235 lines
8.4 KiB
Plaintext
235 lines
8.4 KiB
Plaintext
import Mathlib.Data.Fin.Tuple.Basic
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import Mathlib.Analysis.Complex.Basic
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import Mathlib.Analysis.Complex.TaylorSeries
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import Mathlib.Analysis.Calculus.LineDeriv.Basic
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import Mathlib.Analysis.Calculus.ContDiff.Defs
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import Mathlib.Analysis.Calculus.FDeriv.Basic
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import Mathlib.Analysis.Calculus.FDeriv.Symmetric
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import Mathlib.Data.Complex.Module
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import Mathlib.Data.Complex.Order
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import Mathlib.Data.Complex.Exponential
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import Mathlib.Analysis.RCLike.Basic
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import Mathlib.Order.Filter.Basic
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import Mathlib.Topology.Algebra.InfiniteSum.Module
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import Mathlib.Topology.Basic
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import Mathlib.Topology.Instances.RealVectorSpace
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import Nevanlinna.cauchyRiemann
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import Nevanlinna.partialDeriv
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variable {F : Type*} [NormedAddCommGroup F] [NormedSpace ℝ F]
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variable {G : Type*} [NormedAddCommGroup G] [NormedSpace ℝ G]
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noncomputable def Complex.laplace (f : ℂ → F) : ℂ → F :=
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partialDeriv ℝ 1 (partialDeriv ℝ 1 f) + partialDeriv ℝ Complex.I (partialDeriv ℝ Complex.I f)
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notation "Δ" => Complex.laplace
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theorem laplace_eventuallyEq {f₁ f₂ : ℂ → F} {x : ℂ} (h : f₁ =ᶠ[nhds x] f₂) : Δ f₁ x = Δ f₂ x := by
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unfold Complex.laplace
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simp
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rw [partialDeriv_eventuallyEq ℝ (partialDeriv_eventuallyEq' ℝ h 1) 1]
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rw [partialDeriv_eventuallyEq ℝ (partialDeriv_eventuallyEq' ℝ h Complex.I) Complex.I]
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theorem laplace_add
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{f₁ f₂ : ℂ → F}
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(h₁ : ContDiff ℝ 2 f₁)
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(h₂ : ContDiff ℝ 2 f₂) :
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Δ (f₁ + f₂) = (Δ f₁) + (Δ f₂) := by
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unfold Complex.laplace
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rw [partialDeriv_add₂]
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rw [partialDeriv_add₂]
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rw [partialDeriv_add₂]
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rw [partialDeriv_add₂]
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exact
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add_add_add_comm (partialDeriv ℝ 1 (partialDeriv ℝ 1 f₁))
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(partialDeriv ℝ 1 (partialDeriv ℝ 1 f₂))
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(partialDeriv ℝ Complex.I (partialDeriv ℝ Complex.I f₁))
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(partialDeriv ℝ Complex.I (partialDeriv ℝ Complex.I f₂))
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exact (partialDeriv_contDiff ℝ h₁ Complex.I).differentiable le_rfl
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exact (partialDeriv_contDiff ℝ h₂ Complex.I).differentiable le_rfl
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exact h₁.differentiable one_le_two
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exact h₂.differentiable one_le_two
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exact (partialDeriv_contDiff ℝ h₁ 1).differentiable le_rfl
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exact (partialDeriv_contDiff ℝ h₂ 1).differentiable le_rfl
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exact h₁.differentiable one_le_two
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exact h₂.differentiable one_le_two
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theorem laplace_add_ContDiffOn
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{f₁ f₂ : ℂ → F}
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{s : Set ℂ}
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(hs : IsOpen s)
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(h₁ : ContDiffOn ℝ 2 f₁ s)
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(h₂ : ContDiffOn ℝ 2 f₂ s) :
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∀ x ∈ s, Δ (f₁ + f₂) x = (Δ f₁) x + (Δ f₂) x := by
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unfold Complex.laplace
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simp
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intro x hx
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have hf₁ : ∀ z ∈ s, DifferentiableAt ℝ f₁ z := by
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intro z hz
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convert DifferentiableOn.differentiableAt _ (IsOpen.mem_nhds hs hz)
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apply ContDiffOn.differentiableOn h₁ one_le_two
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have hf₂ : ∀ z ∈ s, DifferentiableAt ℝ f₂ z := by
