refactor: Create Mathematics folder

HepLean/AnomalyCancellation/LinearMaps.lean

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-/-
-Copyright (c) 2024 Joseph Tooby-Smith. All rights reserved.
-Released under Apache 2.0 license.
-Authors: Joseph Tooby-Smith
--/
-import Mathlib.Tactic.Polyrith
-import Mathlib.Algebra.Module.LinearMap.Basic
-import Mathlib.Data.Fintype.BigOperators
-/-!
-# Linear maps
-
-Some definitions and properties of linear, bilinear, and trilinear maps, along with homogeneous
-quadratic and cubic equations.
-
-## TODO
-
-Use definitions in `Mathlib4` for definitions where possible.
-In particular a HomogeneousQuadratic should be a map `V →ₗ[ℚ] V →ₗ[ℚ] ℚ`  etc.
-
--/
-
-/-- The structure defining a homogeneous quadratic equation. -/
-@[simp]
-def HomogeneousQuadratic (V : Type) [AddCommMonoid V] [Module ℚ V] : Type :=
-  V →ₑ[((fun a => a ^ 2) : ℚ → ℚ)] ℚ
-
-namespace HomogeneousQuadratic
-
-variable {V : Type} [AddCommMonoid V] [Module ℚ V]
-
-instance instFun : FunLike (HomogeneousQuadratic V) V ℚ where
-  coe f := f.toFun
-  coe_injective' f g h := by
-    cases f
-    cases g
-    simp_all
-
-lemma map_smul (f : HomogeneousQuadratic V) (a : ℚ) (S : V) : f (a • S) = a ^ 2 * f S :=
-  f.map_smul' a S
-
-end HomogeneousQuadratic
-
-
-/-- The structure of a symmetric bilinear function. -/
-structure BiLinearSymm (V : Type) [AddCommMonoid V] [Module ℚ V] extends V →ₗ[ℚ] V →ₗ[ℚ] ℚ where
-  swap' : ∀ S T, toFun S T = toFun T S
-
-/-- A symmetric bilinear function. -/
-class IsSymmetric {V : Type} [AddCommMonoid V] [Module ℚ V] (f : V →ₗ[ℚ] V →ₗ[ℚ] ℚ) : Prop where
-  swap : ∀ S T, f S T = f T S
-
-namespace BiLinearSymm
-open BigOperators
-
-variable {V : Type} [AddCommMonoid V] [Module ℚ V]
-
-instance instFun (V : Type) [AddCommMonoid V] [Module ℚ V] :
-    FunLike (BiLinearSymm V) V (V →ₗ[ℚ] ℚ) where
-  coe f := f.toFun
-  coe_injective' f g h := by
-    cases f
-    cases g
-    simp_all
-
-/-- The construction of a symmetric bilinear map from `smul` and `map_add` in the first factor,
-and swap. -/
-@[simps!]
