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import Mathlib.MeasureTheory.Integral.Periodic
import Mathlib.MeasureTheory.Integral.CircleIntegral
import Nevanlinna.specialFunctions_Integral_log_sin
import Nevanlinna.harmonicAt_examples
import Nevanlinna.harmonicAt_meanValue
import Nevanlinna.periodic_integrability
open scoped Interval Topology
open Real Filter MeasureTheory intervalIntegral
-- Integrability of periodic functions
-- Lemmas for the circleMap
lemma l₀ {x₁ x₂ : } : (circleMap 0 1 x₁) * (circleMap 0 1 x₂) = circleMap 0 1 (x₁+x₂) := by
dsimp [circleMap]
simp
rw [add_mul, Complex.exp_add]
lemma l₁ {x : } : ‖circleMap 0 1 x‖ = 1 := by
rw [Complex.norm_eq_abs, abs_circleMap_zero]
simp
lemma l₂ {x : } : ‖(circleMap 0 1 x) - a‖ = ‖1 - (circleMap 0 1 (-x)) * a‖ := by
calc ‖(circleMap 0 1 x) - a‖
_ = 1 * ‖(circleMap 0 1 x) - a‖ := by
exact Eq.symm (one_mul ‖circleMap 0 1 x - a‖)
_ = ‖(circleMap 0 1 (-x))‖ * ‖(circleMap 0 1 x) - a‖ := by
rw [l₁]
_ = ‖(circleMap 0 1 (-x)) * ((circleMap 0 1 x) - a)‖ := by
exact Eq.symm (NormedField.norm_mul' (circleMap 0 1 (-x)) (circleMap 0 1 x - a))
_ = ‖(circleMap 0 1 (-x)) * (circleMap 0 1 x) - (circleMap 0 1 (-x)) * a‖ := by
rw [mul_sub]
_ = ‖(circleMap 0 1 0) - (circleMap 0 1 (-x)) * a‖ := by
rw [l₀]
simp
_ = ‖1 - (circleMap 0 1 (-x)) * a‖ := by
congr
dsimp [circleMap]
simp
-- Integral of log ‖circleMap 0 1 x - a‖, for ‖a‖ < 1.
lemma int₀
{a : }
(ha : a ∈ Metric.ball 0 1) :
∫ (x : ) in (0)..2 * π, log ‖circleMap 0 1 x - a‖ = 0 := by
by_cases h₁a : a = 0
· -- case: a = 0
rw [h₁a]
simp
-- case: a ≠ 0
simp_rw [l₂]
have {x : } : log ‖1 - circleMap 0 1 (-x) * a‖ = (fun w ↦ log ‖1 - circleMap 0 1 (w) * a‖) (-x) := by rfl
conv =>
left
arg 1
intro x
rw [this]
rw [intervalIntegral.integral_comp_neg ((fun w ↦ log ‖1 - circleMap 0 1 (w) * a‖))]
let f₁ := fun w ↦ log ‖1 - circleMap 0 1 w * a‖
have {x : } : log ‖1 - circleMap 0 1 x * a‖ = f₁ (x + 2 * π) := by
dsimp [f₁]
congr 4
let A := periodic_circleMap 0 1 x
simp at A
exact id (Eq.symm A)
conv =>
left
arg 1
intro x
rw [this]
rw [intervalIntegral.integral_comp_add_right f₁ (2 * π)]
simp
dsimp [f₁]
let ρ := ‖a‖⁻¹
have hρ : 1 < ρ := by
apply one_lt_inv_iff.mpr
constructor
· exact norm_pos_iff'.mpr h₁a
· exact mem_ball_zero_iff.mp ha
let F := fun z ↦ log ‖1 - z * a‖
have hf : ∀ x ∈ Metric.ball 0 ρ, HarmonicAt F x := by
intro x hx
apply logabs_of_holomorphicAt_is_harmonic
apply Differentiable.holomorphicAt
fun_prop
apply sub_ne_zero_of_ne
by_contra h
have : ‖x * a‖ < 1 := by
calc ‖x * a‖
_ = ‖x‖ * ‖a‖ := by exact NormedField.norm_mul' x a
_ < ρ * ‖a‖ := by
apply (mul_lt_mul_right _).2
exact mem_ball_zero_iff.mp hx
exact norm_pos_iff'.mpr h₁a
_ = 1 := by
dsimp [ρ]
apply inv_mul_cancel₀
exact (AbsoluteValue.ne_zero_iff Complex.abs).mpr h₁a
rw [← h] at this
simp at this
let A := harmonic_meanValue ρ 1 zero_lt_one hρ hf
dsimp [F] at A
simp at A
exact A
-- Integral of log ‖circleMap 0 1 x - 1‖
lemma int₁₁ : ∫ (x : ) in (0)..π, log (4 * sin x ^ 2) = 0 := by
have t₁ {x : } : x ∈ Set.Ioo 0 π → log (4 * sin x ^ 2) = log 4 + 2 * log (sin x) := by
intro hx
rw [log_mul, log_pow]
rfl
exact Ne.symm (NeZero.ne' 4)
apply pow_ne_zero 2
