175 lines
6.8 KiB
Text
175 lines
6.8 KiB
Text
/- Graded (left-) R-modules for a ring R. -/
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-- Author: Floris van Doorn
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import .left_module
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open algebra eq left_module pointed function equiv is_equiv is_trunc prod
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namespace left_module
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definition graded (str : Type) (I : Type) : Type := I → str
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definition graded_module (R : Ring) : Type → Type := graded (LeftModule R)
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variables {R : Ring} {I : Type} {M M₁ M₂ M₃ : graded_module R I}
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/-
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morphisms between graded modules.
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The definition is unconventional in two ways:
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(1) The degree is determined by an endofunction instead of a element of I (and in this case we
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don't need to assume that I is a group). The "standard" degree i corresponds to the endofunction
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which is addition with i on the right. However, this is more flexible. For example, the
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composition of two graded module homomorphisms φ₂ and φ₁ with degrees i₂ and i₁ has type
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M₁ i → M₂ ((i + i₁) + i₂).
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However, a homomorphism with degree i₁ + i₂ must have type
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M₁ i → M₂ (i + (i₁ + i₂)),
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which means that we need to insert a transport. With endofunctions this is not a problem:
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λi, (i + i₁) + i₂
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is a perfectly fine degree of a map
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(2) Since we cannot eliminate all possible transports, we don't define a homomorphism as function
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M₁ i →lm M₂ (i + deg f) or M₁ i →lm M₂ (deg f i)
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but as a function taking a path as argument. Specifically, for every path
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deg f i = j
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we get a function M₁ i → M₂ j.
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-/
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structure graded_hom (M₁ M₂ : graded_module R I) : Type :=
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mk' :: (d : I → I)
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(fn' : Π⦃i j : I⦄ (p : d i = j), M₁ i →lm M₂ j)
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notation M₁ ` →gm ` M₂ := graded_hom M₁ M₂
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abbreviation deg [unfold 5] := @graded_hom.d
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notation `↘` := graded_hom.fn' -- there is probably a better character for this?
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definition graded_hom_fn [unfold 5] [coercion] (f : M₁ →gm M₂) (i : I) : M₁ i →lm M₂ (deg f i) :=
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↘f idp
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definition graded_hom.mk [constructor] {M₁ M₂ : graded_module R I} (d : I → I)
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(fn : Πi, M₁ i →lm M₂ (d i)) : M₁ →gm M₂ :=
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graded_hom.mk' d (λi j p, homomorphism_of_eq (ap M₂ p) ∘lm fn i)
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variables {f' : M₂ →gm M₃} {f : M₁ →gm M₂}
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definition graded_hom_compose [constructor] (f' : M₂ →gm M₃) (f : M₁ →gm M₂) : M₁ →gm M₃ :=
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graded_hom.mk (deg f' ∘ deg f) (λi, f' (deg f i) ∘lm f i)
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variable (M)
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definition graded_hom_id [constructor] [refl] : M →gm M :=
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graded_hom.mk id (λi, lmid)
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variable {M}
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abbreviation gmid [constructor] := graded_hom_id M
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infixr ` ∘gm `:75 := graded_hom_compose
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structure graded_iso (M₁ M₂ : graded_module R I) : Type :=
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(to_hom : M₁ →gm M₂)
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(is_equiv_deg : is_equiv (deg to_hom))
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(is_equiv_to_hom : Π⦃i j⦄ (p : deg to_hom i = j), is_equiv (↘to_hom p))
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infix ` ≃gm `:25 := graded_iso
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attribute graded_iso.to_hom [coercion]
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attribute graded_iso.is_equiv_deg [instance] [priority 1010]
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attribute graded_iso._trans_of_to_hom [unfold 5]
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definition is_equiv_graded_iso [instance] [priority 1010] (φ : M₁ ≃gm M₂) (i : I) :
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is_equiv (φ i) :=
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graded_iso.is_equiv_to_hom φ idp
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definition isomorphism_of_graded_iso' [constructor] (φ : M₁ ≃gm M₂) {i j : I} (p : deg φ i = j) :
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M₁ i ≃lm M₂ j :=
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isomorphism.mk (↘φ p) !graded_iso.is_equiv_to_hom
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definition isomorphism_of_graded_iso [constructor] (φ : M₁ ≃gm M₂) (i : I) :
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M₁ i ≃lm M₂ (deg φ i) :=
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isomorphism.mk (φ i) _
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definition graded_iso_of_isomorphism [constructor] (d : I ≃ I) (φ : Πi, M₁ i ≃lm M₂ (d i)) :