-def mk₂ (f : V × V → ℚ) (map_smul : ∀ a S T, f (a • S, T) = a * f (S, T))
-    (map_add : ∀ S1 S2 T, f (S1 + S2, T) = f (S1, T) + f (S2, T))
-    (swap : ∀ S T, f (S, T) = f (T, S)) : BiLinearSymm V where
-  toFun := fun S => {
-    toFun := fun T => f (S, T)
-    map_add' := by
-      intro T1 T2
-      simp only
-      rw [swap, map_add]
-      exact Mathlib.Tactic.LinearCombination.add_pf (swap T1 S) (swap T2 S)
-    map_smul' :=by
-      intro a T
-      simp only [eq_ratCast, Rat.cast_eq_id, id_eq, smul_eq_mul]
-      rw [swap, map_smul]
-      exact congrArg (HMul.hMul a) (swap T S)
-  }
-  map_smul' := fun a S  => LinearMap.ext fun T => map_smul a S T
-  map_add' := fun S1 S2  => LinearMap.ext fun T => map_add S1 S2 T
-  swap' := swap
-
-lemma map_smul₁ (f : BiLinearSymm V) (a : ℚ) (S T : V) : f (a • S) T = a * f S T := by
-  erw [f.map_smul a S]
-  rfl
-
-lemma swap (f : BiLinearSymm V) (S T : V) : f S T = f T S :=
-  f.swap' S T
-
-lemma map_smul₂ (f : BiLinearSymm V) (a : ℚ)  (S : V) (T : V) : f S (a • T) = a * f S T := by
-  rw [f.swap, f.map_smul₁, f.swap]
-
-lemma map_add₁ (f : BiLinearSymm V) (S1 S2 T : V) : f (S1 + S2) T = f S1 T + f S2 T := by
-  erw [f.map_add]
-  rfl
-
-lemma map_add₂ (f : BiLinearSymm V) (S : V) (T1 T2 : V) :
-    f S (T1 + T2) = f S T1 + f S T2 := by
-  rw [f.swap, f.map_add₁, f.swap T1 S, f.swap T2 S]
-
-/-- Fixing the second input vectors, the resulting linear map. -/
-def toLinear₁  (f : BiLinearSymm V) (T : V) : V →ₗ[ℚ] ℚ where
-  toFun S := f S T
-  map_add' S1 S2 := map_add₁ f S1 S2 T
-  map_smul' a S := by
-    simp only [f.map_smul₁]
-    rfl
-
-lemma toLinear₁_apply (f : BiLinearSymm V) (S T : V) : f S T = f.toLinear₁ T S := rfl
-
-lemma map_sum₁ {n : ℕ} (f : BiLinearSymm V) (S : Fin n → V) (T : V)  :
-    f (∑ i, S i) T = ∑ i, f (S i) T := by
-  rw [f.toLinear₁_apply]
-  rw [map_sum]
-  rfl
-
-lemma map_sum₂ {n : ℕ} (f : BiLinearSymm V) (S : Fin n → V) (T : V) :
-    f T (∑ i, S i) = ∑ i, f T (S i) := by
-  rw [swap, map_sum₁]
-  apply Fintype.sum_congr
-  intro i
-  rw [swap]
-
-
-/-- The homogenous quadratic equation obtainable from a bilinear function. -/
-@[simps!]
-def toHomogeneousQuad {V : Type} [AddCommMonoid V] [Module ℚ V]
-    (τ : BiLinearSymm V) : HomogeneousQuadratic V where
-  toFun S := τ S S
-  map_smul' a S := by
-    simp only
-    rw [τ.map_smul₁, τ.map_smul₂]
-    ring_nf
-    rfl
-
-lemma toHomogeneousQuad_add {V : Type} [AddCommMonoid V] [Module ℚ V]
-    (τ : BiLinearSymm V) (S T : V) :
-    τ.toHomogeneousQuad (S + T) = τ.toHomogeneousQuad S +
-    τ.toHomogeneousQuad T + 2 * τ S T := by
-  simp [toHomogeneousQuad_apply]
-  rw [τ.map_add₁, τ.map_add₁, τ.swap T S]
-  ring
-
-
-end BiLinearSymm
-
-/-- The structure of a homogeneous cubic equation. -/
-@[simp]
-def HomogeneousCubic (V : Type) [AddCommMonoid V] [Module ℚ V] : Type :=
-  V →ₑ[((fun a => a ^ 3) : ℚ → ℚ)] ℚ
-
-namespace HomogeneousCubic
-
-variable {V : Type} [AddCommMonoid V] [Module ℚ V]
-
-instance instFun : FunLike (HomogeneousCubic V) V ℚ where
-  coe f := f.toFun
-  coe_injective' f g h := by
-    cases f
-    cases g
-    simp_all
-
-lemma map_smul (f : HomogeneousCubic V) (a : ℚ) (S : V) : f (a • S) = a ^ 3 * f S :=
-  f.map_smul' a S
-
-end HomogeneousCubic
-
-/-- The structure of a symmetric trilinear function. -/
-structure TriLinearSymm (V : Type) [AddCommMonoid V] [Module ℚ V] extends
-    V →ₗ[ℚ] V →ₗ[ℚ] V →ₗ[ℚ] ℚ where
-  swap₁' : ∀ S T L, toFun S T L  = toFun T S L
-  swap₂' : ∀ S T L, toFun S T L = toFun S L T
-
-namespace TriLinearSymm
-open BigOperators
-variable {V : Type} [AddCommMonoid V] [Module ℚ V]
-
-instance instFun : FunLike (TriLinearSymm V) V (V →ₗ[ℚ] V →ₗ[ℚ] ℚ )  where
-  coe f := f.toFun
-  coe_injective' f g h := by
-    cases f
-    cases g
-    simp_all
-
-/-- The construction of a symmetric trilinear map from `smul` and `map_add` in the first factor,
-and two swap. -/
-@[simps!]
