lemma
proved
coordRay_apply
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IndisputableMonolith.Relativity.Calculus.Derivatives on GitHub at line 23.
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20def coordRay (x : Fin 4 → ℝ) (μ : Fin 4) (t : ℝ) : Fin 4 → ℝ :=
21 fun ν => x ν + t * basisVec μ ν
22
23@[simp] lemma coordRay_apply (x : Fin 4 → ℝ) (μ : Fin 4) (t : ℝ) (ν : Fin 4) :
24 coordRay x μ t ν = x ν + t * basisVec μ ν := rfl
25
26@[simp] lemma coordRay_zero (x : Fin 4 → ℝ) (μ : Fin 4) : coordRay x μ 0 = x := by
27 funext ν; simp [coordRay]
28
29@[simp] lemma coordRay_coordRay (x : Fin 4 → ℝ) (μ : Fin 4) (s t : ℝ) :
30 coordRay (coordRay x μ s) μ t = coordRay x μ (s + t) := by
31 funext ν; simp [coordRay]; ring
32
33/-- Directional derivative `∂_μ f(x)` via real derivative along the coordinate ray. -/
34noncomputable def partialDeriv_v2 (f : (Fin 4 → ℝ) → ℝ) (μ : Fin 4)
35 (x : Fin 4 → ℝ) : ℝ :=
36 deriv (fun t => f (coordRay x μ t)) 0
37
38/-- The derivative of a constant function is zero. -/
39lemma partialDeriv_v2_const {f : (Fin 4 → ℝ) → ℝ} {c : ℝ} (h : ∀ y, f y = c) (μ : Fin 4) (x : Fin 4 → ℝ) :
40 partialDeriv_v2 f μ x = 0 := by
41 unfold partialDeriv_v2
42 have h_const : (fun t => f (coordRay x μ t)) = (fun _ => c) := by
43 funext t
44 rw [h]
45 rw [h_const]
46 exact deriv_const (0 : ℝ) c
47
48/-- Second derivative `∂_μ∂_ν f(x)` as iterated directional derivatives. -/
49noncomputable def secondDeriv (f : (Fin 4 → ℝ) → ℝ) (μ ν : Fin 4)
50 (x : Fin 4 → ℝ) : ℝ :=
51 deriv (fun s => partialDeriv_v2 f μ (coordRay x ν s)) 0
52
53/-- Laplacian `∇² = Σ_{i=1}^3 ∂²/∂xᵢ²`. -/