179 lines
6.7 KiB
Text
179 lines
6.7 KiB
Text
/-
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Copyright (c) 2024 Joseph Tooby-Smith. All rights reserved.
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Released under Apache 2.0 license as described in the file LICENSE.
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Authors: Joseph Tooby-Smith
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-/
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import HepLean.SpaceTime.LorentzGroup.Proper
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import Mathlib.Topology.Constructions
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import HepLean.SpaceTime.LorentzVector.NormOne
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/-!
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# Boosts
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This file defines those Lorentz which are boosts.
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We first define generalised boosts, which are restricted lorentz transformations taking
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a four velocity `u` to a four velocity `v`.
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A boost is the special case of a generalised boost when `u = stdBasis 0`.
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## References
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- The main argument follows: Guillem Cobos, The Lorentz Group, 2015:
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https://diposit.ub.edu/dspace/bitstream/2445/68763/2/memoria.pdf
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-/
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/-! TODO: Show that generalised boosts are in the restricted Lorentz group. -/
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noncomputable section
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namespace LorentzGroup
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open NormOneLorentzVector
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open minkowskiMetric
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variable {d : ℕ}
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/-- An auxillary linear map used in the definition of a generalised boost. -/
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def genBoostAux₁ (u v : FuturePointing d) : LorentzVector d →ₗ[ℝ] LorentzVector d where
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toFun x := (2 * ⟪x, u⟫ₘ) • v.1.1
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map_add' x y := by
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simp only [map_add, LinearMap.add_apply]
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rw [mul_add, add_smul]
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map_smul' c x := by
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simp only [LinearMapClass.map_smul, LinearMap.smul_apply, smul_eq_mul,
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RingHom.id_apply]
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rw [← mul_assoc, mul_comm 2 c, mul_assoc, mul_smul]
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/-- An auxillary linear map used in the definition of a genearlised boost. -/
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def genBoostAux₂ (u v : FuturePointing d) : LorentzVector d →ₗ[ℝ] LorentzVector d where
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toFun x := - (⟪x, u.1.1 + v⟫ₘ / (1 + ⟪u.1.1, v⟫ₘ)) • (u.1.1 + v)
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map_add' x y := by
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simp only
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rw [← add_smul]
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apply congrFun
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apply congrArg
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field_simp
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apply congrFun
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apply congrArg
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ring
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map_smul' c x := by
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simp only
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rw [map_smul]
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rw [show (c • minkowskiMetric x) (↑u + ↑v) = c * minkowskiMetric x (u+v) from rfl]
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rw [mul_div_assoc, neg_mul_eq_mul_neg, smul_smul]
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rfl
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/-- An generalised boost. This is a Lorentz transformation which takes the four velocity `u`
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to `v`. -/
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def genBoost (u v : FuturePointing d) : LorentzVector d →ₗ[ℝ] LorentzVector d :=
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LinearMap.id + genBoostAux₁ u v + genBoostAux₂ u v
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namespace genBoost
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/--
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This lemma states that for a given four-velocity `u`, the general boost
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transformation `genBoost u u` is equal to the identity linear map `LinearMap.id`.
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-/
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lemma self (u : FuturePointing d) : genBoost u u = LinearMap.id := by
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ext x
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simp [genBoost]
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rw [add_assoc]
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rw [@add_right_eq_self]
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rw [@add_eq_zero_iff_eq_neg]
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rw [genBoostAux₁, genBoostAux₂]
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simp only [LinearMap.coe_mk, AddHom.coe_mk, map_add, smul_add, neg_smul, neg_add_rev, neg_neg]
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rw [← add_smul]
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apply congr
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apply congrArg
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repeat rw [u.1.2]
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field_simp
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ring
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rfl
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/-- A generalised boost as a matrix. -/
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def toMatrix (u v : FuturePointing d) : Matrix (Fin 1 ⊕ Fin d) (Fin 1 ⊕ Fin d) ℝ :=
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LinearMap.toMatrix LorentzVector.stdBasis LorentzVector.stdBasis (genBoost u v)
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lemma toMatrix_mulVec (u v : FuturePointing d) (x : LorentzVector d) :
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(toMatrix u v).mulVec x = genBoost u v x :=
