorn 2018-10-03 19:39:08 -04:00
parent c19192fbe5
commit 32512bf47d
6 changed files with 209 additions and 46 deletions

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@ -8,7 +8,7 @@ on trunc 0 (A →* Ω B) and the dependent version trunc 0 (ppi _ _),
which are used in the definition of cohomology. which are used in the definition of cohomology.
-/ -/
import algebra.group_theory ..pointed ..pointed_pi eq2 import algebra.group_theory ..pointed ..pointed_pi eq2 .product_group
open pi pointed algebra group eq equiv is_trunc trunc susp nat function open pi pointed algebra group eq equiv is_trunc trunc susp nat function
namespace group namespace group
@ -317,4 +317,42 @@ namespace group
{ intro g h, apply eq_of_homotopy, intro a, exact respect_mul (f a) g h } { intro g h, apply eq_of_homotopy, intro a, exact respect_mul (f a) g h }
end end
definition Group_pi_eval [constructor] {A : Type} (P : A → Group) (a : A)
: (Πᵍ a, P a) →g P a :=
begin
fconstructor,
{ intro h, exact h a },
{ intro g h, reflexivity }
end
definition Group_pi_functor [constructor] {A B : Type} {P : A → Group} {Q : B → Group}
(f : B → A) (g : Πb, P (f b) →g Q b) : (Πᵍ a, P a) →g Πᵍ b, Q b :=
Group_pi_intro (λb, g b ∘g Group_pi_eval P (f b))
definition Group_pi_functor_compose [constructor] {A B C : Type} {P : A → Group} {Q : B → Group}
{R : C → Group} (f : B → A) (f' : C → B) (g' : Πc, Q (f' c) →g R c) (g : Πb, P (f b) →g Q b) :
Group_pi_functor (f ∘ f') (λc, g' c ∘g g (f' c)) ~
Group_pi_functor f' g' ∘ Group_pi_functor f g :=
begin
intro h, reflexivity
end
open bool prod is_equiv
definition Group_pi_isomorphism_Group_pi [constructor] {A B : Type}
{P : A → Group} {Q : B → Group} (f : B ≃ A) (g : Πb, P (f b) ≃g Q b) :
(Πᵍ a, P a) ≃g Πᵍ b, Q b :=
isomorphism.mk (Group_pi_functor f g) (is_equiv_pi_functor f g)
definition product_isomorphism_Group_pi [constructor] (G H : Group) :
G ×g H ≃g Group_pi (bool.rec G H) :=
begin
fconstructor,
{ exact Group_pi_intro (bool.rec (product_pr1 G H) (product_pr2 G H)) },
{ apply adjointify _ (λh, (h ff, h tt)),
{ intro h, apply eq_of_homotopy, intro b, induction b: reflexivity },
{ intro gh, induction gh, reflexivity }}
end
end group end group

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@ -538,33 +538,33 @@ namespace exact_couple
local attribute [coercion] AddAbGroup_of_Ring local attribute [coercion] AddAbGroup_of_Ring
definition Z2 [constructor] : AddAbGroup := r ×aa r definition Z2 [constructor] : AddAbGroup := r ×aa r
structure convergent_exact_couple.{u v w} {R : Ring} (E' : agag → LeftModule.{u v} R) structure convergent_exact_couple.{u v w} {R : Ring} (E' : → LeftModule.{u v} R)
(Dinf : ag → LeftModule.{u w} R) : Type.{max u (v+1) (w+1)} := (Dinf : → LeftModule.{u w} R) : Type.{max u (v+1) (w+1)} :=
(X : exact_couple.{u 0 w v} R Z2) (X : exact_couple.{u 0 w v} R Z2)
(HH : is_bounded X) (HH : is_bounded X)
(st : ag → Z2) (st : → Z2)
(HB : Π(n : ag), is_bounded.B' HH (deg (k X) (st n)) = 0) (HB : Π(n : ), is_bounded.B' HH (deg (k X) (st n)) = 0)
(e : Π(x : Z2), exact_couple.E X x ≃lm E' x.1 x.2) (e : Π(x : Z2), exact_couple.E X x ≃lm E' x.1 x.2)
(f : Π(n : ag), exact_couple.D X (deg (k X) (st n)) ≃lm Dinf n) (f : Π(n : ), exact_couple.D X (deg (k X) (st n)) ≃lm Dinf n)
(deg_d : → Z2) (deg_d : → Z2)
(deg_d_eq0 : Π(r : ), deg (d (page X r)) 0 = deg_d r) (deg_d_eq0 : Π(r : ), deg (d (page X r)) 0 = deg_d r)
