Spectral/algebra/direct_sum.hlean

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/-
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Copyright (c) 2015 Floris van Doorn, Egbert Rijke, Favonia. All rights reserved.
Released under Apache 2.0 license as described in the file LICENSE.
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Authors: Floris van Doorn, Egbert Rijke, Favonia
Constructions with groups
-/
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import .quotient_group .free_abelian_group .product_group
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open eq is_equiv algebra is_trunc set_quotient relation sigma prod sum list trunc function equiv sigma.ops lift
namespace group
section
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parameters {I : Type} [is_set I] (Y : I → AbGroup)
variables {A' : AbGroup} {Y' : I → AbGroup}
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open option pointed
definition dirsum_carrier : AbGroup := free_ab_group (Σi, Y i)₊
local abbreviation ι [constructor] := (@free_ab_group_inclusion (Σi, Y i)₊ _ ∘ some)
inductive dirsum_rel : dirsum_carrier → Type :=
| rmk : Πi y₁ y₂, dirsum_rel (ι ⟨i, y₁⟩ * ι ⟨i, y₂⟩ * (ι ⟨i, y₁ * y₂⟩)⁻¹)
definition dirsum : AbGroup := quotient_ab_group_gen dirsum_carrier (λg, ∥dirsum_rel g∥)
-- definition dirsum_carrier_incl [constructor] (i : I) : Y i →g dirsum_carrier :=
definition dirsum_incl [constructor] (i : I) : Y i →g dirsum :=
homomorphism.mk (λy, class_of (ι ⟨i, y⟩))
begin intro g h, symmetry, apply gqg_eq_of_rel, apply tr, apply dirsum_rel.rmk end
parameter {Y}
definition dirsum.rec {P : dirsum → Type} [H : Πg, is_prop (P g)]
(h₁ : Πi (y : Y i), P (dirsum_incl i y)) (h₂ : P 1) (h₃ : Πg h, P g → P h → P (g * h)) :
Πg, P g :=
begin
refine @set_quotient.rec_prop _ _ _ H _,
refine @set_quotient.rec_prop _ _ _ (λx, !H) _,
esimp, intro l, induction l with s l ih,
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{ exact h₂ },
{ induction s with z z,
{ induction z with v,
{ refine transport P _ ih, apply ap class_of, symmetry,
exact eq_of_rel (tr (free_ab_group.fcg_rel.resp_append !free_ab_group.fcg_rel.cancelpt1 (free_ab_group.fcg_rel.rrefl l))) },
{ induction v with i y, exact h₃ _ _ (h₁ i y) ih } },
{ induction z with v,
{ refine transport P _ ih, apply ap class_of, symmetry,
exact eq_of_rel (tr (free_ab_group.fcg_rel.resp_append !free_ab_group.fcg_rel.cancelpt2 (free_ab_group.fcg_rel.rrefl l))) },
{ induction v with i y,
refine h₃ (gqg_map _ _ (class_of [inr (some ⟨i, y⟩)])) _ _ ih,
refine transport P _ (h₁ i y⁻¹),
refine _ ⬝ !one_mul,
refine _ ⬝ ap (λx, mul x _) (to_respect_zero (dirsum_incl i)),
apply gqg_eq_of_rel',
apply tr, esimp,
refine transport dirsum_rel _ (dirsum_rel.rmk i y⁻¹ y),
rewrite [mul.left_inv, mul.assoc]} } }
end
definition dirsum_homotopy {φ ψ : dirsum →g A'}
(h : Πi (y : Y i), φ (dirsum_incl i y) = ψ (dirsum_incl i y)) : φ ~ ψ :=
begin
refine dirsum.rec _ _ _,
exact h,
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refine !to_respect_zero ⬝ !to_respect_zero⁻¹,
intro g₁ g₂ h₁ h₂, rewrite [* to_respect_mul, h₁, h₂]
end
definition dirsum_elim_resp_quotient (f : Πi, Y i →g A') (g : dirsum_carrier)
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(r : ∥dirsum_rel g∥) : free_ab_group_elim ((pmap_equiv_left (Σi, Y i) A')⁻¹ (λv, f v.1 v.2)) g = 1 :=
begin
induction r with r, induction r,
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rewrite [to_respect_mul, to_respect_inv, to_respect_mul, ▸*, ↑foldl, *one_mul],
rewrite [↑pmap_equiv_left], esimp,
