Clean up

2024-05-07 13:45:35 +02:00 · 2024-05-07 13:45:35 +02:00 · b5cf426b7f
parent b26256d84e
commit b5cf426b7f
4 changed files with 0 additions and 534 deletions
--- a/Nevanlinna/comparingDerivatives.lean
+++ b/Nevanlinna/comparingDerivatives.lean
@ -1,17 +0,0 @@
 import Mathlib.Data.Fin.Tuple.Basic
 import Mathlib.Analysis.Complex.Basic
 import Mathlib.Analysis.Complex.TaylorSeries
 import Mathlib.Analysis.Calculus.LineDeriv.Basic
 import Mathlib.Analysis.Calculus.ContDiff.Defs
 import Mathlib.Analysis.Calculus.FDeriv.Basic
 import Mathlib.Analysis.Calculus.FDeriv.Symmetric
 lemma l₁ (f : ℝ × ℝ → ℝ) (h : ContDiff ℝ 2 f) :
  ∀ z a b : ℝ × ℝ, (fderiv ℝ (fun w => fderiv ℝ f w) z) a b = iteratedFDeriv ℝ 2 f z ![a, b] := by
  sorry
 lemma l₂ (f : ℝ × ℝ → ℝ) (h : ContDiff ℝ 2 f) :
  ∀ z a b : ℝ × ℝ, (fderiv ℝ (fun w => fderiv ℝ f w) z) a b = (fderiv ℝ (fun w ↦ (fderiv ℝ f w) a) z) b := by
  sorry
--- a/Nevanlinna/harmonic.lean
+++ b/Nevanlinna/harmonic.lean
@ -1,445 +0,0 @@
 import Mathlib.Analysis.Complex.Basic
 import Mathlib.Analysis.Calculus.LineDeriv.Basic
 import Mathlib.Analysis.SpecialFunctions.ExpDeriv
 import Mathlib.Analysis.SpecialFunctions.Trigonometric.Deriv
 import Mathlib.Analysis.Calculus.ContDiff.Basic
 import Mathlib.Analysis.Calculus.Deriv.Linear
 import Mathlib.Analysis.Complex.Conformal
 import Mathlib.Analysis.Calculus.Conformal.NormedSpace
 import Mathlib.Analysis.Complex.RealDeriv
 /RealDeriv.lean
 -- Harmonic functions on the plane
 variable {f : ℂ → ℂ} {e' : ℂ} {z : ℝ} {h : HasDerivAt f e' z}
 example : 1 = 0 := by
  let XX := HasDerivAt.real_of_complex h
  sorry
 noncomputable def lax (f : ℂ → ℝ) (z : ℂ) : ℝ :=
  iteratedFDeriv ℝ 1 f z ![Complex.I]
 example : lax (fun z ↦ z.re) = fun z ↦ 1 := by
  unfold lax
  simp
  funext x
  let XX := HasDerivAt.real_of_complex 
  sorry
 noncomputable def laplace (f : ℂ → ℝ) (z : ℂ) : ℝ :=
  iteratedFDeriv ℝ 2 f z ![1, 1] + iteratedFDeriv ℝ 2 f z ![Complex.I, Complex.I]
 example : laplace (fun z ↦ z.re) = fun z ↦ 0 := by
  unfold laplace
  rw [iteratedFDeriv_succ_eq_comp_left]
  rw [iteratedFDeriv_succ_eq_comp_left]
  rw [iteratedFDeriv_zero_eq_comp]
  simp
  have : Fin.tail ![Complex.I, Complex.I] = ![Complex.I] := by
    rfl
  rw [this]
  rw [deriv_comp]
  simp
  simp
  conv =>
    lhs
    intro x
    arg 1
    intro t
    rw [deriv_add] <;> tactic => try fun_prop
  simp
  rfl
 example : laplace' (fun z ↦ (z*z).re) = fun z ↦ 0 := by
  unfold laplace' lineDeriv  
  simp
  conv =>
    lhs
    intro x
    simp
    arg 1
    arg 1
    intro t
    rw [deriv_sub] <;> tactic => try fun_prop
    simp
    rw [deriv_mul] <;> tactic => try fun_prop
    simp
    rw [deriv_add] <;> tactic => try fun_prop
    simp
  conv =>
    lhs
    intro x
    arg 1
    rw [deriv_add] <;> tactic => try fun_prop
    rw [deriv_add] <;> tactic => try fun_prop