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LinearMap.toMatrix_mulVec_repr LorentzVector.stdBasis LorentzVector.stdBasis (genBoost u v) x
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open minkowskiMatrix LorentzVector in
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@[simp]
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lemma toMatrix_apply (u v : FuturePointing d) (μ ν : Fin 1 ⊕ Fin d) :
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(toMatrix u v) μ ν = η μ μ * (⟪e μ, e ν⟫ₘ + 2 * ⟪e ν, u⟫ₘ * ⟪e μ, v⟫ₘ
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- ⟪e μ, u + v⟫ₘ * ⟪e ν, u + v⟫ₘ / (1 + ⟪u, v.1.1⟫ₘ)) := by
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rw [matrix_apply_stdBasis (toMatrix u v) μ ν, toMatrix_mulVec]
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simp only [genBoost, genBoostAux₁, genBoostAux₂, map_add, smul_add, neg_smul, LinearMap.add_apply,
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LinearMap.id_apply, LinearMap.coe_mk, AddHom.coe_mk, basis_left, map_smul, smul_eq_mul, map_neg,
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mul_eq_mul_left_iff]
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have h1 := FuturePointing.one_add_metric_non_zero u v
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field_simp
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ring_nf
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simp
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open minkowskiMatrix LorentzVector in
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lemma toMatrix_continuous (u : FuturePointing d) : Continuous (toMatrix u) := by
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refine continuous_matrix ?_
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intro i j
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simp only [toMatrix_apply]
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refine Continuous.comp' (continuous_mul_left (η i i)) ?hf
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refine Continuous.sub ?_ ?_
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refine Continuous.comp' (continuous_add_left ⟪e i, e j⟫ₘ) ?_
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refine Continuous.comp' (continuous_mul_left (2 * ⟪e j, u⟫ₘ)) ?_
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exact FuturePointing.metric_continuous _
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refine Continuous.mul ?_ ?_
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refine Continuous.mul ?_ ?_
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simp only [(minkowskiMetric _).map_add]
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refine Continuous.comp' ?_ ?_
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exact continuous_add_left ((minkowskiMetric (stdBasis i)) ↑u)
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exact FuturePointing.metric_continuous _
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simp only [(minkowskiMetric _).map_add]
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refine Continuous.comp' ?_ ?_
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exact continuous_add_left _
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exact FuturePointing.metric_continuous _
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refine Continuous.inv₀ ?_ ?_
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refine Continuous.comp' (continuous_add_left 1) ?_
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exact FuturePointing.metric_continuous _
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exact fun x => FuturePointing.one_add_metric_non_zero u x
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lemma toMatrix_in_lorentzGroup (u v : FuturePointing d) : (toMatrix u v) ∈ LorentzGroup d:= by
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intro x y
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rw [toMatrix_mulVec, toMatrix_mulVec, genBoost, genBoostAux₁, genBoostAux₂]
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have h1 : (1 + (minkowskiMetric ↑u) ↑v.1.1) ≠ 0 := FuturePointing.one_add_metric_non_zero u v
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simp only [map_add, smul_add, neg_smul, LinearMap.add_apply, LinearMap.id_coe,
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id_eq, LinearMap.coe_mk, AddHom.coe_mk, LinearMapClass.map_smul, map_neg, LinearMap.smul_apply,
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smul_eq_mul, LinearMap.neg_apply]
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field_simp
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rw [u.1.2, v.1.2, minkowskiMetric.symm v.1.1 u, minkowskiMetric.symm u y,
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minkowskiMetric.symm v y]
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ring
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/-- A generalised boost as an element of the Lorentz Group. -/
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def toLorentz (u v : FuturePointing d) : LorentzGroup d :=
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⟨toMatrix u v, toMatrix_in_lorentzGroup u v⟩
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lemma toLorentz_continuous (u : FuturePointing d) : Continuous (toLorentz u) := by
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refine Continuous.subtype_mk ?_ (fun x => toMatrix_in_lorentzGroup u x)
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exact toMatrix_continuous u
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lemma toLorentz_joined_to_1 (u v : FuturePointing d) : Joined 1 (toLorentz u v) := by
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obtain ⟨f, _⟩ := FuturePointing.isPathConnected.joinedIn u trivial v trivial
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use ContinuousMap.comp ⟨toLorentz u, toLorentz_continuous u⟩ f
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· simp only [ContinuousMap.toFun_eq_coe, ContinuousMap.comp_apply, ContinuousMap.coe_coe,
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Path.source, ContinuousMap.coe_mk]
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rw [@Subtype.ext_iff, toLorentz]
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simp [toMatrix, self u]
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· simp
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lemma toLorentz_in_connected_component_1 (u v : FuturePointing d) :
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toLorentz u v ∈ connectedComponent 1 :=
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pathComponent_subset_component _ (toLorentz_joined_to_1 u v)
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lemma isProper (u v : FuturePointing d) : IsProper (toLorentz u v) :=
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(isProper_on_connected_component (toLorentz_in_connected_component_1 u v)).mp id_IsProper
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end genBoost
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end LorentzGroup
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end
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