infix ` ⟹ `:25 := convergent_exact_couple -- todo: maybe this should define convergent_spectral_sequence infix ` ⟹ `:25 := convergent_exact_couple -- todo: maybe this should define convergent_spectral_sequence
definition convergent_exact_couple_g [reducible] (E' : agag → AbGroup) (Dinf : ag → AbGroup) : Type := definition convergent_exact_couple_g [reducible] (E' : → AbGroup) (Dinf : → AbGroup) : Type :=
(λn s, LeftModule_int_of_AbGroup (E' n s)) ⟹ (λn, LeftModule_int_of_AbGroup (Dinf n)) (λn s, LeftModule_int_of_AbGroup (E' n s)) ⟹ (λn, LeftModule_int_of_AbGroup (Dinf n))
infix ` ⟹ᵍ `:25 := convergent_exact_couple_g infix ` ⟹ᵍ `:25 := convergent_exact_couple_g
section exact_couple section exact_couple
open convergent_exact_couple open convergent_exact_couple
parameters {R : Ring} {E' : agag → LeftModule R} {Dinf : ag → LeftModule R} (c : E' ⟹ Dinf) parameters {R : Ring} {E' : → LeftModule R} {Dinf : → LeftModule R} (c : E' ⟹ Dinf)
local abbreviation X := X c local abbreviation X := X c
local abbreviation i := i X local abbreviation i := i X
local abbreviation HH := HH c local abbreviation HH := HH c
local abbreviation st := st c local abbreviation st := st c
local abbreviation Dinfdiag (n : ag) (k : ) := Dinfdiag HH (st n) k local abbreviation Dinfdiag (n : ) (k : ) := Dinfdiag HH (st n) k
local abbreviation Einfdiag (n : ag) (k : ) := Einfdiag HH (st n) k local abbreviation Einfdiag (n : ) (k : ) := Einfdiag HH (st n) k
definition deg_d_eq (r : ) (ns : Z2) : (deg (d (page X r))) ns = ns + deg_d c r := definition deg_d_eq (r : ) (ns : Z2) : (deg (d (page X r))) ns = ns + deg_d c r :=
!deg_eq ⬝ ap (λx, _ + x) (deg_d_eq0 c r) !deg_eq ⬝ ap (λx, _ + x) (deg_d_eq0 c r)
@ -573,7 +573,7 @@ namespace exact_couple
(deg (d (page X r)))⁻¹ᵉ ns = ns - deg_d c r := (deg (d (page X r)))⁻¹ᵉ ns = ns - deg_d c r :=
inv_eq_of_eq (!deg_d_eq ⬝ proof !neg_add_cancel_right qed)⁻¹ inv_eq_of_eq (!deg_d_eq ⬝ proof !neg_add_cancel_right qed)⁻¹
definition convergent_exact_couple_isomorphism {E'' : agag → LeftModule R} {Dinf' : graded_module R ag} definition convergent_exact_couple_isomorphism {E'' : → LeftModule R} {Dinf' : graded_module R }
(e' : Πn s, E' n s ≃lm E'' n s) (f' : Πn, Dinf n ≃lm Dinf' n) : E'' ⟹ Dinf' := (e' : Πn s, E' n s ≃lm E'' n s) (f' : Πn, Dinf n ≃lm Dinf' n) : E'' ⟹ Dinf' :=
convergent_exact_couple.mk X HH st (HB c) convergent_exact_couple.mk X HH st (HB c)
begin intro x, induction x with n s, exact e c (n, s) ⬝lm e' n s end begin intro x, induction x with n s, exact e c (n, s) ⬝lm e' n s end
@ -606,8 +606,8 @@ namespace exact_couple
is_built_from (Dinf n) (Einfdiag n) := is_built_from (Dinf n) (Einfdiag n) :=
is_built_from_isomorphism_left (f c n) (is_built_from_infpage HH (st n) (HB c n)) is_built_from_isomorphism_left (f c n) (is_built_from_infpage HH (st n) (HB c n))
theorem is_contr_convergent_exact_couple_precise (n : ag) theorem is_contr_convergent_exact_couple_precise (n : )
(H : Π(n : ag) (l : ), is_contr (E' ((deg i)^[l] (st n)).1 ((deg i)^[l] (st n)).2)) : (H : Π(n : ) (l : ), is_contr (E' ((deg i)^[l] (st n)).1 ((deg i)^[l] (st n)).2)) :
is_contr (Dinf n) := is_contr (Dinf n) :=
begin begin
assert H2 : Π(l : ), is_contr (Einfdiag n l), assert H2 : Π(l : ), is_contr (Einfdiag n l),
@ -616,11 +616,11 @@ namespace exact_couple
exact is_contr_total (is_built_from_of_convergent_exact_couple n) H2 exact is_contr_total (is_built_from_of_convergent_exact_couple n) H2
end end