    simp
    rw [one_add_one_eq_two]
  conv =>
    lhs
    intro x
    arg 2
    conv =>
      arg 1
      intro t
      rw [deriv_sub] <;> tactic => try fun_prop
      rw [deriv_mul] <;> tactic => try fun_prop
      simp
      rw [deriv_mul] <;> tactic => try fun_prop
      simp
      rw [deriv_add] <;> tactic => try fun_prop
      rw [deriv_add] <;> tactic => try fun_prop
      simp
  conv =>
    lhs
    intro x
    rw [deriv_add] <;> tactic => try fun_prop
    rw [deriv_add] <;> tactic => try fun_prop
    simp
  group
 open Complex ContinuousLinearMap
 open scoped ComplexConjugate
 variable {z : ℂ} {f : ℂ → ℂ}
 #check deriv_comp_const_add
 theorem DifferentiableAt_conformalAt (h : DifferentiableAt ℂ f z) :
    ConformalAt f z := by
  let XX := (h.hasFDerivAt.restrictScalars ℝ).fderiv
  let f₁ := fun x ↦ lineDeriv ℝ f x 1
  let f₂ := fun x ↦ lineDeriv ℝ f x Complex.I
  have t₁ : deriv (fun (t : ℂ) => f (z + t)) 0 = deriv f z := by
    rw [deriv_comp_const_add]
    simp
    simp
    exact h
  have t'₁ : deriv (fun (t : ℝ) => f (z + ↑t)) 0 = deriv f z := by
    sorry
  have : f₁ z = deriv f z := by
    dsimp [f₁]
    unfold lineDeriv
    simp
    exact t'₁
  have : f₂ z = deriv f z := by
    dsimp [f₂]
    unfold lineDeriv
    simp
    exact t'₁
  /-
  simp at f₂
  rw [conformalAt_iff_isConformalMap_fderiv, (h.hasFDerivAt.restrictScalars ℝ).fderiv]
  apply isConformalMap_complex_linear
  simpa only [Ne, ext_ring_iff]
  -/
 example : laplace' (fun z ↦ (Complex.exp z).re) = fun z ↦ 0 := by
  let f := fun z ↦ (Complex.exp z).re
  let f₁ := fun x ↦ lineDeriv ℝ f x 1
  let fz := fun x ↦ deriv f
 example : laplace' (fun z ↦ (Complex.exp z).re) = fun z ↦ 0 := by
  unfold laplace' lineDeriv  
  simp
  conv =>
    lhs
    arg 1
    intro x
    arg 1
    intro t
    arg 1
    intro t₁
    rw [Complex.exp_add]
    rw [Complex.exp_add]
  conv =>
    lhs
    arg 1
    intro x
    arg 1
    intro t
    simp
    conv =>
      rhs
      arg 1
      intro x₁
      rw [Complex.exp_re]
      simp
    rw [Real.deriv_exp]
    simp
  conv =>
    lhs
    arg 1
    intro x
    simp
    rhs
    arg 1
    intro x
    rw [Complex.exp_re]
  conv =>
    lhs
    lhs
    intro x
    rhs
    lhs
    intro x₁
    simp
  simp
  conv =>
    lhs
    rhs
    intro x
    lhs
    intro t
    arg 1
    intro t₁
    rw [Complex.exp_add]
    rw [Complex.exp_add]
    simp
    rw [Complex.exp_re]
    rw [Complex.exp_im]
    simp
  conv =>
    lhs
    rhs
    intro x
    lhs
    intro t
    simp
    rw [deriv_sub] <;> tactic => try fun_prop
    rw [deriv_mul] <;> tactic => try fun_prop
    rw [deriv_mul] <;> tactic => try fun_prop
    simp
    -- oops
        conv =>
          lhs
          rw [Complex.exp_add]
        rw [deriv_mul] <;> tactic => try fun_prop
  sorry
  rw [deriv_add] <;> tactic => try fun_prop
