Spectral/homotopy/strunc.hlean
Floris van Doorn 90f4acb3f6 fix definition of atiyah-hirzebruch spectral sequence, define serre spectral sequence
The construction of the Serre spectral sequence is done up to 11 sorry's, all which are marked with 'TODO FOR SSS'. 8 of them are equivalences related to cohomology (6 of which are corollaries of the other 2), 2 of them are calculations on int, and the last is in the definition of a spectrum map.
2017-07-07 22:35:30 +01:00

294 lines
10 KiB
Text
Raw Blame History

This file contains ambiguous Unicode characters

This file contains Unicode characters that might be confused with other characters. If you think that this is intentional, you can safely ignore this warning. Use the Escape button to reveal them.

import .spectrum .EM
namespace int
-- TODO move this
open trunc_index nat algebra
section
private definition maxm2_le.lemma₁ {n k : } : n+(1:int) + -[1+ k] ≤ n :=
le.intro (
calc n + 1 + -[1+ k] + k = n + 1 - (k + 1) + k : by reflexivity
... = n : sorry) /- TODO FOR SSS -/
private definition maxm2_le.lemma₂ {n : } {k : } : -[1+ n] + 1 + k ≤ k :=
le.intro (
calc -[1+ n] + 1 + k + n = - (n + 1) + 1 + k + n : by reflexivity
... = k : sorry) /- TODO FOR SSS -/
definition maxm2_le (n k : ) : maxm2 (n+1+k) ≤ (maxm1m1 n).+1+2+(maxm1m1 k) :=
begin
rewrite [-(maxm1_eq_succ n)],
induction n with n n,
{ induction k with k k,
{ induction k with k IH,
{ apply le.tr_refl },
{ exact succ_le_succ IH } },
{ exact trunc_index.le_trans (maxm2_monotone maxm2_le.lemma₁)
(maxm2_le_maxm1 n) } },
{ krewrite (add_plus_two_comm -1 (maxm1m1 k)),
rewrite [-(maxm1_eq_succ k)],
exact trunc_index.le_trans (maxm2_monotone maxm2_le.lemma₂)
(maxm2_le_maxm1 k) }
end
end
end int
open int trunc eq is_trunc lift unit pointed equiv is_equiv algebra EM
namespace spectrum
definition ptrunc_maxm2_change_int {k l : } (p : k = l) (X : Type*)
: ptrunc (maxm2 k) X ≃* ptrunc (maxm2 l) X :=
ptrunc_change_index (ap maxm2 p) X
definition is_trunc_maxm2_change_int {k l : } (X : pType) (p : k = l)
: is_trunc (maxm2 k) X → is_trunc (maxm2 l) X :=
by induction p; exact id
definition is_trunc_maxm2_loop {k : } {A : Type*} (H : is_trunc (maxm2 (k+1)) A) :
is_trunc (maxm2 k) (Ω A) :=
begin
induction k with k k,
apply is_trunc_loop, exact H,
apply is_contr_loop,
cases k with k,
{ exact H },
{ apply is_trunc_succ, apply is_trunc_succ, exact H }
end
definition loop_ptrunc_maxm2_pequiv {k : } {l : ℕ₋₂} (p : maxm2 (k+1) = l) (X : Type*) :
Ω (ptrunc l X) ≃* ptrunc (maxm2 k) (Ω X) :=
begin
induction p,
induction k with k k,
{ exact loop_ptrunc_pequiv k X },
{ refine pequiv_of_is_contr _ _ _ !is_trunc_trunc,
apply is_contr_loop,
cases k with k,
{ change is_set (trunc 0 X), apply _ },
{ change is_set (trunc -2 X), apply _ }}
end
definition ptrunc_elim_phomotopy2 [constructor] (k : ℕ₋₂) {A B : Type*} {f g : A →* B} (H₁ : is_trunc k B)
(H₂ : is_trunc k B) (p : f ~* g) : @ptrunc.elim k A B H₁ f ~* @ptrunc.elim k A B H₂ g :=
begin
fapply phomotopy.mk,
{ intro x, induction x with a, exact p a },
{ exact to_homotopy_pt p }
end
definition loop_ptrunc_maxm2_pequiv_ptrunc_elim' {k : } {l : ℕ₋₂} (p : maxm2 (k+1) = l)
{A B : Type*} (f : A →* B) {H : is_trunc l B} :
Ω→ (ptrunc.elim l f) ∘* (loop_ptrunc_maxm2_pequiv p A)⁻¹ᵉ* ~*
@ptrunc.elim (maxm2 k) _ _ (is_trunc_maxm2_loop (is_trunc_of_eq p⁻¹ H)) (Ω→ f) :=
begin
induction p, induction k with k k,
{ refine pwhisker_right _ (ap1_phomotopy _) ⬝* @(ap1_ptrunc_elim k f) H,