theorem is_contr_convergent_exact_couple (n : ag) (H : Π(n s : ag), is_contr (E' n s)) : theorem is_contr_convergent_exact_couple (n : ) (H : Π(n s : ), is_contr (E' n s)) :
is_contr (Dinf n) := is_contr (Dinf n) :=
is_contr_convergent_exact_couple_precise n (λn s, !H) is_contr_convergent_exact_couple_precise n (λn s, !H)
-- definition E_isomorphism {r₁ r₂ : } {n s : ag} (H : r₁ ≤ r₂) -- definition E_isomorphism {r₁ r₂ : } {n s : } (H : r₁ ≤ r₂)
-- (H1 : Π⦃r⦄, r₁ ≤ r → r < r₂ → is_contr (E X ((n, s) - deg_d c r))) -- (H1 : Π⦃r⦄, r₁ ≤ r → r < r₂ → is_contr (E X ((n, s) - deg_d c r)))
-- (H2 : Π⦃r⦄, r₁ ≤ r → r < r₂ → is_contr (E X ((n, s) + deg_d c r))) : -- (H2 : Π⦃r⦄, r₁ ≤ r → r < r₂ → is_contr (E X ((n, s) + deg_d c r))) :
-- E (page X r₂) (n, s) ≃lm E (page X r₁) (n, s) := -- E (page X r₂) (n, s) ≃lm E (page X r₁) (n, s) :=
@ -628,18 +628,18 @@ namespace exact_couple
-- (λr Hr₁ Hr₂, transport (is_contr ∘ E X) (deg_d_inv_eq r (n, s))⁻¹ᵖ (H1 Hr₁ Hr₂)) -- (λr Hr₁ Hr₂, transport (is_contr ∘ E X) (deg_d_inv_eq r (n, s))⁻¹ᵖ (H1 Hr₁ Hr₂))
-- (λr Hr₁ Hr₂, transport (is_contr ∘ E X) (deg_d_eq r (n, s))⁻¹ᵖ (H2 Hr₁ Hr₂)) -- (λr Hr₁ Hr₂, transport (is_contr ∘ E X) (deg_d_eq r (n, s))⁻¹ᵖ (H2 Hr₁ Hr₂))
-- definition E_isomorphism0 {r : } {n s : ag} (H1 : Πr, is_contr (E X ((n, s) - deg_d c r))) -- definition E_isomorphism0 {r : } {n s : } (H1 : Πr, is_contr (E X ((n, s) - deg_d c r)))
-- (H2 : Πr, is_contr (E X ((n, s) + deg_d c r))) : E (page X r) (n, s) ≃lm E' n s := -- (H2 : Πr, is_contr (E X ((n, s) + deg_d c r))) : E (page X r) (n, s) ≃lm E' n s :=
-- E_isomorphism (zero_le r) _ _ ⬝lm e c (n, s) -- E_isomorphism (zero_le r) _ _ ⬝lm e c (n, s)
-- definition Einf_isomorphism (r₁ : ) {n s : ag} -- definition Einf_isomorphism (r₁ : ) {n s : }
-- (H1 : Π⦃r⦄, r₁ ≤ r → is_contr (E X ((n,s) - deg_d c r))) -- (H1 : Π⦃r⦄, r₁ ≤ r → is_contr (E X ((n,s) - deg_d c r)))
-- (H2 : Π⦃r⦄, r₁ ≤ r → is_contr (E X ((n,s) + deg_d c r))) : -- (H2 : Π⦃r⦄, r₁ ≤ r → is_contr (E X ((n,s) + deg_d c r))) :
-- Einf HH (n, s) ≃lm E (page X r₁) (n, s) := -- Einf HH (n, s) ≃lm E (page X r₁) (n, s) :=
-- Einf_isomorphism' HH r₁ (λr Hr₁, transport (is_contr ∘ E X) (deg_d_inv_eq r (n, s))⁻¹ᵖ (H1 Hr₁)) -- Einf_isomorphism' HH r₁ (λr Hr₁, transport (is_contr ∘ E X) (deg_d_inv_eq r (n, s))⁻¹ᵖ (H1 Hr₁))
-- (λr Hr₁, transport (is_contr ∘ E X) (deg_d_eq r (n, s))⁻¹ᵖ (H2 Hr₁)) -- (λr Hr₁, transport (is_contr ∘ E X) (deg_d_eq r (n, s))⁻¹ᵖ (H2 Hr₁))
-- definition Einf_isomorphism0 {n s : ag} -- definition Einf_isomorphism0 {n s : }
-- (H1 : Π⦃r⦄, is_contr (E X ((n,s) - deg_d c r))) -- (H1 : Π⦃r⦄, is_contr (E X ((n,s) - deg_d c r)))
-- (H2 : Π⦃r⦄, is_contr (E X ((n,s) + deg_d c r))) : -- (H2 : Π⦃r⦄, is_contr (E X ((n,s) + deg_d c r))) :
-- Einf HH (n, s) ≃lm E' n s := -- Einf HH (n, s) ≃lm E' n s :=
@ -647,9 +647,9 @@ namespace exact_couple
end exact_couple end exact_couple
variables {E' : agag → AbGroup} {Dinf : ag → AbGroup} variables {E' : → AbGroup} {Dinf : → AbGroup}
definition convergent_exact_couple_g_isomorphism {E'' : agag → AbGroup} definition convergent_exact_couple_g_isomorphism {E'' : → AbGroup}
{Dinf' : ag → AbGroup} (c : E' ⟹ᵍ Dinf) {Dinf' : → AbGroup} (c : E' ⟹ᵍ Dinf)
(e' : Πn s, E' n s ≃g E'' n s) (f' : Πn, Dinf n ≃g Dinf' n) : E'' ⟹ᵍ Dinf' := (e' : Πn s, E' n s ≃g E'' n s) (f' : Πn, Dinf n ≃g Dinf' n) : E'' ⟹ᵍ Dinf' :=
convergent_exact_couple_isomorphism c (λn s, lm_iso_int.mk (e' n s)) (λn, lm_iso_int.mk (f' n)) convergent_exact_couple_isomorphism c (λn s, lm_iso_int.mk (e' n s)) (λn, lm_iso_int.mk (f' n))

