From 03548bc6da6b2994e50d1bfcbc154f6adf007313 Mon Sep 17 00:00:00 2001 From: Stefan Kebekus Date: Fri, 2 Aug 2024 11:22:41 +0200 Subject: [PATCH] working --- Nevanlinna/holomorphic_primitive2.lean | 61 +++++++++++++++++++++++--- 1 file changed, 56 insertions(+), 5 deletions(-) diff --git a/Nevanlinna/holomorphic_primitive2.lean b/Nevanlinna/holomorphic_primitive2.lean index 4114ccb..d3991ff 100644 --- a/Nevanlinna/holomorphic_primitive2.lean +++ b/Nevanlinna/holomorphic_primitive2.lean @@ -337,9 +337,59 @@ theorem primitive_additivity (R : ℝ) (hf : DifferentiableOn ℂ f (Metric.ball z₀ R)) (z₁ : ℂ) - (hz₁ : z₁ ∈ Metric.ball z₀ R) : - ∀ z ∈ Metric.ball z₁ (R - ‖z₁‖), (primitive z₀ f z) - (primitive z₁ f z) - (primitive z₀ f z₁) = 0 := by - intro z _ + (hz₁ : z₁ ∈ Metric.ball z₀ R) + : + ∀ z ∈ Metric.ball z₁ (R - dist z₁ z₀), (primitive z₀ f z) - (primitive z₁ f z) - (primitive z₀ f z₁) = 0 := by + intro z hz + + have H : (Set.uIcc z₁.re z.re ×ℂ Set.uIcc z₀.im z₁.im) ⊆ Metric.ball z₀ R := by + intro x hx + + have a₀ : x.re ∈ Set.uIcc z₁.re z.re := by exact (Complex.mem_reProdIm.1 hx).1 + have a₁ : x.im ∈ Set.uIcc z₀.im z₁.im := by exact (Complex.mem_reProdIm.1 hx).2 + + + have A₀ : dist x.re z₀.re ≤ dist x.re z₁.re + dist z₁.re z₀.re := by apply dist_triangle + + have A₁ : dist x.im z₀.im ≤ dist z₁.im z₀.im := by + apply Real.dist_right_le_of_mem_uIcc + rwa [Set.uIcc_comm] + + have A₂ : dist x.re z₁.re ≤ dist z.re z₁.re := by + apply Real.dist_right_le_of_mem_uIcc + rwa [Set.uIcc_comm] + + have A₃ : dist z.re z₁.re < R - dist z₁ z₀ := by + have : ∀ x₀ x₁ : ℂ, dist x₀.re x₁.re ≤ dist x₀ x₁ := by + intro x₀ x₁ + rw [Complex.dist_eq_re_im, Real.dist_eq] + apply Real.le_sqrt_of_sq_le + simp + exact sq_nonneg (x₀.im - x₁.im) + calc dist z.re z₁.re + _ ≤ dist z z₁ := by apply this z z₁ + _ < R - dist z₁ z₀ := by exact hz + + simp + + have B₀ : dist x z₀ ≤ dist x ⟨z₁.re, x.im⟩ + dist ⟨z₁.re, x.im⟩ z₀ := by apply dist_triangle + + have B₁ : dist ⟨z₁.re, x.im⟩ z₀ ≤ dist z₁ z₀ := by + rw [Complex.dist_eq_re_im] + rw [Complex.dist_eq_re_im] + simp + apply Real.sqrt_le_sqrt + simp + exact sq_le_sq.mpr A₁ + + calc dist x z₀ + _ ≤ dist x ⟨z₁.re, x.im⟩ + dist ⟨z₁.re, x.im⟩ z₀ := by apply dist_triangle + _ = dist x.re z₁.re + dist ⟨z₁.re, x.im⟩ z₀ := by rw [Complex.dist_of_im_eq]; rfl + _ ≤ dist z.re z₁.re + dist ⟨z₁.re, x.im⟩ z₀ := by apply add_le_add_right A₂ + _ < (R - dist z₁ z₀) + dist ⟨z₁.re, x.im⟩ z₀ := by apply add_lt_add_right A₃ + _ ≤ (R - dist z₁ z₀) + dist z₁ z₀ := by exact (add_le_add_iff_left (R - dist z₁ z₀)).mpr B₁ + _ = R := by exact sub_add_cancel R (dist z₁ z₀) + unfold primitive have : (∫ (x : ℝ) in z₀.re..z.re, f { re := x, im := z₀.im }) = (∫ (x : ℝ) in z₀.re..z₁.re, f { re := x, im := z₀.im }) + (∫ (x : ℝ) in z₁.re..z.re, f { re := x, im := z₀.im }) := by @@ -363,9 +413,10 @@ theorem primitive_additivity apply DifferentiableOn.mono hf intro x hx simp - + let A₀ : dist x.re z₀.re ≤ dist x.re z₁.re + dist z₁.re z₀.re := by apply dist_triangle - + let A₁ : dist x.im z₀.im ≤ dist z₁.im z₀.im := by sorry +