242 lines
11 KiB
Text
242 lines
11 KiB
Text
/-
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Copyright (c) 2015 Egbert Rijke. All rights reserved.
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Released under Apache 2.0 license as described in the file LICENSE.
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Authors: Floris van Doorn, Egbert Rijke
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Basic concepts of group theory
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-/
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import algebra.group_theory hit.set_quotient types.sigma types.list types.sum
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open eq algebra is_trunc set_quotient relation sigma sigma.ops prod prod.ops sum list trunc function
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equiv
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namespace group
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/- #Subgroups -/
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/-- Recall that a subtype of a type A is the same thing as a family of mere propositions over A. Thus, we define a subgroup of a group G to be a family of mere propositions over (the underlying type of) G, closed under the constants and operations --/
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/-- Question: Why is this called subgroup_rel. Because it is a unary relation? --/
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structure subgroup_rel.{u v} (G : Group.{u}) : Type.{max u (v+1)} :=
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(R : G → Prop.{v})
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(Rone : R one)
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(Rmul : Π{g h}, R g → R h → R (g * h))
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(Rinv : Π{g}, R g → R (g⁻¹))
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/-- Every group G has at least two subgroups, the trivial subgroup containing only one, and the full subgroup. --/
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definition trivial_subgroup.{u} (G : Group.{u}) : subgroup_rel.{u u} G :=
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begin
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fapply subgroup_rel.mk,
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{ intro g, fapply trunctype.mk, exact (g = one), exact _ },
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{ esimp },
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{ intros g h p q, esimp at *, rewrite p, rewrite q, exact mul_one one},
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{ intros g p, esimp at *, rewrite p, exact one_inv }
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end
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definition is_trivial_subgroup (G : Group) (R : subgroup_rel G) : Prop := sorry /- Π g, R g = trivial_subgroup g -/
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definition full_subgroup.{u} (G : Group.{u}) : subgroup_rel.{u 0} G :=
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begin
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fapply subgroup_rel.mk,
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{ intro g, fapply trunctype.mk, exact unit, exact _}, -- instead of the unit type, we take g = g, because the unit type is in Type₀ and not in Type.{u}
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{ esimp, constructor },
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{ intros g h p q, esimp, constructor },
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{ intros g p, esimp, constructor }
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end
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definition is_full_subgroup (G : Group) (R : subgroup_rel G) : Prop := sorry /- Π g, R g -/
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/-- Every group homomorphism f : G -> H determines a subgroup of H, the image of f, and a subgroup of G, the kernel of f. In the following definition we define the image of f. Since a subgroup is required to be closed under the group operations, showing that the image of f is closed under the group operations is part of the definition of the image of f. --/
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/-- TODO. We need to find some reasonable way of dealing with universe levels. The reason why it currently is what it is, is because lean is inflexible with universe leves once tactic mode is started --/
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definition image_subgroup.{u1 u2} {G : Group.{u1}} {H : Group.{u2}} (f : G →g H) : subgroup_rel.{u2 (max u1 u2)} H :=
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begin
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fapply subgroup_rel.mk,
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-- definition of the subset
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{ intro h, apply ttrunc, exact fiber f h},
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-- subset contains 1
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{ apply trunc.tr, fapply fiber.mk, exact 1, apply respect_one},
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-- subset is closed under multiplication
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{ intro h h', intro u v,
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induction u with p, induction v with q,
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induction p with x p, induction q with y q,
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induction p, induction q,
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apply tr, apply fiber.mk (x * y), apply respect_mul},
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-- subset is closed under inverses
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{ intro g, intro t, induction t, induction a with x p, induction p,
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apply tr, apply fiber.mk x⁻¹, apply respect_inv }
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end
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section kernels
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variables {G₁ G₂ : Group}
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-- TODO: maybe define this in more generality for pointed types? <-- Do you mean pointed sets?