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intro z hz
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convert DifferentiableOn.differentiableAt _ (IsOpen.mem_nhds hs hz)
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apply ContDiffOn.differentiableOn h₂ one_le_two
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have : partialDeriv ℝ 1 (f₁ + f₂) =ᶠ[nhds x] (partialDeriv ℝ 1 f₁) + (partialDeriv ℝ 1 f₂) := by
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apply Filter.eventuallyEq_iff_exists_mem.2
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use s
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constructor
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· exact IsOpen.mem_nhds hs hx
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· intro z hz
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apply partialDeriv_add₂_differentiableAt
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exact hf₁ z hz
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exact hf₂ z hz
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rw [partialDeriv_eventuallyEq ℝ this]
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have t₁ : DifferentiableAt ℝ (partialDeriv ℝ 1 f₁) x := by
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let B₀ := (h₁ x hx).contDiffAt (IsOpen.mem_nhds hs hx)
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let A₀ := partialDeriv_contDiffAt ℝ B₀ 1
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exact A₀.differentiableAt (Submonoid.oneLE.proof_2 ℕ∞)
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have t₂ : DifferentiableAt ℝ (partialDeriv ℝ 1 f₂) x := by
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let B₀ := (h₂ x hx).contDiffAt (IsOpen.mem_nhds hs hx)
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let A₀ := partialDeriv_contDiffAt ℝ B₀ 1
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exact A₀.differentiableAt (Submonoid.oneLE.proof_2 ℕ∞)
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rw [partialDeriv_add₂_differentiableAt ℝ t₁ t₂]
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have : partialDeriv ℝ Complex.I (f₁ + f₂) =ᶠ[nhds x] (partialDeriv ℝ Complex.I f₁) + (partialDeriv ℝ Complex.I f₂) := by
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apply Filter.eventuallyEq_iff_exists_mem.2
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use s
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constructor
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· exact IsOpen.mem_nhds hs hx
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· intro z hz
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apply partialDeriv_add₂_differentiableAt
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exact hf₁ z hz
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exact hf₂ z hz
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rw [partialDeriv_eventuallyEq ℝ this]
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have t₃ : DifferentiableAt ℝ (partialDeriv ℝ Complex.I f₁) x := by
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let B₀ := (h₁ x hx).contDiffAt (IsOpen.mem_nhds hs hx)
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let A₀ := partialDeriv_contDiffAt ℝ B₀ Complex.I
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exact A₀.differentiableAt (Submonoid.oneLE.proof_2 ℕ∞)
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have t₄ : DifferentiableAt ℝ (partialDeriv ℝ Complex.I f₂) x := by
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let B₀ := (h₂ x hx).contDiffAt (IsOpen.mem_nhds hs hx)
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let A₀ := partialDeriv_contDiffAt ℝ B₀ Complex.I
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exact A₀.differentiableAt (Submonoid.oneLE.proof_2 ℕ∞)
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rw [partialDeriv_add₂_differentiableAt ℝ t₃ t₄]
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-- I am super confused at this point because the tactic 'ring' does not work.
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-- I do not understand why. So, I need to do things by hand.
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rw [add_assoc]
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rw [add_assoc]
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rw [add_right_inj (partialDeriv ℝ 1 (partialDeriv ℝ 1 f₁) x)]
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rw [add_comm]
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rw [add_assoc]
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rw [add_right_inj (partialDeriv ℝ Complex.I (partialDeriv ℝ Complex.I f₁) x)]
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rw [add_comm]
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theorem laplace_add_ContDiffAt
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{f₁ f₂ : ℂ → F}
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{x : ℂ}
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(h₁ : ContDiffAt ℝ 2 f₁ x)
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(h₂ : ContDiffAt ℝ 2 f₂ x) :
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Δ (f₁ + f₂) x = (Δ f₁) x + (Δ f₂) x := by
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unfold Complex.laplace
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simp
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have h₁₁ : ContDiffAt ℝ 1 f₁ x := h₁.of_le one_le_two
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have h₂₁ : ContDiffAt ℝ 1 f₂ x := h₂.of_le one_le_two
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repeat
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rw [partialDeriv_eventuallyEq ℝ (partialDeriv_add₂_contDiffAt ℝ h₁₁ h₂₁)]
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rw [partialDeriv_add₂_differentiableAt]
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-- I am super confused at this point because the tactic 'ring' does not work.