  sorry
 noncomputable def laplace : (ℂ → ℝ) → (ℂ → ℝ) := by
  intro f
  let F : ℝ × ℝ → ℝ := fun x ↦ f (x.1 + x.2 * Complex.I)
  let e₁ : ℝ × ℝ := ⟨1, 0⟩ 
  let e₂ : ℝ × ℝ := ⟨0, 1⟩ 
  let F₁ := fun x ↦ lineDeriv ℝ F x e₁
  let F₁₁ := fun x ↦ lineDeriv ℝ F₁ x e₁
  let F₂ := fun x ↦ lineDeriv ℝ F x e₂
  let F₂₂ := fun x ↦ lineDeriv ℝ F₂ x e₂
  exact fun x ↦ F₁₁ ⟨x.1, x.2⟩ + F₂₂ ⟨x.1, x.2⟩
 example : ∀ z₀ : ℂ, laplace (fun z ↦ (z*z).re) z₀ = 0 := by
  intro z₀
  unfold laplace
  dsimp [lineDeriv]
  simp
  conv =>
    lhs
    lhs
    arg 1
    intro t
    rw [deriv_sub] <;> tactic => try fun_prop
    rw [deriv_mul] <;> tactic => try fun_prop
    rw [deriv_const_add]
    simp
    ring_nf
  conv =>
    lhs
    rhs
    arg 1
    intro t
    rw [deriv_sub] <;> tactic => try fun_prop
    rw [deriv_const]
    rw [deriv_mul] <;> tactic => try fun_prop
    rw [deriv_const_add]
    simp
    ring_nf
  rw [deriv_const_add, deriv_sub] <;> try fun_prop
  simp
 example : ∀ z₀ : ℂ, laplace (fun z ↦ (Complex.exp z).re) z₀ = 0 := by
  intro z₀ 
  unfold laplace
  dsimp [lineDeriv]
  simp
  sorry
 example : deriv (fun (t : ℝ) ↦ 2 + t) = fun (t : ℝ) ↦ 1 := by
  -- in my experience with the library, more results are stated about
  -- `HasDerivAt` than about equality of `deriv`
  rw [deriv_eq] 
  intro x
  -- I guessed the name `HasDerivAt.add`, which didn't work, but the
  -- autocomplete dropdown showed `add_const` and `const_add` too
  apply HasDerivAt.const_add 
  -- I assumed this was in the library, and `apply?` found it
  exact hasDerivAt_id' x 
 example : laplace (fun z ↦ (Complex.exp z).re) = 0 := by
  have : (fun z => (Complex.exp z).re) = (fun z => Real.exp z.re * Real.cos z.im) := by
    funext z
    rw [Complex.exp_re]
  rw [this]
  unfold laplace
  simp
  have F₁ : (fun (x : ℝ × ℝ) => lineDeriv ℝ (fun (t : ℝ × ℝ) => Real.exp t.1 * Real.cos t.2) x ⟨1, 0⟩) = ((fun (x : ℝ × ℝ) => (Real.exp x.1 * Real.cos x.2))) := by
    funext x    
    dsimp [lineDeriv]        
    simp
    left
    have t₁ : (fun x_1 => Real.exp (x.1 + x_1)) = (fun x_1 => Real.exp x.1 * Real.exp x_1) := by
      funext t
      exact Real.exp_add x.1 t
    rw [t₁]
    simp
  have F₂ : (fun (x : ℝ × ℝ) => lineDeriv ℝ (fun (t : ℝ × ℝ) => Real.exp t.1 * Real.sin t.2) x ⟨0, 1⟩) = ((fun (x : ℝ × ℝ) => (Real.exp x.1 * Real.cos x.2))) := by
    funext x    
    dsimp [lineDeriv]
    simp 
    have t₁ : (fun t => Real.sin (x.2 + t)) = (Real.sin ∘ (fun t => x.2 + t)) := by
      rfl
    rw [t₁]
    rw [deriv.comp]
    simp
    have : deriv (fun (t : ℝ) ↦ 2 + t) = fun (t : ℝ) ↦ 1 := by
      simp [deriv.add]            
      sorry
    rw [this]
    simp
    · exact Real.differentiableAt_sin
    · -- DifferentiableAt ℝ (fun t => x.2 + t) 0
      sorry
  rw [this]
  sorry
    have : deriv (fun x_1 => Real.exp (x_1 + x_1)) 0 = 2 := by
