nevanlinna/Nevanlinna/complexHarmonic.lean

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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
import Mathlib.Analysis.SpecialFunctions.Complex.LogDeriv
import Mathlib.Data.Complex.Module
import Mathlib.Data.Complex.Order
import Mathlib.Data.Complex.Exponential
import Mathlib.Data.Fin.Tuple.Basic
import Mathlib.Analysis.RCLike.Basic
import Mathlib.Topology.Algebra.InfiniteSum.Module
import Mathlib.Topology.Instances.RealVectorSpace
import Nevanlinna.cauchyRiemann
import Nevanlinna.laplace
import Nevanlinna.partialDeriv
variable {F : Type*} [NormedAddCommGroup F] [NormedSpace F]
variable {F₁ : Type*} [NormedAddCommGroup F₁] [NormedSpace F₁] [CompleteSpace F₁]
variable {G : Type*} [NormedAddCommGroup G] [NormedSpace G]
variable {G₁ : Type*} [NormedAddCommGroup G₁] [NormedSpace G₁] [CompleteSpace G₁]
def Harmonic (f : → F) : Prop :=
(ContDiff 2 f) ∧ (∀ z, Complex.laplace f z = 0)
def HarmonicOn (f : → F) (s : Set ) : Prop :=
(ContDiffOn 2 f s) ∧ (∀ z ∈ s, Complex.laplace f z = 0)
theorem HarmonicOn_of_locally_HarmonicOn {f : → F} {s : Set } (h : ∀ x ∈ s, ∃ (u : Set ), IsOpen u ∧ x ∈ u ∧ HarmonicOn f (s ∩ u)) :
HarmonicOn f s := by
constructor
· apply contDiffOn_of_locally_contDiffOn
intro x xHyp
obtain ⟨u, uHyp⟩ := h x xHyp
use u
exact ⟨ uHyp.1, ⟨uHyp.2.1, uHyp.2.2.1⟩⟩
· intro x xHyp
obtain ⟨u, uHyp⟩ := h x xHyp
exact (uHyp.2.2.2) x ⟨xHyp, uHyp.2.1⟩
theorem harmonic_add_harmonic_is_harmonic {f₁ f₂ : → F} (h₁ : Harmonic f₁) (h₂ : Harmonic f₂) :
Harmonic (f₁ + f₂) := by
constructor
· exact ContDiff.add h₁.1 h₂.1
· rw [laplace_add h₁.1 h₂.1]
simp
intro z
rw [h₁.2 z, h₂.2 z]
simp
theorem harmonic_smul_const_is_harmonic {f : → F} {c : } (h : Harmonic f) :
Harmonic (c • f) := by
constructor
· exact ContDiff.const_smul c h.1
· rw [laplace_smul h.1]
dsimp
intro z
rw [h.2 z]
simp
theorem harmonic_iff_smul_const_is_harmonic {f : → F} {c : } (hc : c ≠ 0) :
Harmonic f ↔ Harmonic (c • f) := by
constructor
· exact harmonic_smul_const_is_harmonic
· nth_rewrite 2 [((eq_inv_smul_iff₀ hc).mpr rfl : f = c⁻¹ • c • f)]
exact fun a => harmonic_smul_const_is_harmonic a
theorem harmonic_comp_CLM_is_harmonic {f : → F₁} {l : F₁ →L[] G} (h : Harmonic f) :
Harmonic (l ∘ f) := by
constructor
· -- Continuous differentiability
apply ContDiff.comp
exact ContinuousLinearMap.contDiff l
exact h.1
· rw [laplace_compContLin]
simp
intro z
rw [h.2 z]
simp
exact ContDiff.restrict_scalars h.1
theorem harmonicOn_comp_CLM_is_harmonicOn {f : → F₁} {s : Set } {l : F₁ →L[] G} (hs : IsOpen s) (h : HarmonicOn f s) :
HarmonicOn (l ∘ f) s := by
constructor
· -- Continuous differentiability
apply ContDiffOn.continuousLinearMap_comp
exact h.1
· -- Vanishing of Laplace
intro z zHyp
rw [laplace_compContLinAt]
simp
rw [h.2 z]
simp
assumption
apply ContDiffOn.contDiffAt h.1
exact IsOpen.mem_nhds hs zHyp
theorem harmonic_iff_comp_CLE_is_harmonic {f : → F₁} {l : F₁ ≃L[] G₁} :
Harmonic f ↔ Harmonic (l ∘ f) := by
constructor
· have : l ∘ f = (l : F₁ →L[] G₁) ∘ f := by rfl
rw [this]
exact harmonic_comp_CLM_is_harmonic
· have : f = (l.symm : G₁ →L[] F₁) ∘ l ∘ f := by
funext z
unfold Function.comp
simp
nth_rewrite 2 [this]
exact harmonic_comp_CLM_is_harmonic
theorem holomorphic_is_harmonic {f : → F₁} (h : Differentiable f) :
Harmonic f := by
-- f is real C²
have f_is_real_C2 : ContDiff 2 f :=
ContDiff.restrict_scalars (Differentiable.contDiff h)
have fI_is_real_differentiable : Differentiable (partialDeriv 1 f) := by
exact (partialDeriv_contDiff f_is_real_C2 1).differentiable (Submonoid.oneLE.proof_2 ℕ∞)
constructor
· -- f is two times real continuously differentiable
exact f_is_real_C2
· -- Laplace of f is zero
unfold Complex.laplace
rw [CauchyRiemann₄ h]
-- This lemma says that partial derivatives commute with complex scalar
-- multiplication. This is a consequence of partialDeriv_compContLin once we
-- note that complex scalar multiplication is continuous -linear.