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-- I do not understand why. So, I need to do things by hand.
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rw [add_assoc]
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rw [add_assoc]
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rw [add_right_inj (partialDeriv ℝ 1 (partialDeriv ℝ 1 f₁) x)]
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rw [add_comm]
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rw [add_assoc]
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rw [add_right_inj (partialDeriv ℝ Complex.I (partialDeriv ℝ Complex.I f₁) x)]
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rw [add_comm]
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repeat
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apply fun v ↦ (partialDeriv_contDiffAt ℝ h₁ v).differentiableAt le_rfl
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apply fun v ↦ (partialDeriv_contDiffAt ℝ h₂ v).differentiableAt le_rfl
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theorem laplace_smul {f : ℂ → F} : ∀ v : ℝ, Δ (v • f) = v • (Δ f) := by
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intro v
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unfold Complex.laplace
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repeat
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rw [partialDeriv_smul₂]
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simp
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theorem laplace_compCLMAt {f : ℂ → F} {l : F →L[ℝ] G} {x : ℂ} (h : ContDiffAt ℝ 2 f x) :
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Δ (l ∘ f) x = (l ∘ (Δ f)) x := by
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obtain ⟨v, hv₁, hv₂, hv₃, hv₄⟩ : ∃ v ∈ nhds x, (IsOpen v) ∧ (x ∈ v) ∧ (ContDiffOn ℝ 2 f v) := by
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obtain ⟨u, hu₁, hu₂⟩ : ∃ u ∈ nhds x, ContDiffOn ℝ 2 f u := by
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apply ContDiffAt.contDiffOn h
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rfl
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obtain ⟨v, hv₁, hv₂, hv₃⟩ := mem_nhds_iff.1 hu₁
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use v
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constructor
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· exact IsOpen.mem_nhds hv₂ hv₃
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· constructor
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exact hv₂
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constructor
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· exact hv₃
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· exact ContDiffOn.congr_mono hu₂ (fun x => congrFun rfl) hv₁
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have D : ∀ w : ℂ, partialDeriv ℝ w (l ∘ f) =ᶠ[nhds x] l ∘ partialDeriv ℝ w (f) := by
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intro w
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apply Filter.eventuallyEq_iff_exists_mem.2
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use v
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constructor
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· exact IsOpen.mem_nhds hv₂ hv₃
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· intro y hy
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apply partialDeriv_compContLinAt
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let V := ContDiffOn.differentiableOn hv₄ one_le_two
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apply DifferentiableOn.differentiableAt V
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apply IsOpen.mem_nhds
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assumption
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assumption
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unfold Complex.laplace
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simp
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rw [partialDeriv_eventuallyEq ℝ (D 1) 1]
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rw [partialDeriv_compContLinAt]
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rw [partialDeriv_eventuallyEq ℝ (D Complex.I) Complex.I]
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rw [partialDeriv_compContLinAt]
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simp
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-- DifferentiableAt ℝ (partialDeriv ℝ Complex.I f) x
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apply ContDiffAt.differentiableAt (partialDeriv_contDiffAt ℝ (ContDiffOn.contDiffAt hv₄ hv₁) Complex.I) le_rfl
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-- DifferentiableAt ℝ (partialDeriv ℝ 1 f) x
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apply ContDiffAt.differentiableAt (partialDeriv_contDiffAt ℝ (ContDiffOn.contDiffAt hv₄ hv₁) 1) le_rfl
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theorem laplace_compCLM
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{f : ℂ → F}
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{l : F →L[ℝ] G}
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(h : ContDiff ℝ 2 f) :
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Δ (l ∘ f) = l ∘ (Δ f) := by
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funext z
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exact laplace_compCLMAt h.contDiffAt
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theorem laplace_compCLE {f : ℂ → F} {l : F ≃L[ℝ] G} :
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Δ (l ∘ f) = l ∘ (Δ f) := by
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unfold Complex.laplace
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repeat
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rw [partialDeriv_compCLE]
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simp
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