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@ -9,7 +9,7 @@ Constructions with groups
import algebra.group_theory hit.set_quotient types.list types.sum .subgroup .quotient_group import algebra.group_theory hit.set_quotient types.list types.sum .subgroup .quotient_group
open eq algebra is_trunc set_quotient relation sigma prod prod.ops sum list trunc function open eq algebra is_trunc set_quotient relation sigma prod prod.ops sum list trunc function
equiv equiv is_equiv
namespace group namespace group
variables {G G' : Group} {g g' h h' k : G} variables {G G' : Group} {g g' h h' k : G}
@ -98,4 +98,26 @@ namespace group
definition product_group_mul_eq {G H : Group} (g h : G ×g H) : g * h = product_mul g h := definition product_group_mul_eq {G H : Group} (g h : G ×g H) : g * h = product_mul g h :=
idp idp
definition product_pr1 [constructor] (G H : Group) : G ×g H →g G :=
homomorphism.mk (λx, x.1) (λx y, idp)
definition product_pr2 [constructor] (G H : Group) : G ×g H →g H :=
homomorphism.mk (λx, x.2) (λx y, idp)
definition product_trivial_right [constructor] (G H : Group) (HH : is_contr H) : G ×g H ≃g G :=
begin
apply isomorphism.mk (product_pr1 G H),
apply adjointify _ (product_inl G H),
{ intro g, reflexivity },
{ intro gh, exact prod_eq idp !is_prop.elim }
end
definition product_trivial_left [constructor] (G H : Group) (HH : is_contr G) : G ×g H ≃g H :=
begin
apply isomorphism.mk (product_pr2 G H),
apply adjointify _ (product_inr G H),
{ intro g, reflexivity },
{ intro gh, exact prod_eq !is_prop.elim idp }
end
end group end group

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@ -11,8 +11,8 @@ open algebra is_trunc left_module is_equiv equiv eq function nat sigma set_quoti
left_module group int prod prod.ops left_module group int prod prod.ops
open exact_couple (Z2) open exact_couple (Z2)
structure convergent_spectral_sequence.{u v w} {R : Ring} (E' : agag → LeftModule.{u v} R) structure convergent_spectral_sequence.{u v w} {R : Ring} (E' : → LeftModule.{u v} R)
(Dinf : ag → LeftModule.{u w} R) : Type.{max u (v+1) (w+1)} := (Dinf : → LeftModule.{u w} R) : Type.{max u (v+1) (w+1)} :=
(E : → graded_module.{u 0 v} R Z2) (E : → graded_module.{u 0 v} R Z2)
(d : Π(r : ), E r →gm E r) (d : Π(r : ), E r →gm E r)
(deg_d : → Z2) (deg_d : → Z2)
@ -22,11 +22,11 @@ structure convergent_spectral_sequence.{u v w} {R : Ring} (E' : ag → ag
(s₀ : Z2 → ) (s₀ : Z2 → )
(f : Π{r : } {x : Z2} (h : s₀ x ≤ r), E (s₀ x) x ≃lm E r x) (f : Π{r : } {x : Z2} (h : s₀ x ≤ r), E (s₀ x) x ≃lm E r x)
(lb : ) (lb : )
(HDinf : Π(n : ag), is_built_from (Dinf n) (HDinf : Π(n : ), is_built_from (Dinf n)
(λ(k : ), (λx, E (s₀ x) x) (n - (k + lb n), k + lb n))) (λ(k : ), (λx, E (s₀ x) x) (n - (k + lb n), k + lb n)))
definition convergent_spectral_sequence_g [reducible] (E' : agag → AbGroup) definition convergent_spectral_sequence_g [reducible] (E' : → AbGroup)
(Dinf : ag → AbGroup) : Type := (Dinf : → AbGroup) : Type :=
convergent_spectral_sequence (λn s, LeftModule_int_of_AbGroup (E' n s)) convergent_spectral_sequence (λn s, LeftModule_int_of_AbGroup (E' n s))
(λn, LeftModule_int_of_AbGroup (Dinf n)) (λn, LeftModule_int_of_AbGroup (Dinf n))
@ -34,8 +34,8 @@ convergent_spectral_sequence (λn s, LeftModule_int_of_AbGroup (E' n s))
open exact_couple exact_couple.exact_couple exact_couple.convergent_exact_couple open exact_couple exact_couple.exact_couple exact_couple.convergent_exact_couple