have : ∀ v, ∀ s : , ∀ g : → F₁, Differentiable g → partialDeriv v (s • g) = s • (partialDeriv v g) := by
intro v s g hg
-- Present scalar multiplication as a continuous -linear map. This is
-- horrible, there must be better ways to do that.
let sMuls : F₁ →L[] F₁ :=
{
toFun := fun x ↦ s • x
map_add' := by exact fun x y => DistribSMul.smul_add s x y
map_smul' := by exact fun m x => (smul_comm ((RingHom.id ) m) s x).symm
cont := continuous_const_smul s
}
-- Bring the goal into a form that is recognized by
-- partialDeriv_compContLin.
have : s • g = sMuls ∘ g := by rfl
rw [this]
rw [partialDeriv_compContLin hg]
rfl
rw [this]
rw [partialDeriv_comm f_is_real_C2 Complex.I 1]
rw [CauchyRiemann₄ h]
rw [this]
rw [← smul_assoc]
simp
-- Subgoals coming from the application of 'this'
-- Differentiable (Real.partialDeriv 1 f)
exact fI_is_real_differentiable
-- Differentiable (Real.partialDeriv 1 f)
exact fI_is_real_differentiable
theorem re_of_holomorphic_is_harmonic {f : } (h : Differentiable f) :
Harmonic (Complex.reCLM ∘ f) := by
apply harmonic_comp_CLM_is_harmonic
exact holomorphic_is_harmonic h
theorem im_of_holomorphic_is_harmonic {f : } (h : Differentiable f) :
Harmonic (Complex.imCLM ∘ f) := by
apply harmonic_comp_CLM_is_harmonic
exact holomorphic_is_harmonic h
theorem antiholomorphic_is_harmonic {f : } (h : Differentiable f) :
Harmonic (Complex.conjCLE ∘ f) := by
apply harmonic_iff_comp_CLE_is_harmonic.1
exact holomorphic_is_harmonic h
theorem log_normSq_of_holomorphicOn_is_harmonicOn
{f : }
{s : Set }
(hs : IsOpen s)
(h₁ : DifferentiableOn f s)
(h₂ : ∀ z ∈ s, f z ≠ 0)
(h₃ : ∀ z ∈ s, f z ∈ Complex.slitPlane) :
HarmonicOn (Real.log ∘ Complex.normSq ∘ f) s := by
suffices hyp : HarmonicOn (⇑Complex.ofRealCLM ∘ Real.log ∘ Complex.normSq ∘ f) s from
(harmonicOn_comp_CLM_is_harmonicOn hs hyp : HarmonicOn (Complex.reCLM ∘ Complex.ofRealCLM ∘ Real.log ∘ Complex.normSq ∘ f) s)
suffices hyp : HarmonicOn (Complex.log ∘ (((starRingEnd ) ∘ f) * f)) s from by
have : Complex.ofRealCLM ∘ Real.log ∘ Complex.normSq ∘ f = Complex.log ∘ (((starRingEnd ) ∘ f) * f) := by
funext z
simp
rw [Complex.ofReal_log (Complex.normSq_nonneg (f z))]
rw [Complex.normSq_eq_conj_mul_self]
rw [this]
exact hyp
-- Suffices to show Harmonic (Complex.log ∘ ⇑(starRingEnd ) ∘ f + Complex.log ∘ f)
-- THIS IS WHERE WE USE h₃
have : ∀ z ∈ s, (Complex.log ∘ (⇑(starRingEnd ) ∘ f * f)) z = (Complex.log ∘ ⇑(starRingEnd ) ∘ f + Complex.log ∘ f) z := by
intro z hz
unfold Function.comp
simp
rw [Complex.log_mul_eq_add_log_iff]
have : Complex.arg ((starRingEnd ) (f z)) = - Complex.arg (f z) := by
rw [Complex.arg_conj]
have : ¬ Complex.arg (f z) = Real.pi := by
exact Complex.slitPlane_arg_ne_pi (h₃ z hz)
simp
tauto
rw [this]
simp
constructor
· exact Real.pi_pos
· exact Real.pi_nonneg
exact (AddEquivClass.map_ne_zero_iff starRingAut).mpr (h₂ z hz)