apply (fun a => Ne.symm (ne_of_lt a))
exact sin_pos_of_mem_Ioo hx
have t₂ : Set.EqOn (fun y ↦ log (4 * sin y ^ 2)) (fun y ↦ log 4 + 2 * log (sin y)) (Set.Ioo 0 π) := by
intro x hx
simp
rw [t₁ hx]
rw [intervalIntegral.integral_congr_volume pi_pos t₂]
rw [intervalIntegral.integral_add]
rw [intervalIntegral.integral_const_mul]
simp
rw [integral_log_sin₂]
have : (4 : ) = 2 * 2 := by norm_num
rw [this, log_mul]
ring
norm_num
norm_num
-- IntervalIntegrable (fun x => log 4) volume 0 π
simp
-- IntervalIntegrable (fun x => 2 * log (sin x)) volume 0 π
apply IntervalIntegrable.const_mul
exact intervalIntegrable_log_sin
lemma logAffineHelper {x : } : log ‖circleMap 0 1 x - 1‖ = log (4 * sin (x / 2) ^ 2) / 2 := by
dsimp [Complex.abs]
rw [log_sqrt (Complex.normSq_nonneg (circleMap 0 1 x - 1))]
congr
calc Complex.normSq (circleMap 0 1 x - 1)
_ = (cos x - 1) * (cos x - 1) + sin x * sin x := by
dsimp [circleMap]
rw [Complex.normSq_apply]
simp
_ = sin x ^ 2 + cos x ^ 2 + 1 - 2 * cos x := by
ring
_ = 2 - 2 * cos x := by
rw [sin_sq_add_cos_sq]
norm_num
_ = 2 - 2 * cos (2 * (x / 2)) := by
rw [← mul_div_assoc]
congr; norm_num
_ = 4 - 4 * cos (x / 2) ^ 2 := by
rw [cos_two_mul]
ring
_ = 4 * sin (x / 2) ^ 2 := by
nth_rw 1 [← mul_one 4, ← sin_sq_add_cos_sq (x / 2)]
ring
lemma int'₁ : -- Integrability of log ‖circleMap 0 1 x - 1‖
IntervalIntegrable (fun x ↦ log ‖circleMap 0 1 x - 1‖) volume 0 (2 * π) := by
simp_rw [logAffineHelper]
apply IntervalIntegrable.div_const
rw [← IntervalIntegrable.comp_mul_left_iff (c := 2) (Ne.symm (NeZero.ne' 2))]
simp
have h₁ : Set.EqOn (fun x => log (4 * sin x ^ 2)) (fun x => log 4 + 2 * log (sin x)) (Set.Ioo 0 π) := by
intro x hx
simp [log_mul (Ne.symm (NeZero.ne' 4)), log_pow, ne_of_gt (sin_pos_of_mem_Ioo hx)]
rw [IntervalIntegrable.integral_congr_Ioo pi_nonneg h₁]
apply IntervalIntegrable.add
simp
apply IntervalIntegrable.const_mul
exact intervalIntegrable_log_sin
lemma int''₁ : -- Integrability of log ‖circleMap 0 1 x - 1‖ for arbitrary intervals
∀ (t₁ t₂ : ), IntervalIntegrable (fun x ↦ log ‖circleMap 0 1 x - 1‖) volume t₁ t₂ := by
intro t₁ t₂
apply periodic_integrability4 (T := 2 * π) (t := 0)
--
have : (fun x => log ‖circleMap 0 1 x - 1‖) = (fun x => log ‖x - 1‖) ∘ (circleMap 0 1) := rfl
rw [this]
apply Function.Periodic.comp
exact periodic_circleMap 0 1
--
exact two_pi_pos
--
rw [zero_add]
exact int'₁
lemma int₁ :
∫ x in (0)..(2 * π), log ‖circleMap 0 1 x - 1‖ = 0 := by
simp_rw [logAffineHelper]
simp
have : ∫ (x : ) in (0)..2 * π, log (4 * sin (x / 2) ^ 2) = 2 * ∫ (x : ) in (0)..π, log (4 * sin x ^ 2) := by
have : 1 = 2 * (2 : )⁻¹ := by exact Eq.symm (mul_inv_cancel_of_invertible 2)
nth_rw 1 [← one_mul (∫ (x : ) in (0)..2 * π, log (4 * sin (x / 2) ^ 2))]
rw [← mul_inv_cancel_of_invertible 2, mul_assoc]
let f := fun y ↦ log (4 * sin y ^ 2)
have {x : } : log (4 * sin (x / 2) ^ 2) = f (x / 2) := by simp
conv =>
left
right
right
arg 1
intro x
rw [this]
rw [intervalIntegral.inv_mul_integral_comp_div 2]
simp
rw [this]
simp
exact int₁₁
-- Integral of log ‖circleMap 0 1 x - a‖, for ‖a‖ = 1
lemma int'₂
{a : }
(ha : ‖a‖ = 1) :
IntervalIntegrable (fun x ↦ log ‖circleMap 0 1 x - a‖) volume 0 (2 * π) := by
simp_rw [l₂]