rewrite [-to_respect_mul], apply mul.right_inv
end
definition dirsum_elim [constructor] (f : Πi, Y i →g A') : dirsum →g A' :=
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gqg_elim _ (free_ab_group_elim ((pmap_equiv_left (Σi, Y i) A')⁻¹ (λv, f v.1 v.2))) (dirsum_elim_resp_quotient f)
definition dirsum_elim_compute (f : Πi, Y i →g A') (i : I) (y : Y i) :
dirsum_elim f (dirsum_incl i y) = f i y :=
begin
apply one_mul
end
definition dirsum_elim_unique (f : Πi, Y i →g A') (k : dirsum →g A')
(H : Πi, k ∘g dirsum_incl i ~ f i) : k ~ dirsum_elim f :=
begin
apply gqg_elim_unique,
apply free_ab_group_elim_unique,
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intro x, induction x with z,
{ esimp, refine _ ⬝ to_respect_zero k, apply ap k, apply ap class_of,
exact eq_of_rel (tr !free_ab_group.fcg_rel.cancelpt1) },
{ induction z with i y, exact H i y }
end
end
definition binary_dirsum (G H : AbGroup) : dirsum (bool.rec G H) ≃g G ×ag H :=
let branch := bool.rec G H in
let to_hom := (dirsum_elim (bool.rec (product_inl G H) (product_inr G H))
: dirsum (bool.rec G H) →g G ×ag H) in
let from_hom := (Group_sum_elim (dirsum (bool.rec G H))
(dirsum_incl branch bool.ff) (dirsum_incl branch bool.tt)
: G ×g H →g dirsum branch) in
begin
fapply isomorphism.mk,
{ exact dirsum_elim (bool.rec (product_inl G H) (product_inr G H)) },
fapply adjointify,
{ exact from_hom },
{ intro gh, induction gh with g h,
exact prod_eq (mul_one (1 * g) ⬝ one_mul g) (ap (λ o, o * h) (mul_one 1) ⬝ one_mul h) },
{ refine dirsum.rec _ _ _,
{ intro b x,
refine ap from_hom (dirsum_elim_compute (bool.rec (product_inl G H) (product_inr G H)) b x) ⬝ _,
induction b,
{ exact ap (λ y, dirsum_incl branch bool.ff x * y) (to_respect_one (dirsum_incl branch bool.tt)) ⬝ mul_one _ },
{ exact ap (λ y, y * dirsum_incl branch bool.tt x) (to_respect_one (dirsum_incl branch bool.ff)) ⬝ one_mul _ }
},
{ refine ap from_hom (to_respect_one to_hom) ⬝ to_respect_one from_hom },
{ intro g h gβ hβ,
refine ap from_hom (to_respect_mul to_hom _ _) ⬝ to_respect_mul from_hom _ _ ⬝ _,
exact ap011 mul gβ hβ
}
}
end
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variables {I J : Type} [is_set I] [is_set J] {Y Y' Y'' : I → AbGroup}
definition dirsum_functor [constructor] (f : Πi, Y i →g Y' i) : dirsum Y →g dirsum Y' :=
dirsum_elim (λi, dirsum_incl Y' i ∘g f i)
theorem dirsum_functor_compose (f' : Πi, Y' i →g Y'' i) (f : Πi, Y i →g Y' i) :
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dirsum_functor f' ∘g dirsum_functor f ~ dirsum_functor (λi, f' i ∘g f i) :=
begin
apply dirsum_homotopy,
intro i y, reflexivity,
end
variable (Y)
definition dirsum_functor_gid : dirsum_functor (λi, gid (Y i)) ~ gid (dirsum Y) :=
begin
apply dirsum_homotopy,
intro i y, reflexivity,
end
variable {Y}
definition dirsum_functor_mul (f f' : Πi, Y i →g Y' i) :
homomorphism_mul (dirsum_functor f) (dirsum_functor f') ~
dirsum_functor (λi, homomorphism_mul (f i) (f' i)) :=
begin
apply dirsum_homotopy,
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intro i y, exact sorry
end
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definition dirsum_functor_homotopy (f f' : Πi, Y i →g Y' i) (p : f ~2 f') :
dirsum_functor f ~ dirsum_functor f' :=
begin
apply dirsum_homotopy,
intro i y, exact sorry
end
definition dirsum_functor_left [constructor] (f : J → I) : dirsum (Y ∘ f) →g dirsum Y :=
dirsum_elim (λj, dirsum_incl Y (f j))
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definition dirsum_isomorphism [constructor] (f : Πi, Y i ≃g Y' i) : dirsum Y ≃g dirsum Y' :=