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definition kernel_pred [constructor] (φ : G₁ →g G₂) (g : G₁) : Prop := trunctype.mk (φ g = 1) _
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theorem kernel_mul (φ : G₁ →g G₂) (g h : G₁) (H₁ : kernel_pred φ g) (H₂ : kernel_pred φ h) : kernel_pred φ (g *[G₁] h) :=
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begin
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esimp at *,
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exact calc
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φ (g * h) = (φ g) * (φ h) : to_respect_mul
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... = 1 * (φ h) : H₁
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... = 1 * 1 : H₂
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... = 1 : one_mul
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end
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theorem kernel_inv (φ : G₁ →g G₂) (g : G₁) (H : kernel_pred φ g) : kernel_pred φ (g⁻¹) :=
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begin
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esimp at *,
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exact calc
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φ g⁻¹ = (φ g)⁻¹ : to_respect_inv
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... = 1⁻¹ : H
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... = 1 : one_inv
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end
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definition kernel_subgroup [constructor] (φ : G₁ →g G₂) : subgroup_rel G₁ :=
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⦃ subgroup_rel,
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R := kernel_pred φ,
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Rone := respect_one φ,
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Rmul := kernel_mul φ,
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Rinv := kernel_inv φ
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⦄
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end kernels
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/-- Now we should be able to show that if f is a homomorphism for which the kernel is trivial and the image is full, then f is an isomorphism, except that no one defined the proposition that f is an isomorphism :/ --/
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-- definition is_iso_from_kertriv_imfull {G H : Group} (f : G →g H) : is_trivial_subgroup G (kernel f) → is_full_subgroup H (image_subgroup f) → unit /- replace unit by is_isomorphism f -/ := sorry
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/- #Normal subgroups -/
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/-- Next, we formalize some aspects of normal subgroups. Recall that a normal subgroup H of a group G is a subgroup which is invariant under all inner automorophisms on G. --/
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definition aut.{u} (G : Group.{u}) : Group.{u} :=
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begin
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fapply Group.mk,
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exact (G ≃g G),
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fapply group.mk,
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{ intros e f, fapply isomorphism.mk, exact f ∘g e, exact is_equiv.is_equiv_compose f e},
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{ /-is_set G ≃g G-/ exact sorry},
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{ /-associativity-/ intros e f g, exact sorry},
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{ /-identity-/ fapply isomorphism.mk, exact sorry, exact sorry},
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{ /-identity is left unit-/ exact sorry},
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{ /-identity is right unit-/ exact sorry},
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{ /-inverses-/ exact sorry},
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{ /-inverse is right inverse?-/ exact sorry},
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end
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-- definition inner_aut (G : Group) : G →g (G ≃g G) := sorry /-- h ↦ h * g * h⁻¹ --/
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/-- There is a problem with the following definition, namely that there is no mere proposition that says that N is normal --/
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structure normal_subgroup_rel (G : Group) extends subgroup_rel G :=
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(is_normal : Π{g} h, R g → R (h * g * h⁻¹))
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/-- expect something like (is_normal : isNormal R) where isNormal R is a predefined predicate on subgroups of G --/
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attribute subgroup_rel.R [coercion]
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abbreviation subgroup_to_rel [unfold 2] := @subgroup_rel.R
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abbreviation subgroup_has_one [unfold 2] := @subgroup_rel.Rone
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abbreviation subgroup_respect_mul [unfold 2] := @subgroup_rel.Rmul
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abbreviation subgroup_respect_inv [unfold 2] := @subgroup_rel.Rinv
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abbreviation is_normal_subgroup [unfold 2] := @normal_subgroup_rel.is_normal
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variables {G G' : Group} (H : subgroup_rel G) (N : normal_subgroup_rel G) {g g' h h' k : G}
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{A B : CommGroup}
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theorem is_normal_subgroup' (h : G) (r : N g) : N (h⁻¹ * g * h) :=
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inv_inv h ▸ is_normal_subgroup N h⁻¹ r
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definition normal_subgroup_rel_comm.{u} (R : subgroup_rel.{_ u} A) : normal_subgroup_rel.{_ u} A :=
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⦃normal_subgroup_rel, R,
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is_normal := abstract begin
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intros g h r, xrewrite [mul.comm h g, mul_inv_cancel_right], exact r
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end end⦄
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theorem is_normal_subgroup_rev (h : G) (r : N (h * g * h⁻¹)) : N g :=
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have H : h⁻¹ * (h * g * h⁻¹) * h = g, from calc
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h⁻¹ * (h * g * h⁻¹) * h = h⁻¹ * (h * g) * h⁻¹ * h : by rewrite [-mul.assoc h⁻¹]