exact_couple.convergence_theorem exact_couple.derived_couple exact_couple.convergence_theorem exact_couple.derived_couple
definition convergent_spectral_sequence_of_exact_couple {R : Ring} {E' : agag → LeftModule R} definition convergent_spectral_sequence_of_exact_couple {R : Ring} {E' : → LeftModule R}
{Dinf : ag → LeftModule R} (c : convergent_exact_couple E' Dinf) {Dinf : → LeftModule R} (c : convergent_exact_couple E' Dinf)
(st_eq : Πn, (st c n).1 + (st c n).2 = n) (deg_i_eq : deg (i (X c)) 0 = (- 1, 1)) : (st_eq : Πn, (st c n).1 + (st c n).2 = n) (deg_i_eq : deg (i (X c)) 0 = (- 1, 1)) :
convergent_spectral_sequence E' Dinf := convergent_spectral_sequence E' Dinf :=
convergent_spectral_sequence.mk (λr, E (page (X c) r)) (λr, d (page (X c) r)) convergent_spectral_sequence.mk (λr, E (page (X c) r)) (λr, d (page (X c) r))
@ -60,7 +60,7 @@ convergent_spectral_sequence (λn s, LeftModule_int_of_AbGroup (E' n s))
namespace spectral_sequence namespace spectral_sequence
open convergent_spectral_sequence open convergent_spectral_sequence
variables {R : Ring} {E' : agag → LeftModule R} {Dinf : ag → LeftModule R} variables {R : Ring} {E' : → LeftModule R} {Dinf : → LeftModule R}
(c : convergent_spectral_sequence E' Dinf) (c : convergent_spectral_sequence E' Dinf)
-- (E : → graded_module.{u 0 v} R Z2) -- (E : → graded_module.{u 0 v} R Z2)
@ -72,7 +72,7 @@ namespace spectral_sequence
-- (s₀ : Z2 → ) -- (s₀ : Z2 → )
-- (f : Π{r : } {x : Z2} (h : s₀ x ≤ r), E (s₀ x) x ≃lm E r x) -- (f : Π{r : } {x : Z2} (h : s₀ x ≤ r), E (s₀ x) x ≃lm E r x)
-- (lb : ) -- (lb : )
-- (HDinf : Π(n : ag), is_built_from (Dinf n) -- (HDinf : Π(n : ), is_built_from (Dinf n)
-- (λ(k : ), (λx, E (s₀ x) x) (n - (k + lb n), k + lb n))) -- (λ(k : ), (λx, E (s₀ x) x) (n - (k + lb n), k + lb n)))
definition Einf (x : Z2) : LeftModule R := E c (s₀ c x) x definition Einf (x : Z2) : LeftModule R := E c (s₀ c x) x
@ -115,7 +115,7 @@ namespace spectral_sequence
exact H3 H (le.refl _) exact H3 H (le.refl _)
end end
definition E_isomorphism0 {r : } {n s : ag} definition E_isomorphism0 {r : } {n s : }
(H1 : Πr', r' < r → is_contr (E' (n - (deg_d c r').1) (s - (deg_d c r').2))) (H1 : Πr', r' < r → is_contr (E' (n - (deg_d c r').1) (s - (deg_d c r').2)))
(H2 : Πr', r' < r → is_contr (E' (n + (deg_d c r').1) (s + (deg_d c r').2))) : (H2 : Πr', r' < r → is_contr (E' (n + (deg_d c r').1) (s + (deg_d c r').2))) :
E c r (n, s) ≃lm E' n s := E c r (n, s) ≃lm E' n s :=
@ -133,7 +133,7 @@ namespace spectral_sequence
exact f c Hr exact f c Hr
end end
definition Einf_isomorphism0 {n s : ag} definition Einf_isomorphism0 {n s : }
(H1 : Πr, is_contr (E' (n - (deg_d c r).1) (s - (deg_d c r).2))) (H1 : Πr, is_contr (E' (n - (deg_d c r).1) (s - (deg_d c r).2)))
(H2 : Πr, is_contr (E' (n + (deg_d c r).1) (s + (deg_d c r).2))) : (H2 : Πr, is_contr (E' (n + (deg_d c r).1) (s + (deg_d c r).2))) :
Einf c (n, s) ≃lm E' n s := Einf c (n, s) ≃lm E' n s :=

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@ -6,7 +6,8 @@ Authors: Floris van Doorn, Ulrik Buchholtz
Reduced cohomology of spectra and cohomology theories Reduced cohomology of spectra and cohomology theories
-/ -/
import ..spectrum.basic ..algebra.arrow_group ..homotopy.fwedge ..choice ..homotopy.pushout ..algebra.product_group import ..spectrum.basic ..algebra.arrow_group ..algebra.product_group ..choice
..homotopy.fwedge ..homotopy.pushout ..homotopy.EM ..homotopy.wedge