-def mk₃ (f : V × V × V→ ℚ) (map_smul : ∀ a S T L, f (a • S, T, L) = a * f (S, T, L))
-    (map_add : ∀ S1 S2 T L, f (S1 + S2, T, L) = f (S1, T, L) + f (S2, T, L))
-    (swap₁ : ∀ S T L, f (S, T, L) = f (T, S, L))
-    (swap₂ : ∀ S T L, f (S, T, L) = f (S, L, T)) : TriLinearSymm V where
-  toFun := fun S => (BiLinearSymm.mk₂ (fun T => f (S, T))
-    (by
-      intro a T L
-      simp only
-      rw [swap₁, map_smul, swap₁])
-    (by
-      intro S1 S2 T
-      simp only
-      rw [swap₁, map_add, swap₁, swap₁ S2 S T])
-    (by
-      intro L T
-      simp only
-      rw [swap₂])).toLinearMap
-  map_add' S1 S2 := by
-    apply LinearMap.ext
-    intro T
-    apply LinearMap.ext
-    intro S
-    simp [BiLinearSymm.mk₂, map_add]
-  map_smul' a S := by
-    apply LinearMap.ext
-    intro T
-    apply LinearMap.ext
-    intro L
-    simp [BiLinearSymm.mk₂, map_smul]
-  swap₁' := swap₁
-  swap₂' := swap₂
-
-
-lemma swap₁ (f : TriLinearSymm V) (S T L : V) : f S T L = f T S L :=
-  f.swap₁' S T L
-
-lemma swap₂ (f : TriLinearSymm V) (S T L : V) : f S T L = f S L T :=
-  f.swap₂' S T L
-
-lemma swap₃ (f : TriLinearSymm V) (S T L : V) : f S T L = f L T S := by
-  rw [f.swap₁, f.swap₂, f.swap₁]
-
-lemma map_smul₁ (f : TriLinearSymm V) (a : ℚ) (S T L : V) :
-    f (a • S) T L = a * f S T L := by
-  erw [f.map_smul a S]
-  rfl
-
-lemma map_smul₂ (f : TriLinearSymm V) (S : V) (a : ℚ) (T L : V) :
-    f S (a • T) L = a * f S T L := by
-  rw [f.swap₁, f.map_smul₁, f.swap₁]
-
-lemma map_smul₃ (f : TriLinearSymm V) (S T : V) (a : ℚ) (L : V) :
-    f S T (a • L) = a * f S T L := by
-  rw [f.swap₃, f.map_smul₁, f.swap₃]
-
-lemma map_add₁ (f : TriLinearSymm V) (S1 S2 T L : V) :
-    f (S1 + S2) T L = f S1 T L + f S2 T L := by
-  erw [f.map_add]
-  rfl
-
-lemma map_add₂ (f : TriLinearSymm V) (S T1 T2 L : V) :
-    f S (T1 + T2) L = f S T1 L + f S T2 L := by
-  rw [f.swap₁, f.map_add₁, f.swap₁ S T1, f.swap₁ S T2]
-
-lemma map_add₃ (f : TriLinearSymm V) (S T L1 L2 : V) :
-    f S T (L1 + L2) = f S T L1 + f S T L2 := by
-  rw [f.swap₃, f.map_add₁, f.swap₃, f.swap₃ L2 T S]
-