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... = h⁻¹ * (h * g) : by rewrite [inv_mul_cancel_right]
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... = g : inv_mul_cancel_left,
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H ▸ is_normal_subgroup' N h r
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theorem is_normal_subgroup_rev' (h : G) (r : N (h⁻¹ * g * h)) : N g :=
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is_normal_subgroup_rev N h⁻¹ ((inv_inv h)⁻¹ ▸ r)
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theorem normal_subgroup_insert (r : N k) (r' : N (g * h)) : N (g * (k * h)) :=
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have H1 : N ((g * h) * (h⁻¹ * k * h)), from
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subgroup_respect_mul N r' (is_normal_subgroup' N h r),
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have H2 : (g * h) * (h⁻¹ * k * h) = g * (k * h), from calc
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(g * h) * (h⁻¹ * k * h) = g * (h * (h⁻¹ * k * h)) : mul.assoc
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... = g * (h * (h⁻¹ * (k * h))) : by rewrite [mul.assoc h⁻¹]
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... = g * (k * h) : by rewrite [mul_inv_cancel_left],
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show N (g * (k * h)), from H2 ▸ H1
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/-- In the following, we show that the kernel of any group homomorphism f : G₁ →g G₂ is a normal subgroup of G₁ --/
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theorem is_normal_subgroup_kernel {G₁ G₂ : Group} (φ : G₁ →g G₂) (g : G₁) (h : G₁)
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: kernel_pred φ g → kernel_pred φ (h * g * h⁻¹) :=
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begin
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esimp at *,
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intro p,
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exact calc
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φ (h * g * h⁻¹) = (φ (h * g)) * φ (h⁻¹) : to_respect_mul
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... = (φ h) * (φ g) * (φ h⁻¹) : to_respect_mul
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... = (φ h) * 1 * (φ h⁻¹) : p
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... = (φ h) * (φ h⁻¹) : mul_one
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... = (φ h) * (φ h)⁻¹ : to_respect_inv
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... = 1 : mul.right_inv
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end
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/-- Thus, we extend the kernel subgroup to a normal subgroup --/
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definition normal_subgroup_kernel [constructor] {G₁ G₂ : Group} (φ : G₁ →g G₂) : normal_subgroup_rel G₁ :=
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⦃ normal_subgroup_rel,
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kernel_subgroup φ,
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is_normal := is_normal_subgroup_kernel φ
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⦄
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-- this is just (Σ(g : G), H g), but only defined if (H g) is a prop
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definition sg : Type := {g : G | H g}
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local attribute sg [reducible]
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variable {H}
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definition subgroup_one [constructor] : sg H := ⟨one, !subgroup_has_one⟩
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definition subgroup_inv [unfold 3] : sg H → sg H :=
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λv, ⟨v.1⁻¹, subgroup_respect_inv H v.2⟩
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definition subgroup_mul [unfold 3 4] : sg H → sg H → sg H :=
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λv w, ⟨v.1 * w.1, subgroup_respect_mul H v.2 w.2⟩
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section
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local notation 1 := subgroup_one
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local postfix ⁻¹ := subgroup_inv
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local infix * := subgroup_mul
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theorem subgroup_mul_assoc (g₁ g₂ g₃ : sg H) : g₁ * g₂ * g₃ = g₁ * (g₂ * g₃) :=
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subtype_eq !mul.assoc
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theorem subgroup_one_mul (g : sg H) : 1 * g = g :=
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subtype_eq !one_mul
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theorem subgroup_mul_one (g : sg H) : g * 1 = g :=
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subtype_eq !mul_one
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theorem subgroup_mul_left_inv (g : sg H) : g⁻¹ * g = 1 :=
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subtype_eq !mul.left_inv
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theorem subgroup_mul_comm {G : CommGroup} {H : subgroup_rel G} (g h : sg H)
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: g * h = h * g :=
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subtype_eq !mul.comm
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end
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variable (H)
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definition group_sg [constructor] : group (sg H) :=
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group.mk subgroup_mul _ subgroup_mul_assoc subgroup_one subgroup_one_mul subgroup_mul_one
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subgroup_inv subgroup_mul_left_inv
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definition subgroup [constructor] : Group :=
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Group.mk _ (group_sg H)
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definition comm_group_sg [constructor] {G : CommGroup} (H : subgroup_rel G)
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: comm_group (sg H) :=
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⦃comm_group, group_sg H, mul_comm := subgroup_mul_comm⦄
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definition comm_subgroup [constructor] {G : CommGroup} (H : subgroup_rel G)
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: CommGroup :=
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CommGroup.mk _ (comm_group_sg H)
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end group
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