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M₁ ≃gm M₂ :=
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begin
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apply graded_iso.mk (graded_hom.mk d φ), apply to_is_equiv, intro i j p, induction p,
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exact to_is_equiv (equiv_of_isomorphism (φ i)),
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end
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definition graded_iso_of_eq [constructor] {M₁ M₂ : graded_module R I} (p : M₁ ~ M₂)
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: M₁ ≃gm M₂ :=
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graded_iso_of_isomorphism erfl (λi, isomorphism_of_eq (p i))
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-- definition graded_iso.MK [constructor] (d : I ≃ I) (fn : Πi, M₁ i →lm M₂ (d i))
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-- : M₁ ≃gm M₂ :=
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-- graded_iso.mk _ _ _ --d (λi j p, homomorphism_of_eq (ap M₂ p) ∘lm fn i)
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definition isodeg [unfold 5] (φ : M₁ ≃gm M₂) : I ≃ I :=
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equiv.mk (deg φ) _
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definition graded_iso_to_lminv [constructor] (φ : M₁ ≃gm M₂) : M₂ →gm M₁ :=
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graded_hom.mk (deg φ)⁻¹
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abstract begin
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intro i, apply to_lminv,
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apply isomorphism_of_graded_iso' φ,
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apply to_right_inv (isodeg φ) i
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end end
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definition to_gminv [constructor] (φ : M₁ ≃gm M₂) : M₂ →gm M₁ :=
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graded_hom.mk (deg φ)⁻¹
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abstract begin
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intro i, apply isomorphism.to_hom, symmetry,
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apply isomorphism_of_graded_iso' φ,
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apply to_right_inv (isodeg φ) i
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end end
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variable (M)
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definition graded_iso.refl [refl] [constructor] : M ≃gm M :=
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graded_iso_of_isomorphism equiv.rfl (λi, isomorphism.rfl)
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variable {M}
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definition graded_iso.rfl [refl] [constructor] : M ≃gm M := graded_iso.refl M
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definition graded_iso.symm [symm] [constructor] (φ : M₁ ≃gm M₂) : M₂ ≃gm M₁ :=
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graded_iso.mk (to_gminv φ) !is_equiv_inv
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(λi j p, @is_equiv_compose _ _ _ _ _ !isomorphism.is_equiv_to_hom !is_equiv_cast)
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definition graded_iso.trans [trans] [constructor] (φ : M₁ ≃gm M₂) (ψ : M₂ ≃gm M₃) : M₁ ≃gm M₃ :=
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graded_iso_of_isomorphism (isodeg φ ⬝e isodeg ψ)
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(λi, isomorphism_of_graded_iso φ i ⬝lm isomorphism_of_graded_iso ψ (deg φ i))
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definition graded_iso.eq_trans [trans] [constructor]
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{M₁ M₂ : graded_module R I} {M₃ : graded_module R I} (φ : M₁ ~ M₂) (ψ : M₂ ≃gm M₃) : M₁ ≃gm M₃ :=
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proof graded_iso.trans (graded_iso_of_eq φ) ψ qed
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definition graded_iso.trans_eq [trans] [constructor]
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{M₁ : graded_module R I} {M₂ M₃ : graded_module R I} (φ : M₁ ≃gm M₂) (ψ : M₂ ~ M₃) : M₁ ≃gm M₃ :=
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graded_iso.trans φ (graded_iso_of_eq ψ)
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postfix `⁻¹ᵍᵐ`:(max + 1) := graded_iso.symm
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infixl ` ⬝gm `:75 := graded_iso.trans
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infixl ` ⬝gmp `:75 := graded_iso.trans_eq
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infixl ` ⬝pgm `:75 := graded_iso.eq_trans
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definition graded_hom_of_eq [constructor] {M₁ M₂ : graded_module R I} (p : M₁ ~ M₂)
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: M₁ →gm M₂ :=
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graded_iso_of_eq p
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/- exact couples -/
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definition is_exact_gmod (f : M₁ →gm M₂) (f' : M₂ →gm M₃) : Type :=
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Π{i j k} (p : deg f i = j) (q : deg f' j = k), is_exact_mod (↘f p) (↘f' q)
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structure exact_couple (M₁ M₂ : graded_module R I) : Type :=
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(i : M₁ →gm M₁) (j : M₁ →gm M₂) (k : M₂ →gm M₁)
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(exact_ij : is_exact_gmod i j)
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(exact_jk : is_exact_gmod j k)
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(exact_ki : is_exact_gmod k i)
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variables {i : M₁ →gm M₁} {j : M₁ →gm M₂} {k : M₂ →gm M₁}
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(exact_ij : is_exact_gmod i j)
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(exact_jk : is_exact_gmod j k)
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(exact_ki : is_exact_gmod k i)
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namespace derived_couple
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definition d : M₂ →gm M₂ := j ∘gm k
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end derived_couple
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end left_module
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