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let to_hom := dirsum_functor (λ i, f i) in
let from_hom := dirsum_functor (λ i, (f i)⁻¹ᵍ) in
begin
fapply isomorphism.mk,
exact dirsum_functor (λ i, f i),
fapply is_equiv.adjointify,
exact dirsum_functor (λ i, (f i)⁻¹ᵍ),
{ intro ds,
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refine (homomorphism_compose_eq (dirsum_functor (λ i, f i)) (dirsum_functor (λ i, (f i)⁻¹ᵍ)) _)⁻¹ ⬝ _,
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refine dirsum_functor_compose (λ i, f i) (λ i, (f i)⁻¹ᵍ) ds ⬝ _,
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refine dirsum_functor_homotopy _ (λ i, !gid) (λ i, to_right_inv (equiv_of_isomorphism (f i))) ds ⬝ _,
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exact !dirsum_functor_gid
},
{ intro ds,
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refine (homomorphism_compose_eq (dirsum_functor (λ i, (f i)⁻¹ᵍ)) (dirsum_functor (λ i, f i)) _)⁻¹ ⬝ _,
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refine dirsum_functor_compose (λ i, (f i)⁻¹ᵍ) (λ i, f i) ds ⬝ _,
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refine dirsum_functor_homotopy _ (λ i, !gid) (λ i x,
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proof
to_left_inv (equiv_of_isomorphism (f i)) x
qed
) ds ⬝ _,
exact !dirsum_functor_gid
}
end
end group
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namespace group
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definition dirsum_down_left.{u v w} {I : Type.{u}} [is_set I] (Y : I → AbGroup.{w})
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: dirsum (Y ∘ down.{u v}) ≃g dirsum Y :=
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proof
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let to_hom := @dirsum_functor_left _ _ _ _ Y down.{u v} in
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let from_hom := dirsum_elim (λi, dirsum_incl (Y ∘ down.{u v}) (up.{u v} i)) in
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begin
fapply isomorphism.mk,
{ exact to_hom },
fapply adjointify,
{ exact from_hom },
{ intro ds,
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refine (homomorphism_compose_eq to_hom from_hom ds)⁻¹ ⬝ _,
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refine @dirsum_homotopy I _ Y (dirsum Y) (to_hom ∘g from_hom) !gid _ ds,
intro i y,
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refine homomorphism_compose_eq to_hom from_hom _ ⬝ _,
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refine ap to_hom (dirsum_elim_compute (λi, dirsum_incl (Y ∘ down.{u v}) (up.{u v} i)) i y) ⬝ _,
refine dirsum_elim_compute _ (up.{u v} i) y ⬝ _,
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reflexivity
},
{ intro ds,
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refine (homomorphism_compose_eq from_hom to_hom ds)⁻¹ ⬝ _,
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refine @dirsum_homotopy _ _ (Y ∘ down.{u v}) (dirsum (Y ∘ down.{u v})) (from_hom ∘g to_hom) !gid _ ds,
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intro i y, induction i with i,
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refine homomorphism_compose_eq from_hom to_hom _ ⬝ _,
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refine ap from_hom (dirsum_elim_compute (λi, dirsum_incl Y (down.{u v} i)) (up.{u v} i) y) ⬝ _,
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refine dirsum_elim_compute _ i y ⬝ _,
reflexivity
}
end
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qed
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end group