open eq spectrum int trunc pointed EM group algebra circle sphere nat EM.ops equiv susp is_trunc open eq spectrum int trunc pointed EM group algebra circle sphere nat EM.ops equiv susp is_trunc
function fwedge cofiber bool lift sigma is_equiv choice pushout algebra unit pi is_conn function fwedge cofiber bool lift sigma is_equiv choice pushout algebra unit pi is_conn
@ -103,6 +104,8 @@ definition cohomology_functor [constructor] {X X' : Type*} (f : X' →* X) (Y :
(n : ) : cohomology X Y n →g cohomology X' Y n := (n : ) : cohomology X Y n →g cohomology X' Y n :=
Group_trunc_pmap_homomorphism f Group_trunc_pmap_homomorphism f
notation `H^→` n `[`:0 f:0 `, ` Y:0 `]`:0 := cohomology_functor f Y n
definition cohomology_functor_pid (X : Type*) (Y : spectrum) (n : ) (f : H^n[X, Y]) : definition cohomology_functor_pid (X : Type*) (Y : spectrum) (n : ) (f : H^n[X, Y]) :
cohomology_functor (pid X) Y n f = f := cohomology_functor (pid X) Y n f = f :=
!Group_trunc_pmap_pid !Group_trunc_pmap_pid
@ -116,6 +119,8 @@ definition cohomology_functor_phomotopy {X X' : Type*} {f g : X' →* X} (p : f
(Y : spectrum) (n : ) : cohomology_functor f Y n ~ cohomology_functor g Y n := (Y : spectrum) (n : ) : cohomology_functor f Y n ~ cohomology_functor g Y n :=
Group_trunc_pmap_phomotopy p Group_trunc_pmap_phomotopy p
notation `H^~` n `[`:0 h:0 `, ` Y:0 `]`:0 := cohomology_functor_phomotopy h Y n
definition cohomology_functor_phomotopy_refl {X X' : Type*} (f : X' →* X) (Y : spectrum) (n : ) definition cohomology_functor_phomotopy_refl {X X' : Type*} (f : X' →* X) (Y : spectrum) (n : )
(x : H^n[X, Y]) : cohomology_functor_phomotopy (phomotopy.refl f) Y n x = idp := (x : H^n[X, Y]) : cohomology_functor_phomotopy (phomotopy.refl f) Y n x = idp :=
Group_trunc_pmap_phomotopy_refl f x Group_trunc_pmap_phomotopy_refl f x
@ -128,8 +133,10 @@ definition cohomology_isomorphism {X X' : Type*} (f : X' ≃* X) (Y : spectrum)
H^n[X, Y] ≃g H^n[X', Y] := H^n[X, Y] ≃g H^n[X', Y] :=
Group_trunc_pmap_isomorphism f Group_trunc_pmap_isomorphism f
notation `H^≃` n `[`:0 e:0 `, ` Y:0 `]`:0 := cohomology_isomorphism e Y n
definition cohomology_isomorphism_refl (X : Type*) (Y : spectrum) (n : ) (x : H^n[X,Y]) : definition cohomology_isomorphism_refl (X : Type*) (Y : spectrum) (n : ) (x : H^n[X,Y]) :
cohomology_isomorphism (pequiv.refl X) Y n x = x := H^≃n[pequiv.refl X, Y] x = x :=
!Group_trunc_pmap_isomorphism_refl !Group_trunc_pmap_isomorphism_refl
definition cohomology_isomorphism_right (X : Type*) {Y Y' : spectrum} (e : Πn, Y n ≃* Y' n) definition cohomology_isomorphism_right (X : Type*) {Y Y' : spectrum} (e : Πn, Y n ≃* Y' n)
@ -284,9 +291,13 @@ definition spectrum_additive {I : Type} (H : has_choice 0 I) (X : I → Type*) (
(n : ) : is_equiv (additive_hom X Y n) := (n : ) : is_equiv (additive_hom X Y n) :=
is_equiv_of_equiv_of_homotopy (additive_equiv H X Y n) begin intro f, induction f, reflexivity end is_equiv_of_equiv_of_homotopy (additive_equiv H X Y n) begin intro f, induction f, reflexivity end
definition cohomology_fwedge.{u} {I : Type.{u}} (H : has_choice 0 I) (X : I → Type*) (Y : spectrum)
(n : ) : H^n[X, Y] ≃g Πᵍ i, H^n[X i, Y] :=
isomorphism.mk (additive_hom X Y n) (spectrum_additive H X Y n)
/- dimension axiom for ordinary cohomology -/ /- dimension axiom for ordinary cohomology -/
open is_conn trunc_index open is_conn trunc_index
theorem EM_dimension' (G : AbGroup) (n : ) (H : n ≠ 0) : theorem ordinary_cohomology_dimension (G : AbGroup) (n : ) (H : n ≠ 0) :