-/-- Fixing the second and third input vectors, the resulting linear map. -/
-def toLinear₁  (f : TriLinearSymm V) (T L : V) : V →ₗ[ℚ] ℚ where
-  toFun S := f S T L
-  map_add' S1 S2 := by
-    simp only [f.map_add₁]
-  map_smul' a S := by
-    simp only [f.map_smul₁]
-    rfl
-
-lemma toLinear₁_apply (f : TriLinearSymm V) (S T L : V) : f S T L = f.toLinear₁ T L S := rfl
-
-lemma map_sum₁ {n : ℕ} (f : TriLinearSymm V) (S : Fin n → V) (T : V) (L : V) :
-    f (∑ i, S i) T L = ∑ i, f (S i) T L := by
-  rw [f.toLinear₁_apply]
-  rw [map_sum]
-  rfl
-
-lemma map_sum₂ {n : ℕ} (f : TriLinearSymm V) (S : Fin n → V) (T : V) (L : V) :
-    f T (∑ i, S i) L = ∑ i, f T (S i) L := by
-  rw [swap₁, map_sum₁]
-  apply Fintype.sum_congr
-  intro i
-  rw [swap₁]
-
-lemma map_sum₃ {n : ℕ} (f : TriLinearSymm V) (S : Fin n → V) (T : V) (L : V) :
-    f T L (∑ i, S i) = ∑ i, f T L (S i) := by
-  rw [swap₃, map_sum₁]
-  apply Fintype.sum_congr
-  intro i
-  rw [swap₃]
-
-lemma map_sum₁₂₃ {n1 n2 n3 : ℕ} (f : TriLinearSymm V) (S : Fin n1 → V)
-    (T : Fin n2 → V) (L : Fin n3 → V) :
-    f (∑ i, S i) (∑ i, T i) (∑ i, L i) = ∑ i, ∑ k, ∑ l, f (S i) (T k) (L l) := by
-  rw [map_sum₁]
-  apply Fintype.sum_congr
-  intro i
-  rw [map_sum₂]
-  apply Fintype.sum_congr
-  intro i
-  rw [map_sum₃]
-
-
-/-- The homogenous cubic equation obtainable from a symmetric trilinear function. -/
-@[simps!]
-def toCubic {charges : Type} [AddCommMonoid charges] [Module ℚ charges]
-    (τ : TriLinearSymm charges) : HomogeneousCubic charges where
-  toFun S := τ S S S
-  map_smul' a S := by
-    simp only [smul_eq_mul]
-    rw [τ.map_smul₁, τ.map_smul₂, τ.map_smul₃]
-    ring
-
-lemma toCubic_add {charges : Type} [AddCommMonoid charges] [Module ℚ charges]
-    (τ : TriLinearSymm charges) (S T : charges) :
-    τ.toCubic (S + T) = τ.toCubic S +
-    τ.toCubic T + 3 * τ S S T + 3 * τ T T S := by
-  simp only [HomogeneousCubic, toCubic_apply]
-  rw [τ.map_add₁, τ.map_add₂, τ.map_add₂, τ.map_add₃, τ.map_add₃, τ.map_add₃, τ.map_add₃]
-  rw [τ.swap₂ S T S, τ.swap₁ T S S, τ.swap₂ S T S, τ.swap₂ T S T, τ.swap₁ S T T, τ.swap₂ T S T]
-  ring
-
-end TriLinearSymm