apply ptrunc_elim_phomotopy2, reflexivity },
{ apply phomotopy_of_is_contr_cod, exact is_trunc_maxm2_loop H }
end
definition loop_ptrunc_maxm2_pequiv_ptrunc_elim {k : } {l : ℕ₋₂} (p : maxm2 (k+1) = l)
{A B : Type*} (f : A →* B) {H1 : is_trunc ((maxm2 k).+1) B } {H2 : is_trunc l B} :
Ω→ (ptrunc.elim l f) ∘* (loop_ptrunc_maxm2_pequiv p A)⁻¹ᵉ* ~* ptrunc.elim (maxm2 k) (Ω→ f) :=
begin
induction p, induction k with k k: esimp at H1,
{ refine pwhisker_right _ (ap1_phomotopy _) ⬝* ap1_ptrunc_elim k f,
apply ptrunc_elim_phomotopy2, reflexivity },
{ apply phomotopy_of_is_contr_cod }
end
definition loop_ptrunc_maxm2_pequiv_ptr {k : } {l : ℕ₋₂} (p : maxm2 (k+1) = l) (A : Type*) :
Ω→ (ptr l A) ~* (loop_ptrunc_maxm2_pequiv p A)⁻¹ᵉ* ∘* ptr (maxm2 k) (Ω A) :=
begin
induction p, induction k with k k,
{ exact ap1_ptr k A },
{ apply phomotopy_pinv_left_of_phomotopy, apply phomotopy_of_is_contr_cod, apply is_trunc_trunc }
end
definition is_trunc_of_is_trunc_maxm2 (k : ) (X : Type)
: is_trunc (maxm2 k) X → is_trunc (max0 k) X :=
λ H, @is_trunc_of_le X _ _ (maxm2_le_maxm0 k) H
definition strunc [constructor] (k : ) (E : spectrum) : spectrum :=
spectrum.MK (λ(n : ), ptrunc (maxm2 (k + n)) (E n))
(λ(n : ), ptrunc_pequiv_ptrunc (maxm2 (k + n)) (equiv_glue E n)
⬝e* (loop_ptrunc_maxm2_pequiv (ap maxm2 (add.assoc k n 1)) (E (n+1)))⁻¹ᵉ*)
definition strunc_change_int [constructor] {k l : } (E : spectrum) (p : k = l) :
strunc k E →ₛ strunc l E :=
begin induction p, reflexivity end
definition is_strunc [reducible] (k : ) (E : spectrum) : Type :=
Π (n : ), is_trunc (maxm2 (k + n)) (E n)
definition is_strunc_change_int {k l : } (E : spectrum) (p : k = l)
: is_strunc k E → is_strunc l E :=
begin induction p, exact id end
definition is_strunc_of_le {k l : } (E : spectrum) (H : k ≤ l)
: is_strunc k E → is_strunc l E :=
begin
intro T, intro n, exact is_trunc_of_le (E n)
(maxm2_monotone (algebra.add_le_add_right H n))
end
definition is_strunc_pequiv_closed {k : } {E F : spectrum} (H : Πn, E n ≃* F n)
(H2 : is_strunc k E) : is_strunc k F :=
λn, is_trunc_equiv_closed (maxm2 (k + n)) (H n)
definition is_strunc_strunc (k : ) (E : spectrum)
: is_strunc k (strunc k E) :=
λ n, is_trunc_trunc (maxm2 (k + n)) (E n)
definition is_strunc_strunc_of_is_strunc (k : ) {l : } {E : spectrum} (H : is_strunc l E)
: is_strunc l (strunc k E) :=
λ n, !is_trunc_trunc_of_is_trunc
definition str [constructor] (k : ) (E : spectrum) : E →ₛ strunc k E :=
smap.mk (λ n, ptr (maxm2 (k + n)) (E n))
abstract begin
intro n,
apply psquare_of_phomotopy,
refine !passoc ⬝* pwhisker_left _ !ptr_natural ⬝* _,
refine !passoc⁻¹* ⬝* pwhisker_right _ !loop_ptrunc_maxm2_pequiv_ptr⁻¹*,
end end
definition strunc_elim [constructor] {k : } {E F : spectrum} (f : E →ₛ F)
(H : is_strunc k F) : strunc k E →ₛ F :=
smap.mk (λn, ptrunc.elim (maxm2 (k + n)) (f n))
abstract begin
intro n,
apply psquare_of_phomotopy,
symmetry,
refine !passoc⁻¹* ⬝* pwhisker_right _ !loop_ptrunc_maxm2_pequiv_ptrunc_elim' ⬝* _,
refine @(ptrunc_elim_ptrunc_functor _ _ _) _ ⬝* _,
refine _ ⬝* @(ptrunc_elim_pcompose _ _ _) _ _,
apply is_trunc_maxm2_loop,
refine is_trunc_of_eq _ (H (n+1)), exact ap maxm2 (add.assoc k n 1)⁻¹,
apply ptrunc_elim_phomotopy2,
apply phomotopy_of_psquare,
apply ptranspose,
apply smap.glue_square
end end
definition strunc_functor [constructor] (k : ) {E F : spectrum} (f : E →ₛ F) :
strunc k E →ₛ strunc k F :=
strunc_elim (str k F ∘ₛ f) (is_strunc_strunc k F)
definition is_strunc_sunit (n : ) : is_strunc n sunit :=