is_contr (oH^n[pbool, G]) := is_contr (oH^n[pbool, G]) :=
begin begin
apply is_conn_equiv_closed 0 !pmap_pbool_equiv⁻¹ᵉ, apply is_conn_equiv_closed 0 !pmap_pbool_equiv⁻¹ᵉ,
@ -299,19 +310,104 @@ begin
apply is_trunc_of_le _ (zero_le_of_nat n) _ } apply is_trunc_of_le _ (zero_le_of_nat n) _ }
end end
theorem EM_dimension (G : AbGroup) (n : ) (H : n ≠ 0) : theorem ordinary_cohomology_dimension_plift (G : AbGroup) (n : ) (H : n ≠ 0) :
is_contr (ordinary_cohomology (plift pbool) G n) := is_contr (oH^n[plift pbool, G]) :=
is_trunc_equiv_closed_rev -2 is_trunc_equiv_closed_rev -2
(equiv_of_isomorphism (cohomology_isomorphism (pequiv_plift pbool) _ _)) (equiv_of_isomorphism (cohomology_isomorphism (pequiv_plift pbool) _ _))
(EM_dimension' G n H) (ordinary_cohomology_dimension G n H)
open group algebra definition cohomology_iterate_susp (X : Type*) (Y : spectrum) (n : ) (k : ) :
theorem ordinary_cohomology_pbool (G : AbGroup) : oH^0[pbool, G] ≃g G := H^n+k[iterate_susp k X, Y] ≃g H^n[X, Y] :=
sorry begin
--isomorphism_of_equiv (trunc_equiv_trunc 0 (ppmap_pbool_pequiv _ ⬝e _) ⬝e !trunc_equiv) sorry induction k with k IH,
{ exact cohomology_change_int X Y !add_zero },
{ exact cohomology_change_int _ _ !add.assoc⁻¹ ⬝g cohomology_susp _ _ _ ⬝g IH }
end
theorem is_contr_cohomology_of_is_contr_spectrum (n : ) (X : Type*) (Y : spectrum) (H : is_contr (Y n)) : definition ordinary_cohomology_pbool (G : AbGroup) : oH^0[pbool, G] ≃g G :=
is_contr (H^n[X, Y]) := begin
refine cohomology_isomorphism_shomotopy_group_sp_cotensor _ _ !neg_neg ⬝g _,
change πg[2] (pbool →** EM G 2) ≃g G,
refine homotopy_group_isomorphism_of_pequiv 1 !ppmap_pbool_pequiv ⬝g ghomotopy_group_EM G 1
end
definition ordinary_cohomology_sphere (G : AbGroup) (n : ) : oH^n[sphere n, G] ≃g G :=
begin
refine cohomology_isomorphism_shomotopy_group_sp_cotensor _ _ !neg_neg ⬝g _,
change πg[2] (sphere n →** EM_spectrum G (2 - -n)) ≃g G,
refine homotopy_group_isomorphism_of_pequiv 1 _ ⬝g ghomotopy_group_EMadd1 G 1,
have p : 2 - (-n) = succ (1 + n),
from !sub_eq_add_neg ⬝ ap (add 2) !neg_neg ⬝ ap of_nat !succ_add,
refine !sphere_pmap_pequiv ⬝e* Ω≃[n] (pequiv_ap (EM_spectrum G) p) ⬝e* loopn_EMadd1_add G n 1,
end
definition ordinary_cohomology_sphere_of_neq (G : AbGroup) {n : } {k : } (p : n ≠ k) :
is_contr (oH^n[sphere k, G]) :=
begin
refine is_contr_equiv_closed_rev _
(ordinary_cohomology_dimension G (n-k) (λh, p (eq_of_sub_eq_zero h))),
apply equiv_of_isomorphism,
exact cohomology_change_int _ _ !neg_add_cancel_right⁻¹ ⬝g
cohomology_iterate_susp pbool (EM_spectrum G) (n - k) k
end
definition cohomology_punit (Y : spectrum) (n : ) :
is_contr (H^n[punit, Y]) :=
@is_trunc_trunc_of_is_trunc _ _ _ !is_contr_punit_pmap
definition cohomology_wedge (X X' : Type*) (Y : spectrum) (n : ) :
H^n[wedge X X', Y] ≃g H^n[X, Y] ×ag H^n[X', Y] :=
H^≃n[(wedge_pequiv_fwedge X X')⁻¹ᵉ*, Y] ⬝g
cohomology_fwedge (has_choice_pbool 0) _ _ _ ⬝g
Group_pi_isomorphism_Group_pi erfl begin intro b, induction b: reflexivity end ⬝g
(product_isomorphism_Group_pi H^n[X, Y] H^n[X', Y])⁻¹ᵍ ⬝g
proof !isomorphism.refl qed
definition cohomology_isomorphism_of_equiv {X X' : Type*} (e : X ≃ X') (Y : spectrum) (n : ) :
H^n[X', Y] ≃g H^n[X, Y] :=
!cohomology_susp⁻¹ᵍ ⬝g H^≃n+1[susp_pequiv_of_equiv e, Y] ⬝g !cohomology_susp
definition unreduced_cohomology_split (X : Type*) (Y : spectrum) (n : ) :
uH^n[X, Y] ≃g H^n[X, Y] ×ag H^n[pbool, Y] :=
cohomology_isomorphism_of_equiv (wedge.wedge_pbool_equiv_add_point X) Y n ⬝g