exact h₂ z hz
rw [this]
apply harmonic_add_harmonic_is_harmonic
have : Complex.log ∘ ⇑(starRingEnd ) ∘ f = Complex.conjCLE ∘ Complex.log ∘ f := by
funext z
unfold Function.comp
rw [Complex.log_conj]
rfl
exact Complex.slitPlane_arg_ne_pi (h₃ z)
rw [this]
rw [← harmonic_iff_comp_CLE_is_harmonic]
repeat
apply holomorphic_is_harmonic
intro z
apply DifferentiableAt.comp
exact Complex.differentiableAt_log (h₃ z)
exact h₁ z
theorem log_normSq_of_holomorphic_is_harmonic
{f : }
(h₁ : Differentiable f)
(h₂ : ∀ z, f z ≠ 0)
(h₃ : ∀ z, f z ∈ Complex.slitPlane) :
Harmonic (Real.log ∘ Complex.normSq ∘ f) := by
suffices hyp : Harmonic (⇑Complex.ofRealCLM ∘ Real.log ∘ Complex.normSq ∘ f) from
(harmonic_comp_CLM_is_harmonic hyp : Harmonic (Complex.reCLM ∘ Complex.ofRealCLM ∘ Real.log ∘ Complex.normSq ∘ f))
suffices hyp : Harmonic (Complex.log ∘ (((starRingEnd ) ∘ f) * f)) from by
have : Complex.ofRealCLM ∘ Real.log ∘ Complex.normSq ∘ f = Complex.log ∘ (((starRingEnd ) ∘ f) * f) := by
funext z
simp
rw [Complex.ofReal_log (Complex.normSq_nonneg (f z))]
rw [Complex.normSq_eq_conj_mul_self]
rw [this]
exact hyp
-- Suffices to show Harmonic (Complex.log ∘ ⇑(starRingEnd ) ∘ f + Complex.log ∘ f)
-- THIS IS WHERE WE USE h₃
have : Complex.log ∘ (⇑(starRingEnd ) ∘ f * f) = Complex.log ∘ ⇑(starRingEnd ) ∘ f + Complex.log ∘ f := by
unfold Function.comp
funext z
simp
rw [Complex.log_mul_eq_add_log_iff]
have : Complex.arg ((starRingEnd ) (f z)) = - Complex.arg (f z) := by
rw [Complex.arg_conj]
have : ¬ Complex.arg (f z) = Real.pi := by
exact Complex.slitPlane_arg_ne_pi (h₃ z)
simp
tauto
rw [this]
simp
constructor
· exact Real.pi_pos
· exact Real.pi_nonneg
exact (AddEquivClass.map_ne_zero_iff starRingAut).mpr (h₂ z)
exact h₂ z
rw [this]
apply harmonic_add_harmonic_is_harmonic
have : Complex.log ∘ ⇑(starRingEnd ) ∘ f = Complex.conjCLE ∘ Complex.log ∘ f := by
funext z
unfold Function.comp
rw [Complex.log_conj]
rfl
exact Complex.slitPlane_arg_ne_pi (h₃ z)
rw [this]
rw [← harmonic_iff_comp_CLE_is_harmonic]
repeat
apply holomorphic_is_harmonic
intro z
apply DifferentiableAt.comp
exact Complex.differentiableAt_log (h₃ z)
exact h₁ z
theorem logabs_of_holomorphic_is_harmonic
{f : }
(h₁ : Differentiable f)
(h₂ : ∀ z, f z ≠ 0)
(h₃ : ∀ z, f z ∈ Complex.slitPlane) :
Harmonic (fun z ↦ Real.log ‖f z‖) := by
-- Suffices: Harmonic (2⁻¹ • Real.log ∘ ⇑Complex.normSq ∘ f)
have : (fun z ↦ Real.log ‖f z‖) = (2 : )⁻¹ • (Real.log ∘ Complex.normSq ∘ f) := by
funext z
simp
unfold Complex.abs
simp
rw [Real.log_sqrt]
rw [div_eq_inv_mul (Real.log (Complex.normSq (f z))) 2]
exact Complex.normSq_nonneg (f z)
rw [this]
-- Suffices: Harmonic (Real.log ∘ ⇑Complex.normSq ∘ f)
apply (harmonic_iff_smul_const_is_harmonic (inv_ne_zero two_ne_zero)).1
exact log_normSq_of_holomorphic_is_harmonic h₁ h₂ h₃