Split (1)

train · 219k rows

url stringclasses 147 values	commit stringclasses 147 values	file_path stringlengths 7 101	full_name stringlengths 1 94	start stringlengths 6 10	end stringlengths 6 11	tactic stringlengths 1 11.2k	state_before stringlengths 3 2.09M	state_after stringlengths 6 2.09M	input stringlengths 73 2.09M
https://github.com/girving/ray.git	0be790285dd0fce78913b0cb9bddaffa94bd25f9	Ray/Dynamics/Multibrot/PotentialLower.lean	pass_through	[28, 1]	[54, 19]	rw [←hk]	c z : ℂ c4 : Complex.abs c ≤ 4 z4 : Complex.abs z ≤ 4 s : Super (f 2) 2 OnePoint.infty := superF 2 m : Filter.Tendsto (fun x => Complex.abs ((f' 2 c)^[x] z)) Filter.atTop Filter.atTop n : ℕ p : ℕ → Prop hp : (fun n => 4 < Complex.abs ((f' 2 c)^[n] z)) = p h : p n k : ℕ hk : Nat.find ⋯ = k ⊢ p k	c z : ℂ c4 : Complex.abs c ≤ 4 z4 : Complex.abs z ≤ 4 s : Super (f 2) 2 OnePoint.infty := superF 2 m : Filter.Tendsto (fun x => Complex.abs ((f' 2 c)^[x] z)) Filter.atTop Filter.atTop n : ℕ p : ℕ → Prop hp : (fun n => 4 < Complex.abs ((f' 2 c)^[n] z)) = p h : p n k : ℕ hk : Nat.find ⋯ = k ⊢ p (Nat.find ⋯)	Please generate a tactic in lean4 to solve the state. STATE: c z : ℂ c4 : Complex.abs c ≤ 4 z4 : Complex.abs z ≤ 4 s : Super (f 2) 2 OnePoint.infty := superF 2 m : Filter.Tendsto (fun x => Complex.abs ((f' 2 c)^[x] z)) Filter.atTop Filter.atTop n : ℕ p : ℕ → Prop hp : (fun n => 4 < Complex.abs ((f' 2 c)^[n] z)) = p h : p n k : ℕ hk : Nat.find ⋯ = k ⊢ p k TACTIC:
https://github.com/girving/ray.git	0be790285dd0fce78913b0cb9bddaffa94bd25f9	Ray/Dynamics/Multibrot/PotentialLower.lean	pass_through	[28, 1]	[54, 19]	exact Nat.find_spec (p := p) ⟨_,h⟩	c z : ℂ c4 : Complex.abs c ≤ 4 z4 : Complex.abs z ≤ 4 s : Super (f 2) 2 OnePoint.infty := superF 2 m : Filter.Tendsto (fun x => Complex.abs ((f' 2 c)^[x] z)) Filter.atTop Filter.atTop n : ℕ p : ℕ → Prop hp : (fun n => 4 < Complex.abs ((f' 2 c)^[n] z)) = p h : p n k : ℕ hk : Nat.find ⋯ = k ⊢ p (Nat.find ⋯)	no goals	Please generate a tactic in lean4 to solve the state. STATE: c z : ℂ c4 : Complex.abs c ≤ 4 z4 : Complex.abs z ≤ 4 s : Super (f 2) 2 OnePoint.infty := superF 2 m : Filter.Tendsto (fun x => Complex.abs ((f' 2 c)^[x] z)) Filter.atTop Filter.atTop n : ℕ p : ℕ → Prop hp : (fun n => 4 < Complex.abs ((f' 2 c)^[n] z)) = p h : p n k : ℕ hk : Nat.find ⋯ = k ⊢ p (Nat.find ⋯) TACTIC:
https://github.com/girving/ray.git	0be790285dd0fce78913b0cb9bddaffa94bd25f9	Ray/Dynamics/Multibrot/PotentialLower.lean	pass_through	[28, 1]	[54, 19]	contrapose k4	c z : ℂ c4 : Complex.abs c ≤ 4 z4 : Complex.abs z ≤ 4 s : Super (f 2) 2 OnePoint.infty := superF 2 m : Filter.Tendsto (fun x => Complex.abs ((f' 2 c)^[x] z)) Filter.atTop Filter.atTop n : ℕ p : ℕ → Prop hp : (fun n => 4 < Complex.abs ((f' 2 c)^[n] z)) = p h : p n k : ℕ hk : Nat.find ⋯ = k k4 : p k ⊢ k ≠ 0	c z : ℂ c4 : Complex.abs c ≤ 4 z4 : Complex.abs z ≤ 4 s : Super (f 2) 2 OnePoint.infty := superF 2 m : Filter.Tendsto (fun x => Complex.abs ((f' 2 c)^[x] z)) Filter.atTop Filter.atTop n : ℕ p : ℕ → Prop hp : (fun n => 4 < Complex.abs ((f' 2 c)^[n] z)) = p h : p n k : ℕ hk : Nat.find ⋯ = k k4 : ¬k ≠ 0 ⊢ ¬p k	Please generate a tactic in lean4 to solve the state. STATE: c z : ℂ c4 : Complex.abs c ≤ 4 z4 : Complex.abs z ≤ 4 s : Super (f 2) 2 OnePoint.infty := superF 2 m : Filter.Tendsto (fun x => Complex.abs ((f' 2 c)^[x] z)) Filter.atTop Filter.atTop n : ℕ p : ℕ → Prop hp : (fun n => 4 < Complex.abs ((f' 2 c)^[n] z)) = p h : p n k : ℕ hk : Nat.find ⋯ = k k4 : p k ⊢ k ≠ 0 TACTIC:
https://github.com/girving/ray.git	0be790285dd0fce78913b0cb9bddaffa94bd25f9	Ray/Dynamics/Multibrot/PotentialLower.lean	pass_through	[28, 1]	[54, 19]	simp only [not_not] at k4	c z : ℂ c4 : Complex.abs c ≤ 4 z4 : Complex.abs z ≤ 4 s : Super (f 2) 2 OnePoint.infty := superF 2 m : Filter.Tendsto (fun x => Complex.abs ((f' 2 c)^[x] z)) Filter.atTop Filter.atTop n : ℕ p : ℕ → Prop hp : (fun n => 4 < Complex.abs ((f' 2 c)^[n] z)) = p h : p n k : ℕ hk : Nat.find ⋯ = k k4 : ¬k ≠ 0 ⊢ ¬p k	c z : ℂ c4 : Complex.abs c ≤ 4 z4 : Complex.abs z ≤ 4 s : Super (f 2) 2 OnePoint.infty := superF 2 m : Filter.Tendsto (fun x => Complex.abs ((f' 2 c)^[x] z)) Filter.atTop Filter.atTop n : ℕ p : ℕ → Prop hp : (fun n => 4 < Complex.abs ((f' 2 c)^[n] z)) = p h : p n k : ℕ hk : Nat.find ⋯ = k k4 : k = 0 ⊢ ¬p k	Please generate a tactic in lean4 to solve the state. STATE: c z : ℂ c4 : Complex.abs c ≤ 4 z4 : Complex.abs z ≤ 4 s : Super (f 2) 2 OnePoint.infty := superF 2 m : Filter.Tendsto (fun x => Complex.abs ((f' 2 c)^[x] z)) Filter.atTop Filter.atTop n : ℕ p : ℕ → Prop hp : (fun n => 4 < Complex.abs ((f' 2 c)^[n] z)) = p h : p n k : ℕ hk : Nat.find ⋯ = k k4 : ¬k ≠ 0 ⊢ ¬p k TACTIC:
https://github.com/girving/ray.git	0be790285dd0fce78913b0cb9bddaffa94bd25f9	Ray/Dynamics/Multibrot/PotentialLower.lean	pass_through	[28, 1]	[54, 19]	simp only [k4, ←hp, not_lt, Function.iterate_zero_apply, z4]	c z : ℂ c4 : Complex.abs c ≤ 4 z4 : Complex.abs z ≤ 4 s : Super (f 2) 2 OnePoint.infty := superF 2 m : Filter.Tendsto (fun x => Complex.abs ((f' 2 c)^[x] z)) Filter.atTop Filter.atTop n : ℕ p : ℕ → Prop hp : (fun n => 4 < Complex.abs ((f' 2 c)^[n] z)) = p h : p n k : ℕ hk : Nat.find ⋯ = k k4 : k = 0 ⊢ ¬p k	no goals	Please generate a tactic in lean4 to solve the state. STATE: c z : ℂ c4 : Complex.abs c ≤ 4 z4 : Complex.abs z ≤ 4 s : Super (f 2) 2 OnePoint.infty := superF 2 m : Filter.Tendsto (fun x => Complex.abs ((f' 2 c)^[x] z)) Filter.atTop Filter.atTop n : ℕ p : ℕ → Prop hp : (fun n => 4 < Complex.abs ((f' 2 c)^[n] z)) = p h : p n k : ℕ hk : Nat.find ⋯ = k k4 : k = 0 ⊢ ¬p k TACTIC:
https://github.com/girving/ray.git	0be790285dd0fce78913b0cb9bddaffa94bd25f9	Ray/Dynamics/Multibrot/PotentialLower.lean	pass_through	[28, 1]	[54, 19]	apply Nat.find_min	c z : ℂ c4 : Complex.abs c ≤ 4 z4 : Complex.abs z ≤ 4 s : Super (f 2) 2 OnePoint.infty := superF 2 m : Filter.Tendsto (fun x => Complex.abs ((f' 2 c)^[x] z)) Filter.atTop Filter.atTop n : ℕ p : ℕ → Prop hp : (fun n => 4 < Complex.abs ((f' 2 c)^[n] z)) = p h : p n k : ℕ hk : Nat.find ⋯ = k k4 : p k k0 : k ≠ 0 k1 : 1 ≤ k ⊢ ¬p (k - 1)	case a c z : ℂ c4 : Complex.abs c ≤ 4 z4 : Complex.abs z ≤ 4 s : Super (f 2) 2 OnePoint.infty := superF 2 m : Filter.Tendsto (fun x => Complex.abs ((f' 2 c)^[x] z)) Filter.atTop Filter.atTop n : ℕ p : ℕ → Prop hp : (fun n => 4 < Complex.abs ((f' 2 c)^[n] z)) = p h : p n k : ℕ hk : Nat.find ⋯ = k k4 : p k k0 : k ≠ 0 k1 : 1 ≤ k ⊢ k - 1 < Nat.find ?H case H c z : ℂ c4 : Complex.abs c ≤ 4 z4 : Complex.abs z ≤ 4 s : Super (f 2) 2 OnePoint.infty := superF 2 m : Filter.Tendsto (fun x => Complex.abs ((f' 2 c)^[x] z)) Filter.atTop Filter.atTop n : ℕ p : ℕ → Prop hp : (fun n => 4 < Complex.abs ((f' 2 c)^[n] z)) = p h : p n k : ℕ hk : Nat.find ⋯ = k k4 : p k k0 : k ≠ 0 k1 : 1 ≤ k ⊢ ∃ n, p n	Please generate a tactic in lean4 to solve the state. STATE: c z : ℂ c4 : Complex.abs c ≤ 4 z4 : Complex.abs z ≤ 4 s : Super (f 2) 2 OnePoint.infty := superF 2 m : Filter.Tendsto (fun x => Complex.abs ((f' 2 c)^[x] z)) Filter.atTop Filter.atTop n : ℕ p : ℕ → Prop hp : (fun n => 4 < Complex.abs ((f' 2 c)^[n] z)) = p h : p n k : ℕ hk : Nat.find ⋯ = k k4 : p k k0 : k ≠ 0 k1 : 1 ≤ k ⊢ ¬p (k - 1) TACTIC:
https://github.com/girving/ray.git	0be790285dd0fce78913b0cb9bddaffa94bd25f9	Ray/Dynamics/Multibrot/PotentialLower.lean	pass_through	[28, 1]	[54, 19]	rw [hk]	case a c z : ℂ c4 : Complex.abs c ≤ 4 z4 : Complex.abs z ≤ 4 s : Super (f 2) 2 OnePoint.infty := superF 2 m : Filter.Tendsto (fun x => Complex.abs ((f' 2 c)^[x] z)) Filter.atTop Filter.atTop n : ℕ p : ℕ → Prop hp : (fun n => 4 < Complex.abs ((f' 2 c)^[n] z)) = p h : p n k : ℕ hk : Nat.find ⋯ = k k4 : p k k0 : k ≠ 0 k1 : 1 ≤ k ⊢ k - 1 < Nat.find ?H case H c z : ℂ c4 : Complex.abs c ≤ 4 z4 : Complex.abs z ≤ 4 s : Super (f 2) 2 OnePoint.infty := superF 2 m : Filter.Tendsto (fun x => Complex.abs ((f' 2 c)^[x] z)) Filter.atTop Filter.atTop n : ℕ p : ℕ → Prop hp : (fun n => 4 < Complex.abs ((f' 2 c)^[n] z)) = p h : p n k : ℕ hk : Nat.find ⋯ = k k4 : p k k0 : k ≠ 0 k1 : 1 ≤ k ⊢ ∃ n, p n	case a c z : ℂ c4 : Complex.abs c ≤ 4 z4 : Complex.abs z ≤ 4 s : Super (f 2) 2 OnePoint.infty := superF 2 m : Filter.Tendsto (fun x => Complex.abs ((f' 2 c)^[x] z)) Filter.atTop Filter.atTop n : ℕ p : ℕ → Prop hp : (fun n => 4 < Complex.abs ((f' 2 c)^[n] z)) = p h : p n k : ℕ hk : Nat.find ⋯ = k k4 : p k k0 : k ≠ 0 k1 : 1 ≤ k ⊢ k - 1 < k	Please generate a tactic in lean4 to solve the state. STATE: case a c z : ℂ c4 : Complex.abs c ≤ 4 z4 : Complex.abs z ≤ 4 s : Super (f 2) 2 OnePoint.infty := superF 2 m : Filter.Tendsto (fun x => Complex.abs ((f' 2 c)^[x] z)) Filter.atTop Filter.atTop n : ℕ p : ℕ → Prop hp : (fun n => 4 < Complex.abs ((f' 2 c)^[n] z)) = p h : p n k : ℕ hk : Nat.find ⋯ = k k4 : p k k0 : k ≠ 0 k1 : 1 ≤ k ⊢ k - 1 < Nat.find ?H case H c z : ℂ c4 : Complex.abs c ≤ 4 z4 : Complex.abs z ≤ 4 s : Super (f 2) 2 OnePoint.infty := superF 2 m : Filter.Tendsto (fun x => Complex.abs ((f' 2 c)^[x] z)) Filter.atTop Filter.atTop n : ℕ p : ℕ → Prop hp : (fun n => 4 < Complex.abs ((f' 2 c)^[n] z)) = p h : p n k : ℕ hk : Nat.find ⋯ = k k4 : p k k0 : k ≠ 0 k1 : 1 ≤ k ⊢ ∃ n, p n TACTIC:
https://github.com/girving/ray.git	0be790285dd0fce78913b0cb9bddaffa94bd25f9	Ray/Dynamics/Multibrot/PotentialLower.lean	pass_through	[28, 1]	[54, 19]	omega	case a c z : ℂ c4 : Complex.abs c ≤ 4 z4 : Complex.abs z ≤ 4 s : Super (f 2) 2 OnePoint.infty := superF 2 m : Filter.Tendsto (fun x => Complex.abs ((f' 2 c)^[x] z)) Filter.atTop Filter.atTop n : ℕ p : ℕ → Prop hp : (fun n => 4 < Complex.abs ((f' 2 c)^[n] z)) = p h : p n k : ℕ hk : Nat.find ⋯ = k k4 : p k k0 : k ≠ 0 k1 : 1 ≤ k ⊢ k - 1 < k	no goals	Please generate a tactic in lean4 to solve the state. STATE: case a c z : ℂ c4 : Complex.abs c ≤ 4 z4 : Complex.abs z ≤ 4 s : Super (f 2) 2 OnePoint.infty := superF 2 m : Filter.Tendsto (fun x => Complex.abs ((f' 2 c)^[x] z)) Filter.atTop Filter.atTop n : ℕ p : ℕ → Prop hp : (fun n => 4 < Complex.abs ((f' 2 c)^[n] z)) = p h : p n k : ℕ hk : Nat.find ⋯ = k k4 : p k k0 : k ≠ 0 k1 : 1 ≤ k ⊢ k - 1 < k TACTIC:
https://github.com/girving/ray.git	0be790285dd0fce78913b0cb9bddaffa94bd25f9	Ray/Dynamics/Multibrot/PotentialLower.lean	pass_through	[28, 1]	[54, 19]	norm_num	c z : ℂ c4 : Complex.abs c ≤ 4 z4 : Complex.abs z ≤ 4 s : Super (f 2) 2 OnePoint.infty := superF 2 m : Filter.Tendsto (fun x => Complex.abs ((f' 2 c)^[x] z)) Filter.atTop Filter.atTop n : ℕ p : ℕ → Prop hp : (fun n => 4 < Complex.abs ((f' 2 c)^[n] z)) = p h : p n k : ℕ hk : Nat.find ⋯ = k k0 : k ≠ 0 k1 : 1 ≤ k k4 : 4 < Complex.abs ((f' 2 c)^[k] z) lt : Complex.abs ((f' 2 c)^[k - 1] z) ≤ 4 fs : Complex.abs ((f' 2 c)^[k] z) ≤ Complex.abs ((f' 2 c)^[k - 1] z) ^ 2 + Complex.abs c ⊢ 4 ^ 2 + 4 ≤ 20	no goals	Please generate a tactic in lean4 to solve the state. STATE: c z : ℂ c4 : Complex.abs c ≤ 4 z4 : Complex.abs z ≤ 4 s : Super (f 2) 2 OnePoint.infty := superF 2 m : Filter.Tendsto (fun x => Complex.abs ((f' 2 c)^[x] z)) Filter.atTop Filter.atTop n : ℕ p : ℕ → Prop hp : (fun n => 4 < Complex.abs ((f' 2 c)^[n] z)) = p h : p n k : ℕ hk : Nat.find ⋯ = k k0 : k ≠ 0 k1 : 1 ≤ k k4 : 4 < Complex.abs ((f' 2 c)^[k] z) lt : Complex.abs ((f' 2 c)^[k - 1] z) ≤ 4 fs : Complex.abs ((f' 2 c)^[k] z) ≤ Complex.abs ((f' 2 c)^[k - 1] z) ^ 2 + Complex.abs c ⊢ 4 ^ 2 + 4 ≤ 20 TACTIC:
https://github.com/girving/ray.git	0be790285dd0fce78913b0cb9bddaffa94bd25f9	Ray/Dynamics/Multibrot/PotentialLower.lean	lower_anti	[56, 1]	[84, 26]	have hd : ∀ x, 4 ≤ x → HasDerivAt (fun x : ℝ ↦ 1 / x - k / x^p) (-(x^2)⁻¹ - k * (-(p * x^(p-1)) / (x^p)^2)) x := by intro x x2 simp only [one_div, div_eq_mul_inv, one_mul] refine (hasDerivAt_inv (by positivity)).sub (HasDerivAt.const_mul _ ?_) exact (Real.hasDerivAt_rpow_const (Or.inl (by positivity))).inv (by positivity)	c z : ℂ k p : ℝ kp : autoParam (k * p ≤ 2) _auto✝ hp : autoParam (3 / 2 ≤ p) _auto✝ ⊢ AntitoneOn (fun x => 1 / x - k / x ^ p) (Ici 4)	c z : ℂ k p : ℝ kp : autoParam (k * p ≤ 2) _auto✝ hp : autoParam (3 / 2 ≤ p) _auto✝ hd : ∀ (x : ℝ), 4 ≤ x → HasDerivAt (fun x => 1 / x - k / x ^ p) (-(x ^ 2)⁻¹ - k * (-(p * x ^ (p - 1)) / (x ^ p) ^ 2)) x ⊢ AntitoneOn (fun x => 1 / x - k / x ^ p) (Ici 4)	Please generate a tactic in lean4 to solve the state. STATE: c z : ℂ k p : ℝ kp : autoParam (k * p ≤ 2) _auto✝ hp : autoParam (3 / 2 ≤ p) _auto✝ ⊢ AntitoneOn (fun x => 1 / x - k / x ^ p) (Ici 4) TACTIC:
https://github.com/girving/ray.git	0be790285dd0fce78913b0cb9bddaffa94bd25f9	Ray/Dynamics/Multibrot/PotentialLower.lean	lower_anti	[56, 1]	[84, 26]	simp only [ge_iff_le] at kp hp	c z : ℂ k p : ℝ kp : autoParam (k * p ≤ 2) _auto✝ hp : autoParam (3 / 2 ≤ p) _auto✝ hd : ∀ (x : ℝ), 4 ≤ x → HasDerivAt (fun x => 1 / x - k / x ^ p) (-(x ^ 2)⁻¹ - k * (-(p * x ^ (p - 1)) / (x ^ p) ^ 2)) x ⊢ AntitoneOn (fun x => 1 / x - k / x ^ p) (Ici 4)	c z : ℂ k p : ℝ hd : ∀ (x : ℝ), 4 ≤ x → HasDerivAt (fun x => 1 / x - k / x ^ p) (-(x ^ 2)⁻¹ - k * (-(p * x ^ (p - 1)) / (x ^ p) ^ 2)) x kp : k * p ≤ 2 hp : 3 / 2 ≤ p ⊢ AntitoneOn (fun x => 1 / x - k / x ^ p) (Ici 4)	Please generate a tactic in lean4 to solve the state. STATE: c z : ℂ k p : ℝ kp : autoParam (k * p ≤ 2) _auto✝ hp : autoParam (3 / 2 ≤ p) _auto✝ hd : ∀ (x : ℝ), 4 ≤ x → HasDerivAt (fun x => 1 / x - k / x ^ p) (-(x ^ 2)⁻¹ - k * (-(p * x ^ (p - 1)) / (x ^ p) ^ 2)) x ⊢ AntitoneOn (fun x => 1 / x - k / x ^ p) (Ici 4) TACTIC:
https://github.com/girving/ray.git	0be790285dd0fce78913b0cb9bddaffa94bd25f9	Ray/Dynamics/Multibrot/PotentialLower.lean	lower_anti	[56, 1]	[84, 26]	have d : DifferentiableOn ℝ (fun x ↦ 1 / x - k / x^p) (Ici 4) := fun x m ↦ (hd x m).differentiableAt.differentiableWithinAt	c z : ℂ k p : ℝ hd : ∀ (x : ℝ), 4 ≤ x → HasDerivAt (fun x => 1 / x - k / x ^ p) (-(x ^ 2)⁻¹ - k * (-(p * x ^ (p - 1)) / (x ^ p) ^ 2)) x kp : k * p ≤ 2 hp : 3 / 2 ≤ p ⊢ AntitoneOn (fun x => 1 / x - k / x ^ p) (Ici 4)	c z : ℂ k p : ℝ hd : ∀ (x : ℝ), 4 ≤ x → HasDerivAt (fun x => 1 / x - k / x ^ p) (-(x ^ 2)⁻¹ - k * (-(p * x ^ (p - 1)) / (x ^ p) ^ 2)) x kp : k * p ≤ 2 hp : 3 / 2 ≤ p d : DifferentiableOn ℝ (fun x => 1 / x - k / x ^ p) (Ici 4) ⊢ AntitoneOn (fun x => 1 / x - k / x ^ p) (Ici 4)	Please generate a tactic in lean4 to solve the state. STATE: c z : ℂ k p : ℝ hd : ∀ (x : ℝ), 4 ≤ x → HasDerivAt (fun x => 1 / x - k / x ^ p) (-(x ^ 2)⁻¹ - k * (-(p * x ^ (p - 1)) / (x ^ p) ^ 2)) x kp : k * p ≤ 2 hp : 3 / 2 ≤ p ⊢ AntitoneOn (fun x => 1 / x - k / x ^ p) (Ici 4) TACTIC:
https://github.com/girving/ray.git	0be790285dd0fce78913b0cb9bddaffa94bd25f9	Ray/Dynamics/Multibrot/PotentialLower.lean	lower_anti	[56, 1]	[84, 26]	apply antitoneOn_of_deriv_nonpos (convex_Ici _)	c z : ℂ k p : ℝ hd : ∀ (x : ℝ), 4 ≤ x → HasDerivAt (fun x => 1 / x - k / x ^ p) (-(x ^ 2)⁻¹ - k * (-(p * x ^ (p - 1)) / (x ^ p) ^ 2)) x kp : k * p ≤ 2 hp : 3 / 2 ≤ p d : DifferentiableOn ℝ (fun x => 1 / x - k / x ^ p) (Ici 4) ⊢ AntitoneOn (fun x => 1 / x - k / x ^ p) (Ici 4)	case hf c z : ℂ k p : ℝ hd : ∀ (x : ℝ), 4 ≤ x → HasDerivAt (fun x => 1 / x - k / x ^ p) (-(x ^ 2)⁻¹ - k * (-(p * x ^ (p - 1)) / (x ^ p) ^ 2)) x kp : k * p ≤ 2 hp : 3 / 2 ≤ p d : DifferentiableOn ℝ (fun x => 1 / x - k / x ^ p) (Ici 4) ⊢ ContinuousOn (fun x => 1 / x - k / x ^ p) (Ici 4) case hf' c z : ℂ k p : ℝ hd : ∀ (x : ℝ), 4 ≤ x → HasDerivAt (fun x => 1 / x - k / x ^ p) (-(x ^ 2)⁻¹ - k * (-(p * x ^ (p - 1)) / (x ^ p) ^ 2)) x kp : k * p ≤ 2 hp : 3 / 2 ≤ p d : DifferentiableOn ℝ (fun x => 1 / x - k / x ^ p) (Ici 4) ⊢ DifferentiableOn ℝ (fun x => 1 / x - k / x ^ p) (interior (Ici 4)) case hf'_nonpos c z : ℂ k p : ℝ hd : ∀ (x : ℝ), 4 ≤ x → HasDerivAt (fun x => 1 / x - k / x ^ p) (-(x ^ 2)⁻¹ - k * (-(p * x ^ (p - 1)) / (x ^ p) ^ 2)) x kp : k * p ≤ 2 hp : 3 / 2 ≤ p d : DifferentiableOn ℝ (fun x => 1 / x - k / x ^ p) (Ici 4) ⊢ ∀ x ∈ interior (Ici 4), deriv (fun x => 1 / x - k / x ^ p) x ≤ 0	Please generate a tactic in lean4 to solve the state. STATE: c z : ℂ k p : ℝ hd : ∀ (x : ℝ), 4 ≤ x → HasDerivAt (fun x => 1 / x - k / x ^ p) (-(x ^ 2)⁻¹ - k * (-(p * x ^ (p - 1)) / (x ^ p) ^ 2)) x kp : k * p ≤ 2 hp : 3 / 2 ≤ p d : DifferentiableOn ℝ (fun x => 1 / x - k / x ^ p) (Ici 4) ⊢ AntitoneOn (fun x => 1 / x - k / x ^ p) (Ici 4) TACTIC:
https://github.com/girving/ray.git	0be790285dd0fce78913b0cb9bddaffa94bd25f9	Ray/Dynamics/Multibrot/PotentialLower.lean	lower_anti	[56, 1]	[84, 26]	intro x x2	c z : ℂ k p : ℝ kp : autoParam (k * p ≤ 2) _auto✝ hp : autoParam (3 / 2 ≤ p) _auto✝ ⊢ ∀ (x : ℝ), 4 ≤ x → HasDerivAt (fun x => 1 / x - k / x ^ p) (-(x ^ 2)⁻¹ - k * (-(p * x ^ (p - 1)) / (x ^ p) ^ 2)) x	c z : ℂ k p : ℝ kp : autoParam (k * p ≤ 2) _auto✝ hp : autoParam (3 / 2 ≤ p) _auto✝ x : ℝ x2 : 4 ≤ x ⊢ HasDerivAt (fun x => 1 / x - k / x ^ p) (-(x ^ 2)⁻¹ - k * (-(p * x ^ (p - 1)) / (x ^ p) ^ 2)) x	Please generate a tactic in lean4 to solve the state. STATE: c z : ℂ k p : ℝ kp : autoParam (k * p ≤ 2) _auto✝ hp : autoParam (3 / 2 ≤ p) _auto✝ ⊢ ∀ (x : ℝ), 4 ≤ x → HasDerivAt (fun x => 1 / x - k / x ^ p) (-(x ^ 2)⁻¹ - k * (-(p * x ^ (p - 1)) / (x ^ p) ^ 2)) x TACTIC:
https://github.com/girving/ray.git	0be790285dd0fce78913b0cb9bddaffa94bd25f9	Ray/Dynamics/Multibrot/PotentialLower.lean	lower_anti	[56, 1]	[84, 26]	simp only [one_div, div_eq_mul_inv, one_mul]	c z : ℂ k p : ℝ kp : autoParam (k * p ≤ 2) _auto✝ hp : autoParam (3 / 2 ≤ p) _auto✝ x : ℝ x2 : 4 ≤ x ⊢ HasDerivAt (fun x => 1 / x - k / x ^ p) (-(x ^ 2)⁻¹ - k * (-(p * x ^ (p - 1)) / (x ^ p) ^ 2)) x	c z : ℂ k p : ℝ kp : autoParam (k * p ≤ 2) _auto✝ hp : autoParam (3 / 2 ≤ p) _auto✝ x : ℝ x2 : 4 ≤ x ⊢ HasDerivAt (fun x => x⁻¹ - k * (x ^ p)⁻¹) (-(x ^ 2)⁻¹ - k * (-(p * x ^ (p - 1)) * ((x ^ p) ^ 2)⁻¹)) x	Please generate a tactic in lean4 to solve the state. STATE: c z : ℂ k p : ℝ kp : autoParam (k * p ≤ 2) _auto✝ hp : autoParam (3 / 2 ≤ p) _auto✝ x : ℝ x2 : 4 ≤ x ⊢ HasDerivAt (fun x => 1 / x - k / x ^ p) (-(x ^ 2)⁻¹ - k * (-(p * x ^ (p - 1)) / (x ^ p) ^ 2)) x TACTIC:
https://github.com/girving/ray.git	0be790285dd0fce78913b0cb9bddaffa94bd25f9	Ray/Dynamics/Multibrot/PotentialLower.lean	lower_anti	[56, 1]	[84, 26]	refine (hasDerivAt_inv (by positivity)).sub (HasDerivAt.const_mul _ ?_)	c z : ℂ k p : ℝ kp : autoParam (k * p ≤ 2) _auto✝ hp : autoParam (3 / 2 ≤ p) _auto✝ x : ℝ x2 : 4 ≤ x ⊢ HasDerivAt (fun x => x⁻¹ - k * (x ^ p)⁻¹) (-(x ^ 2)⁻¹ - k * (-(p * x ^ (p - 1)) * ((x ^ p) ^ 2)⁻¹)) x	c z : ℂ k p : ℝ kp : autoParam (k * p ≤ 2) _auto✝ hp : autoParam (3 / 2 ≤ p) _auto✝ x : ℝ x2 : 4 ≤ x ⊢ HasDerivAt (fun x => (x ^ p)⁻¹) (-(p * x ^ (p - 1)) * ((x ^ p) ^ 2)⁻¹) x	Please generate a tactic in lean4 to solve the state. STATE: c z : ℂ k p : ℝ kp : autoParam (k * p ≤ 2) _auto✝ hp : autoParam (3 / 2 ≤ p) _auto✝ x : ℝ x2 : 4 ≤ x ⊢ HasDerivAt (fun x => x⁻¹ - k * (x ^ p)⁻¹) (-(x ^ 2)⁻¹ - k * (-(p * x ^ (p - 1)) * ((x ^ p) ^ 2)⁻¹)) x TACTIC:
https://github.com/girving/ray.git	0be790285dd0fce78913b0cb9bddaffa94bd25f9	Ray/Dynamics/Multibrot/PotentialLower.lean	lower_anti	[56, 1]	[84, 26]	exact (Real.hasDerivAt_rpow_const (Or.inl (by positivity))).inv (by positivity)	c z : ℂ k p : ℝ kp : autoParam (k * p ≤ 2) _auto✝ hp : autoParam (3 / 2 ≤ p) _auto✝ x : ℝ x2 : 4 ≤ x ⊢ HasDerivAt (fun x => (x ^ p)⁻¹) (-(p * x ^ (p - 1)) * ((x ^ p) ^ 2)⁻¹) x	no goals	Please generate a tactic in lean4 to solve the state. STATE: c z : ℂ k p : ℝ kp : autoParam (k * p ≤ 2) _auto✝ hp : autoParam (3 / 2 ≤ p) _auto✝ x : ℝ x2 : 4 ≤ x ⊢ HasDerivAt (fun x => (x ^ p)⁻¹) (-(p * x ^ (p - 1)) * ((x ^ p) ^ 2)⁻¹) x TACTIC:
https://github.com/girving/ray.git	0be790285dd0fce78913b0cb9bddaffa94bd25f9	Ray/Dynamics/Multibrot/PotentialLower.lean	lower_anti	[56, 1]	[84, 26]	positivity	c z : ℂ k p : ℝ kp : autoParam (k * p ≤ 2) _auto✝ hp : autoParam (3 / 2 ≤ p) _auto✝ x : ℝ x2 : 4 ≤ x ⊢ x ≠ 0	no goals	Please generate a tactic in lean4 to solve the state. STATE: c z : ℂ k p : ℝ kp : autoParam (k * p ≤ 2) _auto✝ hp : autoParam (3 / 2 ≤ p) _auto✝ x : ℝ x2 : 4 ≤ x ⊢ x ≠ 0 TACTIC:
https://github.com/girving/ray.git	0be790285dd0fce78913b0cb9bddaffa94bd25f9	Ray/Dynamics/Multibrot/PotentialLower.lean	lower_anti	[56, 1]	[84, 26]	positivity	c z : ℂ k p : ℝ kp : autoParam (k * p ≤ 2) _auto✝ hp : autoParam (3 / 2 ≤ p) _auto✝ x : ℝ x2 : 4 ≤ x ⊢ x ^ p ≠ 0	no goals	Please generate a tactic in lean4 to solve the state. STATE: c z : ℂ k p : ℝ kp : autoParam (k * p ≤ 2) _auto✝ hp : autoParam (3 / 2 ≤ p) _auto✝ x : ℝ x2 : 4 ≤ x ⊢ x ^ p ≠ 0 TACTIC:
https://github.com/girving/ray.git	0be790285dd0fce78913b0cb9bddaffa94bd25f9	Ray/Dynamics/Multibrot/PotentialLower.lean	lower_anti	[56, 1]	[84, 26]	exact d.continuousOn	case hf c z : ℂ k p : ℝ hd : ∀ (x : ℝ), 4 ≤ x → HasDerivAt (fun x => 1 / x - k / x ^ p) (-(x ^ 2)⁻¹ - k * (-(p * x ^ (p - 1)) / (x ^ p) ^ 2)) x kp : k * p ≤ 2 hp : 3 / 2 ≤ p d : DifferentiableOn ℝ (fun x => 1 / x - k / x ^ p) (Ici 4) ⊢ ContinuousOn (fun x => 1 / x - k / x ^ p) (Ici 4)	no goals	Please generate a tactic in lean4 to solve the state. STATE: case hf c z : ℂ k p : ℝ hd : ∀ (x : ℝ), 4 ≤ x → HasDerivAt (fun x => 1 / x - k / x ^ p) (-(x ^ 2)⁻¹ - k * (-(p * x ^ (p - 1)) / (x ^ p) ^ 2)) x kp : k * p ≤ 2 hp : 3 / 2 ≤ p d : DifferentiableOn ℝ (fun x => 1 / x - k / x ^ p) (Ici 4) ⊢ ContinuousOn (fun x => 1 / x - k / x ^ p) (Ici 4) TACTIC:
https://github.com/girving/ray.git	0be790285dd0fce78913b0cb9bddaffa94bd25f9	Ray/Dynamics/Multibrot/PotentialLower.lean	lower_anti	[56, 1]	[84, 26]	exact d.mono interior_subset	case hf' c z : ℂ k p : ℝ hd : ∀ (x : ℝ), 4 ≤ x → HasDerivAt (fun x => 1 / x - k / x ^ p) (-(x ^ 2)⁻¹ - k * (-(p * x ^ (p - 1)) / (x ^ p) ^ 2)) x kp : k * p ≤ 2 hp : 3 / 2 ≤ p d : DifferentiableOn ℝ (fun x => 1 / x - k / x ^ p) (Ici 4) ⊢ DifferentiableOn ℝ (fun x => 1 / x - k / x ^ p) (interior (Ici 4))	no goals	Please generate a tactic in lean4 to solve the state. STATE: case hf' c z : ℂ k p : ℝ hd : ∀ (x : ℝ), 4 ≤ x → HasDerivAt (fun x => 1 / x - k / x ^ p) (-(x ^ 2)⁻¹ - k * (-(p * x ^ (p - 1)) / (x ^ p) ^ 2)) x kp : k * p ≤ 2 hp : 3 / 2 ≤ p d : DifferentiableOn ℝ (fun x => 1 / x - k / x ^ p) (Ici 4) ⊢ DifferentiableOn ℝ (fun x => 1 / x - k / x ^ p) (interior (Ici 4)) TACTIC:
https://github.com/girving/ray.git	0be790285dd0fce78913b0cb9bddaffa94bd25f9	Ray/Dynamics/Multibrot/PotentialLower.lean	lower_anti	[56, 1]	[84, 26]	intro x x4	case hf'_nonpos c z : ℂ k p : ℝ hd : ∀ (x : ℝ), 4 ≤ x → HasDerivAt (fun x => 1 / x - k / x ^ p) (-(x ^ 2)⁻¹ - k * (-(p * x ^ (p - 1)) / (x ^ p) ^ 2)) x kp : k * p ≤ 2 hp : 3 / 2 ≤ p d : DifferentiableOn ℝ (fun x => 1 / x - k / x ^ p) (Ici 4) ⊢ ∀ x ∈ interior (Ici 4), deriv (fun x => 1 / x - k / x ^ p) x ≤ 0	case hf'_nonpos c z : ℂ k p : ℝ hd : ∀ (x : ℝ), 4 ≤ x → HasDerivAt (fun x => 1 / x - k / x ^ p) (-(x ^ 2)⁻¹ - k * (-(p * x ^ (p - 1)) / (x ^ p) ^ 2)) x kp : k * p ≤ 2 hp : 3 / 2 ≤ p d : DifferentiableOn ℝ (fun x => 1 / x - k / x ^ p) (Ici 4) x : ℝ x4 : x ∈ interior (Ici 4) ⊢ deriv (fun x => 1 / x - k / x ^ p) x ≤ 0	Please generate a tactic in lean4 to solve the state. STATE: case hf'_nonpos c z : ℂ k p : ℝ hd : ∀ (x : ℝ), 4 ≤ x → HasDerivAt (fun x => 1 / x - k / x ^ p) (-(x ^ 2)⁻¹ - k * (-(p * x ^ (p - 1)) / (x ^ p) ^ 2)) x kp : k * p ≤ 2 hp : 3 / 2 ≤ p d : DifferentiableOn ℝ (fun x => 1 / x - k / x ^ p) (Ici 4) ⊢ ∀ x ∈ interior (Ici 4), deriv (fun x => 1 / x - k / x ^ p) x ≤ 0 TACTIC:
https://github.com/girving/ray.git	0be790285dd0fce78913b0cb9bddaffa94bd25f9	Ray/Dynamics/Multibrot/PotentialLower.lean	lower_anti	[56, 1]	[84, 26]	simp only [nonempty_Iio, interior_Ici', mem_Ioi] at x4	case hf'_nonpos c z : ℂ k p : ℝ hd : ∀ (x : ℝ), 4 ≤ x → HasDerivAt (fun x => 1 / x - k / x ^ p) (-(x ^ 2)⁻¹ - k * (-(p * x ^ (p - 1)) / (x ^ p) ^ 2)) x kp : k * p ≤ 2 hp : 3 / 2 ≤ p d : DifferentiableOn ℝ (fun x => 1 / x - k / x ^ p) (Ici 4) x : ℝ x4 : x ∈ interior (Ici 4) ⊢ deriv (fun x => 1 / x - k / x ^ p) x ≤ 0	case hf'_nonpos c z : ℂ k p : ℝ hd : ∀ (x : ℝ), 4 ≤ x → HasDerivAt (fun x => 1 / x - k / x ^ p) (-(x ^ 2)⁻¹ - k * (-(p * x ^ (p - 1)) / (x ^ p) ^ 2)) x kp : k * p ≤ 2 hp : 3 / 2 ≤ p d : DifferentiableOn ℝ (fun x => 1 / x - k / x ^ p) (Ici 4) x : ℝ x4 : 4 < x ⊢ deriv (fun x => 1 / x - k / x ^ p) x ≤ 0	Please generate a tactic in lean4 to solve the state. STATE: case hf'_nonpos c z : ℂ k p : ℝ hd : ∀ (x : ℝ), 4 ≤ x → HasDerivAt (fun x => 1 / x - k / x ^ p) (-(x ^ 2)⁻¹ - k * (-(p * x ^ (p - 1)) / (x ^ p) ^ 2)) x kp : k * p ≤ 2 hp : 3 / 2 ≤ p d : DifferentiableOn ℝ (fun x => 1 / x - k / x ^ p) (Ici 4) x : ℝ x4 : x ∈ interior (Ici 4) ⊢ deriv (fun x => 1 / x - k / x ^ p) x ≤ 0 TACTIC:
https://github.com/girving/ray.git	0be790285dd0fce78913b0cb9bddaffa94bd25f9	Ray/Dynamics/Multibrot/PotentialLower.lean	lower_anti	[56, 1]	[84, 26]	have x0 : 0 < x := by linarith	case hf'_nonpos c z : ℂ k p : ℝ hd : ∀ (x : ℝ), 4 ≤ x → HasDerivAt (fun x => 1 / x - k / x ^ p) (-(x ^ 2)⁻¹ - k * (-(p * x ^ (p - 1)) / (x ^ p) ^ 2)) x kp : k * p ≤ 2 hp : 3 / 2 ≤ p d : DifferentiableOn ℝ (fun x => 1 / x - k / x ^ p) (Ici 4) x : ℝ x4 : 4 < x ⊢ deriv (fun x => 1 / x - k / x ^ p) x ≤ 0	case hf'_nonpos c z : ℂ k p : ℝ hd : ∀ (x : ℝ), 4 ≤ x → HasDerivAt (fun x => 1 / x - k / x ^ p) (-(x ^ 2)⁻¹ - k * (-(p * x ^ (p - 1)) / (x ^ p) ^ 2)) x kp : k * p ≤ 2 hp : 3 / 2 ≤ p d : DifferentiableOn ℝ (fun x => 1 / x - k / x ^ p) (Ici 4) x : ℝ x4 : 4 < x x0 : 0 < x ⊢ deriv (fun x => 1 / x - k / x ^ p) x ≤ 0	Please generate a tactic in lean4 to solve the state. STATE: case hf'_nonpos c z : ℂ k p : ℝ hd : ∀ (x : ℝ), 4 ≤ x → HasDerivAt (fun x => 1 / x - k / x ^ p) (-(x ^ 2)⁻¹ - k * (-(p * x ^ (p - 1)) / (x ^ p) ^ 2)) x kp : k * p ≤ 2 hp : 3 / 2 ≤ p d : DifferentiableOn ℝ (fun x => 1 / x - k / x ^ p) (Ici 4) x : ℝ x4 : 4 < x ⊢ deriv (fun x => 1 / x - k / x ^ p) x ≤ 0 TACTIC:
https://github.com/girving/ray.git	0be790285dd0fce78913b0cb9bddaffa94bd25f9	Ray/Dynamics/Multibrot/PotentialLower.lean	lower_anti	[56, 1]	[84, 26]	simp only [(hd x x4.le).deriv]	case hf'_nonpos c z : ℂ k p : ℝ hd : ∀ (x : ℝ), 4 ≤ x → HasDerivAt (fun x => 1 / x - k / x ^ p) (-(x ^ 2)⁻¹ - k * (-(p * x ^ (p - 1)) / (x ^ p) ^ 2)) x kp : k * p ≤ 2 hp : 3 / 2 ≤ p d : DifferentiableOn ℝ (fun x => 1 / x - k / x ^ p) (Ici 4) x : ℝ x4 : 4 < x x0 : 0 < x ⊢ deriv (fun x => 1 / x - k / x ^ p) x ≤ 0	case hf'_nonpos c z : ℂ k p : ℝ hd : ∀ (x : ℝ), 4 ≤ x → HasDerivAt (fun x => 1 / x - k / x ^ p) (-(x ^ 2)⁻¹ - k * (-(p * x ^ (p - 1)) / (x ^ p) ^ 2)) x kp : k * p ≤ 2 hp : 3 / 2 ≤ p d : DifferentiableOn ℝ (fun x => 1 / x - k / x ^ p) (Ici 4) x : ℝ x4 : 4 < x x0 : 0 < x ⊢ -(x ^ 2)⁻¹ - k * (-(p * x ^ (p - 1)) / (x ^ p) ^ 2) ≤ 0	Please generate a tactic in lean4 to solve the state. STATE: case hf'_nonpos c z : ℂ k p : ℝ hd : ∀ (x : ℝ), 4 ≤ x → HasDerivAt (fun x => 1 / x - k / x ^ p) (-(x ^ 2)⁻¹ - k * (-(p * x ^ (p - 1)) / (x ^ p) ^ 2)) x kp : k * p ≤ 2 hp : 3 / 2 ≤ p d : DifferentiableOn ℝ (fun x => 1 / x - k / x ^ p) (Ici 4) x : ℝ x4 : 4 < x x0 : 0 < x ⊢ deriv (fun x => 1 / x - k / x ^ p) x ≤ 0 TACTIC:
https://github.com/girving/ray.git	0be790285dd0fce78913b0cb9bddaffa94bd25f9	Ray/Dynamics/Multibrot/PotentialLower.lean	lower_anti	[56, 1]	[84, 26]	simp only [←Real.rpow_mul x0.le, Nat.cast_ofNat, neg_div, mul_div_assoc p, ← Real.rpow_sub x0, mul_neg, ←mul_assoc k p, sub_neg_eq_add, neg_add_le_iff_le_add, add_zero, ←Real.rpow_two, ←Real.rpow_neg x0.le]	case hf'_nonpos c z : ℂ k p : ℝ hd : ∀ (x : ℝ), 4 ≤ x → HasDerivAt (fun x => 1 / x - k / x ^ p) (-(x ^ 2)⁻¹ - k * (-(p * x ^ (p - 1)) / (x ^ p) ^ 2)) x kp : k * p ≤ 2 hp : 3 / 2 ≤ p d : DifferentiableOn ℝ (fun x => 1 / x - k / x ^ p) (Ici 4) x : ℝ x4 : 4 < x x0 : 0 < x ⊢ -(x ^ 2)⁻¹ - k * (-(p * x ^ (p - 1)) / (x ^ p) ^ 2) ≤ 0	case hf'_nonpos c z : ℂ k p : ℝ hd : ∀ (x : ℝ), 4 ≤ x → HasDerivAt (fun x => 1 / x - k / x ^ p) (-(x ^ 2)⁻¹ - k * (-(p * x ^ (p - 1)) / (x ^ p) ^ 2)) x kp : k * p ≤ 2 hp : 3 / 2 ≤ p d : DifferentiableOn ℝ (fun x => 1 / x - k / x ^ p) (Ici 4) x : ℝ x4 : 4 < x x0 : 0 < x ⊢ k * p * x ^ (p - 1 - p * 2) ≤ x ^ (-2)	Please generate a tactic in lean4 to solve the state. STATE: case hf'_nonpos c z : ℂ k p : ℝ hd : ∀ (x : ℝ), 4 ≤ x → HasDerivAt (fun x => 1 / x - k / x ^ p) (-(x ^ 2)⁻¹ - k * (-(p * x ^ (p - 1)) / (x ^ p) ^ 2)) x kp : k * p ≤ 2 hp : 3 / 2 ≤ p d : DifferentiableOn ℝ (fun x => 1 / x - k / x ^ p) (Ici 4) x : ℝ x4 : 4 < x x0 : 0 < x ⊢ -(x ^ 2)⁻¹ - k * (-(p * x ^ (p - 1)) / (x ^ p) ^ 2) ≤ 0 TACTIC:
https://github.com/girving/ray.git	0be790285dd0fce78913b0cb9bddaffa94bd25f9	Ray/Dynamics/Multibrot/PotentialLower.lean	lower_anti	[56, 1]	[84, 26]	ring_nf	case hf'_nonpos c z : ℂ k p : ℝ hd : ∀ (x : ℝ), 4 ≤ x → HasDerivAt (fun x => 1 / x - k / x ^ p) (-(x ^ 2)⁻¹ - k * (-(p * x ^ (p - 1)) / (x ^ p) ^ 2)) x kp : k * p ≤ 2 hp : 3 / 2 ≤ p d : DifferentiableOn ℝ (fun x => 1 / x - k / x ^ p) (Ici 4) x : ℝ x4 : 4 < x x0 : 0 < x ⊢ k * p * x ^ (p - 1 - p * 2) ≤ x ^ (-2)	case hf'_nonpos c z : ℂ k p : ℝ hd : ∀ (x : ℝ), 4 ≤ x → HasDerivAt (fun x => 1 / x - k / x ^ p) (-(x ^ 2)⁻¹ - k * (-(p * x ^ (p - 1)) / (x ^ p) ^ 2)) x kp : k * p ≤ 2 hp : 3 / 2 ≤ p d : DifferentiableOn ℝ (fun x => 1 / x - k / x ^ p) (Ici 4) x : ℝ x4 : 4 < x x0 : 0 < x ⊢ k * p * x ^ (-1 - p) ≤ x ^ (-2)	Please generate a tactic in lean4 to solve the state. STATE: case hf'_nonpos c z : ℂ k p : ℝ hd : ∀ (x : ℝ), 4 ≤ x → HasDerivAt (fun x => 1 / x - k / x ^ p) (-(x ^ 2)⁻¹ - k * (-(p * x ^ (p - 1)) / (x ^ p) ^ 2)) x kp : k * p ≤ 2 hp : 3 / 2 ≤ p d : DifferentiableOn ℝ (fun x => 1 / x - k / x ^ p) (Ici 4) x : ℝ x4 : 4 < x x0 : 0 < x ⊢ k * p * x ^ (p - 1 - p * 2) ≤ x ^ (-2) TACTIC:
https://github.com/girving/ray.git	0be790285dd0fce78913b0cb9bddaffa94bd25f9	Ray/Dynamics/Multibrot/PotentialLower.lean	lower_anti	[56, 1]	[84, 26]	simp only [←neg_add', Real.rpow_neg x0.le (1 + p)]	case hf'_nonpos c z : ℂ k p : ℝ hd : ∀ (x : ℝ), 4 ≤ x → HasDerivAt (fun x => 1 / x - k / x ^ p) (-(x ^ 2)⁻¹ - k * (-(p * x ^ (p - 1)) / (x ^ p) ^ 2)) x kp : k * p ≤ 2 hp : 3 / 2 ≤ p d : DifferentiableOn ℝ (fun x => 1 / x - k / x ^ p) (Ici 4) x : ℝ x4 : 4 < x x0 : 0 < x ⊢ k * p * x ^ (-1 - p) ≤ x ^ (-2)	case hf'_nonpos c z : ℂ k p : ℝ hd : ∀ (x : ℝ), 4 ≤ x → HasDerivAt (fun x => 1 / x - k / x ^ p) (-(x ^ 2)⁻¹ - k * (-(p * x ^ (p - 1)) / (x ^ p) ^ 2)) x kp : k * p ≤ 2 hp : 3 / 2 ≤ p d : DifferentiableOn ℝ (fun x => 1 / x - k / x ^ p) (Ici 4) x : ℝ x4 : 4 < x x0 : 0 < x ⊢ k * p * (x ^ (1 + p))⁻¹ ≤ x ^ (-2)	Please generate a tactic in lean4 to solve the state. STATE: case hf'_nonpos c z : ℂ k p : ℝ hd : ∀ (x : ℝ), 4 ≤ x → HasDerivAt (fun x => 1 / x - k / x ^ p) (-(x ^ 2)⁻¹ - k * (-(p * x ^ (p - 1)) / (x ^ p) ^ 2)) x kp : k * p ≤ 2 hp : 3 / 2 ≤ p d : DifferentiableOn ℝ (fun x => 1 / x - k / x ^ p) (Ici 4) x : ℝ x4 : 4 < x x0 : 0 < x ⊢ k * p * x ^ (-1 - p) ≤ x ^ (-2) TACTIC:
https://github.com/girving/ray.git	0be790285dd0fce78913b0cb9bddaffa94bd25f9	Ray/Dynamics/Multibrot/PotentialLower.lean	lower_anti	[56, 1]	[84, 26]	rw [mul_inv_le_iff (by positivity), ←Real.rpow_add x0, (by ring_nf : 1 + p + -2 = p - 1)]	case hf'_nonpos c z : ℂ k p : ℝ hd : ∀ (x : ℝ), 4 ≤ x → HasDerivAt (fun x => 1 / x - k / x ^ p) (-(x ^ 2)⁻¹ - k * (-(p * x ^ (p - 1)) / (x ^ p) ^ 2)) x kp : k * p ≤ 2 hp : 3 / 2 ≤ p d : DifferentiableOn ℝ (fun x => 1 / x - k / x ^ p) (Ici 4) x : ℝ x4 : 4 < x x0 : 0 < x ⊢ k * p * (x ^ (1 + p))⁻¹ ≤ x ^ (-2)	case hf'_nonpos c z : ℂ k p : ℝ hd : ∀ (x : ℝ), 4 ≤ x → HasDerivAt (fun x => 1 / x - k / x ^ p) (-(x ^ 2)⁻¹ - k * (-(p * x ^ (p - 1)) / (x ^ p) ^ 2)) x kp : k * p ≤ 2 hp : 3 / 2 ≤ p d : DifferentiableOn ℝ (fun x => 1 / x - k / x ^ p) (Ici 4) x : ℝ x4 : 4 < x x0 : 0 < x ⊢ k * p ≤ x ^ (p - 1)	Please generate a tactic in lean4 to solve the state. STATE: case hf'_nonpos c z : ℂ k p : ℝ hd : ∀ (x : ℝ), 4 ≤ x → HasDerivAt (fun x => 1 / x - k / x ^ p) (-(x ^ 2)⁻¹ - k * (-(p * x ^ (p - 1)) / (x ^ p) ^ 2)) x kp : k * p ≤ 2 hp : 3 / 2 ≤ p d : DifferentiableOn ℝ (fun x => 1 / x - k / x ^ p) (Ici 4) x : ℝ x4 : 4 < x x0 : 0 < x ⊢ k * p * (x ^ (1 + p))⁻¹ ≤ x ^ (-2) TACTIC:
https://github.com/girving/ray.git	0be790285dd0fce78913b0cb9bddaffa94bd25f9	Ray/Dynamics/Multibrot/PotentialLower.lean	lower_anti	[56, 1]	[84, 26]	have p1' : 1/2 ≤ p - 1 := by linarith	case hf'_nonpos c z : ℂ k p : ℝ hd : ∀ (x : ℝ), 4 ≤ x → HasDerivAt (fun x => 1 / x - k / x ^ p) (-(x ^ 2)⁻¹ - k * (-(p * x ^ (p - 1)) / (x ^ p) ^ 2)) x kp : k * p ≤ 2 hp : 3 / 2 ≤ p d : DifferentiableOn ℝ (fun x => 1 / x - k / x ^ p) (Ici 4) x : ℝ x4 : 4 < x x0 : 0 < x ⊢ k * p ≤ x ^ (p - 1)	case hf'_nonpos c z : ℂ k p : ℝ hd : ∀ (x : ℝ), 4 ≤ x → HasDerivAt (fun x => 1 / x - k / x ^ p) (-(x ^ 2)⁻¹ - k * (-(p * x ^ (p - 1)) / (x ^ p) ^ 2)) x kp : k * p ≤ 2 hp : 3 / 2 ≤ p d : DifferentiableOn ℝ (fun x => 1 / x - k / x ^ p) (Ici 4) x : ℝ x4 : 4 < x x0 : 0 < x p1' : 1 / 2 ≤ p - 1 ⊢ k * p ≤ x ^ (p - 1)	Please generate a tactic in lean4 to solve the state. STATE: case hf'_nonpos c z : ℂ k p : ℝ hd : ∀ (x : ℝ), 4 ≤ x → HasDerivAt (fun x => 1 / x - k / x ^ p) (-(x ^ 2)⁻¹ - k * (-(p * x ^ (p - 1)) / (x ^ p) ^ 2)) x kp : k * p ≤ 2 hp : 3 / 2 ≤ p d : DifferentiableOn ℝ (fun x => 1 / x - k / x ^ p) (Ici 4) x : ℝ x4 : 4 < x x0 : 0 < x ⊢ k * p ≤ x ^ (p - 1) TACTIC:
https://github.com/girving/ray.git	0be790285dd0fce78913b0cb9bddaffa94bd25f9	Ray/Dynamics/Multibrot/PotentialLower.lean	lower_anti	[56, 1]	[84, 26]	refine le_trans kp (le_trans ?_ (Real.rpow_le_rpow_of_exponent_le (by linarith) p1'))	case hf'_nonpos c z : ℂ k p : ℝ hd : ∀ (x : ℝ), 4 ≤ x → HasDerivAt (fun x => 1 / x - k / x ^ p) (-(x ^ 2)⁻¹ - k * (-(p * x ^ (p - 1)) / (x ^ p) ^ 2)) x kp : k * p ≤ 2 hp : 3 / 2 ≤ p d : DifferentiableOn ℝ (fun x => 1 / x - k / x ^ p) (Ici 4) x : ℝ x4 : 4 < x x0 : 0 < x p1' : 1 / 2 ≤ p - 1 ⊢ k * p ≤ x ^ (p - 1)	case hf'_nonpos c z : ℂ k p : ℝ hd : ∀ (x : ℝ), 4 ≤ x → HasDerivAt (fun x => 1 / x - k / x ^ p) (-(x ^ 2)⁻¹ - k * (-(p * x ^ (p - 1)) / (x ^ p) ^ 2)) x kp : k * p ≤ 2 hp : 3 / 2 ≤ p d : DifferentiableOn ℝ (fun x => 1 / x - k / x ^ p) (Ici 4) x : ℝ x4 : 4 < x x0 : 0 < x p1' : 1 / 2 ≤ p - 1 ⊢ 2 ≤ x ^ (1 / 2)	Please generate a tactic in lean4 to solve the state. STATE: case hf'_nonpos c z : ℂ k p : ℝ hd : ∀ (x : ℝ), 4 ≤ x → HasDerivAt (fun x => 1 / x - k / x ^ p) (-(x ^ 2)⁻¹ - k * (-(p * x ^ (p - 1)) / (x ^ p) ^ 2)) x kp : k * p ≤ 2 hp : 3 / 2 ≤ p d : DifferentiableOn ℝ (fun x => 1 / x - k / x ^ p) (Ici 4) x : ℝ x4 : 4 < x x0 : 0 < x p1' : 1 / 2 ≤ p - 1 ⊢ k * p ≤ x ^ (p - 1) TACTIC:
https://github.com/girving/ray.git	0be790285dd0fce78913b0cb9bddaffa94bd25f9	Ray/Dynamics/Multibrot/PotentialLower.lean	lower_anti	[56, 1]	[84, 26]	rw [one_div, Real.le_rpow_inv_iff_of_pos (by norm_num) x0.le (by norm_num)]	case hf'_nonpos c z : ℂ k p : ℝ hd : ∀ (x : ℝ), 4 ≤ x → HasDerivAt (fun x => 1 / x - k / x ^ p) (-(x ^ 2)⁻¹ - k * (-(p * x ^ (p - 1)) / (x ^ p) ^ 2)) x kp : k * p ≤ 2 hp : 3 / 2 ≤ p d : DifferentiableOn ℝ (fun x => 1 / x - k / x ^ p) (Ici 4) x : ℝ x4 : 4 < x x0 : 0 < x p1' : 1 / 2 ≤ p - 1 ⊢ 2 ≤ x ^ (1 / 2)	case hf'_nonpos c z : ℂ k p : ℝ hd : ∀ (x : ℝ), 4 ≤ x → HasDerivAt (fun x => 1 / x - k / x ^ p) (-(x ^ 2)⁻¹ - k * (-(p * x ^ (p - 1)) / (x ^ p) ^ 2)) x kp : k * p ≤ 2 hp : 3 / 2 ≤ p d : DifferentiableOn ℝ (fun x => 1 / x - k / x ^ p) (Ici 4) x : ℝ x4 : 4 < x x0 : 0 < x p1' : 1 / 2 ≤ p - 1 ⊢ 2 ^ 2 ≤ x	Please generate a tactic in lean4 to solve the state. STATE: case hf'_nonpos c z : ℂ k p : ℝ hd : ∀ (x : ℝ), 4 ≤ x → HasDerivAt (fun x => 1 / x - k / x ^ p) (-(x ^ 2)⁻¹ - k * (-(p * x ^ (p - 1)) / (x ^ p) ^ 2)) x kp : k * p ≤ 2 hp : 3 / 2 ≤ p d : DifferentiableOn ℝ (fun x => 1 / x - k / x ^ p) (Ici 4) x : ℝ x4 : 4 < x x0 : 0 < x p1' : 1 / 2 ≤ p - 1 ⊢ 2 ≤ x ^ (1 / 2) TACTIC:
https://github.com/girving/ray.git	0be790285dd0fce78913b0cb9bddaffa94bd25f9	Ray/Dynamics/Multibrot/PotentialLower.lean	lower_anti	[56, 1]	[84, 26]	norm_num	case hf'_nonpos c z : ℂ k p : ℝ hd : ∀ (x : ℝ), 4 ≤ x → HasDerivAt (fun x => 1 / x - k / x ^ p) (-(x ^ 2)⁻¹ - k * (-(p * x ^ (p - 1)) / (x ^ p) ^ 2)) x kp : k * p ≤ 2 hp : 3 / 2 ≤ p d : DifferentiableOn ℝ (fun x => 1 / x - k / x ^ p) (Ici 4) x : ℝ x4 : 4 < x x0 : 0 < x p1' : 1 / 2 ≤ p - 1 ⊢ 2 ^ 2 ≤ x	case hf'_nonpos c z : ℂ k p : ℝ hd : ∀ (x : ℝ), 4 ≤ x → HasDerivAt (fun x => 1 / x - k / x ^ p) (-(x ^ 2)⁻¹ - k * (-(p * x ^ (p - 1)) / (x ^ p) ^ 2)) x kp : k * p ≤ 2 hp : 3 / 2 ≤ p d : DifferentiableOn ℝ (fun x => 1 / x - k / x ^ p) (Ici 4) x : ℝ x4 : 4 < x x0 : 0 < x p1' : 1 / 2 ≤ p - 1 ⊢ 4 ≤ x	Please generate a tactic in lean4 to solve the state. STATE: case hf'_nonpos c z : ℂ k p : ℝ hd : ∀ (x : ℝ), 4 ≤ x → HasDerivAt (fun x => 1 / x - k / x ^ p) (-(x ^ 2)⁻¹ - k * (-(p * x ^ (p - 1)) / (x ^ p) ^ 2)) x kp : k * p ≤ 2 hp : 3 / 2 ≤ p d : DifferentiableOn ℝ (fun x => 1 / x - k / x ^ p) (Ici 4) x : ℝ x4 : 4 < x x0 : 0 < x p1' : 1 / 2 ≤ p - 1 ⊢ 2 ^ 2 ≤ x TACTIC:
https://github.com/girving/ray.git	0be790285dd0fce78913b0cb9bddaffa94bd25f9	Ray/Dynamics/Multibrot/PotentialLower.lean	lower_anti	[56, 1]	[84, 26]	exact x4.le	case hf'_nonpos c z : ℂ k p : ℝ hd : ∀ (x : ℝ), 4 ≤ x → HasDerivAt (fun x => 1 / x - k / x ^ p) (-(x ^ 2)⁻¹ - k * (-(p * x ^ (p - 1)) / (x ^ p) ^ 2)) x kp : k * p ≤ 2 hp : 3 / 2 ≤ p d : DifferentiableOn ℝ (fun x => 1 / x - k / x ^ p) (Ici 4) x : ℝ x4 : 4 < x x0 : 0 < x p1' : 1 / 2 ≤ p - 1 ⊢ 4 ≤ x	no goals	Please generate a tactic in lean4 to solve the state. STATE: case hf'_nonpos c z : ℂ k p : ℝ hd : ∀ (x : ℝ), 4 ≤ x → HasDerivAt (fun x => 1 / x - k / x ^ p) (-(x ^ 2)⁻¹ - k * (-(p * x ^ (p - 1)) / (x ^ p) ^ 2)) x kp : k * p ≤ 2 hp : 3 / 2 ≤ p d : DifferentiableOn ℝ (fun x => 1 / x - k / x ^ p) (Ici 4) x : ℝ x4 : 4 < x x0 : 0 < x p1' : 1 / 2 ≤ p - 1 ⊢ 4 ≤ x TACTIC:
https://github.com/girving/ray.git	0be790285dd0fce78913b0cb9bddaffa94bd25f9	Ray/Dynamics/Multibrot/PotentialLower.lean	lower_anti	[56, 1]	[84, 26]	linarith	c z : ℂ k p : ℝ hd : ∀ (x : ℝ), 4 ≤ x → HasDerivAt (fun x => 1 / x - k / x ^ p) (-(x ^ 2)⁻¹ - k * (-(p * x ^ (p - 1)) / (x ^ p) ^ 2)) x kp : k * p ≤ 2 hp : 3 / 2 ≤ p d : DifferentiableOn ℝ (fun x => 1 / x - k / x ^ p) (Ici 4) x : ℝ x4 : 4 < x ⊢ 0 < x	no goals	Please generate a tactic in lean4 to solve the state. STATE: c z : ℂ k p : ℝ hd : ∀ (x : ℝ), 4 ≤ x → HasDerivAt (fun x => 1 / x - k / x ^ p) (-(x ^ 2)⁻¹ - k * (-(p * x ^ (p - 1)) / (x ^ p) ^ 2)) x kp : k * p ≤ 2 hp : 3 / 2 ≤ p d : DifferentiableOn ℝ (fun x => 1 / x - k / x ^ p) (Ici 4) x : ℝ x4 : 4 < x ⊢ 0 < x TACTIC:
https://github.com/girving/ray.git	0be790285dd0fce78913b0cb9bddaffa94bd25f9	Ray/Dynamics/Multibrot/PotentialLower.lean	lower_anti	[56, 1]	[84, 26]	positivity	c z : ℂ k p : ℝ hd : ∀ (x : ℝ), 4 ≤ x → HasDerivAt (fun x => 1 / x - k / x ^ p) (-(x ^ 2)⁻¹ - k * (-(p * x ^ (p - 1)) / (x ^ p) ^ 2)) x kp : k * p ≤ 2 hp : 3 / 2 ≤ p d : DifferentiableOn ℝ (fun x => 1 / x - k / x ^ p) (Ici 4) x : ℝ x4 : 4 < x x0 : 0 < x ⊢ 0 < x ^ (1 + p)	no goals	Please generate a tactic in lean4 to solve the state. STATE: c z : ℂ k p : ℝ hd : ∀ (x : ℝ), 4 ≤ x → HasDerivAt (fun x => 1 / x - k / x ^ p) (-(x ^ 2)⁻¹ - k * (-(p * x ^ (p - 1)) / (x ^ p) ^ 2)) x kp : k * p ≤ 2 hp : 3 / 2 ≤ p d : DifferentiableOn ℝ (fun x => 1 / x - k / x ^ p) (Ici 4) x : ℝ x4 : 4 < x x0 : 0 < x ⊢ 0 < x ^ (1 + p) TACTIC:
https://github.com/girving/ray.git	0be790285dd0fce78913b0cb9bddaffa94bd25f9	Ray/Dynamics/Multibrot/PotentialLower.lean	lower_anti	[56, 1]	[84, 26]	ring_nf	c z : ℂ k p : ℝ hd : ∀ (x : ℝ), 4 ≤ x → HasDerivAt (fun x => 1 / x - k / x ^ p) (-(x ^ 2)⁻¹ - k * (-(p * x ^ (p - 1)) / (x ^ p) ^ 2)) x kp : k * p ≤ 2 hp : 3 / 2 ≤ p d : DifferentiableOn ℝ (fun x => 1 / x - k / x ^ p) (Ici 4) x : ℝ x4 : 4 < x x0 : 0 < x ⊢ 1 + p + -2 = p - 1	no goals	Please generate a tactic in lean4 to solve the state. STATE: c z : ℂ k p : ℝ hd : ∀ (x : ℝ), 4 ≤ x → HasDerivAt (fun x => 1 / x - k / x ^ p) (-(x ^ 2)⁻¹ - k * (-(p * x ^ (p - 1)) / (x ^ p) ^ 2)) x kp : k * p ≤ 2 hp : 3 / 2 ≤ p d : DifferentiableOn ℝ (fun x => 1 / x - k / x ^ p) (Ici 4) x : ℝ x4 : 4 < x x0 : 0 < x ⊢ 1 + p + -2 = p - 1 TACTIC:
https://github.com/girving/ray.git	0be790285dd0fce78913b0cb9bddaffa94bd25f9	Ray/Dynamics/Multibrot/PotentialLower.lean	lower_anti	[56, 1]	[84, 26]	linarith	c z : ℂ k p : ℝ hd : ∀ (x : ℝ), 4 ≤ x → HasDerivAt (fun x => 1 / x - k / x ^ p) (-(x ^ 2)⁻¹ - k * (-(p * x ^ (p - 1)) / (x ^ p) ^ 2)) x kp : k * p ≤ 2 hp : 3 / 2 ≤ p d : DifferentiableOn ℝ (fun x => 1 / x - k / x ^ p) (Ici 4) x : ℝ x4 : 4 < x x0 : 0 < x ⊢ 1 / 2 ≤ p - 1	no goals	Please generate a tactic in lean4 to solve the state. STATE: c z : ℂ k p : ℝ hd : ∀ (x : ℝ), 4 ≤ x → HasDerivAt (fun x => 1 / x - k / x ^ p) (-(x ^ 2)⁻¹ - k * (-(p * x ^ (p - 1)) / (x ^ p) ^ 2)) x kp : k * p ≤ 2 hp : 3 / 2 ≤ p d : DifferentiableOn ℝ (fun x => 1 / x - k / x ^ p) (Ici 4) x : ℝ x4 : 4 < x x0 : 0 < x ⊢ 1 / 2 ≤ p - 1 TACTIC:
https://github.com/girving/ray.git	0be790285dd0fce78913b0cb9bddaffa94bd25f9	Ray/Dynamics/Multibrot/PotentialLower.lean	lower_anti	[56, 1]	[84, 26]	linarith	c z : ℂ k p : ℝ hd : ∀ (x : ℝ), 4 ≤ x → HasDerivAt (fun x => 1 / x - k / x ^ p) (-(x ^ 2)⁻¹ - k * (-(p * x ^ (p - 1)) / (x ^ p) ^ 2)) x kp : k * p ≤ 2 hp : 3 / 2 ≤ p d : DifferentiableOn ℝ (fun x => 1 / x - k / x ^ p) (Ici 4) x : ℝ x4 : 4 < x x0 : 0 < x p1' : 1 / 2 ≤ p - 1 ⊢ 1 ≤ x	no goals	Please generate a tactic in lean4 to solve the state. STATE: c z : ℂ k p : ℝ hd : ∀ (x : ℝ), 4 ≤ x → HasDerivAt (fun x => 1 / x - k / x ^ p) (-(x ^ 2)⁻¹ - k * (-(p * x ^ (p - 1)) / (x ^ p) ^ 2)) x kp : k * p ≤ 2 hp : 3 / 2 ≤ p d : DifferentiableOn ℝ (fun x => 1 / x - k / x ^ p) (Ici 4) x : ℝ x4 : 4 < x x0 : 0 < x p1' : 1 / 2 ≤ p - 1 ⊢ 1 ≤ x TACTIC:
https://github.com/girving/ray.git	0be790285dd0fce78913b0cb9bddaffa94bd25f9	Ray/Dynamics/Multibrot/PotentialLower.lean	lower_anti	[56, 1]	[84, 26]	norm_num	c z : ℂ k p : ℝ hd : ∀ (x : ℝ), 4 ≤ x → HasDerivAt (fun x => 1 / x - k / x ^ p) (-(x ^ 2)⁻¹ - k * (-(p * x ^ (p - 1)) / (x ^ p) ^ 2)) x kp : k * p ≤ 2 hp : 3 / 2 ≤ p d : DifferentiableOn ℝ (fun x => 1 / x - k / x ^ p) (Ici 4) x : ℝ x4 : 4 < x x0 : 0 < x p1' : 1 / 2 ≤ p - 1 ⊢ 0 ≤ 2	no goals	Please generate a tactic in lean4 to solve the state. STATE: c z : ℂ k p : ℝ hd : ∀ (x : ℝ), 4 ≤ x → HasDerivAt (fun x => 1 / x - k / x ^ p) (-(x ^ 2)⁻¹ - k * (-(p * x ^ (p - 1)) / (x ^ p) ^ 2)) x kp : k * p ≤ 2 hp : 3 / 2 ≤ p d : DifferentiableOn ℝ (fun x => 1 / x - k / x ^ p) (Ici 4) x : ℝ x4 : 4 < x x0 : 0 < x p1' : 1 / 2 ≤ p - 1 ⊢ 0 ≤ 2 TACTIC:
https://github.com/girving/ray.git	0be790285dd0fce78913b0cb9bddaffa94bd25f9	Ray/Dynamics/Multibrot/PotentialLower.lean	lower_anti	[56, 1]	[84, 26]	norm_num	c z : ℂ k p : ℝ hd : ∀ (x : ℝ), 4 ≤ x → HasDerivAt (fun x => 1 / x - k / x ^ p) (-(x ^ 2)⁻¹ - k * (-(p * x ^ (p - 1)) / (x ^ p) ^ 2)) x kp : k * p ≤ 2 hp : 3 / 2 ≤ p d : DifferentiableOn ℝ (fun x => 1 / x - k / x ^ p) (Ici 4) x : ℝ x4 : 4 < x x0 : 0 < x p1' : 1 / 2 ≤ p - 1 ⊢ 0 < 2	no goals	Please generate a tactic in lean4 to solve the state. STATE: c z : ℂ k p : ℝ hd : ∀ (x : ℝ), 4 ≤ x → HasDerivAt (fun x => 1 / x - k / x ^ p) (-(x ^ 2)⁻¹ - k * (-(p * x ^ (p - 1)) / (x ^ p) ^ 2)) x kp : k * p ≤ 2 hp : 3 / 2 ≤ p d : DifferentiableOn ℝ (fun x => 1 / x - k / x ^ p) (Ici 4) x : ℝ x4 : 4 < x x0 : 0 < x p1' : 1 / 2 ≤ p - 1 ⊢ 0 < 2 TACTIC:
https://github.com/girving/ray.git	0be790285dd0fce78913b0cb9bddaffa94bd25f9	Ray/Dynamics/Multibrot/PotentialLower.lean	le_potential	[86, 1]	[119, 13]	set s := superF 2	c z : ℂ c4 : Complex.abs c ≤ 4 z4 : Complex.abs z ≤ 4 ⊢ 0.216 ≤ ⋯.potential c ↑z	c z : ℂ c4 : Complex.abs c ≤ 4 z4 : Complex.abs z ≤ 4 s : Super (f 2) 2 OnePoint.infty := superF 2 ⊢ 0.216 ≤ s.potential c ↑z	Please generate a tactic in lean4 to solve the state. STATE: c z : ℂ c4 : Complex.abs c ≤ 4 z4 : Complex.abs z ≤ 4 ⊢ 0.216 ≤ ⋯.potential c ↑z TACTIC:
https://github.com/girving/ray.git	0be790285dd0fce78913b0cb9bddaffa94bd25f9	Ray/Dynamics/Multibrot/PotentialLower.lean	le_potential	[86, 1]	[119, 13]	by_cases m : (c,↑z) ∈ s.basin	c z : ℂ c4 : Complex.abs c ≤ 4 z4 : Complex.abs z ≤ 4 s : Super (f 2) 2 OnePoint.infty := superF 2 ⊢ 0.216 ≤ s.potential c ↑z	case pos c z : ℂ c4 : Complex.abs c ≤ 4 z4 : Complex.abs z ≤ 4 s : Super (f 2) 2 OnePoint.infty := superF 2 m : (c, ↑z) ∈ s.basin ⊢ 0.216 ≤ s.potential c ↑z case neg c z : ℂ c4 : Complex.abs c ≤ 4 z4 : Complex.abs z ≤ 4 s : Super (f 2) 2 OnePoint.infty := superF 2 m : (c, ↑z) ∉ s.basin ⊢ 0.216 ≤ s.potential c ↑z	Please generate a tactic in lean4 to solve the state. STATE: c z : ℂ c4 : Complex.abs c ≤ 4 z4 : Complex.abs z ≤ 4 s : Super (f 2) 2 OnePoint.infty := superF 2 ⊢ 0.216 ≤ s.potential c ↑z TACTIC:
https://github.com/girving/ray.git	0be790285dd0fce78913b0cb9bddaffa94bd25f9	Ray/Dynamics/Multibrot/PotentialLower.lean	le_potential	[86, 1]	[119, 13]	rcases pass_through c4 z4 m with ⟨n,w4,w20⟩	case pos c z : ℂ c4 : Complex.abs c ≤ 4 z4 : Complex.abs z ≤ 4 s : Super (f 2) 2 OnePoint.infty := superF 2 m : (c, ↑z) ∈ s.basin ⊢ 0.216 ≤ s.potential c ↑z	case pos.intro.intro c z : ℂ c4 : Complex.abs c ≤ 4 z4 : Complex.abs z ≤ 4 s : Super (f 2) 2 OnePoint.infty := superF 2 m : (c, ↑z) ∈ s.basin n : ℕ w4 : 4 < Complex.abs ((f' 2 c)^[n + 1] z) w20 : Complex.abs ((f' 2 c)^[n + 1] z) ≤ 20 ⊢ 0.216 ≤ s.potential c ↑z	Please generate a tactic in lean4 to solve the state. STATE: case pos c z : ℂ c4 : Complex.abs c ≤ 4 z4 : Complex.abs z ≤ 4 s : Super (f 2) 2 OnePoint.infty := superF 2 m : (c, ↑z) ∈ s.basin ⊢ 0.216 ≤ s.potential c ↑z TACTIC:
https://github.com/girving/ray.git	0be790285dd0fce78913b0cb9bddaffa94bd25f9	Ray/Dynamics/Multibrot/PotentialLower.lean	le_potential	[86, 1]	[119, 13]	generalize hw : (f' 2 c)^[n+1] z = w at w4 w20	case pos.intro.intro c z : ℂ c4 : Complex.abs c ≤ 4 z4 : Complex.abs z ≤ 4 s : Super (f 2) 2 OnePoint.infty := superF 2 m : (c, ↑z) ∈ s.basin n : ℕ w4 : 4 < Complex.abs ((f' 2 c)^[n + 1] z) w20 : Complex.abs ((f' 2 c)^[n + 1] z) ≤ 20 ⊢ 0.216 ≤ s.potential c ↑z	case pos.intro.intro c z : ℂ c4 : Complex.abs c ≤ 4 z4 : Complex.abs z ≤ 4 s : Super (f 2) 2 OnePoint.infty := superF 2 m : (c, ↑z) ∈ s.basin n : ℕ w : ℂ hw : (f' 2 c)^[n + 1] z = w w4 : 4 < Complex.abs w w20 : Complex.abs w ≤ 20 ⊢ 0.216 ≤ s.potential c ↑z	Please generate a tactic in lean4 to solve the state. STATE: case pos.intro.intro c z : ℂ c4 : Complex.abs c ≤ 4 z4 : Complex.abs z ≤ 4 s : Super (f 2) 2 OnePoint.infty := superF 2 m : (c, ↑z) ∈ s.basin n : ℕ w4 : 4 < Complex.abs ((f' 2 c)^[n + 1] z) w20 : Complex.abs ((f' 2 c)^[n + 1] z) ≤ 20 ⊢ 0.216 ≤ s.potential c ↑z TACTIC:
https://github.com/girving/ray.git	0be790285dd0fce78913b0cb9bddaffa94bd25f9	Ray/Dynamics/Multibrot/PotentialLower.lean	le_potential	[86, 1]	[119, 13]	have cw : abs c ≤ abs w := by linarith	case pos.intro.intro c z : ℂ c4 : Complex.abs c ≤ 4 z4 : Complex.abs z ≤ 4 s : Super (f 2) 2 OnePoint.infty := superF 2 m : (c, ↑z) ∈ s.basin n : ℕ w : ℂ hw : (f' 2 c)^[n + 1] z = w w4 : 4 < Complex.abs w w20 : Complex.abs w ≤ 20 ⊢ 0.216 ≤ s.potential c ↑z	case pos.intro.intro c z : ℂ c4 : Complex.abs c ≤ 4 z4 : Complex.abs z ≤ 4 s : Super (f 2) 2 OnePoint.infty := superF 2 m : (c, ↑z) ∈ s.basin n : ℕ w : ℂ hw : (f' 2 c)^[n + 1] z = w w4 : 4 < Complex.abs w w20 : Complex.abs w ≤ 20 cw : Complex.abs c ≤ Complex.abs w ⊢ 0.216 ≤ s.potential c ↑z	Please generate a tactic in lean4 to solve the state. STATE: case pos.intro.intro c z : ℂ c4 : Complex.abs c ≤ 4 z4 : Complex.abs z ≤ 4 s : Super (f 2) 2 OnePoint.infty := superF 2 m : (c, ↑z) ∈ s.basin n : ℕ w : ℂ hw : (f' 2 c)^[n + 1] z = w w4 : 4 < Complex.abs w w20 : Complex.abs w ≤ 20 ⊢ 0.216 ≤ s.potential c ↑z TACTIC:
https://github.com/girving/ray.git	0be790285dd0fce78913b0cb9bddaffa94bd25f9	Ray/Dynamics/Multibrot/PotentialLower.lean	le_potential	[86, 1]	[119, 13]	have pw : 0.0469 ≤ s.potential c w := by have pw := (abs_le.mp (le_trans (potential_approx 2 w4.le cw) (potential_error_le_of_z4 2 w4.le cw))).1 rw [le_sub_iff_add_le, neg_add_eq_sub] at pw have anti := lower_anti 0.8095 1.864 (by norm_num) (by norm_num) (a := abs w) (b := 20) w4.le (by norm_num) w20 refine le_trans ?_ (le_trans anti pw) norm_num have le : (266 : ℝ) ≤ 20 ^ (233 / 125 : ℝ) := by rw [div_eq_mul_inv, Real.rpow_mul (by positivity), Real.le_rpow_inv_iff_of_pos (by norm_num) (by positivity) (by positivity)] norm_num exact le_trans (by norm_num) (sub_le_sub_left (div_le_div_of_nonneg_left (by norm_num) (by norm_num) le) _)	case pos.intro.intro c z : ℂ c4 : Complex.abs c ≤ 4 z4 : Complex.abs z ≤ 4 s : Super (f 2) 2 OnePoint.infty := superF 2 m : (c, ↑z) ∈ s.basin n : ℕ w : ℂ hw : (f' 2 c)^[n + 1] z = w w4 : 4 < Complex.abs w w20 : Complex.abs w ≤ 20 cw : Complex.abs c ≤ Complex.abs w ⊢ 0.216 ≤ s.potential c ↑z	case pos.intro.intro c z : ℂ c4 : Complex.abs c ≤ 4 z4 : Complex.abs z ≤ 4 s : Super (f 2) 2 OnePoint.infty := superF 2 m : (c, ↑z) ∈ s.basin n : ℕ w : ℂ hw : (f' 2 c)^[n + 1] z = w w4 : 4 < Complex.abs w w20 : Complex.abs w ≤ 20 cw : Complex.abs c ≤ Complex.abs w pw : 469e-4 ≤ s.potential c ↑w ⊢ 0.216 ≤ s.potential c ↑z	Please generate a tactic in lean4 to solve the state. STATE: case pos.intro.intro c z : ℂ c4 : Complex.abs c ≤ 4 z4 : Complex.abs z ≤ 4 s : Super (f 2) 2 OnePoint.infty := superF 2 m : (c, ↑z) ∈ s.basin n : ℕ w : ℂ hw : (f' 2 c)^[n + 1] z = w w4 : 4 < Complex.abs w w20 : Complex.abs w ≤ 20 cw : Complex.abs c ≤ Complex.abs w ⊢ 0.216 ≤ s.potential c ↑z TACTIC:
https://github.com/girving/ray.git	0be790285dd0fce78913b0cb9bddaffa94bd25f9	Ray/Dynamics/Multibrot/PotentialLower.lean	le_potential	[86, 1]	[119, 13]	have pwz : s.potential c w = s.potential c z ^ 2^(n+1) := by simp only [←hw, ←f_f'_iter, s.potential_eqn_iter]	case pos.intro.intro c z : ℂ c4 : Complex.abs c ≤ 4 z4 : Complex.abs z ≤ 4 s : Super (f 2) 2 OnePoint.infty := superF 2 m : (c, ↑z) ∈ s.basin n : ℕ w : ℂ hw : (f' 2 c)^[n + 1] z = w w4 : 4 < Complex.abs w w20 : Complex.abs w ≤ 20 cw : Complex.abs c ≤ Complex.abs w pw : 469e-4 ≤ s.potential c ↑w ⊢ 0.216 ≤ s.potential c ↑z	case pos.intro.intro c z : ℂ c4 : Complex.abs c ≤ 4 z4 : Complex.abs z ≤ 4 s : Super (f 2) 2 OnePoint.infty := superF 2 m : (c, ↑z) ∈ s.basin n : ℕ w : ℂ hw : (f' 2 c)^[n + 1] z = w w4 : 4 < Complex.abs w w20 : Complex.abs w ≤ 20 cw : Complex.abs c ≤ Complex.abs w pw : 469e-4 ≤ s.potential c ↑w pwz : s.potential c ↑w = s.potential c ↑z ^ 2 ^ (n + 1) ⊢ 0.216 ≤ s.potential c ↑z	Please generate a tactic in lean4 to solve the state. STATE: case pos.intro.intro c z : ℂ c4 : Complex.abs c ≤ 4 z4 : Complex.abs z ≤ 4 s : Super (f 2) 2 OnePoint.infty := superF 2 m : (c, ↑z) ∈ s.basin n : ℕ w : ℂ hw : (f' 2 c)^[n + 1] z = w w4 : 4 < Complex.abs w w20 : Complex.abs w ≤ 20 cw : Complex.abs c ≤ Complex.abs w pw : 469e-4 ≤ s.potential c ↑w ⊢ 0.216 ≤ s.potential c ↑z TACTIC:
https://github.com/girving/ray.git	0be790285dd0fce78913b0cb9bddaffa94bd25f9	Ray/Dynamics/Multibrot/PotentialLower.lean	le_potential	[86, 1]	[119, 13]	rw [←Real.rpow_natCast] at pwz	case pos.intro.intro c z : ℂ c4 : Complex.abs c ≤ 4 z4 : Complex.abs z ≤ 4 s : Super (f 2) 2 OnePoint.infty := superF 2 m : (c, ↑z) ∈ s.basin n : ℕ w : ℂ hw : (f' 2 c)^[n + 1] z = w w4 : 4 < Complex.abs w w20 : Complex.abs w ≤ 20 cw : Complex.abs c ≤ Complex.abs w pw : 469e-4 ≤ s.potential c ↑w pwz : s.potential c ↑w = s.potential c ↑z ^ 2 ^ (n + 1) ⊢ 0.216 ≤ s.potential c ↑z	case pos.intro.intro c z : ℂ c4 : Complex.abs c ≤ 4 z4 : Complex.abs z ≤ 4 s : Super (f 2) 2 OnePoint.infty := superF 2 m : (c, ↑z) ∈ s.basin n : ℕ w : ℂ hw : (f' 2 c)^[n + 1] z = w w4 : 4 < Complex.abs w w20 : Complex.abs w ≤ 20 cw : Complex.abs c ≤ Complex.abs w pw : 469e-4 ≤ s.potential c ↑w pwz : s.potential c ↑w = s.potential c ↑z ^ ↑(2 ^ (n + 1)) ⊢ 0.216 ≤ s.potential c ↑z	Please generate a tactic in lean4 to solve the state. STATE: case pos.intro.intro c z : ℂ c4 : Complex.abs c ≤ 4 z4 : Complex.abs z ≤ 4 s : Super (f 2) 2 OnePoint.infty := superF 2 m : (c, ↑z) ∈ s.basin n : ℕ w : ℂ hw : (f' 2 c)^[n + 1] z = w w4 : 4 < Complex.abs w w20 : Complex.abs w ≤ 20 cw : Complex.abs c ≤ Complex.abs w pw : 469e-4 ≤ s.potential c ↑w pwz : s.potential c ↑w = s.potential c ↑z ^ 2 ^ (n + 1) ⊢ 0.216 ≤ s.potential c ↑z TACTIC:
https://github.com/girving/ray.git	0be790285dd0fce78913b0cb9bddaffa94bd25f9	Ray/Dynamics/Multibrot/PotentialLower.lean	le_potential	[86, 1]	[119, 13]	rw [←Real.rpow_inv_eq s.potential_nonneg s.potential_nonneg (NeZero.natCast_ne (2^(n+1)) ℝ)] at pwz	case pos.intro.intro c z : ℂ c4 : Complex.abs c ≤ 4 z4 : Complex.abs z ≤ 4 s : Super (f 2) 2 OnePoint.infty := superF 2 m : (c, ↑z) ∈ s.basin n : ℕ w : ℂ hw : (f' 2 c)^[n + 1] z = w w4 : 4 < Complex.abs w w20 : Complex.abs w ≤ 20 cw : Complex.abs c ≤ Complex.abs w pw : 469e-4 ≤ s.potential c ↑w pwz : s.potential c ↑w = s.potential c ↑z ^ ↑(2 ^ (n + 1)) ⊢ 0.216 ≤ s.potential c ↑z	case pos.intro.intro c z : ℂ c4 : Complex.abs c ≤ 4 z4 : Complex.abs z ≤ 4 s : Super (f 2) 2 OnePoint.infty := superF 2 m : (c, ↑z) ∈ s.basin n : ℕ w : ℂ hw : (f' 2 c)^[n + 1] z = w w4 : 4 < Complex.abs w w20 : Complex.abs w ≤ 20 cw : Complex.abs c ≤ Complex.abs w pw : 469e-4 ≤ s.potential c ↑w pwz : s.potential c ↑w ^ (↑(2 ^ (n + 1)))⁻¹ = s.potential c ↑z ⊢ 0.216 ≤ s.potential c ↑z	Please generate a tactic in lean4 to solve the state. STATE: case pos.intro.intro c z : ℂ c4 : Complex.abs c ≤ 4 z4 : Complex.abs z ≤ 4 s : Super (f 2) 2 OnePoint.infty := superF 2 m : (c, ↑z) ∈ s.basin n : ℕ w : ℂ hw : (f' 2 c)^[n + 1] z = w w4 : 4 < Complex.abs w w20 : Complex.abs w ≤ 20 cw : Complex.abs c ≤ Complex.abs w pw : 469e-4 ≤ s.potential c ↑w pwz : s.potential c ↑w = s.potential c ↑z ^ ↑(2 ^ (n + 1)) ⊢ 0.216 ≤ s.potential c ↑z TACTIC:
https://github.com/girving/ray.git	0be790285dd0fce78913b0cb9bddaffa94bd25f9	Ray/Dynamics/Multibrot/PotentialLower.lean	le_potential	[86, 1]	[119, 13]	rw [←pwz]	case pos.intro.intro c z : ℂ c4 : Complex.abs c ≤ 4 z4 : Complex.abs z ≤ 4 s : Super (f 2) 2 OnePoint.infty := superF 2 m : (c, ↑z) ∈ s.basin n : ℕ w : ℂ hw : (f' 2 c)^[n + 1] z = w w4 : 4 < Complex.abs w w20 : Complex.abs w ≤ 20 cw : Complex.abs c ≤ Complex.abs w pw : 469e-4 ≤ s.potential c ↑w pwz : s.potential c ↑w ^ (↑(2 ^ (n + 1)))⁻¹ = s.potential c ↑z ⊢ 0.216 ≤ s.potential c ↑z	case pos.intro.intro c z : ℂ c4 : Complex.abs c ≤ 4 z4 : Complex.abs z ≤ 4 s : Super (f 2) 2 OnePoint.infty := superF 2 m : (c, ↑z) ∈ s.basin n : ℕ w : ℂ hw : (f' 2 c)^[n + 1] z = w w4 : 4 < Complex.abs w w20 : Complex.abs w ≤ 20 cw : Complex.abs c ≤ Complex.abs w pw : 469e-4 ≤ s.potential c ↑w pwz : s.potential c ↑w ^ (↑(2 ^ (n + 1)))⁻¹ = s.potential c ↑z ⊢ 0.216 ≤ s.potential c ↑w ^ (↑(2 ^ (n + 1)))⁻¹	Please generate a tactic in lean4 to solve the state. STATE: case pos.intro.intro c z : ℂ c4 : Complex.abs c ≤ 4 z4 : Complex.abs z ≤ 4 s : Super (f 2) 2 OnePoint.infty := superF 2 m : (c, ↑z) ∈ s.basin n : ℕ w : ℂ hw : (f' 2 c)^[n + 1] z = w w4 : 4 < Complex.abs w w20 : Complex.abs w ≤ 20 cw : Complex.abs c ≤ Complex.abs w pw : 469e-4 ≤ s.potential c ↑w pwz : s.potential c ↑w ^ (↑(2 ^ (n + 1)))⁻¹ = s.potential c ↑z ⊢ 0.216 ≤ s.potential c ↑z TACTIC:
https://github.com/girving/ray.git	0be790285dd0fce78913b0cb9bddaffa94bd25f9	Ray/Dynamics/Multibrot/PotentialLower.lean	le_potential	[86, 1]	[119, 13]	refine le_trans ?_ (Real.rpow_le_rpow (by norm_num) pw (by positivity))	case pos.intro.intro c z : ℂ c4 : Complex.abs c ≤ 4 z4 : Complex.abs z ≤ 4 s : Super (f 2) 2 OnePoint.infty := superF 2 m : (c, ↑z) ∈ s.basin n : ℕ w : ℂ hw : (f' 2 c)^[n + 1] z = w w4 : 4 < Complex.abs w w20 : Complex.abs w ≤ 20 cw : Complex.abs c ≤ Complex.abs w pw : 469e-4 ≤ s.potential c ↑w pwz : s.potential c ↑w ^ (↑(2 ^ (n + 1)))⁻¹ = s.potential c ↑z ⊢ 0.216 ≤ s.potential c ↑w ^ (↑(2 ^ (n + 1)))⁻¹	case pos.intro.intro c z : ℂ c4 : Complex.abs c ≤ 4 z4 : Complex.abs z ≤ 4 s : Super (f 2) 2 OnePoint.infty := superF 2 m : (c, ↑z) ∈ s.basin n : ℕ w : ℂ hw : (f' 2 c)^[n + 1] z = w w4 : 4 < Complex.abs w w20 : Complex.abs w ≤ 20 cw : Complex.abs c ≤ Complex.abs w pw : 469e-4 ≤ s.potential c ↑w pwz : s.potential c ↑w ^ (↑(2 ^ (n + 1)))⁻¹ = s.potential c ↑z ⊢ 0.216 ≤ 469e-4 ^ (↑(2 ^ (n + 1)))⁻¹	Please generate a tactic in lean4 to solve the state. STATE: case pos.intro.intro c z : ℂ c4 : Complex.abs c ≤ 4 z4 : Complex.abs z ≤ 4 s : Super (f 2) 2 OnePoint.infty := superF 2 m : (c, ↑z) ∈ s.basin n : ℕ w : ℂ hw : (f' 2 c)^[n + 1] z = w w4 : 4 < Complex.abs w w20 : Complex.abs w ≤ 20 cw : Complex.abs c ≤ Complex.abs w pw : 469e-4 ≤ s.potential c ↑w pwz : s.potential c ↑w ^ (↑(2 ^ (n + 1)))⁻¹ = s.potential c ↑z ⊢ 0.216 ≤ s.potential c ↑w ^ (↑(2 ^ (n + 1)))⁻¹ TACTIC:
https://github.com/girving/ray.git	0be790285dd0fce78913b0cb9bddaffa94bd25f9	Ray/Dynamics/Multibrot/PotentialLower.lean	le_potential	[86, 1]	[119, 13]	rw [Real.le_rpow_inv_iff_of_pos (by norm_num) (by norm_num) (by positivity), Real.rpow_natCast]	case pos.intro.intro c z : ℂ c4 : Complex.abs c ≤ 4 z4 : Complex.abs z ≤ 4 s : Super (f 2) 2 OnePoint.infty := superF 2 m : (c, ↑z) ∈ s.basin n : ℕ w : ℂ hw : (f' 2 c)^[n + 1] z = w w4 : 4 < Complex.abs w w20 : Complex.abs w ≤ 20 cw : Complex.abs c ≤ Complex.abs w pw : 469e-4 ≤ s.potential c ↑w pwz : s.potential c ↑w ^ (↑(2 ^ (n + 1)))⁻¹ = s.potential c ↑z ⊢ 0.216 ≤ 469e-4 ^ (↑(2 ^ (n + 1)))⁻¹	case pos.intro.intro c z : ℂ c4 : Complex.abs c ≤ 4 z4 : Complex.abs z ≤ 4 s : Super (f 2) 2 OnePoint.infty := superF 2 m : (c, ↑z) ∈ s.basin n : ℕ w : ℂ hw : (f' 2 c)^[n + 1] z = w w4 : 4 < Complex.abs w w20 : Complex.abs w ≤ 20 cw : Complex.abs c ≤ Complex.abs w pw : 469e-4 ≤ s.potential c ↑w pwz : s.potential c ↑w ^ (↑(2 ^ (n + 1)))⁻¹ = s.potential c ↑z ⊢ 0.216 ^ 2 ^ (n + 1) ≤ 469e-4	Please generate a tactic in lean4 to solve the state. STATE: case pos.intro.intro c z : ℂ c4 : Complex.abs c ≤ 4 z4 : Complex.abs z ≤ 4 s : Super (f 2) 2 OnePoint.infty := superF 2 m : (c, ↑z) ∈ s.basin n : ℕ w : ℂ hw : (f' 2 c)^[n + 1] z = w w4 : 4 < Complex.abs w w20 : Complex.abs w ≤ 20 cw : Complex.abs c ≤ Complex.abs w pw : 469e-4 ≤ s.potential c ↑w pwz : s.potential c ↑w ^ (↑(2 ^ (n + 1)))⁻¹ = s.potential c ↑z ⊢ 0.216 ≤ 469e-4 ^ (↑(2 ^ (n + 1)))⁻¹ TACTIC:
https://github.com/girving/ray.git	0be790285dd0fce78913b0cb9bddaffa94bd25f9	Ray/Dynamics/Multibrot/PotentialLower.lean	le_potential	[86, 1]	[119, 13]	refine le_trans (pow_le_pow_of_le_one (by norm_num) (by norm_num) (pow_le_pow_right (by norm_num) (Nat.le_add_left 1 n))) ?_	case pos.intro.intro c z : ℂ c4 : Complex.abs c ≤ 4 z4 : Complex.abs z ≤ 4 s : Super (f 2) 2 OnePoint.infty := superF 2 m : (c, ↑z) ∈ s.basin n : ℕ w : ℂ hw : (f' 2 c)^[n + 1] z = w w4 : 4 < Complex.abs w w20 : Complex.abs w ≤ 20 cw : Complex.abs c ≤ Complex.abs w pw : 469e-4 ≤ s.potential c ↑w pwz : s.potential c ↑w ^ (↑(2 ^ (n + 1)))⁻¹ = s.potential c ↑z ⊢ 0.216 ^ 2 ^ (n + 1) ≤ 469e-4	case pos.intro.intro c z : ℂ c4 : Complex.abs c ≤ 4 z4 : Complex.abs z ≤ 4 s : Super (f 2) 2 OnePoint.infty := superF 2 m : (c, ↑z) ∈ s.basin n : ℕ w : ℂ hw : (f' 2 c)^[n + 1] z = w w4 : 4 < Complex.abs w w20 : Complex.abs w ≤ 20 cw : Complex.abs c ≤ Complex.abs w pw : 469e-4 ≤ s.potential c ↑w pwz : s.potential c ↑w ^ (↑(2 ^ (n + 1)))⁻¹ = s.potential c ↑z ⊢ 0.216 ^ 2 ^ 1 ≤ 469e-4	Please generate a tactic in lean4 to solve the state. STATE: case pos.intro.intro c z : ℂ c4 : Complex.abs c ≤ 4 z4 : Complex.abs z ≤ 4 s : Super (f 2) 2 OnePoint.infty := superF 2 m : (c, ↑z) ∈ s.basin n : ℕ w : ℂ hw : (f' 2 c)^[n + 1] z = w w4 : 4 < Complex.abs w w20 : Complex.abs w ≤ 20 cw : Complex.abs c ≤ Complex.abs w pw : 469e-4 ≤ s.potential c ↑w pwz : s.potential c ↑w ^ (↑(2 ^ (n + 1)))⁻¹ = s.potential c ↑z ⊢ 0.216 ^ 2 ^ (n + 1) ≤ 469e-4 TACTIC:
https://github.com/girving/ray.git	0be790285dd0fce78913b0cb9bddaffa94bd25f9	Ray/Dynamics/Multibrot/PotentialLower.lean	le_potential	[86, 1]	[119, 13]	norm_num	case pos.intro.intro c z : ℂ c4 : Complex.abs c ≤ 4 z4 : Complex.abs z ≤ 4 s : Super (f 2) 2 OnePoint.infty := superF 2 m : (c, ↑z) ∈ s.basin n : ℕ w : ℂ hw : (f' 2 c)^[n + 1] z = w w4 : 4 < Complex.abs w w20 : Complex.abs w ≤ 20 cw : Complex.abs c ≤ Complex.abs w pw : 469e-4 ≤ s.potential c ↑w pwz : s.potential c ↑w ^ (↑(2 ^ (n + 1)))⁻¹ = s.potential c ↑z ⊢ 0.216 ^ 2 ^ 1 ≤ 469e-4	no goals	Please generate a tactic in lean4 to solve the state. STATE: case pos.intro.intro c z : ℂ c4 : Complex.abs c ≤ 4 z4 : Complex.abs z ≤ 4 s : Super (f 2) 2 OnePoint.infty := superF 2 m : (c, ↑z) ∈ s.basin n : ℕ w : ℂ hw : (f' 2 c)^[n + 1] z = w w4 : 4 < Complex.abs w w20 : Complex.abs w ≤ 20 cw : Complex.abs c ≤ Complex.abs w pw : 469e-4 ≤ s.potential c ↑w pwz : s.potential c ↑w ^ (↑(2 ^ (n + 1)))⁻¹ = s.potential c ↑z ⊢ 0.216 ^ 2 ^ 1 ≤ 469e-4 TACTIC:
https://github.com/girving/ray.git	0be790285dd0fce78913b0cb9bddaffa94bd25f9	Ray/Dynamics/Multibrot/PotentialLower.lean	le_potential	[86, 1]	[119, 13]	linarith	c z : ℂ c4 : Complex.abs c ≤ 4 z4 : Complex.abs z ≤ 4 s : Super (f 2) 2 OnePoint.infty := superF 2 m : (c, ↑z) ∈ s.basin n : ℕ w : ℂ hw : (f' 2 c)^[n + 1] z = w w4 : 4 < Complex.abs w w20 : Complex.abs w ≤ 20 ⊢ Complex.abs c ≤ Complex.abs w	no goals	Please generate a tactic in lean4 to solve the state. STATE: c z : ℂ c4 : Complex.abs c ≤ 4 z4 : Complex.abs z ≤ 4 s : Super (f 2) 2 OnePoint.infty := superF 2 m : (c, ↑z) ∈ s.basin n : ℕ w : ℂ hw : (f' 2 c)^[n + 1] z = w w4 : 4 < Complex.abs w w20 : Complex.abs w ≤ 20 ⊢ Complex.abs c ≤ Complex.abs w TACTIC:
https://github.com/girving/ray.git	0be790285dd0fce78913b0cb9bddaffa94bd25f9	Ray/Dynamics/Multibrot/PotentialLower.lean	le_potential	[86, 1]	[119, 13]	have pw := (abs_le.mp (le_trans (potential_approx 2 w4.le cw) (potential_error_le_of_z4 2 w4.le cw))).1	c z : ℂ c4 : Complex.abs c ≤ 4 z4 : Complex.abs z ≤ 4 s : Super (f 2) 2 OnePoint.infty := superF 2 m : (c, ↑z) ∈ s.basin n : ℕ w : ℂ hw : (f' 2 c)^[n + 1] z = w w4 : 4 < Complex.abs w w20 : Complex.abs w ≤ 20 cw : Complex.abs c ≤ Complex.abs w ⊢ 469e-4 ≤ s.potential c ↑w	c z : ℂ c4 : Complex.abs c ≤ 4 z4 : Complex.abs z ≤ 4 s : Super (f 2) 2 OnePoint.infty := superF 2 m : (c, ↑z) ∈ s.basin n : ℕ w : ℂ hw : (f' 2 c)^[n + 1] z = w w4 : 4 < Complex.abs w w20 : Complex.abs w ≤ 20 cw : Complex.abs c ≤ Complex.abs w pw : -(0.8095 / Complex.abs w ^ 1.864) ≤ ⋯.potential c ↑w - 1 / Complex.abs w ⊢ 469e-4 ≤ s.potential c ↑w	Please generate a tactic in lean4 to solve the state. STATE: c z : ℂ c4 : Complex.abs c ≤ 4 z4 : Complex.abs z ≤ 4 s : Super (f 2) 2 OnePoint.infty := superF 2 m : (c, ↑z) ∈ s.basin n : ℕ w : ℂ hw : (f' 2 c)^[n + 1] z = w w4 : 4 < Complex.abs w w20 : Complex.abs w ≤ 20 cw : Complex.abs c ≤ Complex.abs w ⊢ 469e-4 ≤ s.potential c ↑w TACTIC:
https://github.com/girving/ray.git	0be790285dd0fce78913b0cb9bddaffa94bd25f9	Ray/Dynamics/Multibrot/PotentialLower.lean	le_potential	[86, 1]	[119, 13]	rw [le_sub_iff_add_le, neg_add_eq_sub] at pw	c z : ℂ c4 : Complex.abs c ≤ 4 z4 : Complex.abs z ≤ 4 s : Super (f 2) 2 OnePoint.infty := superF 2 m : (c, ↑z) ∈ s.basin n : ℕ w : ℂ hw : (f' 2 c)^[n + 1] z = w w4 : 4 < Complex.abs w w20 : Complex.abs w ≤ 20 cw : Complex.abs c ≤ Complex.abs w pw : -(0.8095 / Complex.abs w ^ 1.864) ≤ ⋯.potential c ↑w - 1 / Complex.abs w ⊢ 469e-4 ≤ s.potential c ↑w	c z : ℂ c4 : Complex.abs c ≤ 4 z4 : Complex.abs z ≤ 4 s : Super (f 2) 2 OnePoint.infty := superF 2 m : (c, ↑z) ∈ s.basin n : ℕ w : ℂ hw : (f' 2 c)^[n + 1] z = w w4 : 4 < Complex.abs w w20 : Complex.abs w ≤ 20 cw : Complex.abs c ≤ Complex.abs w pw : 1 / Complex.abs w - 0.8095 / Complex.abs w ^ 1.864 ≤ ⋯.potential c ↑w ⊢ 469e-4 ≤ s.potential c ↑w	Please generate a tactic in lean4 to solve the state. STATE: c z : ℂ c4 : Complex.abs c ≤ 4 z4 : Complex.abs z ≤ 4 s : Super (f 2) 2 OnePoint.infty := superF 2 m : (c, ↑z) ∈ s.basin n : ℕ w : ℂ hw : (f' 2 c)^[n + 1] z = w w4 : 4 < Complex.abs w w20 : Complex.abs w ≤ 20 cw : Complex.abs c ≤ Complex.abs w pw : -(0.8095 / Complex.abs w ^ 1.864) ≤ ⋯.potential c ↑w - 1 / Complex.abs w ⊢ 469e-4 ≤ s.potential c ↑w TACTIC:
https://github.com/girving/ray.git	0be790285dd0fce78913b0cb9bddaffa94bd25f9	Ray/Dynamics/Multibrot/PotentialLower.lean	le_potential	[86, 1]	[119, 13]	have anti := lower_anti 0.8095 1.864 (by norm_num) (by norm_num) (a := abs w) (b := 20) w4.le (by norm_num) w20	c z : ℂ c4 : Complex.abs c ≤ 4 z4 : Complex.abs z ≤ 4 s : Super (f 2) 2 OnePoint.infty := superF 2 m : (c, ↑z) ∈ s.basin n : ℕ w : ℂ hw : (f' 2 c)^[n + 1] z = w w4 : 4 < Complex.abs w w20 : Complex.abs w ≤ 20 cw : Complex.abs c ≤ Complex.abs w pw : 1 / Complex.abs w - 0.8095 / Complex.abs w ^ 1.864 ≤ ⋯.potential c ↑w ⊢ 469e-4 ≤ s.potential c ↑w	c z : ℂ c4 : Complex.abs c ≤ 4 z4 : Complex.abs z ≤ 4 s : Super (f 2) 2 OnePoint.infty := superF 2 m : (c, ↑z) ∈ s.basin n : ℕ w : ℂ hw : (f' 2 c)^[n + 1] z = w w4 : 4 < Complex.abs w w20 : Complex.abs w ≤ 20 cw : Complex.abs c ≤ Complex.abs w pw : 1 / Complex.abs w - 0.8095 / Complex.abs w ^ 1.864 ≤ ⋯.potential c ↑w anti : (fun x => 1 / x - 0.8095 / x ^ 1.864) 20 ≤ (fun x => 1 / x - 0.8095 / x ^ 1.864) (Complex.abs w) ⊢ 469e-4 ≤ s.potential c ↑w	Please generate a tactic in lean4 to solve the state. STATE: c z : ℂ c4 : Complex.abs c ≤ 4 z4 : Complex.abs z ≤ 4 s : Super (f 2) 2 OnePoint.infty := superF 2 m : (c, ↑z) ∈ s.basin n : ℕ w : ℂ hw : (f' 2 c)^[n + 1] z = w w4 : 4 < Complex.abs w w20 : Complex.abs w ≤ 20 cw : Complex.abs c ≤ Complex.abs w pw : 1 / Complex.abs w - 0.8095 / Complex.abs w ^ 1.864 ≤ ⋯.potential c ↑w ⊢ 469e-4 ≤ s.potential c ↑w TACTIC:
https://github.com/girving/ray.git	0be790285dd0fce78913b0cb9bddaffa94bd25f9	Ray/Dynamics/Multibrot/PotentialLower.lean	le_potential	[86, 1]	[119, 13]	refine le_trans ?_ (le_trans anti pw)	c z : ℂ c4 : Complex.abs c ≤ 4 z4 : Complex.abs z ≤ 4 s : Super (f 2) 2 OnePoint.infty := superF 2 m : (c, ↑z) ∈ s.basin n : ℕ w : ℂ hw : (f' 2 c)^[n + 1] z = w w4 : 4 < Complex.abs w w20 : Complex.abs w ≤ 20 cw : Complex.abs c ≤ Complex.abs w pw : 1 / Complex.abs w - 0.8095 / Complex.abs w ^ 1.864 ≤ ⋯.potential c ↑w anti : (fun x => 1 / x - 0.8095 / x ^ 1.864) 20 ≤ (fun x => 1 / x - 0.8095 / x ^ 1.864) (Complex.abs w) ⊢ 469e-4 ≤ s.potential c ↑w	c z : ℂ c4 : Complex.abs c ≤ 4 z4 : Complex.abs z ≤ 4 s : Super (f 2) 2 OnePoint.infty := superF 2 m : (c, ↑z) ∈ s.basin n : ℕ w : ℂ hw : (f' 2 c)^[n + 1] z = w w4 : 4 < Complex.abs w w20 : Complex.abs w ≤ 20 cw : Complex.abs c ≤ Complex.abs w pw : 1 / Complex.abs w - 0.8095 / Complex.abs w ^ 1.864 ≤ ⋯.potential c ↑w anti : (fun x => 1 / x - 0.8095 / x ^ 1.864) 20 ≤ (fun x => 1 / x - 0.8095 / x ^ 1.864) (Complex.abs w) ⊢ 469e-4 ≤ (fun x => 1 / x - 0.8095 / x ^ 1.864) 20	Please generate a tactic in lean4 to solve the state. STATE: c z : ℂ c4 : Complex.abs c ≤ 4 z4 : Complex.abs z ≤ 4 s : Super (f 2) 2 OnePoint.infty := superF 2 m : (c, ↑z) ∈ s.basin n : ℕ w : ℂ hw : (f' 2 c)^[n + 1] z = w w4 : 4 < Complex.abs w w20 : Complex.abs w ≤ 20 cw : Complex.abs c ≤ Complex.abs w pw : 1 / Complex.abs w - 0.8095 / Complex.abs w ^ 1.864 ≤ ⋯.potential c ↑w anti : (fun x => 1 / x - 0.8095 / x ^ 1.864) 20 ≤ (fun x => 1 / x - 0.8095 / x ^ 1.864) (Complex.abs w) ⊢ 469e-4 ≤ s.potential c ↑w TACTIC:
https://github.com/girving/ray.git	0be790285dd0fce78913b0cb9bddaffa94bd25f9	Ray/Dynamics/Multibrot/PotentialLower.lean	le_potential	[86, 1]	[119, 13]	norm_num	c z : ℂ c4 : Complex.abs c ≤ 4 z4 : Complex.abs z ≤ 4 s : Super (f 2) 2 OnePoint.infty := superF 2 m : (c, ↑z) ∈ s.basin n : ℕ w : ℂ hw : (f' 2 c)^[n + 1] z = w w4 : 4 < Complex.abs w w20 : Complex.abs w ≤ 20 cw : Complex.abs c ≤ Complex.abs w pw : 1 / Complex.abs w - 0.8095 / Complex.abs w ^ 1.864 ≤ ⋯.potential c ↑w anti : (fun x => 1 / x - 0.8095 / x ^ 1.864) 20 ≤ (fun x => 1 / x - 0.8095 / x ^ 1.864) (Complex.abs w) ⊢ 469e-4 ≤ (fun x => 1 / x - 0.8095 / x ^ 1.864) 20	c z : ℂ c4 : Complex.abs c ≤ 4 z4 : Complex.abs z ≤ 4 s : Super (f 2) 2 OnePoint.infty := superF 2 m : (c, ↑z) ∈ s.basin n : ℕ w : ℂ hw : (f' 2 c)^[n + 1] z = w w4 : 4 < Complex.abs w w20 : Complex.abs w ≤ 20 cw : Complex.abs c ≤ Complex.abs w pw : 1 / Complex.abs w - 0.8095 / Complex.abs w ^ 1.864 ≤ ⋯.potential c ↑w anti : (fun x => 1 / x - 0.8095 / x ^ 1.864) 20 ≤ (fun x => 1 / x - 0.8095 / x ^ 1.864) (Complex.abs w) ⊢ 469 / 10000 ≤ 1 / 20 - 1619 / 2000 / 20 ^ (233 / 125)	Please generate a tactic in lean4 to solve the state. STATE: c z : ℂ c4 : Complex.abs c ≤ 4 z4 : Complex.abs z ≤ 4 s : Super (f 2) 2 OnePoint.infty := superF 2 m : (c, ↑z) ∈ s.basin n : ℕ w : ℂ hw : (f' 2 c)^[n + 1] z = w w4 : 4 < Complex.abs w w20 : Complex.abs w ≤ 20 cw : Complex.abs c ≤ Complex.abs w pw : 1 / Complex.abs w - 0.8095 / Complex.abs w ^ 1.864 ≤ ⋯.potential c ↑w anti : (fun x => 1 / x - 0.8095 / x ^ 1.864) 20 ≤ (fun x => 1 / x - 0.8095 / x ^ 1.864) (Complex.abs w) ⊢ 469e-4 ≤ (fun x => 1 / x - 0.8095 / x ^ 1.864) 20 TACTIC:
https://github.com/girving/ray.git	0be790285dd0fce78913b0cb9bddaffa94bd25f9	Ray/Dynamics/Multibrot/PotentialLower.lean	le_potential	[86, 1]	[119, 13]	have le : (266 : ℝ) ≤ 20 ^ (233 / 125 : ℝ) := by rw [div_eq_mul_inv, Real.rpow_mul (by positivity), Real.le_rpow_inv_iff_of_pos (by norm_num) (by positivity) (by positivity)] norm_num	c z : ℂ c4 : Complex.abs c ≤ 4 z4 : Complex.abs z ≤ 4 s : Super (f 2) 2 OnePoint.infty := superF 2 m : (c, ↑z) ∈ s.basin n : ℕ w : ℂ hw : (f' 2 c)^[n + 1] z = w w4 : 4 < Complex.abs w w20 : Complex.abs w ≤ 20 cw : Complex.abs c ≤ Complex.abs w pw : 1 / Complex.abs w - 0.8095 / Complex.abs w ^ 1.864 ≤ ⋯.potential c ↑w anti : (fun x => 1 / x - 0.8095 / x ^ 1.864) 20 ≤ (fun x => 1 / x - 0.8095 / x ^ 1.864) (Complex.abs w) ⊢ 469 / 10000 ≤ 1 / 20 - 1619 / 2000 / 20 ^ (233 / 125)	c z : ℂ c4 : Complex.abs c ≤ 4 z4 : Complex.abs z ≤ 4 s : Super (f 2) 2 OnePoint.infty := superF 2 m : (c, ↑z) ∈ s.basin n : ℕ w : ℂ hw : (f' 2 c)^[n + 1] z = w w4 : 4 < Complex.abs w w20 : Complex.abs w ≤ 20 cw : Complex.abs c ≤ Complex.abs w pw : 1 / Complex.abs w - 0.8095 / Complex.abs w ^ 1.864 ≤ ⋯.potential c ↑w anti : (fun x => 1 / x - 0.8095 / x ^ 1.864) 20 ≤ (fun x => 1 / x - 0.8095 / x ^ 1.864) (Complex.abs w) le : 266 ≤ 20 ^ (233 / 125) ⊢ 469 / 10000 ≤ 1 / 20 - 1619 / 2000 / 20 ^ (233 / 125)	Please generate a tactic in lean4 to solve the state. STATE: c z : ℂ c4 : Complex.abs c ≤ 4 z4 : Complex.abs z ≤ 4 s : Super (f 2) 2 OnePoint.infty := superF 2 m : (c, ↑z) ∈ s.basin n : ℕ w : ℂ hw : (f' 2 c)^[n + 1] z = w w4 : 4 < Complex.abs w w20 : Complex.abs w ≤ 20 cw : Complex.abs c ≤ Complex.abs w pw : 1 / Complex.abs w - 0.8095 / Complex.abs w ^ 1.864 ≤ ⋯.potential c ↑w anti : (fun x => 1 / x - 0.8095 / x ^ 1.864) 20 ≤ (fun x => 1 / x - 0.8095 / x ^ 1.864) (Complex.abs w) ⊢ 469 / 10000 ≤ 1 / 20 - 1619 / 2000 / 20 ^ (233 / 125) TACTIC:
https://github.com/girving/ray.git	0be790285dd0fce78913b0cb9bddaffa94bd25f9	Ray/Dynamics/Multibrot/PotentialLower.lean	le_potential	[86, 1]	[119, 13]	exact le_trans (by norm_num) (sub_le_sub_left (div_le_div_of_nonneg_left (by norm_num) (by norm_num) le) _)	c z : ℂ c4 : Complex.abs c ≤ 4 z4 : Complex.abs z ≤ 4 s : Super (f 2) 2 OnePoint.infty := superF 2 m : (c, ↑z) ∈ s.basin n : ℕ w : ℂ hw : (f' 2 c)^[n + 1] z = w w4 : 4 < Complex.abs w w20 : Complex.abs w ≤ 20 cw : Complex.abs c ≤ Complex.abs w pw : 1 / Complex.abs w - 0.8095 / Complex.abs w ^ 1.864 ≤ ⋯.potential c ↑w anti : (fun x => 1 / x - 0.8095 / x ^ 1.864) 20 ≤ (fun x => 1 / x - 0.8095 / x ^ 1.864) (Complex.abs w) le : 266 ≤ 20 ^ (233 / 125) ⊢ 469 / 10000 ≤ 1 / 20 - 1619 / 2000 / 20 ^ (233 / 125)	no goals	Please generate a tactic in lean4 to solve the state. STATE: c z : ℂ c4 : Complex.abs c ≤ 4 z4 : Complex.abs z ≤ 4 s : Super (f 2) 2 OnePoint.infty := superF 2 m : (c, ↑z) ∈ s.basin n : ℕ w : ℂ hw : (f' 2 c)^[n + 1] z = w w4 : 4 < Complex.abs w w20 : Complex.abs w ≤ 20 cw : Complex.abs c ≤ Complex.abs w pw : 1 / Complex.abs w - 0.8095 / Complex.abs w ^ 1.864 ≤ ⋯.potential c ↑w anti : (fun x => 1 / x - 0.8095 / x ^ 1.864) 20 ≤ (fun x => 1 / x - 0.8095 / x ^ 1.864) (Complex.abs w) le : 266 ≤ 20 ^ (233 / 125) ⊢ 469 / 10000 ≤ 1 / 20 - 1619 / 2000 / 20 ^ (233 / 125) TACTIC:
https://github.com/girving/ray.git	0be790285dd0fce78913b0cb9bddaffa94bd25f9	Ray/Dynamics/Multibrot/PotentialLower.lean	le_potential	[86, 1]	[119, 13]	norm_num	c z : ℂ c4 : Complex.abs c ≤ 4 z4 : Complex.abs z ≤ 4 s : Super (f 2) 2 OnePoint.infty := superF 2 m : (c, ↑z) ∈ s.basin n : ℕ w : ℂ hw : (f' 2 c)^[n + 1] z = w w4 : 4 < Complex.abs w w20 : Complex.abs w ≤ 20 cw : Complex.abs c ≤ Complex.abs w pw : 1 / Complex.abs w - 0.8095 / Complex.abs w ^ 1.864 ≤ ⋯.potential c ↑w ⊢ 0.8095 * 1.864 ≤ 2	no goals	Please generate a tactic in lean4 to solve the state. STATE: c z : ℂ c4 : Complex.abs c ≤ 4 z4 : Complex.abs z ≤ 4 s : Super (f 2) 2 OnePoint.infty := superF 2 m : (c, ↑z) ∈ s.basin n : ℕ w : ℂ hw : (f' 2 c)^[n + 1] z = w w4 : 4 < Complex.abs w w20 : Complex.abs w ≤ 20 cw : Complex.abs c ≤ Complex.abs w pw : 1 / Complex.abs w - 0.8095 / Complex.abs w ^ 1.864 ≤ ⋯.potential c ↑w ⊢ 0.8095 * 1.864 ≤ 2 TACTIC:
https://github.com/girving/ray.git	0be790285dd0fce78913b0cb9bddaffa94bd25f9	Ray/Dynamics/Multibrot/PotentialLower.lean	le_potential	[86, 1]	[119, 13]	norm_num	c z : ℂ c4 : Complex.abs c ≤ 4 z4 : Complex.abs z ≤ 4 s : Super (f 2) 2 OnePoint.infty := superF 2 m : (c, ↑z) ∈ s.basin n : ℕ w : ℂ hw : (f' 2 c)^[n + 1] z = w w4 : 4 < Complex.abs w w20 : Complex.abs w ≤ 20 cw : Complex.abs c ≤ Complex.abs w pw : 1 / Complex.abs w - 0.8095 / Complex.abs w ^ 1.864 ≤ ⋯.potential c ↑w ⊢ 3 / 2 ≤ 1.864	no goals	Please generate a tactic in lean4 to solve the state. STATE: c z : ℂ c4 : Complex.abs c ≤ 4 z4 : Complex.abs z ≤ 4 s : Super (f 2) 2 OnePoint.infty := superF 2 m : (c, ↑z) ∈ s.basin n : ℕ w : ℂ hw : (f' 2 c)^[n + 1] z = w w4 : 4 < Complex.abs w w20 : Complex.abs w ≤ 20 cw : Complex.abs c ≤ Complex.abs w pw : 1 / Complex.abs w - 0.8095 / Complex.abs w ^ 1.864 ≤ ⋯.potential c ↑w ⊢ 3 / 2 ≤ 1.864 TACTIC:
https://github.com/girving/ray.git	0be790285dd0fce78913b0cb9bddaffa94bd25f9	Ray/Dynamics/Multibrot/PotentialLower.lean	le_potential	[86, 1]	[119, 13]	norm_num	c z : ℂ c4 : Complex.abs c ≤ 4 z4 : Complex.abs z ≤ 4 s : Super (f 2) 2 OnePoint.infty := superF 2 m : (c, ↑z) ∈ s.basin n : ℕ w : ℂ hw : (f' 2 c)^[n + 1] z = w w4 : 4 < Complex.abs w w20 : Complex.abs w ≤ 20 cw : Complex.abs c ≤ Complex.abs w pw : 1 / Complex.abs w - 0.8095 / Complex.abs w ^ 1.864 ≤ ⋯.potential c ↑w ⊢ 20 ∈ Ici 4	no goals	Please generate a tactic in lean4 to solve the state. STATE: c z : ℂ c4 : Complex.abs c ≤ 4 z4 : Complex.abs z ≤ 4 s : Super (f 2) 2 OnePoint.infty := superF 2 m : (c, ↑z) ∈ s.basin n : ℕ w : ℂ hw : (f' 2 c)^[n + 1] z = w w4 : 4 < Complex.abs w w20 : Complex.abs w ≤ 20 cw : Complex.abs c ≤ Complex.abs w pw : 1 / Complex.abs w - 0.8095 / Complex.abs w ^ 1.864 ≤ ⋯.potential c ↑w ⊢ 20 ∈ Ici 4 TACTIC:
https://github.com/girving/ray.git	0be790285dd0fce78913b0cb9bddaffa94bd25f9	Ray/Dynamics/Multibrot/PotentialLower.lean	le_potential	[86, 1]	[119, 13]	rw [div_eq_mul_inv, Real.rpow_mul (by positivity), Real.le_rpow_inv_iff_of_pos (by norm_num) (by positivity) (by positivity)]	c z : ℂ c4 : Complex.abs c ≤ 4 z4 : Complex.abs z ≤ 4 s : Super (f 2) 2 OnePoint.infty := superF 2 m : (c, ↑z) ∈ s.basin n : ℕ w : ℂ hw : (f' 2 c)^[n + 1] z = w w4 : 4 < Complex.abs w w20 : Complex.abs w ≤ 20 cw : Complex.abs c ≤ Complex.abs w pw : 1 / Complex.abs w - 0.8095 / Complex.abs w ^ 1.864 ≤ ⋯.potential c ↑w anti : (fun x => 1 / x - 0.8095 / x ^ 1.864) 20 ≤ (fun x => 1 / x - 0.8095 / x ^ 1.864) (Complex.abs w) ⊢ 266 ≤ 20 ^ (233 / 125)	c z : ℂ c4 : Complex.abs c ≤ 4 z4 : Complex.abs z ≤ 4 s : Super (f 2) 2 OnePoint.infty := superF 2 m : (c, ↑z) ∈ s.basin n : ℕ w : ℂ hw : (f' 2 c)^[n + 1] z = w w4 : 4 < Complex.abs w w20 : Complex.abs w ≤ 20 cw : Complex.abs c ≤ Complex.abs w pw : 1 / Complex.abs w - 0.8095 / Complex.abs w ^ 1.864 ≤ ⋯.potential c ↑w anti : (fun x => 1 / x - 0.8095 / x ^ 1.864) 20 ≤ (fun x => 1 / x - 0.8095 / x ^ 1.864) (Complex.abs w) ⊢ 266 ^ 125 ≤ 20 ^ 233	Please generate a tactic in lean4 to solve the state. STATE: c z : ℂ c4 : Complex.abs c ≤ 4 z4 : Complex.abs z ≤ 4 s : Super (f 2) 2 OnePoint.infty := superF 2 m : (c, ↑z) ∈ s.basin n : ℕ w : ℂ hw : (f' 2 c)^[n + 1] z = w w4 : 4 < Complex.abs w w20 : Complex.abs w ≤ 20 cw : Complex.abs c ≤ Complex.abs w pw : 1 / Complex.abs w - 0.8095 / Complex.abs w ^ 1.864 ≤ ⋯.potential c ↑w anti : (fun x => 1 / x - 0.8095 / x ^ 1.864) 20 ≤ (fun x => 1 / x - 0.8095 / x ^ 1.864) (Complex.abs w) ⊢ 266 ≤ 20 ^ (233 / 125) TACTIC:
https://github.com/girving/ray.git	0be790285dd0fce78913b0cb9bddaffa94bd25f9	Ray/Dynamics/Multibrot/PotentialLower.lean	le_potential	[86, 1]	[119, 13]	norm_num	c z : ℂ c4 : Complex.abs c ≤ 4 z4 : Complex.abs z ≤ 4 s : Super (f 2) 2 OnePoint.infty := superF 2 m : (c, ↑z) ∈ s.basin n : ℕ w : ℂ hw : (f' 2 c)^[n + 1] z = w w4 : 4 < Complex.abs w w20 : Complex.abs w ≤ 20 cw : Complex.abs c ≤ Complex.abs w pw : 1 / Complex.abs w - 0.8095 / Complex.abs w ^ 1.864 ≤ ⋯.potential c ↑w anti : (fun x => 1 / x - 0.8095 / x ^ 1.864) 20 ≤ (fun x => 1 / x - 0.8095 / x ^ 1.864) (Complex.abs w) ⊢ 266 ^ 125 ≤ 20 ^ 233	no goals	Please generate a tactic in lean4 to solve the state. STATE: c z : ℂ c4 : Complex.abs c ≤ 4 z4 : Complex.abs z ≤ 4 s : Super (f 2) 2 OnePoint.infty := superF 2 m : (c, ↑z) ∈ s.basin n : ℕ w : ℂ hw : (f' 2 c)^[n + 1] z = w w4 : 4 < Complex.abs w w20 : Complex.abs w ≤ 20 cw : Complex.abs c ≤ Complex.abs w pw : 1 / Complex.abs w - 0.8095 / Complex.abs w ^ 1.864 ≤ ⋯.potential c ↑w anti : (fun x => 1 / x - 0.8095 / x ^ 1.864) 20 ≤ (fun x => 1 / x - 0.8095 / x ^ 1.864) (Complex.abs w) ⊢ 266 ^ 125 ≤ 20 ^ 233 TACTIC:
https://github.com/girving/ray.git	0be790285dd0fce78913b0cb9bddaffa94bd25f9	Ray/Dynamics/Multibrot/PotentialLower.lean	le_potential	[86, 1]	[119, 13]	positivity	c z : ℂ c4 : Complex.abs c ≤ 4 z4 : Complex.abs z ≤ 4 s : Super (f 2) 2 OnePoint.infty := superF 2 m : (c, ↑z) ∈ s.basin n : ℕ w : ℂ hw : (f' 2 c)^[n + 1] z = w w4 : 4 < Complex.abs w w20 : Complex.abs w ≤ 20 cw : Complex.abs c ≤ Complex.abs w pw : 1 / Complex.abs w - 0.8095 / Complex.abs w ^ 1.864 ≤ ⋯.potential c ↑w anti : (fun x => 1 / x - 0.8095 / x ^ 1.864) 20 ≤ (fun x => 1 / x - 0.8095 / x ^ 1.864) (Complex.abs w) ⊢ 0 ≤ 20	no goals	Please generate a tactic in lean4 to solve the state. STATE: c z : ℂ c4 : Complex.abs c ≤ 4 z4 : Complex.abs z ≤ 4 s : Super (f 2) 2 OnePoint.infty := superF 2 m : (c, ↑z) ∈ s.basin n : ℕ w : ℂ hw : (f' 2 c)^[n + 1] z = w w4 : 4 < Complex.abs w w20 : Complex.abs w ≤ 20 cw : Complex.abs c ≤ Complex.abs w pw : 1 / Complex.abs w - 0.8095 / Complex.abs w ^ 1.864 ≤ ⋯.potential c ↑w anti : (fun x => 1 / x - 0.8095 / x ^ 1.864) 20 ≤ (fun x => 1 / x - 0.8095 / x ^ 1.864) (Complex.abs w) ⊢ 0 ≤ 20 TACTIC:
https://github.com/girving/ray.git	0be790285dd0fce78913b0cb9bddaffa94bd25f9	Ray/Dynamics/Multibrot/PotentialLower.lean	le_potential	[86, 1]	[119, 13]	norm_num	c z : ℂ c4 : Complex.abs c ≤ 4 z4 : Complex.abs z ≤ 4 s : Super (f 2) 2 OnePoint.infty := superF 2 m : (c, ↑z) ∈ s.basin n : ℕ w : ℂ hw : (f' 2 c)^[n + 1] z = w w4 : 4 < Complex.abs w w20 : Complex.abs w ≤ 20 cw : Complex.abs c ≤ Complex.abs w pw : 1 / Complex.abs w - 0.8095 / Complex.abs w ^ 1.864 ≤ ⋯.potential c ↑w anti : (fun x => 1 / x - 0.8095 / x ^ 1.864) 20 ≤ (fun x => 1 / x - 0.8095 / x ^ 1.864) (Complex.abs w) ⊢ 0 ≤ 266	no goals	Please generate a tactic in lean4 to solve the state. STATE: c z : ℂ c4 : Complex.abs c ≤ 4 z4 : Complex.abs z ≤ 4 s : Super (f 2) 2 OnePoint.infty := superF 2 m : (c, ↑z) ∈ s.basin n : ℕ w : ℂ hw : (f' 2 c)^[n + 1] z = w w4 : 4 < Complex.abs w w20 : Complex.abs w ≤ 20 cw : Complex.abs c ≤ Complex.abs w pw : 1 / Complex.abs w - 0.8095 / Complex.abs w ^ 1.864 ≤ ⋯.potential c ↑w anti : (fun x => 1 / x - 0.8095 / x ^ 1.864) 20 ≤ (fun x => 1 / x - 0.8095 / x ^ 1.864) (Complex.abs w) ⊢ 0 ≤ 266 TACTIC:
https://github.com/girving/ray.git	0be790285dd0fce78913b0cb9bddaffa94bd25f9	Ray/Dynamics/Multibrot/PotentialLower.lean	le_potential	[86, 1]	[119, 13]	positivity	c z : ℂ c4 : Complex.abs c ≤ 4 z4 : Complex.abs z ≤ 4 s : Super (f 2) 2 OnePoint.infty := superF 2 m : (c, ↑z) ∈ s.basin n : ℕ w : ℂ hw : (f' 2 c)^[n + 1] z = w w4 : 4 < Complex.abs w w20 : Complex.abs w ≤ 20 cw : Complex.abs c ≤ Complex.abs w pw : 1 / Complex.abs w - 0.8095 / Complex.abs w ^ 1.864 ≤ ⋯.potential c ↑w anti : (fun x => 1 / x - 0.8095 / x ^ 1.864) 20 ≤ (fun x => 1 / x - 0.8095 / x ^ 1.864) (Complex.abs w) ⊢ 0 ≤ 20 ^ 233	no goals	Please generate a tactic in lean4 to solve the state. STATE: c z : ℂ c4 : Complex.abs c ≤ 4 z4 : Complex.abs z ≤ 4 s : Super (f 2) 2 OnePoint.infty := superF 2 m : (c, ↑z) ∈ s.basin n : ℕ w : ℂ hw : (f' 2 c)^[n + 1] z = w w4 : 4 < Complex.abs w w20 : Complex.abs w ≤ 20 cw : Complex.abs c ≤ Complex.abs w pw : 1 / Complex.abs w - 0.8095 / Complex.abs w ^ 1.864 ≤ ⋯.potential c ↑w anti : (fun x => 1 / x - 0.8095 / x ^ 1.864) 20 ≤ (fun x => 1 / x - 0.8095 / x ^ 1.864) (Complex.abs w) ⊢ 0 ≤ 20 ^ 233 TACTIC:
https://github.com/girving/ray.git	0be790285dd0fce78913b0cb9bddaffa94bd25f9	Ray/Dynamics/Multibrot/PotentialLower.lean	le_potential	[86, 1]	[119, 13]	positivity	c z : ℂ c4 : Complex.abs c ≤ 4 z4 : Complex.abs z ≤ 4 s : Super (f 2) 2 OnePoint.infty := superF 2 m : (c, ↑z) ∈ s.basin n : ℕ w : ℂ hw : (f' 2 c)^[n + 1] z = w w4 : 4 < Complex.abs w w20 : Complex.abs w ≤ 20 cw : Complex.abs c ≤ Complex.abs w pw : 1 / Complex.abs w - 0.8095 / Complex.abs w ^ 1.864 ≤ ⋯.potential c ↑w anti : (fun x => 1 / x - 0.8095 / x ^ 1.864) 20 ≤ (fun x => 1 / x - 0.8095 / x ^ 1.864) (Complex.abs w) ⊢ 0 < 125	no goals	Please generate a tactic in lean4 to solve the state. STATE: c z : ℂ c4 : Complex.abs c ≤ 4 z4 : Complex.abs z ≤ 4 s : Super (f 2) 2 OnePoint.infty := superF 2 m : (c, ↑z) ∈ s.basin n : ℕ w : ℂ hw : (f' 2 c)^[n + 1] z = w w4 : 4 < Complex.abs w w20 : Complex.abs w ≤ 20 cw : Complex.abs c ≤ Complex.abs w pw : 1 / Complex.abs w - 0.8095 / Complex.abs w ^ 1.864 ≤ ⋯.potential c ↑w anti : (fun x => 1 / x - 0.8095 / x ^ 1.864) 20 ≤ (fun x => 1 / x - 0.8095 / x ^ 1.864) (Complex.abs w) ⊢ 0 < 125 TACTIC:
https://github.com/girving/ray.git	0be790285dd0fce78913b0cb9bddaffa94bd25f9	Ray/Dynamics/Multibrot/PotentialLower.lean	le_potential	[86, 1]	[119, 13]	norm_num	c z : ℂ c4 : Complex.abs c ≤ 4 z4 : Complex.abs z ≤ 4 s : Super (f 2) 2 OnePoint.infty := superF 2 m : (c, ↑z) ∈ s.basin n : ℕ w : ℂ hw : (f' 2 c)^[n + 1] z = w w4 : 4 < Complex.abs w w20 : Complex.abs w ≤ 20 cw : Complex.abs c ≤ Complex.abs w pw : 1 / Complex.abs w - 0.8095 / Complex.abs w ^ 1.864 ≤ ⋯.potential c ↑w anti : (fun x => 1 / x - 0.8095 / x ^ 1.864) 20 ≤ (fun x => 1 / x - 0.8095 / x ^ 1.864) (Complex.abs w) le : 266 ≤ 20 ^ (233 / 125) ⊢ 469 / 10000 ≤ 1 / 20 - 1619 / 2000 / 266	no goals	Please generate a tactic in lean4 to solve the state. STATE: c z : ℂ c4 : Complex.abs c ≤ 4 z4 : Complex.abs z ≤ 4 s : Super (f 2) 2 OnePoint.infty := superF 2 m : (c, ↑z) ∈ s.basin n : ℕ w : ℂ hw : (f' 2 c)^[n + 1] z = w w4 : 4 < Complex.abs w w20 : Complex.abs w ≤ 20 cw : Complex.abs c ≤ Complex.abs w pw : 1 / Complex.abs w - 0.8095 / Complex.abs w ^ 1.864 ≤ ⋯.potential c ↑w anti : (fun x => 1 / x - 0.8095 / x ^ 1.864) 20 ≤ (fun x => 1 / x - 0.8095 / x ^ 1.864) (Complex.abs w) le : 266 ≤ 20 ^ (233 / 125) ⊢ 469 / 10000 ≤ 1 / 20 - 1619 / 2000 / 266 TACTIC:
https://github.com/girving/ray.git	0be790285dd0fce78913b0cb9bddaffa94bd25f9	Ray/Dynamics/Multibrot/PotentialLower.lean	le_potential	[86, 1]	[119, 13]	norm_num	c z : ℂ c4 : Complex.abs c ≤ 4 z4 : Complex.abs z ≤ 4 s : Super (f 2) 2 OnePoint.infty := superF 2 m : (c, ↑z) ∈ s.basin n : ℕ w : ℂ hw : (f' 2 c)^[n + 1] z = w w4 : 4 < Complex.abs w w20 : Complex.abs w ≤ 20 cw : Complex.abs c ≤ Complex.abs w pw : 1 / Complex.abs w - 0.8095 / Complex.abs w ^ 1.864 ≤ ⋯.potential c ↑w anti : (fun x => 1 / x - 0.8095 / x ^ 1.864) 20 ≤ (fun x => 1 / x - 0.8095 / x ^ 1.864) (Complex.abs w) le : 266 ≤ 20 ^ (233 / 125) ⊢ 0 ≤ 1619 / 2000	no goals	Please generate a tactic in lean4 to solve the state. STATE: c z : ℂ c4 : Complex.abs c ≤ 4 z4 : Complex.abs z ≤ 4 s : Super (f 2) 2 OnePoint.infty := superF 2 m : (c, ↑z) ∈ s.basin n : ℕ w : ℂ hw : (f' 2 c)^[n + 1] z = w w4 : 4 < Complex.abs w w20 : Complex.abs w ≤ 20 cw : Complex.abs c ≤ Complex.abs w pw : 1 / Complex.abs w - 0.8095 / Complex.abs w ^ 1.864 ≤ ⋯.potential c ↑w anti : (fun x => 1 / x - 0.8095 / x ^ 1.864) 20 ≤ (fun x => 1 / x - 0.8095 / x ^ 1.864) (Complex.abs w) le : 266 ≤ 20 ^ (233 / 125) ⊢ 0 ≤ 1619 / 2000 TACTIC:
https://github.com/girving/ray.git	0be790285dd0fce78913b0cb9bddaffa94bd25f9	Ray/Dynamics/Multibrot/PotentialLower.lean	le_potential	[86, 1]	[119, 13]	norm_num	c z : ℂ c4 : Complex.abs c ≤ 4 z4 : Complex.abs z ≤ 4 s : Super (f 2) 2 OnePoint.infty := superF 2 m : (c, ↑z) ∈ s.basin n : ℕ w : ℂ hw : (f' 2 c)^[n + 1] z = w w4 : 4 < Complex.abs w w20 : Complex.abs w ≤ 20 cw : Complex.abs c ≤ Complex.abs w pw : 1 / Complex.abs w - 0.8095 / Complex.abs w ^ 1.864 ≤ ⋯.potential c ↑w anti : (fun x => 1 / x - 0.8095 / x ^ 1.864) 20 ≤ (fun x => 1 / x - 0.8095 / x ^ 1.864) (Complex.abs w) le : 266 ≤ 20 ^ (233 / 125) ⊢ 0 < 266	no goals	Please generate a tactic in lean4 to solve the state. STATE: c z : ℂ c4 : Complex.abs c ≤ 4 z4 : Complex.abs z ≤ 4 s : Super (f 2) 2 OnePoint.infty := superF 2 m : (c, ↑z) ∈ s.basin n : ℕ w : ℂ hw : (f' 2 c)^[n + 1] z = w w4 : 4 < Complex.abs w w20 : Complex.abs w ≤ 20 cw : Complex.abs c ≤ Complex.abs w pw : 1 / Complex.abs w - 0.8095 / Complex.abs w ^ 1.864 ≤ ⋯.potential c ↑w anti : (fun x => 1 / x - 0.8095 / x ^ 1.864) 20 ≤ (fun x => 1 / x - 0.8095 / x ^ 1.864) (Complex.abs w) le : 266 ≤ 20 ^ (233 / 125) ⊢ 0 < 266 TACTIC:
https://github.com/girving/ray.git	0be790285dd0fce78913b0cb9bddaffa94bd25f9	Ray/Dynamics/Multibrot/PotentialLower.lean	le_potential	[86, 1]	[119, 13]	simp only [←hw, ←f_f'_iter, s.potential_eqn_iter]	c z : ℂ c4 : Complex.abs c ≤ 4 z4 : Complex.abs z ≤ 4 s : Super (f 2) 2 OnePoint.infty := superF 2 m : (c, ↑z) ∈ s.basin n : ℕ w : ℂ hw : (f' 2 c)^[n + 1] z = w w4 : 4 < Complex.abs w w20 : Complex.abs w ≤ 20 cw : Complex.abs c ≤ Complex.abs w pw : 469e-4 ≤ s.potential c ↑w ⊢ s.potential c ↑w = s.potential c ↑z ^ 2 ^ (n + 1)	no goals	Please generate a tactic in lean4 to solve the state. STATE: c z : ℂ c4 : Complex.abs c ≤ 4 z4 : Complex.abs z ≤ 4 s : Super (f 2) 2 OnePoint.infty := superF 2 m : (c, ↑z) ∈ s.basin n : ℕ w : ℂ hw : (f' 2 c)^[n + 1] z = w w4 : 4 < Complex.abs w w20 : Complex.abs w ≤ 20 cw : Complex.abs c ≤ Complex.abs w pw : 469e-4 ≤ s.potential c ↑w ⊢ s.potential c ↑w = s.potential c ↑z ^ 2 ^ (n + 1) TACTIC:
https://github.com/girving/ray.git	0be790285dd0fce78913b0cb9bddaffa94bd25f9	Ray/Dynamics/Multibrot/PotentialLower.lean	le_potential	[86, 1]	[119, 13]	norm_num	c z : ℂ c4 : Complex.abs c ≤ 4 z4 : Complex.abs z ≤ 4 s : Super (f 2) 2 OnePoint.infty := superF 2 m : (c, ↑z) ∈ s.basin n : ℕ w : ℂ hw : (f' 2 c)^[n + 1] z = w w4 : 4 < Complex.abs w w20 : Complex.abs w ≤ 20 cw : Complex.abs c ≤ Complex.abs w pw : 469e-4 ≤ s.potential c ↑w pwz : s.potential c ↑w ^ (↑(2 ^ (n + 1)))⁻¹ = s.potential c ↑z ⊢ 0 ≤ 469e-4	no goals	Please generate a tactic in lean4 to solve the state. STATE: c z : ℂ c4 : Complex.abs c ≤ 4 z4 : Complex.abs z ≤ 4 s : Super (f 2) 2 OnePoint.infty := superF 2 m : (c, ↑z) ∈ s.basin n : ℕ w : ℂ hw : (f' 2 c)^[n + 1] z = w w4 : 4 < Complex.abs w w20 : Complex.abs w ≤ 20 cw : Complex.abs c ≤ Complex.abs w pw : 469e-4 ≤ s.potential c ↑w pwz : s.potential c ↑w ^ (↑(2 ^ (n + 1)))⁻¹ = s.potential c ↑z ⊢ 0 ≤ 469e-4 TACTIC:
https://github.com/girving/ray.git	0be790285dd0fce78913b0cb9bddaffa94bd25f9	Ray/Dynamics/Multibrot/PotentialLower.lean	le_potential	[86, 1]	[119, 13]	positivity	c z : ℂ c4 : Complex.abs c ≤ 4 z4 : Complex.abs z ≤ 4 s : Super (f 2) 2 OnePoint.infty := superF 2 m : (c, ↑z) ∈ s.basin n : ℕ w : ℂ hw : (f' 2 c)^[n + 1] z = w w4 : 4 < Complex.abs w w20 : Complex.abs w ≤ 20 cw : Complex.abs c ≤ Complex.abs w pw : 469e-4 ≤ s.potential c ↑w pwz : s.potential c ↑w ^ (↑(2 ^ (n + 1)))⁻¹ = s.potential c ↑z ⊢ 0 ≤ (↑(2 ^ (n + 1)))⁻¹	no goals	Please generate a tactic in lean4 to solve the state. STATE: c z : ℂ c4 : Complex.abs c ≤ 4 z4 : Complex.abs z ≤ 4 s : Super (f 2) 2 OnePoint.infty := superF 2 m : (c, ↑z) ∈ s.basin n : ℕ w : ℂ hw : (f' 2 c)^[n + 1] z = w w4 : 4 < Complex.abs w w20 : Complex.abs w ≤ 20 cw : Complex.abs c ≤ Complex.abs w pw : 469e-4 ≤ s.potential c ↑w pwz : s.potential c ↑w ^ (↑(2 ^ (n + 1)))⁻¹ = s.potential c ↑z ⊢ 0 ≤ (↑(2 ^ (n + 1)))⁻¹ TACTIC:
https://github.com/girving/ray.git	0be790285dd0fce78913b0cb9bddaffa94bd25f9	Ray/Dynamics/Multibrot/PotentialLower.lean	le_potential	[86, 1]	[119, 13]	norm_num	c z : ℂ c4 : Complex.abs c ≤ 4 z4 : Complex.abs z ≤ 4 s : Super (f 2) 2 OnePoint.infty := superF 2 m : (c, ↑z) ∈ s.basin n : ℕ w : ℂ hw : (f' 2 c)^[n + 1] z = w w4 : 4 < Complex.abs w w20 : Complex.abs w ≤ 20 cw : Complex.abs c ≤ Complex.abs w pw : 469e-4 ≤ s.potential c ↑w pwz : s.potential c ↑w ^ (↑(2 ^ (n + 1)))⁻¹ = s.potential c ↑z ⊢ 0 ≤ 0.216	no goals	Please generate a tactic in lean4 to solve the state. STATE: c z : ℂ c4 : Complex.abs c ≤ 4 z4 : Complex.abs z ≤ 4 s : Super (f 2) 2 OnePoint.infty := superF 2 m : (c, ↑z) ∈ s.basin n : ℕ w : ℂ hw : (f' 2 c)^[n + 1] z = w w4 : 4 < Complex.abs w w20 : Complex.abs w ≤ 20 cw : Complex.abs c ≤ Complex.abs w pw : 469e-4 ≤ s.potential c ↑w pwz : s.potential c ↑w ^ (↑(2 ^ (n + 1)))⁻¹ = s.potential c ↑z ⊢ 0 ≤ 0.216 TACTIC:
https://github.com/girving/ray.git	0be790285dd0fce78913b0cb9bddaffa94bd25f9	Ray/Dynamics/Multibrot/PotentialLower.lean	le_potential	[86, 1]	[119, 13]	positivity	c z : ℂ c4 : Complex.abs c ≤ 4 z4 : Complex.abs z ≤ 4 s : Super (f 2) 2 OnePoint.infty := superF 2 m : (c, ↑z) ∈ s.basin n : ℕ w : ℂ hw : (f' 2 c)^[n + 1] z = w w4 : 4 < Complex.abs w w20 : Complex.abs w ≤ 20 cw : Complex.abs c ≤ Complex.abs w pw : 469e-4 ≤ s.potential c ↑w pwz : s.potential c ↑w ^ (↑(2 ^ (n + 1)))⁻¹ = s.potential c ↑z ⊢ 0 < ↑(2 ^ (n + 1))	no goals	Please generate a tactic in lean4 to solve the state. STATE: c z : ℂ c4 : Complex.abs c ≤ 4 z4 : Complex.abs z ≤ 4 s : Super (f 2) 2 OnePoint.infty := superF 2 m : (c, ↑z) ∈ s.basin n : ℕ w : ℂ hw : (f' 2 c)^[n + 1] z = w w4 : 4 < Complex.abs w w20 : Complex.abs w ≤ 20 cw : Complex.abs c ≤ Complex.abs w pw : 469e-4 ≤ s.potential c ↑w pwz : s.potential c ↑w ^ (↑(2 ^ (n + 1)))⁻¹ = s.potential c ↑z ⊢ 0 < ↑(2 ^ (n + 1)) TACTIC:
https://github.com/girving/ray.git	0be790285dd0fce78913b0cb9bddaffa94bd25f9	Ray/Dynamics/Multibrot/PotentialLower.lean	le_potential	[86, 1]	[119, 13]	norm_num	c z : ℂ c4 : Complex.abs c ≤ 4 z4 : Complex.abs z ≤ 4 s : Super (f 2) 2 OnePoint.infty := superF 2 m : (c, ↑z) ∈ s.basin n : ℕ w : ℂ hw : (f' 2 c)^[n + 1] z = w w4 : 4 < Complex.abs w w20 : Complex.abs w ≤ 20 cw : Complex.abs c ≤ Complex.abs w pw : 469e-4 ≤ s.potential c ↑w pwz : s.potential c ↑w ^ (↑(2 ^ (n + 1)))⁻¹ = s.potential c ↑z ⊢ 0.216 ≤ 1	no goals	Please generate a tactic in lean4 to solve the state. STATE: c z : ℂ c4 : Complex.abs c ≤ 4 z4 : Complex.abs z ≤ 4 s : Super (f 2) 2 OnePoint.infty := superF 2 m : (c, ↑z) ∈ s.basin n : ℕ w : ℂ hw : (f' 2 c)^[n + 1] z = w w4 : 4 < Complex.abs w w20 : Complex.abs w ≤ 20 cw : Complex.abs c ≤ Complex.abs w pw : 469e-4 ≤ s.potential c ↑w pwz : s.potential c ↑w ^ (↑(2 ^ (n + 1)))⁻¹ = s.potential c ↑z ⊢ 0.216 ≤ 1 TACTIC:
https://github.com/girving/ray.git	0be790285dd0fce78913b0cb9bddaffa94bd25f9	Ray/Dynamics/Multibrot/PotentialLower.lean	le_potential	[86, 1]	[119, 13]	norm_num	c z : ℂ c4 : Complex.abs c ≤ 4 z4 : Complex.abs z ≤ 4 s : Super (f 2) 2 OnePoint.infty := superF 2 m : (c, ↑z) ∈ s.basin n : ℕ w : ℂ hw : (f' 2 c)^[n + 1] z = w w4 : 4 < Complex.abs w w20 : Complex.abs w ≤ 20 cw : Complex.abs c ≤ Complex.abs w pw : 469e-4 ≤ s.potential c ↑w pwz : s.potential c ↑w ^ (↑(2 ^ (n + 1)))⁻¹ = s.potential c ↑z ⊢ 1 ≤ 2	no goals	Please generate a tactic in lean4 to solve the state. STATE: c z : ℂ c4 : Complex.abs c ≤ 4 z4 : Complex.abs z ≤ 4 s : Super (f 2) 2 OnePoint.infty := superF 2 m : (c, ↑z) ∈ s.basin n : ℕ w : ℂ hw : (f' 2 c)^[n + 1] z = w w4 : 4 < Complex.abs w w20 : Complex.abs w ≤ 20 cw : Complex.abs c ≤ Complex.abs w pw : 469e-4 ≤ s.potential c ↑w pwz : s.potential c ↑w ^ (↑(2 ^ (n + 1)))⁻¹ = s.potential c ↑z ⊢ 1 ≤ 2 TACTIC:
https://github.com/girving/ray.git	0be790285dd0fce78913b0cb9bddaffa94bd25f9	Ray/Dynamics/Multibrot/PotentialLower.lean	le_potential	[86, 1]	[119, 13]	rw [s.potential_eq_one (not_exists.mp m)]	case neg c z : ℂ c4 : Complex.abs c ≤ 4 z4 : Complex.abs z ≤ 4 s : Super (f 2) 2 OnePoint.infty := superF 2 m : (c, ↑z) ∉ s.basin ⊢ 0.216 ≤ s.potential c ↑z	case neg c z : ℂ c4 : Complex.abs c ≤ 4 z4 : Complex.abs z ≤ 4 s : Super (f 2) 2 OnePoint.infty := superF 2 m : (c, ↑z) ∉ s.basin ⊢ 0.216 ≤ 1	Please generate a tactic in lean4 to solve the state. STATE: case neg c z : ℂ c4 : Complex.abs c ≤ 4 z4 : Complex.abs z ≤ 4 s : Super (f 2) 2 OnePoint.infty := superF 2 m : (c, ↑z) ∉ s.basin ⊢ 0.216 ≤ s.potential c ↑z TACTIC:
https://github.com/girving/ray.git	0be790285dd0fce78913b0cb9bddaffa94bd25f9	Ray/Dynamics/Multibrot/PotentialLower.lean	le_potential	[86, 1]	[119, 13]	norm_num	case neg c z : ℂ c4 : Complex.abs c ≤ 4 z4 : Complex.abs z ≤ 4 s : Super (f 2) 2 OnePoint.infty := superF 2 m : (c, ↑z) ∉ s.basin ⊢ 0.216 ≤ 1	no goals	Please generate a tactic in lean4 to solve the state. STATE: case neg c z : ℂ c4 : Complex.abs c ≤ 4 z4 : Complex.abs z ≤ 4 s : Super (f 2) 2 OnePoint.infty := superF 2 m : (c, ↑z) ∉ s.basin ⊢ 0.216 ≤ 1 TACTIC:
https://github.com/girving/ray.git	0be790285dd0fce78913b0cb9bddaffa94bd25f9	Ray/AnalyticManifold/Nonseparating.lean	Nonseparating.univ_prod	[33, 1]	[48, 40]	have e : ((univ : Set X) ×ˢ t)ᶜ = univ ×ˢ tᶜ := by apply Set.ext; intro ⟨a, x⟩; rw [mem_compl_iff] simp only [prod_mk_mem_set_prod_eq, mem_univ, mem_compl_iff, true_and_iff]	X : Type inst✝⁵ : TopologicalSpace X Y : Type inst✝⁴ : TopologicalSpace Y S : Type inst✝³ : TopologicalSpace S inst✝² : ChartedSpace ℂ S inst✝¹ : AnalyticManifold I S inst✝ : LocallyConnectedSpace X t : Set Y n : Nonseparating t ⊢ Nonseparating (univ ×ˢ t)	X : Type inst✝⁵ : TopologicalSpace X Y : Type inst✝⁴ : TopologicalSpace Y S : Type inst✝³ : TopologicalSpace S inst✝² : ChartedSpace ℂ S inst✝¹ : AnalyticManifold I S inst✝ : LocallyConnectedSpace X t : Set Y n : Nonseparating t e : (univ ×ˢ t)ᶜ = univ ×ˢ tᶜ ⊢ Nonseparating (univ ×ˢ t)	Please generate a tactic in lean4 to solve the state. STATE: X : Type inst✝⁵ : TopologicalSpace X Y : Type inst✝⁴ : TopologicalSpace Y S : Type inst✝³ : TopologicalSpace S inst✝² : ChartedSpace ℂ S inst✝¹ : AnalyticManifold I S inst✝ : LocallyConnectedSpace X t : Set Y n : Nonseparating t ⊢ Nonseparating (univ ×ˢ t) TACTIC:
https://github.com/girving/ray.git	0be790285dd0fce78913b0cb9bddaffa94bd25f9	Ray/AnalyticManifold/Nonseparating.lean	Nonseparating.univ_prod	[33, 1]	[48, 40]	constructor	X : Type inst✝⁵ : TopologicalSpace X Y : Type inst✝⁴ : TopologicalSpace Y S : Type inst✝³ : TopologicalSpace S inst✝² : ChartedSpace ℂ S inst✝¹ : AnalyticManifold I S inst✝ : LocallyConnectedSpace X t : Set Y n : Nonseparating t e : (univ ×ˢ t)ᶜ = univ ×ˢ tᶜ ⊢ Nonseparating (univ ×ˢ t)	case dense X : Type inst✝⁵ : TopologicalSpace X Y : Type inst✝⁴ : TopologicalSpace Y S : Type inst✝³ : TopologicalSpace S inst✝² : ChartedSpace ℂ S inst✝¹ : AnalyticManifold I S inst✝ : LocallyConnectedSpace X t : Set Y n : Nonseparating t e : (univ ×ˢ t)ᶜ = univ ×ˢ tᶜ ⊢ Dense (univ ×ˢ t)ᶜ case loc X : Type inst✝⁵ : TopologicalSpace X Y : Type inst✝⁴ : TopologicalSpace Y S : Type inst✝³ : TopologicalSpace S inst✝² : ChartedSpace ℂ S inst✝¹ : AnalyticManifold I S inst✝ : LocallyConnectedSpace X t : Set Y n : Nonseparating t e : (univ ×ˢ t)ᶜ = univ ×ˢ tᶜ ⊢ ∀ (x : X × Y) (u : Set (X × Y)), x ∈ univ ×ˢ t → u ∈ 𝓝 x → ∃ c ⊆ u \ univ ×ˢ t, c ∈ 𝓝[(univ ×ˢ t)ᶜ] x ∧ IsPreconnected c	Please generate a tactic in lean4 to solve the state. STATE: X : Type inst✝⁵ : TopologicalSpace X Y : Type inst✝⁴ : TopologicalSpace Y S : Type inst✝³ : TopologicalSpace S inst✝² : ChartedSpace ℂ S inst✝¹ : AnalyticManifold I S inst✝ : LocallyConnectedSpace X t : Set Y n : Nonseparating t e : (univ ×ˢ t)ᶜ = univ ×ˢ tᶜ ⊢ Nonseparating (univ ×ˢ t) TACTIC:
https://github.com/girving/ray.git	0be790285dd0fce78913b0cb9bddaffa94bd25f9	Ray/AnalyticManifold/Nonseparating.lean	Nonseparating.univ_prod	[33, 1]	[48, 40]	apply Set.ext	X : Type inst✝⁵ : TopologicalSpace X Y : Type inst✝⁴ : TopologicalSpace Y S : Type inst✝³ : TopologicalSpace S inst✝² : ChartedSpace ℂ S inst✝¹ : AnalyticManifold I S inst✝ : LocallyConnectedSpace X t : Set Y n : Nonseparating t ⊢ (univ ×ˢ t)ᶜ = univ ×ˢ tᶜ	case h X : Type inst✝⁵ : TopologicalSpace X Y : Type inst✝⁴ : TopologicalSpace Y S : Type inst✝³ : TopologicalSpace S inst✝² : ChartedSpace ℂ S inst✝¹ : AnalyticManifold I S inst✝ : LocallyConnectedSpace X t : Set Y n : Nonseparating t ⊢ ∀ (x : X × Y), x ∈ (univ ×ˢ t)ᶜ ↔ x ∈ univ ×ˢ tᶜ	Please generate a tactic in lean4 to solve the state. STATE: X : Type inst✝⁵ : TopologicalSpace X Y : Type inst✝⁴ : TopologicalSpace Y S : Type inst✝³ : TopologicalSpace S inst✝² : ChartedSpace ℂ S inst✝¹ : AnalyticManifold I S inst✝ : LocallyConnectedSpace X t : Set Y n : Nonseparating t ⊢ (univ ×ˢ t)ᶜ = univ ×ˢ tᶜ TACTIC:
https://github.com/girving/ray.git	0be790285dd0fce78913b0cb9bddaffa94bd25f9	Ray/AnalyticManifold/Nonseparating.lean	Nonseparating.univ_prod	[33, 1]	[48, 40]	intro ⟨a, x⟩	case h X : Type inst✝⁵ : TopologicalSpace X Y : Type inst✝⁴ : TopologicalSpace Y S : Type inst✝³ : TopologicalSpace S inst✝² : ChartedSpace ℂ S inst✝¹ : AnalyticManifold I S inst✝ : LocallyConnectedSpace X t : Set Y n : Nonseparating t ⊢ ∀ (x : X × Y), x ∈ (univ ×ˢ t)ᶜ ↔ x ∈ univ ×ˢ tᶜ	case h X : Type inst✝⁵ : TopologicalSpace X Y : Type inst✝⁴ : TopologicalSpace Y S : Type inst✝³ : TopologicalSpace S inst✝² : ChartedSpace ℂ S inst✝¹ : AnalyticManifold I S inst✝ : LocallyConnectedSpace X t : Set Y n : Nonseparating t a : X x : Y ⊢ (a, x) ∈ (univ ×ˢ t)ᶜ ↔ (a, x) ∈ univ ×ˢ tᶜ	Please generate a tactic in lean4 to solve the state. STATE: case h X : Type inst✝⁵ : TopologicalSpace X Y : Type inst✝⁴ : TopologicalSpace Y S : Type inst✝³ : TopologicalSpace S inst✝² : ChartedSpace ℂ S inst✝¹ : AnalyticManifold I S inst✝ : LocallyConnectedSpace X t : Set Y n : Nonseparating t ⊢ ∀ (x : X × Y), x ∈ (univ ×ˢ t)ᶜ ↔ x ∈ univ ×ˢ tᶜ TACTIC:
https://github.com/girving/ray.git	0be790285dd0fce78913b0cb9bddaffa94bd25f9	Ray/AnalyticManifold/Nonseparating.lean	Nonseparating.univ_prod	[33, 1]	[48, 40]	rw [mem_compl_iff]	case h X : Type inst✝⁵ : TopologicalSpace X Y : Type inst✝⁴ : TopologicalSpace Y S : Type inst✝³ : TopologicalSpace S inst✝² : ChartedSpace ℂ S inst✝¹ : AnalyticManifold I S inst✝ : LocallyConnectedSpace X t : Set Y n : Nonseparating t a : X x : Y ⊢ (a, x) ∈ (univ ×ˢ t)ᶜ ↔ (a, x) ∈ univ ×ˢ tᶜ	case h X : Type inst✝⁵ : TopologicalSpace X Y : Type inst✝⁴ : TopologicalSpace Y S : Type inst✝³ : TopologicalSpace S inst✝² : ChartedSpace ℂ S inst✝¹ : AnalyticManifold I S inst✝ : LocallyConnectedSpace X t : Set Y n : Nonseparating t a : X x : Y ⊢ (a, x) ∉ univ ×ˢ t ↔ (a, x) ∈ univ ×ˢ tᶜ	Please generate a tactic in lean4 to solve the state. STATE: case h X : Type inst✝⁵ : TopologicalSpace X Y : Type inst✝⁴ : TopologicalSpace Y S : Type inst✝³ : TopologicalSpace S inst✝² : ChartedSpace ℂ S inst✝¹ : AnalyticManifold I S inst✝ : LocallyConnectedSpace X t : Set Y n : Nonseparating t a : X x : Y ⊢ (a, x) ∈ (univ ×ˢ t)ᶜ ↔ (a, x) ∈ univ ×ˢ tᶜ TACTIC:
https://github.com/girving/ray.git	0be790285dd0fce78913b0cb9bddaffa94bd25f9	Ray/AnalyticManifold/Nonseparating.lean	Nonseparating.univ_prod	[33, 1]	[48, 40]	simp only [prod_mk_mem_set_prod_eq, mem_univ, mem_compl_iff, true_and_iff]	case h X : Type inst✝⁵ : TopologicalSpace X Y : Type inst✝⁴ : TopologicalSpace Y S : Type inst✝³ : TopologicalSpace S inst✝² : ChartedSpace ℂ S inst✝¹ : AnalyticManifold I S inst✝ : LocallyConnectedSpace X t : Set Y n : Nonseparating t a : X x : Y ⊢ (a, x) ∉ univ ×ˢ t ↔ (a, x) ∈ univ ×ˢ tᶜ	no goals	Please generate a tactic in lean4 to solve the state. STATE: case h X : Type inst✝⁵ : TopologicalSpace X Y : Type inst✝⁴ : TopologicalSpace Y S : Type inst✝³ : TopologicalSpace S inst✝² : ChartedSpace ℂ S inst✝¹ : AnalyticManifold I S inst✝ : LocallyConnectedSpace X t : Set Y n : Nonseparating t a : X x : Y ⊢ (a, x) ∉ univ ×ˢ t ↔ (a, x) ∈ univ ×ˢ tᶜ TACTIC:
https://github.com/girving/ray.git	0be790285dd0fce78913b0cb9bddaffa94bd25f9	Ray/AnalyticManifold/Nonseparating.lean	Nonseparating.univ_prod	[33, 1]	[48, 40]	rw [e]	case dense X : Type inst✝⁵ : TopologicalSpace X Y : Type inst✝⁴ : TopologicalSpace Y S : Type inst✝³ : TopologicalSpace S inst✝² : ChartedSpace ℂ S inst✝¹ : AnalyticManifold I S inst✝ : LocallyConnectedSpace X t : Set Y n : Nonseparating t e : (univ ×ˢ t)ᶜ = univ ×ˢ tᶜ ⊢ Dense (univ ×ˢ t)ᶜ	case dense X : Type inst✝⁵ : TopologicalSpace X Y : Type inst✝⁴ : TopologicalSpace Y S : Type inst✝³ : TopologicalSpace S inst✝² : ChartedSpace ℂ S inst✝¹ : AnalyticManifold I S inst✝ : LocallyConnectedSpace X t : Set Y n : Nonseparating t e : (univ ×ˢ t)ᶜ = univ ×ˢ tᶜ ⊢ Dense (univ ×ˢ tᶜ)	Please generate a tactic in lean4 to solve the state. STATE: case dense X : Type inst✝⁵ : TopologicalSpace X Y : Type inst✝⁴ : TopologicalSpace Y S : Type inst✝³ : TopologicalSpace S inst✝² : ChartedSpace ℂ S inst✝¹ : AnalyticManifold I S inst✝ : LocallyConnectedSpace X t : Set Y n : Nonseparating t e : (univ ×ˢ t)ᶜ = univ ×ˢ tᶜ ⊢ Dense (univ ×ˢ t)ᶜ TACTIC:
https://github.com/girving/ray.git	0be790285dd0fce78913b0cb9bddaffa94bd25f9	Ray/AnalyticManifold/Nonseparating.lean	Nonseparating.univ_prod	[33, 1]	[48, 40]	exact dense_univ.prod n.dense	case dense X : Type inst✝⁵ : TopologicalSpace X Y : Type inst✝⁴ : TopologicalSpace Y S : Type inst✝³ : TopologicalSpace S inst✝² : ChartedSpace ℂ S inst✝¹ : AnalyticManifold I S inst✝ : LocallyConnectedSpace X t : Set Y n : Nonseparating t e : (univ ×ˢ t)ᶜ = univ ×ˢ tᶜ ⊢ Dense (univ ×ˢ tᶜ)	no goals	Please generate a tactic in lean4 to solve the state. STATE: case dense X : Type inst✝⁵ : TopologicalSpace X Y : Type inst✝⁴ : TopologicalSpace Y S : Type inst✝³ : TopologicalSpace S inst✝² : ChartedSpace ℂ S inst✝¹ : AnalyticManifold I S inst✝ : LocallyConnectedSpace X t : Set Y n : Nonseparating t e : (univ ×ˢ t)ᶜ = univ ×ˢ tᶜ ⊢ Dense (univ ×ˢ tᶜ) TACTIC:
https://github.com/girving/ray.git	0be790285dd0fce78913b0cb9bddaffa94bd25f9	Ray/AnalyticManifold/Nonseparating.lean	Nonseparating.univ_prod	[33, 1]	[48, 40]	intro ⟨a, x⟩ u m un	case loc X : Type inst✝⁵ : TopologicalSpace X Y : Type inst✝⁴ : TopologicalSpace Y S : Type inst✝³ : TopologicalSpace S inst✝² : ChartedSpace ℂ S inst✝¹ : AnalyticManifold I S inst✝ : LocallyConnectedSpace X t : Set Y n : Nonseparating t e : (univ ×ˢ t)ᶜ = univ ×ˢ tᶜ ⊢ ∀ (x : X × Y) (u : Set (X × Y)), x ∈ univ ×ˢ t → u ∈ 𝓝 x → ∃ c ⊆ u \ univ ×ˢ t, c ∈ 𝓝[(univ ×ˢ t)ᶜ] x ∧ IsPreconnected c	case loc X : Type inst✝⁵ : TopologicalSpace X Y : Type inst✝⁴ : TopologicalSpace Y S : Type inst✝³ : TopologicalSpace S inst✝² : ChartedSpace ℂ S inst✝¹ : AnalyticManifold I S inst✝ : LocallyConnectedSpace X t : Set Y n : Nonseparating t e : (univ ×ˢ t)ᶜ = univ ×ˢ tᶜ a : X x : Y u : Set (X × Y) m : (a, x) ∈ univ ×ˢ t un : u ∈ 𝓝 (a, x) ⊢ ∃ c ⊆ u \ univ ×ˢ t, c ∈ 𝓝[(univ ×ˢ t)ᶜ] (a, x) ∧ IsPreconnected c	Please generate a tactic in lean4 to solve the state. STATE: case loc X : Type inst✝⁵ : TopologicalSpace X Y : Type inst✝⁴ : TopologicalSpace Y S : Type inst✝³ : TopologicalSpace S inst✝² : ChartedSpace ℂ S inst✝¹ : AnalyticManifold I S inst✝ : LocallyConnectedSpace X t : Set Y n : Nonseparating t e : (univ ×ˢ t)ᶜ = univ ×ˢ tᶜ ⊢ ∀ (x : X × Y) (u : Set (X × Y)), x ∈ univ ×ˢ t → u ∈ 𝓝 x → ∃ c ⊆ u \ univ ×ˢ t, c ∈ 𝓝[(univ ×ˢ t)ᶜ] x ∧ IsPreconnected c TACTIC:
https://github.com/girving/ray.git	0be790285dd0fce78913b0cb9bddaffa94bd25f9	Ray/AnalyticManifold/Nonseparating.lean	Nonseparating.univ_prod	[33, 1]	[48, 40]	simp only [mem_prod_eq, mem_univ, true_and_iff] at m	case loc X : Type inst✝⁵ : TopologicalSpace X Y : Type inst✝⁴ : TopologicalSpace Y S : Type inst✝³ : TopologicalSpace S inst✝² : ChartedSpace ℂ S inst✝¹ : AnalyticManifold I S inst✝ : LocallyConnectedSpace X t : Set Y n : Nonseparating t e : (univ ×ˢ t)ᶜ = univ ×ˢ tᶜ a : X x : Y u : Set (X × Y) m : (a, x) ∈ univ ×ˢ t un : u ∈ 𝓝 (a, x) ⊢ ∃ c ⊆ u \ univ ×ˢ t, c ∈ 𝓝[(univ ×ˢ t)ᶜ] (a, x) ∧ IsPreconnected c	case loc X : Type inst✝⁵ : TopologicalSpace X Y : Type inst✝⁴ : TopologicalSpace Y S : Type inst✝³ : TopologicalSpace S inst✝² : ChartedSpace ℂ S inst✝¹ : AnalyticManifold I S inst✝ : LocallyConnectedSpace X t : Set Y n : Nonseparating t e : (univ ×ˢ t)ᶜ = univ ×ˢ tᶜ a : X x : Y u : Set (X × Y) un : u ∈ 𝓝 (a, x) m : x ∈ t ⊢ ∃ c ⊆ u \ univ ×ˢ t, c ∈ 𝓝[(univ ×ˢ t)ᶜ] (a, x) ∧ IsPreconnected c	Please generate a tactic in lean4 to solve the state. STATE: case loc X : Type inst✝⁵ : TopologicalSpace X Y : Type inst✝⁴ : TopologicalSpace Y S : Type inst✝³ : TopologicalSpace S inst✝² : ChartedSpace ℂ S inst✝¹ : AnalyticManifold I S inst✝ : LocallyConnectedSpace X t : Set Y n : Nonseparating t e : (univ ×ˢ t)ᶜ = univ ×ˢ tᶜ a : X x : Y u : Set (X × Y) m : (a, x) ∈ univ ×ˢ t un : u ∈ 𝓝 (a, x) ⊢ ∃ c ⊆ u \ univ ×ˢ t, c ∈ 𝓝[(univ ×ˢ t)ᶜ] (a, x) ∧ IsPreconnected c TACTIC:
https://github.com/girving/ray.git	0be790285dd0fce78913b0cb9bddaffa94bd25f9	Ray/AnalyticManifold/Nonseparating.lean	Nonseparating.univ_prod	[33, 1]	[48, 40]	rcases mem_nhds_prod_iff.mp un with ⟨u0, n0, u1, n1, uu⟩	case loc X : Type inst✝⁵ : TopologicalSpace X Y : Type inst✝⁴ : TopologicalSpace Y S : Type inst✝³ : TopologicalSpace S inst✝² : ChartedSpace ℂ S inst✝¹ : AnalyticManifold I S inst✝ : LocallyConnectedSpace X t : Set Y n : Nonseparating t e : (univ ×ˢ t)ᶜ = univ ×ˢ tᶜ a : X x : Y u : Set (X × Y) un : u ∈ 𝓝 (a, x) m : x ∈ t ⊢ ∃ c ⊆ u \ univ ×ˢ t, c ∈ 𝓝[(univ ×ˢ t)ᶜ] (a, x) ∧ IsPreconnected c	case loc.intro.intro.intro.intro X : Type inst✝⁵ : TopologicalSpace X Y : Type inst✝⁴ : TopologicalSpace Y S : Type inst✝³ : TopologicalSpace S inst✝² : ChartedSpace ℂ S inst✝¹ : AnalyticManifold I S inst✝ : LocallyConnectedSpace X t : Set Y n : Nonseparating t e : (univ ×ˢ t)ᶜ = univ ×ˢ tᶜ a : X x : Y u : Set (X × Y) un : u ∈ 𝓝 (a, x) m : x ∈ t u0 : Set X n0 : u0 ∈ 𝓝 a u1 : Set Y n1 : u1 ∈ 𝓝 x uu : u0 ×ˢ u1 ⊆ u ⊢ ∃ c ⊆ u \ univ ×ˢ t, c ∈ 𝓝[(univ ×ˢ t)ᶜ] (a, x) ∧ IsPreconnected c	Please generate a tactic in lean4 to solve the state. STATE: case loc X : Type inst✝⁵ : TopologicalSpace X Y : Type inst✝⁴ : TopologicalSpace Y S : Type inst✝³ : TopologicalSpace S inst✝² : ChartedSpace ℂ S inst✝¹ : AnalyticManifold I S inst✝ : LocallyConnectedSpace X t : Set Y n : Nonseparating t e : (univ ×ˢ t)ᶜ = univ ×ˢ tᶜ a : X x : Y u : Set (X × Y) un : u ∈ 𝓝 (a, x) m : x ∈ t ⊢ ∃ c ⊆ u \ univ ×ˢ t, c ∈ 𝓝[(univ ×ˢ t)ᶜ] (a, x) ∧ IsPreconnected c TACTIC:
https://github.com/girving/ray.git	0be790285dd0fce78913b0cb9bddaffa94bd25f9	Ray/AnalyticManifold/Nonseparating.lean	Nonseparating.univ_prod	[33, 1]	[48, 40]	rcases n.loc x u1 m n1 with ⟨c1, cs1, cn1, cp1⟩	case loc.intro.intro.intro.intro X : Type inst✝⁵ : TopologicalSpace X Y : Type inst✝⁴ : TopologicalSpace Y S : Type inst✝³ : TopologicalSpace S inst✝² : ChartedSpace ℂ S inst✝¹ : AnalyticManifold I S inst✝ : LocallyConnectedSpace X t : Set Y n : Nonseparating t e : (univ ×ˢ t)ᶜ = univ ×ˢ tᶜ a : X x : Y u : Set (X × Y) un : u ∈ 𝓝 (a, x) m : x ∈ t u0 : Set X n0 : u0 ∈ 𝓝 a u1 : Set Y n1 : u1 ∈ 𝓝 x uu : u0 ×ˢ u1 ⊆ u ⊢ ∃ c ⊆ u \ univ ×ˢ t, c ∈ 𝓝[(univ ×ˢ t)ᶜ] (a, x) ∧ IsPreconnected c	case loc.intro.intro.intro.intro.intro.intro.intro X : Type inst✝⁵ : TopologicalSpace X Y : Type inst✝⁴ : TopologicalSpace Y S : Type inst✝³ : TopologicalSpace S inst✝² : ChartedSpace ℂ S inst✝¹ : AnalyticManifold I S inst✝ : LocallyConnectedSpace X t : Set Y n : Nonseparating t e : (univ ×ˢ t)ᶜ = univ ×ˢ tᶜ a : X x : Y u : Set (X × Y) un : u ∈ 𝓝 (a, x) m : x ∈ t u0 : Set X n0 : u0 ∈ 𝓝 a u1 : Set Y n1 : u1 ∈ 𝓝 x uu : u0 ×ˢ u1 ⊆ u c1 : Set Y cs1 : c1 ⊆ u1 \ t cn1 : c1 ∈ 𝓝[tᶜ] x cp1 : IsPreconnected c1 ⊢ ∃ c ⊆ u \ univ ×ˢ t, c ∈ 𝓝[(univ ×ˢ t)ᶜ] (a, x) ∧ IsPreconnected c	Please generate a tactic in lean4 to solve the state. STATE: case loc.intro.intro.intro.intro X : Type inst✝⁵ : TopologicalSpace X Y : Type inst✝⁴ : TopologicalSpace Y S : Type inst✝³ : TopologicalSpace S inst✝² : ChartedSpace ℂ S inst✝¹ : AnalyticManifold I S inst✝ : LocallyConnectedSpace X t : Set Y n : Nonseparating t e : (univ ×ˢ t)ᶜ = univ ×ˢ tᶜ a : X x : Y u : Set (X × Y) un : u ∈ 𝓝 (a, x) m : x ∈ t u0 : Set X n0 : u0 ∈ 𝓝 a u1 : Set Y n1 : u1 ∈ 𝓝 x uu : u0 ×ˢ u1 ⊆ u ⊢ ∃ c ⊆ u \ univ ×ˢ t, c ∈ 𝓝[(univ ×ˢ t)ᶜ] (a, x) ∧ IsPreconnected c TACTIC:
https://github.com/girving/ray.git	0be790285dd0fce78913b0cb9bddaffa94bd25f9	Ray/AnalyticManifold/Nonseparating.lean	Nonseparating.univ_prod	[33, 1]	[48, 40]	rcases locallyConnectedSpace_iff_open_connected_subsets.mp (by infer_instance) a u0 n0 with ⟨c0, cs0, co0, cm0, cc0⟩	case loc.intro.intro.intro.intro.intro.intro.intro X : Type inst✝⁵ : TopologicalSpace X Y : Type inst✝⁴ : TopologicalSpace Y S : Type inst✝³ : TopologicalSpace S inst✝² : ChartedSpace ℂ S inst✝¹ : AnalyticManifold I S inst✝ : LocallyConnectedSpace X t : Set Y n : Nonseparating t e : (univ ×ˢ t)ᶜ = univ ×ˢ tᶜ a : X x : Y u : Set (X × Y) un : u ∈ 𝓝 (a, x) m : x ∈ t u0 : Set X n0 : u0 ∈ 𝓝 a u1 : Set Y n1 : u1 ∈ 𝓝 x uu : u0 ×ˢ u1 ⊆ u c1 : Set Y cs1 : c1 ⊆ u1 \ t cn1 : c1 ∈ 𝓝[tᶜ] x cp1 : IsPreconnected c1 ⊢ ∃ c ⊆ u \ univ ×ˢ t, c ∈ 𝓝[(univ ×ˢ t)ᶜ] (a, x) ∧ IsPreconnected c	case loc.intro.intro.intro.intro.intro.intro.intro.intro.intro.intro.intro X : Type inst✝⁵ : TopologicalSpace X Y : Type inst✝⁴ : TopologicalSpace Y S : Type inst✝³ : TopologicalSpace S inst✝² : ChartedSpace ℂ S inst✝¹ : AnalyticManifold I S inst✝ : LocallyConnectedSpace X t : Set Y n : Nonseparating t e : (univ ×ˢ t)ᶜ = univ ×ˢ tᶜ a : X x : Y u : Set (X × Y) un : u ∈ 𝓝 (a, x) m : x ∈ t u0 : Set X n0 : u0 ∈ 𝓝 a u1 : Set Y n1 : u1 ∈ 𝓝 x uu : u0 ×ˢ u1 ⊆ u c1 : Set Y cs1 : c1 ⊆ u1 \ t cn1 : c1 ∈ 𝓝[tᶜ] x cp1 : IsPreconnected c1 c0 : Set X cs0 : c0 ⊆ u0 co0 : IsOpen c0 cm0 : a ∈ c0 cc0 : IsConnected c0 ⊢ ∃ c ⊆ u \ univ ×ˢ t, c ∈ 𝓝[(univ ×ˢ t)ᶜ] (a, x) ∧ IsPreconnected c	Please generate a tactic in lean4 to solve the state. STATE: case loc.intro.intro.intro.intro.intro.intro.intro X : Type inst✝⁵ : TopologicalSpace X Y : Type inst✝⁴ : TopologicalSpace Y S : Type inst✝³ : TopologicalSpace S inst✝² : ChartedSpace ℂ S inst✝¹ : AnalyticManifold I S inst✝ : LocallyConnectedSpace X t : Set Y n : Nonseparating t e : (univ ×ˢ t)ᶜ = univ ×ˢ tᶜ a : X x : Y u : Set (X × Y) un : u ∈ 𝓝 (a, x) m : x ∈ t u0 : Set X n0 : u0 ∈ 𝓝 a u1 : Set Y n1 : u1 ∈ 𝓝 x uu : u0 ×ˢ u1 ⊆ u c1 : Set Y cs1 : c1 ⊆ u1 \ t cn1 : c1 ∈ 𝓝[tᶜ] x cp1 : IsPreconnected c1 ⊢ ∃ c ⊆ u \ univ ×ˢ t, c ∈ 𝓝[(univ ×ˢ t)ᶜ] (a, x) ∧ IsPreconnected c TACTIC:
https://github.com/girving/ray.git	0be790285dd0fce78913b0cb9bddaffa94bd25f9	Ray/AnalyticManifold/Nonseparating.lean	Nonseparating.univ_prod	[33, 1]	[48, 40]	use c0 ×ˢ c1	case loc.intro.intro.intro.intro.intro.intro.intro.intro.intro.intro.intro X : Type inst✝⁵ : TopologicalSpace X Y : Type inst✝⁴ : TopologicalSpace Y S : Type inst✝³ : TopologicalSpace S inst✝² : ChartedSpace ℂ S inst✝¹ : AnalyticManifold I S inst✝ : LocallyConnectedSpace X t : Set Y n : Nonseparating t e : (univ ×ˢ t)ᶜ = univ ×ˢ tᶜ a : X x : Y u : Set (X × Y) un : u ∈ 𝓝 (a, x) m : x ∈ t u0 : Set X n0 : u0 ∈ 𝓝 a u1 : Set Y n1 : u1 ∈ 𝓝 x uu : u0 ×ˢ u1 ⊆ u c1 : Set Y cs1 : c1 ⊆ u1 \ t cn1 : c1 ∈ 𝓝[tᶜ] x cp1 : IsPreconnected c1 c0 : Set X cs0 : c0 ⊆ u0 co0 : IsOpen c0 cm0 : a ∈ c0 cc0 : IsConnected c0 ⊢ ∃ c ⊆ u \ univ ×ˢ t, c ∈ 𝓝[(univ ×ˢ t)ᶜ] (a, x) ∧ IsPreconnected c	case h X : Type inst✝⁵ : TopologicalSpace X Y : Type inst✝⁴ : TopologicalSpace Y S : Type inst✝³ : TopologicalSpace S inst✝² : ChartedSpace ℂ S inst✝¹ : AnalyticManifold I S inst✝ : LocallyConnectedSpace X t : Set Y n : Nonseparating t e : (univ ×ˢ t)ᶜ = univ ×ˢ tᶜ a : X x : Y u : Set (X × Y) un : u ∈ 𝓝 (a, x) m : x ∈ t u0 : Set X n0 : u0 ∈ 𝓝 a u1 : Set Y n1 : u1 ∈ 𝓝 x uu : u0 ×ˢ u1 ⊆ u c1 : Set Y cs1 : c1 ⊆ u1 \ t cn1 : c1 ∈ 𝓝[tᶜ] x cp1 : IsPreconnected c1 c0 : Set X cs0 : c0 ⊆ u0 co0 : IsOpen c0 cm0 : a ∈ c0 cc0 : IsConnected c0 ⊢ c0 ×ˢ c1 ⊆ u \ univ ×ˢ t ∧ c0 ×ˢ c1 ∈ 𝓝[(univ ×ˢ t)ᶜ] (a, x) ∧ IsPreconnected (c0 ×ˢ c1)	Please generate a tactic in lean4 to solve the state. STATE: case loc.intro.intro.intro.intro.intro.intro.intro.intro.intro.intro.intro X : Type inst✝⁵ : TopologicalSpace X Y : Type inst✝⁴ : TopologicalSpace Y S : Type inst✝³ : TopologicalSpace S inst✝² : ChartedSpace ℂ S inst✝¹ : AnalyticManifold I S inst✝ : LocallyConnectedSpace X t : Set Y n : Nonseparating t e : (univ ×ˢ t)ᶜ = univ ×ˢ tᶜ a : X x : Y u : Set (X × Y) un : u ∈ 𝓝 (a, x) m : x ∈ t u0 : Set X n0 : u0 ∈ 𝓝 a u1 : Set Y n1 : u1 ∈ 𝓝 x uu : u0 ×ˢ u1 ⊆ u c1 : Set Y cs1 : c1 ⊆ u1 \ t cn1 : c1 ∈ 𝓝[tᶜ] x cp1 : IsPreconnected c1 c0 : Set X cs0 : c0 ⊆ u0 co0 : IsOpen c0 cm0 : a ∈ c0 cc0 : IsConnected c0 ⊢ ∃ c ⊆ u \ univ ×ˢ t, c ∈ 𝓝[(univ ×ˢ t)ᶜ] (a, x) ∧ IsPreconnected c TACTIC:
https://github.com/girving/ray.git	0be790285dd0fce78913b0cb9bddaffa94bd25f9	Ray/AnalyticManifold/Nonseparating.lean	Nonseparating.univ_prod	[33, 1]	[48, 40]	refine ⟨?_, ?_, ?_⟩	case h X : Type inst✝⁵ : TopologicalSpace X Y : Type inst✝⁴ : TopologicalSpace Y S : Type inst✝³ : TopologicalSpace S inst✝² : ChartedSpace ℂ S inst✝¹ : AnalyticManifold I S inst✝ : LocallyConnectedSpace X t : Set Y n : Nonseparating t e : (univ ×ˢ t)ᶜ = univ ×ˢ tᶜ a : X x : Y u : Set (X × Y) un : u ∈ 𝓝 (a, x) m : x ∈ t u0 : Set X n0 : u0 ∈ 𝓝 a u1 : Set Y n1 : u1 ∈ 𝓝 x uu : u0 ×ˢ u1 ⊆ u c1 : Set Y cs1 : c1 ⊆ u1 \ t cn1 : c1 ∈ 𝓝[tᶜ] x cp1 : IsPreconnected c1 c0 : Set X cs0 : c0 ⊆ u0 co0 : IsOpen c0 cm0 : a ∈ c0 cc0 : IsConnected c0 ⊢ c0 ×ˢ c1 ⊆ u \ univ ×ˢ t ∧ c0 ×ˢ c1 ∈ 𝓝[(univ ×ˢ t)ᶜ] (a, x) ∧ IsPreconnected (c0 ×ˢ c1)	case h.refine_1 X : Type inst✝⁵ : TopologicalSpace X Y : Type inst✝⁴ : TopologicalSpace Y S : Type inst✝³ : TopologicalSpace S inst✝² : ChartedSpace ℂ S inst✝¹ : AnalyticManifold I S inst✝ : LocallyConnectedSpace X t : Set Y n : Nonseparating t e : (univ ×ˢ t)ᶜ = univ ×ˢ tᶜ a : X x : Y u : Set (X × Y) un : u ∈ 𝓝 (a, x) m : x ∈ t u0 : Set X n0 : u0 ∈ 𝓝 a u1 : Set Y n1 : u1 ∈ 𝓝 x uu : u0 ×ˢ u1 ⊆ u c1 : Set Y cs1 : c1 ⊆ u1 \ t cn1 : c1 ∈ 𝓝[tᶜ] x cp1 : IsPreconnected c1 c0 : Set X cs0 : c0 ⊆ u0 co0 : IsOpen c0 cm0 : a ∈ c0 cc0 : IsConnected c0 ⊢ c0 ×ˢ c1 ⊆ u \ univ ×ˢ t case h.refine_2 X : Type inst✝⁵ : TopologicalSpace X Y : Type inst✝⁴ : TopologicalSpace Y S : Type inst✝³ : TopologicalSpace S inst✝² : ChartedSpace ℂ S inst✝¹ : AnalyticManifold I S inst✝ : LocallyConnectedSpace X t : Set Y n : Nonseparating t e : (univ ×ˢ t)ᶜ = univ ×ˢ tᶜ a : X x : Y u : Set (X × Y) un : u ∈ 𝓝 (a, x) m : x ∈ t u0 : Set X n0 : u0 ∈ 𝓝 a u1 : Set Y n1 : u1 ∈ 𝓝 x uu : u0 ×ˢ u1 ⊆ u c1 : Set Y cs1 : c1 ⊆ u1 \ t cn1 : c1 ∈ 𝓝[tᶜ] x cp1 : IsPreconnected c1 c0 : Set X cs0 : c0 ⊆ u0 co0 : IsOpen c0 cm0 : a ∈ c0 cc0 : IsConnected c0 ⊢ c0 ×ˢ c1 ∈ 𝓝[(univ ×ˢ t)ᶜ] (a, x) case h.refine_3 X : Type inst✝⁵ : TopologicalSpace X Y : Type inst✝⁴ : TopologicalSpace Y S : Type inst✝³ : TopologicalSpace S inst✝² : ChartedSpace ℂ S inst✝¹ : AnalyticManifold I S inst✝ : LocallyConnectedSpace X t : Set Y n : Nonseparating t e : (univ ×ˢ t)ᶜ = univ ×ˢ tᶜ a : X x : Y u : Set (X × Y) un : u ∈ 𝓝 (a, x) m : x ∈ t u0 : Set X n0 : u0 ∈ 𝓝 a u1 : Set Y n1 : u1 ∈ 𝓝 x uu : u0 ×ˢ u1 ⊆ u c1 : Set Y cs1 : c1 ⊆ u1 \ t cn1 : c1 ∈ 𝓝[tᶜ] x cp1 : IsPreconnected c1 c0 : Set X cs0 : c0 ⊆ u0 co0 : IsOpen c0 cm0 : a ∈ c0 cc0 : IsConnected c0 ⊢ IsPreconnected (c0 ×ˢ c1)	Please generate a tactic in lean4 to solve the state. STATE: case h X : Type inst✝⁵ : TopologicalSpace X Y : Type inst✝⁴ : TopologicalSpace Y S : Type inst✝³ : TopologicalSpace S inst✝² : ChartedSpace ℂ S inst✝¹ : AnalyticManifold I S inst✝ : LocallyConnectedSpace X t : Set Y n : Nonseparating t e : (univ ×ˢ t)ᶜ = univ ×ˢ tᶜ a : X x : Y u : Set (X × Y) un : u ∈ 𝓝 (a, x) m : x ∈ t u0 : Set X n0 : u0 ∈ 𝓝 a u1 : Set Y n1 : u1 ∈ 𝓝 x uu : u0 ×ˢ u1 ⊆ u c1 : Set Y cs1 : c1 ⊆ u1 \ t cn1 : c1 ∈ 𝓝[tᶜ] x cp1 : IsPreconnected c1 c0 : Set X cs0 : c0 ⊆ u0 co0 : IsOpen c0 cm0 : a ∈ c0 cc0 : IsConnected c0 ⊢ c0 ×ˢ c1 ⊆ u \ univ ×ˢ t ∧ c0 ×ˢ c1 ∈ 𝓝[(univ ×ˢ t)ᶜ] (a, x) ∧ IsPreconnected (c0 ×ˢ c1) TACTIC:
https://github.com/girving/ray.git	0be790285dd0fce78913b0cb9bddaffa94bd25f9	Ray/AnalyticManifold/Nonseparating.lean	Nonseparating.univ_prod	[33, 1]	[48, 40]	infer_instance	X : Type inst✝⁵ : TopologicalSpace X Y : Type inst✝⁴ : TopologicalSpace Y S : Type inst✝³ : TopologicalSpace S inst✝² : ChartedSpace ℂ S inst✝¹ : AnalyticManifold I S inst✝ : LocallyConnectedSpace X t : Set Y n : Nonseparating t e : (univ ×ˢ t)ᶜ = univ ×ˢ tᶜ a : X x : Y u : Set (X × Y) un : u ∈ 𝓝 (a, x) m : x ∈ t u0 : Set X n0 : u0 ∈ 𝓝 a u1 : Set Y n1 : u1 ∈ 𝓝 x uu : u0 ×ˢ u1 ⊆ u c1 : Set Y cs1 : c1 ⊆ u1 \ t cn1 : c1 ∈ 𝓝[tᶜ] x cp1 : IsPreconnected c1 ⊢ LocallyConnectedSpace X	no goals	Please generate a tactic in lean4 to solve the state. STATE: X : Type inst✝⁵ : TopologicalSpace X Y : Type inst✝⁴ : TopologicalSpace Y S : Type inst✝³ : TopologicalSpace S inst✝² : ChartedSpace ℂ S inst✝¹ : AnalyticManifold I S inst✝ : LocallyConnectedSpace X t : Set Y n : Nonseparating t e : (univ ×ˢ t)ᶜ = univ ×ˢ tᶜ a : X x : Y u : Set (X × Y) un : u ∈ 𝓝 (a, x) m : x ∈ t u0 : Set X n0 : u0 ∈ 𝓝 a u1 : Set Y n1 : u1 ∈ 𝓝 x uu : u0 ×ˢ u1 ⊆ u c1 : Set Y cs1 : c1 ⊆ u1 \ t cn1 : c1 ∈ 𝓝[tᶜ] x cp1 : IsPreconnected c1 ⊢ LocallyConnectedSpace X TACTIC:

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