cohomology_wedge X pbool Y n
definition unreduced_ordinary_cohomology_nonzero (X : Type*) (G : AbGroup) (n : ) (H : n ≠ 0) :
uoH^n[X, G] ≃g oH^n[X, G] :=
unreduced_cohomology_split X (EM_spectrum G) n ⬝g
product_trivial_right _ _ (ordinary_cohomology_dimension _ _ H)
definition unreduced_ordinary_cohomology_zero (X : Type*) (G : AbGroup) :
uoH^0[X, G] ≃g oH^0[X, G] ×ag G :=
unreduced_cohomology_split X (EM_spectrum G) 0 ⬝g
(!isomorphism.refl ×≃g ordinary_cohomology_pbool G)
definition unreduced_ordinary_cohomology_pbool (G : AbGroup) : uoH^0[pbool, G] ≃g G ×ag G :=
unreduced_ordinary_cohomology_zero pbool G ⬝g (ordinary_cohomology_pbool G ×≃g !isomorphism.refl)
definition unreduced_ordinary_cohomology_pbool_nonzero (G : AbGroup) (n : ) (H : n ≠ 0) :
is_contr (uoH^n[pbool, G]) :=
is_contr_equiv_closed_rev (equiv_of_isomorphism (unreduced_ordinary_cohomology_nonzero pbool G n H))
(ordinary_cohomology_dimension G n H)
definition unreduced_ordinary_cohomology_sphere_zero (G : AbGroup) (n : ) (H : n ≠ 0) :
uoH^0[sphere n, G] ≃g G :=
unreduced_ordinary_cohomology_zero (sphere n) G ⬝g
product_trivial_left _ _ (ordinary_cohomology_sphere_of_neq _ (λh, H h⁻¹))
definition unreduced_ordinary_cohomology_sphere (G : AbGroup) (n : ) (H : n ≠ 0) :
uoH^n[sphere n, G] ≃g G :=
unreduced_ordinary_cohomology_nonzero (sphere n) G n H ⬝g
ordinary_cohomology_sphere G n
definition unreduced_ordinary_cohomology_sphere_of_neq (G : AbGroup) {n : } {k : } (p : n ≠ k)
(q : n ≠ 0) : is_contr (uoH^n[sphere k, G]) :=
is_contr_equiv_closed_rev
(equiv_of_isomorphism (unreduced_ordinary_cohomology_nonzero (sphere k) G n q))
(ordinary_cohomology_sphere_of_neq G p)
theorem is_contr_cohomology_of_is_contr_spectrum (n : ) (X : Type*) (Y : spectrum)
(H : is_contr (Y n)) : is_contr (H^n[X, Y]) :=
begin begin
apply is_trunc_trunc_of_is_trunc, apply is_trunc_trunc_of_is_trunc,
apply is_trunc_pmap, apply is_trunc_pmap,
@ -339,6 +435,8 @@ begin
apply is_contr_EM_spectrum_neg apply is_contr_EM_spectrum_neg
end end
/- cohomology theory -/ /- cohomology theory -/
structure cohomology_theory.{u} : Type.{u+1} := structure cohomology_theory.{u} : Type.{u+1} :=
@ -441,6 +539,6 @@ cohomology_theory.mk
-- print equiv_lift -- print equiv_lift
-- print has_choice_equiv_closed -- print has_choice_equiv_closed
definition ordinary_cohomology_theory_EM [constructor] (G : AbGroup) : ordinary_cohomology_theory := definition ordinary_cohomology_theory_EM [constructor] (G : AbGroup) : ordinary_cohomology_theory :=
⦃ordinary_cohomology_theory, cohomology_theory_spectrum (EM_spectrum G), Hdimension := EM_dimension G ⦄ ⦃ordinary_cohomology_theory, cohomology_theory_spectrum (EM_spectrum G), Hdimension := ordinary_cohomology_dimension_plift G ⦄
end cohomology end cohomology

View file

@ -5,6 +5,11 @@ open susp eq pointed function is_equiv lift equiv is_trunc nat
namespace susp namespace susp
variables {X X' Y Y' Z : Type*} variables {X X' Y Y' Z : Type*}
definition susp_functor_of_fn [constructor] (f : X → Y) : susp X →* susp Y :=
pmap.mk (susp_functor' f) idp
definition susp_pequiv_of_equiv [constructor] (f : X ≃ Y) : susp X ≃* susp Y :=
pequiv_of_equiv (susp.equiv f) idp
definition iterate_susp_iterate_susp_rev (n m : ) (A : Type*) : definition iterate_susp_iterate_susp_rev (n m : ) (A : Type*) :
iterate_susp n (iterate_susp m A) ≃* iterate_susp (m + n) A := iterate_susp n (iterate_susp m A) ≃* iterate_susp (m + n) A :=
begin begin