have {x : } : log ‖1 - circleMap 0 1 (-x) * a‖ = (fun w ↦ log ‖1 - circleMap 0 1 (w) * a‖) (-x) := by rfl
conv =>
arg 1
intro x
rw [this]
rw [IntervalIntegrable.iff_comp_neg]
let f₁ := fun w ↦ log ‖1 - circleMap 0 1 w * a‖
have {x : } : log ‖1 - circleMap 0 1 x * a‖ = f₁ (x + 2 * π) := by
dsimp [f₁]
congr 4
let A := periodic_circleMap 0 1 x
simp at A
exact id (Eq.symm A)
conv =>
arg 1
intro x
arg 0
intro w
rw [this]
simp
have : 0 = 2 * π - 2 * π := by ring
rw [this]
have : -(2 * π ) = 0 - 2 * π := by ring
rw [this]
apply IntervalIntegrable.comp_add_right _ (2 * π) --f₁ (2 * π)
dsimp [f₁]
have : ∃ ζ, a = circleMap 0 1 ζ := by
apply Set.exists_range_iff.mp
use a
simp
exact ha
obtain ⟨ζ, hζ⟩ := this
rw [hζ]
simp_rw [l₀]
have : 2 * π = (2 * π + ζ) - ζ := by ring
rw [this]
have : 0 = ζ - ζ := by ring
rw [this]
have : (fun w => log (Complex.abs (1 - circleMap 0 1 (w + ζ)))) = fun x ↦ (fun w ↦ log (Complex.abs (1 - circleMap 0 1 (w)))) (x + ζ) := rfl
rw [this]
apply IntervalIntegrable.comp_add_right (f := (fun w ↦ log (Complex.abs (1 - circleMap 0 1 (w))))) _ ζ
have : Function.Periodic (fun x ↦ log (Complex.abs (1 - circleMap 0 1 x))) (2 * π) := by
have : (fun x ↦ log (Complex.abs (1 - circleMap 0 1 x))) = ( (fun x ↦ log (Complex.abs (1 - x))) ∘ (circleMap 0 1) ) := by rfl
rw [this]
apply Function.Periodic.comp
exact periodic_circleMap 0 1
let A := int''₁ (2 * π + ζ) ζ
have {x : } : ‖circleMap 0 1 x - 1‖ = Complex.abs (1 - circleMap 0 1 x) := AbsoluteValue.map_sub Complex.abs (circleMap 0 1 x) 1
simp_rw [this] at A
exact A
lemma int₂
{a : }
(ha : ‖a‖ = 1) :
∫ x in (0)..(2 * π), log ‖circleMap 0 1 x - a‖ = 0 := by
simp_rw [l₂]
have {x : } : log ‖1 - circleMap 0 1 (-x) * a‖ = (fun w ↦ log ‖1 - circleMap 0 1 (w) * a‖) (-x) := by rfl
conv =>
left
arg 1
intro x
rw [this]
rw [intervalIntegral.integral_comp_neg ((fun w ↦ log ‖1 - circleMap 0 1 (w) * a‖))]
let f₁ := fun w ↦ log ‖1 - circleMap 0 1 w * a‖
have {x : } : log ‖1 - circleMap 0 1 x * a‖ = f₁ (x + 2 * π) := by
dsimp [f₁]
congr 4
let A := periodic_circleMap 0 1 x
simp at A
exact id (Eq.symm A)
conv =>
left
arg 1
intro x
rw [this]
rw [intervalIntegral.integral_comp_add_right f₁ (2 * π)]
simp
dsimp [f₁]
have : ∃ ζ, a = circleMap 0 1 ζ := by
apply Set.exists_range_iff.mp
use a
simp
exact ha
obtain ⟨ζ, hζ⟩ := this
rw [hζ]
simp_rw [l₀]
rw [intervalIntegral.integral_comp_add_right (f := fun x ↦ log (Complex.abs (1 - circleMap 0 1 (x))))]
have : Function.Periodic (fun x ↦ log (Complex.abs (1 - circleMap 0 1 x))) (2 * π) := by
have : (fun x ↦ log (Complex.abs (1 - circleMap 0 1 x))) = ( (fun x ↦ log (Complex.abs (1 - x))) ∘ (circleMap 0 1) ) := by rfl
rw [this]
apply Function.Periodic.comp
exact periodic_circleMap 0 1
let A := Function.Periodic.intervalIntegral_add_eq this ζ 0
simp at A
simp
rw [add_comm]
rw [A]
have {x : } : log (Complex.abs (1 - circleMap 0 1 x)) = log ‖circleMap 0 1 x - 1‖ := by
rw [← AbsoluteValue.map_neg Complex.abs]
simp
simp_rw [this]
exact int₁
lemma int₃
{a : }
(ha : a ∈ Metric.closedBall 0 1) :
∫ x in (0)..(2 * π), log ‖circleMap 0 1 x - a‖ = 0 := by
by_cases h₁a : a ∈ Metric.ball 0 1
· exact int₀ h₁a
· apply int₂
simp at ha
simp at h₁a
simp
linarith