      simp
      group
    rw [this]
    simp
    have : deriv (fun t => Real.cos (x.2 + t * y.2)) = (fun t => -y.2 * Real.sin (x.2 + t * y.2)) := by
      funext t₀
      have t₁ : (fun t => Real.cos (x.2 + t * y.2)) = (Real.cos ∘ (fun t => x.2 + t * y.2)) := by
        rfl
      rw [t₁]
      rw [deriv.comp]
      simp
      · group
      · exact Real.differentiableAt_cos
      · simp
    simp
    simp
    sorry
  let XX := fderiv ℝ (fun (x : ℝ × ℝ) => Real.exp x.1 * Real.cos x.2)
  simp at XX
  have : fderiv ℝ fun x => Real.exp x.1 * Real.cos x.2 = 0 := by
    sorry
  funext z
  simp
  funext 
  let ZZ := Complex.exp_re z
  sorry
--- a/Nevanlinna/logabs.lean
+++ b/Nevanlinna/logabs.lean
@ -1,56 +0,0 @@
 import Mathlib.Analysis.Complex.CauchyIntegral
 open ComplexConjugate
 /- logAbs of a product is sum of logAbs of factors -/
 lemma logAbs_mul : ∀ z₁ z₂ : ℂ, z₁ ≠ 0 → z₂ ≠ 0 → Real.log (Complex.abs (z₁ * z₂)) = Real.log (Complex.abs z₁) + Real.log (Complex.abs z₂) := by
  intro z₁ z₂ z₁Hyp z₂Hyp
  rw [Complex.instNormedFieldComplex.proof_2 z₁ z₂]
  exact Real.log_mul ((AbsoluteValue.ne_zero_iff Complex.abs).mpr z₁Hyp) ((AbsoluteValue.ne_zero_iff Complex.abs).mpr z₂Hyp)
 lemma absAndProd : ∀ z : ℂ, Complex.abs z = Real.sqrt ( (z * conj z).re ) := by
  intro z
  simp
  rfl
 #check Complex.log_mul_eq_add_log_iff
 #check Complex.arg_eq_pi_iff
 lemma logAbsXX : ∀ z : ℂ, z ≠ 0 → Real.log (Complex.abs z) = (1 / 2) * Complex.log z + (1 / 2) * Complex.log (conj z) := by
  intro z z₁Hyp
  by_cases argHyp : Complex.arg z = Real.pi
  -- Show pos: Complex.arg z = Real.pi
  have : conj z = z := by
    apply Complex.conj_eq_iff_im.2
    rw [Complex.arg_eq_pi_iff] at argHyp
    exact argHyp.right
  rw [this]
  sorry
  -- Show pos: Complex.arg z ≠ Real.pi
  have t₁ : Complex.abs z = Real.sqrt (Complex.normSq z) := by
    exact rfl
  rw [t₁]
  have t₂ : 0 ≤ Complex.normSq z := by
    exact Complex.normSq_nonneg z
  rw [ Real.log_sqrt t₂ ]
  have t₃ : Real.log (Complex.normSq z) = Complex.log (Complex.normSq z) := by
    apply Complex.ofReal_log
    exact t₂
  simp
  rw [t₃]
  rw [Complex.normSq_eq_conj_mul_self]
  have t₄ : conj z ≠ 0 := by
    exact (AddEquivClass.map_ne_zero_iff starRingAut).mpr z₁Hyp
  let XX := Complex.log_mul_eq_add_log_iff this z₁Hyp
  sorry
--- a/Nevanlinna/realHarmonic.lean
+++ b/Nevanlinna/realHarmonic.lean
@ -1,16 +0,0 @@
 import Mathlib.Analysis.Calculus.LineDeriv.Basic
 import Mathlib.Analysis.Calculus.ContDiff.Defs
 noncomputable def Real.laplace : (ℝ × ℝ → ℝ) → (ℝ × ℝ → ℝ) := by
  intro f
  let f₁ := fun x ↦ lineDeriv ℝ f x ⟨1,0⟩
  let f₁₁ := fun x ↦ lineDeriv ℝ f₁ x ⟨1,0⟩
  let f₂ := fun x ↦ lineDeriv ℝ f x ⟨0,1⟩
  let f₂₂ := fun x ↦ lineDeriv ℝ f₂ x ⟨0,1⟩
  exact f₁₁ + f₂₂
 def Harmonic (f : ℝ × ℝ → ℝ) : Prop :=
  (ContDiff ℝ 2 f) ∧ (∀ x, Real.laplace f x = 0)