begin
intro k, apply is_trunc_lift, apply is_trunc_unit
end
open option
definition is_strunc_add_point_spectrum {X : Type} {Y : X → spectrum} {s₀ : }
(H : Πx, is_strunc s₀ (Y x)) : Π(x : X₊), is_strunc s₀ (add_point_spectrum Y x)
| (some x) := H x
| none := is_strunc_sunit s₀
definition is_strunc_EM_spectrum (G : AbGroup)
: is_strunc 0 (EM_spectrum G) :=
begin
intro n, induction n with n n,
{ -- case ≥ 0
apply is_trunc_maxm2_change_int (EM G n) (zero_add n)⁻¹,
apply is_trunc_EM },
{ change is_contr (EM_spectrum G (-[1+n])),
induction n with n IH,
{ -- case = -1
apply is_contr_loop, exact is_trunc_EM G 0 },
{ -- case < -1
apply is_trunc_loop, apply is_trunc_succ, exact IH }}
end
definition trivial_shomotopy_group_of_is_strunc (E : spectrum)
{n k : } (K : is_strunc n E) (H : n < k)
: is_contr (πₛ[k] E) :=
let m := n + (2 - k) in
have I : m < 2, from
calc
m = (2 - k) + n : int.add_comm n (2 - k)
... < (2 - k) + k : add_lt_add_left H (2 - k)
... = 2 : sub_add_cancel 2 k,
@trivial_homotopy_group_of_is_trunc (E (2 - k)) (max0 m) 2
(is_trunc_of_is_trunc_maxm2 m (E (2 - k)) (K (2 - k)))
(nat.succ_le_succ (max0_le_of_le (le_sub_one_of_lt I)))
structure truncspectrum (n : ) :=
(carrier : spectrum)
(struct : is_strunc n carrier)
notation n `-spectrum` := truncspectrum n
attribute truncspectrum.carrier [coercion]
definition genspectrum_of_truncspectrum (n : )
: n-spectrum → gen_spectrum + :=
λ E, truncspectrum.carrier E
attribute genspectrum_of_truncspectrum [coercion]
section
open is_conn
definition is_conn_maxm1_of_maxm2 (A : Type*) (n : )
: is_conn (maxm2 n) A → is_conn (maxm1m1 n).+1 A :=
begin
intro H, induction n with n n,
{ exact H },
{ exact is_conn_minus_one A (tr pt) }
end
definition is_trunc_maxm2_of_maxm1 (A : Type*) (n : )
: is_trunc (maxm1m1 n).+1 A → is_trunc (maxm2 n) A :=
begin
intro H, induction n with n n,
{ exact H},
{ apply is_contr_of_merely_prop,
{ exact H },
{ exact tr pt } }
end
variables (A : Type*) (n : ) [H : is_conn (maxm2 n) A]
include H
definition is_trunc_maxm2_ppi (k l : ) (H3 : l ≤ n+1+k) (P : A → Type*)
(H2 : Πa, is_trunc (maxm2 l) (P a)) : is_trunc (maxm2 k) (Π*(a : A), P a) :=
is_trunc_maxm2_of_maxm1 (Π*(a : A), P a) k
(@is_trunc_ppi_of_is_conn A (maxm1m1 n) (is_conn_maxm1_of_maxm2 A n H) (maxm1m1 k) _
(le.trans (maxm2_monotone H3) (maxm2_le n k)) P H2)
definition is_strunc_spi_of_is_conn (k l : ) (H3 : l ≤ n+1+k) (P : A → spectrum)
(H2 : Πa, is_strunc l (P a)) : is_strunc k (spi A P) :=
begin
intro m, unfold spi,
exact is_trunc_maxm2_ppi A n (k+m) _ (le.trans (add_le_add_right H3 _)
(le_of_eq (add.assoc (n+1) k m))) (λ a, P a m) (λa, H2 a m)
end
end
definition is_strunc_spi_of_le {A : Type*} (k n : ) (H : n ≤ k) (P : A → spectrum)
(H2 : Πa, is_strunc n (P a)) : is_strunc k (spi A P) :=
begin
assert K : n ≤ -[1+ 0] + 1 + k,
{ krewrite (int.zero_add k), exact H },
{ exact @is_strunc_spi_of_is_conn A (-[1+ 0]) (is_conn.is_conn_minus_two A) k _ K P H2 }
end
definition is_strunc_spi {A : Type*} (n : ) (P : A → spectrum) (H : Πa, is_strunc n (P a))
: is_strunc n (spi A P) :=
is_strunc_spi_of_le n n !le.refl P H
definition is_strunc_sp_cotensor (n : ) (A : Type*) {Y : spectrum} (H : is_strunc n Y)
: is_strunc n (sp_cotensor A Y) :=
is_strunc_pequiv_closed (λn, !pppi_pequiv_ppmap) (is_strunc_spi n (λa, Y) (λa, H))
definition is_strunc_sp_ucotensor (n : ) (A : Type) {Y : spectrum} (H : is_strunc n Y)
: is_strunc n (sp_ucotensor A Y) :=
λk, !pi.is_trunc_arrow
end spectrum