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/Iterates.lean	iter_error_le	[276, 1]	[342, 54]	bound	c✝ : ℂ d : ℕ inst✝ : Fact (2 ≤ d) i b s0 s1 s2 : ℝ c : ℂ b3 : 3 ≤ b s1p : 0 ≤ s1 s2p : 0 ≤ s2 bs0 : ∀ {w : ℂ}, b ≤ Complex.abs w → f_error d w ≤ s0 / (Complex.abs w * (Complex.abs w).log) bs1 : ∀ {w : ℂ}, (b ^ (d - 1) - 1) * b ≤ Complex.abs w → f_error d w ≤ s1 / (Complex.abs w * (Complex.abs w).log) b0' : 0 < b ^ (d - 1) - 1 z : ℂ bz : b ≤ Complex.abs z cz : Complex.abs c ≤ Complex.abs z b0 : 0 < b z0 : 0 < Complex.abs z z3 : 3 ≤ Complex.abs z l0 : 1 < (Complex.abs z).log bb : ℝ hbb : (b ^ (d - 1) - 1) ^ d * b ^ (d - 1) - 1 = bb b11 : 11 ≤ bb bb3 : 3 ≤ bb * b bs2 : ∀ {w : ℂ}, bb * b ≤ Complex.abs w → f_error d w ≤ s2 / (Complex.abs w * (Complex.abs w).log) b0'' : 0 < 1 - (bb * b - 1)⁻¹ si : s0 + s1 / (b ^ (d - 1) - 1) + s2 / ((1 - (bb * b - 1)⁻¹) * bb) ≤ i fz : Complex.abs z ^ d - Complex.abs c ≤ Complex.abs (f' d c z) ⊢ (Complex.abs z ^ (d - 1) - 1) * Complex.abs z ≥ (b ^ (d - 1) - 1) * Complex.abs z	no goals	Please generate a tactic in lean4 to solve the state. STATE: c✝ : ℂ d : ℕ inst✝ : Fact (2 ≤ d) i b s0 s1 s2 : ℝ c : ℂ b3 : 3 ≤ b s1p : 0 ≤ s1 s2p : 0 ≤ s2 bs0 : ∀ {w : ℂ}, b ≤ Complex.abs w → f_error d w ≤ s0 / (Complex.abs w * (Complex.abs w).log) bs1 : ∀ {w : ℂ}, (b ^ (d - 1) - 1) * b ≤ Complex.abs w → f_error d w ≤ s1 / (Complex.abs w * (Complex.abs w).log) b0' : 0 < b ^ (d - 1) - 1 z : ℂ bz : b ≤ Complex.abs z cz : Complex.abs c ≤ Complex.abs z b0 : 0 < b z0 : 0 < Complex.abs z z3 : 3 ≤ Complex.abs z l0 : 1 < (Complex.abs z).log bb : ℝ hbb : (b ^ (d - 1) - 1) ^ d * b ^ (d - 1) - 1 = bb b11 : 11 ≤ bb bb3 : 3 ≤ bb * b bs2 : ∀ {w : ℂ}, bb * b ≤ Complex.abs w → f_error d w ≤ s2 / (Complex.abs w * (Complex.abs w).log) b0'' : 0 < 1 - (bb * b - 1)⁻¹ si : s0 + s1 / (b ^ (d - 1) - 1) + s2 / ((1 - (bb * b - 1)⁻¹) * bb) ≤ i fz : Complex.abs z ^ d - Complex.abs c ≤ Complex.abs (f' d c z) ⊢ (Complex.abs z ^ (d - 1) - 1) * Complex.abs z ≥ (b ^ (d - 1) - 1) * Complex.abs z TACTIC:
https://github.com/girving/ray.git	0be790285dd0fce78913b0cb9bddaffa94bd25f9	Ray/Dynamics/Multibrot/Iterates.lean	iter_error_le	[276, 1]	[342, 54]	calc abs ((f' d c z)^d + c) _ ≥ abs ((f' d c z)^d) - abs c := by bound _ = (abs (f' d c z))^d - abs c := by rw [Complex.abs.map_pow] _ ≥ ((b^(d-1)-1) * abs z)^d - abs z := by bound _ = (b^(d-1)-1)^d * (abs z)^(d-1) * abs z - abs z := by rw [mul_assoc, ←pow_succ, mul_pow, Nat.sub_add_cancel (d_ge_one d)] _ ≥ (b^(d-1)-1)^d * b^(d-1) * abs z - abs z := by bound _ = bb * abs z := by rw [←hbb, sub_one_mul]	c✝ : ℂ d : ℕ inst✝ : Fact (2 ≤ d) i b s0 s1 s2 : ℝ c : ℂ b3 : 3 ≤ b s1p : 0 ≤ s1 s2p : 0 ≤ s2 bs0 : ∀ {w : ℂ}, b ≤ Complex.abs w → f_error d w ≤ s0 / (Complex.abs w * (Complex.abs w).log) bs1 : ∀ {w : ℂ}, (b ^ (d - 1) - 1) * b ≤ Complex.abs w → f_error d w ≤ s1 / (Complex.abs w * (Complex.abs w).log) b0' : 0 < b ^ (d - 1) - 1 z : ℂ bz : b ≤ Complex.abs z cz : Complex.abs c ≤ Complex.abs z b0 : 0 < b z0 : 0 < Complex.abs z z3 : 3 ≤ Complex.abs z l0 : 1 < (Complex.abs z).log bb : ℝ hbb : (b ^ (d - 1) - 1) ^ d * b ^ (d - 1) - 1 = bb b11 : 11 ≤ bb bb3 : 3 ≤ bb * b bs2 : ∀ {w : ℂ}, bb * b ≤ Complex.abs w → f_error d w ≤ s2 / (Complex.abs w * (Complex.abs w).log) b0'' : 0 < 1 - (bb * b - 1)⁻¹ si : s0 + s1 / (b ^ (d - 1) - 1) + s2 / ((1 - (bb * b - 1)⁻¹) * bb) ≤ i fz : Complex.abs z ^ d - Complex.abs c ≤ Complex.abs (f' d c z) fz' : (b ^ (d - 1) - 1) * Complex.abs z ≤ Complex.abs (f' d c z) zfz : Complex.abs z ≤ Complex.abs (f' d c z) zffz : Complex.abs z ≤ Complex.abs (f' d c (f' d c z)) bfz : b ≤ Complex.abs (f' d c z) ⊢ bb * Complex.abs z ≤ Complex.abs (f' d c (f' d c z))	no goals	Please generate a tactic in lean4 to solve the state. STATE: c✝ : ℂ d : ℕ inst✝ : Fact (2 ≤ d) i b s0 s1 s2 : ℝ c : ℂ b3 : 3 ≤ b s1p : 0 ≤ s1 s2p : 0 ≤ s2 bs0 : ∀ {w : ℂ}, b ≤ Complex.abs w → f_error d w ≤ s0 / (Complex.abs w * (Complex.abs w).log) bs1 : ∀ {w : ℂ}, (b ^ (d - 1) - 1) * b ≤ Complex.abs w → f_error d w ≤ s1 / (Complex.abs w * (Complex.abs w).log) b0' : 0 < b ^ (d - 1) - 1 z : ℂ bz : b ≤ Complex.abs z cz : Complex.abs c ≤ Complex.abs z b0 : 0 < b z0 : 0 < Complex.abs z z3 : 3 ≤ Complex.abs z l0 : 1 < (Complex.abs z).log bb : ℝ hbb : (b ^ (d - 1) - 1) ^ d * b ^ (d - 1) - 1 = bb b11 : 11 ≤ bb bb3 : 3 ≤ bb * b bs2 : ∀ {w : ℂ}, bb * b ≤ Complex.abs w → f_error d w ≤ s2 / (Complex.abs w * (Complex.abs w).log) b0'' : 0 < 1 - (bb * b - 1)⁻¹ si : s0 + s1 / (b ^ (d - 1) - 1) + s2 / ((1 - (bb * b - 1)⁻¹) * bb) ≤ i fz : Complex.abs z ^ d - Complex.abs c ≤ Complex.abs (f' d c z) fz' : (b ^ (d - 1) - 1) * Complex.abs z ≤ Complex.abs (f' d c z) zfz : Complex.abs z ≤ Complex.abs (f' d c z) zffz : Complex.abs z ≤ Complex.abs (f' d c (f' d c z)) bfz : b ≤ Complex.abs (f' d c z) ⊢ bb * Complex.abs z ≤ Complex.abs (f' d c (f' d c z)) TACTIC:
https://github.com/girving/ray.git	0be790285dd0fce78913b0cb9bddaffa94bd25f9	Ray/Dynamics/Multibrot/Iterates.lean	iter_error_le	[276, 1]	[342, 54]	bound	c✝ : ℂ d : ℕ inst✝ : Fact (2 ≤ d) i b s0 s1 s2 : ℝ c : ℂ b3 : 3 ≤ b s1p : 0 ≤ s1 s2p : 0 ≤ s2 bs0 : ∀ {w : ℂ}, b ≤ Complex.abs w → f_error d w ≤ s0 / (Complex.abs w * (Complex.abs w).log) bs1 : ∀ {w : ℂ}, (b ^ (d - 1) - 1) * b ≤ Complex.abs w → f_error d w ≤ s1 / (Complex.abs w * (Complex.abs w).log) b0' : 0 < b ^ (d - 1) - 1 z : ℂ bz : b ≤ Complex.abs z cz : Complex.abs c ≤ Complex.abs z b0 : 0 < b z0 : 0 < Complex.abs z z3 : 3 ≤ Complex.abs z l0 : 1 < (Complex.abs z).log bb : ℝ hbb : (b ^ (d - 1) - 1) ^ d * b ^ (d - 1) - 1 = bb b11 : 11 ≤ bb bb3 : 3 ≤ bb * b bs2 : ∀ {w : ℂ}, bb * b ≤ Complex.abs w → f_error d w ≤ s2 / (Complex.abs w * (Complex.abs w).log) b0'' : 0 < 1 - (bb * b - 1)⁻¹ si : s0 + s1 / (b ^ (d - 1) - 1) + s2 / ((1 - (bb * b - 1)⁻¹) * bb) ≤ i fz : Complex.abs z ^ d - Complex.abs c ≤ Complex.abs (f' d c z) fz' : (b ^ (d - 1) - 1) * Complex.abs z ≤ Complex.abs (f' d c z) zfz : Complex.abs z ≤ Complex.abs (f' d c z) zffz : Complex.abs z ≤ Complex.abs (f' d c (f' d c z)) bfz : b ≤ Complex.abs (f' d c z) ⊢ Complex.abs (f' d c z ^ d + c) ≥ Complex.abs (f' d c z ^ d) - Complex.abs c	no goals	Please generate a tactic in lean4 to solve the state. STATE: c✝ : ℂ d : ℕ inst✝ : Fact (2 ≤ d) i b s0 s1 s2 : ℝ c : ℂ b3 : 3 ≤ b s1p : 0 ≤ s1 s2p : 0 ≤ s2 bs0 : ∀ {w : ℂ}, b ≤ Complex.abs w → f_error d w ≤ s0 / (Complex.abs w * (Complex.abs w).log) bs1 : ∀ {w : ℂ}, (b ^ (d - 1) - 1) * b ≤ Complex.abs w → f_error d w ≤ s1 / (Complex.abs w * (Complex.abs w).log) b0' : 0 < b ^ (d - 1) - 1 z : ℂ bz : b ≤ Complex.abs z cz : Complex.abs c ≤ Complex.abs z b0 : 0 < b z0 : 0 < Complex.abs z z3 : 3 ≤ Complex.abs z l0 : 1 < (Complex.abs z).log bb : ℝ hbb : (b ^ (d - 1) - 1) ^ d * b ^ (d - 1) - 1 = bb b11 : 11 ≤ bb bb3 : 3 ≤ bb * b bs2 : ∀ {w : ℂ}, bb * b ≤ Complex.abs w → f_error d w ≤ s2 / (Complex.abs w * (Complex.abs w).log) b0'' : 0 < 1 - (bb * b - 1)⁻¹ si : s0 + s1 / (b ^ (d - 1) - 1) + s2 / ((1 - (bb * b - 1)⁻¹) * bb) ≤ i fz : Complex.abs z ^ d - Complex.abs c ≤ Complex.abs (f' d c z) fz' : (b ^ (d - 1) - 1) * Complex.abs z ≤ Complex.abs (f' d c z) zfz : Complex.abs z ≤ Complex.abs (f' d c z) zffz : Complex.abs z ≤ Complex.abs (f' d c (f' d c z)) bfz : b ≤ Complex.abs (f' d c z) ⊢ Complex.abs (f' d c z ^ d + c) ≥ Complex.abs (f' d c z ^ d) - Complex.abs c TACTIC:
https://github.com/girving/ray.git	0be790285dd0fce78913b0cb9bddaffa94bd25f9	Ray/Dynamics/Multibrot/Iterates.lean	iter_error_le	[276, 1]	[342, 54]	rw [Complex.abs.map_pow]	c✝ : ℂ d : ℕ inst✝ : Fact (2 ≤ d) i b s0 s1 s2 : ℝ c : ℂ b3 : 3 ≤ b s1p : 0 ≤ s1 s2p : 0 ≤ s2 bs0 : ∀ {w : ℂ}, b ≤ Complex.abs w → f_error d w ≤ s0 / (Complex.abs w * (Complex.abs w).log) bs1 : ∀ {w : ℂ}, (b ^ (d - 1) - 1) * b ≤ Complex.abs w → f_error d w ≤ s1 / (Complex.abs w * (Complex.abs w).log) b0' : 0 < b ^ (d - 1) - 1 z : ℂ bz : b ≤ Complex.abs z cz : Complex.abs c ≤ Complex.abs z b0 : 0 < b z0 : 0 < Complex.abs z z3 : 3 ≤ Complex.abs z l0 : 1 < (Complex.abs z).log bb : ℝ hbb : (b ^ (d - 1) - 1) ^ d * b ^ (d - 1) - 1 = bb b11 : 11 ≤ bb bb3 : 3 ≤ bb * b bs2 : ∀ {w : ℂ}, bb * b ≤ Complex.abs w → f_error d w ≤ s2 / (Complex.abs w * (Complex.abs w).log) b0'' : 0 < 1 - (bb * b - 1)⁻¹ si : s0 + s1 / (b ^ (d - 1) - 1) + s2 / ((1 - (bb * b - 1)⁻¹) * bb) ≤ i fz : Complex.abs z ^ d - Complex.abs c ≤ Complex.abs (f' d c z) fz' : (b ^ (d - 1) - 1) * Complex.abs z ≤ Complex.abs (f' d c z) zfz : Complex.abs z ≤ Complex.abs (f' d c z) zffz : Complex.abs z ≤ Complex.abs (f' d c (f' d c z)) bfz : b ≤ Complex.abs (f' d c z) ⊢ Complex.abs (f' d c z ^ d) - Complex.abs c = Complex.abs (f' d c z) ^ d - Complex.abs c	no goals	Please generate a tactic in lean4 to solve the state. STATE: c✝ : ℂ d : ℕ inst✝ : Fact (2 ≤ d) i b s0 s1 s2 : ℝ c : ℂ b3 : 3 ≤ b s1p : 0 ≤ s1 s2p : 0 ≤ s2 bs0 : ∀ {w : ℂ}, b ≤ Complex.abs w → f_error d w ≤ s0 / (Complex.abs w * (Complex.abs w).log) bs1 : ∀ {w : ℂ}, (b ^ (d - 1) - 1) * b ≤ Complex.abs w → f_error d w ≤ s1 / (Complex.abs w * (Complex.abs w).log) b0' : 0 < b ^ (d - 1) - 1 z : ℂ bz : b ≤ Complex.abs z cz : Complex.abs c ≤ Complex.abs z b0 : 0 < b z0 : 0 < Complex.abs z z3 : 3 ≤ Complex.abs z l0 : 1 < (Complex.abs z).log bb : ℝ hbb : (b ^ (d - 1) - 1) ^ d * b ^ (d - 1) - 1 = bb b11 : 11 ≤ bb bb3 : 3 ≤ bb * b bs2 : ∀ {w : ℂ}, bb * b ≤ Complex.abs w → f_error d w ≤ s2 / (Complex.abs w * (Complex.abs w).log) b0'' : 0 < 1 - (bb * b - 1)⁻¹ si : s0 + s1 / (b ^ (d - 1) - 1) + s2 / ((1 - (bb * b - 1)⁻¹) * bb) ≤ i fz : Complex.abs z ^ d - Complex.abs c ≤ Complex.abs (f' d c z) fz' : (b ^ (d - 1) - 1) * Complex.abs z ≤ Complex.abs (f' d c z) zfz : Complex.abs z ≤ Complex.abs (f' d c z) zffz : Complex.abs z ≤ Complex.abs (f' d c (f' d c z)) bfz : b ≤ Complex.abs (f' d c z) ⊢ Complex.abs (f' d c z ^ d) - Complex.abs c = Complex.abs (f' d c z) ^ d - Complex.abs c TACTIC:
https://github.com/girving/ray.git	0be790285dd0fce78913b0cb9bddaffa94bd25f9	Ray/Dynamics/Multibrot/Iterates.lean	iter_error_le	[276, 1]	[342, 54]	bound	c✝ : ℂ d : ℕ inst✝ : Fact (2 ≤ d) i b s0 s1 s2 : ℝ c : ℂ b3 : 3 ≤ b s1p : 0 ≤ s1 s2p : 0 ≤ s2 bs0 : ∀ {w : ℂ}, b ≤ Complex.abs w → f_error d w ≤ s0 / (Complex.abs w * (Complex.abs w).log) bs1 : ∀ {w : ℂ}, (b ^ (d - 1) - 1) * b ≤ Complex.abs w → f_error d w ≤ s1 / (Complex.abs w * (Complex.abs w).log) b0' : 0 < b ^ (d - 1) - 1 z : ℂ bz : b ≤ Complex.abs z cz : Complex.abs c ≤ Complex.abs z b0 : 0 < b z0 : 0 < Complex.abs z z3 : 3 ≤ Complex.abs z l0 : 1 < (Complex.abs z).log bb : ℝ hbb : (b ^ (d - 1) - 1) ^ d * b ^ (d - 1) - 1 = bb b11 : 11 ≤ bb bb3 : 3 ≤ bb * b bs2 : ∀ {w : ℂ}, bb * b ≤ Complex.abs w → f_error d w ≤ s2 / (Complex.abs w * (Complex.abs w).log) b0'' : 0 < 1 - (bb * b - 1)⁻¹ si : s0 + s1 / (b ^ (d - 1) - 1) + s2 / ((1 - (bb * b - 1)⁻¹) * bb) ≤ i fz : Complex.abs z ^ d - Complex.abs c ≤ Complex.abs (f' d c z) fz' : (b ^ (d - 1) - 1) * Complex.abs z ≤ Complex.abs (f' d c z) zfz : Complex.abs z ≤ Complex.abs (f' d c z) zffz : Complex.abs z ≤ Complex.abs (f' d c (f' d c z)) bfz : b ≤ Complex.abs (f' d c z) ⊢ Complex.abs (f' d c z) ^ d - Complex.abs c ≥ ((b ^ (d - 1) - 1) * Complex.abs z) ^ d - Complex.abs z	no goals	Please generate a tactic in lean4 to solve the state. STATE: c✝ : ℂ d : ℕ inst✝ : Fact (2 ≤ d) i b s0 s1 s2 : ℝ c : ℂ b3 : 3 ≤ b s1p : 0 ≤ s1 s2p : 0 ≤ s2 bs0 : ∀ {w : ℂ}, b ≤ Complex.abs w → f_error d w ≤ s0 / (Complex.abs w * (Complex.abs w).log) bs1 : ∀ {w : ℂ}, (b ^ (d - 1) - 1) * b ≤ Complex.abs w → f_error d w ≤ s1 / (Complex.abs w * (Complex.abs w).log) b0' : 0 < b ^ (d - 1) - 1 z : ℂ bz : b ≤ Complex.abs z cz : Complex.abs c ≤ Complex.abs z b0 : 0 < b z0 : 0 < Complex.abs z z3 : 3 ≤ Complex.abs z l0 : 1 < (Complex.abs z).log bb : ℝ hbb : (b ^ (d - 1) - 1) ^ d * b ^ (d - 1) - 1 = bb b11 : 11 ≤ bb bb3 : 3 ≤ bb * b bs2 : ∀ {w : ℂ}, bb * b ≤ Complex.abs w → f_error d w ≤ s2 / (Complex.abs w * (Complex.abs w).log) b0'' : 0 < 1 - (bb * b - 1)⁻¹ si : s0 + s1 / (b ^ (d - 1) - 1) + s2 / ((1 - (bb * b - 1)⁻¹) * bb) ≤ i fz : Complex.abs z ^ d - Complex.abs c ≤ Complex.abs (f' d c z) fz' : (b ^ (d - 1) - 1) * Complex.abs z ≤ Complex.abs (f' d c z) zfz : Complex.abs z ≤ Complex.abs (f' d c z) zffz : Complex.abs z ≤ Complex.abs (f' d c (f' d c z)) bfz : b ≤ Complex.abs (f' d c z) ⊢ Complex.abs (f' d c z) ^ d - Complex.abs c ≥ ((b ^ (d - 1) - 1) * Complex.abs z) ^ d - Complex.abs z TACTIC:
https://github.com/girving/ray.git	0be790285dd0fce78913b0cb9bddaffa94bd25f9	Ray/Dynamics/Multibrot/Iterates.lean	iter_error_le	[276, 1]	[342, 54]	rw [mul_assoc, ←pow_succ, mul_pow, Nat.sub_add_cancel (d_ge_one d)]	c✝ : ℂ d : ℕ inst✝ : Fact (2 ≤ d) i b s0 s1 s2 : ℝ c : ℂ b3 : 3 ≤ b s1p : 0 ≤ s1 s2p : 0 ≤ s2 bs0 : ∀ {w : ℂ}, b ≤ Complex.abs w → f_error d w ≤ s0 / (Complex.abs w * (Complex.abs w).log) bs1 : ∀ {w : ℂ}, (b ^ (d - 1) - 1) * b ≤ Complex.abs w → f_error d w ≤ s1 / (Complex.abs w * (Complex.abs w).log) b0' : 0 < b ^ (d - 1) - 1 z : ℂ bz : b ≤ Complex.abs z cz : Complex.abs c ≤ Complex.abs z b0 : 0 < b z0 : 0 < Complex.abs z z3 : 3 ≤ Complex.abs z l0 : 1 < (Complex.abs z).log bb : ℝ hbb : (b ^ (d - 1) - 1) ^ d * b ^ (d - 1) - 1 = bb b11 : 11 ≤ bb bb3 : 3 ≤ bb * b bs2 : ∀ {w : ℂ}, bb * b ≤ Complex.abs w → f_error d w ≤ s2 / (Complex.abs w * (Complex.abs w).log) b0'' : 0 < 1 - (bb * b - 1)⁻¹ si : s0 + s1 / (b ^ (d - 1) - 1) + s2 / ((1 - (bb * b - 1)⁻¹) * bb) ≤ i fz : Complex.abs z ^ d - Complex.abs c ≤ Complex.abs (f' d c z) fz' : (b ^ (d - 1) - 1) * Complex.abs z ≤ Complex.abs (f' d c z) zfz : Complex.abs z ≤ Complex.abs (f' d c z) zffz : Complex.abs z ≤ Complex.abs (f' d c (f' d c z)) bfz : b ≤ Complex.abs (f' d c z) ⊢ ((b ^ (d - 1) - 1) * Complex.abs z) ^ d - Complex.abs z = (b ^ (d - 1) - 1) ^ d * Complex.abs z ^ (d - 1) * Complex.abs z - Complex.abs z	no goals	Please generate a tactic in lean4 to solve the state. STATE: c✝ : ℂ d : ℕ inst✝ : Fact (2 ≤ d) i b s0 s1 s2 : ℝ c : ℂ b3 : 3 ≤ b s1p : 0 ≤ s1 s2p : 0 ≤ s2 bs0 : ∀ {w : ℂ}, b ≤ Complex.abs w → f_error d w ≤ s0 / (Complex.abs w * (Complex.abs w).log) bs1 : ∀ {w : ℂ}, (b ^ (d - 1) - 1) * b ≤ Complex.abs w → f_error d w ≤ s1 / (Complex.abs w * (Complex.abs w).log) b0' : 0 < b ^ (d - 1) - 1 z : ℂ bz : b ≤ Complex.abs z cz : Complex.abs c ≤ Complex.abs z b0 : 0 < b z0 : 0 < Complex.abs z z3 : 3 ≤ Complex.abs z l0 : 1 < (Complex.abs z).log bb : ℝ hbb : (b ^ (d - 1) - 1) ^ d * b ^ (d - 1) - 1 = bb b11 : 11 ≤ bb bb3 : 3 ≤ bb * b bs2 : ∀ {w : ℂ}, bb * b ≤ Complex.abs w → f_error d w ≤ s2 / (Complex.abs w * (Complex.abs w).log) b0'' : 0 < 1 - (bb * b - 1)⁻¹ si : s0 + s1 / (b ^ (d - 1) - 1) + s2 / ((1 - (bb * b - 1)⁻¹) * bb) ≤ i fz : Complex.abs z ^ d - Complex.abs c ≤ Complex.abs (f' d c z) fz' : (b ^ (d - 1) - 1) * Complex.abs z ≤ Complex.abs (f' d c z) zfz : Complex.abs z ≤ Complex.abs (f' d c z) zffz : Complex.abs z ≤ Complex.abs (f' d c (f' d c z)) bfz : b ≤ Complex.abs (f' d c z) ⊢ ((b ^ (d - 1) - 1) * Complex.abs z) ^ d - Complex.abs z = (b ^ (d - 1) - 1) ^ d * Complex.abs z ^ (d - 1) * Complex.abs z - Complex.abs z TACTIC:
https://github.com/girving/ray.git	0be790285dd0fce78913b0cb9bddaffa94bd25f9	Ray/Dynamics/Multibrot/Iterates.lean	iter_error_le	[276, 1]	[342, 54]	bound	c✝ : ℂ d : ℕ inst✝ : Fact (2 ≤ d) i b s0 s1 s2 : ℝ c : ℂ b3 : 3 ≤ b s1p : 0 ≤ s1 s2p : 0 ≤ s2 bs0 : ∀ {w : ℂ}, b ≤ Complex.abs w → f_error d w ≤ s0 / (Complex.abs w * (Complex.abs w).log) bs1 : ∀ {w : ℂ}, (b ^ (d - 1) - 1) * b ≤ Complex.abs w → f_error d w ≤ s1 / (Complex.abs w * (Complex.abs w).log) b0' : 0 < b ^ (d - 1) - 1 z : ℂ bz : b ≤ Complex.abs z cz : Complex.abs c ≤ Complex.abs z b0 : 0 < b z0 : 0 < Complex.abs z z3 : 3 ≤ Complex.abs z l0 : 1 < (Complex.abs z).log bb : ℝ hbb : (b ^ (d - 1) - 1) ^ d * b ^ (d - 1) - 1 = bb b11 : 11 ≤ bb bb3 : 3 ≤ bb * b bs2 : ∀ {w : ℂ}, bb * b ≤ Complex.abs w → f_error d w ≤ s2 / (Complex.abs w * (Complex.abs w).log) b0'' : 0 < 1 - (bb * b - 1)⁻¹ si : s0 + s1 / (b ^ (d - 1) - 1) + s2 / ((1 - (bb * b - 1)⁻¹) * bb) ≤ i fz : Complex.abs z ^ d - Complex.abs c ≤ Complex.abs (f' d c z) fz' : (b ^ (d - 1) - 1) * Complex.abs z ≤ Complex.abs (f' d c z) zfz : Complex.abs z ≤ Complex.abs (f' d c z) zffz : Complex.abs z ≤ Complex.abs (f' d c (f' d c z)) bfz : b ≤ Complex.abs (f' d c z) ⊢ (b ^ (d - 1) - 1) ^ d * Complex.abs z ^ (d - 1) * Complex.abs z - Complex.abs z ≥ (b ^ (d - 1) - 1) ^ d * b ^ (d - 1) * Complex.abs z - Complex.abs z	no goals	Please generate a tactic in lean4 to solve the state. STATE: c✝ : ℂ d : ℕ inst✝ : Fact (2 ≤ d) i b s0 s1 s2 : ℝ c : ℂ b3 : 3 ≤ b s1p : 0 ≤ s1 s2p : 0 ≤ s2 bs0 : ∀ {w : ℂ}, b ≤ Complex.abs w → f_error d w ≤ s0 / (Complex.abs w * (Complex.abs w).log) bs1 : ∀ {w : ℂ}, (b ^ (d - 1) - 1) * b ≤ Complex.abs w → f_error d w ≤ s1 / (Complex.abs w * (Complex.abs w).log) b0' : 0 < b ^ (d - 1) - 1 z : ℂ bz : b ≤ Complex.abs z cz : Complex.abs c ≤ Complex.abs z b0 : 0 < b z0 : 0 < Complex.abs z z3 : 3 ≤ Complex.abs z l0 : 1 < (Complex.abs z).log bb : ℝ hbb : (b ^ (d - 1) - 1) ^ d * b ^ (d - 1) - 1 = bb b11 : 11 ≤ bb bb3 : 3 ≤ bb * b bs2 : ∀ {w : ℂ}, bb * b ≤ Complex.abs w → f_error d w ≤ s2 / (Complex.abs w * (Complex.abs w).log) b0'' : 0 < 1 - (bb * b - 1)⁻¹ si : s0 + s1 / (b ^ (d - 1) - 1) + s2 / ((1 - (bb * b - 1)⁻¹) * bb) ≤ i fz : Complex.abs z ^ d - Complex.abs c ≤ Complex.abs (f' d c z) fz' : (b ^ (d - 1) - 1) * Complex.abs z ≤ Complex.abs (f' d c z) zfz : Complex.abs z ≤ Complex.abs (f' d c z) zffz : Complex.abs z ≤ Complex.abs (f' d c (f' d c z)) bfz : b ≤ Complex.abs (f' d c z) ⊢ (b ^ (d - 1) - 1) ^ d * Complex.abs z ^ (d - 1) * Complex.abs z - Complex.abs z ≥ (b ^ (d - 1) - 1) ^ d * b ^ (d - 1) * Complex.abs z - Complex.abs z TACTIC:
https://github.com/girving/ray.git	0be790285dd0fce78913b0cb9bddaffa94bd25f9	Ray/Dynamics/Multibrot/Iterates.lean	iter_error_le	[276, 1]	[342, 54]	rw [←hbb, sub_one_mul]	c✝ : ℂ d : ℕ inst✝ : Fact (2 ≤ d) i b s0 s1 s2 : ℝ c : ℂ b3 : 3 ≤ b s1p : 0 ≤ s1 s2p : 0 ≤ s2 bs0 : ∀ {w : ℂ}, b ≤ Complex.abs w → f_error d w ≤ s0 / (Complex.abs w * (Complex.abs w).log) bs1 : ∀ {w : ℂ}, (b ^ (d - 1) - 1) * b ≤ Complex.abs w → f_error d w ≤ s1 / (Complex.abs w * (Complex.abs w).log) b0' : 0 < b ^ (d - 1) - 1 z : ℂ bz : b ≤ Complex.abs z cz : Complex.abs c ≤ Complex.abs z b0 : 0 < b z0 : 0 < Complex.abs z z3 : 3 ≤ Complex.abs z l0 : 1 < (Complex.abs z).log bb : ℝ hbb : (b ^ (d - 1) - 1) ^ d * b ^ (d - 1) - 1 = bb b11 : 11 ≤ bb bb3 : 3 ≤ bb * b bs2 : ∀ {w : ℂ}, bb * b ≤ Complex.abs w → f_error d w ≤ s2 / (Complex.abs w * (Complex.abs w).log) b0'' : 0 < 1 - (bb * b - 1)⁻¹ si : s0 + s1 / (b ^ (d - 1) - 1) + s2 / ((1 - (bb * b - 1)⁻¹) * bb) ≤ i fz : Complex.abs z ^ d - Complex.abs c ≤ Complex.abs (f' d c z) fz' : (b ^ (d - 1) - 1) * Complex.abs z ≤ Complex.abs (f' d c z) zfz : Complex.abs z ≤ Complex.abs (f' d c z) zffz : Complex.abs z ≤ Complex.abs (f' d c (f' d c z)) bfz : b ≤ Complex.abs (f' d c z) ⊢ (b ^ (d - 1) - 1) ^ d * b ^ (d - 1) * Complex.abs z - Complex.abs z = bb * Complex.abs z	no goals	Please generate a tactic in lean4 to solve the state. STATE: c✝ : ℂ d : ℕ inst✝ : Fact (2 ≤ d) i b s0 s1 s2 : ℝ c : ℂ b3 : 3 ≤ b s1p : 0 ≤ s1 s2p : 0 ≤ s2 bs0 : ∀ {w : ℂ}, b ≤ Complex.abs w → f_error d w ≤ s0 / (Complex.abs w * (Complex.abs w).log) bs1 : ∀ {w : ℂ}, (b ^ (d - 1) - 1) * b ≤ Complex.abs w → f_error d w ≤ s1 / (Complex.abs w * (Complex.abs w).log) b0' : 0 < b ^ (d - 1) - 1 z : ℂ bz : b ≤ Complex.abs z cz : Complex.abs c ≤ Complex.abs z b0 : 0 < b z0 : 0 < Complex.abs z z3 : 3 ≤ Complex.abs z l0 : 1 < (Complex.abs z).log bb : ℝ hbb : (b ^ (d - 1) - 1) ^ d * b ^ (d - 1) - 1 = bb b11 : 11 ≤ bb bb3 : 3 ≤ bb * b bs2 : ∀ {w : ℂ}, bb * b ≤ Complex.abs w → f_error d w ≤ s2 / (Complex.abs w * (Complex.abs w).log) b0'' : 0 < 1 - (bb * b - 1)⁻¹ si : s0 + s1 / (b ^ (d - 1) - 1) + s2 / ((1 - (bb * b - 1)⁻¹) * bb) ≤ i fz : Complex.abs z ^ d - Complex.abs c ≤ Complex.abs (f' d c z) fz' : (b ^ (d - 1) - 1) * Complex.abs z ≤ Complex.abs (f' d c z) zfz : Complex.abs z ≤ Complex.abs (f' d c z) zffz : Complex.abs z ≤ Complex.abs (f' d c (f' d c z)) bfz : b ≤ Complex.abs (f' d c z) ⊢ (b ^ (d - 1) - 1) ^ d * b ^ (d - 1) * Complex.abs z - Complex.abs z = bb * Complex.abs z TACTIC:
https://github.com/girving/ray.git	0be790285dd0fce78913b0cb9bddaffa94bd25f9	Ray/Dynamics/Multibrot/Iterates.lean	iter_error_le	[276, 1]	[342, 54]	refine le_trans (bs1 ?_) ?_	c✝ : ℂ d : ℕ inst✝ : Fact (2 ≤ d) i b s0 s1 s2 : ℝ c : ℂ b3 : 3 ≤ b s1p : 0 ≤ s1 s2p : 0 ≤ s2 bs0 : ∀ {w : ℂ}, b ≤ Complex.abs w → f_error d w ≤ s0 / (Complex.abs w * (Complex.abs w).log) bs1 : ∀ {w : ℂ}, (b ^ (d - 1) - 1) * b ≤ Complex.abs w → f_error d w ≤ s1 / (Complex.abs w * (Complex.abs w).log) b0' : 0 < b ^ (d - 1) - 1 z : ℂ bz : b ≤ Complex.abs z cz : Complex.abs c ≤ Complex.abs z b0 : 0 < b z0 : 0 < Complex.abs z z3 : 3 ≤ Complex.abs z l0 : 1 < (Complex.abs z).log bb : ℝ hbb : (b ^ (d - 1) - 1) ^ d * b ^ (d - 1) - 1 = bb b11 : 11 ≤ bb bb3 : 3 ≤ bb * b bs2 : ∀ {w : ℂ}, bb * b ≤ Complex.abs w → f_error d w ≤ s2 / (Complex.abs w * (Complex.abs w).log) b0'' : 0 < 1 - (bb * b - 1)⁻¹ si : s0 + s1 / (b ^ (d - 1) - 1) + s2 / ((1 - (bb * b - 1)⁻¹) * bb) ≤ i fz : Complex.abs z ^ d - Complex.abs c ≤ Complex.abs (f' d c z) fz' : (b ^ (d - 1) - 1) * Complex.abs z ≤ Complex.abs (f' d c z) zfz : Complex.abs z ≤ Complex.abs (f' d c z) zffz : Complex.abs z ≤ Complex.abs (f' d c (f' d c z)) bfz : b ≤ Complex.abs (f' d c z) ffz : bb * Complex.abs z ≤ Complex.abs (f' d c (f' d c z)) e0 : f_error d z ≤ s0 / (Complex.abs z * (Complex.abs z).log) ⊢ f_error d (f' d c z) ≤ s1 / (b ^ (d - 1) - 1) / (Complex.abs z * (Complex.abs z).log)	case refine_1 c✝ : ℂ d : ℕ inst✝ : Fact (2 ≤ d) i b s0 s1 s2 : ℝ c : ℂ b3 : 3 ≤ b s1p : 0 ≤ s1 s2p : 0 ≤ s2 bs0 : ∀ {w : ℂ}, b ≤ Complex.abs w → f_error d w ≤ s0 / (Complex.abs w * (Complex.abs w).log) bs1 : ∀ {w : ℂ}, (b ^ (d - 1) - 1) * b ≤ Complex.abs w → f_error d w ≤ s1 / (Complex.abs w * (Complex.abs w).log) b0' : 0 < b ^ (d - 1) - 1 z : ℂ bz : b ≤ Complex.abs z cz : Complex.abs c ≤ Complex.abs z b0 : 0 < b z0 : 0 < Complex.abs z z3 : 3 ≤ Complex.abs z l0 : 1 < (Complex.abs z).log bb : ℝ hbb : (b ^ (d - 1) - 1) ^ d * b ^ (d - 1) - 1 = bb b11 : 11 ≤ bb bb3 : 3 ≤ bb * b bs2 : ∀ {w : ℂ}, bb * b ≤ Complex.abs w → f_error d w ≤ s2 / (Complex.abs w * (Complex.abs w).log) b0'' : 0 < 1 - (bb * b - 1)⁻¹ si : s0 + s1 / (b ^ (d - 1) - 1) + s2 / ((1 - (bb * b - 1)⁻¹) * bb) ≤ i fz : Complex.abs z ^ d - Complex.abs c ≤ Complex.abs (f' d c z) fz' : (b ^ (d - 1) - 1) * Complex.abs z ≤ Complex.abs (f' d c z) zfz : Complex.abs z ≤ Complex.abs (f' d c z) zffz : Complex.abs z ≤ Complex.abs (f' d c (f' d c z)) bfz : b ≤ Complex.abs (f' d c z) ffz : bb * Complex.abs z ≤ Complex.abs (f' d c (f' d c z)) e0 : f_error d z ≤ s0 / (Complex.abs z * (Complex.abs z).log) ⊢ (b ^ (d - 1) - 1) * b ≤ Complex.abs (f' d c z) case refine_2 c✝ : ℂ d : ℕ inst✝ : Fact (2 ≤ d) i b s0 s1 s2 : ℝ c : ℂ b3 : 3 ≤ b s1p : 0 ≤ s1 s2p : 0 ≤ s2 bs0 : ∀ {w : ℂ}, b ≤ Complex.abs w → f_error d w ≤ s0 / (Complex.abs w * (Complex.abs w).log) bs1 : ∀ {w : ℂ}, (b ^ (d - 1) - 1) * b ≤ Complex.abs w → f_error d w ≤ s1 / (Complex.abs w * (Complex.abs w).log) b0' : 0 < b ^ (d - 1) - 1 z : ℂ bz : b ≤ Complex.abs z cz : Complex.abs c ≤ Complex.abs z b0 : 0 < b z0 : 0 < Complex.abs z z3 : 3 ≤ Complex.abs z l0 : 1 < (Complex.abs z).log bb : ℝ hbb : (b ^ (d - 1) - 1) ^ d * b ^ (d - 1) - 1 = bb b11 : 11 ≤ bb bb3 : 3 ≤ bb * b bs2 : ∀ {w : ℂ}, bb * b ≤ Complex.abs w → f_error d w ≤ s2 / (Complex.abs w * (Complex.abs w).log) b0'' : 0 < 1 - (bb * b - 1)⁻¹ si : s0 + s1 / (b ^ (d - 1) - 1) + s2 / ((1 - (bb * b - 1)⁻¹) * bb) ≤ i fz : Complex.abs z ^ d - Complex.abs c ≤ Complex.abs (f' d c z) fz' : (b ^ (d - 1) - 1) * Complex.abs z ≤ Complex.abs (f' d c z) zfz : Complex.abs z ≤ Complex.abs (f' d c z) zffz : Complex.abs z ≤ Complex.abs (f' d c (f' d c z)) bfz : b ≤ Complex.abs (f' d c z) ffz : bb * Complex.abs z ≤ Complex.abs (f' d c (f' d c z)) e0 : f_error d z ≤ s0 / (Complex.abs z * (Complex.abs z).log) ⊢ s1 / (Complex.abs (f' d c z) * (Complex.abs (f' d c z)).log) ≤ s1 / (b ^ (d - 1) - 1) / (Complex.abs z * (Complex.abs z).log)	Please generate a tactic in lean4 to solve the state. STATE: c✝ : ℂ d : ℕ inst✝ : Fact (2 ≤ d) i b s0 s1 s2 : ℝ c : ℂ b3 : 3 ≤ b s1p : 0 ≤ s1 s2p : 0 ≤ s2 bs0 : ∀ {w : ℂ}, b ≤ Complex.abs w → f_error d w ≤ s0 / (Complex.abs w * (Complex.abs w).log) bs1 : ∀ {w : ℂ}, (b ^ (d - 1) - 1) * b ≤ Complex.abs w → f_error d w ≤ s1 / (Complex.abs w * (Complex.abs w).log) b0' : 0 < b ^ (d - 1) - 1 z : ℂ bz : b ≤ Complex.abs z cz : Complex.abs c ≤ Complex.abs z b0 : 0 < b z0 : 0 < Complex.abs z z3 : 3 ≤ Complex.abs z l0 : 1 < (Complex.abs z).log bb : ℝ hbb : (b ^ (d - 1) - 1) ^ d * b ^ (d - 1) - 1 = bb b11 : 11 ≤ bb bb3 : 3 ≤ bb * b bs2 : ∀ {w : ℂ}, bb * b ≤ Complex.abs w → f_error d w ≤ s2 / (Complex.abs w * (Complex.abs w).log) b0'' : 0 < 1 - (bb * b - 1)⁻¹ si : s0 + s1 / (b ^ (d - 1) - 1) + s2 / ((1 - (bb * b - 1)⁻¹) * bb) ≤ i fz : Complex.abs z ^ d - Complex.abs c ≤ Complex.abs (f' d c z) fz' : (b ^ (d - 1) - 1) * Complex.abs z ≤ Complex.abs (f' d c z) zfz : Complex.abs z ≤ Complex.abs (f' d c z) zffz : Complex.abs z ≤ Complex.abs (f' d c (f' d c z)) bfz : b ≤ Complex.abs (f' d c z) ffz : bb * Complex.abs z ≤ Complex.abs (f' d c (f' d c z)) e0 : f_error d z ≤ s0 / (Complex.abs z * (Complex.abs z).log) ⊢ f_error d (f' d c z) ≤ s1 / (b ^ (d - 1) - 1) / (Complex.abs z * (Complex.abs z).log) TACTIC:
https://github.com/girving/ray.git	0be790285dd0fce78913b0cb9bddaffa94bd25f9	Ray/Dynamics/Multibrot/Iterates.lean	iter_error_le	[276, 1]	[342, 54]	exact le_trans (mul_le_mul_of_nonneg_left bz b0'.le) fz'	case refine_1 c✝ : ℂ d : ℕ inst✝ : Fact (2 ≤ d) i b s0 s1 s2 : ℝ c : ℂ b3 : 3 ≤ b s1p : 0 ≤ s1 s2p : 0 ≤ s2 bs0 : ∀ {w : ℂ}, b ≤ Complex.abs w → f_error d w ≤ s0 / (Complex.abs w * (Complex.abs w).log) bs1 : ∀ {w : ℂ}, (b ^ (d - 1) - 1) * b ≤ Complex.abs w → f_error d w ≤ s1 / (Complex.abs w * (Complex.abs w).log) b0' : 0 < b ^ (d - 1) - 1 z : ℂ bz : b ≤ Complex.abs z cz : Complex.abs c ≤ Complex.abs z b0 : 0 < b z0 : 0 < Complex.abs z z3 : 3 ≤ Complex.abs z l0 : 1 < (Complex.abs z).log bb : ℝ hbb : (b ^ (d - 1) - 1) ^ d * b ^ (d - 1) - 1 = bb b11 : 11 ≤ bb bb3 : 3 ≤ bb * b bs2 : ∀ {w : ℂ}, bb * b ≤ Complex.abs w → f_error d w ≤ s2 / (Complex.abs w * (Complex.abs w).log) b0'' : 0 < 1 - (bb * b - 1)⁻¹ si : s0 + s1 / (b ^ (d - 1) - 1) + s2 / ((1 - (bb * b - 1)⁻¹) * bb) ≤ i fz : Complex.abs z ^ d - Complex.abs c ≤ Complex.abs (f' d c z) fz' : (b ^ (d - 1) - 1) * Complex.abs z ≤ Complex.abs (f' d c z) zfz : Complex.abs z ≤ Complex.abs (f' d c z) zffz : Complex.abs z ≤ Complex.abs (f' d c (f' d c z)) bfz : b ≤ Complex.abs (f' d c z) ffz : bb * Complex.abs z ≤ Complex.abs (f' d c (f' d c z)) e0 : f_error d z ≤ s0 / (Complex.abs z * (Complex.abs z).log) ⊢ (b ^ (d - 1) - 1) * b ≤ Complex.abs (f' d c z)	no goals	Please generate a tactic in lean4 to solve the state. STATE: case refine_1 c✝ : ℂ d : ℕ inst✝ : Fact (2 ≤ d) i b s0 s1 s2 : ℝ c : ℂ b3 : 3 ≤ b s1p : 0 ≤ s1 s2p : 0 ≤ s2 bs0 : ∀ {w : ℂ}, b ≤ Complex.abs w → f_error d w ≤ s0 / (Complex.abs w * (Complex.abs w).log) bs1 : ∀ {w : ℂ}, (b ^ (d - 1) - 1) * b ≤ Complex.abs w → f_error d w ≤ s1 / (Complex.abs w * (Complex.abs w).log) b0' : 0 < b ^ (d - 1) - 1 z : ℂ bz : b ≤ Complex.abs z cz : Complex.abs c ≤ Complex.abs z b0 : 0 < b z0 : 0 < Complex.abs z z3 : 3 ≤ Complex.abs z l0 : 1 < (Complex.abs z).log bb : ℝ hbb : (b ^ (d - 1) - 1) ^ d * b ^ (d - 1) - 1 = bb b11 : 11 ≤ bb bb3 : 3 ≤ bb * b bs2 : ∀ {w : ℂ}, bb * b ≤ Complex.abs w → f_error d w ≤ s2 / (Complex.abs w * (Complex.abs w).log) b0'' : 0 < 1 - (bb * b - 1)⁻¹ si : s0 + s1 / (b ^ (d - 1) - 1) + s2 / ((1 - (bb * b - 1)⁻¹) * bb) ≤ i fz : Complex.abs z ^ d - Complex.abs c ≤ Complex.abs (f' d c z) fz' : (b ^ (d - 1) - 1) * Complex.abs z ≤ Complex.abs (f' d c z) zfz : Complex.abs z ≤ Complex.abs (f' d c z) zffz : Complex.abs z ≤ Complex.abs (f' d c (f' d c z)) bfz : b ≤ Complex.abs (f' d c z) ffz : bb * Complex.abs z ≤ Complex.abs (f' d c (f' d c z)) e0 : f_error d z ≤ s0 / (Complex.abs z * (Complex.abs z).log) ⊢ (b ^ (d - 1) - 1) * b ≤ Complex.abs (f' d c z) TACTIC:
https://github.com/girving/ray.git	0be790285dd0fce78913b0cb9bddaffa94bd25f9	Ray/Dynamics/Multibrot/Iterates.lean	iter_error_le	[276, 1]	[342, 54]	simp only [div_eq_mul_inv, mul_inv, ←mul_assoc _ (abs z)⁻¹, mul_assoc s1 _ (abs z)⁻¹]	case refine_2 c✝ : ℂ d : ℕ inst✝ : Fact (2 ≤ d) i b s0 s1 s2 : ℝ c : ℂ b3 : 3 ≤ b s1p : 0 ≤ s1 s2p : 0 ≤ s2 bs0 : ∀ {w : ℂ}, b ≤ Complex.abs w → f_error d w ≤ s0 / (Complex.abs w * (Complex.abs w).log) bs1 : ∀ {w : ℂ}, (b ^ (d - 1) - 1) * b ≤ Complex.abs w → f_error d w ≤ s1 / (Complex.abs w * (Complex.abs w).log) b0' : 0 < b ^ (d - 1) - 1 z : ℂ bz : b ≤ Complex.abs z cz : Complex.abs c ≤ Complex.abs z b0 : 0 < b z0 : 0 < Complex.abs z z3 : 3 ≤ Complex.abs z l0 : 1 < (Complex.abs z).log bb : ℝ hbb : (b ^ (d - 1) - 1) ^ d * b ^ (d - 1) - 1 = bb b11 : 11 ≤ bb bb3 : 3 ≤ bb * b bs2 : ∀ {w : ℂ}, bb * b ≤ Complex.abs w → f_error d w ≤ s2 / (Complex.abs w * (Complex.abs w).log) b0'' : 0 < 1 - (bb * b - 1)⁻¹ si : s0 + s1 / (b ^ (d - 1) - 1) + s2 / ((1 - (bb * b - 1)⁻¹) * bb) ≤ i fz : Complex.abs z ^ d - Complex.abs c ≤ Complex.abs (f' d c z) fz' : (b ^ (d - 1) - 1) * Complex.abs z ≤ Complex.abs (f' d c z) zfz : Complex.abs z ≤ Complex.abs (f' d c z) zffz : Complex.abs z ≤ Complex.abs (f' d c (f' d c z)) bfz : b ≤ Complex.abs (f' d c z) ffz : bb * Complex.abs z ≤ Complex.abs (f' d c (f' d c z)) e0 : f_error d z ≤ s0 / (Complex.abs z * (Complex.abs z).log) ⊢ s1 / (Complex.abs (f' d c z) * (Complex.abs (f' d c z)).log) ≤ s1 / (b ^ (d - 1) - 1) / (Complex.abs z * (Complex.abs z).log)	case refine_2 c✝ : ℂ d : ℕ inst✝ : Fact (2 ≤ d) i b s0 s1 s2 : ℝ c : ℂ b3 : 3 ≤ b s1p : 0 ≤ s1 s2p : 0 ≤ s2 bs0 : ∀ {w : ℂ}, b ≤ Complex.abs w → f_error d w ≤ s0 / (Complex.abs w * (Complex.abs w).log) bs1 : ∀ {w : ℂ}, (b ^ (d - 1) - 1) * b ≤ Complex.abs w → f_error d w ≤ s1 / (Complex.abs w * (Complex.abs w).log) b0' : 0 < b ^ (d - 1) - 1 z : ℂ bz : b ≤ Complex.abs z cz : Complex.abs c ≤ Complex.abs z b0 : 0 < b z0 : 0 < Complex.abs z z3 : 3 ≤ Complex.abs z l0 : 1 < (Complex.abs z).log bb : ℝ hbb : (b ^ (d - 1) - 1) ^ d * b ^ (d - 1) - 1 = bb b11 : 11 ≤ bb bb3 : 3 ≤ bb * b bs2 : ∀ {w : ℂ}, bb * b ≤ Complex.abs w → f_error d w ≤ s2 / (Complex.abs w * (Complex.abs w).log) b0'' : 0 < 1 - (bb * b - 1)⁻¹ si : s0 + s1 / (b ^ (d - 1) - 1) + s2 / ((1 - (bb * b - 1)⁻¹) * bb) ≤ i fz : Complex.abs z ^ d - Complex.abs c ≤ Complex.abs (f' d c z) fz' : (b ^ (d - 1) - 1) * Complex.abs z ≤ Complex.abs (f' d c z) zfz : Complex.abs z ≤ Complex.abs (f' d c z) zffz : Complex.abs z ≤ Complex.abs (f' d c (f' d c z)) bfz : b ≤ Complex.abs (f' d c z) ffz : bb * Complex.abs z ≤ Complex.abs (f' d c (f' d c z)) e0 : f_error d z ≤ s0 / (Complex.abs z * (Complex.abs z).log) ⊢ s1 * ((Complex.abs (f' d c z))⁻¹ * (Complex.abs (f' d c z)).log⁻¹) ≤ s1 * ((b ^ (d - 1) - 1)⁻¹ * (Complex.abs z)⁻¹) * (Complex.abs z).log⁻¹	Please generate a tactic in lean4 to solve the state. STATE: case refine_2 c✝ : ℂ d : ℕ inst✝ : Fact (2 ≤ d) i b s0 s1 s2 : ℝ c : ℂ b3 : 3 ≤ b s1p : 0 ≤ s1 s2p : 0 ≤ s2 bs0 : ∀ {w : ℂ}, b ≤ Complex.abs w → f_error d w ≤ s0 / (Complex.abs w * (Complex.abs w).log) bs1 : ∀ {w : ℂ}, (b ^ (d - 1) - 1) * b ≤ Complex.abs w → f_error d w ≤ s1 / (Complex.abs w * (Complex.abs w).log) b0' : 0 < b ^ (d - 1) - 1 z : ℂ bz : b ≤ Complex.abs z cz : Complex.abs c ≤ Complex.abs z b0 : 0 < b z0 : 0 < Complex.abs z z3 : 3 ≤ Complex.abs z l0 : 1 < (Complex.abs z).log bb : ℝ hbb : (b ^ (d - 1) - 1) ^ d * b ^ (d - 1) - 1 = bb b11 : 11 ≤ bb bb3 : 3 ≤ bb * b bs2 : ∀ {w : ℂ}, bb * b ≤ Complex.abs w → f_error d w ≤ s2 / (Complex.abs w * (Complex.abs w).log) b0'' : 0 < 1 - (bb * b - 1)⁻¹ si : s0 + s1 / (b ^ (d - 1) - 1) + s2 / ((1 - (bb * b - 1)⁻¹) * bb) ≤ i fz : Complex.abs z ^ d - Complex.abs c ≤ Complex.abs (f' d c z) fz' : (b ^ (d - 1) - 1) * Complex.abs z ≤ Complex.abs (f' d c z) zfz : Complex.abs z ≤ Complex.abs (f' d c z) zffz : Complex.abs z ≤ Complex.abs (f' d c (f' d c z)) bfz : b ≤ Complex.abs (f' d c z) ffz : bb * Complex.abs z ≤ Complex.abs (f' d c (f' d c z)) e0 : f_error d z ≤ s0 / (Complex.abs z * (Complex.abs z).log) ⊢ s1 / (Complex.abs (f' d c z) * (Complex.abs (f' d c z)).log) ≤ s1 / (b ^ (d - 1) - 1) / (Complex.abs z * (Complex.abs z).log) TACTIC:
https://github.com/girving/ray.git	0be790285dd0fce78913b0cb9bddaffa94bd25f9	Ray/Dynamics/Multibrot/Iterates.lean	iter_error_le	[276, 1]	[342, 54]	simp only [←mul_inv, mul_assoc s1]	case refine_2 c✝ : ℂ d : ℕ inst✝ : Fact (2 ≤ d) i b s0 s1 s2 : ℝ c : ℂ b3 : 3 ≤ b s1p : 0 ≤ s1 s2p : 0 ≤ s2 bs0 : ∀ {w : ℂ}, b ≤ Complex.abs w → f_error d w ≤ s0 / (Complex.abs w * (Complex.abs w).log) bs1 : ∀ {w : ℂ}, (b ^ (d - 1) - 1) * b ≤ Complex.abs w → f_error d w ≤ s1 / (Complex.abs w * (Complex.abs w).log) b0' : 0 < b ^ (d - 1) - 1 z : ℂ bz : b ≤ Complex.abs z cz : Complex.abs c ≤ Complex.abs z b0 : 0 < b z0 : 0 < Complex.abs z z3 : 3 ≤ Complex.abs z l0 : 1 < (Complex.abs z).log bb : ℝ hbb : (b ^ (d - 1) - 1) ^ d * b ^ (d - 1) - 1 = bb b11 : 11 ≤ bb bb3 : 3 ≤ bb * b bs2 : ∀ {w : ℂ}, bb * b ≤ Complex.abs w → f_error d w ≤ s2 / (Complex.abs w * (Complex.abs w).log) b0'' : 0 < 1 - (bb * b - 1)⁻¹ si : s0 + s1 / (b ^ (d - 1) - 1) + s2 / ((1 - (bb * b - 1)⁻¹) * bb) ≤ i fz : Complex.abs z ^ d - Complex.abs c ≤ Complex.abs (f' d c z) fz' : (b ^ (d - 1) - 1) * Complex.abs z ≤ Complex.abs (f' d c z) zfz : Complex.abs z ≤ Complex.abs (f' d c z) zffz : Complex.abs z ≤ Complex.abs (f' d c (f' d c z)) bfz : b ≤ Complex.abs (f' d c z) ffz : bb * Complex.abs z ≤ Complex.abs (f' d c (f' d c z)) e0 : f_error d z ≤ s0 / (Complex.abs z * (Complex.abs z).log) ⊢ s1 * ((Complex.abs (f' d c z))⁻¹ * (Complex.abs (f' d c z)).log⁻¹) ≤ s1 * ((b ^ (d - 1) - 1)⁻¹ * (Complex.abs z)⁻¹) * (Complex.abs z).log⁻¹	case refine_2 c✝ : ℂ d : ℕ inst✝ : Fact (2 ≤ d) i b s0 s1 s2 : ℝ c : ℂ b3 : 3 ≤ b s1p : 0 ≤ s1 s2p : 0 ≤ s2 bs0 : ∀ {w : ℂ}, b ≤ Complex.abs w → f_error d w ≤ s0 / (Complex.abs w * (Complex.abs w).log) bs1 : ∀ {w : ℂ}, (b ^ (d - 1) - 1) * b ≤ Complex.abs w → f_error d w ≤ s1 / (Complex.abs w * (Complex.abs w).log) b0' : 0 < b ^ (d - 1) - 1 z : ℂ bz : b ≤ Complex.abs z cz : Complex.abs c ≤ Complex.abs z b0 : 0 < b z0 : 0 < Complex.abs z z3 : 3 ≤ Complex.abs z l0 : 1 < (Complex.abs z).log bb : ℝ hbb : (b ^ (d - 1) - 1) ^ d * b ^ (d - 1) - 1 = bb b11 : 11 ≤ bb bb3 : 3 ≤ bb * b bs2 : ∀ {w : ℂ}, bb * b ≤ Complex.abs w → f_error d w ≤ s2 / (Complex.abs w * (Complex.abs w).log) b0'' : 0 < 1 - (bb * b - 1)⁻¹ si : s0 + s1 / (b ^ (d - 1) - 1) + s2 / ((1 - (bb * b - 1)⁻¹) * bb) ≤ i fz : Complex.abs z ^ d - Complex.abs c ≤ Complex.abs (f' d c z) fz' : (b ^ (d - 1) - 1) * Complex.abs z ≤ Complex.abs (f' d c z) zfz : Complex.abs z ≤ Complex.abs (f' d c z) zffz : Complex.abs z ≤ Complex.abs (f' d c (f' d c z)) bfz : b ≤ Complex.abs (f' d c z) ffz : bb * Complex.abs z ≤ Complex.abs (f' d c (f' d c z)) e0 : f_error d z ≤ s0 / (Complex.abs z * (Complex.abs z).log) ⊢ s1 * (Complex.abs (f' d c z) * (Complex.abs (f' d c z)).log)⁻¹ ≤ s1 * ((b ^ (d - 1) - 1) * Complex.abs z * (Complex.abs z).log)⁻¹	Please generate a tactic in lean4 to solve the state. STATE: case refine_2 c✝ : ℂ d : ℕ inst✝ : Fact (2 ≤ d) i b s0 s1 s2 : ℝ c : ℂ b3 : 3 ≤ b s1p : 0 ≤ s1 s2p : 0 ≤ s2 bs0 : ∀ {w : ℂ}, b ≤ Complex.abs w → f_error d w ≤ s0 / (Complex.abs w * (Complex.abs w).log) bs1 : ∀ {w : ℂ}, (b ^ (d - 1) - 1) * b ≤ Complex.abs w → f_error d w ≤ s1 / (Complex.abs w * (Complex.abs w).log) b0' : 0 < b ^ (d - 1) - 1 z : ℂ bz : b ≤ Complex.abs z cz : Complex.abs c ≤ Complex.abs z b0 : 0 < b z0 : 0 < Complex.abs z z3 : 3 ≤ Complex.abs z l0 : 1 < (Complex.abs z).log bb : ℝ hbb : (b ^ (d - 1) - 1) ^ d * b ^ (d - 1) - 1 = bb b11 : 11 ≤ bb bb3 : 3 ≤ bb * b bs2 : ∀ {w : ℂ}, bb * b ≤ Complex.abs w → f_error d w ≤ s2 / (Complex.abs w * (Complex.abs w).log) b0'' : 0 < 1 - (bb * b - 1)⁻¹ si : s0 + s1 / (b ^ (d - 1) - 1) + s2 / ((1 - (bb * b - 1)⁻¹) * bb) ≤ i fz : Complex.abs z ^ d - Complex.abs c ≤ Complex.abs (f' d c z) fz' : (b ^ (d - 1) - 1) * Complex.abs z ≤ Complex.abs (f' d c z) zfz : Complex.abs z ≤ Complex.abs (f' d c z) zffz : Complex.abs z ≤ Complex.abs (f' d c (f' d c z)) bfz : b ≤ Complex.abs (f' d c z) ffz : bb * Complex.abs z ≤ Complex.abs (f' d c (f' d c z)) e0 : f_error d z ≤ s0 / (Complex.abs z * (Complex.abs z).log) ⊢ s1 * ((Complex.abs (f' d c z))⁻¹ * (Complex.abs (f' d c z)).log⁻¹) ≤ s1 * ((b ^ (d - 1) - 1)⁻¹ * (Complex.abs z)⁻¹) * (Complex.abs z).log⁻¹ TACTIC:
https://github.com/girving/ray.git	0be790285dd0fce78913b0cb9bddaffa94bd25f9	Ray/Dynamics/Multibrot/Iterates.lean	iter_error_le	[276, 1]	[342, 54]	refine mul_le_mul_of_nonneg_left (inv_le_inv_of_le (by positivity) ?_) s1p	case refine_2 c✝ : ℂ d : ℕ inst✝ : Fact (2 ≤ d) i b s0 s1 s2 : ℝ c : ℂ b3 : 3 ≤ b s1p : 0 ≤ s1 s2p : 0 ≤ s2 bs0 : ∀ {w : ℂ}, b ≤ Complex.abs w → f_error d w ≤ s0 / (Complex.abs w * (Complex.abs w).log) bs1 : ∀ {w : ℂ}, (b ^ (d - 1) - 1) * b ≤ Complex.abs w → f_error d w ≤ s1 / (Complex.abs w * (Complex.abs w).log) b0' : 0 < b ^ (d - 1) - 1 z : ℂ bz : b ≤ Complex.abs z cz : Complex.abs c ≤ Complex.abs z b0 : 0 < b z0 : 0 < Complex.abs z z3 : 3 ≤ Complex.abs z l0 : 1 < (Complex.abs z).log bb : ℝ hbb : (b ^ (d - 1) - 1) ^ d * b ^ (d - 1) - 1 = bb b11 : 11 ≤ bb bb3 : 3 ≤ bb * b bs2 : ∀ {w : ℂ}, bb * b ≤ Complex.abs w → f_error d w ≤ s2 / (Complex.abs w * (Complex.abs w).log) b0'' : 0 < 1 - (bb * b - 1)⁻¹ si : s0 + s1 / (b ^ (d - 1) - 1) + s2 / ((1 - (bb * b - 1)⁻¹) * bb) ≤ i fz : Complex.abs z ^ d - Complex.abs c ≤ Complex.abs (f' d c z) fz' : (b ^ (d - 1) - 1) * Complex.abs z ≤ Complex.abs (f' d c z) zfz : Complex.abs z ≤ Complex.abs (f' d c z) zffz : Complex.abs z ≤ Complex.abs (f' d c (f' d c z)) bfz : b ≤ Complex.abs (f' d c z) ffz : bb * Complex.abs z ≤ Complex.abs (f' d c (f' d c z)) e0 : f_error d z ≤ s0 / (Complex.abs z * (Complex.abs z).log) ⊢ s1 * (Complex.abs (f' d c z) * (Complex.abs (f' d c z)).log)⁻¹ ≤ s1 * ((b ^ (d - 1) - 1) * Complex.abs z * (Complex.abs z).log)⁻¹	case refine_2 c✝ : ℂ d : ℕ inst✝ : Fact (2 ≤ d) i b s0 s1 s2 : ℝ c : ℂ b3 : 3 ≤ b s1p : 0 ≤ s1 s2p : 0 ≤ s2 bs0 : ∀ {w : ℂ}, b ≤ Complex.abs w → f_error d w ≤ s0 / (Complex.abs w * (Complex.abs w).log) bs1 : ∀ {w : ℂ}, (b ^ (d - 1) - 1) * b ≤ Complex.abs w → f_error d w ≤ s1 / (Complex.abs w * (Complex.abs w).log) b0' : 0 < b ^ (d - 1) - 1 z : ℂ bz : b ≤ Complex.abs z cz : Complex.abs c ≤ Complex.abs z b0 : 0 < b z0 : 0 < Complex.abs z z3 : 3 ≤ Complex.abs z l0 : 1 < (Complex.abs z).log bb : ℝ hbb : (b ^ (d - 1) - 1) ^ d * b ^ (d - 1) - 1 = bb b11 : 11 ≤ bb bb3 : 3 ≤ bb * b bs2 : ∀ {w : ℂ}, bb * b ≤ Complex.abs w → f_error d w ≤ s2 / (Complex.abs w * (Complex.abs w).log) b0'' : 0 < 1 - (bb * b - 1)⁻¹ si : s0 + s1 / (b ^ (d - 1) - 1) + s2 / ((1 - (bb * b - 1)⁻¹) * bb) ≤ i fz : Complex.abs z ^ d - Complex.abs c ≤ Complex.abs (f' d c z) fz' : (b ^ (d - 1) - 1) * Complex.abs z ≤ Complex.abs (f' d c z) zfz : Complex.abs z ≤ Complex.abs (f' d c z) zffz : Complex.abs z ≤ Complex.abs (f' d c (f' d c z)) bfz : b ≤ Complex.abs (f' d c z) ffz : bb * Complex.abs z ≤ Complex.abs (f' d c (f' d c z)) e0 : f_error d z ≤ s0 / (Complex.abs z * (Complex.abs z).log) ⊢ (b ^ (d - 1) - 1) * Complex.abs z * (Complex.abs z).log ≤ Complex.abs (f' d c z) * (Complex.abs (f' d c z)).log	Please generate a tactic in lean4 to solve the state. STATE: case refine_2 c✝ : ℂ d : ℕ inst✝ : Fact (2 ≤ d) i b s0 s1 s2 : ℝ c : ℂ b3 : 3 ≤ b s1p : 0 ≤ s1 s2p : 0 ≤ s2 bs0 : ∀ {w : ℂ}, b ≤ Complex.abs w → f_error d w ≤ s0 / (Complex.abs w * (Complex.abs w).log) bs1 : ∀ {w : ℂ}, (b ^ (d - 1) - 1) * b ≤ Complex.abs w → f_error d w ≤ s1 / (Complex.abs w * (Complex.abs w).log) b0' : 0 < b ^ (d - 1) - 1 z : ℂ bz : b ≤ Complex.abs z cz : Complex.abs c ≤ Complex.abs z b0 : 0 < b z0 : 0 < Complex.abs z z3 : 3 ≤ Complex.abs z l0 : 1 < (Complex.abs z).log bb : ℝ hbb : (b ^ (d - 1) - 1) ^ d * b ^ (d - 1) - 1 = bb b11 : 11 ≤ bb bb3 : 3 ≤ bb * b bs2 : ∀ {w : ℂ}, bb * b ≤ Complex.abs w → f_error d w ≤ s2 / (Complex.abs w * (Complex.abs w).log) b0'' : 0 < 1 - (bb * b - 1)⁻¹ si : s0 + s1 / (b ^ (d - 1) - 1) + s2 / ((1 - (bb * b - 1)⁻¹) * bb) ≤ i fz : Complex.abs z ^ d - Complex.abs c ≤ Complex.abs (f' d c z) fz' : (b ^ (d - 1) - 1) * Complex.abs z ≤ Complex.abs (f' d c z) zfz : Complex.abs z ≤ Complex.abs (f' d c z) zffz : Complex.abs z ≤ Complex.abs (f' d c (f' d c z)) bfz : b ≤ Complex.abs (f' d c z) ffz : bb * Complex.abs z ≤ Complex.abs (f' d c (f' d c z)) e0 : f_error d z ≤ s0 / (Complex.abs z * (Complex.abs z).log) ⊢ s1 * (Complex.abs (f' d c z) * (Complex.abs (f' d c z)).log)⁻¹ ≤ s1 * ((b ^ (d - 1) - 1) * Complex.abs z * (Complex.abs z).log)⁻¹ TACTIC:
https://github.com/girving/ray.git	0be790285dd0fce78913b0cb9bddaffa94bd25f9	Ray/Dynamics/Multibrot/Iterates.lean	iter_error_le	[276, 1]	[342, 54]	exact mul_le_mul fz' (Real.log_le_log (by positivity) zfz) (by positivity) (le_trans b0.le bfz)	case refine_2 c✝ : ℂ d : ℕ inst✝ : Fact (2 ≤ d) i b s0 s1 s2 : ℝ c : ℂ b3 : 3 ≤ b s1p : 0 ≤ s1 s2p : 0 ≤ s2 bs0 : ∀ {w : ℂ}, b ≤ Complex.abs w → f_error d w ≤ s0 / (Complex.abs w * (Complex.abs w).log) bs1 : ∀ {w : ℂ}, (b ^ (d - 1) - 1) * b ≤ Complex.abs w → f_error d w ≤ s1 / (Complex.abs w * (Complex.abs w).log) b0' : 0 < b ^ (d - 1) - 1 z : ℂ bz : b ≤ Complex.abs z cz : Complex.abs c ≤ Complex.abs z b0 : 0 < b z0 : 0 < Complex.abs z z3 : 3 ≤ Complex.abs z l0 : 1 < (Complex.abs z).log bb : ℝ hbb : (b ^ (d - 1) - 1) ^ d * b ^ (d - 1) - 1 = bb b11 : 11 ≤ bb bb3 : 3 ≤ bb * b bs2 : ∀ {w : ℂ}, bb * b ≤ Complex.abs w → f_error d w ≤ s2 / (Complex.abs w * (Complex.abs w).log) b0'' : 0 < 1 - (bb * b - 1)⁻¹ si : s0 + s1 / (b ^ (d - 1) - 1) + s2 / ((1 - (bb * b - 1)⁻¹) * bb) ≤ i fz : Complex.abs z ^ d - Complex.abs c ≤ Complex.abs (f' d c z) fz' : (b ^ (d - 1) - 1) * Complex.abs z ≤ Complex.abs (f' d c z) zfz : Complex.abs z ≤ Complex.abs (f' d c z) zffz : Complex.abs z ≤ Complex.abs (f' d c (f' d c z)) bfz : b ≤ Complex.abs (f' d c z) ffz : bb * Complex.abs z ≤ Complex.abs (f' d c (f' d c z)) e0 : f_error d z ≤ s0 / (Complex.abs z * (Complex.abs z).log) ⊢ (b ^ (d - 1) - 1) * Complex.abs z * (Complex.abs z).log ≤ Complex.abs (f' d c z) * (Complex.abs (f' d c z)).log	no goals	Please generate a tactic in lean4 to solve the state. STATE: case refine_2 c✝ : ℂ d : ℕ inst✝ : Fact (2 ≤ d) i b s0 s1 s2 : ℝ c : ℂ b3 : 3 ≤ b s1p : 0 ≤ s1 s2p : 0 ≤ s2 bs0 : ∀ {w : ℂ}, b ≤ Complex.abs w → f_error d w ≤ s0 / (Complex.abs w * (Complex.abs w).log) bs1 : ∀ {w : ℂ}, (b ^ (d - 1) - 1) * b ≤ Complex.abs w → f_error d w ≤ s1 / (Complex.abs w * (Complex.abs w).log) b0' : 0 < b ^ (d - 1) - 1 z : ℂ bz : b ≤ Complex.abs z cz : Complex.abs c ≤ Complex.abs z b0 : 0 < b z0 : 0 < Complex.abs z z3 : 3 ≤ Complex.abs z l0 : 1 < (Complex.abs z).log bb : ℝ hbb : (b ^ (d - 1) - 1) ^ d * b ^ (d - 1) - 1 = bb b11 : 11 ≤ bb bb3 : 3 ≤ bb * b bs2 : ∀ {w : ℂ}, bb * b ≤ Complex.abs w → f_error d w ≤ s2 / (Complex.abs w * (Complex.abs w).log) b0'' : 0 < 1 - (bb * b - 1)⁻¹ si : s0 + s1 / (b ^ (d - 1) - 1) + s2 / ((1 - (bb * b - 1)⁻¹) * bb) ≤ i fz : Complex.abs z ^ d - Complex.abs c ≤ Complex.abs (f' d c z) fz' : (b ^ (d - 1) - 1) * Complex.abs z ≤ Complex.abs (f' d c z) zfz : Complex.abs z ≤ Complex.abs (f' d c z) zffz : Complex.abs z ≤ Complex.abs (f' d c (f' d c z)) bfz : b ≤ Complex.abs (f' d c z) ffz : bb * Complex.abs z ≤ Complex.abs (f' d c (f' d c z)) e0 : f_error d z ≤ s0 / (Complex.abs z * (Complex.abs z).log) ⊢ (b ^ (d - 1) - 1) * Complex.abs z * (Complex.abs z).log ≤ Complex.abs (f' d c z) * (Complex.abs (f' d c z)).log TACTIC:
https://github.com/girving/ray.git	0be790285dd0fce78913b0cb9bddaffa94bd25f9	Ray/Dynamics/Multibrot/Iterates.lean	iter_error_le	[276, 1]	[342, 54]	positivity	c✝ : ℂ d : ℕ inst✝ : Fact (2 ≤ d) i b s0 s1 s2 : ℝ c : ℂ b3 : 3 ≤ b s1p : 0 ≤ s1 s2p : 0 ≤ s2 bs0 : ∀ {w : ℂ}, b ≤ Complex.abs w → f_error d w ≤ s0 / (Complex.abs w * (Complex.abs w).log) bs1 : ∀ {w : ℂ}, (b ^ (d - 1) - 1) * b ≤ Complex.abs w → f_error d w ≤ s1 / (Complex.abs w * (Complex.abs w).log) b0' : 0 < b ^ (d - 1) - 1 z : ℂ bz : b ≤ Complex.abs z cz : Complex.abs c ≤ Complex.abs z b0 : 0 < b z0 : 0 < Complex.abs z z3 : 3 ≤ Complex.abs z l0 : 1 < (Complex.abs z).log bb : ℝ hbb : (b ^ (d - 1) - 1) ^ d * b ^ (d - 1) - 1 = bb b11 : 11 ≤ bb bb3 : 3 ≤ bb * b bs2 : ∀ {w : ℂ}, bb * b ≤ Complex.abs w → f_error d w ≤ s2 / (Complex.abs w * (Complex.abs w).log) b0'' : 0 < 1 - (bb * b - 1)⁻¹ si : s0 + s1 / (b ^ (d - 1) - 1) + s2 / ((1 - (bb * b - 1)⁻¹) * bb) ≤ i fz : Complex.abs z ^ d - Complex.abs c ≤ Complex.abs (f' d c z) fz' : (b ^ (d - 1) - 1) * Complex.abs z ≤ Complex.abs (f' d c z) zfz : Complex.abs z ≤ Complex.abs (f' d c z) zffz : Complex.abs z ≤ Complex.abs (f' d c (f' d c z)) bfz : b ≤ Complex.abs (f' d c z) ffz : bb * Complex.abs z ≤ Complex.abs (f' d c (f' d c z)) e0 : f_error d z ≤ s0 / (Complex.abs z * (Complex.abs z).log) ⊢ 0 < (b ^ (d - 1) - 1) * Complex.abs z * (Complex.abs z).log	no goals	Please generate a tactic in lean4 to solve the state. STATE: c✝ : ℂ d : ℕ inst✝ : Fact (2 ≤ d) i b s0 s1 s2 : ℝ c : ℂ b3 : 3 ≤ b s1p : 0 ≤ s1 s2p : 0 ≤ s2 bs0 : ∀ {w : ℂ}, b ≤ Complex.abs w → f_error d w ≤ s0 / (Complex.abs w * (Complex.abs w).log) bs1 : ∀ {w : ℂ}, (b ^ (d - 1) - 1) * b ≤ Complex.abs w → f_error d w ≤ s1 / (Complex.abs w * (Complex.abs w).log) b0' : 0 < b ^ (d - 1) - 1 z : ℂ bz : b ≤ Complex.abs z cz : Complex.abs c ≤ Complex.abs z b0 : 0 < b z0 : 0 < Complex.abs z z3 : 3 ≤ Complex.abs z l0 : 1 < (Complex.abs z).log bb : ℝ hbb : (b ^ (d - 1) - 1) ^ d * b ^ (d - 1) - 1 = bb b11 : 11 ≤ bb bb3 : 3 ≤ bb * b bs2 : ∀ {w : ℂ}, bb * b ≤ Complex.abs w → f_error d w ≤ s2 / (Complex.abs w * (Complex.abs w).log) b0'' : 0 < 1 - (bb * b - 1)⁻¹ si : s0 + s1 / (b ^ (d - 1) - 1) + s2 / ((1 - (bb * b - 1)⁻¹) * bb) ≤ i fz : Complex.abs z ^ d - Complex.abs c ≤ Complex.abs (f' d c z) fz' : (b ^ (d - 1) - 1) * Complex.abs z ≤ Complex.abs (f' d c z) zfz : Complex.abs z ≤ Complex.abs (f' d c z) zffz : Complex.abs z ≤ Complex.abs (f' d c (f' d c z)) bfz : b ≤ Complex.abs (f' d c z) ffz : bb * Complex.abs z ≤ Complex.abs (f' d c (f' d c z)) e0 : f_error d z ≤ s0 / (Complex.abs z * (Complex.abs z).log) ⊢ 0 < (b ^ (d - 1) - 1) * Complex.abs z * (Complex.abs z).log TACTIC:
https://github.com/girving/ray.git	0be790285dd0fce78913b0cb9bddaffa94bd25f9	Ray/Dynamics/Multibrot/Iterates.lean	iter_error_le	[276, 1]	[342, 54]	positivity	c✝ : ℂ d : ℕ inst✝ : Fact (2 ≤ d) i b s0 s1 s2 : ℝ c : ℂ b3 : 3 ≤ b s1p : 0 ≤ s1 s2p : 0 ≤ s2 bs0 : ∀ {w : ℂ}, b ≤ Complex.abs w → f_error d w ≤ s0 / (Complex.abs w * (Complex.abs w).log) bs1 : ∀ {w : ℂ}, (b ^ (d - 1) - 1) * b ≤ Complex.abs w → f_error d w ≤ s1 / (Complex.abs w * (Complex.abs w).log) b0' : 0 < b ^ (d - 1) - 1 z : ℂ bz : b ≤ Complex.abs z cz : Complex.abs c ≤ Complex.abs z b0 : 0 < b z0 : 0 < Complex.abs z z3 : 3 ≤ Complex.abs z l0 : 1 < (Complex.abs z).log bb : ℝ hbb : (b ^ (d - 1) - 1) ^ d * b ^ (d - 1) - 1 = bb b11 : 11 ≤ bb bb3 : 3 ≤ bb * b bs2 : ∀ {w : ℂ}, bb * b ≤ Complex.abs w → f_error d w ≤ s2 / (Complex.abs w * (Complex.abs w).log) b0'' : 0 < 1 - (bb * b - 1)⁻¹ si : s0 + s1 / (b ^ (d - 1) - 1) + s2 / ((1 - (bb * b - 1)⁻¹) * bb) ≤ i fz : Complex.abs z ^ d - Complex.abs c ≤ Complex.abs (f' d c z) fz' : (b ^ (d - 1) - 1) * Complex.abs z ≤ Complex.abs (f' d c z) zfz : Complex.abs z ≤ Complex.abs (f' d c z) zffz : Complex.abs z ≤ Complex.abs (f' d c (f' d c z)) bfz : b ≤ Complex.abs (f' d c z) ffz : bb * Complex.abs z ≤ Complex.abs (f' d c (f' d c z)) e0 : f_error d z ≤ s0 / (Complex.abs z * (Complex.abs z).log) ⊢ 0 < Complex.abs z	no goals	Please generate a tactic in lean4 to solve the state. STATE: c✝ : ℂ d : ℕ inst✝ : Fact (2 ≤ d) i b s0 s1 s2 : ℝ c : ℂ b3 : 3 ≤ b s1p : 0 ≤ s1 s2p : 0 ≤ s2 bs0 : ∀ {w : ℂ}, b ≤ Complex.abs w → f_error d w ≤ s0 / (Complex.abs w * (Complex.abs w).log) bs1 : ∀ {w : ℂ}, (b ^ (d - 1) - 1) * b ≤ Complex.abs w → f_error d w ≤ s1 / (Complex.abs w * (Complex.abs w).log) b0' : 0 < b ^ (d - 1) - 1 z : ℂ bz : b ≤ Complex.abs z cz : Complex.abs c ≤ Complex.abs z b0 : 0 < b z0 : 0 < Complex.abs z z3 : 3 ≤ Complex.abs z l0 : 1 < (Complex.abs z).log bb : ℝ hbb : (b ^ (d - 1) - 1) ^ d * b ^ (d - 1) - 1 = bb b11 : 11 ≤ bb bb3 : 3 ≤ bb * b bs2 : ∀ {w : ℂ}, bb * b ≤ Complex.abs w → f_error d w ≤ s2 / (Complex.abs w * (Complex.abs w).log) b0'' : 0 < 1 - (bb * b - 1)⁻¹ si : s0 + s1 / (b ^ (d - 1) - 1) + s2 / ((1 - (bb * b - 1)⁻¹) * bb) ≤ i fz : Complex.abs z ^ d - Complex.abs c ≤ Complex.abs (f' d c z) fz' : (b ^ (d - 1) - 1) * Complex.abs z ≤ Complex.abs (f' d c z) zfz : Complex.abs z ≤ Complex.abs (f' d c z) zffz : Complex.abs z ≤ Complex.abs (f' d c (f' d c z)) bfz : b ≤ Complex.abs (f' d c z) ffz : bb * Complex.abs z ≤ Complex.abs (f' d c (f' d c z)) e0 : f_error d z ≤ s0 / (Complex.abs z * (Complex.abs z).log) ⊢ 0 < Complex.abs z TACTIC:
https://github.com/girving/ray.git	0be790285dd0fce78913b0cb9bddaffa94bd25f9	Ray/Dynamics/Multibrot/Iterates.lean	iter_error_le	[276, 1]	[342, 54]	positivity	c✝ : ℂ d : ℕ inst✝ : Fact (2 ≤ d) i b s0 s1 s2 : ℝ c : ℂ b3 : 3 ≤ b s1p : 0 ≤ s1 s2p : 0 ≤ s2 bs0 : ∀ {w : ℂ}, b ≤ Complex.abs w → f_error d w ≤ s0 / (Complex.abs w * (Complex.abs w).log) bs1 : ∀ {w : ℂ}, (b ^ (d - 1) - 1) * b ≤ Complex.abs w → f_error d w ≤ s1 / (Complex.abs w * (Complex.abs w).log) b0' : 0 < b ^ (d - 1) - 1 z : ℂ bz : b ≤ Complex.abs z cz : Complex.abs c ≤ Complex.abs z b0 : 0 < b z0 : 0 < Complex.abs z z3 : 3 ≤ Complex.abs z l0 : 1 < (Complex.abs z).log bb : ℝ hbb : (b ^ (d - 1) - 1) ^ d * b ^ (d - 1) - 1 = bb b11 : 11 ≤ bb bb3 : 3 ≤ bb * b bs2 : ∀ {w : ℂ}, bb * b ≤ Complex.abs w → f_error d w ≤ s2 / (Complex.abs w * (Complex.abs w).log) b0'' : 0 < 1 - (bb * b - 1)⁻¹ si : s0 + s1 / (b ^ (d - 1) - 1) + s2 / ((1 - (bb * b - 1)⁻¹) * bb) ≤ i fz : Complex.abs z ^ d - Complex.abs c ≤ Complex.abs (f' d c z) fz' : (b ^ (d - 1) - 1) * Complex.abs z ≤ Complex.abs (f' d c z) zfz : Complex.abs z ≤ Complex.abs (f' d c z) zffz : Complex.abs z ≤ Complex.abs (f' d c (f' d c z)) bfz : b ≤ Complex.abs (f' d c z) ffz : bb * Complex.abs z ≤ Complex.abs (f' d c (f' d c z)) e0 : f_error d z ≤ s0 / (Complex.abs z * (Complex.abs z).log) ⊢ 0 ≤ (Complex.abs z).log	no goals	Please generate a tactic in lean4 to solve the state. STATE: c✝ : ℂ d : ℕ inst✝ : Fact (2 ≤ d) i b s0 s1 s2 : ℝ c : ℂ b3 : 3 ≤ b s1p : 0 ≤ s1 s2p : 0 ≤ s2 bs0 : ∀ {w : ℂ}, b ≤ Complex.abs w → f_error d w ≤ s0 / (Complex.abs w * (Complex.abs w).log) bs1 : ∀ {w : ℂ}, (b ^ (d - 1) - 1) * b ≤ Complex.abs w → f_error d w ≤ s1 / (Complex.abs w * (Complex.abs w).log) b0' : 0 < b ^ (d - 1) - 1 z : ℂ bz : b ≤ Complex.abs z cz : Complex.abs c ≤ Complex.abs z b0 : 0 < b z0 : 0 < Complex.abs z z3 : 3 ≤ Complex.abs z l0 : 1 < (Complex.abs z).log bb : ℝ hbb : (b ^ (d - 1) - 1) ^ d * b ^ (d - 1) - 1 = bb b11 : 11 ≤ bb bb3 : 3 ≤ bb * b bs2 : ∀ {w : ℂ}, bb * b ≤ Complex.abs w → f_error d w ≤ s2 / (Complex.abs w * (Complex.abs w).log) b0'' : 0 < 1 - (bb * b - 1)⁻¹ si : s0 + s1 / (b ^ (d - 1) - 1) + s2 / ((1 - (bb * b - 1)⁻¹) * bb) ≤ i fz : Complex.abs z ^ d - Complex.abs c ≤ Complex.abs (f' d c z) fz' : (b ^ (d - 1) - 1) * Complex.abs z ≤ Complex.abs (f' d c z) zfz : Complex.abs z ≤ Complex.abs (f' d c z) zffz : Complex.abs z ≤ Complex.abs (f' d c (f' d c z)) bfz : b ≤ Complex.abs (f' d c z) ffz : bb * Complex.abs z ≤ Complex.abs (f' d c (f' d c z)) e0 : f_error d z ≤ s0 / (Complex.abs z * (Complex.abs z).log) ⊢ 0 ≤ (Complex.abs z).log TACTIC:
https://github.com/girving/ray.git	0be790285dd0fce78913b0cb9bddaffa94bd25f9	Ray/Dynamics/Multibrot/Iterates.lean	iter_error_le	[276, 1]	[342, 54]	refine le_trans (iter_error_weak d bb3 s2p bs2 ?_ (le_trans cz zffz)) ?_	c✝ : ℂ d : ℕ inst✝ : Fact (2 ≤ d) i b s0 s1 s2 : ℝ c : ℂ b3 : 3 ≤ b s1p : 0 ≤ s1 s2p : 0 ≤ s2 bs0 : ∀ {w : ℂ}, b ≤ Complex.abs w → f_error d w ≤ s0 / (Complex.abs w * (Complex.abs w).log) bs1 : ∀ {w : ℂ}, (b ^ (d - 1) - 1) * b ≤ Complex.abs w → f_error d w ≤ s1 / (Complex.abs w * (Complex.abs w).log) b0' : 0 < b ^ (d - 1) - 1 z : ℂ bz : b ≤ Complex.abs z cz : Complex.abs c ≤ Complex.abs z b0 : 0 < b z0 : 0 < Complex.abs z z3 : 3 ≤ Complex.abs z l0 : 1 < (Complex.abs z).log bb : ℝ hbb : (b ^ (d - 1) - 1) ^ d * b ^ (d - 1) - 1 = bb b11 : 11 ≤ bb bb3 : 3 ≤ bb * b bs2 : ∀ {w : ℂ}, bb * b ≤ Complex.abs w → f_error d w ≤ s2 / (Complex.abs w * (Complex.abs w).log) b0'' : 0 < 1 - (bb * b - 1)⁻¹ si : s0 + s1 / (b ^ (d - 1) - 1) + s2 / ((1 - (bb * b - 1)⁻¹) * bb) ≤ i fz : Complex.abs z ^ d - Complex.abs c ≤ Complex.abs (f' d c z) fz' : (b ^ (d - 1) - 1) * Complex.abs z ≤ Complex.abs (f' d c z) zfz : Complex.abs z ≤ Complex.abs (f' d c z) zffz : Complex.abs z ≤ Complex.abs (f' d c (f' d c z)) bfz : b ≤ Complex.abs (f' d c z) ffz : bb * Complex.abs z ≤ Complex.abs (f' d c (f' d c z)) e0 : f_error d z ≤ s0 / (Complex.abs z * (Complex.abs z).log) e1 : f_error d (f' d c z) ≤ s1 / (b ^ (d - 1) - 1) / (Complex.abs z * (Complex.abs z).log) ⊢ iter_error d c (f' d c (f' d c z)) ≤ s2 / ((1 - (bb * b - 1)⁻¹) * bb) / (Complex.abs z * (Complex.abs z).log)	case refine_1 c✝ : ℂ d : ℕ inst✝ : Fact (2 ≤ d) i b s0 s1 s2 : ℝ c : ℂ b3 : 3 ≤ b s1p : 0 ≤ s1 s2p : 0 ≤ s2 bs0 : ∀ {w : ℂ}, b ≤ Complex.abs w → f_error d w ≤ s0 / (Complex.abs w * (Complex.abs w).log) bs1 : ∀ {w : ℂ}, (b ^ (d - 1) - 1) * b ≤ Complex.abs w → f_error d w ≤ s1 / (Complex.abs w * (Complex.abs w).log) b0' : 0 < b ^ (d - 1) - 1 z : ℂ bz : b ≤ Complex.abs z cz : Complex.abs c ≤ Complex.abs z b0 : 0 < b z0 : 0 < Complex.abs z z3 : 3 ≤ Complex.abs z l0 : 1 < (Complex.abs z).log bb : ℝ hbb : (b ^ (d - 1) - 1) ^ d * b ^ (d - 1) - 1 = bb b11 : 11 ≤ bb bb3 : 3 ≤ bb * b bs2 : ∀ {w : ℂ}, bb * b ≤ Complex.abs w → f_error d w ≤ s2 / (Complex.abs w * (Complex.abs w).log) b0'' : 0 < 1 - (bb * b - 1)⁻¹ si : s0 + s1 / (b ^ (d - 1) - 1) + s2 / ((1 - (bb * b - 1)⁻¹) * bb) ≤ i fz : Complex.abs z ^ d - Complex.abs c ≤ Complex.abs (f' d c z) fz' : (b ^ (d - 1) - 1) * Complex.abs z ≤ Complex.abs (f' d c z) zfz : Complex.abs z ≤ Complex.abs (f' d c z) zffz : Complex.abs z ≤ Complex.abs (f' d c (f' d c z)) bfz : b ≤ Complex.abs (f' d c z) ffz : bb * Complex.abs z ≤ Complex.abs (f' d c (f' d c z)) e0 : f_error d z ≤ s0 / (Complex.abs z * (Complex.abs z).log) e1 : f_error d (f' d c z) ≤ s1 / (b ^ (d - 1) - 1) / (Complex.abs z * (Complex.abs z).log) ⊢ bb * b ≤ Complex.abs (f' d c (f' d c z)) case refine_2 c✝ : ℂ d : ℕ inst✝ : Fact (2 ≤ d) i b s0 s1 s2 : ℝ c : ℂ b3 : 3 ≤ b s1p : 0 ≤ s1 s2p : 0 ≤ s2 bs0 : ∀ {w : ℂ}, b ≤ Complex.abs w → f_error d w ≤ s0 / (Complex.abs w * (Complex.abs w).log) bs1 : ∀ {w : ℂ}, (b ^ (d - 1) - 1) * b ≤ Complex.abs w → f_error d w ≤ s1 / (Complex.abs w * (Complex.abs w).log) b0' : 0 < b ^ (d - 1) - 1 z : ℂ bz : b ≤ Complex.abs z cz : Complex.abs c ≤ Complex.abs z b0 : 0 < b z0 : 0 < Complex.abs z z3 : 3 ≤ Complex.abs z l0 : 1 < (Complex.abs z).log bb : ℝ hbb : (b ^ (d - 1) - 1) ^ d * b ^ (d - 1) - 1 = bb b11 : 11 ≤ bb bb3 : 3 ≤ bb * b bs2 : ∀ {w : ℂ}, bb * b ≤ Complex.abs w → f_error d w ≤ s2 / (Complex.abs w * (Complex.abs w).log) b0'' : 0 < 1 - (bb * b - 1)⁻¹ si : s0 + s1 / (b ^ (d - 1) - 1) + s2 / ((1 - (bb * b - 1)⁻¹) * bb) ≤ i fz : Complex.abs z ^ d - Complex.abs c ≤ Complex.abs (f' d c z) fz' : (b ^ (d - 1) - 1) * Complex.abs z ≤ Complex.abs (f' d c z) zfz : Complex.abs z ≤ Complex.abs (f' d c z) zffz : Complex.abs z ≤ Complex.abs (f' d c (f' d c z)) bfz : b ≤ Complex.abs (f' d c z) ffz : bb * Complex.abs z ≤ Complex.abs (f' d c (f' d c z)) e0 : f_error d z ≤ s0 / (Complex.abs z * (Complex.abs z).log) e1 : f_error d (f' d c z) ≤ s1 / (b ^ (d - 1) - 1) / (Complex.abs z * (Complex.abs z).log) ⊢ s2 / (1 - (bb * b - 1)⁻¹) / (Complex.abs (f' d c (f' d c z)) * (Complex.abs (f' d c (f' d c z))).log) ≤ s2 / ((1 - (bb * b - 1)⁻¹) * bb) / (Complex.abs z * (Complex.abs z).log)	Please generate a tactic in lean4 to solve the state. STATE: c✝ : ℂ d : ℕ inst✝ : Fact (2 ≤ d) i b s0 s1 s2 : ℝ c : ℂ b3 : 3 ≤ b s1p : 0 ≤ s1 s2p : 0 ≤ s2 bs0 : ∀ {w : ℂ}, b ≤ Complex.abs w → f_error d w ≤ s0 / (Complex.abs w * (Complex.abs w).log) bs1 : ∀ {w : ℂ}, (b ^ (d - 1) - 1) * b ≤ Complex.abs w → f_error d w ≤ s1 / (Complex.abs w * (Complex.abs w).log) b0' : 0 < b ^ (d - 1) - 1 z : ℂ bz : b ≤ Complex.abs z cz : Complex.abs c ≤ Complex.abs z b0 : 0 < b z0 : 0 < Complex.abs z z3 : 3 ≤ Complex.abs z l0 : 1 < (Complex.abs z).log bb : ℝ hbb : (b ^ (d - 1) - 1) ^ d * b ^ (d - 1) - 1 = bb b11 : 11 ≤ bb bb3 : 3 ≤ bb * b bs2 : ∀ {w : ℂ}, bb * b ≤ Complex.abs w → f_error d w ≤ s2 / (Complex.abs w * (Complex.abs w).log) b0'' : 0 < 1 - (bb * b - 1)⁻¹ si : s0 + s1 / (b ^ (d - 1) - 1) + s2 / ((1 - (bb * b - 1)⁻¹) * bb) ≤ i fz : Complex.abs z ^ d - Complex.abs c ≤ Complex.abs (f' d c z) fz' : (b ^ (d - 1) - 1) * Complex.abs z ≤ Complex.abs (f' d c z) zfz : Complex.abs z ≤ Complex.abs (f' d c z) zffz : Complex.abs z ≤ Complex.abs (f' d c (f' d c z)) bfz : b ≤ Complex.abs (f' d c z) ffz : bb * Complex.abs z ≤ Complex.abs (f' d c (f' d c z)) e0 : f_error d z ≤ s0 / (Complex.abs z * (Complex.abs z).log) e1 : f_error d (f' d c z) ≤ s1 / (b ^ (d - 1) - 1) / (Complex.abs z * (Complex.abs z).log) ⊢ iter_error d c (f' d c (f' d c z)) ≤ s2 / ((1 - (bb * b - 1)⁻¹) * bb) / (Complex.abs z * (Complex.abs z).log) TACTIC:
https://github.com/girving/ray.git	0be790285dd0fce78913b0cb9bddaffa94bd25f9	Ray/Dynamics/Multibrot/Iterates.lean	iter_error_le	[276, 1]	[342, 54]	exact le_trans (mul_le_mul_of_nonneg_left bz (by positivity)) ffz	case refine_1 c✝ : ℂ d : ℕ inst✝ : Fact (2 ≤ d) i b s0 s1 s2 : ℝ c : ℂ b3 : 3 ≤ b s1p : 0 ≤ s1 s2p : 0 ≤ s2 bs0 : ∀ {w : ℂ}, b ≤ Complex.abs w → f_error d w ≤ s0 / (Complex.abs w * (Complex.abs w).log) bs1 : ∀ {w : ℂ}, (b ^ (d - 1) - 1) * b ≤ Complex.abs w → f_error d w ≤ s1 / (Complex.abs w * (Complex.abs w).log) b0' : 0 < b ^ (d - 1) - 1 z : ℂ bz : b ≤ Complex.abs z cz : Complex.abs c ≤ Complex.abs z b0 : 0 < b z0 : 0 < Complex.abs z z3 : 3 ≤ Complex.abs z l0 : 1 < (Complex.abs z).log bb : ℝ hbb : (b ^ (d - 1) - 1) ^ d * b ^ (d - 1) - 1 = bb b11 : 11 ≤ bb bb3 : 3 ≤ bb * b bs2 : ∀ {w : ℂ}, bb * b ≤ Complex.abs w → f_error d w ≤ s2 / (Complex.abs w * (Complex.abs w).log) b0'' : 0 < 1 - (bb * b - 1)⁻¹ si : s0 + s1 / (b ^ (d - 1) - 1) + s2 / ((1 - (bb * b - 1)⁻¹) * bb) ≤ i fz : Complex.abs z ^ d - Complex.abs c ≤ Complex.abs (f' d c z) fz' : (b ^ (d - 1) - 1) * Complex.abs z ≤ Complex.abs (f' d c z) zfz : Complex.abs z ≤ Complex.abs (f' d c z) zffz : Complex.abs z ≤ Complex.abs (f' d c (f' d c z)) bfz : b ≤ Complex.abs (f' d c z) ffz : bb * Complex.abs z ≤ Complex.abs (f' d c (f' d c z)) e0 : f_error d z ≤ s0 / (Complex.abs z * (Complex.abs z).log) e1 : f_error d (f' d c z) ≤ s1 / (b ^ (d - 1) - 1) / (Complex.abs z * (Complex.abs z).log) ⊢ bb * b ≤ Complex.abs (f' d c (f' d c z))	no goals	Please generate a tactic in lean4 to solve the state. STATE: case refine_1 c✝ : ℂ d : ℕ inst✝ : Fact (2 ≤ d) i b s0 s1 s2 : ℝ c : ℂ b3 : 3 ≤ b s1p : 0 ≤ s1 s2p : 0 ≤ s2 bs0 : ∀ {w : ℂ}, b ≤ Complex.abs w → f_error d w ≤ s0 / (Complex.abs w * (Complex.abs w).log) bs1 : ∀ {w : ℂ}, (b ^ (d - 1) - 1) * b ≤ Complex.abs w → f_error d w ≤ s1 / (Complex.abs w * (Complex.abs w).log) b0' : 0 < b ^ (d - 1) - 1 z : ℂ bz : b ≤ Complex.abs z cz : Complex.abs c ≤ Complex.abs z b0 : 0 < b z0 : 0 < Complex.abs z z3 : 3 ≤ Complex.abs z l0 : 1 < (Complex.abs z).log bb : ℝ hbb : (b ^ (d - 1) - 1) ^ d * b ^ (d - 1) - 1 = bb b11 : 11 ≤ bb bb3 : 3 ≤ bb * b bs2 : ∀ {w : ℂ}, bb * b ≤ Complex.abs w → f_error d w ≤ s2 / (Complex.abs w * (Complex.abs w).log) b0'' : 0 < 1 - (bb * b - 1)⁻¹ si : s0 + s1 / (b ^ (d - 1) - 1) + s2 / ((1 - (bb * b - 1)⁻¹) * bb) ≤ i fz : Complex.abs z ^ d - Complex.abs c ≤ Complex.abs (f' d c z) fz' : (b ^ (d - 1) - 1) * Complex.abs z ≤ Complex.abs (f' d c z) zfz : Complex.abs z ≤ Complex.abs (f' d c z) zffz : Complex.abs z ≤ Complex.abs (f' d c (f' d c z)) bfz : b ≤ Complex.abs (f' d c z) ffz : bb * Complex.abs z ≤ Complex.abs (f' d c (f' d c z)) e0 : f_error d z ≤ s0 / (Complex.abs z * (Complex.abs z).log) e1 : f_error d (f' d c z) ≤ s1 / (b ^ (d - 1) - 1) / (Complex.abs z * (Complex.abs z).log) ⊢ bb * b ≤ Complex.abs (f' d c (f' d c z)) TACTIC:
https://github.com/girving/ray.git	0be790285dd0fce78913b0cb9bddaffa94bd25f9	Ray/Dynamics/Multibrot/Iterates.lean	iter_error_le	[276, 1]	[342, 54]	positivity	c✝ : ℂ d : ℕ inst✝ : Fact (2 ≤ d) i b s0 s1 s2 : ℝ c : ℂ b3 : 3 ≤ b s1p : 0 ≤ s1 s2p : 0 ≤ s2 bs0 : ∀ {w : ℂ}, b ≤ Complex.abs w → f_error d w ≤ s0 / (Complex.abs w * (Complex.abs w).log) bs1 : ∀ {w : ℂ}, (b ^ (d - 1) - 1) * b ≤ Complex.abs w → f_error d w ≤ s1 / (Complex.abs w * (Complex.abs w).log) b0' : 0 < b ^ (d - 1) - 1 z : ℂ bz : b ≤ Complex.abs z cz : Complex.abs c ≤ Complex.abs z b0 : 0 < b z0 : 0 < Complex.abs z z3 : 3 ≤ Complex.abs z l0 : 1 < (Complex.abs z).log bb : ℝ hbb : (b ^ (d - 1) - 1) ^ d * b ^ (d - 1) - 1 = bb b11 : 11 ≤ bb bb3 : 3 ≤ bb * b bs2 : ∀ {w : ℂ}, bb * b ≤ Complex.abs w → f_error d w ≤ s2 / (Complex.abs w * (Complex.abs w).log) b0'' : 0 < 1 - (bb * b - 1)⁻¹ si : s0 + s1 / (b ^ (d - 1) - 1) + s2 / ((1 - (bb * b - 1)⁻¹) * bb) ≤ i fz : Complex.abs z ^ d - Complex.abs c ≤ Complex.abs (f' d c z) fz' : (b ^ (d - 1) - 1) * Complex.abs z ≤ Complex.abs (f' d c z) zfz : Complex.abs z ≤ Complex.abs (f' d c z) zffz : Complex.abs z ≤ Complex.abs (f' d c (f' d c z)) bfz : b ≤ Complex.abs (f' d c z) ffz : bb * Complex.abs z ≤ Complex.abs (f' d c (f' d c z)) e0 : f_error d z ≤ s0 / (Complex.abs z * (Complex.abs z).log) e1 : f_error d (f' d c z) ≤ s1 / (b ^ (d - 1) - 1) / (Complex.abs z * (Complex.abs z).log) ⊢ 0 ≤ bb	no goals	Please generate a tactic in lean4 to solve the state. STATE: c✝ : ℂ d : ℕ inst✝ : Fact (2 ≤ d) i b s0 s1 s2 : ℝ c : ℂ b3 : 3 ≤ b s1p : 0 ≤ s1 s2p : 0 ≤ s2 bs0 : ∀ {w : ℂ}, b ≤ Complex.abs w → f_error d w ≤ s0 / (Complex.abs w * (Complex.abs w).log) bs1 : ∀ {w : ℂ}, (b ^ (d - 1) - 1) * b ≤ Complex.abs w → f_error d w ≤ s1 / (Complex.abs w * (Complex.abs w).log) b0' : 0 < b ^ (d - 1) - 1 z : ℂ bz : b ≤ Complex.abs z cz : Complex.abs c ≤ Complex.abs z b0 : 0 < b z0 : 0 < Complex.abs z z3 : 3 ≤ Complex.abs z l0 : 1 < (Complex.abs z).log bb : ℝ hbb : (b ^ (d - 1) - 1) ^ d * b ^ (d - 1) - 1 = bb b11 : 11 ≤ bb bb3 : 3 ≤ bb * b bs2 : ∀ {w : ℂ}, bb * b ≤ Complex.abs w → f_error d w ≤ s2 / (Complex.abs w * (Complex.abs w).log) b0'' : 0 < 1 - (bb * b - 1)⁻¹ si : s0 + s1 / (b ^ (d - 1) - 1) + s2 / ((1 - (bb * b - 1)⁻¹) * bb) ≤ i fz : Complex.abs z ^ d - Complex.abs c ≤ Complex.abs (f' d c z) fz' : (b ^ (d - 1) - 1) * Complex.abs z ≤ Complex.abs (f' d c z) zfz : Complex.abs z ≤ Complex.abs (f' d c z) zffz : Complex.abs z ≤ Complex.abs (f' d c (f' d c z)) bfz : b ≤ Complex.abs (f' d c z) ffz : bb * Complex.abs z ≤ Complex.abs (f' d c (f' d c z)) e0 : f_error d z ≤ s0 / (Complex.abs z * (Complex.abs z).log) e1 : f_error d (f' d c z) ≤ s1 / (b ^ (d - 1) - 1) / (Complex.abs z * (Complex.abs z).log) ⊢ 0 ≤ bb TACTIC:
https://github.com/girving/ray.git	0be790285dd0fce78913b0cb9bddaffa94bd25f9	Ray/Dynamics/Multibrot/Iterates.lean	iter_error_le	[276, 1]	[342, 54]	simp only [div_eq_mul_inv, mul_assoc s2]	case refine_2 c✝ : ℂ d : ℕ inst✝ : Fact (2 ≤ d) i b s0 s1 s2 : ℝ c : ℂ b3 : 3 ≤ b s1p : 0 ≤ s1 s2p : 0 ≤ s2 bs0 : ∀ {w : ℂ}, b ≤ Complex.abs w → f_error d w ≤ s0 / (Complex.abs w * (Complex.abs w).log) bs1 : ∀ {w : ℂ}, (b ^ (d - 1) - 1) * b ≤ Complex.abs w → f_error d w ≤ s1 / (Complex.abs w * (Complex.abs w).log) b0' : 0 < b ^ (d - 1) - 1 z : ℂ bz : b ≤ Complex.abs z cz : Complex.abs c ≤ Complex.abs z b0 : 0 < b z0 : 0 < Complex.abs z z3 : 3 ≤ Complex.abs z l0 : 1 < (Complex.abs z).log bb : ℝ hbb : (b ^ (d - 1) - 1) ^ d * b ^ (d - 1) - 1 = bb b11 : 11 ≤ bb bb3 : 3 ≤ bb * b bs2 : ∀ {w : ℂ}, bb * b ≤ Complex.abs w → f_error d w ≤ s2 / (Complex.abs w * (Complex.abs w).log) b0'' : 0 < 1 - (bb * b - 1)⁻¹ si : s0 + s1 / (b ^ (d - 1) - 1) + s2 / ((1 - (bb * b - 1)⁻¹) * bb) ≤ i fz : Complex.abs z ^ d - Complex.abs c ≤ Complex.abs (f' d c z) fz' : (b ^ (d - 1) - 1) * Complex.abs z ≤ Complex.abs (f' d c z) zfz : Complex.abs z ≤ Complex.abs (f' d c z) zffz : Complex.abs z ≤ Complex.abs (f' d c (f' d c z)) bfz : b ≤ Complex.abs (f' d c z) ffz : bb * Complex.abs z ≤ Complex.abs (f' d c (f' d c z)) e0 : f_error d z ≤ s0 / (Complex.abs z * (Complex.abs z).log) e1 : f_error d (f' d c z) ≤ s1 / (b ^ (d - 1) - 1) / (Complex.abs z * (Complex.abs z).log) ⊢ s2 / (1 - (bb * b - 1)⁻¹) / (Complex.abs (f' d c (f' d c z)) * (Complex.abs (f' d c (f' d c z))).log) ≤ s2 / ((1 - (bb * b - 1)⁻¹) * bb) / (Complex.abs z * (Complex.abs z).log)	case refine_2 c✝ : ℂ d : ℕ inst✝ : Fact (2 ≤ d) i b s0 s1 s2 : ℝ c : ℂ b3 : 3 ≤ b s1p : 0 ≤ s1 s2p : 0 ≤ s2 bs0 : ∀ {w : ℂ}, b ≤ Complex.abs w → f_error d w ≤ s0 / (Complex.abs w * (Complex.abs w).log) bs1 : ∀ {w : ℂ}, (b ^ (d - 1) - 1) * b ≤ Complex.abs w → f_error d w ≤ s1 / (Complex.abs w * (Complex.abs w).log) b0' : 0 < b ^ (d - 1) - 1 z : ℂ bz : b ≤ Complex.abs z cz : Complex.abs c ≤ Complex.abs z b0 : 0 < b z0 : 0 < Complex.abs z z3 : 3 ≤ Complex.abs z l0 : 1 < (Complex.abs z).log bb : ℝ hbb : (b ^ (d - 1) - 1) ^ d * b ^ (d - 1) - 1 = bb b11 : 11 ≤ bb bb3 : 3 ≤ bb * b bs2 : ∀ {w : ℂ}, bb * b ≤ Complex.abs w → f_error d w ≤ s2 / (Complex.abs w * (Complex.abs w).log) b0'' : 0 < 1 - (bb * b - 1)⁻¹ si : s0 + s1 / (b ^ (d - 1) - 1) + s2 / ((1 - (bb * b - 1)⁻¹) * bb) ≤ i fz : Complex.abs z ^ d - Complex.abs c ≤ Complex.abs (f' d c z) fz' : (b ^ (d - 1) - 1) * Complex.abs z ≤ Complex.abs (f' d c z) zfz : Complex.abs z ≤ Complex.abs (f' d c z) zffz : Complex.abs z ≤ Complex.abs (f' d c (f' d c z)) bfz : b ≤ Complex.abs (f' d c z) ffz : bb * Complex.abs z ≤ Complex.abs (f' d c (f' d c z)) e0 : f_error d z ≤ s0 / (Complex.abs z * (Complex.abs z).log) e1 : f_error d (f' d c z) ≤ s1 / (b ^ (d - 1) - 1) / (Complex.abs z * (Complex.abs z).log) ⊢ s2 * ((1 - (bb * b - 1)⁻¹)⁻¹ * (Complex.abs (f' d c (f' d c z)) * (Complex.abs (f' d c (f' d c z))).log)⁻¹) ≤ s2 * (((1 - (bb * b - 1)⁻¹) * bb)⁻¹ * (Complex.abs z * (Complex.abs z).log)⁻¹)	Please generate a tactic in lean4 to solve the state. STATE: case refine_2 c✝ : ℂ d : ℕ inst✝ : Fact (2 ≤ d) i b s0 s1 s2 : ℝ c : ℂ b3 : 3 ≤ b s1p : 0 ≤ s1 s2p : 0 ≤ s2 bs0 : ∀ {w : ℂ}, b ≤ Complex.abs w → f_error d w ≤ s0 / (Complex.abs w * (Complex.abs w).log) bs1 : ∀ {w : ℂ}, (b ^ (d - 1) - 1) * b ≤ Complex.abs w → f_error d w ≤ s1 / (Complex.abs w * (Complex.abs w).log) b0' : 0 < b ^ (d - 1) - 1 z : ℂ bz : b ≤ Complex.abs z cz : Complex.abs c ≤ Complex.abs z b0 : 0 < b z0 : 0 < Complex.abs z z3 : 3 ≤ Complex.abs z l0 : 1 < (Complex.abs z).log bb : ℝ hbb : (b ^ (d - 1) - 1) ^ d * b ^ (d - 1) - 1 = bb b11 : 11 ≤ bb bb3 : 3 ≤ bb * b bs2 : ∀ {w : ℂ}, bb * b ≤ Complex.abs w → f_error d w ≤ s2 / (Complex.abs w * (Complex.abs w).log) b0'' : 0 < 1 - (bb * b - 1)⁻¹ si : s0 + s1 / (b ^ (d - 1) - 1) + s2 / ((1 - (bb * b - 1)⁻¹) * bb) ≤ i fz : Complex.abs z ^ d - Complex.abs c ≤ Complex.abs (f' d c z) fz' : (b ^ (d - 1) - 1) * Complex.abs z ≤ Complex.abs (f' d c z) zfz : Complex.abs z ≤ Complex.abs (f' d c z) zffz : Complex.abs z ≤ Complex.abs (f' d c (f' d c z)) bfz : b ≤ Complex.abs (f' d c z) ffz : bb * Complex.abs z ≤ Complex.abs (f' d c (f' d c z)) e0 : f_error d z ≤ s0 / (Complex.abs z * (Complex.abs z).log) e1 : f_error d (f' d c z) ≤ s1 / (b ^ (d - 1) - 1) / (Complex.abs z * (Complex.abs z).log) ⊢ s2 / (1 - (bb * b - 1)⁻¹) / (Complex.abs (f' d c (f' d c z)) * (Complex.abs (f' d c (f' d c z))).log) ≤ s2 / ((1 - (bb * b - 1)⁻¹) * bb) / (Complex.abs z * (Complex.abs z).log) TACTIC:
https://github.com/girving/ray.git	0be790285dd0fce78913b0cb9bddaffa94bd25f9	Ray/Dynamics/Multibrot/Iterates.lean	iter_error_le	[276, 1]	[342, 54]	refine mul_le_mul_of_nonneg_left ?_ s2p	case refine_2 c✝ : ℂ d : ℕ inst✝ : Fact (2 ≤ d) i b s0 s1 s2 : ℝ c : ℂ b3 : 3 ≤ b s1p : 0 ≤ s1 s2p : 0 ≤ s2 bs0 : ∀ {w : ℂ}, b ≤ Complex.abs w → f_error d w ≤ s0 / (Complex.abs w * (Complex.abs w).log) bs1 : ∀ {w : ℂ}, (b ^ (d - 1) - 1) * b ≤ Complex.abs w → f_error d w ≤ s1 / (Complex.abs w * (Complex.abs w).log) b0' : 0 < b ^ (d - 1) - 1 z : ℂ bz : b ≤ Complex.abs z cz : Complex.abs c ≤ Complex.abs z b0 : 0 < b z0 : 0 < Complex.abs z z3 : 3 ≤ Complex.abs z l0 : 1 < (Complex.abs z).log bb : ℝ hbb : (b ^ (d - 1) - 1) ^ d * b ^ (d - 1) - 1 = bb b11 : 11 ≤ bb bb3 : 3 ≤ bb * b bs2 : ∀ {w : ℂ}, bb * b ≤ Complex.abs w → f_error d w ≤ s2 / (Complex.abs w * (Complex.abs w).log) b0'' : 0 < 1 - (bb * b - 1)⁻¹ si : s0 + s1 / (b ^ (d - 1) - 1) + s2 / ((1 - (bb * b - 1)⁻¹) * bb) ≤ i fz : Complex.abs z ^ d - Complex.abs c ≤ Complex.abs (f' d c z) fz' : (b ^ (d - 1) - 1) * Complex.abs z ≤ Complex.abs (f' d c z) zfz : Complex.abs z ≤ Complex.abs (f' d c z) zffz : Complex.abs z ≤ Complex.abs (f' d c (f' d c z)) bfz : b ≤ Complex.abs (f' d c z) ffz : bb * Complex.abs z ≤ Complex.abs (f' d c (f' d c z)) e0 : f_error d z ≤ s0 / (Complex.abs z * (Complex.abs z).log) e1 : f_error d (f' d c z) ≤ s1 / (b ^ (d - 1) - 1) / (Complex.abs z * (Complex.abs z).log) ⊢ s2 * ((1 - (bb * b - 1)⁻¹)⁻¹ * (Complex.abs (f' d c (f' d c z)) * (Complex.abs (f' d c (f' d c z))).log)⁻¹) ≤ s2 * (((1 - (bb * b - 1)⁻¹) * bb)⁻¹ * (Complex.abs z * (Complex.abs z).log)⁻¹)	case refine_2 c✝ : ℂ d : ℕ inst✝ : Fact (2 ≤ d) i b s0 s1 s2 : ℝ c : ℂ b3 : 3 ≤ b s1p : 0 ≤ s1 s2p : 0 ≤ s2 bs0 : ∀ {w : ℂ}, b ≤ Complex.abs w → f_error d w ≤ s0 / (Complex.abs w * (Complex.abs w).log) bs1 : ∀ {w : ℂ}, (b ^ (d - 1) - 1) * b ≤ Complex.abs w → f_error d w ≤ s1 / (Complex.abs w * (Complex.abs w).log) b0' : 0 < b ^ (d - 1) - 1 z : ℂ bz : b ≤ Complex.abs z cz : Complex.abs c ≤ Complex.abs z b0 : 0 < b z0 : 0 < Complex.abs z z3 : 3 ≤ Complex.abs z l0 : 1 < (Complex.abs z).log bb : ℝ hbb : (b ^ (d - 1) - 1) ^ d * b ^ (d - 1) - 1 = bb b11 : 11 ≤ bb bb3 : 3 ≤ bb * b bs2 : ∀ {w : ℂ}, bb * b ≤ Complex.abs w → f_error d w ≤ s2 / (Complex.abs w * (Complex.abs w).log) b0'' : 0 < 1 - (bb * b - 1)⁻¹ si : s0 + s1 / (b ^ (d - 1) - 1) + s2 / ((1 - (bb * b - 1)⁻¹) * bb) ≤ i fz : Complex.abs z ^ d - Complex.abs c ≤ Complex.abs (f' d c z) fz' : (b ^ (d - 1) - 1) * Complex.abs z ≤ Complex.abs (f' d c z) zfz : Complex.abs z ≤ Complex.abs (f' d c z) zffz : Complex.abs z ≤ Complex.abs (f' d c (f' d c z)) bfz : b ≤ Complex.abs (f' d c z) ffz : bb * Complex.abs z ≤ Complex.abs (f' d c (f' d c z)) e0 : f_error d z ≤ s0 / (Complex.abs z * (Complex.abs z).log) e1 : f_error d (f' d c z) ≤ s1 / (b ^ (d - 1) - 1) / (Complex.abs z * (Complex.abs z).log) ⊢ (1 - (bb * b - 1)⁻¹)⁻¹ * (Complex.abs (f' d c (f' d c z)) * (Complex.abs (f' d c (f' d c z))).log)⁻¹ ≤ ((1 - (bb * b - 1)⁻¹) * bb)⁻¹ * (Complex.abs z * (Complex.abs z).log)⁻¹	Please generate a tactic in lean4 to solve the state. STATE: case refine_2 c✝ : ℂ d : ℕ inst✝ : Fact (2 ≤ d) i b s0 s1 s2 : ℝ c : ℂ b3 : 3 ≤ b s1p : 0 ≤ s1 s2p : 0 ≤ s2 bs0 : ∀ {w : ℂ}, b ≤ Complex.abs w → f_error d w ≤ s0 / (Complex.abs w * (Complex.abs w).log) bs1 : ∀ {w : ℂ}, (b ^ (d - 1) - 1) * b ≤ Complex.abs w → f_error d w ≤ s1 / (Complex.abs w * (Complex.abs w).log) b0' : 0 < b ^ (d - 1) - 1 z : ℂ bz : b ≤ Complex.abs z cz : Complex.abs c ≤ Complex.abs z b0 : 0 < b z0 : 0 < Complex.abs z z3 : 3 ≤ Complex.abs z l0 : 1 < (Complex.abs z).log bb : ℝ hbb : (b ^ (d - 1) - 1) ^ d * b ^ (d - 1) - 1 = bb b11 : 11 ≤ bb bb3 : 3 ≤ bb * b bs2 : ∀ {w : ℂ}, bb * b ≤ Complex.abs w → f_error d w ≤ s2 / (Complex.abs w * (Complex.abs w).log) b0'' : 0 < 1 - (bb * b - 1)⁻¹ si : s0 + s1 / (b ^ (d - 1) - 1) + s2 / ((1 - (bb * b - 1)⁻¹) * bb) ≤ i fz : Complex.abs z ^ d - Complex.abs c ≤ Complex.abs (f' d c z) fz' : (b ^ (d - 1) - 1) * Complex.abs z ≤ Complex.abs (f' d c z) zfz : Complex.abs z ≤ Complex.abs (f' d c z) zffz : Complex.abs z ≤ Complex.abs (f' d c (f' d c z)) bfz : b ≤ Complex.abs (f' d c z) ffz : bb * Complex.abs z ≤ Complex.abs (f' d c (f' d c z)) e0 : f_error d z ≤ s0 / (Complex.abs z * (Complex.abs z).log) e1 : f_error d (f' d c z) ≤ s1 / (b ^ (d - 1) - 1) / (Complex.abs z * (Complex.abs z).log) ⊢ s2 * ((1 - (bb * b - 1)⁻¹)⁻¹ * (Complex.abs (f' d c (f' d c z)) * (Complex.abs (f' d c (f' d c z))).log)⁻¹) ≤ s2 * (((1 - (bb * b - 1)⁻¹) * bb)⁻¹ * (Complex.abs z * (Complex.abs z).log)⁻¹) TACTIC:
https://github.com/girving/ray.git	0be790285dd0fce78913b0cb9bddaffa94bd25f9	Ray/Dynamics/Multibrot/Iterates.lean	iter_error_le	[276, 1]	[342, 54]	simp only [←mul_inv, ←mul_assoc]	case refine_2 c✝ : ℂ d : ℕ inst✝ : Fact (2 ≤ d) i b s0 s1 s2 : ℝ c : ℂ b3 : 3 ≤ b s1p : 0 ≤ s1 s2p : 0 ≤ s2 bs0 : ∀ {w : ℂ}, b ≤ Complex.abs w → f_error d w ≤ s0 / (Complex.abs w * (Complex.abs w).log) bs1 : ∀ {w : ℂ}, (b ^ (d - 1) - 1) * b ≤ Complex.abs w → f_error d w ≤ s1 / (Complex.abs w * (Complex.abs w).log) b0' : 0 < b ^ (d - 1) - 1 z : ℂ bz : b ≤ Complex.abs z cz : Complex.abs c ≤ Complex.abs z b0 : 0 < b z0 : 0 < Complex.abs z z3 : 3 ≤ Complex.abs z l0 : 1 < (Complex.abs z).log bb : ℝ hbb : (b ^ (d - 1) - 1) ^ d * b ^ (d - 1) - 1 = bb b11 : 11 ≤ bb bb3 : 3 ≤ bb * b bs2 : ∀ {w : ℂ}, bb * b ≤ Complex.abs w → f_error d w ≤ s2 / (Complex.abs w * (Complex.abs w).log) b0'' : 0 < 1 - (bb * b - 1)⁻¹ si : s0 + s1 / (b ^ (d - 1) - 1) + s2 / ((1 - (bb * b - 1)⁻¹) * bb) ≤ i fz : Complex.abs z ^ d - Complex.abs c ≤ Complex.abs (f' d c z) fz' : (b ^ (d - 1) - 1) * Complex.abs z ≤ Complex.abs (f' d c z) zfz : Complex.abs z ≤ Complex.abs (f' d c z) zffz : Complex.abs z ≤ Complex.abs (f' d c (f' d c z)) bfz : b ≤ Complex.abs (f' d c z) ffz : bb * Complex.abs z ≤ Complex.abs (f' d c (f' d c z)) e0 : f_error d z ≤ s0 / (Complex.abs z * (Complex.abs z).log) e1 : f_error d (f' d c z) ≤ s1 / (b ^ (d - 1) - 1) / (Complex.abs z * (Complex.abs z).log) ⊢ (1 - (bb * b - 1)⁻¹)⁻¹ * (Complex.abs (f' d c (f' d c z)) * (Complex.abs (f' d c (f' d c z))).log)⁻¹ ≤ ((1 - (bb * b - 1)⁻¹) * bb)⁻¹ * (Complex.abs z * (Complex.abs z).log)⁻¹	case refine_2 c✝ : ℂ d : ℕ inst✝ : Fact (2 ≤ d) i b s0 s1 s2 : ℝ c : ℂ b3 : 3 ≤ b s1p : 0 ≤ s1 s2p : 0 ≤ s2 bs0 : ∀ {w : ℂ}, b ≤ Complex.abs w → f_error d w ≤ s0 / (Complex.abs w * (Complex.abs w).log) bs1 : ∀ {w : ℂ}, (b ^ (d - 1) - 1) * b ≤ Complex.abs w → f_error d w ≤ s1 / (Complex.abs w * (Complex.abs w).log) b0' : 0 < b ^ (d - 1) - 1 z : ℂ bz : b ≤ Complex.abs z cz : Complex.abs c ≤ Complex.abs z b0 : 0 < b z0 : 0 < Complex.abs z z3 : 3 ≤ Complex.abs z l0 : 1 < (Complex.abs z).log bb : ℝ hbb : (b ^ (d - 1) - 1) ^ d * b ^ (d - 1) - 1 = bb b11 : 11 ≤ bb bb3 : 3 ≤ bb * b bs2 : ∀ {w : ℂ}, bb * b ≤ Complex.abs w → f_error d w ≤ s2 / (Complex.abs w * (Complex.abs w).log) b0'' : 0 < 1 - (bb * b - 1)⁻¹ si : s0 + s1 / (b ^ (d - 1) - 1) + s2 / ((1 - (bb * b - 1)⁻¹) * bb) ≤ i fz : Complex.abs z ^ d - Complex.abs c ≤ Complex.abs (f' d c z) fz' : (b ^ (d - 1) - 1) * Complex.abs z ≤ Complex.abs (f' d c z) zfz : Complex.abs z ≤ Complex.abs (f' d c z) zffz : Complex.abs z ≤ Complex.abs (f' d c (f' d c z)) bfz : b ≤ Complex.abs (f' d c z) ffz : bb * Complex.abs z ≤ Complex.abs (f' d c (f' d c z)) e0 : f_error d z ≤ s0 / (Complex.abs z * (Complex.abs z).log) e1 : f_error d (f' d c z) ≤ s1 / (b ^ (d - 1) - 1) / (Complex.abs z * (Complex.abs z).log) ⊢ ((1 - (bb * b - 1)⁻¹) * Complex.abs (f' d c (f' d c z)) * (Complex.abs (f' d c (f' d c z))).log)⁻¹ ≤ ((1 - (bb * b - 1)⁻¹) * bb * Complex.abs z * (Complex.abs z).log)⁻¹	Please generate a tactic in lean4 to solve the state. STATE: case refine_2 c✝ : ℂ d : ℕ inst✝ : Fact (2 ≤ d) i b s0 s1 s2 : ℝ c : ℂ b3 : 3 ≤ b s1p : 0 ≤ s1 s2p : 0 ≤ s2 bs0 : ∀ {w : ℂ}, b ≤ Complex.abs w → f_error d w ≤ s0 / (Complex.abs w * (Complex.abs w).log) bs1 : ∀ {w : ℂ}, (b ^ (d - 1) - 1) * b ≤ Complex.abs w → f_error d w ≤ s1 / (Complex.abs w * (Complex.abs w).log) b0' : 0 < b ^ (d - 1) - 1 z : ℂ bz : b ≤ Complex.abs z cz : Complex.abs c ≤ Complex.abs z b0 : 0 < b z0 : 0 < Complex.abs z z3 : 3 ≤ Complex.abs z l0 : 1 < (Complex.abs z).log bb : ℝ hbb : (b ^ (d - 1) - 1) ^ d * b ^ (d - 1) - 1 = bb b11 : 11 ≤ bb bb3 : 3 ≤ bb * b bs2 : ∀ {w : ℂ}, bb * b ≤ Complex.abs w → f_error d w ≤ s2 / (Complex.abs w * (Complex.abs w).log) b0'' : 0 < 1 - (bb * b - 1)⁻¹ si : s0 + s1 / (b ^ (d - 1) - 1) + s2 / ((1 - (bb * b - 1)⁻¹) * bb) ≤ i fz : Complex.abs z ^ d - Complex.abs c ≤ Complex.abs (f' d c z) fz' : (b ^ (d - 1) - 1) * Complex.abs z ≤ Complex.abs (f' d c z) zfz : Complex.abs z ≤ Complex.abs (f' d c z) zffz : Complex.abs z ≤ Complex.abs (f' d c (f' d c z)) bfz : b ≤ Complex.abs (f' d c z) ffz : bb * Complex.abs z ≤ Complex.abs (f' d c (f' d c z)) e0 : f_error d z ≤ s0 / (Complex.abs z * (Complex.abs z).log) e1 : f_error d (f' d c z) ≤ s1 / (b ^ (d - 1) - 1) / (Complex.abs z * (Complex.abs z).log) ⊢ (1 - (bb * b - 1)⁻¹)⁻¹ * (Complex.abs (f' d c (f' d c z)) * (Complex.abs (f' d c (f' d c z))).log)⁻¹ ≤ ((1 - (bb * b - 1)⁻¹) * bb)⁻¹ * (Complex.abs z * (Complex.abs z).log)⁻¹ TACTIC:
https://github.com/girving/ray.git	0be790285dd0fce78913b0cb9bddaffa94bd25f9	Ray/Dynamics/Multibrot/Iterates.lean	iter_error_le	[276, 1]	[342, 54]	refine inv_le_inv_of_le (by positivity) ?_	case refine_2 c✝ : ℂ d : ℕ inst✝ : Fact (2 ≤ d) i b s0 s1 s2 : ℝ c : ℂ b3 : 3 ≤ b s1p : 0 ≤ s1 s2p : 0 ≤ s2 bs0 : ∀ {w : ℂ}, b ≤ Complex.abs w → f_error d w ≤ s0 / (Complex.abs w * (Complex.abs w).log) bs1 : ∀ {w : ℂ}, (b ^ (d - 1) - 1) * b ≤ Complex.abs w → f_error d w ≤ s1 / (Complex.abs w * (Complex.abs w).log) b0' : 0 < b ^ (d - 1) - 1 z : ℂ bz : b ≤ Complex.abs z cz : Complex.abs c ≤ Complex.abs z b0 : 0 < b z0 : 0 < Complex.abs z z3 : 3 ≤ Complex.abs z l0 : 1 < (Complex.abs z).log bb : ℝ hbb : (b ^ (d - 1) - 1) ^ d * b ^ (d - 1) - 1 = bb b11 : 11 ≤ bb bb3 : 3 ≤ bb * b bs2 : ∀ {w : ℂ}, bb * b ≤ Complex.abs w → f_error d w ≤ s2 / (Complex.abs w * (Complex.abs w).log) b0'' : 0 < 1 - (bb * b - 1)⁻¹ si : s0 + s1 / (b ^ (d - 1) - 1) + s2 / ((1 - (bb * b - 1)⁻¹) * bb) ≤ i fz : Complex.abs z ^ d - Complex.abs c ≤ Complex.abs (f' d c z) fz' : (b ^ (d - 1) - 1) * Complex.abs z ≤ Complex.abs (f' d c z) zfz : Complex.abs z ≤ Complex.abs (f' d c z) zffz : Complex.abs z ≤ Complex.abs (f' d c (f' d c z)) bfz : b ≤ Complex.abs (f' d c z) ffz : bb * Complex.abs z ≤ Complex.abs (f' d c (f' d c z)) e0 : f_error d z ≤ s0 / (Complex.abs z * (Complex.abs z).log) e1 : f_error d (f' d c z) ≤ s1 / (b ^ (d - 1) - 1) / (Complex.abs z * (Complex.abs z).log) ⊢ ((1 - (bb * b - 1)⁻¹) * Complex.abs (f' d c (f' d c z)) * (Complex.abs (f' d c (f' d c z))).log)⁻¹ ≤ ((1 - (bb * b - 1)⁻¹) * bb * Complex.abs z * (Complex.abs z).log)⁻¹	case refine_2 c✝ : ℂ d : ℕ inst✝ : Fact (2 ≤ d) i b s0 s1 s2 : ℝ c : ℂ b3 : 3 ≤ b s1p : 0 ≤ s1 s2p : 0 ≤ s2 bs0 : ∀ {w : ℂ}, b ≤ Complex.abs w → f_error d w ≤ s0 / (Complex.abs w * (Complex.abs w).log) bs1 : ∀ {w : ℂ}, (b ^ (d - 1) - 1) * b ≤ Complex.abs w → f_error d w ≤ s1 / (Complex.abs w * (Complex.abs w).log) b0' : 0 < b ^ (d - 1) - 1 z : ℂ bz : b ≤ Complex.abs z cz : Complex.abs c ≤ Complex.abs z b0 : 0 < b z0 : 0 < Complex.abs z z3 : 3 ≤ Complex.abs z l0 : 1 < (Complex.abs z).log bb : ℝ hbb : (b ^ (d - 1) - 1) ^ d * b ^ (d - 1) - 1 = bb b11 : 11 ≤ bb bb3 : 3 ≤ bb * b bs2 : ∀ {w : ℂ}, bb * b ≤ Complex.abs w → f_error d w ≤ s2 / (Complex.abs w * (Complex.abs w).log) b0'' : 0 < 1 - (bb * b - 1)⁻¹ si : s0 + s1 / (b ^ (d - 1) - 1) + s2 / ((1 - (bb * b - 1)⁻¹) * bb) ≤ i fz : Complex.abs z ^ d - Complex.abs c ≤ Complex.abs (f' d c z) fz' : (b ^ (d - 1) - 1) * Complex.abs z ≤ Complex.abs (f' d c z) zfz : Complex.abs z ≤ Complex.abs (f' d c z) zffz : Complex.abs z ≤ Complex.abs (f' d c (f' d c z)) bfz : b ≤ Complex.abs (f' d c z) ffz : bb * Complex.abs z ≤ Complex.abs (f' d c (f' d c z)) e0 : f_error d z ≤ s0 / (Complex.abs z * (Complex.abs z).log) e1 : f_error d (f' d c z) ≤ s1 / (b ^ (d - 1) - 1) / (Complex.abs z * (Complex.abs z).log) ⊢ (1 - (bb * b - 1)⁻¹) * bb * Complex.abs z * (Complex.abs z).log ≤ (1 - (bb * b - 1)⁻¹) * Complex.abs (f' d c (f' d c z)) * (Complex.abs (f' d c (f' d c z))).log	Please generate a tactic in lean4 to solve the state. STATE: case refine_2 c✝ : ℂ d : ℕ inst✝ : Fact (2 ≤ d) i b s0 s1 s2 : ℝ c : ℂ b3 : 3 ≤ b s1p : 0 ≤ s1 s2p : 0 ≤ s2 bs0 : ∀ {w : ℂ}, b ≤ Complex.abs w → f_error d w ≤ s0 / (Complex.abs w * (Complex.abs w).log) bs1 : ∀ {w : ℂ}, (b ^ (d - 1) - 1) * b ≤ Complex.abs w → f_error d w ≤ s1 / (Complex.abs w * (Complex.abs w).log) b0' : 0 < b ^ (d - 1) - 1 z : ℂ bz : b ≤ Complex.abs z cz : Complex.abs c ≤ Complex.abs z b0 : 0 < b z0 : 0 < Complex.abs z z3 : 3 ≤ Complex.abs z l0 : 1 < (Complex.abs z).log bb : ℝ hbb : (b ^ (d - 1) - 1) ^ d * b ^ (d - 1) - 1 = bb b11 : 11 ≤ bb bb3 : 3 ≤ bb * b bs2 : ∀ {w : ℂ}, bb * b ≤ Complex.abs w → f_error d w ≤ s2 / (Complex.abs w * (Complex.abs w).log) b0'' : 0 < 1 - (bb * b - 1)⁻¹ si : s0 + s1 / (b ^ (d - 1) - 1) + s2 / ((1 - (bb * b - 1)⁻¹) * bb) ≤ i fz : Complex.abs z ^ d - Complex.abs c ≤ Complex.abs (f' d c z) fz' : (b ^ (d - 1) - 1) * Complex.abs z ≤ Complex.abs (f' d c z) zfz : Complex.abs z ≤ Complex.abs (f' d c z) zffz : Complex.abs z ≤ Complex.abs (f' d c (f' d c z)) bfz : b ≤ Complex.abs (f' d c z) ffz : bb * Complex.abs z ≤ Complex.abs (f' d c (f' d c z)) e0 : f_error d z ≤ s0 / (Complex.abs z * (Complex.abs z).log) e1 : f_error d (f' d c z) ≤ s1 / (b ^ (d - 1) - 1) / (Complex.abs z * (Complex.abs z).log) ⊢ ((1 - (bb * b - 1)⁻¹) * Complex.abs (f' d c (f' d c z)) * (Complex.abs (f' d c (f' d c z))).log)⁻¹ ≤ ((1 - (bb * b - 1)⁻¹) * bb * Complex.abs z * (Complex.abs z).log)⁻¹ TACTIC:
https://github.com/girving/ray.git	0be790285dd0fce78913b0cb9bddaffa94bd25f9	Ray/Dynamics/Multibrot/Iterates.lean	iter_error_le	[276, 1]	[342, 54]	refine mul_le_mul ?_ (Real.log_le_log z0 zffz) (by positivity) (by positivity)	case refine_2 c✝ : ℂ d : ℕ inst✝ : Fact (2 ≤ d) i b s0 s1 s2 : ℝ c : ℂ b3 : 3 ≤ b s1p : 0 ≤ s1 s2p : 0 ≤ s2 bs0 : ∀ {w : ℂ}, b ≤ Complex.abs w → f_error d w ≤ s0 / (Complex.abs w * (Complex.abs w).log) bs1 : ∀ {w : ℂ}, (b ^ (d - 1) - 1) * b ≤ Complex.abs w → f_error d w ≤ s1 / (Complex.abs w * (Complex.abs w).log) b0' : 0 < b ^ (d - 1) - 1 z : ℂ bz : b ≤ Complex.abs z cz : Complex.abs c ≤ Complex.abs z b0 : 0 < b z0 : 0 < Complex.abs z z3 : 3 ≤ Complex.abs z l0 : 1 < (Complex.abs z).log bb : ℝ hbb : (b ^ (d - 1) - 1) ^ d * b ^ (d - 1) - 1 = bb b11 : 11 ≤ bb bb3 : 3 ≤ bb * b bs2 : ∀ {w : ℂ}, bb * b ≤ Complex.abs w → f_error d w ≤ s2 / (Complex.abs w * (Complex.abs w).log) b0'' : 0 < 1 - (bb * b - 1)⁻¹ si : s0 + s1 / (b ^ (d - 1) - 1) + s2 / ((1 - (bb * b - 1)⁻¹) * bb) ≤ i fz : Complex.abs z ^ d - Complex.abs c ≤ Complex.abs (f' d c z) fz' : (b ^ (d - 1) - 1) * Complex.abs z ≤ Complex.abs (f' d c z) zfz : Complex.abs z ≤ Complex.abs (f' d c z) zffz : Complex.abs z ≤ Complex.abs (f' d c (f' d c z)) bfz : b ≤ Complex.abs (f' d c z) ffz : bb * Complex.abs z ≤ Complex.abs (f' d c (f' d c z)) e0 : f_error d z ≤ s0 / (Complex.abs z * (Complex.abs z).log) e1 : f_error d (f' d c z) ≤ s1 / (b ^ (d - 1) - 1) / (Complex.abs z * (Complex.abs z).log) ⊢ (1 - (bb * b - 1)⁻¹) * bb * Complex.abs z * (Complex.abs z).log ≤ (1 - (bb * b - 1)⁻¹) * Complex.abs (f' d c (f' d c z)) * (Complex.abs (f' d c (f' d c z))).log	case refine_2 c✝ : ℂ d : ℕ inst✝ : Fact (2 ≤ d) i b s0 s1 s2 : ℝ c : ℂ b3 : 3 ≤ b s1p : 0 ≤ s1 s2p : 0 ≤ s2 bs0 : ∀ {w : ℂ}, b ≤ Complex.abs w → f_error d w ≤ s0 / (Complex.abs w * (Complex.abs w).log) bs1 : ∀ {w : ℂ}, (b ^ (d - 1) - 1) * b ≤ Complex.abs w → f_error d w ≤ s1 / (Complex.abs w * (Complex.abs w).log) b0' : 0 < b ^ (d - 1) - 1 z : ℂ bz : b ≤ Complex.abs z cz : Complex.abs c ≤ Complex.abs z b0 : 0 < b z0 : 0 < Complex.abs z z3 : 3 ≤ Complex.abs z l0 : 1 < (Complex.abs z).log bb : ℝ hbb : (b ^ (d - 1) - 1) ^ d * b ^ (d - 1) - 1 = bb b11 : 11 ≤ bb bb3 : 3 ≤ bb * b bs2 : ∀ {w : ℂ}, bb * b ≤ Complex.abs w → f_error d w ≤ s2 / (Complex.abs w * (Complex.abs w).log) b0'' : 0 < 1 - (bb * b - 1)⁻¹ si : s0 + s1 / (b ^ (d - 1) - 1) + s2 / ((1 - (bb * b - 1)⁻¹) * bb) ≤ i fz : Complex.abs z ^ d - Complex.abs c ≤ Complex.abs (f' d c z) fz' : (b ^ (d - 1) - 1) * Complex.abs z ≤ Complex.abs (f' d c z) zfz : Complex.abs z ≤ Complex.abs (f' d c z) zffz : Complex.abs z ≤ Complex.abs (f' d c (f' d c z)) bfz : b ≤ Complex.abs (f' d c z) ffz : bb * Complex.abs z ≤ Complex.abs (f' d c (f' d c z)) e0 : f_error d z ≤ s0 / (Complex.abs z * (Complex.abs z).log) e1 : f_error d (f' d c z) ≤ s1 / (b ^ (d - 1) - 1) / (Complex.abs z * (Complex.abs z).log) ⊢ (1 - (bb * b - 1)⁻¹) * bb * Complex.abs z ≤ (1 - (bb * b - 1)⁻¹) * Complex.abs (f' d c (f' d c z))	Please generate a tactic in lean4 to solve the state. STATE: case refine_2 c✝ : ℂ d : ℕ inst✝ : Fact (2 ≤ d) i b s0 s1 s2 : ℝ c : ℂ b3 : 3 ≤ b s1p : 0 ≤ s1 s2p : 0 ≤ s2 bs0 : ∀ {w : ℂ}, b ≤ Complex.abs w → f_error d w ≤ s0 / (Complex.abs w * (Complex.abs w).log) bs1 : ∀ {w : ℂ}, (b ^ (d - 1) - 1) * b ≤ Complex.abs w → f_error d w ≤ s1 / (Complex.abs w * (Complex.abs w).log) b0' : 0 < b ^ (d - 1) - 1 z : ℂ bz : b ≤ Complex.abs z cz : Complex.abs c ≤ Complex.abs z b0 : 0 < b z0 : 0 < Complex.abs z z3 : 3 ≤ Complex.abs z l0 : 1 < (Complex.abs z).log bb : ℝ hbb : (b ^ (d - 1) - 1) ^ d * b ^ (d - 1) - 1 = bb b11 : 11 ≤ bb bb3 : 3 ≤ bb * b bs2 : ∀ {w : ℂ}, bb * b ≤ Complex.abs w → f_error d w ≤ s2 / (Complex.abs w * (Complex.abs w).log) b0'' : 0 < 1 - (bb * b - 1)⁻¹ si : s0 + s1 / (b ^ (d - 1) - 1) + s2 / ((1 - (bb * b - 1)⁻¹) * bb) ≤ i fz : Complex.abs z ^ d - Complex.abs c ≤ Complex.abs (f' d c z) fz' : (b ^ (d - 1) - 1) * Complex.abs z ≤ Complex.abs (f' d c z) zfz : Complex.abs z ≤ Complex.abs (f' d c z) zffz : Complex.abs z ≤ Complex.abs (f' d c (f' d c z)) bfz : b ≤ Complex.abs (f' d c z) ffz : bb * Complex.abs z ≤ Complex.abs (f' d c (f' d c z)) e0 : f_error d z ≤ s0 / (Complex.abs z * (Complex.abs z).log) e1 : f_error d (f' d c z) ≤ s1 / (b ^ (d - 1) - 1) / (Complex.abs z * (Complex.abs z).log) ⊢ (1 - (bb * b - 1)⁻¹) * bb * Complex.abs z * (Complex.abs z).log ≤ (1 - (bb * b - 1)⁻¹) * Complex.abs (f' d c (f' d c z)) * (Complex.abs (f' d c (f' d c z))).log TACTIC:
https://github.com/girving/ray.git	0be790285dd0fce78913b0cb9bddaffa94bd25f9	Ray/Dynamics/Multibrot/Iterates.lean	iter_error_le	[276, 1]	[342, 54]	rw [mul_assoc]	case refine_2 c✝ : ℂ d : ℕ inst✝ : Fact (2 ≤ d) i b s0 s1 s2 : ℝ c : ℂ b3 : 3 ≤ b s1p : 0 ≤ s1 s2p : 0 ≤ s2 bs0 : ∀ {w : ℂ}, b ≤ Complex.abs w → f_error d w ≤ s0 / (Complex.abs w * (Complex.abs w).log) bs1 : ∀ {w : ℂ}, (b ^ (d - 1) - 1) * b ≤ Complex.abs w → f_error d w ≤ s1 / (Complex.abs w * (Complex.abs w).log) b0' : 0 < b ^ (d - 1) - 1 z : ℂ bz : b ≤ Complex.abs z cz : Complex.abs c ≤ Complex.abs z b0 : 0 < b z0 : 0 < Complex.abs z z3 : 3 ≤ Complex.abs z l0 : 1 < (Complex.abs z).log bb : ℝ hbb : (b ^ (d - 1) - 1) ^ d * b ^ (d - 1) - 1 = bb b11 : 11 ≤ bb bb3 : 3 ≤ bb * b bs2 : ∀ {w : ℂ}, bb * b ≤ Complex.abs w → f_error d w ≤ s2 / (Complex.abs w * (Complex.abs w).log) b0'' : 0 < 1 - (bb * b - 1)⁻¹ si : s0 + s1 / (b ^ (d - 1) - 1) + s2 / ((1 - (bb * b - 1)⁻¹) * bb) ≤ i fz : Complex.abs z ^ d - Complex.abs c ≤ Complex.abs (f' d c z) fz' : (b ^ (d - 1) - 1) * Complex.abs z ≤ Complex.abs (f' d c z) zfz : Complex.abs z ≤ Complex.abs (f' d c z) zffz : Complex.abs z ≤ Complex.abs (f' d c (f' d c z)) bfz : b ≤ Complex.abs (f' d c z) ffz : bb * Complex.abs z ≤ Complex.abs (f' d c (f' d c z)) e0 : f_error d z ≤ s0 / (Complex.abs z * (Complex.abs z).log) e1 : f_error d (f' d c z) ≤ s1 / (b ^ (d - 1) - 1) / (Complex.abs z * (Complex.abs z).log) ⊢ (1 - (bb * b - 1)⁻¹) * bb * Complex.abs z ≤ (1 - (bb * b - 1)⁻¹) * Complex.abs (f' d c (f' d c z))	case refine_2 c✝ : ℂ d : ℕ inst✝ : Fact (2 ≤ d) i b s0 s1 s2 : ℝ c : ℂ b3 : 3 ≤ b s1p : 0 ≤ s1 s2p : 0 ≤ s2 bs0 : ∀ {w : ℂ}, b ≤ Complex.abs w → f_error d w ≤ s0 / (Complex.abs w * (Complex.abs w).log) bs1 : ∀ {w : ℂ}, (b ^ (d - 1) - 1) * b ≤ Complex.abs w → f_error d w ≤ s1 / (Complex.abs w * (Complex.abs w).log) b0' : 0 < b ^ (d - 1) - 1 z : ℂ bz : b ≤ Complex.abs z cz : Complex.abs c ≤ Complex.abs z b0 : 0 < b z0 : 0 < Complex.abs z z3 : 3 ≤ Complex.abs z l0 : 1 < (Complex.abs z).log bb : ℝ hbb : (b ^ (d - 1) - 1) ^ d * b ^ (d - 1) - 1 = bb b11 : 11 ≤ bb bb3 : 3 ≤ bb * b bs2 : ∀ {w : ℂ}, bb * b ≤ Complex.abs w → f_error d w ≤ s2 / (Complex.abs w * (Complex.abs w).log) b0'' : 0 < 1 - (bb * b - 1)⁻¹ si : s0 + s1 / (b ^ (d - 1) - 1) + s2 / ((1 - (bb * b - 1)⁻¹) * bb) ≤ i fz : Complex.abs z ^ d - Complex.abs c ≤ Complex.abs (f' d c z) fz' : (b ^ (d - 1) - 1) * Complex.abs z ≤ Complex.abs (f' d c z) zfz : Complex.abs z ≤ Complex.abs (f' d c z) zffz : Complex.abs z ≤ Complex.abs (f' d c (f' d c z)) bfz : b ≤ Complex.abs (f' d c z) ffz : bb * Complex.abs z ≤ Complex.abs (f' d c (f' d c z)) e0 : f_error d z ≤ s0 / (Complex.abs z * (Complex.abs z).log) e1 : f_error d (f' d c z) ≤ s1 / (b ^ (d - 1) - 1) / (Complex.abs z * (Complex.abs z).log) ⊢ (1 - (bb * b - 1)⁻¹) * (bb * Complex.abs z) ≤ (1 - (bb * b - 1)⁻¹) * Complex.abs (f' d c (f' d c z))	Please generate a tactic in lean4 to solve the state. STATE: case refine_2 c✝ : ℂ d : ℕ inst✝ : Fact (2 ≤ d) i b s0 s1 s2 : ℝ c : ℂ b3 : 3 ≤ b s1p : 0 ≤ s1 s2p : 0 ≤ s2 bs0 : ∀ {w : ℂ}, b ≤ Complex.abs w → f_error d w ≤ s0 / (Complex.abs w * (Complex.abs w).log) bs1 : ∀ {w : ℂ}, (b ^ (d - 1) - 1) * b ≤ Complex.abs w → f_error d w ≤ s1 / (Complex.abs w * (Complex.abs w).log) b0' : 0 < b ^ (d - 1) - 1 z : ℂ bz : b ≤ Complex.abs z cz : Complex.abs c ≤ Complex.abs z b0 : 0 < b z0 : 0 < Complex.abs z z3 : 3 ≤ Complex.abs z l0 : 1 < (Complex.abs z).log bb : ℝ hbb : (b ^ (d - 1) - 1) ^ d * b ^ (d - 1) - 1 = bb b11 : 11 ≤ bb bb3 : 3 ≤ bb * b bs2 : ∀ {w : ℂ}, bb * b ≤ Complex.abs w → f_error d w ≤ s2 / (Complex.abs w * (Complex.abs w).log) b0'' : 0 < 1 - (bb * b - 1)⁻¹ si : s0 + s1 / (b ^ (d - 1) - 1) + s2 / ((1 - (bb * b - 1)⁻¹) * bb) ≤ i fz : Complex.abs z ^ d - Complex.abs c ≤ Complex.abs (f' d c z) fz' : (b ^ (d - 1) - 1) * Complex.abs z ≤ Complex.abs (f' d c z) zfz : Complex.abs z ≤ Complex.abs (f' d c z) zffz : Complex.abs z ≤ Complex.abs (f' d c (f' d c z)) bfz : b ≤ Complex.abs (f' d c z) ffz : bb * Complex.abs z ≤ Complex.abs (f' d c (f' d c z)) e0 : f_error d z ≤ s0 / (Complex.abs z * (Complex.abs z).log) e1 : f_error d (f' d c z) ≤ s1 / (b ^ (d - 1) - 1) / (Complex.abs z * (Complex.abs z).log) ⊢ (1 - (bb * b - 1)⁻¹) * bb * Complex.abs z ≤ (1 - (bb * b - 1)⁻¹) * Complex.abs (f' d c (f' d c z)) TACTIC:
https://github.com/girving/ray.git	0be790285dd0fce78913b0cb9bddaffa94bd25f9	Ray/Dynamics/Multibrot/Iterates.lean	iter_error_le	[276, 1]	[342, 54]	exact mul_le_mul_of_nonneg_left ffz (by positivity)	case refine_2 c✝ : ℂ d : ℕ inst✝ : Fact (2 ≤ d) i b s0 s1 s2 : ℝ c : ℂ b3 : 3 ≤ b s1p : 0 ≤ s1 s2p : 0 ≤ s2 bs0 : ∀ {w : ℂ}, b ≤ Complex.abs w → f_error d w ≤ s0 / (Complex.abs w * (Complex.abs w).log) bs1 : ∀ {w : ℂ}, (b ^ (d - 1) - 1) * b ≤ Complex.abs w → f_error d w ≤ s1 / (Complex.abs w * (Complex.abs w).log) b0' : 0 < b ^ (d - 1) - 1 z : ℂ bz : b ≤ Complex.abs z cz : Complex.abs c ≤ Complex.abs z b0 : 0 < b z0 : 0 < Complex.abs z z3 : 3 ≤ Complex.abs z l0 : 1 < (Complex.abs z).log bb : ℝ hbb : (b ^ (d - 1) - 1) ^ d * b ^ (d - 1) - 1 = bb b11 : 11 ≤ bb bb3 : 3 ≤ bb * b bs2 : ∀ {w : ℂ}, bb * b ≤ Complex.abs w → f_error d w ≤ s2 / (Complex.abs w * (Complex.abs w).log) b0'' : 0 < 1 - (bb * b - 1)⁻¹ si : s0 + s1 / (b ^ (d - 1) - 1) + s2 / ((1 - (bb * b - 1)⁻¹) * bb) ≤ i fz : Complex.abs z ^ d - Complex.abs c ≤ Complex.abs (f' d c z) fz' : (b ^ (d - 1) - 1) * Complex.abs z ≤ Complex.abs (f' d c z) zfz : Complex.abs z ≤ Complex.abs (f' d c z) zffz : Complex.abs z ≤ Complex.abs (f' d c (f' d c z)) bfz : b ≤ Complex.abs (f' d c z) ffz : bb * Complex.abs z ≤ Complex.abs (f' d c (f' d c z)) e0 : f_error d z ≤ s0 / (Complex.abs z * (Complex.abs z).log) e1 : f_error d (f' d c z) ≤ s1 / (b ^ (d - 1) - 1) / (Complex.abs z * (Complex.abs z).log) ⊢ (1 - (bb * b - 1)⁻¹) * (bb * Complex.abs z) ≤ (1 - (bb * b - 1)⁻¹) * Complex.abs (f' d c (f' d c z))	no goals	Please generate a tactic in lean4 to solve the state. STATE: case refine_2 c✝ : ℂ d : ℕ inst✝ : Fact (2 ≤ d) i b s0 s1 s2 : ℝ c : ℂ b3 : 3 ≤ b s1p : 0 ≤ s1 s2p : 0 ≤ s2 bs0 : ∀ {w : ℂ}, b ≤ Complex.abs w → f_error d w ≤ s0 / (Complex.abs w * (Complex.abs w).log) bs1 : ∀ {w : ℂ}, (b ^ (d - 1) - 1) * b ≤ Complex.abs w → f_error d w ≤ s1 / (Complex.abs w * (Complex.abs w).log) b0' : 0 < b ^ (d - 1) - 1 z : ℂ bz : b ≤ Complex.abs z cz : Complex.abs c ≤ Complex.abs z b0 : 0 < b z0 : 0 < Complex.abs z z3 : 3 ≤ Complex.abs z l0 : 1 < (Complex.abs z).log bb : ℝ hbb : (b ^ (d - 1) - 1) ^ d * b ^ (d - 1) - 1 = bb b11 : 11 ≤ bb bb3 : 3 ≤ bb * b bs2 : ∀ {w : ℂ}, bb * b ≤ Complex.abs w → f_error d w ≤ s2 / (Complex.abs w * (Complex.abs w).log) b0'' : 0 < 1 - (bb * b - 1)⁻¹ si : s0 + s1 / (b ^ (d - 1) - 1) + s2 / ((1 - (bb * b - 1)⁻¹) * bb) ≤ i fz : Complex.abs z ^ d - Complex.abs c ≤ Complex.abs (f' d c z) fz' : (b ^ (d - 1) - 1) * Complex.abs z ≤ Complex.abs (f' d c z) zfz : Complex.abs z ≤ Complex.abs (f' d c z) zffz : Complex.abs z ≤ Complex.abs (f' d c (f' d c z)) bfz : b ≤ Complex.abs (f' d c z) ffz : bb * Complex.abs z ≤ Complex.abs (f' d c (f' d c z)) e0 : f_error d z ≤ s0 / (Complex.abs z * (Complex.abs z).log) e1 : f_error d (f' d c z) ≤ s1 / (b ^ (d - 1) - 1) / (Complex.abs z * (Complex.abs z).log) ⊢ (1 - (bb * b - 1)⁻¹) * (bb * Complex.abs z) ≤ (1 - (bb * b - 1)⁻¹) * Complex.abs (f' d c (f' d c z)) TACTIC:
https://github.com/girving/ray.git	0be790285dd0fce78913b0cb9bddaffa94bd25f9	Ray/Dynamics/Multibrot/Iterates.lean	iter_error_le	[276, 1]	[342, 54]	positivity	c✝ : ℂ d : ℕ inst✝ : Fact (2 ≤ d) i b s0 s1 s2 : ℝ c : ℂ b3 : 3 ≤ b s1p : 0 ≤ s1 s2p : 0 ≤ s2 bs0 : ∀ {w : ℂ}, b ≤ Complex.abs w → f_error d w ≤ s0 / (Complex.abs w * (Complex.abs w).log) bs1 : ∀ {w : ℂ}, (b ^ (d - 1) - 1) * b ≤ Complex.abs w → f_error d w ≤ s1 / (Complex.abs w * (Complex.abs w).log) b0' : 0 < b ^ (d - 1) - 1 z : ℂ bz : b ≤ Complex.abs z cz : Complex.abs c ≤ Complex.abs z b0 : 0 < b z0 : 0 < Complex.abs z z3 : 3 ≤ Complex.abs z l0 : 1 < (Complex.abs z).log bb : ℝ hbb : (b ^ (d - 1) - 1) ^ d * b ^ (d - 1) - 1 = bb b11 : 11 ≤ bb bb3 : 3 ≤ bb * b bs2 : ∀ {w : ℂ}, bb * b ≤ Complex.abs w → f_error d w ≤ s2 / (Complex.abs w * (Complex.abs w).log) b0'' : 0 < 1 - (bb * b - 1)⁻¹ si : s0 + s1 / (b ^ (d - 1) - 1) + s2 / ((1 - (bb * b - 1)⁻¹) * bb) ≤ i fz : Complex.abs z ^ d - Complex.abs c ≤ Complex.abs (f' d c z) fz' : (b ^ (d - 1) - 1) * Complex.abs z ≤ Complex.abs (f' d c z) zfz : Complex.abs z ≤ Complex.abs (f' d c z) zffz : Complex.abs z ≤ Complex.abs (f' d c (f' d c z)) bfz : b ≤ Complex.abs (f' d c z) ffz : bb * Complex.abs z ≤ Complex.abs (f' d c (f' d c z)) e0 : f_error d z ≤ s0 / (Complex.abs z * (Complex.abs z).log) e1 : f_error d (f' d c z) ≤ s1 / (b ^ (d - 1) - 1) / (Complex.abs z * (Complex.abs z).log) ⊢ 0 < (1 - (bb * b - 1)⁻¹) * bb * Complex.abs z * (Complex.abs z).log	no goals	Please generate a tactic in lean4 to solve the state. STATE: c✝ : ℂ d : ℕ inst✝ : Fact (2 ≤ d) i b s0 s1 s2 : ℝ c : ℂ b3 : 3 ≤ b s1p : 0 ≤ s1 s2p : 0 ≤ s2 bs0 : ∀ {w : ℂ}, b ≤ Complex.abs w → f_error d w ≤ s0 / (Complex.abs w * (Complex.abs w).log) bs1 : ∀ {w : ℂ}, (b ^ (d - 1) - 1) * b ≤ Complex.abs w → f_error d w ≤ s1 / (Complex.abs w * (Complex.abs w).log) b0' : 0 < b ^ (d - 1) - 1 z : ℂ bz : b ≤ Complex.abs z cz : Complex.abs c ≤ Complex.abs z b0 : 0 < b z0 : 0 < Complex.abs z z3 : 3 ≤ Complex.abs z l0 : 1 < (Complex.abs z).log bb : ℝ hbb : (b ^ (d - 1) - 1) ^ d * b ^ (d - 1) - 1 = bb b11 : 11 ≤ bb bb3 : 3 ≤ bb * b bs2 : ∀ {w : ℂ}, bb * b ≤ Complex.abs w → f_error d w ≤ s2 / (Complex.abs w * (Complex.abs w).log) b0'' : 0 < 1 - (bb * b - 1)⁻¹ si : s0 + s1 / (b ^ (d - 1) - 1) + s2 / ((1 - (bb * b - 1)⁻¹) * bb) ≤ i fz : Complex.abs z ^ d - Complex.abs c ≤ Complex.abs (f' d c z) fz' : (b ^ (d - 1) - 1) * Complex.abs z ≤ Complex.abs (f' d c z) zfz : Complex.abs z ≤ Complex.abs (f' d c z) zffz : Complex.abs z ≤ Complex.abs (f' d c (f' d c z)) bfz : b ≤ Complex.abs (f' d c z) ffz : bb * Complex.abs z ≤ Complex.abs (f' d c (f' d c z)) e0 : f_error d z ≤ s0 / (Complex.abs z * (Complex.abs z).log) e1 : f_error d (f' d c z) ≤ s1 / (b ^ (d - 1) - 1) / (Complex.abs z * (Complex.abs z).log) ⊢ 0 < (1 - (bb * b - 1)⁻¹) * bb * Complex.abs z * (Complex.abs z).log TACTIC:
https://github.com/girving/ray.git	0be790285dd0fce78913b0cb9bddaffa94bd25f9	Ray/Dynamics/Multibrot/Iterates.lean	iter_error_le	[276, 1]	[342, 54]	positivity	c✝ : ℂ d : ℕ inst✝ : Fact (2 ≤ d) i b s0 s1 s2 : ℝ c : ℂ b3 : 3 ≤ b s1p : 0 ≤ s1 s2p : 0 ≤ s2 bs0 : ∀ {w : ℂ}, b ≤ Complex.abs w → f_error d w ≤ s0 / (Complex.abs w * (Complex.abs w).log) bs1 : ∀ {w : ℂ}, (b ^ (d - 1) - 1) * b ≤ Complex.abs w → f_error d w ≤ s1 / (Complex.abs w * (Complex.abs w).log) b0' : 0 < b ^ (d - 1) - 1 z : ℂ bz : b ≤ Complex.abs z cz : Complex.abs c ≤ Complex.abs z b0 : 0 < b z0 : 0 < Complex.abs z z3 : 3 ≤ Complex.abs z l0 : 1 < (Complex.abs z).log bb : ℝ hbb : (b ^ (d - 1) - 1) ^ d * b ^ (d - 1) - 1 = bb b11 : 11 ≤ bb bb3 : 3 ≤ bb * b bs2 : ∀ {w : ℂ}, bb * b ≤ Complex.abs w → f_error d w ≤ s2 / (Complex.abs w * (Complex.abs w).log) b0'' : 0 < 1 - (bb * b - 1)⁻¹ si : s0 + s1 / (b ^ (d - 1) - 1) + s2 / ((1 - (bb * b - 1)⁻¹) * bb) ≤ i fz : Complex.abs z ^ d - Complex.abs c ≤ Complex.abs (f' d c z) fz' : (b ^ (d - 1) - 1) * Complex.abs z ≤ Complex.abs (f' d c z) zfz : Complex.abs z ≤ Complex.abs (f' d c z) zffz : Complex.abs z ≤ Complex.abs (f' d c (f' d c z)) bfz : b ≤ Complex.abs (f' d c z) ffz : bb * Complex.abs z ≤ Complex.abs (f' d c (f' d c z)) e0 : f_error d z ≤ s0 / (Complex.abs z * (Complex.abs z).log) e1 : f_error d (f' d c z) ≤ s1 / (b ^ (d - 1) - 1) / (Complex.abs z * (Complex.abs z).log) ⊢ 0 ≤ (Complex.abs z).log	no goals	Please generate a tactic in lean4 to solve the state. STATE: c✝ : ℂ d : ℕ inst✝ : Fact (2 ≤ d) i b s0 s1 s2 : ℝ c : ℂ b3 : 3 ≤ b s1p : 0 ≤ s1 s2p : 0 ≤ s2 bs0 : ∀ {w : ℂ}, b ≤ Complex.abs w → f_error d w ≤ s0 / (Complex.abs w * (Complex.abs w).log) bs1 : ∀ {w : ℂ}, (b ^ (d - 1) - 1) * b ≤ Complex.abs w → f_error d w ≤ s1 / (Complex.abs w * (Complex.abs w).log) b0' : 0 < b ^ (d - 1) - 1 z : ℂ bz : b ≤ Complex.abs z cz : Complex.abs c ≤ Complex.abs z b0 : 0 < b z0 : 0 < Complex.abs z z3 : 3 ≤ Complex.abs z l0 : 1 < (Complex.abs z).log bb : ℝ hbb : (b ^ (d - 1) - 1) ^ d * b ^ (d - 1) - 1 = bb b11 : 11 ≤ bb bb3 : 3 ≤ bb * b bs2 : ∀ {w : ℂ}, bb * b ≤ Complex.abs w → f_error d w ≤ s2 / (Complex.abs w * (Complex.abs w).log) b0'' : 0 < 1 - (bb * b - 1)⁻¹ si : s0 + s1 / (b ^ (d - 1) - 1) + s2 / ((1 - (bb * b - 1)⁻¹) * bb) ≤ i fz : Complex.abs z ^ d - Complex.abs c ≤ Complex.abs (f' d c z) fz' : (b ^ (d - 1) - 1) * Complex.abs z ≤ Complex.abs (f' d c z) zfz : Complex.abs z ≤ Complex.abs (f' d c z) zffz : Complex.abs z ≤ Complex.abs (f' d c (f' d c z)) bfz : b ≤ Complex.abs (f' d c z) ffz : bb * Complex.abs z ≤ Complex.abs (f' d c (f' d c z)) e0 : f_error d z ≤ s0 / (Complex.abs z * (Complex.abs z).log) e1 : f_error d (f' d c z) ≤ s1 / (b ^ (d - 1) - 1) / (Complex.abs z * (Complex.abs z).log) ⊢ 0 ≤ (Complex.abs z).log TACTIC:
https://github.com/girving/ray.git	0be790285dd0fce78913b0cb9bddaffa94bd25f9	Ray/Dynamics/Multibrot/Iterates.lean	iter_error_le	[276, 1]	[342, 54]	positivity	c✝ : ℂ d : ℕ inst✝ : Fact (2 ≤ d) i b s0 s1 s2 : ℝ c : ℂ b3 : 3 ≤ b s1p : 0 ≤ s1 s2p : 0 ≤ s2 bs0 : ∀ {w : ℂ}, b ≤ Complex.abs w → f_error d w ≤ s0 / (Complex.abs w * (Complex.abs w).log) bs1 : ∀ {w : ℂ}, (b ^ (d - 1) - 1) * b ≤ Complex.abs w → f_error d w ≤ s1 / (Complex.abs w * (Complex.abs w).log) b0' : 0 < b ^ (d - 1) - 1 z : ℂ bz : b ≤ Complex.abs z cz : Complex.abs c ≤ Complex.abs z b0 : 0 < b z0 : 0 < Complex.abs z z3 : 3 ≤ Complex.abs z l0 : 1 < (Complex.abs z).log bb : ℝ hbb : (b ^ (d - 1) - 1) ^ d * b ^ (d - 1) - 1 = bb b11 : 11 ≤ bb bb3 : 3 ≤ bb * b bs2 : ∀ {w : ℂ}, bb * b ≤ Complex.abs w → f_error d w ≤ s2 / (Complex.abs w * (Complex.abs w).log) b0'' : 0 < 1 - (bb * b - 1)⁻¹ si : s0 + s1 / (b ^ (d - 1) - 1) + s2 / ((1 - (bb * b - 1)⁻¹) * bb) ≤ i fz : Complex.abs z ^ d - Complex.abs c ≤ Complex.abs (f' d c z) fz' : (b ^ (d - 1) - 1) * Complex.abs z ≤ Complex.abs (f' d c z) zfz : Complex.abs z ≤ Complex.abs (f' d c z) zffz : Complex.abs z ≤ Complex.abs (f' d c (f' d c z)) bfz : b ≤ Complex.abs (f' d c z) ffz : bb * Complex.abs z ≤ Complex.abs (f' d c (f' d c z)) e0 : f_error d z ≤ s0 / (Complex.abs z * (Complex.abs z).log) e1 : f_error d (f' d c z) ≤ s1 / (b ^ (d - 1) - 1) / (Complex.abs z * (Complex.abs z).log) ⊢ 0 ≤ (1 - (bb * b - 1)⁻¹) * Complex.abs (f' d c (f' d c z))	no goals	Please generate a tactic in lean4 to solve the state. STATE: c✝ : ℂ d : ℕ inst✝ : Fact (2 ≤ d) i b s0 s1 s2 : ℝ c : ℂ b3 : 3 ≤ b s1p : 0 ≤ s1 s2p : 0 ≤ s2 bs0 : ∀ {w : ℂ}, b ≤ Complex.abs w → f_error d w ≤ s0 / (Complex.abs w * (Complex.abs w).log) bs1 : ∀ {w : ℂ}, (b ^ (d - 1) - 1) * b ≤ Complex.abs w → f_error d w ≤ s1 / (Complex.abs w * (Complex.abs w).log) b0' : 0 < b ^ (d - 1) - 1 z : ℂ bz : b ≤ Complex.abs z cz : Complex.abs c ≤ Complex.abs z b0 : 0 < b z0 : 0 < Complex.abs z z3 : 3 ≤ Complex.abs z l0 : 1 < (Complex.abs z).log bb : ℝ hbb : (b ^ (d - 1) - 1) ^ d * b ^ (d - 1) - 1 = bb b11 : 11 ≤ bb bb3 : 3 ≤ bb * b bs2 : ∀ {w : ℂ}, bb * b ≤ Complex.abs w → f_error d w ≤ s2 / (Complex.abs w * (Complex.abs w).log) b0'' : 0 < 1 - (bb * b - 1)⁻¹ si : s0 + s1 / (b ^ (d - 1) - 1) + s2 / ((1 - (bb * b - 1)⁻¹) * bb) ≤ i fz : Complex.abs z ^ d - Complex.abs c ≤ Complex.abs (f' d c z) fz' : (b ^ (d - 1) - 1) * Complex.abs z ≤ Complex.abs (f' d c z) zfz : Complex.abs z ≤ Complex.abs (f' d c z) zffz : Complex.abs z ≤ Complex.abs (f' d c (f' d c z)) bfz : b ≤ Complex.abs (f' d c z) ffz : bb * Complex.abs z ≤ Complex.abs (f' d c (f' d c z)) e0 : f_error d z ≤ s0 / (Complex.abs z * (Complex.abs z).log) e1 : f_error d (f' d c z) ≤ s1 / (b ^ (d - 1) - 1) / (Complex.abs z * (Complex.abs z).log) ⊢ 0 ≤ (1 - (bb * b - 1)⁻¹) * Complex.abs (f' d c (f' d c z)) TACTIC:
https://github.com/girving/ray.git	0be790285dd0fce78913b0cb9bddaffa94bd25f9	Ray/Dynamics/Multibrot/Iterates.lean	iter_error_le	[276, 1]	[342, 54]	positivity	c✝ : ℂ d : ℕ inst✝ : Fact (2 ≤ d) i b s0 s1 s2 : ℝ c : ℂ b3 : 3 ≤ b s1p : 0 ≤ s1 s2p : 0 ≤ s2 bs0 : ∀ {w : ℂ}, b ≤ Complex.abs w → f_error d w ≤ s0 / (Complex.abs w * (Complex.abs w).log) bs1 : ∀ {w : ℂ}, (b ^ (d - 1) - 1) * b ≤ Complex.abs w → f_error d w ≤ s1 / (Complex.abs w * (Complex.abs w).log) b0' : 0 < b ^ (d - 1) - 1 z : ℂ bz : b ≤ Complex.abs z cz : Complex.abs c ≤ Complex.abs z b0 : 0 < b z0 : 0 < Complex.abs z z3 : 3 ≤ Complex.abs z l0 : 1 < (Complex.abs z).log bb : ℝ hbb : (b ^ (d - 1) - 1) ^ d * b ^ (d - 1) - 1 = bb b11 : 11 ≤ bb bb3 : 3 ≤ bb * b bs2 : ∀ {w : ℂ}, bb * b ≤ Complex.abs w → f_error d w ≤ s2 / (Complex.abs w * (Complex.abs w).log) b0'' : 0 < 1 - (bb * b - 1)⁻¹ si : s0 + s1 / (b ^ (d - 1) - 1) + s2 / ((1 - (bb * b - 1)⁻¹) * bb) ≤ i fz : Complex.abs z ^ d - Complex.abs c ≤ Complex.abs (f' d c z) fz' : (b ^ (d - 1) - 1) * Complex.abs z ≤ Complex.abs (f' d c z) zfz : Complex.abs z ≤ Complex.abs (f' d c z) zffz : Complex.abs z ≤ Complex.abs (f' d c (f' d c z)) bfz : b ≤ Complex.abs (f' d c z) ffz : bb * Complex.abs z ≤ Complex.abs (f' d c (f' d c z)) e0 : f_error d z ≤ s0 / (Complex.abs z * (Complex.abs z).log) e1 : f_error d (f' d c z) ≤ s1 / (b ^ (d - 1) - 1) / (Complex.abs z * (Complex.abs z).log) ⊢ 0 ≤ 1 - (bb * b - 1)⁻¹	no goals	Please generate a tactic in lean4 to solve the state. STATE: c✝ : ℂ d : ℕ inst✝ : Fact (2 ≤ d) i b s0 s1 s2 : ℝ c : ℂ b3 : 3 ≤ b s1p : 0 ≤ s1 s2p : 0 ≤ s2 bs0 : ∀ {w : ℂ}, b ≤ Complex.abs w → f_error d w ≤ s0 / (Complex.abs w * (Complex.abs w).log) bs1 : ∀ {w : ℂ}, (b ^ (d - 1) - 1) * b ≤ Complex.abs w → f_error d w ≤ s1 / (Complex.abs w * (Complex.abs w).log) b0' : 0 < b ^ (d - 1) - 1 z : ℂ bz : b ≤ Complex.abs z cz : Complex.abs c ≤ Complex.abs z b0 : 0 < b z0 : 0 < Complex.abs z z3 : 3 ≤ Complex.abs z l0 : 1 < (Complex.abs z).log bb : ℝ hbb : (b ^ (d - 1) - 1) ^ d * b ^ (d - 1) - 1 = bb b11 : 11 ≤ bb bb3 : 3 ≤ bb * b bs2 : ∀ {w : ℂ}, bb * b ≤ Complex.abs w → f_error d w ≤ s2 / (Complex.abs w * (Complex.abs w).log) b0'' : 0 < 1 - (bb * b - 1)⁻¹ si : s0 + s1 / (b ^ (d - 1) - 1) + s2 / ((1 - (bb * b - 1)⁻¹) * bb) ≤ i fz : Complex.abs z ^ d - Complex.abs c ≤ Complex.abs (f' d c z) fz' : (b ^ (d - 1) - 1) * Complex.abs z ≤ Complex.abs (f' d c z) zfz : Complex.abs z ≤ Complex.abs (f' d c z) zffz : Complex.abs z ≤ Complex.abs (f' d c (f' d c z)) bfz : b ≤ Complex.abs (f' d c z) ffz : bb * Complex.abs z ≤ Complex.abs (f' d c (f' d c z)) e0 : f_error d z ≤ s0 / (Complex.abs z * (Complex.abs z).log) e1 : f_error d (f' d c z) ≤ s1 / (b ^ (d - 1) - 1) / (Complex.abs z * (Complex.abs z).log) ⊢ 0 ≤ 1 - (bb * b - 1)⁻¹ TACTIC:
https://github.com/girving/ray.git	0be790285dd0fce78913b0cb9bddaffa94bd25f9	Ray/Dynamics/Multibrot/Iterates.lean	iter_error_le	[276, 1]	[342, 54]	positivity	c✝ : ℂ d : ℕ inst✝ : Fact (2 ≤ d) i b s0 s1 s2 : ℝ c : ℂ b3 : 3 ≤ b s1p : 0 ≤ s1 s2p : 0 ≤ s2 bs0 : ∀ {w : ℂ}, b ≤ Complex.abs w → f_error d w ≤ s0 / (Complex.abs w * (Complex.abs w).log) bs1 : ∀ {w : ℂ}, (b ^ (d - 1) - 1) * b ≤ Complex.abs w → f_error d w ≤ s1 / (Complex.abs w * (Complex.abs w).log) b0' : 0 < b ^ (d - 1) - 1 z : ℂ bz : b ≤ Complex.abs z cz : Complex.abs c ≤ Complex.abs z b0 : 0 < b z0 : 0 < Complex.abs z z3 : 3 ≤ Complex.abs z l0 : 1 < (Complex.abs z).log bb : ℝ hbb : (b ^ (d - 1) - 1) ^ d * b ^ (d - 1) - 1 = bb b11 : 11 ≤ bb bb3 : 3 ≤ bb * b bs2 : ∀ {w : ℂ}, bb * b ≤ Complex.abs w → f_error d w ≤ s2 / (Complex.abs w * (Complex.abs w).log) b0'' : 0 < 1 - (bb * b - 1)⁻¹ si : s0 + s1 / (b ^ (d - 1) - 1) + s2 / ((1 - (bb * b - 1)⁻¹) * bb) ≤ i fz : Complex.abs z ^ d - Complex.abs c ≤ Complex.abs (f' d c z) fz' : (b ^ (d - 1) - 1) * Complex.abs z ≤ Complex.abs (f' d c z) zfz : Complex.abs z ≤ Complex.abs (f' d c z) zffz : Complex.abs z ≤ Complex.abs (f' d c (f' d c z)) bfz : b ≤ Complex.abs (f' d c z) ffz : bb * Complex.abs z ≤ Complex.abs (f' d c (f' d c z)) e0 : f_error d z ≤ s0 / (Complex.abs z * (Complex.abs z).log) e1 : f_error d (f' d c z) ≤ s1 / (b ^ (d - 1) - 1) / (Complex.abs z * (Complex.abs z).log) e2 : iter_error d c (f' d c (f' d c z)) ≤ s2 / ((1 - (bb * b - 1)⁻¹) * bb) / (Complex.abs z * (Complex.abs z).log) ⊢ 0 ≤ Complex.abs z * (Complex.abs z).log	no goals	Please generate a tactic in lean4 to solve the state. STATE: c✝ : ℂ d : ℕ inst✝ : Fact (2 ≤ d) i b s0 s1 s2 : ℝ c : ℂ b3 : 3 ≤ b s1p : 0 ≤ s1 s2p : 0 ≤ s2 bs0 : ∀ {w : ℂ}, b ≤ Complex.abs w → f_error d w ≤ s0 / (Complex.abs w * (Complex.abs w).log) bs1 : ∀ {w : ℂ}, (b ^ (d - 1) - 1) * b ≤ Complex.abs w → f_error d w ≤ s1 / (Complex.abs w * (Complex.abs w).log) b0' : 0 < b ^ (d - 1) - 1 z : ℂ bz : b ≤ Complex.abs z cz : Complex.abs c ≤ Complex.abs z b0 : 0 < b z0 : 0 < Complex.abs z z3 : 3 ≤ Complex.abs z l0 : 1 < (Complex.abs z).log bb : ℝ hbb : (b ^ (d - 1) - 1) ^ d * b ^ (d - 1) - 1 = bb b11 : 11 ≤ bb bb3 : 3 ≤ bb * b bs2 : ∀ {w : ℂ}, bb * b ≤ Complex.abs w → f_error d w ≤ s2 / (Complex.abs w * (Complex.abs w).log) b0'' : 0 < 1 - (bb * b - 1)⁻¹ si : s0 + s1 / (b ^ (d - 1) - 1) + s2 / ((1 - (bb * b - 1)⁻¹) * bb) ≤ i fz : Complex.abs z ^ d - Complex.abs c ≤ Complex.abs (f' d c z) fz' : (b ^ (d - 1) - 1) * Complex.abs z ≤ Complex.abs (f' d c z) zfz : Complex.abs z ≤ Complex.abs (f' d c z) zffz : Complex.abs z ≤ Complex.abs (f' d c (f' d c z)) bfz : b ≤ Complex.abs (f' d c z) ffz : bb * Complex.abs z ≤ Complex.abs (f' d c (f' d c z)) e0 : f_error d z ≤ s0 / (Complex.abs z * (Complex.abs z).log) e1 : f_error d (f' d c z) ≤ s1 / (b ^ (d - 1) - 1) / (Complex.abs z * (Complex.abs z).log) e2 : iter_error d c (f' d c (f' d c z)) ≤ s2 / ((1 - (bb * b - 1)⁻¹) * bb) / (Complex.abs z * (Complex.abs z).log) ⊢ 0 ≤ Complex.abs z * (Complex.abs z).log TACTIC:
https://github.com/girving/ray.git	0be790285dd0fce78913b0cb9bddaffa94bd25f9	Ray/Dynamics/Multibrot/Iterates.lean	iter_error_le_of_z3	[344, 1]	[379, 81]	have b3 : (3:ℝ) ≤ 3^(d-1) := by calc (3:ℝ)^(d-1) _ ≥ 3^(2-1) := by bound _ = 3 := by norm_num	c✝ : ℂ d✝ : ℕ inst✝¹ : Fact (2 ≤ d✝) d : ℕ inst✝ : Fact (2 ≤ d) c z : ℂ z3 : 3 ≤ Complex.abs z cz : Complex.abs c ≤ Complex.abs z ⊢ iter_error d c z ≤ 1.03 / (Complex.abs z * (Complex.abs z).log)	c✝ : ℂ d✝ : ℕ inst✝¹ : Fact (2 ≤ d✝) d : ℕ inst✝ : Fact (2 ≤ d) c z : ℂ z3 : 3 ≤ Complex.abs z cz : Complex.abs c ≤ Complex.abs z b3 : 3 ≤ 3 ^ (d - 1) ⊢ iter_error d c z ≤ 1.03 / (Complex.abs z * (Complex.abs z).log)	Please generate a tactic in lean4 to solve the state. STATE: c✝ : ℂ d✝ : ℕ inst✝¹ : Fact (2 ≤ d✝) d : ℕ inst✝ : Fact (2 ≤ d) c z : ℂ z3 : 3 ≤ Complex.abs z cz : Complex.abs c ≤ Complex.abs z ⊢ iter_error d c z ≤ 1.03 / (Complex.abs z * (Complex.abs z).log) TACTIC:
https://github.com/girving/ray.git	0be790285dd0fce78913b0cb9bddaffa94bd25f9	Ray/Dynamics/Multibrot/Iterates.lean	iter_error_le_of_z3	[344, 1]	[379, 81]	generalize hb3 : (3:ℝ)^(d-1) = t3 at b3	c✝ : ℂ d✝ : ℕ inst✝¹ : Fact (2 ≤ d✝) d : ℕ inst✝ : Fact (2 ≤ d) c z : ℂ z3 : 3 ≤ Complex.abs z cz : Complex.abs c ≤ Complex.abs z b3 : 3 ≤ 3 ^ (d - 1) ⊢ iter_error d c z ≤ 1.03 / (Complex.abs z * (Complex.abs z).log)	c✝ : ℂ d✝ : ℕ inst✝¹ : Fact (2 ≤ d✝) d : ℕ inst✝ : Fact (2 ≤ d) c z : ℂ z3 : 3 ≤ Complex.abs z cz : Complex.abs c ≤ Complex.abs z t3 : ℝ hb3 : 3 ^ (d - 1) = t3 b3 : 3 ≤ t3 ⊢ iter_error d c z ≤ 1.03 / (Complex.abs z * (Complex.abs z).log)	Please generate a tactic in lean4 to solve the state. STATE: c✝ : ℂ d✝ : ℕ inst✝¹ : Fact (2 ≤ d✝) d : ℕ inst✝ : Fact (2 ≤ d) c z : ℂ z3 : 3 ≤ Complex.abs z cz : Complex.abs c ≤ Complex.abs z b3 : 3 ≤ 3 ^ (d - 1) ⊢ iter_error d c z ≤ 1.03 / (Complex.abs z * (Complex.abs z).log) TACTIC:
https://github.com/girving/ray.git	0be790285dd0fce78913b0cb9bddaffa94bd25f9	Ray/Dynamics/Multibrot/Iterates.lean	iter_error_le_of_z3	[344, 1]	[379, 81]	have b2 : (2:ℝ) ≤ t3 - 1 := by linarith	c✝ : ℂ d✝ : ℕ inst✝¹ : Fact (2 ≤ d✝) d : ℕ inst✝ : Fact (2 ≤ d) c z : ℂ z3 : 3 ≤ Complex.abs z cz : Complex.abs c ≤ Complex.abs z t3 : ℝ hb3 : 3 ^ (d - 1) = t3 b3 : 3 ≤ t3 ⊢ iter_error d c z ≤ 1.03 / (Complex.abs z * (Complex.abs z).log)	c✝ : ℂ d✝ : ℕ inst✝¹ : Fact (2 ≤ d✝) d : ℕ inst✝ : Fact (2 ≤ d) c z : ℂ z3 : 3 ≤ Complex.abs z cz : Complex.abs c ≤ Complex.abs z t3 : ℝ hb3 : 3 ^ (d - 1) = t3 b3 : 3 ≤ t3 b2 : 2 ≤ t3 - 1 ⊢ iter_error d c z ≤ 1.03 / (Complex.abs z * (Complex.abs z).log)	Please generate a tactic in lean4 to solve the state. STATE: c✝ : ℂ d✝ : ℕ inst✝¹ : Fact (2 ≤ d✝) d : ℕ inst✝ : Fact (2 ≤ d) c z : ℂ z3 : 3 ≤ Complex.abs z cz : Complex.abs c ≤ Complex.abs z t3 : ℝ hb3 : 3 ^ (d - 1) = t3 b3 : 3 ≤ t3 ⊢ iter_error d c z ≤ 1.03 / (Complex.abs z * (Complex.abs z).log) TACTIC:
https://github.com/girving/ray.git	0be790285dd0fce78913b0cb9bddaffa94bd25f9	Ray/Dynamics/Multibrot/Iterates.lean	iter_error_le_of_z3	[344, 1]	[379, 81]	generalize hb2 : t3 - 1 = t2 at b2	c✝ : ℂ d✝ : ℕ inst✝¹ : Fact (2 ≤ d✝) d : ℕ inst✝ : Fact (2 ≤ d) c z : ℂ z3 : 3 ≤ Complex.abs z cz : Complex.abs c ≤ Complex.abs z t3 : ℝ hb3 : 3 ^ (d - 1) = t3 b3 : 3 ≤ t3 b2 : 2 ≤ t3 - 1 ⊢ iter_error d c z ≤ 1.03 / (Complex.abs z * (Complex.abs z).log)	c✝ : ℂ d✝ : ℕ inst✝¹ : Fact (2 ≤ d✝) d : ℕ inst✝ : Fact (2 ≤ d) c z : ℂ z3 : 3 ≤ Complex.abs z cz : Complex.abs c ≤ Complex.abs z t3 : ℝ hb3 : 3 ^ (d - 1) = t3 b3 : 3 ≤ t3 t2 : ℝ hb2 : t3 - 1 = t2 b2 : 2 ≤ t2 ⊢ iter_error d c z ≤ 1.03 / (Complex.abs z * (Complex.abs z).log)	Please generate a tactic in lean4 to solve the state. STATE: c✝ : ℂ d✝ : ℕ inst✝¹ : Fact (2 ≤ d✝) d : ℕ inst✝ : Fact (2 ≤ d) c z : ℂ z3 : 3 ≤ Complex.abs z cz : Complex.abs c ≤ Complex.abs z t3 : ℝ hb3 : 3 ^ (d - 1) = t3 b3 : 3 ≤ t3 b2 : 2 ≤ t3 - 1 ⊢ iter_error d c z ≤ 1.03 / (Complex.abs z * (Complex.abs z).log) TACTIC:
https://github.com/girving/ray.git	0be790285dd0fce78913b0cb9bddaffa94bd25f9	Ray/Dynamics/Multibrot/Iterates.lean	iter_error_le_of_z3	[344, 1]	[379, 81]	have t2p : 0 ≤ t2 := by positivity	c✝ : ℂ d✝ : ℕ inst✝¹ : Fact (2 ≤ d✝) d : ℕ inst✝ : Fact (2 ≤ d) c z : ℂ z3 : 3 ≤ Complex.abs z cz : Complex.abs c ≤ Complex.abs z t3 : ℝ hb3 : 3 ^ (d - 1) = t3 b3 : 3 ≤ t3 t2 : ℝ hb2 : t3 - 1 = t2 b2 : 2 ≤ t2 ⊢ iter_error d c z ≤ 1.03 / (Complex.abs z * (Complex.abs z).log)	c✝ : ℂ d✝ : ℕ inst✝¹ : Fact (2 ≤ d✝) d : ℕ inst✝ : Fact (2 ≤ d) c z : ℂ z3 : 3 ≤ Complex.abs z cz : Complex.abs c ≤ Complex.abs z t3 : ℝ hb3 : 3 ^ (d - 1) = t3 b3 : 3 ≤ t3 t2 : ℝ hb2 : t3 - 1 = t2 b2 : 2 ≤ t2 t2p : 0 ≤ t2 ⊢ iter_error d c z ≤ 1.03 / (Complex.abs z * (Complex.abs z).log)	Please generate a tactic in lean4 to solve the state. STATE: c✝ : ℂ d✝ : ℕ inst✝¹ : Fact (2 ≤ d✝) d : ℕ inst✝ : Fact (2 ≤ d) c z : ℂ z3 : 3 ≤ Complex.abs z cz : Complex.abs c ≤ Complex.abs z t3 : ℝ hb3 : 3 ^ (d - 1) = t3 b3 : 3 ≤ t3 t2 : ℝ hb2 : t3 - 1 = t2 b2 : 2 ≤ t2 ⊢ iter_error d c z ≤ 1.03 / (Complex.abs z * (Complex.abs z).log) TACTIC:
https://github.com/girving/ray.git	0be790285dd0fce78913b0cb9bddaffa94bd25f9	Ray/Dynamics/Multibrot/Iterates.lean	iter_error_le_of_z3	[344, 1]	[379, 81]	have b6 : (6:ℝ) ≤ t2 * 3 := by linarith	c✝ : ℂ d✝ : ℕ inst✝¹ : Fact (2 ≤ d✝) d : ℕ inst✝ : Fact (2 ≤ d) c z : ℂ z3 : 3 ≤ Complex.abs z cz : Complex.abs c ≤ Complex.abs z t3 : ℝ hb3 : 3 ^ (d - 1) = t3 b3 : 3 ≤ t3 t2 : ℝ hb2 : t3 - 1 = t2 b2 : 2 ≤ t2 t2p : 0 ≤ t2 ⊢ iter_error d c z ≤ 1.03 / (Complex.abs z * (Complex.abs z).log)	c✝ : ℂ d✝ : ℕ inst✝¹ : Fact (2 ≤ d✝) d : ℕ inst✝ : Fact (2 ≤ d) c z : ℂ z3 : 3 ≤ Complex.abs z cz : Complex.abs c ≤ Complex.abs z t3 : ℝ hb3 : 3 ^ (d - 1) = t3 b3 : 3 ≤ t3 t2 : ℝ hb2 : t3 - 1 = t2 b2 : 2 ≤ t2 t2p : 0 ≤ t2 b6 : 6 ≤ t2 * 3 ⊢ iter_error d c z ≤ 1.03 / (Complex.abs z * (Complex.abs z).log)	Please generate a tactic in lean4 to solve the state. STATE: c✝ : ℂ d✝ : ℕ inst✝¹ : Fact (2 ≤ d✝) d : ℕ inst✝ : Fact (2 ≤ d) c z : ℂ z3 : 3 ≤ Complex.abs z cz : Complex.abs c ≤ Complex.abs z t3 : ℝ hb3 : 3 ^ (d - 1) = t3 b3 : 3 ≤ t3 t2 : ℝ hb2 : t3 - 1 = t2 b2 : 2 ≤ t2 t2p : 0 ≤ t2 ⊢ iter_error d c z ≤ 1.03 / (Complex.abs z * (Complex.abs z).log) TACTIC:
https://github.com/girving/ray.git	0be790285dd0fce78913b0cb9bddaffa94bd25f9	Ray/Dynamics/Multibrot/Iterates.lean	iter_error_le_of_z3	[344, 1]	[379, 81]	have b11 : (11:ℝ) ≤ t2^d * t3 - 1 := by calc t2^d * t3 - 1 _ ≥ 2^d * 3 - 1 := by bound _ ≥ 2^2 * 3 - 1 := by bound _ = 11 := by norm_num	c✝ : ℂ d✝ : ℕ inst✝¹ : Fact (2 ≤ d✝) d : ℕ inst✝ : Fact (2 ≤ d) c z : ℂ z3 : 3 ≤ Complex.abs z cz : Complex.abs c ≤ Complex.abs z t3 : ℝ hb3 : 3 ^ (d - 1) = t3 b3 : 3 ≤ t3 t2 : ℝ hb2 : t3 - 1 = t2 b2 : 2 ≤ t2 t2p : 0 ≤ t2 b6 : 6 ≤ t2 * 3 ⊢ iter_error d c z ≤ 1.03 / (Complex.abs z * (Complex.abs z).log)	c✝ : ℂ d✝ : ℕ inst✝¹ : Fact (2 ≤ d✝) d : ℕ inst✝ : Fact (2 ≤ d) c z : ℂ z3 : 3 ≤ Complex.abs z cz : Complex.abs c ≤ Complex.abs z t3 : ℝ hb3 : 3 ^ (d - 1) = t3 b3 : 3 ≤ t3 t2 : ℝ hb2 : t3 - 1 = t2 b2 : 2 ≤ t2 t2p : 0 ≤ t2 b6 : 6 ≤ t2 * 3 b11 : 11 ≤ t2 ^ d * t3 - 1 ⊢ iter_error d c z ≤ 1.03 / (Complex.abs z * (Complex.abs z).log)	Please generate a tactic in lean4 to solve the state. STATE: c✝ : ℂ d✝ : ℕ inst✝¹ : Fact (2 ≤ d✝) d : ℕ inst✝ : Fact (2 ≤ d) c z : ℂ z3 : 3 ≤ Complex.abs z cz : Complex.abs c ≤ Complex.abs z t3 : ℝ hb3 : 3 ^ (d - 1) = t3 b3 : 3 ≤ t3 t2 : ℝ hb2 : t3 - 1 = t2 b2 : 2 ≤ t2 t2p : 0 ≤ t2 b6 : 6 ≤ t2 * 3 ⊢ iter_error d c z ≤ 1.03 / (Complex.abs z * (Complex.abs z).log) TACTIC:
https://github.com/girving/ray.git	0be790285dd0fce78913b0cb9bddaffa94bd25f9	Ray/Dynamics/Multibrot/Iterates.lean	iter_error_le_of_z3	[344, 1]	[379, 81]	generalize hb11 : t2^d * t3 - 1 = t11 at b11	c✝ : ℂ d✝ : ℕ inst✝¹ : Fact (2 ≤ d✝) d : ℕ inst✝ : Fact (2 ≤ d) c z : ℂ z3 : 3 ≤ Complex.abs z cz : Complex.abs c ≤ Complex.abs z t3 : ℝ hb3 : 3 ^ (d - 1) = t3 b3 : 3 ≤ t3 t2 : ℝ hb2 : t3 - 1 = t2 b2 : 2 ≤ t2 t2p : 0 ≤ t2 b6 : 6 ≤ t2 * 3 b11 : 11 ≤ t2 ^ d * t3 - 1 ⊢ iter_error d c z ≤ 1.03 / (Complex.abs z * (Complex.abs z).log)	c✝ : ℂ d✝ : ℕ inst✝¹ : Fact (2 ≤ d✝) d : ℕ inst✝ : Fact (2 ≤ d) c z : ℂ z3 : 3 ≤ Complex.abs z cz : Complex.abs c ≤ Complex.abs z t3 : ℝ hb3 : 3 ^ (d - 1) = t3 b3 : 3 ≤ t3 t2 : ℝ hb2 : t3 - 1 = t2 b2 : 2 ≤ t2 t2p : 0 ≤ t2 b6 : 6 ≤ t2 * 3 t11 : ℝ hb11 : t2 ^ d * t3 - 1 = t11 b11 : 11 ≤ t11 ⊢ iter_error d c z ≤ 1.03 / (Complex.abs z * (Complex.abs z).log)	Please generate a tactic in lean4 to solve the state. STATE: c✝ : ℂ d✝ : ℕ inst✝¹ : Fact (2 ≤ d✝) d : ℕ inst✝ : Fact (2 ≤ d) c z : ℂ z3 : 3 ≤ Complex.abs z cz : Complex.abs c ≤ Complex.abs z t3 : ℝ hb3 : 3 ^ (d - 1) = t3 b3 : 3 ≤ t3 t2 : ℝ hb2 : t3 - 1 = t2 b2 : 2 ≤ t2 t2p : 0 ≤ t2 b6 : 6 ≤ t2 * 3 b11 : 11 ≤ t2 ^ d * t3 - 1 ⊢ iter_error d c z ≤ 1.03 / (Complex.abs z * (Complex.abs z).log) TACTIC:
https://github.com/girving/ray.git	0be790285dd0fce78913b0cb9bddaffa94bd25f9	Ray/Dynamics/Multibrot/Iterates.lean	iter_error_le_of_z3	[344, 1]	[379, 81]	have b33 : (33:ℝ) ≤ t11 * 3 := by linarith	c✝ : ℂ d✝ : ℕ inst✝¹ : Fact (2 ≤ d✝) d : ℕ inst✝ : Fact (2 ≤ d) c z : ℂ z3 : 3 ≤ Complex.abs z cz : Complex.abs c ≤ Complex.abs z t3 : ℝ hb3 : 3 ^ (d - 1) = t3 b3 : 3 ≤ t3 t2 : ℝ hb2 : t3 - 1 = t2 b2 : 2 ≤ t2 t2p : 0 ≤ t2 b6 : 6 ≤ t2 * 3 t11 : ℝ hb11 : t2 ^ d * t3 - 1 = t11 b11 : 11 ≤ t11 ⊢ iter_error d c z ≤ 1.03 / (Complex.abs z * (Complex.abs z).log)	c✝ : ℂ d✝ : ℕ inst✝¹ : Fact (2 ≤ d✝) d : ℕ inst✝ : Fact (2 ≤ d) c z : ℂ z3 : 3 ≤ Complex.abs z cz : Complex.abs c ≤ Complex.abs z t3 : ℝ hb3 : 3 ^ (d - 1) = t3 b3 : 3 ≤ t3 t2 : ℝ hb2 : t3 - 1 = t2 b2 : 2 ≤ t2 t2p : 0 ≤ t2 b6 : 6 ≤ t2 * 3 t11 : ℝ hb11 : t2 ^ d * t3 - 1 = t11 b11 : 11 ≤ t11 b33 : 33 ≤ t11 * 3 ⊢ iter_error d c z ≤ 1.03 / (Complex.abs z * (Complex.abs z).log)	Please generate a tactic in lean4 to solve the state. STATE: c✝ : ℂ d✝ : ℕ inst✝¹ : Fact (2 ≤ d✝) d : ℕ inst✝ : Fact (2 ≤ d) c z : ℂ z3 : 3 ≤ Complex.abs z cz : Complex.abs c ≤ Complex.abs z t3 : ℝ hb3 : 3 ^ (d - 1) = t3 b3 : 3 ≤ t3 t2 : ℝ hb2 : t3 - 1 = t2 b2 : 2 ≤ t2 t2p : 0 ≤ t2 b6 : 6 ≤ t2 * 3 t11 : ℝ hb11 : t2 ^ d * t3 - 1 = t11 b11 : 11 ≤ t11 ⊢ iter_error d c z ≤ 1.03 / (Complex.abs z * (Complex.abs z).log) TACTIC:
https://github.com/girving/ray.git	0be790285dd0fce78913b0cb9bddaffa94bd25f9	Ray/Dynamics/Multibrot/Iterates.lean	iter_error_le_of_z3	[344, 1]	[379, 81]	generalize hb33 : t11 * 3 = t33 at b33	c✝ : ℂ d✝ : ℕ inst✝¹ : Fact (2 ≤ d✝) d : ℕ inst✝ : Fact (2 ≤ d) c z : ℂ z3 : 3 ≤ Complex.abs z cz : Complex.abs c ≤ Complex.abs z t3 : ℝ hb3 : 3 ^ (d - 1) = t3 b3 : 3 ≤ t3 t2 : ℝ hb2 : t3 - 1 = t2 b2 : 2 ≤ t2 t2p : 0 ≤ t2 b6 : 6 ≤ t2 * 3 t11 : ℝ hb11 : t2 ^ d * t3 - 1 = t11 b11 : 11 ≤ t11 b33 : 33 ≤ t11 * 3 ⊢ iter_error d c z ≤ 1.03 / (Complex.abs z * (Complex.abs z).log)	c✝ : ℂ d✝ : ℕ inst✝¹ : Fact (2 ≤ d✝) d : ℕ inst✝ : Fact (2 ≤ d) c z : ℂ z3 : 3 ≤ Complex.abs z cz : Complex.abs c ≤ Complex.abs z t3 : ℝ hb3 : 3 ^ (d - 1) = t3 b3 : 3 ≤ t3 t2 : ℝ hb2 : t3 - 1 = t2 b2 : 2 ≤ t2 t2p : 0 ≤ t2 b6 : 6 ≤ t2 * 3 t11 : ℝ hb11 : t2 ^ d * t3 - 1 = t11 b11 : 11 ≤ t11 t33 : ℝ hb33 : t11 * 3 = t33 b33 : 33 ≤ t33 ⊢ iter_error d c z ≤ 1.03 / (Complex.abs z * (Complex.abs z).log)	Please generate a tactic in lean4 to solve the state. STATE: c✝ : ℂ d✝ : ℕ inst✝¹ : Fact (2 ≤ d✝) d : ℕ inst✝ : Fact (2 ≤ d) c z : ℂ z3 : 3 ≤ Complex.abs z cz : Complex.abs c ≤ Complex.abs z t3 : ℝ hb3 : 3 ^ (d - 1) = t3 b3 : 3 ≤ t3 t2 : ℝ hb2 : t3 - 1 = t2 b2 : 2 ≤ t2 t2p : 0 ≤ t2 b6 : 6 ≤ t2 * 3 t11 : ℝ hb11 : t2 ^ d * t3 - 1 = t11 b11 : 11 ≤ t11 b33 : 33 ≤ t11 * 3 ⊢ iter_error d c z ≤ 1.03 / (Complex.abs z * (Complex.abs z).log) TACTIC:
https://github.com/girving/ray.git	0be790285dd0fce78913b0cb9bddaffa94bd25f9	Ray/Dynamics/Multibrot/Iterates.lean	iter_error_le_of_z3	[344, 1]	[379, 81]	have b10 : 10.65 ≤ (1 - (t33 - 1)⁻¹) * t11 := by have h : 1 ≤ t33 - 1 := by linarith calc (1 - (t33 - 1)⁻¹) * t11 _ ≥ (1 - (33 - 1)⁻¹) * 11 := by bound _ ≥ 10.65 := by norm_num	c✝ : ℂ d✝ : ℕ inst✝¹ : Fact (2 ≤ d✝) d : ℕ inst✝ : Fact (2 ≤ d) c z : ℂ z3 : 3 ≤ Complex.abs z cz : Complex.abs c ≤ Complex.abs z t3 : ℝ hb3 : 3 ^ (d - 1) = t3 b3 : 3 ≤ t3 t2 : ℝ hb2 : t3 - 1 = t2 b2 : 2 ≤ t2 t2p : 0 ≤ t2 b6 : 6 ≤ t2 * 3 t11 : ℝ hb11 : t2 ^ d * t3 - 1 = t11 b11 : 11 ≤ t11 t33 : ℝ hb33 : t11 * 3 = t33 b33 : 33 ≤ t33 ⊢ iter_error d c z ≤ 1.03 / (Complex.abs z * (Complex.abs z).log)	c✝ : ℂ d✝ : ℕ inst✝¹ : Fact (2 ≤ d✝) d : ℕ inst✝ : Fact (2 ≤ d) c z : ℂ z3 : 3 ≤ Complex.abs z cz : Complex.abs c ≤ Complex.abs z t3 : ℝ hb3 : 3 ^ (d - 1) = t3 b3 : 3 ≤ t3 t2 : ℝ hb2 : t3 - 1 = t2 b2 : 2 ≤ t2 t2p : 0 ≤ t2 b6 : 6 ≤ t2 * 3 t11 : ℝ hb11 : t2 ^ d * t3 - 1 = t11 b11 : 11 ≤ t11 t33 : ℝ hb33 : t11 * 3 = t33 b33 : 33 ≤ t33 b10 : 10.65 ≤ (1 - (t33 - 1)⁻¹) * t11 ⊢ iter_error d c z ≤ 1.03 / (Complex.abs z * (Complex.abs z).log)	Please generate a tactic in lean4 to solve the state. STATE: c✝ : ℂ d✝ : ℕ inst✝¹ : Fact (2 ≤ d✝) d : ℕ inst✝ : Fact (2 ≤ d) c z : ℂ z3 : 3 ≤ Complex.abs z cz : Complex.abs c ≤ Complex.abs z t3 : ℝ hb3 : 3 ^ (d - 1) = t3 b3 : 3 ≤ t3 t2 : ℝ hb2 : t3 - 1 = t2 b2 : 2 ≤ t2 t2p : 0 ≤ t2 b6 : 6 ≤ t2 * 3 t11 : ℝ hb11 : t2 ^ d * t3 - 1 = t11 b11 : 11 ≤ t11 t33 : ℝ hb33 : t11 * 3 = t33 b33 : 33 ≤ t33 ⊢ iter_error d c z ≤ 1.03 / (Complex.abs z * (Complex.abs z).log) TACTIC:
https://github.com/girving/ray.git	0be790285dd0fce78913b0cb9bddaffa94bd25f9	Ray/Dynamics/Multibrot/Iterates.lean	iter_error_le_of_z3	[344, 1]	[379, 81]	simp only [←hb2, ←hb3, ←hb11, ←hb33] at b2 b6 b11 b33	c✝ : ℂ d✝ : ℕ inst✝¹ : Fact (2 ≤ d✝) d : ℕ inst✝ : Fact (2 ≤ d) c z : ℂ z3 : 3 ≤ Complex.abs z cz : Complex.abs c ≤ Complex.abs z t3 : ℝ hb3 : 3 ^ (d - 1) = t3 b3 : 3 ≤ t3 t2 : ℝ hb2 : t3 - 1 = t2 b2 : 2 ≤ t2 t2p : 0 ≤ t2 b6 : 6 ≤ t2 * 3 t11 : ℝ hb11 : t2 ^ d * t3 - 1 = t11 b11 : 11 ≤ t11 t33 : ℝ hb33 : t11 * 3 = t33 b33 : 33 ≤ t33 b10 : 10.65 ≤ (1 - (t33 - 1)⁻¹) * t11 ⊢ iter_error d c z ≤ 1.03 / (Complex.abs z * (Complex.abs z).log)	c✝ : ℂ d✝ : ℕ inst✝¹ : Fact (2 ≤ d✝) d : ℕ inst✝ : Fact (2 ≤ d) c z : ℂ z3 : 3 ≤ Complex.abs z cz : Complex.abs c ≤ Complex.abs z t3 : ℝ hb3 : 3 ^ (d - 1) = t3 b3 : 3 ≤ t3 t2 : ℝ hb2 : t3 - 1 = t2 t2p : 0 ≤ t2 t11 : ℝ hb11 : t2 ^ d * t3 - 1 = t11 t33 : ℝ hb33 : t11 * 3 = t33 b10 : 10.65 ≤ (1 - (t33 - 1)⁻¹) * t11 b2 : 2 ≤ 3 ^ (d - 1) - 1 b6 : 6 ≤ (3 ^ (d - 1) - 1) * 3 b11 : 11 ≤ (3 ^ (d - 1) - 1) ^ d * 3 ^ (d - 1) - 1 b33 : 33 ≤ ((3 ^ (d - 1) - 1) ^ d * 3 ^ (d - 1) - 1) * 3 ⊢ iter_error d c z ≤ 1.03 / (Complex.abs z * (Complex.abs z).log)	Please generate a tactic in lean4 to solve the state. STATE: c✝ : ℂ d✝ : ℕ inst✝¹ : Fact (2 ≤ d✝) d : ℕ inst✝ : Fact (2 ≤ d) c z : ℂ z3 : 3 ≤ Complex.abs z cz : Complex.abs c ≤ Complex.abs z t3 : ℝ hb3 : 3 ^ (d - 1) = t3 b3 : 3 ≤ t3 t2 : ℝ hb2 : t3 - 1 = t2 b2 : 2 ≤ t2 t2p : 0 ≤ t2 b6 : 6 ≤ t2 * 3 t11 : ℝ hb11 : t2 ^ d * t3 - 1 = t11 b11 : 11 ≤ t11 t33 : ℝ hb33 : t11 * 3 = t33 b33 : 33 ≤ t33 b10 : 10.65 ≤ (1 - (t33 - 1)⁻¹) * t11 ⊢ iter_error d c z ≤ 1.03 / (Complex.abs z * (Complex.abs z).log) TACTIC:
https://github.com/girving/ray.git	0be790285dd0fce78913b0cb9bddaffa94bd25f9	Ray/Dynamics/Multibrot/Iterates.lean	iter_error_le_of_z3	[344, 1]	[379, 81]	refine iter_error_le _ (by norm_num) (by norm_num) (by norm_num) (bs0 := f_error_le_of_z3 d) (bs1 := fun {_} bz ↦ f_error_le_of_z6 d (le_trans b6 bz)) (bs2 := fun {_} bz ↦ f_error_le_of_z33 d (le_trans b33 bz)) b11 (le_trans (by norm_num) b33) (by positivity) ?_ ?_ z3 cz	c✝ : ℂ d✝ : ℕ inst✝¹ : Fact (2 ≤ d✝) d : ℕ inst✝ : Fact (2 ≤ d) c z : ℂ z3 : 3 ≤ Complex.abs z cz : Complex.abs c ≤ Complex.abs z t3 : ℝ hb3 : 3 ^ (d - 1) = t3 b3 : 3 ≤ t3 t2 : ℝ hb2 : t3 - 1 = t2 t2p : 0 ≤ t2 t11 : ℝ hb11 : t2 ^ d * t3 - 1 = t11 t33 : ℝ hb33 : t11 * 3 = t33 b10 : 10.65 ≤ (1 - (t33 - 1)⁻¹) * t11 b2 : 2 ≤ 3 ^ (d - 1) - 1 b6 : 6 ≤ (3 ^ (d - 1) - 1) * 3 b11 : 11 ≤ (3 ^ (d - 1) - 1) ^ d * 3 ^ (d - 1) - 1 b33 : 33 ≤ ((3 ^ (d - 1) - 1) ^ d * 3 ^ (d - 1) - 1) * 3 ⊢ iter_error d c z ≤ 1.03 / (Complex.abs z * (Complex.abs z).log)	case refine_1 c✝ : ℂ d✝ : ℕ inst✝¹ : Fact (2 ≤ d✝) d : ℕ inst✝ : Fact (2 ≤ d) c z : ℂ z3 : 3 ≤ Complex.abs z cz : Complex.abs c ≤ Complex.abs z t3 : ℝ hb3 : 3 ^ (d - 1) = t3 b3 : 3 ≤ t3 t2 : ℝ hb2 : t3 - 1 = t2 t2p : 0 ≤ t2 t11 : ℝ hb11 : t2 ^ d * t3 - 1 = t11 t33 : ℝ hb33 : t11 * 3 = t33 b10 : 10.65 ≤ (1 - (t33 - 1)⁻¹) * t11 b2 : 2 ≤ 3 ^ (d - 1) - 1 b6 : 6 ≤ (3 ^ (d - 1) - 1) * 3 b11 : 11 ≤ (3 ^ (d - 1) - 1) ^ d * 3 ^ (d - 1) - 1 b33 : 33 ≤ ((3 ^ (d - 1) - 1) ^ d * 3 ^ (d - 1) - 1) * 3 ⊢ 0 < 1 - (((3 ^ (d - 1) - 1) ^ d * 3 ^ (d - 1) - 1) * 3 - 1)⁻¹ case refine_2 c✝ : ℂ d✝ : ℕ inst✝¹ : Fact (2 ≤ d✝) d : ℕ inst✝ : Fact (2 ≤ d) c z : ℂ z3 : 3 ≤ Complex.abs z cz : Complex.abs c ≤ Complex.abs z t3 : ℝ hb3 : 3 ^ (d - 1) = t3 b3 : 3 ≤ t3 t2 : ℝ hb2 : t3 - 1 = t2 t2p : 0 ≤ t2 t11 : ℝ hb11 : t2 ^ d * t3 - 1 = t11 t33 : ℝ hb33 : t11 * 3 = t33 b10 : 10.65 ≤ (1 - (t33 - 1)⁻¹) * t11 b2 : 2 ≤ 3 ^ (d - 1) - 1 b6 : 6 ≤ (3 ^ (d - 1) - 1) * 3 b11 : 11 ≤ (3 ^ (d - 1) - 1) ^ d * 3 ^ (d - 1) - 1 b33 : 33 ≤ ((3 ^ (d - 1) - 1) ^ d * 3 ^ (d - 1) - 1) * 3 ⊢ 0.699 + 0.565 / (3 ^ (d - 1) - 1) + 0.512 / ((1 - (((3 ^ (d - 1) - 1) ^ d * 3 ^ (d - 1) - 1) * 3 - 1)⁻¹) * ((3 ^ (d - 1) - 1) ^ d * 3 ^ (d - 1) - 1)) ≤ 1.03	Please generate a tactic in lean4 to solve the state. STATE: c✝ : ℂ d✝ : ℕ inst✝¹ : Fact (2 ≤ d✝) d : ℕ inst✝ : Fact (2 ≤ d) c z : ℂ z3 : 3 ≤ Complex.abs z cz : Complex.abs c ≤ Complex.abs z t3 : ℝ hb3 : 3 ^ (d - 1) = t3 b3 : 3 ≤ t3 t2 : ℝ hb2 : t3 - 1 = t2 t2p : 0 ≤ t2 t11 : ℝ hb11 : t2 ^ d * t3 - 1 = t11 t33 : ℝ hb33 : t11 * 3 = t33 b10 : 10.65 ≤ (1 - (t33 - 1)⁻¹) * t11 b2 : 2 ≤ 3 ^ (d - 1) - 1 b6 : 6 ≤ (3 ^ (d - 1) - 1) * 3 b11 : 11 ≤ (3 ^ (d - 1) - 1) ^ d * 3 ^ (d - 1) - 1 b33 : 33 ≤ ((3 ^ (d - 1) - 1) ^ d * 3 ^ (d - 1) - 1) * 3 ⊢ iter_error d c z ≤ 1.03 / (Complex.abs z * (Complex.abs z).log) TACTIC:
https://github.com/girving/ray.git	0be790285dd0fce78913b0cb9bddaffa94bd25f9	Ray/Dynamics/Multibrot/Iterates.lean	iter_error_le_of_z3	[344, 1]	[379, 81]	calc (3:ℝ)^(d-1) _ ≥ 3^(2-1) := by bound _ = 3 := by norm_num	c✝ : ℂ d✝ : ℕ inst✝¹ : Fact (2 ≤ d✝) d : ℕ inst✝ : Fact (2 ≤ d) c z : ℂ z3 : 3 ≤ Complex.abs z cz : Complex.abs c ≤ Complex.abs z ⊢ 3 ≤ 3 ^ (d - 1)	no goals	Please generate a tactic in lean4 to solve the state. STATE: c✝ : ℂ d✝ : ℕ inst✝¹ : Fact (2 ≤ d✝) d : ℕ inst✝ : Fact (2 ≤ d) c z : ℂ z3 : 3 ≤ Complex.abs z cz : Complex.abs c ≤ Complex.abs z ⊢ 3 ≤ 3 ^ (d - 1) TACTIC:
https://github.com/girving/ray.git	0be790285dd0fce78913b0cb9bddaffa94bd25f9	Ray/Dynamics/Multibrot/Iterates.lean	iter_error_le_of_z3	[344, 1]	[379, 81]	bound	c✝ : ℂ d✝ : ℕ inst✝¹ : Fact (2 ≤ d✝) d : ℕ inst✝ : Fact (2 ≤ d) c z : ℂ z3 : 3 ≤ Complex.abs z cz : Complex.abs c ≤ Complex.abs z ⊢ 3 ^ (d - 1) ≥ 3 ^ (2 - 1)	no goals	Please generate a tactic in lean4 to solve the state. STATE: c✝ : ℂ d✝ : ℕ inst✝¹ : Fact (2 ≤ d✝) d : ℕ inst✝ : Fact (2 ≤ d) c z : ℂ z3 : 3 ≤ Complex.abs z cz : Complex.abs c ≤ Complex.abs z ⊢ 3 ^ (d - 1) ≥ 3 ^ (2 - 1) TACTIC:
https://github.com/girving/ray.git	0be790285dd0fce78913b0cb9bddaffa94bd25f9	Ray/Dynamics/Multibrot/Iterates.lean	iter_error_le_of_z3	[344, 1]	[379, 81]	norm_num	c✝ : ℂ d✝ : ℕ inst✝¹ : Fact (2 ≤ d✝) d : ℕ inst✝ : Fact (2 ≤ d) c z : ℂ z3 : 3 ≤ Complex.abs z cz : Complex.abs c ≤ Complex.abs z ⊢ 3 ^ (2 - 1) = 3	no goals	Please generate a tactic in lean4 to solve the state. STATE: c✝ : ℂ d✝ : ℕ inst✝¹ : Fact (2 ≤ d✝) d : ℕ inst✝ : Fact (2 ≤ d) c z : ℂ z3 : 3 ≤ Complex.abs z cz : Complex.abs c ≤ Complex.abs z ⊢ 3 ^ (2 - 1) = 3 TACTIC:
https://github.com/girving/ray.git	0be790285dd0fce78913b0cb9bddaffa94bd25f9	Ray/Dynamics/Multibrot/Iterates.lean	iter_error_le_of_z3	[344, 1]	[379, 81]	linarith	c✝ : ℂ d✝ : ℕ inst✝¹ : Fact (2 ≤ d✝) d : ℕ inst✝ : Fact (2 ≤ d) c z : ℂ z3 : 3 ≤ Complex.abs z cz : Complex.abs c ≤ Complex.abs z t3 : ℝ hb3 : 3 ^ (d - 1) = t3 b3 : 3 ≤ t3 ⊢ 2 ≤ t3 - 1	no goals	Please generate a tactic in lean4 to solve the state. STATE: c✝ : ℂ d✝ : ℕ inst✝¹ : Fact (2 ≤ d✝) d : ℕ inst✝ : Fact (2 ≤ d) c z : ℂ z3 : 3 ≤ Complex.abs z cz : Complex.abs c ≤ Complex.abs z t3 : ℝ hb3 : 3 ^ (d - 1) = t3 b3 : 3 ≤ t3 ⊢ 2 ≤ t3 - 1 TACTIC:
https://github.com/girving/ray.git	0be790285dd0fce78913b0cb9bddaffa94bd25f9	Ray/Dynamics/Multibrot/Iterates.lean	iter_error_le_of_z3	[344, 1]	[379, 81]	positivity	c✝ : ℂ d✝ : ℕ inst✝¹ : Fact (2 ≤ d✝) d : ℕ inst✝ : Fact (2 ≤ d) c z : ℂ z3 : 3 ≤ Complex.abs z cz : Complex.abs c ≤ Complex.abs z t3 : ℝ hb3 : 3 ^ (d - 1) = t3 b3 : 3 ≤ t3 t2 : ℝ hb2 : t3 - 1 = t2 b2 : 2 ≤ t2 ⊢ 0 ≤ t2	no goals	Please generate a tactic in lean4 to solve the state. STATE: c✝ : ℂ d✝ : ℕ inst✝¹ : Fact (2 ≤ d✝) d : ℕ inst✝ : Fact (2 ≤ d) c z : ℂ z3 : 3 ≤ Complex.abs z cz : Complex.abs c ≤ Complex.abs z t3 : ℝ hb3 : 3 ^ (d - 1) = t3 b3 : 3 ≤ t3 t2 : ℝ hb2 : t3 - 1 = t2 b2 : 2 ≤ t2 ⊢ 0 ≤ t2 TACTIC:
https://github.com/girving/ray.git	0be790285dd0fce78913b0cb9bddaffa94bd25f9	Ray/Dynamics/Multibrot/Iterates.lean	iter_error_le_of_z3	[344, 1]	[379, 81]	linarith	c✝ : ℂ d✝ : ℕ inst✝¹ : Fact (2 ≤ d✝) d : ℕ inst✝ : Fact (2 ≤ d) c z : ℂ z3 : 3 ≤ Complex.abs z cz : Complex.abs c ≤ Complex.abs z t3 : ℝ hb3 : 3 ^ (d - 1) = t3 b3 : 3 ≤ t3 t2 : ℝ hb2 : t3 - 1 = t2 b2 : 2 ≤ t2 t2p : 0 ≤ t2 ⊢ 6 ≤ t2 * 3	no goals	Please generate a tactic in lean4 to solve the state. STATE: c✝ : ℂ d✝ : ℕ inst✝¹ : Fact (2 ≤ d✝) d : ℕ inst✝ : Fact (2 ≤ d) c z : ℂ z3 : 3 ≤ Complex.abs z cz : Complex.abs c ≤ Complex.abs z t3 : ℝ hb3 : 3 ^ (d - 1) = t3 b3 : 3 ≤ t3 t2 : ℝ hb2 : t3 - 1 = t2 b2 : 2 ≤ t2 t2p : 0 ≤ t2 ⊢ 6 ≤ t2 * 3 TACTIC:
https://github.com/girving/ray.git	0be790285dd0fce78913b0cb9bddaffa94bd25f9	Ray/Dynamics/Multibrot/Iterates.lean	iter_error_le_of_z3	[344, 1]	[379, 81]	calc t2^d * t3 - 1 _ ≥ 2^d * 3 - 1 := by bound _ ≥ 2^2 * 3 - 1 := by bound _ = 11 := by norm_num	c✝ : ℂ d✝ : ℕ inst✝¹ : Fact (2 ≤ d✝) d : ℕ inst✝ : Fact (2 ≤ d) c z : ℂ z3 : 3 ≤ Complex.abs z cz : Complex.abs c ≤ Complex.abs z t3 : ℝ hb3 : 3 ^ (d - 1) = t3 b3 : 3 ≤ t3 t2 : ℝ hb2 : t3 - 1 = t2 b2 : 2 ≤ t2 t2p : 0 ≤ t2 b6 : 6 ≤ t2 * 3 ⊢ 11 ≤ t2 ^ d * t3 - 1	no goals	Please generate a tactic in lean4 to solve the state. STATE: c✝ : ℂ d✝ : ℕ inst✝¹ : Fact (2 ≤ d✝) d : ℕ inst✝ : Fact (2 ≤ d) c z : ℂ z3 : 3 ≤ Complex.abs z cz : Complex.abs c ≤ Complex.abs z t3 : ℝ hb3 : 3 ^ (d - 1) = t3 b3 : 3 ≤ t3 t2 : ℝ hb2 : t3 - 1 = t2 b2 : 2 ≤ t2 t2p : 0 ≤ t2 b6 : 6 ≤ t2 * 3 ⊢ 11 ≤ t2 ^ d * t3 - 1 TACTIC:
https://github.com/girving/ray.git	0be790285dd0fce78913b0cb9bddaffa94bd25f9	Ray/Dynamics/Multibrot/Iterates.lean	iter_error_le_of_z3	[344, 1]	[379, 81]	bound	c✝ : ℂ d✝ : ℕ inst✝¹ : Fact (2 ≤ d✝) d : ℕ inst✝ : Fact (2 ≤ d) c z : ℂ z3 : 3 ≤ Complex.abs z cz : Complex.abs c ≤ Complex.abs z t3 : ℝ hb3 : 3 ^ (d - 1) = t3 b3 : 3 ≤ t3 t2 : ℝ hb2 : t3 - 1 = t2 b2 : 2 ≤ t2 t2p : 0 ≤ t2 b6 : 6 ≤ t2 * 3 ⊢ t2 ^ d * t3 - 1 ≥ 2 ^ d * 3 - 1	no goals	Please generate a tactic in lean4 to solve the state. STATE: c✝ : ℂ d✝ : ℕ inst✝¹ : Fact (2 ≤ d✝) d : ℕ inst✝ : Fact (2 ≤ d) c z : ℂ z3 : 3 ≤ Complex.abs z cz : Complex.abs c ≤ Complex.abs z t3 : ℝ hb3 : 3 ^ (d - 1) = t3 b3 : 3 ≤ t3 t2 : ℝ hb2 : t3 - 1 = t2 b2 : 2 ≤ t2 t2p : 0 ≤ t2 b6 : 6 ≤ t2 * 3 ⊢ t2 ^ d * t3 - 1 ≥ 2 ^ d * 3 - 1 TACTIC:
https://github.com/girving/ray.git	0be790285dd0fce78913b0cb9bddaffa94bd25f9	Ray/Dynamics/Multibrot/Iterates.lean	iter_error_le_of_z3	[344, 1]	[379, 81]	bound	c✝ : ℂ d✝ : ℕ inst✝¹ : Fact (2 ≤ d✝) d : ℕ inst✝ : Fact (2 ≤ d) c z : ℂ z3 : 3 ≤ Complex.abs z cz : Complex.abs c ≤ Complex.abs z t3 : ℝ hb3 : 3 ^ (d - 1) = t3 b3 : 3 ≤ t3 t2 : ℝ hb2 : t3 - 1 = t2 b2 : 2 ≤ t2 t2p : 0 ≤ t2 b6 : 6 ≤ t2 * 3 ⊢ 2 ^ d * 3 - 1 ≥ 2 ^ 2 * 3 - 1	no goals	Please generate a tactic in lean4 to solve the state. STATE: c✝ : ℂ d✝ : ℕ inst✝¹ : Fact (2 ≤ d✝) d : ℕ inst✝ : Fact (2 ≤ d) c z : ℂ z3 : 3 ≤ Complex.abs z cz : Complex.abs c ≤ Complex.abs z t3 : ℝ hb3 : 3 ^ (d - 1) = t3 b3 : 3 ≤ t3 t2 : ℝ hb2 : t3 - 1 = t2 b2 : 2 ≤ t2 t2p : 0 ≤ t2 b6 : 6 ≤ t2 * 3 ⊢ 2 ^ d * 3 - 1 ≥ 2 ^ 2 * 3 - 1 TACTIC:
https://github.com/girving/ray.git	0be790285dd0fce78913b0cb9bddaffa94bd25f9	Ray/Dynamics/Multibrot/Iterates.lean	iter_error_le_of_z3	[344, 1]	[379, 81]	norm_num	c✝ : ℂ d✝ : ℕ inst✝¹ : Fact (2 ≤ d✝) d : ℕ inst✝ : Fact (2 ≤ d) c z : ℂ z3 : 3 ≤ Complex.abs z cz : Complex.abs c ≤ Complex.abs z t3 : ℝ hb3 : 3 ^ (d - 1) = t3 b3 : 3 ≤ t3 t2 : ℝ hb2 : t3 - 1 = t2 b2 : 2 ≤ t2 t2p : 0 ≤ t2 b6 : 6 ≤ t2 * 3 ⊢ 2 ^ 2 * 3 - 1 = 11	no goals	Please generate a tactic in lean4 to solve the state. STATE: c✝ : ℂ d✝ : ℕ inst✝¹ : Fact (2 ≤ d✝) d : ℕ inst✝ : Fact (2 ≤ d) c z : ℂ z3 : 3 ≤ Complex.abs z cz : Complex.abs c ≤ Complex.abs z t3 : ℝ hb3 : 3 ^ (d - 1) = t3 b3 : 3 ≤ t3 t2 : ℝ hb2 : t3 - 1 = t2 b2 : 2 ≤ t2 t2p : 0 ≤ t2 b6 : 6 ≤ t2 * 3 ⊢ 2 ^ 2 * 3 - 1 = 11 TACTIC:
https://github.com/girving/ray.git	0be790285dd0fce78913b0cb9bddaffa94bd25f9	Ray/Dynamics/Multibrot/Iterates.lean	iter_error_le_of_z3	[344, 1]	[379, 81]	linarith	c✝ : ℂ d✝ : ℕ inst✝¹ : Fact (2 ≤ d✝) d : ℕ inst✝ : Fact (2 ≤ d) c z : ℂ z3 : 3 ≤ Complex.abs z cz : Complex.abs c ≤ Complex.abs z t3 : ℝ hb3 : 3 ^ (d - 1) = t3 b3 : 3 ≤ t3 t2 : ℝ hb2 : t3 - 1 = t2 b2 : 2 ≤ t2 t2p : 0 ≤ t2 b6 : 6 ≤ t2 * 3 t11 : ℝ hb11 : t2 ^ d * t3 - 1 = t11 b11 : 11 ≤ t11 ⊢ 33 ≤ t11 * 3	no goals	Please generate a tactic in lean4 to solve the state. STATE: c✝ : ℂ d✝ : ℕ inst✝¹ : Fact (2 ≤ d✝) d : ℕ inst✝ : Fact (2 ≤ d) c z : ℂ z3 : 3 ≤ Complex.abs z cz : Complex.abs c ≤ Complex.abs z t3 : ℝ hb3 : 3 ^ (d - 1) = t3 b3 : 3 ≤ t3 t2 : ℝ hb2 : t3 - 1 = t2 b2 : 2 ≤ t2 t2p : 0 ≤ t2 b6 : 6 ≤ t2 * 3 t11 : ℝ hb11 : t2 ^ d * t3 - 1 = t11 b11 : 11 ≤ t11 ⊢ 33 ≤ t11 * 3 TACTIC:
https://github.com/girving/ray.git	0be790285dd0fce78913b0cb9bddaffa94bd25f9	Ray/Dynamics/Multibrot/Iterates.lean	iter_error_le_of_z3	[344, 1]	[379, 81]	have h : 1 ≤ t33 - 1 := by linarith	c✝ : ℂ d✝ : ℕ inst✝¹ : Fact (2 ≤ d✝) d : ℕ inst✝ : Fact (2 ≤ d) c z : ℂ z3 : 3 ≤ Complex.abs z cz : Complex.abs c ≤ Complex.abs z t3 : ℝ hb3 : 3 ^ (d - 1) = t3 b3 : 3 ≤ t3 t2 : ℝ hb2 : t3 - 1 = t2 b2 : 2 ≤ t2 t2p : 0 ≤ t2 b6 : 6 ≤ t2 * 3 t11 : ℝ hb11 : t2 ^ d * t3 - 1 = t11 b11 : 11 ≤ t11 t33 : ℝ hb33 : t11 * 3 = t33 b33 : 33 ≤ t33 ⊢ 10.65 ≤ (1 - (t33 - 1)⁻¹) * t11	c✝ : ℂ d✝ : ℕ inst✝¹ : Fact (2 ≤ d✝) d : ℕ inst✝ : Fact (2 ≤ d) c z : ℂ z3 : 3 ≤ Complex.abs z cz : Complex.abs c ≤ Complex.abs z t3 : ℝ hb3 : 3 ^ (d - 1) = t3 b3 : 3 ≤ t3 t2 : ℝ hb2 : t3 - 1 = t2 b2 : 2 ≤ t2 t2p : 0 ≤ t2 b6 : 6 ≤ t2 * 3 t11 : ℝ hb11 : t2 ^ d * t3 - 1 = t11 b11 : 11 ≤ t11 t33 : ℝ hb33 : t11 * 3 = t33 b33 : 33 ≤ t33 h : 1 ≤ t33 - 1 ⊢ 10.65 ≤ (1 - (t33 - 1)⁻¹) * t11	Please generate a tactic in lean4 to solve the state. STATE: c✝ : ℂ d✝ : ℕ inst✝¹ : Fact (2 ≤ d✝) d : ℕ inst✝ : Fact (2 ≤ d) c z : ℂ z3 : 3 ≤ Complex.abs z cz : Complex.abs c ≤ Complex.abs z t3 : ℝ hb3 : 3 ^ (d - 1) = t3 b3 : 3 ≤ t3 t2 : ℝ hb2 : t3 - 1 = t2 b2 : 2 ≤ t2 t2p : 0 ≤ t2 b6 : 6 ≤ t2 * 3 t11 : ℝ hb11 : t2 ^ d * t3 - 1 = t11 b11 : 11 ≤ t11 t33 : ℝ hb33 : t11 * 3 = t33 b33 : 33 ≤ t33 ⊢ 10.65 ≤ (1 - (t33 - 1)⁻¹) * t11 TACTIC:
https://github.com/girving/ray.git	0be790285dd0fce78913b0cb9bddaffa94bd25f9	Ray/Dynamics/Multibrot/Iterates.lean	iter_error_le_of_z3	[344, 1]	[379, 81]	calc (1 - (t33 - 1)⁻¹) * t11 _ ≥ (1 - (33 - 1)⁻¹) * 11 := by bound _ ≥ 10.65 := by norm_num	c✝ : ℂ d✝ : ℕ inst✝¹ : Fact (2 ≤ d✝) d : ℕ inst✝ : Fact (2 ≤ d) c z : ℂ z3 : 3 ≤ Complex.abs z cz : Complex.abs c ≤ Complex.abs z t3 : ℝ hb3 : 3 ^ (d - 1) = t3 b3 : 3 ≤ t3 t2 : ℝ hb2 : t3 - 1 = t2 b2 : 2 ≤ t2 t2p : 0 ≤ t2 b6 : 6 ≤ t2 * 3 t11 : ℝ hb11 : t2 ^ d * t3 - 1 = t11 b11 : 11 ≤ t11 t33 : ℝ hb33 : t11 * 3 = t33 b33 : 33 ≤ t33 h : 1 ≤ t33 - 1 ⊢ 10.65 ≤ (1 - (t33 - 1)⁻¹) * t11	no goals	Please generate a tactic in lean4 to solve the state. STATE: c✝ : ℂ d✝ : ℕ inst✝¹ : Fact (2 ≤ d✝) d : ℕ inst✝ : Fact (2 ≤ d) c z : ℂ z3 : 3 ≤ Complex.abs z cz : Complex.abs c ≤ Complex.abs z t3 : ℝ hb3 : 3 ^ (d - 1) = t3 b3 : 3 ≤ t3 t2 : ℝ hb2 : t3 - 1 = t2 b2 : 2 ≤ t2 t2p : 0 ≤ t2 b6 : 6 ≤ t2 * 3 t11 : ℝ hb11 : t2 ^ d * t3 - 1 = t11 b11 : 11 ≤ t11 t33 : ℝ hb33 : t11 * 3 = t33 b33 : 33 ≤ t33 h : 1 ≤ t33 - 1 ⊢ 10.65 ≤ (1 - (t33 - 1)⁻¹) * t11 TACTIC:
https://github.com/girving/ray.git	0be790285dd0fce78913b0cb9bddaffa94bd25f9	Ray/Dynamics/Multibrot/Iterates.lean	iter_error_le_of_z3	[344, 1]	[379, 81]	linarith	c✝ : ℂ d✝ : ℕ inst✝¹ : Fact (2 ≤ d✝) d : ℕ inst✝ : Fact (2 ≤ d) c z : ℂ z3 : 3 ≤ Complex.abs z cz : Complex.abs c ≤ Complex.abs z t3 : ℝ hb3 : 3 ^ (d - 1) = t3 b3 : 3 ≤ t3 t2 : ℝ hb2 : t3 - 1 = t2 b2 : 2 ≤ t2 t2p : 0 ≤ t2 b6 : 6 ≤ t2 * 3 t11 : ℝ hb11 : t2 ^ d * t3 - 1 = t11 b11 : 11 ≤ t11 t33 : ℝ hb33 : t11 * 3 = t33 b33 : 33 ≤ t33 ⊢ 1 ≤ t33 - 1	no goals	Please generate a tactic in lean4 to solve the state. STATE: c✝ : ℂ d✝ : ℕ inst✝¹ : Fact (2 ≤ d✝) d : ℕ inst✝ : Fact (2 ≤ d) c z : ℂ z3 : 3 ≤ Complex.abs z cz : Complex.abs c ≤ Complex.abs z t3 : ℝ hb3 : 3 ^ (d - 1) = t3 b3 : 3 ≤ t3 t2 : ℝ hb2 : t3 - 1 = t2 b2 : 2 ≤ t2 t2p : 0 ≤ t2 b6 : 6 ≤ t2 * 3 t11 : ℝ hb11 : t2 ^ d * t3 - 1 = t11 b11 : 11 ≤ t11 t33 : ℝ hb33 : t11 * 3 = t33 b33 : 33 ≤ t33 ⊢ 1 ≤ t33 - 1 TACTIC:
https://github.com/girving/ray.git	0be790285dd0fce78913b0cb9bddaffa94bd25f9	Ray/Dynamics/Multibrot/Iterates.lean	iter_error_le_of_z3	[344, 1]	[379, 81]	bound	c✝ : ℂ d✝ : ℕ inst✝¹ : Fact (2 ≤ d✝) d : ℕ inst✝ : Fact (2 ≤ d) c z : ℂ z3 : 3 ≤ Complex.abs z cz : Complex.abs c ≤ Complex.abs z t3 : ℝ hb3 : 3 ^ (d - 1) = t3 b3 : 3 ≤ t3 t2 : ℝ hb2 : t3 - 1 = t2 b2 : 2 ≤ t2 t2p : 0 ≤ t2 b6 : 6 ≤ t2 * 3 t11 : ℝ hb11 : t2 ^ d * t3 - 1 = t11 b11 : 11 ≤ t11 t33 : ℝ hb33 : t11 * 3 = t33 b33 : 33 ≤ t33 h : 1 ≤ t33 - 1 ⊢ (1 - (t33 - 1)⁻¹) * t11 ≥ (1 - (33 - 1)⁻¹) * 11	no goals	Please generate a tactic in lean4 to solve the state. STATE: c✝ : ℂ d✝ : ℕ inst✝¹ : Fact (2 ≤ d✝) d : ℕ inst✝ : Fact (2 ≤ d) c z : ℂ z3 : 3 ≤ Complex.abs z cz : Complex.abs c ≤ Complex.abs z t3 : ℝ hb3 : 3 ^ (d - 1) = t3 b3 : 3 ≤ t3 t2 : ℝ hb2 : t3 - 1 = t2 b2 : 2 ≤ t2 t2p : 0 ≤ t2 b6 : 6 ≤ t2 * 3 t11 : ℝ hb11 : t2 ^ d * t3 - 1 = t11 b11 : 11 ≤ t11 t33 : ℝ hb33 : t11 * 3 = t33 b33 : 33 ≤ t33 h : 1 ≤ t33 - 1 ⊢ (1 - (t33 - 1)⁻¹) * t11 ≥ (1 - (33 - 1)⁻¹) * 11 TACTIC:
https://github.com/girving/ray.git	0be790285dd0fce78913b0cb9bddaffa94bd25f9	Ray/Dynamics/Multibrot/Iterates.lean	iter_error_le_of_z3	[344, 1]	[379, 81]	norm_num	c✝ : ℂ d✝ : ℕ inst✝¹ : Fact (2 ≤ d✝) d : ℕ inst✝ : Fact (2 ≤ d) c z : ℂ z3 : 3 ≤ Complex.abs z cz : Complex.abs c ≤ Complex.abs z t3 : ℝ hb3 : 3 ^ (d - 1) = t3 b3 : 3 ≤ t3 t2 : ℝ hb2 : t3 - 1 = t2 b2 : 2 ≤ t2 t2p : 0 ≤ t2 b6 : 6 ≤ t2 * 3 t11 : ℝ hb11 : t2 ^ d * t3 - 1 = t11 b11 : 11 ≤ t11 t33 : ℝ hb33 : t11 * 3 = t33 b33 : 33 ≤ t33 h : 1 ≤ t33 - 1 ⊢ (1 - (33 - 1)⁻¹) * 11 ≥ 10.65	no goals	Please generate a tactic in lean4 to solve the state. STATE: c✝ : ℂ d✝ : ℕ inst✝¹ : Fact (2 ≤ d✝) d : ℕ inst✝ : Fact (2 ≤ d) c z : ℂ z3 : 3 ≤ Complex.abs z cz : Complex.abs c ≤ Complex.abs z t3 : ℝ hb3 : 3 ^ (d - 1) = t3 b3 : 3 ≤ t3 t2 : ℝ hb2 : t3 - 1 = t2 b2 : 2 ≤ t2 t2p : 0 ≤ t2 b6 : 6 ≤ t2 * 3 t11 : ℝ hb11 : t2 ^ d * t3 - 1 = t11 b11 : 11 ≤ t11 t33 : ℝ hb33 : t11 * 3 = t33 b33 : 33 ≤ t33 h : 1 ≤ t33 - 1 ⊢ (1 - (33 - 1)⁻¹) * 11 ≥ 10.65 TACTIC:
https://github.com/girving/ray.git	0be790285dd0fce78913b0cb9bddaffa94bd25f9	Ray/Dynamics/Multibrot/Iterates.lean	iter_error_le_of_z3	[344, 1]	[379, 81]	norm_num	c✝ : ℂ d✝ : ℕ inst✝¹ : Fact (2 ≤ d✝) d : ℕ inst✝ : Fact (2 ≤ d) c z : ℂ z3 : 3 ≤ Complex.abs z cz : Complex.abs c ≤ Complex.abs z t3 : ℝ hb3 : 3 ^ (d - 1) = t3 b3 : 3 ≤ t3 t2 : ℝ hb2 : t3 - 1 = t2 t2p : 0 ≤ t2 t11 : ℝ hb11 : t2 ^ d * t3 - 1 = t11 t33 : ℝ hb33 : t11 * 3 = t33 b10 : 10.65 ≤ (1 - (t33 - 1)⁻¹) * t11 b2 : 2 ≤ 3 ^ (d - 1) - 1 b6 : 6 ≤ (3 ^ (d - 1) - 1) * 3 b11 : 11 ≤ (3 ^ (d - 1) - 1) ^ d * 3 ^ (d - 1) - 1 b33 : 33 ≤ ((3 ^ (d - 1) - 1) ^ d * 3 ^ (d - 1) - 1) * 3 ⊢ 3 ≤ 3	no goals	Please generate a tactic in lean4 to solve the state. STATE: c✝ : ℂ d✝ : ℕ inst✝¹ : Fact (2 ≤ d✝) d : ℕ inst✝ : Fact (2 ≤ d) c z : ℂ z3 : 3 ≤ Complex.abs z cz : Complex.abs c ≤ Complex.abs z t3 : ℝ hb3 : 3 ^ (d - 1) = t3 b3 : 3 ≤ t3 t2 : ℝ hb2 : t3 - 1 = t2 t2p : 0 ≤ t2 t11 : ℝ hb11 : t2 ^ d * t3 - 1 = t11 t33 : ℝ hb33 : t11 * 3 = t33 b10 : 10.65 ≤ (1 - (t33 - 1)⁻¹) * t11 b2 : 2 ≤ 3 ^ (d - 1) - 1 b6 : 6 ≤ (3 ^ (d - 1) - 1) * 3 b11 : 11 ≤ (3 ^ (d - 1) - 1) ^ d * 3 ^ (d - 1) - 1 b33 : 33 ≤ ((3 ^ (d - 1) - 1) ^ d * 3 ^ (d - 1) - 1) * 3 ⊢ 3 ≤ 3 TACTIC:
https://github.com/girving/ray.git	0be790285dd0fce78913b0cb9bddaffa94bd25f9	Ray/Dynamics/Multibrot/Iterates.lean	iter_error_le_of_z3	[344, 1]	[379, 81]	norm_num	c✝ : ℂ d✝ : ℕ inst✝¹ : Fact (2 ≤ d✝) d : ℕ inst✝ : Fact (2 ≤ d) c z : ℂ z3 : 3 ≤ Complex.abs z cz : Complex.abs c ≤ Complex.abs z t3 : ℝ hb3 : 3 ^ (d - 1) = t3 b3 : 3 ≤ t3 t2 : ℝ hb2 : t3 - 1 = t2 t2p : 0 ≤ t2 t11 : ℝ hb11 : t2 ^ d * t3 - 1 = t11 t33 : ℝ hb33 : t11 * 3 = t33 b10 : 10.65 ≤ (1 - (t33 - 1)⁻¹) * t11 b2 : 2 ≤ 3 ^ (d - 1) - 1 b6 : 6 ≤ (3 ^ (d - 1) - 1) * 3 b11 : 11 ≤ (3 ^ (d - 1) - 1) ^ d * 3 ^ (d - 1) - 1 b33 : 33 ≤ ((3 ^ (d - 1) - 1) ^ d * 3 ^ (d - 1) - 1) * 3 ⊢ 0 ≤ 0.565	no goals	Please generate a tactic in lean4 to solve the state. STATE: c✝ : ℂ d✝ : ℕ inst✝¹ : Fact (2 ≤ d✝) d : ℕ inst✝ : Fact (2 ≤ d) c z : ℂ z3 : 3 ≤ Complex.abs z cz : Complex.abs c ≤ Complex.abs z t3 : ℝ hb3 : 3 ^ (d - 1) = t3 b3 : 3 ≤ t3 t2 : ℝ hb2 : t3 - 1 = t2 t2p : 0 ≤ t2 t11 : ℝ hb11 : t2 ^ d * t3 - 1 = t11 t33 : ℝ hb33 : t11 * 3 = t33 b10 : 10.65 ≤ (1 - (t33 - 1)⁻¹) * t11 b2 : 2 ≤ 3 ^ (d - 1) - 1 b6 : 6 ≤ (3 ^ (d - 1) - 1) * 3 b11 : 11 ≤ (3 ^ (d - 1) - 1) ^ d * 3 ^ (d - 1) - 1 b33 : 33 ≤ ((3 ^ (d - 1) - 1) ^ d * 3 ^ (d - 1) - 1) * 3 ⊢ 0 ≤ 0.565 TACTIC:
https://github.com/girving/ray.git	0be790285dd0fce78913b0cb9bddaffa94bd25f9	Ray/Dynamics/Multibrot/Iterates.lean	iter_error_le_of_z3	[344, 1]	[379, 81]	norm_num	c✝ : ℂ d✝ : ℕ inst✝¹ : Fact (2 ≤ d✝) d : ℕ inst✝ : Fact (2 ≤ d) c z : ℂ z3 : 3 ≤ Complex.abs z cz : Complex.abs c ≤ Complex.abs z t3 : ℝ hb3 : 3 ^ (d - 1) = t3 b3 : 3 ≤ t3 t2 : ℝ hb2 : t3 - 1 = t2 t2p : 0 ≤ t2 t11 : ℝ hb11 : t2 ^ d * t3 - 1 = t11 t33 : ℝ hb33 : t11 * 3 = t33 b10 : 10.65 ≤ (1 - (t33 - 1)⁻¹) * t11 b2 : 2 ≤ 3 ^ (d - 1) - 1 b6 : 6 ≤ (3 ^ (d - 1) - 1) * 3 b11 : 11 ≤ (3 ^ (d - 1) - 1) ^ d * 3 ^ (d - 1) - 1 b33 : 33 ≤ ((3 ^ (d - 1) - 1) ^ d * 3 ^ (d - 1) - 1) * 3 ⊢ 0 ≤ 0.512	no goals	Please generate a tactic in lean4 to solve the state. STATE: c✝ : ℂ d✝ : ℕ inst✝¹ : Fact (2 ≤ d✝) d : ℕ inst✝ : Fact (2 ≤ d) c z : ℂ z3 : 3 ≤ Complex.abs z cz : Complex.abs c ≤ Complex.abs z t3 : ℝ hb3 : 3 ^ (d - 1) = t3 b3 : 3 ≤ t3 t2 : ℝ hb2 : t3 - 1 = t2 t2p : 0 ≤ t2 t11 : ℝ hb11 : t2 ^ d * t3 - 1 = t11 t33 : ℝ hb33 : t11 * 3 = t33 b10 : 10.65 ≤ (1 - (t33 - 1)⁻¹) * t11 b2 : 2 ≤ 3 ^ (d - 1) - 1 b6 : 6 ≤ (3 ^ (d - 1) - 1) * 3 b11 : 11 ≤ (3 ^ (d - 1) - 1) ^ d * 3 ^ (d - 1) - 1 b33 : 33 ≤ ((3 ^ (d - 1) - 1) ^ d * 3 ^ (d - 1) - 1) * 3 ⊢ 0 ≤ 0.512 TACTIC:
https://github.com/girving/ray.git	0be790285dd0fce78913b0cb9bddaffa94bd25f9	Ray/Dynamics/Multibrot/Iterates.lean	iter_error_le_of_z3	[344, 1]	[379, 81]	norm_num	c✝ : ℂ d✝ : ℕ inst✝¹ : Fact (2 ≤ d✝) d : ℕ inst✝ : Fact (2 ≤ d) c z : ℂ z3 : 3 ≤ Complex.abs z cz : Complex.abs c ≤ Complex.abs z t3 : ℝ hb3 : 3 ^ (d - 1) = t3 b3 : 3 ≤ t3 t2 : ℝ hb2 : t3 - 1 = t2 t2p : 0 ≤ t2 t11 : ℝ hb11 : t2 ^ d * t3 - 1 = t11 t33 : ℝ hb33 : t11 * 3 = t33 b10 : 10.65 ≤ (1 - (t33 - 1)⁻¹) * t11 b2 : 2 ≤ 3 ^ (d - 1) - 1 b6 : 6 ≤ (3 ^ (d - 1) - 1) * 3 b11 : 11 ≤ (3 ^ (d - 1) - 1) ^ d * 3 ^ (d - 1) - 1 b33 : 33 ≤ ((3 ^ (d - 1) - 1) ^ d * 3 ^ (d - 1) - 1) * 3 ⊢ 3 ≤ 33	no goals	Please generate a tactic in lean4 to solve the state. STATE: c✝ : ℂ d✝ : ℕ inst✝¹ : Fact (2 ≤ d✝) d : ℕ inst✝ : Fact (2 ≤ d) c z : ℂ z3 : 3 ≤ Complex.abs z cz : Complex.abs c ≤ Complex.abs z t3 : ℝ hb3 : 3 ^ (d - 1) = t3 b3 : 3 ≤ t3 t2 : ℝ hb2 : t3 - 1 = t2 t2p : 0 ≤ t2 t11 : ℝ hb11 : t2 ^ d * t3 - 1 = t11 t33 : ℝ hb33 : t11 * 3 = t33 b10 : 10.65 ≤ (1 - (t33 - 1)⁻¹) * t11 b2 : 2 ≤ 3 ^ (d - 1) - 1 b6 : 6 ≤ (3 ^ (d - 1) - 1) * 3 b11 : 11 ≤ (3 ^ (d - 1) - 1) ^ d * 3 ^ (d - 1) - 1 b33 : 33 ≤ ((3 ^ (d - 1) - 1) ^ d * 3 ^ (d - 1) - 1) * 3 ⊢ 3 ≤ 33 TACTIC:
https://github.com/girving/ray.git	0be790285dd0fce78913b0cb9bddaffa94bd25f9	Ray/Dynamics/Multibrot/Iterates.lean	iter_error_le_of_z3	[344, 1]	[379, 81]	positivity	c✝ : ℂ d✝ : ℕ inst✝¹ : Fact (2 ≤ d✝) d : ℕ inst✝ : Fact (2 ≤ d) c z : ℂ z3 : 3 ≤ Complex.abs z cz : Complex.abs c ≤ Complex.abs z t3 : ℝ hb3 : 3 ^ (d - 1) = t3 b3 : 3 ≤ t3 t2 : ℝ hb2 : t3 - 1 = t2 t2p : 0 ≤ t2 t11 : ℝ hb11 : t2 ^ d * t3 - 1 = t11 t33 : ℝ hb33 : t11 * 3 = t33 b10 : 10.65 ≤ (1 - (t33 - 1)⁻¹) * t11 b2 : 2 ≤ 3 ^ (d - 1) - 1 b6 : 6 ≤ (3 ^ (d - 1) - 1) * 3 b11 : 11 ≤ (3 ^ (d - 1) - 1) ^ d * 3 ^ (d - 1) - 1 b33 : 33 ≤ ((3 ^ (d - 1) - 1) ^ d * 3 ^ (d - 1) - 1) * 3 ⊢ 0 < 3 ^ (d - 1) - 1	no goals	Please generate a tactic in lean4 to solve the state. STATE: c✝ : ℂ d✝ : ℕ inst✝¹ : Fact (2 ≤ d✝) d : ℕ inst✝ : Fact (2 ≤ d) c z : ℂ z3 : 3 ≤ Complex.abs z cz : Complex.abs c ≤ Complex.abs z t3 : ℝ hb3 : 3 ^ (d - 1) = t3 b3 : 3 ≤ t3 t2 : ℝ hb2 : t3 - 1 = t2 t2p : 0 ≤ t2 t11 : ℝ hb11 : t2 ^ d * t3 - 1 = t11 t33 : ℝ hb33 : t11 * 3 = t33 b10 : 10.65 ≤ (1 - (t33 - 1)⁻¹) * t11 b2 : 2 ≤ 3 ^ (d - 1) - 1 b6 : 6 ≤ (3 ^ (d - 1) - 1) * 3 b11 : 11 ≤ (3 ^ (d - 1) - 1) ^ d * 3 ^ (d - 1) - 1 b33 : 33 ≤ ((3 ^ (d - 1) - 1) ^ d * 3 ^ (d - 1) - 1) * 3 ⊢ 0 < 3 ^ (d - 1) - 1 TACTIC:
https://github.com/girving/ray.git	0be790285dd0fce78913b0cb9bddaffa94bd25f9	Ray/Dynamics/Multibrot/Iterates.lean	iter_error_le_of_z3	[344, 1]	[379, 81]	exact sub_pos.mpr (inv_lt_one (by linarith))	case refine_1 c✝ : ℂ d✝ : ℕ inst✝¹ : Fact (2 ≤ d✝) d : ℕ inst✝ : Fact (2 ≤ d) c z : ℂ z3 : 3 ≤ Complex.abs z cz : Complex.abs c ≤ Complex.abs z t3 : ℝ hb3 : 3 ^ (d - 1) = t3 b3 : 3 ≤ t3 t2 : ℝ hb2 : t3 - 1 = t2 t2p : 0 ≤ t2 t11 : ℝ hb11 : t2 ^ d * t3 - 1 = t11 t33 : ℝ hb33 : t11 * 3 = t33 b10 : 10.65 ≤ (1 - (t33 - 1)⁻¹) * t11 b2 : 2 ≤ 3 ^ (d - 1) - 1 b6 : 6 ≤ (3 ^ (d - 1) - 1) * 3 b11 : 11 ≤ (3 ^ (d - 1) - 1) ^ d * 3 ^ (d - 1) - 1 b33 : 33 ≤ ((3 ^ (d - 1) - 1) ^ d * 3 ^ (d - 1) - 1) * 3 ⊢ 0 < 1 - (((3 ^ (d - 1) - 1) ^ d * 3 ^ (d - 1) - 1) * 3 - 1)⁻¹	no goals	Please generate a tactic in lean4 to solve the state. STATE: case refine_1 c✝ : ℂ d✝ : ℕ inst✝¹ : Fact (2 ≤ d✝) d : ℕ inst✝ : Fact (2 ≤ d) c z : ℂ z3 : 3 ≤ Complex.abs z cz : Complex.abs c ≤ Complex.abs z t3 : ℝ hb3 : 3 ^ (d - 1) = t3 b3 : 3 ≤ t3 t2 : ℝ hb2 : t3 - 1 = t2 t2p : 0 ≤ t2 t11 : ℝ hb11 : t2 ^ d * t3 - 1 = t11 t33 : ℝ hb33 : t11 * 3 = t33 b10 : 10.65 ≤ (1 - (t33 - 1)⁻¹) * t11 b2 : 2 ≤ 3 ^ (d - 1) - 1 b6 : 6 ≤ (3 ^ (d - 1) - 1) * 3 b11 : 11 ≤ (3 ^ (d - 1) - 1) ^ d * 3 ^ (d - 1) - 1 b33 : 33 ≤ ((3 ^ (d - 1) - 1) ^ d * 3 ^ (d - 1) - 1) * 3 ⊢ 0 < 1 - (((3 ^ (d - 1) - 1) ^ d * 3 ^ (d - 1) - 1) * 3 - 1)⁻¹ TACTIC:
https://github.com/girving/ray.git	0be790285dd0fce78913b0cb9bddaffa94bd25f9	Ray/Dynamics/Multibrot/Iterates.lean	iter_error_le_of_z3	[344, 1]	[379, 81]	linarith	c✝ : ℂ d✝ : ℕ inst✝¹ : Fact (2 ≤ d✝) d : ℕ inst✝ : Fact (2 ≤ d) c z : ℂ z3 : 3 ≤ Complex.abs z cz : Complex.abs c ≤ Complex.abs z t3 : ℝ hb3 : 3 ^ (d - 1) = t3 b3 : 3 ≤ t3 t2 : ℝ hb2 : t3 - 1 = t2 t2p : 0 ≤ t2 t11 : ℝ hb11 : t2 ^ d * t3 - 1 = t11 t33 : ℝ hb33 : t11 * 3 = t33 b10 : 10.65 ≤ (1 - (t33 - 1)⁻¹) * t11 b2 : 2 ≤ 3 ^ (d - 1) - 1 b6 : 6 ≤ (3 ^ (d - 1) - 1) * 3 b11 : 11 ≤ (3 ^ (d - 1) - 1) ^ d * 3 ^ (d - 1) - 1 b33 : 33 ≤ ((3 ^ (d - 1) - 1) ^ d * 3 ^ (d - 1) - 1) * 3 ⊢ 1 < ((3 ^ (d - 1) - 1) ^ d * 3 ^ (d - 1) - 1) * 3 - 1	no goals	Please generate a tactic in lean4 to solve the state. STATE: c✝ : ℂ d✝ : ℕ inst✝¹ : Fact (2 ≤ d✝) d : ℕ inst✝ : Fact (2 ≤ d) c z : ℂ z3 : 3 ≤ Complex.abs z cz : Complex.abs c ≤ Complex.abs z t3 : ℝ hb3 : 3 ^ (d - 1) = t3 b3 : 3 ≤ t3 t2 : ℝ hb2 : t3 - 1 = t2 t2p : 0 ≤ t2 t11 : ℝ hb11 : t2 ^ d * t3 - 1 = t11 t33 : ℝ hb33 : t11 * 3 = t33 b10 : 10.65 ≤ (1 - (t33 - 1)⁻¹) * t11 b2 : 2 ≤ 3 ^ (d - 1) - 1 b6 : 6 ≤ (3 ^ (d - 1) - 1) * 3 b11 : 11 ≤ (3 ^ (d - 1) - 1) ^ d * 3 ^ (d - 1) - 1 b33 : 33 ≤ ((3 ^ (d - 1) - 1) ^ d * 3 ^ (d - 1) - 1) * 3 ⊢ 1 < ((3 ^ (d - 1) - 1) ^ d * 3 ^ (d - 1) - 1) * 3 - 1 TACTIC:
https://github.com/girving/ray.git	0be790285dd0fce78913b0cb9bddaffa94bd25f9	Ray/Dynamics/Multibrot/Iterates.lean	iter_error_le_of_z3	[344, 1]	[379, 81]	simp only [hb2, hb3, hb11, hb33] at b2 b3 b6 b11 b33 ⊢	case refine_2 c✝ : ℂ d✝ : ℕ inst✝¹ : Fact (2 ≤ d✝) d : ℕ inst✝ : Fact (2 ≤ d) c z : ℂ z3 : 3 ≤ Complex.abs z cz : Complex.abs c ≤ Complex.abs z t3 : ℝ hb3 : 3 ^ (d - 1) = t3 b3 : 3 ≤ t3 t2 : ℝ hb2 : t3 - 1 = t2 t2p : 0 ≤ t2 t11 : ℝ hb11 : t2 ^ d * t3 - 1 = t11 t33 : ℝ hb33 : t11 * 3 = t33 b10 : 10.65 ≤ (1 - (t33 - 1)⁻¹) * t11 b2 : 2 ≤ 3 ^ (d - 1) - 1 b6 : 6 ≤ (3 ^ (d - 1) - 1) * 3 b11 : 11 ≤ (3 ^ (d - 1) - 1) ^ d * 3 ^ (d - 1) - 1 b33 : 33 ≤ ((3 ^ (d - 1) - 1) ^ d * 3 ^ (d - 1) - 1) * 3 ⊢ 0.699 + 0.565 / (3 ^ (d - 1) - 1) + 0.512 / ((1 - (((3 ^ (d - 1) - 1) ^ d * 3 ^ (d - 1) - 1) * 3 - 1)⁻¹) * ((3 ^ (d - 1) - 1) ^ d * 3 ^ (d - 1) - 1)) ≤ 1.03	case refine_2 c✝ : ℂ d✝ : ℕ inst✝¹ : Fact (2 ≤ d✝) d : ℕ inst✝ : Fact (2 ≤ d) c z : ℂ z3 : 3 ≤ Complex.abs z cz : Complex.abs c ≤ Complex.abs z t3 : ℝ hb3 : 3 ^ (d - 1) = t3 b3 : 3 ≤ t3 t2 : ℝ hb2 : t3 - 1 = t2 t2p : 0 ≤ t2 t11 : ℝ hb11 : t2 ^ d * t3 - 1 = t11 t33 : ℝ hb33 : t11 * 3 = t33 b10 : 10.65 ≤ (1 - (t33 - 1)⁻¹) * t11 b2 : 2 ≤ t2 b6 : 6 ≤ t2 * 3 b11 : 11 ≤ t11 b33 : 33 ≤ t33 ⊢ 0.699 + 0.565 / t2 + 0.512 / ((1 - (t33 - 1)⁻¹) * t11) ≤ 1.03	Please generate a tactic in lean4 to solve the state. STATE: case refine_2 c✝ : ℂ d✝ : ℕ inst✝¹ : Fact (2 ≤ d✝) d : ℕ inst✝ : Fact (2 ≤ d) c z : ℂ z3 : 3 ≤ Complex.abs z cz : Complex.abs c ≤ Complex.abs z t3 : ℝ hb3 : 3 ^ (d - 1) = t3 b3 : 3 ≤ t3 t2 : ℝ hb2 : t3 - 1 = t2 t2p : 0 ≤ t2 t11 : ℝ hb11 : t2 ^ d * t3 - 1 = t11 t33 : ℝ hb33 : t11 * 3 = t33 b10 : 10.65 ≤ (1 - (t33 - 1)⁻¹) * t11 b2 : 2 ≤ 3 ^ (d - 1) - 1 b6 : 6 ≤ (3 ^ (d - 1) - 1) * 3 b11 : 11 ≤ (3 ^ (d - 1) - 1) ^ d * 3 ^ (d - 1) - 1 b33 : 33 ≤ ((3 ^ (d - 1) - 1) ^ d * 3 ^ (d - 1) - 1) * 3 ⊢ 0.699 + 0.565 / (3 ^ (d - 1) - 1) + 0.512 / ((1 - (((3 ^ (d - 1) - 1) ^ d * 3 ^ (d - 1) - 1) * 3 - 1)⁻¹) * ((3 ^ (d - 1) - 1) ^ d * 3 ^ (d - 1) - 1)) ≤ 1.03 TACTIC:
https://github.com/girving/ray.git	0be790285dd0fce78913b0cb9bddaffa94bd25f9	Ray/Dynamics/Multibrot/Iterates.lean	iter_error_le_of_z3	[344, 1]	[379, 81]	exact le_trans (add_le_add (add_le_add_left (div_le_div_of_nonneg_left (by norm_num) (by norm_num) b2) _) (div_le_div_of_nonneg_left (by norm_num) (by norm_num) b10)) (by norm_num)	case refine_2 c✝ : ℂ d✝ : ℕ inst✝¹ : Fact (2 ≤ d✝) d : ℕ inst✝ : Fact (2 ≤ d) c z : ℂ z3 : 3 ≤ Complex.abs z cz : Complex.abs c ≤ Complex.abs z t3 : ℝ hb3 : 3 ^ (d - 1) = t3 b3 : 3 ≤ t3 t2 : ℝ hb2 : t3 - 1 = t2 t2p : 0 ≤ t2 t11 : ℝ hb11 : t2 ^ d * t3 - 1 = t11 t33 : ℝ hb33 : t11 * 3 = t33 b10 : 10.65 ≤ (1 - (t33 - 1)⁻¹) * t11 b2 : 2 ≤ t2 b6 : 6 ≤ t2 * 3 b11 : 11 ≤ t11 b33 : 33 ≤ t33 ⊢ 0.699 + 0.565 / t2 + 0.512 / ((1 - (t33 - 1)⁻¹) * t11) ≤ 1.03	no goals	Please generate a tactic in lean4 to solve the state. STATE: case refine_2 c✝ : ℂ d✝ : ℕ inst✝¹ : Fact (2 ≤ d✝) d : ℕ inst✝ : Fact (2 ≤ d) c z : ℂ z3 : 3 ≤ Complex.abs z cz : Complex.abs c ≤ Complex.abs z t3 : ℝ hb3 : 3 ^ (d - 1) = t3 b3 : 3 ≤ t3 t2 : ℝ hb2 : t3 - 1 = t2 t2p : 0 ≤ t2 t11 : ℝ hb11 : t2 ^ d * t3 - 1 = t11 t33 : ℝ hb33 : t11 * 3 = t33 b10 : 10.65 ≤ (1 - (t33 - 1)⁻¹) * t11 b2 : 2 ≤ t2 b6 : 6 ≤ t2 * 3 b11 : 11 ≤ t11 b33 : 33 ≤ t33 ⊢ 0.699 + 0.565 / t2 + 0.512 / ((1 - (t33 - 1)⁻¹) * t11) ≤ 1.03 TACTIC:
https://github.com/girving/ray.git	0be790285dd0fce78913b0cb9bddaffa94bd25f9	Ray/Dynamics/Multibrot/Iterates.lean	iter_error_le_of_z3	[344, 1]	[379, 81]	norm_num	c✝ : ℂ d✝ : ℕ inst✝¹ : Fact (2 ≤ d✝) d : ℕ inst✝ : Fact (2 ≤ d) c z : ℂ z3 : 3 ≤ Complex.abs z cz : Complex.abs c ≤ Complex.abs z t3 : ℝ hb3 : 3 ^ (d - 1) = t3 b3 : 3 ≤ t3 t2 : ℝ hb2 : t3 - 1 = t2 t2p : 0 ≤ t2 t11 : ℝ hb11 : t2 ^ d * t3 - 1 = t11 t33 : ℝ hb33 : t11 * 3 = t33 b10 : 10.65 ≤ (1 - (t33 - 1)⁻¹) * t11 b2 : 2 ≤ t2 b6 : 6 ≤ t2 * 3 b11 : 11 ≤ t11 b33 : 33 ≤ t33 ⊢ 0 ≤ 0.565	no goals	Please generate a tactic in lean4 to solve the state. STATE: c✝ : ℂ d✝ : ℕ inst✝¹ : Fact (2 ≤ d✝) d : ℕ inst✝ : Fact (2 ≤ d) c z : ℂ z3 : 3 ≤ Complex.abs z cz : Complex.abs c ≤ Complex.abs z t3 : ℝ hb3 : 3 ^ (d - 1) = t3 b3 : 3 ≤ t3 t2 : ℝ hb2 : t3 - 1 = t2 t2p : 0 ≤ t2 t11 : ℝ hb11 : t2 ^ d * t3 - 1 = t11 t33 : ℝ hb33 : t11 * 3 = t33 b10 : 10.65 ≤ (1 - (t33 - 1)⁻¹) * t11 b2 : 2 ≤ t2 b6 : 6 ≤ t2 * 3 b11 : 11 ≤ t11 b33 : 33 ≤ t33 ⊢ 0 ≤ 0.565 TACTIC:
https://github.com/girving/ray.git	0be790285dd0fce78913b0cb9bddaffa94bd25f9	Ray/Dynamics/Multibrot/Iterates.lean	iter_error_le_of_z3	[344, 1]	[379, 81]	norm_num	c✝ : ℂ d✝ : ℕ inst✝¹ : Fact (2 ≤ d✝) d : ℕ inst✝ : Fact (2 ≤ d) c z : ℂ z3 : 3 ≤ Complex.abs z cz : Complex.abs c ≤ Complex.abs z t3 : ℝ hb3 : 3 ^ (d - 1) = t3 b3 : 3 ≤ t3 t2 : ℝ hb2 : t3 - 1 = t2 t2p : 0 ≤ t2 t11 : ℝ hb11 : t2 ^ d * t3 - 1 = t11 t33 : ℝ hb33 : t11 * 3 = t33 b10 : 10.65 ≤ (1 - (t33 - 1)⁻¹) * t11 b2 : 2 ≤ t2 b6 : 6 ≤ t2 * 3 b11 : 11 ≤ t11 b33 : 33 ≤ t33 ⊢ 0 < 2	no goals	Please generate a tactic in lean4 to solve the state. STATE: c✝ : ℂ d✝ : ℕ inst✝¹ : Fact (2 ≤ d✝) d : ℕ inst✝ : Fact (2 ≤ d) c z : ℂ z3 : 3 ≤ Complex.abs z cz : Complex.abs c ≤ Complex.abs z t3 : ℝ hb3 : 3 ^ (d - 1) = t3 b3 : 3 ≤ t3 t2 : ℝ hb2 : t3 - 1 = t2 t2p : 0 ≤ t2 t11 : ℝ hb11 : t2 ^ d * t3 - 1 = t11 t33 : ℝ hb33 : t11 * 3 = t33 b10 : 10.65 ≤ (1 - (t33 - 1)⁻¹) * t11 b2 : 2 ≤ t2 b6 : 6 ≤ t2 * 3 b11 : 11 ≤ t11 b33 : 33 ≤ t33 ⊢ 0 < 2 TACTIC:
https://github.com/girving/ray.git	0be790285dd0fce78913b0cb9bddaffa94bd25f9	Ray/Dynamics/Multibrot/Iterates.lean	iter_error_le_of_z3	[344, 1]	[379, 81]	norm_num	c✝ : ℂ d✝ : ℕ inst✝¹ : Fact (2 ≤ d✝) d : ℕ inst✝ : Fact (2 ≤ d) c z : ℂ z3 : 3 ≤ Complex.abs z cz : Complex.abs c ≤ Complex.abs z t3 : ℝ hb3 : 3 ^ (d - 1) = t3 b3 : 3 ≤ t3 t2 : ℝ hb2 : t3 - 1 = t2 t2p : 0 ≤ t2 t11 : ℝ hb11 : t2 ^ d * t3 - 1 = t11 t33 : ℝ hb33 : t11 * 3 = t33 b10 : 10.65 ≤ (1 - (t33 - 1)⁻¹) * t11 b2 : 2 ≤ t2 b6 : 6 ≤ t2 * 3 b11 : 11 ≤ t11 b33 : 33 ≤ t33 ⊢ 0 ≤ 0.512	no goals	Please generate a tactic in lean4 to solve the state. STATE: c✝ : ℂ d✝ : ℕ inst✝¹ : Fact (2 ≤ d✝) d : ℕ inst✝ : Fact (2 ≤ d) c z : ℂ z3 : 3 ≤ Complex.abs z cz : Complex.abs c ≤ Complex.abs z t3 : ℝ hb3 : 3 ^ (d - 1) = t3 b3 : 3 ≤ t3 t2 : ℝ hb2 : t3 - 1 = t2 t2p : 0 ≤ t2 t11 : ℝ hb11 : t2 ^ d * t3 - 1 = t11 t33 : ℝ hb33 : t11 * 3 = t33 b10 : 10.65 ≤ (1 - (t33 - 1)⁻¹) * t11 b2 : 2 ≤ t2 b6 : 6 ≤ t2 * 3 b11 : 11 ≤ t11 b33 : 33 ≤ t33 ⊢ 0 ≤ 0.512 TACTIC:
https://github.com/girving/ray.git	0be790285dd0fce78913b0cb9bddaffa94bd25f9	Ray/Dynamics/Multibrot/Iterates.lean	iter_error_le_of_z3	[344, 1]	[379, 81]	norm_num	c✝ : ℂ d✝ : ℕ inst✝¹ : Fact (2 ≤ d✝) d : ℕ inst✝ : Fact (2 ≤ d) c z : ℂ z3 : 3 ≤ Complex.abs z cz : Complex.abs c ≤ Complex.abs z t3 : ℝ hb3 : 3 ^ (d - 1) = t3 b3 : 3 ≤ t3 t2 : ℝ hb2 : t3 - 1 = t2 t2p : 0 ≤ t2 t11 : ℝ hb11 : t2 ^ d * t3 - 1 = t11 t33 : ℝ hb33 : t11 * 3 = t33 b10 : 10.65 ≤ (1 - (t33 - 1)⁻¹) * t11 b2 : 2 ≤ t2 b6 : 6 ≤ t2 * 3 b11 : 11 ≤ t11 b33 : 33 ≤ t33 ⊢ 0 < 10.65	no goals	Please generate a tactic in lean4 to solve the state. STATE: c✝ : ℂ d✝ : ℕ inst✝¹ : Fact (2 ≤ d✝) d : ℕ inst✝ : Fact (2 ≤ d) c z : ℂ z3 : 3 ≤ Complex.abs z cz : Complex.abs c ≤ Complex.abs z t3 : ℝ hb3 : 3 ^ (d - 1) = t3 b3 : 3 ≤ t3 t2 : ℝ hb2 : t3 - 1 = t2 t2p : 0 ≤ t2 t11 : ℝ hb11 : t2 ^ d * t3 - 1 = t11 t33 : ℝ hb33 : t11 * 3 = t33 b10 : 10.65 ≤ (1 - (t33 - 1)⁻¹) * t11 b2 : 2 ≤ t2 b6 : 6 ≤ t2 * 3 b11 : 11 ≤ t11 b33 : 33 ≤ t33 ⊢ 0 < 10.65 TACTIC:
https://github.com/girving/ray.git	0be790285dd0fce78913b0cb9bddaffa94bd25f9	Ray/Dynamics/Multibrot/Iterates.lean	iter_error_le_of_z3	[344, 1]	[379, 81]	norm_num	c✝ : ℂ d✝ : ℕ inst✝¹ : Fact (2 ≤ d✝) d : ℕ inst✝ : Fact (2 ≤ d) c z : ℂ z3 : 3 ≤ Complex.abs z cz : Complex.abs c ≤ Complex.abs z t3 : ℝ hb3 : 3 ^ (d - 1) = t3 b3 : 3 ≤ t3 t2 : ℝ hb2 : t3 - 1 = t2 t2p : 0 ≤ t2 t11 : ℝ hb11 : t2 ^ d * t3 - 1 = t11 t33 : ℝ hb33 : t11 * 3 = t33 b10 : 10.65 ≤ (1 - (t33 - 1)⁻¹) * t11 b2 : 2 ≤ t2 b6 : 6 ≤ t2 * 3 b11 : 11 ≤ t11 b33 : 33 ≤ t33 ⊢ 0.699 + 0.565 / 2 + 0.512 / 10.65 ≤ 1.03	no goals	Please generate a tactic in lean4 to solve the state. STATE: c✝ : ℂ d✝ : ℕ inst✝¹ : Fact (2 ≤ d✝) d : ℕ inst✝ : Fact (2 ≤ d) c z : ℂ z3 : 3 ≤ Complex.abs z cz : Complex.abs c ≤ Complex.abs z t3 : ℝ hb3 : 3 ^ (d - 1) = t3 b3 : 3 ≤ t3 t2 : ℝ hb2 : t3 - 1 = t2 t2p : 0 ≤ t2 t11 : ℝ hb11 : t2 ^ d * t3 - 1 = t11 t33 : ℝ hb33 : t11 * 3 = t33 b10 : 10.65 ≤ (1 - (t33 - 1)⁻¹) * t11 b2 : 2 ≤ t2 b6 : 6 ≤ t2 * 3 b11 : 11 ≤ t11 b33 : 33 ≤ t33 ⊢ 0.699 + 0.565 / 2 + 0.512 / 10.65 ≤ 1.03 TACTIC:
https://github.com/girving/ray.git	0be790285dd0fce78913b0cb9bddaffa94bd25f9	Ray/Dynamics/Multibrot/Iterates.lean	iter_error_le_of_z4	[381, 1]	[416, 81]	have b3 : (4:ℝ) ≤ 4^(d-1) := by calc (4:ℝ)^(d-1) _ ≥ 4^(2-1) := by bound _ = 4 := by norm_num	c✝ : ℂ d✝ : ℕ inst✝¹ : Fact (2 ≤ d✝) d : ℕ inst✝ : Fact (2 ≤ d) c z : ℂ z4 : 4 ≤ Complex.abs z cz : Complex.abs c ≤ Complex.abs z ⊢ iter_error d c z ≤ 0.8095 / (Complex.abs z * (Complex.abs z).log)	c✝ : ℂ d✝ : ℕ inst✝¹ : Fact (2 ≤ d✝) d : ℕ inst✝ : Fact (2 ≤ d) c z : ℂ z4 : 4 ≤ Complex.abs z cz : Complex.abs c ≤ Complex.abs z b3 : 4 ≤ 4 ^ (d - 1) ⊢ iter_error d c z ≤ 0.8095 / (Complex.abs z * (Complex.abs z).log)	Please generate a tactic in lean4 to solve the state. STATE: c✝ : ℂ d✝ : ℕ inst✝¹ : Fact (2 ≤ d✝) d : ℕ inst✝ : Fact (2 ≤ d) c z : ℂ z4 : 4 ≤ Complex.abs z cz : Complex.abs c ≤ Complex.abs z ⊢ iter_error d c z ≤ 0.8095 / (Complex.abs z * (Complex.abs z).log) TACTIC:
https://github.com/girving/ray.git	0be790285dd0fce78913b0cb9bddaffa94bd25f9	Ray/Dynamics/Multibrot/Iterates.lean	iter_error_le_of_z4	[381, 1]	[416, 81]	generalize hb3 : (4:ℝ)^(d-1) = t3 at b3	c✝ : ℂ d✝ : ℕ inst✝¹ : Fact (2 ≤ d✝) d : ℕ inst✝ : Fact (2 ≤ d) c z : ℂ z4 : 4 ≤ Complex.abs z cz : Complex.abs c ≤ Complex.abs z b3 : 4 ≤ 4 ^ (d - 1) ⊢ iter_error d c z ≤ 0.8095 / (Complex.abs z * (Complex.abs z).log)	c✝ : ℂ d✝ : ℕ inst✝¹ : Fact (2 ≤ d✝) d : ℕ inst✝ : Fact (2 ≤ d) c z : ℂ z4 : 4 ≤ Complex.abs z cz : Complex.abs c ≤ Complex.abs z t3 : ℝ hb3 : 4 ^ (d - 1) = t3 b3 : 4 ≤ t3 ⊢ iter_error d c z ≤ 0.8095 / (Complex.abs z * (Complex.abs z).log)	Please generate a tactic in lean4 to solve the state. STATE: c✝ : ℂ d✝ : ℕ inst✝¹ : Fact (2 ≤ d✝) d : ℕ inst✝ : Fact (2 ≤ d) c z : ℂ z4 : 4 ≤ Complex.abs z cz : Complex.abs c ≤ Complex.abs z b3 : 4 ≤ 4 ^ (d - 1) ⊢ iter_error d c z ≤ 0.8095 / (Complex.abs z * (Complex.abs z).log) TACTIC:
https://github.com/girving/ray.git	0be790285dd0fce78913b0cb9bddaffa94bd25f9	Ray/Dynamics/Multibrot/Iterates.lean	iter_error_le_of_z4	[381, 1]	[416, 81]	have b2 : (3:ℝ) ≤ t3 - 1 := by linarith	c✝ : ℂ d✝ : ℕ inst✝¹ : Fact (2 ≤ d✝) d : ℕ inst✝ : Fact (2 ≤ d) c z : ℂ z4 : 4 ≤ Complex.abs z cz : Complex.abs c ≤ Complex.abs z t3 : ℝ hb3 : 4 ^ (d - 1) = t3 b3 : 4 ≤ t3 ⊢ iter_error d c z ≤ 0.8095 / (Complex.abs z * (Complex.abs z).log)	c✝ : ℂ d✝ : ℕ inst✝¹ : Fact (2 ≤ d✝) d : ℕ inst✝ : Fact (2 ≤ d) c z : ℂ z4 : 4 ≤ Complex.abs z cz : Complex.abs c ≤ Complex.abs z t3 : ℝ hb3 : 4 ^ (d - 1) = t3 b3 : 4 ≤ t3 b2 : 3 ≤ t3 - 1 ⊢ iter_error d c z ≤ 0.8095 / (Complex.abs z * (Complex.abs z).log)	Please generate a tactic in lean4 to solve the state. STATE: c✝ : ℂ d✝ : ℕ inst✝¹ : Fact (2 ≤ d✝) d : ℕ inst✝ : Fact (2 ≤ d) c z : ℂ z4 : 4 ≤ Complex.abs z cz : Complex.abs c ≤ Complex.abs z t3 : ℝ hb3 : 4 ^ (d - 1) = t3 b3 : 4 ≤ t3 ⊢ iter_error d c z ≤ 0.8095 / (Complex.abs z * (Complex.abs z).log) TACTIC:
https://github.com/girving/ray.git	0be790285dd0fce78913b0cb9bddaffa94bd25f9	Ray/Dynamics/Multibrot/Iterates.lean	iter_error_le_of_z4	[381, 1]	[416, 81]	generalize hb2 : t3 - 1 = t2 at b2	c✝ : ℂ d✝ : ℕ inst✝¹ : Fact (2 ≤ d✝) d : ℕ inst✝ : Fact (2 ≤ d) c z : ℂ z4 : 4 ≤ Complex.abs z cz : Complex.abs c ≤ Complex.abs z t3 : ℝ hb3 : 4 ^ (d - 1) = t3 b3 : 4 ≤ t3 b2 : 3 ≤ t3 - 1 ⊢ iter_error d c z ≤ 0.8095 / (Complex.abs z * (Complex.abs z).log)	c✝ : ℂ d✝ : ℕ inst✝¹ : Fact (2 ≤ d✝) d : ℕ inst✝ : Fact (2 ≤ d) c z : ℂ z4 : 4 ≤ Complex.abs z cz : Complex.abs c ≤ Complex.abs z t3 : ℝ hb3 : 4 ^ (d - 1) = t3 b3 : 4 ≤ t3 t2 : ℝ hb2 : t3 - 1 = t2 b2 : 3 ≤ t2 ⊢ iter_error d c z ≤ 0.8095 / (Complex.abs z * (Complex.abs z).log)	Please generate a tactic in lean4 to solve the state. STATE: c✝ : ℂ d✝ : ℕ inst✝¹ : Fact (2 ≤ d✝) d : ℕ inst✝ : Fact (2 ≤ d) c z : ℂ z4 : 4 ≤ Complex.abs z cz : Complex.abs c ≤ Complex.abs z t3 : ℝ hb3 : 4 ^ (d - 1) = t3 b3 : 4 ≤ t3 b2 : 3 ≤ t3 - 1 ⊢ iter_error d c z ≤ 0.8095 / (Complex.abs z * (Complex.abs z).log) TACTIC:
https://github.com/girving/ray.git	0be790285dd0fce78913b0cb9bddaffa94bd25f9	Ray/Dynamics/Multibrot/Iterates.lean	iter_error_le_of_z4	[381, 1]	[416, 81]	have t2p : 0 ≤ t2 := by positivity	c✝ : ℂ d✝ : ℕ inst✝¹ : Fact (2 ≤ d✝) d : ℕ inst✝ : Fact (2 ≤ d) c z : ℂ z4 : 4 ≤ Complex.abs z cz : Complex.abs c ≤ Complex.abs z t3 : ℝ hb3 : 4 ^ (d - 1) = t3 b3 : 4 ≤ t3 t2 : ℝ hb2 : t3 - 1 = t2 b2 : 3 ≤ t2 ⊢ iter_error d c z ≤ 0.8095 / (Complex.abs z * (Complex.abs z).log)	c✝ : ℂ d✝ : ℕ inst✝¹ : Fact (2 ≤ d✝) d : ℕ inst✝ : Fact (2 ≤ d) c z : ℂ z4 : 4 ≤ Complex.abs z cz : Complex.abs c ≤ Complex.abs z t3 : ℝ hb3 : 4 ^ (d - 1) = t3 b3 : 4 ≤ t3 t2 : ℝ hb2 : t3 - 1 = t2 b2 : 3 ≤ t2 t2p : 0 ≤ t2 ⊢ iter_error d c z ≤ 0.8095 / (Complex.abs z * (Complex.abs z).log)	Please generate a tactic in lean4 to solve the state. STATE: c✝ : ℂ d✝ : ℕ inst✝¹ : Fact (2 ≤ d✝) d : ℕ inst✝ : Fact (2 ≤ d) c z : ℂ z4 : 4 ≤ Complex.abs z cz : Complex.abs c ≤ Complex.abs z t3 : ℝ hb3 : 4 ^ (d - 1) = t3 b3 : 4 ≤ t3 t2 : ℝ hb2 : t3 - 1 = t2 b2 : 3 ≤ t2 ⊢ iter_error d c z ≤ 0.8095 / (Complex.abs z * (Complex.abs z).log) TACTIC:
https://github.com/girving/ray.git	0be790285dd0fce78913b0cb9bddaffa94bd25f9	Ray/Dynamics/Multibrot/Iterates.lean	iter_error_le_of_z4	[381, 1]	[416, 81]	have b6 : (12:ℝ) ≤ t2 * 4 := by linarith	c✝ : ℂ d✝ : ℕ inst✝¹ : Fact (2 ≤ d✝) d : ℕ inst✝ : Fact (2 ≤ d) c z : ℂ z4 : 4 ≤ Complex.abs z cz : Complex.abs c ≤ Complex.abs z t3 : ℝ hb3 : 4 ^ (d - 1) = t3 b3 : 4 ≤ t3 t2 : ℝ hb2 : t3 - 1 = t2 b2 : 3 ≤ t2 t2p : 0 ≤ t2 ⊢ iter_error d c z ≤ 0.8095 / (Complex.abs z * (Complex.abs z).log)	c✝ : ℂ d✝ : ℕ inst✝¹ : Fact (2 ≤ d✝) d : ℕ inst✝ : Fact (2 ≤ d) c z : ℂ z4 : 4 ≤ Complex.abs z cz : Complex.abs c ≤ Complex.abs z t3 : ℝ hb3 : 4 ^ (d - 1) = t3 b3 : 4 ≤ t3 t2 : ℝ hb2 : t3 - 1 = t2 b2 : 3 ≤ t2 t2p : 0 ≤ t2 b6 : 12 ≤ t2 * 4 ⊢ iter_error d c z ≤ 0.8095 / (Complex.abs z * (Complex.abs z).log)	Please generate a tactic in lean4 to solve the state. STATE: c✝ : ℂ d✝ : ℕ inst✝¹ : Fact (2 ≤ d✝) d : ℕ inst✝ : Fact (2 ≤ d) c z : ℂ z4 : 4 ≤ Complex.abs z cz : Complex.abs c ≤ Complex.abs z t3 : ℝ hb3 : 4 ^ (d - 1) = t3 b3 : 4 ≤ t3 t2 : ℝ hb2 : t3 - 1 = t2 b2 : 3 ≤ t2 t2p : 0 ≤ t2 ⊢ iter_error d c z ≤ 0.8095 / (Complex.abs z * (Complex.abs z).log) TACTIC:
https://github.com/girving/ray.git	0be790285dd0fce78913b0cb9bddaffa94bd25f9	Ray/Dynamics/Multibrot/Iterates.lean	iter_error_le_of_z4	[381, 1]	[416, 81]	have b11 : (35:ℝ) ≤ t2^d * t3 - 1 := by calc t2^d * t3 - 1 _ ≥ 3^d * 4 - 1 := by bound _ ≥ 3^2 * 4 - 1 := by bound _ = 35 := by norm_num	c✝ : ℂ d✝ : ℕ inst✝¹ : Fact (2 ≤ d✝) d : ℕ inst✝ : Fact (2 ≤ d) c z : ℂ z4 : 4 ≤ Complex.abs z cz : Complex.abs c ≤ Complex.abs z t3 : ℝ hb3 : 4 ^ (d - 1) = t3 b3 : 4 ≤ t3 t2 : ℝ hb2 : t3 - 1 = t2 b2 : 3 ≤ t2 t2p : 0 ≤ t2 b6 : 12 ≤ t2 * 4 ⊢ iter_error d c z ≤ 0.8095 / (Complex.abs z * (Complex.abs z).log)	c✝ : ℂ d✝ : ℕ inst✝¹ : Fact (2 ≤ d✝) d : ℕ inst✝ : Fact (2 ≤ d) c z : ℂ z4 : 4 ≤ Complex.abs z cz : Complex.abs c ≤ Complex.abs z t3 : ℝ hb3 : 4 ^ (d - 1) = t3 b3 : 4 ≤ t3 t2 : ℝ hb2 : t3 - 1 = t2 b2 : 3 ≤ t2 t2p : 0 ≤ t2 b6 : 12 ≤ t2 * 4 b11 : 35 ≤ t2 ^ d * t3 - 1 ⊢ iter_error d c z ≤ 0.8095 / (Complex.abs z * (Complex.abs z).log)	Please generate a tactic in lean4 to solve the state. STATE: c✝ : ℂ d✝ : ℕ inst✝¹ : Fact (2 ≤ d✝) d : ℕ inst✝ : Fact (2 ≤ d) c z : ℂ z4 : 4 ≤ Complex.abs z cz : Complex.abs c ≤ Complex.abs z t3 : ℝ hb3 : 4 ^ (d - 1) = t3 b3 : 4 ≤ t3 t2 : ℝ hb2 : t3 - 1 = t2 b2 : 3 ≤ t2 t2p : 0 ≤ t2 b6 : 12 ≤ t2 * 4 ⊢ iter_error d c z ≤ 0.8095 / (Complex.abs z * (Complex.abs z).log) TACTIC:
https://github.com/girving/ray.git	0be790285dd0fce78913b0cb9bddaffa94bd25f9	Ray/Dynamics/Multibrot/Iterates.lean	iter_error_le_of_z4	[381, 1]	[416, 81]	generalize hb11 : t2^d * t3 - 1 = t11 at b11	c✝ : ℂ d✝ : ℕ inst✝¹ : Fact (2 ≤ d✝) d : ℕ inst✝ : Fact (2 ≤ d) c z : ℂ z4 : 4 ≤ Complex.abs z cz : Complex.abs c ≤ Complex.abs z t3 : ℝ hb3 : 4 ^ (d - 1) = t3 b3 : 4 ≤ t3 t2 : ℝ hb2 : t3 - 1 = t2 b2 : 3 ≤ t2 t2p : 0 ≤ t2 b6 : 12 ≤ t2 * 4 b11 : 35 ≤ t2 ^ d * t3 - 1 ⊢ iter_error d c z ≤ 0.8095 / (Complex.abs z * (Complex.abs z).log)	c✝ : ℂ d✝ : ℕ inst✝¹ : Fact (2 ≤ d✝) d : ℕ inst✝ : Fact (2 ≤ d) c z : ℂ z4 : 4 ≤ Complex.abs z cz : Complex.abs c ≤ Complex.abs z t3 : ℝ hb3 : 4 ^ (d - 1) = t3 b3 : 4 ≤ t3 t2 : ℝ hb2 : t3 - 1 = t2 b2 : 3 ≤ t2 t2p : 0 ≤ t2 b6 : 12 ≤ t2 * 4 t11 : ℝ hb11 : t2 ^ d * t3 - 1 = t11 b11 : 35 ≤ t11 ⊢ iter_error d c z ≤ 0.8095 / (Complex.abs z * (Complex.abs z).log)	Please generate a tactic in lean4 to solve the state. STATE: c✝ : ℂ d✝ : ℕ inst✝¹ : Fact (2 ≤ d✝) d : ℕ inst✝ : Fact (2 ≤ d) c z : ℂ z4 : 4 ≤ Complex.abs z cz : Complex.abs c ≤ Complex.abs z t3 : ℝ hb3 : 4 ^ (d - 1) = t3 b3 : 4 ≤ t3 t2 : ℝ hb2 : t3 - 1 = t2 b2 : 3 ≤ t2 t2p : 0 ≤ t2 b6 : 12 ≤ t2 * 4 b11 : 35 ≤ t2 ^ d * t3 - 1 ⊢ iter_error d c z ≤ 0.8095 / (Complex.abs z * (Complex.abs z).log) TACTIC:
https://github.com/girving/ray.git	0be790285dd0fce78913b0cb9bddaffa94bd25f9	Ray/Dynamics/Multibrot/Iterates.lean	iter_error_le_of_z4	[381, 1]	[416, 81]	have b33 : (140:ℝ) ≤ t11 * 4 := by linarith	c✝ : ℂ d✝ : ℕ inst✝¹ : Fact (2 ≤ d✝) d : ℕ inst✝ : Fact (2 ≤ d) c z : ℂ z4 : 4 ≤ Complex.abs z cz : Complex.abs c ≤ Complex.abs z t3 : ℝ hb3 : 4 ^ (d - 1) = t3 b3 : 4 ≤ t3 t2 : ℝ hb2 : t3 - 1 = t2 b2 : 3 ≤ t2 t2p : 0 ≤ t2 b6 : 12 ≤ t2 * 4 t11 : ℝ hb11 : t2 ^ d * t3 - 1 = t11 b11 : 35 ≤ t11 ⊢ iter_error d c z ≤ 0.8095 / (Complex.abs z * (Complex.abs z).log)	c✝ : ℂ d✝ : ℕ inst✝¹ : Fact (2 ≤ d✝) d : ℕ inst✝ : Fact (2 ≤ d) c z : ℂ z4 : 4 ≤ Complex.abs z cz : Complex.abs c ≤ Complex.abs z t3 : ℝ hb3 : 4 ^ (d - 1) = t3 b3 : 4 ≤ t3 t2 : ℝ hb2 : t3 - 1 = t2 b2 : 3 ≤ t2 t2p : 0 ≤ t2 b6 : 12 ≤ t2 * 4 t11 : ℝ hb11 : t2 ^ d * t3 - 1 = t11 b11 : 35 ≤ t11 b33 : 140 ≤ t11 * 4 ⊢ iter_error d c z ≤ 0.8095 / (Complex.abs z * (Complex.abs z).log)	Please generate a tactic in lean4 to solve the state. STATE: c✝ : ℂ d✝ : ℕ inst✝¹ : Fact (2 ≤ d✝) d : ℕ inst✝ : Fact (2 ≤ d) c z : ℂ z4 : 4 ≤ Complex.abs z cz : Complex.abs c ≤ Complex.abs z t3 : ℝ hb3 : 4 ^ (d - 1) = t3 b3 : 4 ≤ t3 t2 : ℝ hb2 : t3 - 1 = t2 b2 : 3 ≤ t2 t2p : 0 ≤ t2 b6 : 12 ≤ t2 * 4 t11 : ℝ hb11 : t2 ^ d * t3 - 1 = t11 b11 : 35 ≤ t11 ⊢ iter_error d c z ≤ 0.8095 / (Complex.abs z * (Complex.abs z).log) TACTIC:
https://github.com/girving/ray.git	0be790285dd0fce78913b0cb9bddaffa94bd25f9	Ray/Dynamics/Multibrot/Iterates.lean	iter_error_le_of_z4	[381, 1]	[416, 81]	generalize hb33 : t11 * 4 = t33 at b33	c✝ : ℂ d✝ : ℕ inst✝¹ : Fact (2 ≤ d✝) d : ℕ inst✝ : Fact (2 ≤ d) c z : ℂ z4 : 4 ≤ Complex.abs z cz : Complex.abs c ≤ Complex.abs z t3 : ℝ hb3 : 4 ^ (d - 1) = t3 b3 : 4 ≤ t3 t2 : ℝ hb2 : t3 - 1 = t2 b2 : 3 ≤ t2 t2p : 0 ≤ t2 b6 : 12 ≤ t2 * 4 t11 : ℝ hb11 : t2 ^ d * t3 - 1 = t11 b11 : 35 ≤ t11 b33 : 140 ≤ t11 * 4 ⊢ iter_error d c z ≤ 0.8095 / (Complex.abs z * (Complex.abs z).log)	c✝ : ℂ d✝ : ℕ inst✝¹ : Fact (2 ≤ d✝) d : ℕ inst✝ : Fact (2 ≤ d) c z : ℂ z4 : 4 ≤ Complex.abs z cz : Complex.abs c ≤ Complex.abs z t3 : ℝ hb3 : 4 ^ (d - 1) = t3 b3 : 4 ≤ t3 t2 : ℝ hb2 : t3 - 1 = t2 b2 : 3 ≤ t2 t2p : 0 ≤ t2 b6 : 12 ≤ t2 * 4 t11 : ℝ hb11 : t2 ^ d * t3 - 1 = t11 b11 : 35 ≤ t11 t33 : ℝ hb33 : t11 * 4 = t33 b33 : 140 ≤ t33 ⊢ iter_error d c z ≤ 0.8095 / (Complex.abs z * (Complex.abs z).log)	Please generate a tactic in lean4 to solve the state. STATE: c✝ : ℂ d✝ : ℕ inst✝¹ : Fact (2 ≤ d✝) d : ℕ inst✝ : Fact (2 ≤ d) c z : ℂ z4 : 4 ≤ Complex.abs z cz : Complex.abs c ≤ Complex.abs z t3 : ℝ hb3 : 4 ^ (d - 1) = t3 b3 : 4 ≤ t3 t2 : ℝ hb2 : t3 - 1 = t2 b2 : 3 ≤ t2 t2p : 0 ≤ t2 b6 : 12 ≤ t2 * 4 t11 : ℝ hb11 : t2 ^ d * t3 - 1 = t11 b11 : 35 ≤ t11 b33 : 140 ≤ t11 * 4 ⊢ iter_error d c z ≤ 0.8095 / (Complex.abs z * (Complex.abs z).log) TACTIC:
https://github.com/girving/ray.git	0be790285dd0fce78913b0cb9bddaffa94bd25f9	Ray/Dynamics/Multibrot/Iterates.lean	iter_error_le_of_z4	[381, 1]	[416, 81]	have b10 : 34.748 ≤ (1 - (t33 - 1)⁻¹) * t11 := by have h : 1 ≤ t33 - 1 := by linarith calc (1 - (t33 - 1)⁻¹) * t11 _ ≥ (1 - (140 - 1)⁻¹) * 35 := by bound _ ≥ 34.748 := by norm_num	c✝ : ℂ d✝ : ℕ inst✝¹ : Fact (2 ≤ d✝) d : ℕ inst✝ : Fact (2 ≤ d) c z : ℂ z4 : 4 ≤ Complex.abs z cz : Complex.abs c ≤ Complex.abs z t3 : ℝ hb3 : 4 ^ (d - 1) = t3 b3 : 4 ≤ t3 t2 : ℝ hb2 : t3 - 1 = t2 b2 : 3 ≤ t2 t2p : 0 ≤ t2 b6 : 12 ≤ t2 * 4 t11 : ℝ hb11 : t2 ^ d * t3 - 1 = t11 b11 : 35 ≤ t11 t33 : ℝ hb33 : t11 * 4 = t33 b33 : 140 ≤ t33 ⊢ iter_error d c z ≤ 0.8095 / (Complex.abs z * (Complex.abs z).log)	c✝ : ℂ d✝ : ℕ inst✝¹ : Fact (2 ≤ d✝) d : ℕ inst✝ : Fact (2 ≤ d) c z : ℂ z4 : 4 ≤ Complex.abs z cz : Complex.abs c ≤ Complex.abs z t3 : ℝ hb3 : 4 ^ (d - 1) = t3 b3 : 4 ≤ t3 t2 : ℝ hb2 : t3 - 1 = t2 b2 : 3 ≤ t2 t2p : 0 ≤ t2 b6 : 12 ≤ t2 * 4 t11 : ℝ hb11 : t2 ^ d * t3 - 1 = t11 b11 : 35 ≤ t11 t33 : ℝ hb33 : t11 * 4 = t33 b33 : 140 ≤ t33 b10 : 34.748 ≤ (1 - (t33 - 1)⁻¹) * t11 ⊢ iter_error d c z ≤ 0.8095 / (Complex.abs z * (Complex.abs z).log)	Please generate a tactic in lean4 to solve the state. STATE: c✝ : ℂ d✝ : ℕ inst✝¹ : Fact (2 ≤ d✝) d : ℕ inst✝ : Fact (2 ≤ d) c z : ℂ z4 : 4 ≤ Complex.abs z cz : Complex.abs c ≤ Complex.abs z t3 : ℝ hb3 : 4 ^ (d - 1) = t3 b3 : 4 ≤ t3 t2 : ℝ hb2 : t3 - 1 = t2 b2 : 3 ≤ t2 t2p : 0 ≤ t2 b6 : 12 ≤ t2 * 4 t11 : ℝ hb11 : t2 ^ d * t3 - 1 = t11 b11 : 35 ≤ t11 t33 : ℝ hb33 : t11 * 4 = t33 b33 : 140 ≤ t33 ⊢ iter_error d c z ≤ 0.8095 / (Complex.abs z * (Complex.abs z).log) TACTIC:
https://github.com/girving/ray.git	0be790285dd0fce78913b0cb9bddaffa94bd25f9	Ray/Dynamics/Multibrot/Iterates.lean	iter_error_le_of_z4	[381, 1]	[416, 81]	simp only [←hb2, ←hb3, ←hb11, ←hb33] at b2 b6 b11 b33	c✝ : ℂ d✝ : ℕ inst✝¹ : Fact (2 ≤ d✝) d : ℕ inst✝ : Fact (2 ≤ d) c z : ℂ z4 : 4 ≤ Complex.abs z cz : Complex.abs c ≤ Complex.abs z t3 : ℝ hb3 : 4 ^ (d - 1) = t3 b3 : 4 ≤ t3 t2 : ℝ hb2 : t3 - 1 = t2 b2 : 3 ≤ t2 t2p : 0 ≤ t2 b6 : 12 ≤ t2 * 4 t11 : ℝ hb11 : t2 ^ d * t3 - 1 = t11 b11 : 35 ≤ t11 t33 : ℝ hb33 : t11 * 4 = t33 b33 : 140 ≤ t33 b10 : 34.748 ≤ (1 - (t33 - 1)⁻¹) * t11 ⊢ iter_error d c z ≤ 0.8095 / (Complex.abs z * (Complex.abs z).log)	c✝ : ℂ d✝ : ℕ inst✝¹ : Fact (2 ≤ d✝) d : ℕ inst✝ : Fact (2 ≤ d) c z : ℂ z4 : 4 ≤ Complex.abs z cz : Complex.abs c ≤ Complex.abs z t3 : ℝ hb3 : 4 ^ (d - 1) = t3 b3 : 4 ≤ t3 t2 : ℝ hb2 : t3 - 1 = t2 t2p : 0 ≤ t2 t11 : ℝ hb11 : t2 ^ d * t3 - 1 = t11 t33 : ℝ hb33 : t11 * 4 = t33 b10 : 34.748 ≤ (1 - (t33 - 1)⁻¹) * t11 b2 : 3 ≤ 4 ^ (d - 1) - 1 b6 : 12 ≤ (4 ^ (d - 1) - 1) * 4 b11 : 35 ≤ (4 ^ (d - 1) - 1) ^ d * 4 ^ (d - 1) - 1 b33 : 140 ≤ ((4 ^ (d - 1) - 1) ^ d * 4 ^ (d - 1) - 1) * 4 ⊢ iter_error d c z ≤ 0.8095 / (Complex.abs z * (Complex.abs z).log)	Please generate a tactic in lean4 to solve the state. STATE: c✝ : ℂ d✝ : ℕ inst✝¹ : Fact (2 ≤ d✝) d : ℕ inst✝ : Fact (2 ≤ d) c z : ℂ z4 : 4 ≤ Complex.abs z cz : Complex.abs c ≤ Complex.abs z t3 : ℝ hb3 : 4 ^ (d - 1) = t3 b3 : 4 ≤ t3 t2 : ℝ hb2 : t3 - 1 = t2 b2 : 3 ≤ t2 t2p : 0 ≤ t2 b6 : 12 ≤ t2 * 4 t11 : ℝ hb11 : t2 ^ d * t3 - 1 = t11 b11 : 35 ≤ t11 t33 : ℝ hb33 : t11 * 4 = t33 b33 : 140 ≤ t33 b10 : 34.748 ≤ (1 - (t33 - 1)⁻¹) * t11 ⊢ iter_error d c z ≤ 0.8095 / (Complex.abs z * (Complex.abs z).log) TACTIC:
https://github.com/girving/ray.git	0be790285dd0fce78913b0cb9bddaffa94bd25f9	Ray/Dynamics/Multibrot/Iterates.lean	iter_error_le_of_z4	[381, 1]	[416, 81]	refine iter_error_le _ (by norm_num) (by norm_num) (by norm_num) (bs0 := f_error_le_of_z4 d) (bs1 := fun {_} bz ↦ f_error_le_of_z12 d (le_trans b6 bz)) (bs2 := fun {_} bz ↦ f_error_le_of_z140 d (le_trans b33 bz)) (le_trans (by norm_num) b11) (le_trans (by norm_num) b33) (by positivity) ?_ ?_ z4 cz	c✝ : ℂ d✝ : ℕ inst✝¹ : Fact (2 ≤ d✝) d : ℕ inst✝ : Fact (2 ≤ d) c z : ℂ z4 : 4 ≤ Complex.abs z cz : Complex.abs c ≤ Complex.abs z t3 : ℝ hb3 : 4 ^ (d - 1) = t3 b3 : 4 ≤ t3 t2 : ℝ hb2 : t3 - 1 = t2 t2p : 0 ≤ t2 t11 : ℝ hb11 : t2 ^ d * t3 - 1 = t11 t33 : ℝ hb33 : t11 * 4 = t33 b10 : 34.748 ≤ (1 - (t33 - 1)⁻¹) * t11 b2 : 3 ≤ 4 ^ (d - 1) - 1 b6 : 12 ≤ (4 ^ (d - 1) - 1) * 4 b11 : 35 ≤ (4 ^ (d - 1) - 1) ^ d * 4 ^ (d - 1) - 1 b33 : 140 ≤ ((4 ^ (d - 1) - 1) ^ d * 4 ^ (d - 1) - 1) * 4 ⊢ iter_error d c z ≤ 0.8095 / (Complex.abs z * (Complex.abs z).log)	case refine_1 c✝ : ℂ d✝ : ℕ inst✝¹ : Fact (2 ≤ d✝) d : ℕ inst✝ : Fact (2 ≤ d) c z : ℂ z4 : 4 ≤ Complex.abs z cz : Complex.abs c ≤ Complex.abs z t3 : ℝ hb3 : 4 ^ (d - 1) = t3 b3 : 4 ≤ t3 t2 : ℝ hb2 : t3 - 1 = t2 t2p : 0 ≤ t2 t11 : ℝ hb11 : t2 ^ d * t3 - 1 = t11 t33 : ℝ hb33 : t11 * 4 = t33 b10 : 34.748 ≤ (1 - (t33 - 1)⁻¹) * t11 b2 : 3 ≤ 4 ^ (d - 1) - 1 b6 : 12 ≤ (4 ^ (d - 1) - 1) * 4 b11 : 35 ≤ (4 ^ (d - 1) - 1) ^ d * 4 ^ (d - 1) - 1 b33 : 140 ≤ ((4 ^ (d - 1) - 1) ^ d * 4 ^ (d - 1) - 1) * 4 ⊢ 0 < 1 - (((4 ^ (d - 1) - 1) ^ d * 4 ^ (d - 1) - 1) * 4 - 1)⁻¹ case refine_2 c✝ : ℂ d✝ : ℕ inst✝¹ : Fact (2 ≤ d✝) d : ℕ inst✝ : Fact (2 ≤ d) c z : ℂ z4 : 4 ≤ Complex.abs z cz : Complex.abs c ≤ Complex.abs z t3 : ℝ hb3 : 4 ^ (d - 1) = t3 b3 : 4 ≤ t3 t2 : ℝ hb2 : t3 - 1 = t2 t2p : 0 ≤ t2 t11 : ℝ hb11 : t2 ^ d * t3 - 1 = t11 t33 : ℝ hb33 : t11 * 4 = t33 b10 : 34.748 ≤ (1 - (t33 - 1)⁻¹) * t11 b2 : 3 ≤ 4 ^ (d - 1) - 1 b6 : 12 ≤ (4 ^ (d - 1) - 1) * 4 b11 : 35 ≤ (4 ^ (d - 1) - 1) ^ d * 4 ^ (d - 1) - 1 b33 : 140 ≤ ((4 ^ (d - 1) - 1) ^ d * 4 ^ (d - 1) - 1) * 4 ⊢ 0.619 + 0.528 / (4 ^ (d - 1) - 1) + 0.5023 / ((1 - (((4 ^ (d - 1) - 1) ^ d * 4 ^ (d - 1) - 1) * 4 - 1)⁻¹) * ((4 ^ (d - 1) - 1) ^ d * 4 ^ (d - 1) - 1)) ≤ 0.8095	Please generate a tactic in lean4 to solve the state. STATE: c✝ : ℂ d✝ : ℕ inst✝¹ : Fact (2 ≤ d✝) d : ℕ inst✝ : Fact (2 ≤ d) c z : ℂ z4 : 4 ≤ Complex.abs z cz : Complex.abs c ≤ Complex.abs z t3 : ℝ hb3 : 4 ^ (d - 1) = t3 b3 : 4 ≤ t3 t2 : ℝ hb2 : t3 - 1 = t2 t2p : 0 ≤ t2 t11 : ℝ hb11 : t2 ^ d * t3 - 1 = t11 t33 : ℝ hb33 : t11 * 4 = t33 b10 : 34.748 ≤ (1 - (t33 - 1)⁻¹) * t11 b2 : 3 ≤ 4 ^ (d - 1) - 1 b6 : 12 ≤ (4 ^ (d - 1) - 1) * 4 b11 : 35 ≤ (4 ^ (d - 1) - 1) ^ d * 4 ^ (d - 1) - 1 b33 : 140 ≤ ((4 ^ (d - 1) - 1) ^ d * 4 ^ (d - 1) - 1) * 4 ⊢ iter_error d c z ≤ 0.8095 / (Complex.abs z * (Complex.abs z).log) TACTIC:
https://github.com/girving/ray.git	0be790285dd0fce78913b0cb9bddaffa94bd25f9	Ray/Dynamics/Multibrot/Iterates.lean	iter_error_le_of_z4	[381, 1]	[416, 81]	calc (4:ℝ)^(d-1) _ ≥ 4^(2-1) := by bound _ = 4 := by norm_num	c✝ : ℂ d✝ : ℕ inst✝¹ : Fact (2 ≤ d✝) d : ℕ inst✝ : Fact (2 ≤ d) c z : ℂ z4 : 4 ≤ Complex.abs z cz : Complex.abs c ≤ Complex.abs z ⊢ 4 ≤ 4 ^ (d - 1)	no goals	Please generate a tactic in lean4 to solve the state. STATE: c✝ : ℂ d✝ : ℕ inst✝¹ : Fact (2 ≤ d✝) d : ℕ inst✝ : Fact (2 ≤ d) c z : ℂ z4 : 4 ≤ Complex.abs z cz : Complex.abs c ≤ Complex.abs z ⊢ 4 ≤ 4 ^ (d - 1) TACTIC:
https://github.com/girving/ray.git	0be790285dd0fce78913b0cb9bddaffa94bd25f9	Ray/Dynamics/Multibrot/Iterates.lean	iter_error_le_of_z4	[381, 1]	[416, 81]	bound	c✝ : ℂ d✝ : ℕ inst✝¹ : Fact (2 ≤ d✝) d : ℕ inst✝ : Fact (2 ≤ d) c z : ℂ z4 : 4 ≤ Complex.abs z cz : Complex.abs c ≤ Complex.abs z ⊢ 4 ^ (d - 1) ≥ 4 ^ (2 - 1)	no goals	Please generate a tactic in lean4 to solve the state. STATE: c✝ : ℂ d✝ : ℕ inst✝¹ : Fact (2 ≤ d✝) d : ℕ inst✝ : Fact (2 ≤ d) c z : ℂ z4 : 4 ≤ Complex.abs z cz : Complex.abs c ≤ Complex.abs z ⊢ 4 ^ (d - 1) ≥ 4 ^ (2 - 1) TACTIC:
https://github.com/girving/ray.git	0be790285dd0fce78913b0cb9bddaffa94bd25f9	Ray/Dynamics/Multibrot/Iterates.lean	iter_error_le_of_z4	[381, 1]	[416, 81]	norm_num	c✝ : ℂ d✝ : ℕ inst✝¹ : Fact (2 ≤ d✝) d : ℕ inst✝ : Fact (2 ≤ d) c z : ℂ z4 : 4 ≤ Complex.abs z cz : Complex.abs c ≤ Complex.abs z ⊢ 4 ^ (2 - 1) = 4	no goals	Please generate a tactic in lean4 to solve the state. STATE: c✝ : ℂ d✝ : ℕ inst✝¹ : Fact (2 ≤ d✝) d : ℕ inst✝ : Fact (2 ≤ d) c z : ℂ z4 : 4 ≤ Complex.abs z cz : Complex.abs c ≤ Complex.abs z ⊢ 4 ^ (2 - 1) = 4 TACTIC:
https://github.com/girving/ray.git	0be790285dd0fce78913b0cb9bddaffa94bd25f9	Ray/Dynamics/Multibrot/Iterates.lean	iter_error_le_of_z4	[381, 1]	[416, 81]	linarith	c✝ : ℂ d✝ : ℕ inst✝¹ : Fact (2 ≤ d✝) d : ℕ inst✝ : Fact (2 ≤ d) c z : ℂ z4 : 4 ≤ Complex.abs z cz : Complex.abs c ≤ Complex.abs z t3 : ℝ hb3 : 4 ^ (d - 1) = t3 b3 : 4 ≤ t3 ⊢ 3 ≤ t3 - 1	no goals	Please generate a tactic in lean4 to solve the state. STATE: c✝ : ℂ d✝ : ℕ inst✝¹ : Fact (2 ≤ d✝) d : ℕ inst✝ : Fact (2 ≤ d) c z : ℂ z4 : 4 ≤ Complex.abs z cz : Complex.abs c ≤ Complex.abs z t3 : ℝ hb3 : 4 ^ (d - 1) = t3 b3 : 4 ≤ t3 ⊢ 3 ≤ t3 - 1 TACTIC:
https://github.com/girving/ray.git	0be790285dd0fce78913b0cb9bddaffa94bd25f9	Ray/Dynamics/Multibrot/Iterates.lean	iter_error_le_of_z4	[381, 1]	[416, 81]	positivity	c✝ : ℂ d✝ : ℕ inst✝¹ : Fact (2 ≤ d✝) d : ℕ inst✝ : Fact (2 ≤ d) c z : ℂ z4 : 4 ≤ Complex.abs z cz : Complex.abs c ≤ Complex.abs z t3 : ℝ hb3 : 4 ^ (d - 1) = t3 b3 : 4 ≤ t3 t2 : ℝ hb2 : t3 - 1 = t2 b2 : 3 ≤ t2 ⊢ 0 ≤ t2	no goals	Please generate a tactic in lean4 to solve the state. STATE: c✝ : ℂ d✝ : ℕ inst✝¹ : Fact (2 ≤ d✝) d : ℕ inst✝ : Fact (2 ≤ d) c z : ℂ z4 : 4 ≤ Complex.abs z cz : Complex.abs c ≤ Complex.abs z t3 : ℝ hb3 : 4 ^ (d - 1) = t3 b3 : 4 ≤ t3 t2 : ℝ hb2 : t3 - 1 = t2 b2 : 3 ≤ t2 ⊢ 0 ≤ t2 TACTIC:
https://github.com/girving/ray.git	0be790285dd0fce78913b0cb9bddaffa94bd25f9	Ray/Dynamics/Multibrot/Iterates.lean	iter_error_le_of_z4	[381, 1]	[416, 81]	linarith	c✝ : ℂ d✝ : ℕ inst✝¹ : Fact (2 ≤ d✝) d : ℕ inst✝ : Fact (2 ≤ d) c z : ℂ z4 : 4 ≤ Complex.abs z cz : Complex.abs c ≤ Complex.abs z t3 : ℝ hb3 : 4 ^ (d - 1) = t3 b3 : 4 ≤ t3 t2 : ℝ hb2 : t3 - 1 = t2 b2 : 3 ≤ t2 t2p : 0 ≤ t2 ⊢ 12 ≤ t2 * 4	no goals	Please generate a tactic in lean4 to solve the state. STATE: c✝ : ℂ d✝ : ℕ inst✝¹ : Fact (2 ≤ d✝) d : ℕ inst✝ : Fact (2 ≤ d) c z : ℂ z4 : 4 ≤ Complex.abs z cz : Complex.abs c ≤ Complex.abs z t3 : ℝ hb3 : 4 ^ (d - 1) = t3 b3 : 4 ≤ t3 t2 : ℝ hb2 : t3 - 1 = t2 b2 : 3 ≤ t2 t2p : 0 ≤ t2 ⊢ 12 ≤ t2 * 4 TACTIC:
https://github.com/girving/ray.git	0be790285dd0fce78913b0cb9bddaffa94bd25f9	Ray/Dynamics/Multibrot/Iterates.lean	iter_error_le_of_z4	[381, 1]	[416, 81]	calc t2^d * t3 - 1 _ ≥ 3^d * 4 - 1 := by bound _ ≥ 3^2 * 4 - 1 := by bound _ = 35 := by norm_num	c✝ : ℂ d✝ : ℕ inst✝¹ : Fact (2 ≤ d✝) d : ℕ inst✝ : Fact (2 ≤ d) c z : ℂ z4 : 4 ≤ Complex.abs z cz : Complex.abs c ≤ Complex.abs z t3 : ℝ hb3 : 4 ^ (d - 1) = t3 b3 : 4 ≤ t3 t2 : ℝ hb2 : t3 - 1 = t2 b2 : 3 ≤ t2 t2p : 0 ≤ t2 b6 : 12 ≤ t2 * 4 ⊢ 35 ≤ t2 ^ d * t3 - 1	no goals	Please generate a tactic in lean4 to solve the state. STATE: c✝ : ℂ d✝ : ℕ inst✝¹ : Fact (2 ≤ d✝) d : ℕ inst✝ : Fact (2 ≤ d) c z : ℂ z4 : 4 ≤ Complex.abs z cz : Complex.abs c ≤ Complex.abs z t3 : ℝ hb3 : 4 ^ (d - 1) = t3 b3 : 4 ≤ t3 t2 : ℝ hb2 : t3 - 1 = t2 b2 : 3 ≤ t2 t2p : 0 ≤ t2 b6 : 12 ≤ t2 * 4 ⊢ 35 ≤ t2 ^ d * t3 - 1 TACTIC:
https://github.com/girving/ray.git	0be790285dd0fce78913b0cb9bddaffa94bd25f9	Ray/Dynamics/Multibrot/Iterates.lean	iter_error_le_of_z4	[381, 1]	[416, 81]	bound	c✝ : ℂ d✝ : ℕ inst✝¹ : Fact (2 ≤ d✝) d : ℕ inst✝ : Fact (2 ≤ d) c z : ℂ z4 : 4 ≤ Complex.abs z cz : Complex.abs c ≤ Complex.abs z t3 : ℝ hb3 : 4 ^ (d - 1) = t3 b3 : 4 ≤ t3 t2 : ℝ hb2 : t3 - 1 = t2 b2 : 3 ≤ t2 t2p : 0 ≤ t2 b6 : 12 ≤ t2 * 4 ⊢ t2 ^ d * t3 - 1 ≥ 3 ^ d * 4 - 1	no goals	Please generate a tactic in lean4 to solve the state. STATE: c✝ : ℂ d✝ : ℕ inst✝¹ : Fact (2 ≤ d✝) d : ℕ inst✝ : Fact (2 ≤ d) c z : ℂ z4 : 4 ≤ Complex.abs z cz : Complex.abs c ≤ Complex.abs z t3 : ℝ hb3 : 4 ^ (d - 1) = t3 b3 : 4 ≤ t3 t2 : ℝ hb2 : t3 - 1 = t2 b2 : 3 ≤ t2 t2p : 0 ≤ t2 b6 : 12 ≤ t2 * 4 ⊢ t2 ^ d * t3 - 1 ≥ 3 ^ d * 4 - 1 TACTIC:
https://github.com/girving/ray.git	0be790285dd0fce78913b0cb9bddaffa94bd25f9	Ray/Dynamics/Multibrot/Iterates.lean	iter_error_le_of_z4	[381, 1]	[416, 81]	bound	c✝ : ℂ d✝ : ℕ inst✝¹ : Fact (2 ≤ d✝) d : ℕ inst✝ : Fact (2 ≤ d) c z : ℂ z4 : 4 ≤ Complex.abs z cz : Complex.abs c ≤ Complex.abs z t3 : ℝ hb3 : 4 ^ (d - 1) = t3 b3 : 4 ≤ t3 t2 : ℝ hb2 : t3 - 1 = t2 b2 : 3 ≤ t2 t2p : 0 ≤ t2 b6 : 12 ≤ t2 * 4 ⊢ 3 ^ d * 4 - 1 ≥ 3 ^ 2 * 4 - 1	no goals	Please generate a tactic in lean4 to solve the state. STATE: c✝ : ℂ d✝ : ℕ inst✝¹ : Fact (2 ≤ d✝) d : ℕ inst✝ : Fact (2 ≤ d) c z : ℂ z4 : 4 ≤ Complex.abs z cz : Complex.abs c ≤ Complex.abs z t3 : ℝ hb3 : 4 ^ (d - 1) = t3 b3 : 4 ≤ t3 t2 : ℝ hb2 : t3 - 1 = t2 b2 : 3 ≤ t2 t2p : 0 ≤ t2 b6 : 12 ≤ t2 * 4 ⊢ 3 ^ d * 4 - 1 ≥ 3 ^ 2 * 4 - 1 TACTIC:
https://github.com/girving/ray.git	0be790285dd0fce78913b0cb9bddaffa94bd25f9	Ray/Dynamics/Multibrot/Iterates.lean	iter_error_le_of_z4	[381, 1]	[416, 81]	norm_num	c✝ : ℂ d✝ : ℕ inst✝¹ : Fact (2 ≤ d✝) d : ℕ inst✝ : Fact (2 ≤ d) c z : ℂ z4 : 4 ≤ Complex.abs z cz : Complex.abs c ≤ Complex.abs z t3 : ℝ hb3 : 4 ^ (d - 1) = t3 b3 : 4 ≤ t3 t2 : ℝ hb2 : t3 - 1 = t2 b2 : 3 ≤ t2 t2p : 0 ≤ t2 b6 : 12 ≤ t2 * 4 ⊢ 3 ^ 2 * 4 - 1 = 35	no goals	Please generate a tactic in lean4 to solve the state. STATE: c✝ : ℂ d✝ : ℕ inst✝¹ : Fact (2 ≤ d✝) d : ℕ inst✝ : Fact (2 ≤ d) c z : ℂ z4 : 4 ≤ Complex.abs z cz : Complex.abs c ≤ Complex.abs z t3 : ℝ hb3 : 4 ^ (d - 1) = t3 b3 : 4 ≤ t3 t2 : ℝ hb2 : t3 - 1 = t2 b2 : 3 ≤ t2 t2p : 0 ≤ t2 b6 : 12 ≤ t2 * 4 ⊢ 3 ^ 2 * 4 - 1 = 35 TACTIC:
https://github.com/girving/ray.git	0be790285dd0fce78913b0cb9bddaffa94bd25f9	Ray/Dynamics/Multibrot/Iterates.lean	iter_error_le_of_z4	[381, 1]	[416, 81]	linarith	c✝ : ℂ d✝ : ℕ inst✝¹ : Fact (2 ≤ d✝) d : ℕ inst✝ : Fact (2 ≤ d) c z : ℂ z4 : 4 ≤ Complex.abs z cz : Complex.abs c ≤ Complex.abs z t3 : ℝ hb3 : 4 ^ (d - 1) = t3 b3 : 4 ≤ t3 t2 : ℝ hb2 : t3 - 1 = t2 b2 : 3 ≤ t2 t2p : 0 ≤ t2 b6 : 12 ≤ t2 * 4 t11 : ℝ hb11 : t2 ^ d * t3 - 1 = t11 b11 : 35 ≤ t11 ⊢ 140 ≤ t11 * 4	no goals	Please generate a tactic in lean4 to solve the state. STATE: c✝ : ℂ d✝ : ℕ inst✝¹ : Fact (2 ≤ d✝) d : ℕ inst✝ : Fact (2 ≤ d) c z : ℂ z4 : 4 ≤ Complex.abs z cz : Complex.abs c ≤ Complex.abs z t3 : ℝ hb3 : 4 ^ (d - 1) = t3 b3 : 4 ≤ t3 t2 : ℝ hb2 : t3 - 1 = t2 b2 : 3 ≤ t2 t2p : 0 ≤ t2 b6 : 12 ≤ t2 * 4 t11 : ℝ hb11 : t2 ^ d * t3 - 1 = t11 b11 : 35 ≤ t11 ⊢ 140 ≤ t11 * 4 TACTIC:
https://github.com/girving/ray.git	0be790285dd0fce78913b0cb9bddaffa94bd25f9	Ray/Dynamics/Multibrot/Iterates.lean	iter_error_le_of_z4	[381, 1]	[416, 81]	have h : 1 ≤ t33 - 1 := by linarith	c✝ : ℂ d✝ : ℕ inst✝¹ : Fact (2 ≤ d✝) d : ℕ inst✝ : Fact (2 ≤ d) c z : ℂ z4 : 4 ≤ Complex.abs z cz : Complex.abs c ≤ Complex.abs z t3 : ℝ hb3 : 4 ^ (d - 1) = t3 b3 : 4 ≤ t3 t2 : ℝ hb2 : t3 - 1 = t2 b2 : 3 ≤ t2 t2p : 0 ≤ t2 b6 : 12 ≤ t2 * 4 t11 : ℝ hb11 : t2 ^ d * t3 - 1 = t11 b11 : 35 ≤ t11 t33 : ℝ hb33 : t11 * 4 = t33 b33 : 140 ≤ t33 ⊢ 34.748 ≤ (1 - (t33 - 1)⁻¹) * t11	c✝ : ℂ d✝ : ℕ inst✝¹ : Fact (2 ≤ d✝) d : ℕ inst✝ : Fact (2 ≤ d) c z : ℂ z4 : 4 ≤ Complex.abs z cz : Complex.abs c ≤ Complex.abs z t3 : ℝ hb3 : 4 ^ (d - 1) = t3 b3 : 4 ≤ t3 t2 : ℝ hb2 : t3 - 1 = t2 b2 : 3 ≤ t2 t2p : 0 ≤ t2 b6 : 12 ≤ t2 * 4 t11 : ℝ hb11 : t2 ^ d * t3 - 1 = t11 b11 : 35 ≤ t11 t33 : ℝ hb33 : t11 * 4 = t33 b33 : 140 ≤ t33 h : 1 ≤ t33 - 1 ⊢ 34.748 ≤ (1 - (t33 - 1)⁻¹) * t11	Please generate a tactic in lean4 to solve the state. STATE: c✝ : ℂ d✝ : ℕ inst✝¹ : Fact (2 ≤ d✝) d : ℕ inst✝ : Fact (2 ≤ d) c z : ℂ z4 : 4 ≤ Complex.abs z cz : Complex.abs c ≤ Complex.abs z t3 : ℝ hb3 : 4 ^ (d - 1) = t3 b3 : 4 ≤ t3 t2 : ℝ hb2 : t3 - 1 = t2 b2 : 3 ≤ t2 t2p : 0 ≤ t2 b6 : 12 ≤ t2 * 4 t11 : ℝ hb11 : t2 ^ d * t3 - 1 = t11 b11 : 35 ≤ t11 t33 : ℝ hb33 : t11 * 4 = t33 b33 : 140 ≤ t33 ⊢ 34.748 ≤ (1 - (t33 - 1)⁻¹) * t11 TACTIC:

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