pkuAI4M/lean_github · Datasets at Hugging Face

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/Potential.lean	iter_error_le_log_log_abs	[245, 1]	[259, 83]	positivity	c✝ z✝ : 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 hl : 1.38 ≤ (Complex.abs z).log hll : 0.32 ≤ (Complex.abs z).log.log ⊢ 0 ≤ 1.38	no goals	Please generate a tactic in lean4 to solve the state. STATE: c✝ z✝ : 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 hl : 1.38 ≤ (Complex.abs z).log hll : 0.32 ≤ (Complex.abs z).log.log ⊢ 0 ≤ 1.38 TACTIC:
https://github.com/girving/ray.git	0be790285dd0fce78913b0cb9bddaffa94bd25f9	Ray/Dynamics/Multibrot/Potential.lean	iter_error_le_log_log_abs	[245, 1]	[259, 83]	positivity	c✝ z✝ : 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 hl : 1.38 ≤ (Complex.abs z).log hll : 0.32 ≤ (Complex.abs z).log.log ⊢ 0 ≤ Complex.abs z	no goals	Please generate a tactic in lean4 to solve the state. STATE: c✝ z✝ : 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 hl : 1.38 ≤ (Complex.abs z).log hll : 0.32 ≤ (Complex.abs z).log.log ⊢ 0 ≤ Complex.abs z TACTIC:
https://github.com/girving/ray.git	0be790285dd0fce78913b0cb9bddaffa94bd25f9	Ray/Dynamics/Multibrot/Potential.lean	potential_approx	[262, 1]	[295, 40]	set s := superF d	c✝ z✝ : 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 ⊢ \|⋯.potential c ↑z - 1 / Complex.abs z\| ≤ potential_error d c z	c✝ z✝ : 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 s : Super (f d) d OnePoint.infty := superF d ⊢ \|s.potential c ↑z - 1 / Complex.abs z\| ≤ potential_error d c z	Please generate a tactic in lean4 to solve the state. STATE: c✝ z✝ : 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 ⊢ \|⋯.potential c ↑z - 1 / Complex.abs z\| ≤ potential_error d c z TACTIC:
https://github.com/girving/ray.git	0be790285dd0fce78913b0cb9bddaffa94bd25f9	Ray/Dynamics/Multibrot/Potential.lean	potential_approx	[262, 1]	[295, 40]	have z3 : 3 ≤ abs z := le_trans (by norm_num) z4	c✝ z✝ : 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 s : Super (f d) d OnePoint.infty := superF d ⊢ \|s.potential c ↑z - 1 / Complex.abs z\| ≤ potential_error d c z	c✝ z✝ : 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 s : Super (f d) d OnePoint.infty := superF d z3 : 3 ≤ Complex.abs z ⊢ \|s.potential c ↑z - 1 / Complex.abs z\| ≤ potential_error d c z	Please generate a tactic in lean4 to solve the state. STATE: c✝ z✝ : 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 s : Super (f d) d OnePoint.infty := superF d ⊢ \|s.potential c ↑z - 1 / Complex.abs z\| ≤ potential_error d c z TACTIC:
https://github.com/girving/ray.git	0be790285dd0fce78913b0cb9bddaffa94bd25f9	Ray/Dynamics/Multibrot/Potential.lean	potential_approx	[262, 1]	[295, 40]	have z0 : 0 < abs z := lt_of_lt_of_le (by norm_num) z3	c✝ z✝ : 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 s : Super (f d) d OnePoint.infty := superF d z3 : 3 ≤ Complex.abs z ⊢ \|s.potential c ↑z - 1 / Complex.abs z\| ≤ potential_error d c z	c✝ z✝ : 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 s : Super (f d) d OnePoint.infty := superF d z3 : 3 ≤ Complex.abs z z0 : 0 < Complex.abs z ⊢ \|s.potential c ↑z - 1 / Complex.abs z\| ≤ potential_error d c z	Please generate a tactic in lean4 to solve the state. STATE: c✝ z✝ : 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 s : Super (f d) d OnePoint.infty := superF d z3 : 3 ≤ Complex.abs z ⊢ \|s.potential c ↑z - 1 / Complex.abs z\| ≤ potential_error d c z TACTIC:
https://github.com/girving/ray.git	0be790285dd0fce78913b0cb9bddaffa94bd25f9	Ray/Dynamics/Multibrot/Potential.lean	potential_approx	[262, 1]	[295, 40]	have l2 : 0 < log (abs z) := Real.log_pos (by linarith)	c✝ z✝ : 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 s : Super (f d) d OnePoint.infty := superF d z3 : 3 ≤ Complex.abs z z0 : 0 < Complex.abs z ⊢ \|s.potential c ↑z - 1 / Complex.abs z\| ≤ potential_error d c z	c✝ z✝ : 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 s : Super (f d) d OnePoint.infty := superF d z3 : 3 ≤ Complex.abs z z0 : 0 < Complex.abs z l2 : 0 < (Complex.abs z).log ⊢ \|s.potential c ↑z - 1 / Complex.abs z\| ≤ potential_error d c z	Please generate a tactic in lean4 to solve the state. STATE: c✝ z✝ : 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 s : Super (f d) d OnePoint.infty := superF d z3 : 3 ≤ Complex.abs z z0 : 0 < Complex.abs z ⊢ \|s.potential c ↑z - 1 / Complex.abs z\| ≤ potential_error d c z TACTIC:
https://github.com/girving/ray.git	0be790285dd0fce78913b0cb9bddaffa94bd25f9	Ray/Dynamics/Multibrot/Potential.lean	potential_approx	[262, 1]	[295, 40]	have h := log_neg_log_potential_approx d z3 cz	c✝ z✝ : 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 s : Super (f d) d OnePoint.infty := superF d z3 : 3 ≤ Complex.abs z z0 : 0 < Complex.abs z l2 : 0 < (Complex.abs z).log ⊢ \|s.potential c ↑z - 1 / Complex.abs z\| ≤ potential_error d c z	c✝ z✝ : 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 s : Super (f d) d OnePoint.infty := superF d z3 : 3 ≤ Complex.abs z z0 : 0 < Complex.abs z l2 : 0 < (Complex.abs z).log h : \|(-(⋯.potential c ↑z).log).log - (Complex.abs z).log.log\| ≤ iter_error d c z ⊢ \|s.potential c ↑z - 1 / Complex.abs z\| ≤ potential_error d c z	Please generate a tactic in lean4 to solve the state. STATE: c✝ z✝ : 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 s : Super (f d) d OnePoint.infty := superF d z3 : 3 ≤ Complex.abs z z0 : 0 < Complex.abs z l2 : 0 < (Complex.abs z).log ⊢ \|s.potential c ↑z - 1 / Complex.abs z\| ≤ potential_error d c z TACTIC:
https://github.com/girving/ray.git	0be790285dd0fce78913b0cb9bddaffa94bd25f9	Ray/Dynamics/Multibrot/Potential.lean	potential_approx	[262, 1]	[295, 40]	have p0 : 0 < s.potential c z := potential_pos	c✝ z✝ : 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 s : Super (f d) d OnePoint.infty := superF d z3 : 3 ≤ Complex.abs z z0 : 0 < Complex.abs z l2 : 0 < (Complex.abs z).log h : \|(-(⋯.potential c ↑z).log).log - (Complex.abs z).log.log\| ≤ iter_error d c z ⊢ \|s.potential c ↑z - 1 / Complex.abs z\| ≤ potential_error d c z	c✝ z✝ : 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 s : Super (f d) d OnePoint.infty := superF d z3 : 3 ≤ Complex.abs z z0 : 0 < Complex.abs z l2 : 0 < (Complex.abs z).log h : \|(-(⋯.potential c ↑z).log).log - (Complex.abs z).log.log\| ≤ iter_error d c z p0 : 0 < s.potential c ↑z ⊢ \|s.potential c ↑z - 1 / Complex.abs z\| ≤ potential_error d c z	Please generate a tactic in lean4 to solve the state. STATE: c✝ z✝ : 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 s : Super (f d) d OnePoint.infty := superF d z3 : 3 ≤ Complex.abs z z0 : 0 < Complex.abs z l2 : 0 < (Complex.abs z).log h : \|(-(⋯.potential c ↑z).log).log - (Complex.abs z).log.log\| ≤ iter_error d c z ⊢ \|s.potential c ↑z - 1 / Complex.abs z\| ≤ potential_error d c z TACTIC:
https://github.com/girving/ray.git	0be790285dd0fce78913b0cb9bddaffa94bd25f9	Ray/Dynamics/Multibrot/Potential.lean	potential_approx	[262, 1]	[295, 40]	have lp0 : 0 < -log (s.potential c z) := neg_pos.mpr (Real.log_neg p0 (potential_lt_one_of_two_lt (by linarith) cz))	c✝ z✝ : 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 s : Super (f d) d OnePoint.infty := superF d z3 : 3 ≤ Complex.abs z z0 : 0 < Complex.abs z l2 : 0 < (Complex.abs z).log h : \|(-(⋯.potential c ↑z).log).log - (Complex.abs z).log.log\| ≤ iter_error d c z p0 : 0 < s.potential c ↑z ⊢ \|s.potential c ↑z - 1 / Complex.abs z\| ≤ potential_error d c z	c✝ z✝ : 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 s : Super (f d) d OnePoint.infty := superF d z3 : 3 ≤ Complex.abs z z0 : 0 < Complex.abs z l2 : 0 < (Complex.abs z).log h : \|(-(⋯.potential c ↑z).log).log - (Complex.abs z).log.log\| ≤ iter_error d c z p0 : 0 < s.potential c ↑z lp0 : 0 < -(s.potential c ↑z).log ⊢ \|s.potential c ↑z - 1 / Complex.abs z\| ≤ potential_error d c z	Please generate a tactic in lean4 to solve the state. STATE: c✝ z✝ : 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 s : Super (f d) d OnePoint.infty := superF d z3 : 3 ≤ Complex.abs z z0 : 0 < Complex.abs z l2 : 0 < (Complex.abs z).log h : \|(-(⋯.potential c ↑z).log).log - (Complex.abs z).log.log\| ≤ iter_error d c z p0 : 0 < s.potential c ↑z ⊢ \|s.potential c ↑z - 1 / Complex.abs z\| ≤ potential_error d c z TACTIC:
https://github.com/girving/ray.git	0be790285dd0fce78913b0cb9bddaffa94bd25f9	Ray/Dynamics/Multibrot/Potential.lean	potential_approx	[262, 1]	[295, 40]	generalize s.potential c z = p at h p0 lp0	c✝ z✝ : 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 s : Super (f d) d OnePoint.infty := superF d z3 : 3 ≤ Complex.abs z z0 : 0 < Complex.abs z l2 : 0 < (Complex.abs z).log h : \|(-(⋯.potential c ↑z).log).log - (Complex.abs z).log.log\| ≤ iter_error d c z p0 : 0 < s.potential c ↑z lp0 : 0 < -(s.potential c ↑z).log ⊢ \|s.potential c ↑z - 1 / Complex.abs z\| ≤ potential_error d c z	c✝ z✝ : 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 s : Super (f d) d OnePoint.infty := superF d z3 : 3 ≤ Complex.abs z z0 : 0 < Complex.abs z l2 : 0 < (Complex.abs z).log p : ℝ h : \|(-p.log).log - (Complex.abs z).log.log\| ≤ iter_error d c z p0 : 0 < p lp0 : 0 < -p.log ⊢ \|p - 1 / Complex.abs z\| ≤ potential_error d c z	Please generate a tactic in lean4 to solve the state. STATE: c✝ z✝ : 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 s : Super (f d) d OnePoint.infty := superF d z3 : 3 ≤ Complex.abs z z0 : 0 < Complex.abs z l2 : 0 < (Complex.abs z).log h : \|(-(⋯.potential c ↑z).log).log - (Complex.abs z).log.log\| ≤ iter_error d c z p0 : 0 < s.potential c ↑z lp0 : 0 < -(s.potential c ↑z).log ⊢ \|s.potential c ↑z - 1 / Complex.abs z\| ≤ potential_error d c z TACTIC:
https://github.com/girving/ray.git	0be790285dd0fce78913b0cb9bddaffa94bd25f9	Ray/Dynamics/Multibrot/Potential.lean	potential_approx	[262, 1]	[295, 40]	generalize hr : iter_error d c z = r at h	c✝ z✝ : 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 s : Super (f d) d OnePoint.infty := superF d z3 : 3 ≤ Complex.abs z z0 : 0 < Complex.abs z l2 : 0 < (Complex.abs z).log p : ℝ h : \|(-p.log).log - (Complex.abs z).log.log\| ≤ iter_error d c z p0 : 0 < p lp0 : 0 < -p.log ⊢ \|p - 1 / Complex.abs z\| ≤ potential_error d c z	c✝ z✝ : 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 s : Super (f d) d OnePoint.infty := superF d z3 : 3 ≤ Complex.abs z z0 : 0 < Complex.abs z l2 : 0 < (Complex.abs z).log p : ℝ p0 : 0 < p lp0 : 0 < -p.log r : ℝ hr : iter_error d c z = r h : \|(-p.log).log - (Complex.abs z).log.log\| ≤ r ⊢ \|p - 1 / Complex.abs z\| ≤ potential_error d c z	Please generate a tactic in lean4 to solve the state. STATE: c✝ z✝ : 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 s : Super (f d) d OnePoint.infty := superF d z3 : 3 ≤ Complex.abs z z0 : 0 < Complex.abs z l2 : 0 < (Complex.abs z).log p : ℝ h : \|(-p.log).log - (Complex.abs z).log.log\| ≤ iter_error d c z p0 : 0 < p lp0 : 0 < -p.log ⊢ \|p - 1 / Complex.abs z\| ≤ potential_error d c z TACTIC:
https://github.com/girving/ray.git	0be790285dd0fce78913b0cb9bddaffa94bd25f9	Ray/Dynamics/Multibrot/Potential.lean	potential_approx	[262, 1]	[295, 40]	have r0 : 0 ≤ r := le_trans (abs_nonneg _) h	c✝ z✝ : 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 s : Super (f d) d OnePoint.infty := superF d z3 : 3 ≤ Complex.abs z z0 : 0 < Complex.abs z l2 : 0 < (Complex.abs z).log p : ℝ p0 : 0 < p lp0 : 0 < -p.log r : ℝ hr : iter_error d c z = r h : \|(-p.log).log - (Complex.abs z).log.log\| ≤ r ⊢ \|p - 1 / Complex.abs z\| ≤ potential_error d c z	c✝ z✝ : 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 s : Super (f d) d OnePoint.infty := superF d z3 : 3 ≤ Complex.abs z z0 : 0 < Complex.abs z l2 : 0 < (Complex.abs z).log p : ℝ p0 : 0 < p lp0 : 0 < -p.log r : ℝ hr : iter_error d c z = r h : \|(-p.log).log - (Complex.abs z).log.log\| ≤ r r0 : 0 ≤ r ⊢ \|p - 1 / Complex.abs z\| ≤ potential_error d c z	Please generate a tactic in lean4 to solve the state. STATE: c✝ z✝ : 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 s : Super (f d) d OnePoint.infty := superF d z3 : 3 ≤ Complex.abs z z0 : 0 < Complex.abs z l2 : 0 < (Complex.abs z).log p : ℝ p0 : 0 < p lp0 : 0 < -p.log r : ℝ hr : iter_error d c z = r h : \|(-p.log).log - (Complex.abs z).log.log\| ≤ r ⊢ \|p - 1 / Complex.abs z\| ≤ potential_error d c z TACTIC:
https://github.com/girving/ray.git	0be790285dd0fce78913b0cb9bddaffa94bd25f9	Ray/Dynamics/Multibrot/Potential.lean	potential_approx	[262, 1]	[295, 40]	set t := Ici (log (log (abs z)) - r)	c✝ z✝ : 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 s : Super (f d) d OnePoint.infty := superF d z3 : 3 ≤ Complex.abs z z0 : 0 < Complex.abs z l2 : 0 < (Complex.abs z).log p : ℝ p0 : 0 < p lp0 : 0 < -p.log r : ℝ hr : iter_error d c z = r h : \|(-p.log).log - (Complex.abs z).log.log\| ≤ r r0 : 0 ≤ r ⊢ \|p - 1 / Complex.abs z\| ≤ potential_error d c z	c✝ z✝ : 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 s : Super (f d) d OnePoint.infty := superF d z3 : 3 ≤ Complex.abs z z0 : 0 < Complex.abs z l2 : 0 < (Complex.abs z).log p : ℝ p0 : 0 < p lp0 : 0 < -p.log r : ℝ hr : iter_error d c z = r h : \|(-p.log).log - (Complex.abs z).log.log\| ≤ r r0 : 0 ≤ r t : Set ℝ := Ici ((Complex.abs z).log.log - r) ⊢ \|p - 1 / Complex.abs z\| ≤ potential_error d c z	Please generate a tactic in lean4 to solve the state. STATE: c✝ z✝ : 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 s : Super (f d) d OnePoint.infty := superF d z3 : 3 ≤ Complex.abs z z0 : 0 < Complex.abs z l2 : 0 < (Complex.abs z).log p : ℝ p0 : 0 < p lp0 : 0 < -p.log r : ℝ hr : iter_error d c z = r h : \|(-p.log).log - (Complex.abs z).log.log\| ≤ r r0 : 0 ≤ r ⊢ \|p - 1 / Complex.abs z\| ≤ potential_error d c z TACTIC:
https://github.com/girving/ray.git	0be790285dd0fce78913b0cb9bddaffa94bd25f9	Ray/Dynamics/Multibrot/Potential.lean	potential_approx	[262, 1]	[295, 40]	have yt : log (-log p) ∈ t := by simp only [abs_le, neg_le_sub_iff_le_add, tsub_le_iff_right, add_comm r] at h simp only [mem_Ici, tsub_le_iff_right, h, t]	c✝ z✝ : 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 s : Super (f d) d OnePoint.infty := superF d z3 : 3 ≤ Complex.abs z z0 : 0 < Complex.abs z l2 : 0 < (Complex.abs z).log p : ℝ p0 : 0 < p lp0 : 0 < -p.log r : ℝ hr : iter_error d c z = r h : \|(-p.log).log - (Complex.abs z).log.log\| ≤ r r0 : 0 ≤ r t : Set ℝ := Ici ((Complex.abs z).log.log - r) ⊢ \|p - 1 / Complex.abs z\| ≤ potential_error d c z	c✝ z✝ : 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 s : Super (f d) d OnePoint.infty := superF d z3 : 3 ≤ Complex.abs z z0 : 0 < Complex.abs z l2 : 0 < (Complex.abs z).log p : ℝ p0 : 0 < p lp0 : 0 < -p.log r : ℝ hr : iter_error d c z = r h : \|(-p.log).log - (Complex.abs z).log.log\| ≤ r r0 : 0 ≤ r t : Set ℝ := Ici ((Complex.abs z).log.log - r) yt : (-p.log).log ∈ t ⊢ \|p - 1 / Complex.abs z\| ≤ potential_error d c z	Please generate a tactic in lean4 to solve the state. STATE: c✝ z✝ : 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 s : Super (f d) d OnePoint.infty := superF d z3 : 3 ≤ Complex.abs z z0 : 0 < Complex.abs z l2 : 0 < (Complex.abs z).log p : ℝ p0 : 0 < p lp0 : 0 < -p.log r : ℝ hr : iter_error d c z = r h : \|(-p.log).log - (Complex.abs z).log.log\| ≤ r r0 : 0 ≤ r t : Set ℝ := Ici ((Complex.abs z).log.log - r) ⊢ \|p - 1 / Complex.abs z\| ≤ potential_error d c z TACTIC:
https://github.com/girving/ray.git	0be790285dd0fce78913b0cb9bddaffa94bd25f9	Ray/Dynamics/Multibrot/Potential.lean	potential_approx	[262, 1]	[295, 40]	have lt : log (log (abs z)) ∈ t := by simp only [mem_Ici, tsub_le_iff_right, le_add_iff_nonneg_right, r0, t]	c✝ z✝ : 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 s : Super (f d) d OnePoint.infty := superF d z3 : 3 ≤ Complex.abs z z0 : 0 < Complex.abs z l2 : 0 < (Complex.abs z).log p : ℝ p0 : 0 < p lp0 : 0 < -p.log r : ℝ hr : iter_error d c z = r h : \|(-p.log).log - (Complex.abs z).log.log\| ≤ r r0 : 0 ≤ r t : Set ℝ := Ici ((Complex.abs z).log.log - r) yt : (-p.log).log ∈ t ⊢ \|p - 1 / Complex.abs z\| ≤ potential_error d c z	c✝ z✝ : 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 s : Super (f d) d OnePoint.infty := superF d z3 : 3 ≤ Complex.abs z z0 : 0 < Complex.abs z l2 : 0 < (Complex.abs z).log p : ℝ p0 : 0 < p lp0 : 0 < -p.log r : ℝ hr : iter_error d c z = r h : \|(-p.log).log - (Complex.abs z).log.log\| ≤ r r0 : 0 ≤ r t : Set ℝ := Ici ((Complex.abs z).log.log - r) yt : (-p.log).log ∈ t lt : (Complex.abs z).log.log ∈ t ⊢ \|p - 1 / Complex.abs z\| ≤ potential_error d c z	Please generate a tactic in lean4 to solve the state. STATE: c✝ z✝ : 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 s : Super (f d) d OnePoint.infty := superF d z3 : 3 ≤ Complex.abs z z0 : 0 < Complex.abs z l2 : 0 < (Complex.abs z).log p : ℝ p0 : 0 < p lp0 : 0 < -p.log r : ℝ hr : iter_error d c z = r h : \|(-p.log).log - (Complex.abs z).log.log\| ≤ r r0 : 0 ≤ r t : Set ℝ := Ici ((Complex.abs z).log.log - r) yt : (-p.log).log ∈ t ⊢ \|p - 1 / Complex.abs z\| ≤ potential_error d c z TACTIC:
https://github.com/girving/ray.git	0be790285dd0fce78913b0cb9bddaffa94bd25f9	Ray/Dynamics/Multibrot/Potential.lean	potential_approx	[262, 1]	[295, 40]	generalize hb : dene (log (log (abs z)) - r) = b	c✝ z✝ : 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 s : Super (f d) d OnePoint.infty := superF d z3 : 3 ≤ Complex.abs z z0 : 0 < Complex.abs z l2 : 0 < (Complex.abs z).log p : ℝ p0 : 0 < p lp0 : 0 < -p.log r : ℝ hr : iter_error d c z = r h : \|(-p.log).log - (Complex.abs z).log.log\| ≤ r r0 : 0 ≤ r t : Set ℝ := Ici ((Complex.abs z).log.log - r) yt : (-p.log).log ∈ t lt : (Complex.abs z).log.log ∈ t ⊢ \|p - 1 / Complex.abs z\| ≤ potential_error d c z	c✝ z✝ : 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 s : Super (f d) d OnePoint.infty := superF d z3 : 3 ≤ Complex.abs z z0 : 0 < Complex.abs z l2 : 0 < (Complex.abs z).log p : ℝ p0 : 0 < p lp0 : 0 < -p.log r : ℝ hr : iter_error d c z = r h : \|(-p.log).log - (Complex.abs z).log.log\| ≤ r r0 : 0 ≤ r t : Set ℝ := Ici ((Complex.abs z).log.log - r) yt : (-p.log).log ∈ t lt : (Complex.abs z).log.log ∈ t b : ℝ hb : dene ((Complex.abs z).log.log - r) = b ⊢ \|p - 1 / Complex.abs z\| ≤ potential_error d c z	Please generate a tactic in lean4 to solve the state. STATE: c✝ z✝ : 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 s : Super (f d) d OnePoint.infty := superF d z3 : 3 ≤ Complex.abs z z0 : 0 < Complex.abs z l2 : 0 < (Complex.abs z).log p : ℝ p0 : 0 < p lp0 : 0 < -p.log r : ℝ hr : iter_error d c z = r h : \|(-p.log).log - (Complex.abs z).log.log\| ≤ r r0 : 0 ≤ r t : Set ℝ := Ici ((Complex.abs z).log.log - r) yt : (-p.log).log ∈ t lt : (Complex.abs z).log.log ∈ t ⊢ \|p - 1 / Complex.abs z\| ≤ potential_error d c z TACTIC:
https://github.com/girving/ray.git	0be790285dd0fce78913b0cb9bddaffa94bd25f9	Ray/Dynamics/Multibrot/Potential.lean	potential_approx	[262, 1]	[295, 40]	have b0 : 0 ≤ b := by rw [←hb]; exact dene_nonneg	c✝ z✝ : 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 s : Super (f d) d OnePoint.infty := superF d z3 : 3 ≤ Complex.abs z z0 : 0 < Complex.abs z l2 : 0 < (Complex.abs z).log p : ℝ p0 : 0 < p lp0 : 0 < -p.log r : ℝ hr : iter_error d c z = r h : \|(-p.log).log - (Complex.abs z).log.log\| ≤ r r0 : 0 ≤ r t : Set ℝ := Ici ((Complex.abs z).log.log - r) yt : (-p.log).log ∈ t lt : (Complex.abs z).log.log ∈ t b : ℝ hb : dene ((Complex.abs z).log.log - r) = b ⊢ \|p - 1 / Complex.abs z\| ≤ potential_error d c z	c✝ z✝ : 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 s : Super (f d) d OnePoint.infty := superF d z3 : 3 ≤ Complex.abs z z0 : 0 < Complex.abs z l2 : 0 < (Complex.abs z).log p : ℝ p0 : 0 < p lp0 : 0 < -p.log r : ℝ hr : iter_error d c z = r h : \|(-p.log).log - (Complex.abs z).log.log\| ≤ r r0 : 0 ≤ r t : Set ℝ := Ici ((Complex.abs z).log.log - r) yt : (-p.log).log ∈ t lt : (Complex.abs z).log.log ∈ t b : ℝ hb : dene ((Complex.abs z).log.log - r) = b b0 : 0 ≤ b ⊢ \|p - 1 / Complex.abs z\| ≤ potential_error d c z	Please generate a tactic in lean4 to solve the state. STATE: c✝ z✝ : 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 s : Super (f d) d OnePoint.infty := superF d z3 : 3 ≤ Complex.abs z z0 : 0 < Complex.abs z l2 : 0 < (Complex.abs z).log p : ℝ p0 : 0 < p lp0 : 0 < -p.log r : ℝ hr : iter_error d c z = r h : \|(-p.log).log - (Complex.abs z).log.log\| ≤ r r0 : 0 ≤ r t : Set ℝ := Ici ((Complex.abs z).log.log - r) yt : (-p.log).log ∈ t lt : (Complex.abs z).log.log ∈ t b : ℝ hb : dene ((Complex.abs z).log.log - r) = b ⊢ \|p - 1 / Complex.abs z\| ≤ potential_error d c z TACTIC:
https://github.com/girving/ray.git	0be790285dd0fce78913b0cb9bddaffa94bd25f9	Ray/Dynamics/Multibrot/Potential.lean	potential_approx	[262, 1]	[295, 40]	have bound : ∀ x, x ∈ t → ‖deriv ene x‖ ≤ b := by intro x m simp only [Real.dist_eq, mem_Ici, ←hr, t] at m simp only [deriv_ene, norm_neg, Real.norm_of_nonneg dene_nonneg, ←hb, ←hr] apply dene_anti (sub_nonneg.mpr (iter_error_le_log_log_abs d z4 cz)) m	c✝ z✝ : 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 s : Super (f d) d OnePoint.infty := superF d z3 : 3 ≤ Complex.abs z z0 : 0 < Complex.abs z l2 : 0 < (Complex.abs z).log p : ℝ p0 : 0 < p lp0 : 0 < -p.log r : ℝ hr : iter_error d c z = r h : \|(-p.log).log - (Complex.abs z).log.log\| ≤ r r0 : 0 ≤ r t : Set ℝ := Ici ((Complex.abs z).log.log - r) yt : (-p.log).log ∈ t lt : (Complex.abs z).log.log ∈ t b : ℝ hb : dene ((Complex.abs z).log.log - r) = b b0 : 0 ≤ b ⊢ \|p - 1 / Complex.abs z\| ≤ potential_error d c z	c✝ z✝ : 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 s : Super (f d) d OnePoint.infty := superF d z3 : 3 ≤ Complex.abs z z0 : 0 < Complex.abs z l2 : 0 < (Complex.abs z).log p : ℝ p0 : 0 < p lp0 : 0 < -p.log r : ℝ hr : iter_error d c z = r h : \|(-p.log).log - (Complex.abs z).log.log\| ≤ r r0 : 0 ≤ r t : Set ℝ := Ici ((Complex.abs z).log.log - r) yt : (-p.log).log ∈ t lt : (Complex.abs z).log.log ∈ t b : ℝ hb : dene ((Complex.abs z).log.log - r) = b b0 : 0 ≤ b bound : ∀ x ∈ t, ‖deriv ene x‖ ≤ b ⊢ \|p - 1 / Complex.abs z\| ≤ potential_error d c z	Please generate a tactic in lean4 to solve the state. STATE: c✝ z✝ : 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 s : Super (f d) d OnePoint.infty := superF d z3 : 3 ≤ Complex.abs z z0 : 0 < Complex.abs z l2 : 0 < (Complex.abs z).log p : ℝ p0 : 0 < p lp0 : 0 < -p.log r : ℝ hr : iter_error d c z = r h : \|(-p.log).log - (Complex.abs z).log.log\| ≤ r r0 : 0 ≤ r t : Set ℝ := Ici ((Complex.abs z).log.log - r) yt : (-p.log).log ∈ t lt : (Complex.abs z).log.log ∈ t b : ℝ hb : dene ((Complex.abs z).log.log - r) = b b0 : 0 ≤ b ⊢ \|p - 1 / Complex.abs z\| ≤ potential_error d c z TACTIC:
https://github.com/girving/ray.git	0be790285dd0fce78913b0cb9bddaffa94bd25f9	Ray/Dynamics/Multibrot/Potential.lean	potential_approx	[262, 1]	[295, 40]	have m := Convex.norm_image_sub_le_of_norm_deriv_le (fun x _ ↦ (hasDerivAt_ene x).differentiableAt) bound (convex_Ici _) lt yt	c✝ z✝ : 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 s : Super (f d) d OnePoint.infty := superF d z3 : 3 ≤ Complex.abs z z0 : 0 < Complex.abs z l2 : 0 < (Complex.abs z).log p : ℝ p0 : 0 < p lp0 : 0 < -p.log r : ℝ hr : iter_error d c z = r h : \|(-p.log).log - (Complex.abs z).log.log\| ≤ r r0 : 0 ≤ r t : Set ℝ := Ici ((Complex.abs z).log.log - r) yt : (-p.log).log ∈ t lt : (Complex.abs z).log.log ∈ t b : ℝ hb : dene ((Complex.abs z).log.log - r) = b b0 : 0 ≤ b bound : ∀ x ∈ t, ‖deriv ene x‖ ≤ b ⊢ \|p - 1 / Complex.abs z\| ≤ potential_error d c z	c✝ z✝ : 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 s : Super (f d) d OnePoint.infty := superF d z3 : 3 ≤ Complex.abs z z0 : 0 < Complex.abs z l2 : 0 < (Complex.abs z).log p : ℝ p0 : 0 < p lp0 : 0 < -p.log r : ℝ hr : iter_error d c z = r h : \|(-p.log).log - (Complex.abs z).log.log\| ≤ r r0 : 0 ≤ r t : Set ℝ := Ici ((Complex.abs z).log.log - r) yt : (-p.log).log ∈ t lt : (Complex.abs z).log.log ∈ t b : ℝ hb : dene ((Complex.abs z).log.log - r) = b b0 : 0 ≤ b bound : ∀ x ∈ t, ‖deriv ene x‖ ≤ b m : ‖ene (-p.log).log - ene (Complex.abs z).log.log‖ ≤ b * ‖(-p.log).log - (Complex.abs z).log.log‖ ⊢ \|p - 1 / Complex.abs z\| ≤ potential_error d c z	Please generate a tactic in lean4 to solve the state. STATE: c✝ z✝ : 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 s : Super (f d) d OnePoint.infty := superF d z3 : 3 ≤ Complex.abs z z0 : 0 < Complex.abs z l2 : 0 < (Complex.abs z).log p : ℝ p0 : 0 < p lp0 : 0 < -p.log r : ℝ hr : iter_error d c z = r h : \|(-p.log).log - (Complex.abs z).log.log\| ≤ r r0 : 0 ≤ r t : Set ℝ := Ici ((Complex.abs z).log.log - r) yt : (-p.log).log ∈ t lt : (Complex.abs z).log.log ∈ t b : ℝ hb : dene ((Complex.abs z).log.log - r) = b b0 : 0 ≤ b bound : ∀ x ∈ t, ‖deriv ene x‖ ≤ b ⊢ \|p - 1 / Complex.abs z\| ≤ potential_error d c z TACTIC:
https://github.com/girving/ray.git	0be790285dd0fce78913b0cb9bddaffa94bd25f9	Ray/Dynamics/Multibrot/Potential.lean	potential_approx	[262, 1]	[295, 40]	simp only [Real.norm_eq_abs] at m	c✝ z✝ : 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 s : Super (f d) d OnePoint.infty := superF d z3 : 3 ≤ Complex.abs z z0 : 0 < Complex.abs z l2 : 0 < (Complex.abs z).log p : ℝ p0 : 0 < p lp0 : 0 < -p.log r : ℝ hr : iter_error d c z = r h : \|(-p.log).log - (Complex.abs z).log.log\| ≤ r r0 : 0 ≤ r t : Set ℝ := Ici ((Complex.abs z).log.log - r) yt : (-p.log).log ∈ t lt : (Complex.abs z).log.log ∈ t b : ℝ hb : dene ((Complex.abs z).log.log - r) = b b0 : 0 ≤ b bound : ∀ x ∈ t, ‖deriv ene x‖ ≤ b m : ‖ene (-p.log).log - ene (Complex.abs z).log.log‖ ≤ b * ‖(-p.log).log - (Complex.abs z).log.log‖ ⊢ \|p - 1 / Complex.abs z\| ≤ potential_error d c z	c✝ z✝ : 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 s : Super (f d) d OnePoint.infty := superF d z3 : 3 ≤ Complex.abs z z0 : 0 < Complex.abs z l2 : 0 < (Complex.abs z).log p : ℝ p0 : 0 < p lp0 : 0 < -p.log r : ℝ hr : iter_error d c z = r h : \|(-p.log).log - (Complex.abs z).log.log\| ≤ r r0 : 0 ≤ r t : Set ℝ := Ici ((Complex.abs z).log.log - r) yt : (-p.log).log ∈ t lt : (Complex.abs z).log.log ∈ t b : ℝ hb : dene ((Complex.abs z).log.log - r) = b b0 : 0 ≤ b bound : ∀ x ∈ t, ‖deriv ene x‖ ≤ b m : \|ene (-p.log).log - ene (Complex.abs z).log.log\| ≤ b * \|(-p.log).log - (Complex.abs z).log.log\| ⊢ \|p - 1 / Complex.abs z\| ≤ potential_error d c z	Please generate a tactic in lean4 to solve the state. STATE: c✝ z✝ : 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 s : Super (f d) d OnePoint.infty := superF d z3 : 3 ≤ Complex.abs z z0 : 0 < Complex.abs z l2 : 0 < (Complex.abs z).log p : ℝ p0 : 0 < p lp0 : 0 < -p.log r : ℝ hr : iter_error d c z = r h : \|(-p.log).log - (Complex.abs z).log.log\| ≤ r r0 : 0 ≤ r t : Set ℝ := Ici ((Complex.abs z).log.log - r) yt : (-p.log).log ∈ t lt : (Complex.abs z).log.log ∈ t b : ℝ hb : dene ((Complex.abs z).log.log - r) = b b0 : 0 ≤ b bound : ∀ x ∈ t, ‖deriv ene x‖ ≤ b m : ‖ene (-p.log).log - ene (Complex.abs z).log.log‖ ≤ b * ‖(-p.log).log - (Complex.abs z).log.log‖ ⊢ \|p - 1 / Complex.abs z\| ≤ potential_error d c z TACTIC:
https://github.com/girving/ray.git	0be790285dd0fce78913b0cb9bddaffa94bd25f9	Ray/Dynamics/Multibrot/Potential.lean	potential_approx	[262, 1]	[295, 40]	replace m := le_trans m (mul_le_mul_of_nonneg_left h (by bound))	c✝ z✝ : 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 s : Super (f d) d OnePoint.infty := superF d z3 : 3 ≤ Complex.abs z z0 : 0 < Complex.abs z l2 : 0 < (Complex.abs z).log p : ℝ p0 : 0 < p lp0 : 0 < -p.log r : ℝ hr : iter_error d c z = r h : \|(-p.log).log - (Complex.abs z).log.log\| ≤ r r0 : 0 ≤ r t : Set ℝ := Ici ((Complex.abs z).log.log - r) yt : (-p.log).log ∈ t lt : (Complex.abs z).log.log ∈ t b : ℝ hb : dene ((Complex.abs z).log.log - r) = b b0 : 0 ≤ b bound : ∀ x ∈ t, ‖deriv ene x‖ ≤ b m : \|ene (-p.log).log - ene (Complex.abs z).log.log\| ≤ b * \|(-p.log).log - (Complex.abs z).log.log\| ⊢ \|p - 1 / Complex.abs z\| ≤ potential_error d c z	c✝ z✝ : 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 s : Super (f d) d OnePoint.infty := superF d z3 : 3 ≤ Complex.abs z z0 : 0 < Complex.abs z l2 : 0 < (Complex.abs z).log p : ℝ p0 : 0 < p lp0 : 0 < -p.log r : ℝ hr : iter_error d c z = r h : \|(-p.log).log - (Complex.abs z).log.log\| ≤ r r0 : 0 ≤ r t : Set ℝ := Ici ((Complex.abs z).log.log - r) yt : (-p.log).log ∈ t lt : (Complex.abs z).log.log ∈ t b : ℝ hb : dene ((Complex.abs z).log.log - r) = b b0 : 0 ≤ b bound : ∀ x ∈ t, ‖deriv ene x‖ ≤ b m : \|ene (-p.log).log - ene (Complex.abs z).log.log\| ≤ b * r ⊢ \|p - 1 / Complex.abs z\| ≤ potential_error d c z	Please generate a tactic in lean4 to solve the state. STATE: c✝ z✝ : 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 s : Super (f d) d OnePoint.infty := superF d z3 : 3 ≤ Complex.abs z z0 : 0 < Complex.abs z l2 : 0 < (Complex.abs z).log p : ℝ p0 : 0 < p lp0 : 0 < -p.log r : ℝ hr : iter_error d c z = r h : \|(-p.log).log - (Complex.abs z).log.log\| ≤ r r0 : 0 ≤ r t : Set ℝ := Ici ((Complex.abs z).log.log - r) yt : (-p.log).log ∈ t lt : (Complex.abs z).log.log ∈ t b : ℝ hb : dene ((Complex.abs z).log.log - r) = b b0 : 0 ≤ b bound : ∀ x ∈ t, ‖deriv ene x‖ ≤ b m : \|ene (-p.log).log - ene (Complex.abs z).log.log\| ≤ b * \|(-p.log).log - (Complex.abs z).log.log\| ⊢ \|p - 1 / Complex.abs z\| ≤ potential_error d c z TACTIC:
https://github.com/girving/ray.git	0be790285dd0fce78913b0cb9bddaffa94bd25f9	Ray/Dynamics/Multibrot/Potential.lean	potential_approx	[262, 1]	[295, 40]	simp only [ene, Real.exp_log lp0, neg_neg, Real.exp_log p0, Real.exp_log l2, Real.exp_neg, Real.exp_log z0, inv_eq_one_div] at m	c✝ z✝ : 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 s : Super (f d) d OnePoint.infty := superF d z3 : 3 ≤ Complex.abs z z0 : 0 < Complex.abs z l2 : 0 < (Complex.abs z).log p : ℝ p0 : 0 < p lp0 : 0 < -p.log r : ℝ hr : iter_error d c z = r h : \|(-p.log).log - (Complex.abs z).log.log\| ≤ r r0 : 0 ≤ r t : Set ℝ := Ici ((Complex.abs z).log.log - r) yt : (-p.log).log ∈ t lt : (Complex.abs z).log.log ∈ t b : ℝ hb : dene ((Complex.abs z).log.log - r) = b b0 : 0 ≤ b bound : ∀ x ∈ t, ‖deriv ene x‖ ≤ b m : \|ene (-p.log).log - ene (Complex.abs z).log.log\| ≤ b * r ⊢ \|p - 1 / Complex.abs z\| ≤ potential_error d c z	c✝ z✝ : 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 s : Super (f d) d OnePoint.infty := superF d z3 : 3 ≤ Complex.abs z z0 : 0 < Complex.abs z l2 : 0 < (Complex.abs z).log p : ℝ p0 : 0 < p lp0 : 0 < -p.log r : ℝ hr : iter_error d c z = r h : \|(-p.log).log - (Complex.abs z).log.log\| ≤ r r0 : 0 ≤ r t : Set ℝ := Ici ((Complex.abs z).log.log - r) yt : (-p.log).log ∈ t lt : (Complex.abs z).log.log ∈ t b : ℝ hb : dene ((Complex.abs z).log.log - r) = b b0 : 0 ≤ b bound : ∀ x ∈ t, ‖deriv ene x‖ ≤ b m : \|p - 1 / Complex.abs z\| ≤ b * r ⊢ \|p - 1 / Complex.abs z\| ≤ potential_error d c z	Please generate a tactic in lean4 to solve the state. STATE: c✝ z✝ : 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 s : Super (f d) d OnePoint.infty := superF d z3 : 3 ≤ Complex.abs z z0 : 0 < Complex.abs z l2 : 0 < (Complex.abs z).log p : ℝ p0 : 0 < p lp0 : 0 < -p.log r : ℝ hr : iter_error d c z = r h : \|(-p.log).log - (Complex.abs z).log.log\| ≤ r r0 : 0 ≤ r t : Set ℝ := Ici ((Complex.abs z).log.log - r) yt : (-p.log).log ∈ t lt : (Complex.abs z).log.log ∈ t b : ℝ hb : dene ((Complex.abs z).log.log - r) = b b0 : 0 ≤ b bound : ∀ x ∈ t, ‖deriv ene x‖ ≤ b m : \|ene (-p.log).log - ene (Complex.abs z).log.log\| ≤ b * r ⊢ \|p - 1 / Complex.abs z\| ≤ potential_error d c z TACTIC:
https://github.com/girving/ray.git	0be790285dd0fce78913b0cb9bddaffa94bd25f9	Ray/Dynamics/Multibrot/Potential.lean	potential_approx	[262, 1]	[295, 40]	refine le_trans m (le_of_eq ?_)	c✝ z✝ : 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 s : Super (f d) d OnePoint.infty := superF d z3 : 3 ≤ Complex.abs z z0 : 0 < Complex.abs z l2 : 0 < (Complex.abs z).log p : ℝ p0 : 0 < p lp0 : 0 < -p.log r : ℝ hr : iter_error d c z = r h : \|(-p.log).log - (Complex.abs z).log.log\| ≤ r r0 : 0 ≤ r t : Set ℝ := Ici ((Complex.abs z).log.log - r) yt : (-p.log).log ∈ t lt : (Complex.abs z).log.log ∈ t b : ℝ hb : dene ((Complex.abs z).log.log - r) = b b0 : 0 ≤ b bound : ∀ x ∈ t, ‖deriv ene x‖ ≤ b m : \|p - 1 / Complex.abs z\| ≤ b * r ⊢ \|p - 1 / Complex.abs z\| ≤ potential_error d c z	c✝ z✝ : 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 s : Super (f d) d OnePoint.infty := superF d z3 : 3 ≤ Complex.abs z z0 : 0 < Complex.abs z l2 : 0 < (Complex.abs z).log p : ℝ p0 : 0 < p lp0 : 0 < -p.log r : ℝ hr : iter_error d c z = r h : \|(-p.log).log - (Complex.abs z).log.log\| ≤ r r0 : 0 ≤ r t : Set ℝ := Ici ((Complex.abs z).log.log - r) yt : (-p.log).log ∈ t lt : (Complex.abs z).log.log ∈ t b : ℝ hb : dene ((Complex.abs z).log.log - r) = b b0 : 0 ≤ b bound : ∀ x ∈ t, ‖deriv ene x‖ ≤ b m : \|p - 1 / Complex.abs z\| ≤ b * r ⊢ b * r = potential_error d c z	Please generate a tactic in lean4 to solve the state. STATE: c✝ z✝ : 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 s : Super (f d) d OnePoint.infty := superF d z3 : 3 ≤ Complex.abs z z0 : 0 < Complex.abs z l2 : 0 < (Complex.abs z).log p : ℝ p0 : 0 < p lp0 : 0 < -p.log r : ℝ hr : iter_error d c z = r h : \|(-p.log).log - (Complex.abs z).log.log\| ≤ r r0 : 0 ≤ r t : Set ℝ := Ici ((Complex.abs z).log.log - r) yt : (-p.log).log ∈ t lt : (Complex.abs z).log.log ∈ t b : ℝ hb : dene ((Complex.abs z).log.log - r) = b b0 : 0 ≤ b bound : ∀ x ∈ t, ‖deriv ene x‖ ≤ b m : \|p - 1 / Complex.abs z\| ≤ b * r ⊢ \|p - 1 / Complex.abs z\| ≤ potential_error d c z TACTIC:
https://github.com/girving/ray.git	0be790285dd0fce78913b0cb9bddaffa94bd25f9	Ray/Dynamics/Multibrot/Potential.lean	potential_approx	[262, 1]	[295, 40]	simp only [←hr, ←hb, potential_error]	c✝ z✝ : 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 s : Super (f d) d OnePoint.infty := superF d z3 : 3 ≤ Complex.abs z z0 : 0 < Complex.abs z l2 : 0 < (Complex.abs z).log p : ℝ p0 : 0 < p lp0 : 0 < -p.log r : ℝ hr : iter_error d c z = r h : \|(-p.log).log - (Complex.abs z).log.log\| ≤ r r0 : 0 ≤ r t : Set ℝ := Ici ((Complex.abs z).log.log - r) yt : (-p.log).log ∈ t lt : (Complex.abs z).log.log ∈ t b : ℝ hb : dene ((Complex.abs z).log.log - r) = b b0 : 0 ≤ b bound : ∀ x ∈ t, ‖deriv ene x‖ ≤ b m : \|p - 1 / Complex.abs z\| ≤ b * r ⊢ b * r = potential_error d c z	no goals	Please generate a tactic in lean4 to solve the state. STATE: c✝ z✝ : 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 s : Super (f d) d OnePoint.infty := superF d z3 : 3 ≤ Complex.abs z z0 : 0 < Complex.abs z l2 : 0 < (Complex.abs z).log p : ℝ p0 : 0 < p lp0 : 0 < -p.log r : ℝ hr : iter_error d c z = r h : \|(-p.log).log - (Complex.abs z).log.log\| ≤ r r0 : 0 ≤ r t : Set ℝ := Ici ((Complex.abs z).log.log - r) yt : (-p.log).log ∈ t lt : (Complex.abs z).log.log ∈ t b : ℝ hb : dene ((Complex.abs z).log.log - r) = b b0 : 0 ≤ b bound : ∀ x ∈ t, ‖deriv ene x‖ ≤ b m : \|p - 1 / Complex.abs z\| ≤ b * r ⊢ b * r = potential_error d c z TACTIC:
https://github.com/girving/ray.git	0be790285dd0fce78913b0cb9bddaffa94bd25f9	Ray/Dynamics/Multibrot/Potential.lean	potential_approx	[262, 1]	[295, 40]	norm_num	c✝ z✝ : 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 s : Super (f d) d OnePoint.infty := superF d ⊢ 3 ≤ 4	no goals	Please generate a tactic in lean4 to solve the state. STATE: c✝ z✝ : 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 s : Super (f d) d OnePoint.infty := superF d ⊢ 3 ≤ 4 TACTIC:
https://github.com/girving/ray.git	0be790285dd0fce78913b0cb9bddaffa94bd25f9	Ray/Dynamics/Multibrot/Potential.lean	potential_approx	[262, 1]	[295, 40]	norm_num	c✝ z✝ : 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 s : Super (f d) d OnePoint.infty := superF d z3 : 3 ≤ Complex.abs z ⊢ 0 < 3	no goals	Please generate a tactic in lean4 to solve the state. STATE: c✝ z✝ : 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 s : Super (f d) d OnePoint.infty := superF d z3 : 3 ≤ Complex.abs z ⊢ 0 < 3 TACTIC:
https://github.com/girving/ray.git	0be790285dd0fce78913b0cb9bddaffa94bd25f9	Ray/Dynamics/Multibrot/Potential.lean	potential_approx	[262, 1]	[295, 40]	linarith	c✝ z✝ : 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 s : Super (f d) d OnePoint.infty := superF d z3 : 3 ≤ Complex.abs z z0 : 0 < Complex.abs z ⊢ 1 < Complex.abs z	no goals	Please generate a tactic in lean4 to solve the state. STATE: c✝ z✝ : 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 s : Super (f d) d OnePoint.infty := superF d z3 : 3 ≤ Complex.abs z z0 : 0 < Complex.abs z ⊢ 1 < Complex.abs z TACTIC:
https://github.com/girving/ray.git	0be790285dd0fce78913b0cb9bddaffa94bd25f9	Ray/Dynamics/Multibrot/Potential.lean	potential_approx	[262, 1]	[295, 40]	linarith	c✝ z✝ : 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 s : Super (f d) d OnePoint.infty := superF d z3 : 3 ≤ Complex.abs z z0 : 0 < Complex.abs z l2 : 0 < (Complex.abs z).log h : \|(-(⋯.potential c ↑z).log).log - (Complex.abs z).log.log\| ≤ iter_error d c z p0 : 0 < s.potential c ↑z ⊢ 2 < Complex.abs z	no goals	Please generate a tactic in lean4 to solve the state. STATE: c✝ z✝ : 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 s : Super (f d) d OnePoint.infty := superF d z3 : 3 ≤ Complex.abs z z0 : 0 < Complex.abs z l2 : 0 < (Complex.abs z).log h : \|(-(⋯.potential c ↑z).log).log - (Complex.abs z).log.log\| ≤ iter_error d c z p0 : 0 < s.potential c ↑z ⊢ 2 < Complex.abs z TACTIC:
https://github.com/girving/ray.git	0be790285dd0fce78913b0cb9bddaffa94bd25f9	Ray/Dynamics/Multibrot/Potential.lean	potential_approx	[262, 1]	[295, 40]	simp only [abs_le, neg_le_sub_iff_le_add, tsub_le_iff_right, add_comm r] at h	c✝ z✝ : 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 s : Super (f d) d OnePoint.infty := superF d z3 : 3 ≤ Complex.abs z z0 : 0 < Complex.abs z l2 : 0 < (Complex.abs z).log p : ℝ p0 : 0 < p lp0 : 0 < -p.log r : ℝ hr : iter_error d c z = r h : \|(-p.log).log - (Complex.abs z).log.log\| ≤ r r0 : 0 ≤ r t : Set ℝ := Ici ((Complex.abs z).log.log - r) ⊢ (-p.log).log ∈ t	c✝ z✝ : 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 s : Super (f d) d OnePoint.infty := superF d z3 : 3 ≤ Complex.abs z z0 : 0 < Complex.abs z l2 : 0 < (Complex.abs z).log p : ℝ p0 : 0 < p lp0 : 0 < -p.log r : ℝ hr : iter_error d c z = r r0 : 0 ≤ r t : Set ℝ := Ici ((Complex.abs z).log.log - r) h : (Complex.abs z).log.log ≤ (-p.log).log + r ∧ (-p.log).log ≤ (Complex.abs z).log.log + r ⊢ (-p.log).log ∈ t	Please generate a tactic in lean4 to solve the state. STATE: c✝ z✝ : 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 s : Super (f d) d OnePoint.infty := superF d z3 : 3 ≤ Complex.abs z z0 : 0 < Complex.abs z l2 : 0 < (Complex.abs z).log p : ℝ p0 : 0 < p lp0 : 0 < -p.log r : ℝ hr : iter_error d c z = r h : \|(-p.log).log - (Complex.abs z).log.log\| ≤ r r0 : 0 ≤ r t : Set ℝ := Ici ((Complex.abs z).log.log - r) ⊢ (-p.log).log ∈ t TACTIC:
https://github.com/girving/ray.git	0be790285dd0fce78913b0cb9bddaffa94bd25f9	Ray/Dynamics/Multibrot/Potential.lean	potential_approx	[262, 1]	[295, 40]	simp only [mem_Ici, tsub_le_iff_right, h, t]	c✝ z✝ : 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 s : Super (f d) d OnePoint.infty := superF d z3 : 3 ≤ Complex.abs z z0 : 0 < Complex.abs z l2 : 0 < (Complex.abs z).log p : ℝ p0 : 0 < p lp0 : 0 < -p.log r : ℝ hr : iter_error d c z = r r0 : 0 ≤ r t : Set ℝ := Ici ((Complex.abs z).log.log - r) h : (Complex.abs z).log.log ≤ (-p.log).log + r ∧ (-p.log).log ≤ (Complex.abs z).log.log + r ⊢ (-p.log).log ∈ t	no goals	Please generate a tactic in lean4 to solve the state. STATE: c✝ z✝ : 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 s : Super (f d) d OnePoint.infty := superF d z3 : 3 ≤ Complex.abs z z0 : 0 < Complex.abs z l2 : 0 < (Complex.abs z).log p : ℝ p0 : 0 < p lp0 : 0 < -p.log r : ℝ hr : iter_error d c z = r r0 : 0 ≤ r t : Set ℝ := Ici ((Complex.abs z).log.log - r) h : (Complex.abs z).log.log ≤ (-p.log).log + r ∧ (-p.log).log ≤ (Complex.abs z).log.log + r ⊢ (-p.log).log ∈ t TACTIC:
https://github.com/girving/ray.git	0be790285dd0fce78913b0cb9bddaffa94bd25f9	Ray/Dynamics/Multibrot/Potential.lean	potential_approx	[262, 1]	[295, 40]	simp only [mem_Ici, tsub_le_iff_right, le_add_iff_nonneg_right, r0, t]	c✝ z✝ : 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 s : Super (f d) d OnePoint.infty := superF d z3 : 3 ≤ Complex.abs z z0 : 0 < Complex.abs z l2 : 0 < (Complex.abs z).log p : ℝ p0 : 0 < p lp0 : 0 < -p.log r : ℝ hr : iter_error d c z = r h : \|(-p.log).log - (Complex.abs z).log.log\| ≤ r r0 : 0 ≤ r t : Set ℝ := Ici ((Complex.abs z).log.log - r) yt : (-p.log).log ∈ t ⊢ (Complex.abs z).log.log ∈ t	no goals	Please generate a tactic in lean4 to solve the state. STATE: c✝ z✝ : 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 s : Super (f d) d OnePoint.infty := superF d z3 : 3 ≤ Complex.abs z z0 : 0 < Complex.abs z l2 : 0 < (Complex.abs z).log p : ℝ p0 : 0 < p lp0 : 0 < -p.log r : ℝ hr : iter_error d c z = r h : \|(-p.log).log - (Complex.abs z).log.log\| ≤ r r0 : 0 ≤ r t : Set ℝ := Ici ((Complex.abs z).log.log - r) yt : (-p.log).log ∈ t ⊢ (Complex.abs z).log.log ∈ t TACTIC:
https://github.com/girving/ray.git	0be790285dd0fce78913b0cb9bddaffa94bd25f9	Ray/Dynamics/Multibrot/Potential.lean	potential_approx	[262, 1]	[295, 40]	rw [←hb]	c✝ z✝ : 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 s : Super (f d) d OnePoint.infty := superF d z3 : 3 ≤ Complex.abs z z0 : 0 < Complex.abs z l2 : 0 < (Complex.abs z).log p : ℝ p0 : 0 < p lp0 : 0 < -p.log r : ℝ hr : iter_error d c z = r h : \|(-p.log).log - (Complex.abs z).log.log\| ≤ r r0 : 0 ≤ r t : Set ℝ := Ici ((Complex.abs z).log.log - r) yt : (-p.log).log ∈ t lt : (Complex.abs z).log.log ∈ t b : ℝ hb : dene ((Complex.abs z).log.log - r) = b ⊢ 0 ≤ b	c✝ z✝ : 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 s : Super (f d) d OnePoint.infty := superF d z3 : 3 ≤ Complex.abs z z0 : 0 < Complex.abs z l2 : 0 < (Complex.abs z).log p : ℝ p0 : 0 < p lp0 : 0 < -p.log r : ℝ hr : iter_error d c z = r h : \|(-p.log).log - (Complex.abs z).log.log\| ≤ r r0 : 0 ≤ r t : Set ℝ := Ici ((Complex.abs z).log.log - r) yt : (-p.log).log ∈ t lt : (Complex.abs z).log.log ∈ t b : ℝ hb : dene ((Complex.abs z).log.log - r) = b ⊢ 0 ≤ dene ((Complex.abs z).log.log - r)	Please generate a tactic in lean4 to solve the state. STATE: c✝ z✝ : 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 s : Super (f d) d OnePoint.infty := superF d z3 : 3 ≤ Complex.abs z z0 : 0 < Complex.abs z l2 : 0 < (Complex.abs z).log p : ℝ p0 : 0 < p lp0 : 0 < -p.log r : ℝ hr : iter_error d c z = r h : \|(-p.log).log - (Complex.abs z).log.log\| ≤ r r0 : 0 ≤ r t : Set ℝ := Ici ((Complex.abs z).log.log - r) yt : (-p.log).log ∈ t lt : (Complex.abs z).log.log ∈ t b : ℝ hb : dene ((Complex.abs z).log.log - r) = b ⊢ 0 ≤ b TACTIC:
https://github.com/girving/ray.git	0be790285dd0fce78913b0cb9bddaffa94bd25f9	Ray/Dynamics/Multibrot/Potential.lean	potential_approx	[262, 1]	[295, 40]	exact dene_nonneg	c✝ z✝ : 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 s : Super (f d) d OnePoint.infty := superF d z3 : 3 ≤ Complex.abs z z0 : 0 < Complex.abs z l2 : 0 < (Complex.abs z).log p : ℝ p0 : 0 < p lp0 : 0 < -p.log r : ℝ hr : iter_error d c z = r h : \|(-p.log).log - (Complex.abs z).log.log\| ≤ r r0 : 0 ≤ r t : Set ℝ := Ici ((Complex.abs z).log.log - r) yt : (-p.log).log ∈ t lt : (Complex.abs z).log.log ∈ t b : ℝ hb : dene ((Complex.abs z).log.log - r) = b ⊢ 0 ≤ dene ((Complex.abs z).log.log - r)	no goals	Please generate a tactic in lean4 to solve the state. STATE: c✝ z✝ : 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 s : Super (f d) d OnePoint.infty := superF d z3 : 3 ≤ Complex.abs z z0 : 0 < Complex.abs z l2 : 0 < (Complex.abs z).log p : ℝ p0 : 0 < p lp0 : 0 < -p.log r : ℝ hr : iter_error d c z = r h : \|(-p.log).log - (Complex.abs z).log.log\| ≤ r r0 : 0 ≤ r t : Set ℝ := Ici ((Complex.abs z).log.log - r) yt : (-p.log).log ∈ t lt : (Complex.abs z).log.log ∈ t b : ℝ hb : dene ((Complex.abs z).log.log - r) = b ⊢ 0 ≤ dene ((Complex.abs z).log.log - r) TACTIC:
https://github.com/girving/ray.git	0be790285dd0fce78913b0cb9bddaffa94bd25f9	Ray/Dynamics/Multibrot/Potential.lean	potential_approx	[262, 1]	[295, 40]	intro x m	c✝ z✝ : 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 s : Super (f d) d OnePoint.infty := superF d z3 : 3 ≤ Complex.abs z z0 : 0 < Complex.abs z l2 : 0 < (Complex.abs z).log p : ℝ p0 : 0 < p lp0 : 0 < -p.log r : ℝ hr : iter_error d c z = r h : \|(-p.log).log - (Complex.abs z).log.log\| ≤ r r0 : 0 ≤ r t : Set ℝ := Ici ((Complex.abs z).log.log - r) yt : (-p.log).log ∈ t lt : (Complex.abs z).log.log ∈ t b : ℝ hb : dene ((Complex.abs z).log.log - r) = b b0 : 0 ≤ b ⊢ ∀ x ∈ t, ‖deriv ene x‖ ≤ b	c✝ z✝ : 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 s : Super (f d) d OnePoint.infty := superF d z3 : 3 ≤ Complex.abs z z0 : 0 < Complex.abs z l2 : 0 < (Complex.abs z).log p : ℝ p0 : 0 < p lp0 : 0 < -p.log r : ℝ hr : iter_error d c z = r h : \|(-p.log).log - (Complex.abs z).log.log\| ≤ r r0 : 0 ≤ r t : Set ℝ := Ici ((Complex.abs z).log.log - r) yt : (-p.log).log ∈ t lt : (Complex.abs z).log.log ∈ t b : ℝ hb : dene ((Complex.abs z).log.log - r) = b b0 : 0 ≤ b x : ℝ m : x ∈ t ⊢ ‖deriv ene x‖ ≤ b	Please generate a tactic in lean4 to solve the state. STATE: c✝ z✝ : 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 s : Super (f d) d OnePoint.infty := superF d z3 : 3 ≤ Complex.abs z z0 : 0 < Complex.abs z l2 : 0 < (Complex.abs z).log p : ℝ p0 : 0 < p lp0 : 0 < -p.log r : ℝ hr : iter_error d c z = r h : \|(-p.log).log - (Complex.abs z).log.log\| ≤ r r0 : 0 ≤ r t : Set ℝ := Ici ((Complex.abs z).log.log - r) yt : (-p.log).log ∈ t lt : (Complex.abs z).log.log ∈ t b : ℝ hb : dene ((Complex.abs z).log.log - r) = b b0 : 0 ≤ b ⊢ ∀ x ∈ t, ‖deriv ene x‖ ≤ b TACTIC:
https://github.com/girving/ray.git	0be790285dd0fce78913b0cb9bddaffa94bd25f9	Ray/Dynamics/Multibrot/Potential.lean	potential_approx	[262, 1]	[295, 40]	simp only [Real.dist_eq, mem_Ici, ←hr, t] at m	c✝ z✝ : 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 s : Super (f d) d OnePoint.infty := superF d z3 : 3 ≤ Complex.abs z z0 : 0 < Complex.abs z l2 : 0 < (Complex.abs z).log p : ℝ p0 : 0 < p lp0 : 0 < -p.log r : ℝ hr : iter_error d c z = r h : \|(-p.log).log - (Complex.abs z).log.log\| ≤ r r0 : 0 ≤ r t : Set ℝ := Ici ((Complex.abs z).log.log - r) yt : (-p.log).log ∈ t lt : (Complex.abs z).log.log ∈ t b : ℝ hb : dene ((Complex.abs z).log.log - r) = b b0 : 0 ≤ b x : ℝ m : x ∈ t ⊢ ‖deriv ene x‖ ≤ b	c✝ z✝ : 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 s : Super (f d) d OnePoint.infty := superF d z3 : 3 ≤ Complex.abs z z0 : 0 < Complex.abs z l2 : 0 < (Complex.abs z).log p : ℝ p0 : 0 < p lp0 : 0 < -p.log r : ℝ hr : iter_error d c z = r h : \|(-p.log).log - (Complex.abs z).log.log\| ≤ r r0 : 0 ≤ r t : Set ℝ := Ici ((Complex.abs z).log.log - r) yt : (-p.log).log ∈ t lt : (Complex.abs z).log.log ∈ t b : ℝ hb : dene ((Complex.abs z).log.log - r) = b b0 : 0 ≤ b x : ℝ m : (Complex.abs z).log.log - iter_error d c z ≤ x ⊢ ‖deriv ene x‖ ≤ b	Please generate a tactic in lean4 to solve the state. STATE: c✝ z✝ : 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 s : Super (f d) d OnePoint.infty := superF d z3 : 3 ≤ Complex.abs z z0 : 0 < Complex.abs z l2 : 0 < (Complex.abs z).log p : ℝ p0 : 0 < p lp0 : 0 < -p.log r : ℝ hr : iter_error d c z = r h : \|(-p.log).log - (Complex.abs z).log.log\| ≤ r r0 : 0 ≤ r t : Set ℝ := Ici ((Complex.abs z).log.log - r) yt : (-p.log).log ∈ t lt : (Complex.abs z).log.log ∈ t b : ℝ hb : dene ((Complex.abs z).log.log - r) = b b0 : 0 ≤ b x : ℝ m : x ∈ t ⊢ ‖deriv ene x‖ ≤ b TACTIC:
https://github.com/girving/ray.git	0be790285dd0fce78913b0cb9bddaffa94bd25f9	Ray/Dynamics/Multibrot/Potential.lean	potential_approx	[262, 1]	[295, 40]	simp only [deriv_ene, norm_neg, Real.norm_of_nonneg dene_nonneg, ←hb, ←hr]	c✝ z✝ : 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 s : Super (f d) d OnePoint.infty := superF d z3 : 3 ≤ Complex.abs z z0 : 0 < Complex.abs z l2 : 0 < (Complex.abs z).log p : ℝ p0 : 0 < p lp0 : 0 < -p.log r : ℝ hr : iter_error d c z = r h : \|(-p.log).log - (Complex.abs z).log.log\| ≤ r r0 : 0 ≤ r t : Set ℝ := Ici ((Complex.abs z).log.log - r) yt : (-p.log).log ∈ t lt : (Complex.abs z).log.log ∈ t b : ℝ hb : dene ((Complex.abs z).log.log - r) = b b0 : 0 ≤ b x : ℝ m : (Complex.abs z).log.log - iter_error d c z ≤ x ⊢ ‖deriv ene x‖ ≤ b	c✝ z✝ : 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 s : Super (f d) d OnePoint.infty := superF d z3 : 3 ≤ Complex.abs z z0 : 0 < Complex.abs z l2 : 0 < (Complex.abs z).log p : ℝ p0 : 0 < p lp0 : 0 < -p.log r : ℝ hr : iter_error d c z = r h : \|(-p.log).log - (Complex.abs z).log.log\| ≤ r r0 : 0 ≤ r t : Set ℝ := Ici ((Complex.abs z).log.log - r) yt : (-p.log).log ∈ t lt : (Complex.abs z).log.log ∈ t b : ℝ hb : dene ((Complex.abs z).log.log - r) = b b0 : 0 ≤ b x : ℝ m : (Complex.abs z).log.log - iter_error d c z ≤ x ⊢ dene x ≤ dene ((Complex.abs z).log.log - iter_error d c z)	Please generate a tactic in lean4 to solve the state. STATE: c✝ z✝ : 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 s : Super (f d) d OnePoint.infty := superF d z3 : 3 ≤ Complex.abs z z0 : 0 < Complex.abs z l2 : 0 < (Complex.abs z).log p : ℝ p0 : 0 < p lp0 : 0 < -p.log r : ℝ hr : iter_error d c z = r h : \|(-p.log).log - (Complex.abs z).log.log\| ≤ r r0 : 0 ≤ r t : Set ℝ := Ici ((Complex.abs z).log.log - r) yt : (-p.log).log ∈ t lt : (Complex.abs z).log.log ∈ t b : ℝ hb : dene ((Complex.abs z).log.log - r) = b b0 : 0 ≤ b x : ℝ m : (Complex.abs z).log.log - iter_error d c z ≤ x ⊢ ‖deriv ene x‖ ≤ b TACTIC:
https://github.com/girving/ray.git	0be790285dd0fce78913b0cb9bddaffa94bd25f9	Ray/Dynamics/Multibrot/Potential.lean	potential_approx	[262, 1]	[295, 40]	apply dene_anti (sub_nonneg.mpr (iter_error_le_log_log_abs d z4 cz)) m	c✝ z✝ : 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 s : Super (f d) d OnePoint.infty := superF d z3 : 3 ≤ Complex.abs z z0 : 0 < Complex.abs z l2 : 0 < (Complex.abs z).log p : ℝ p0 : 0 < p lp0 : 0 < -p.log r : ℝ hr : iter_error d c z = r h : \|(-p.log).log - (Complex.abs z).log.log\| ≤ r r0 : 0 ≤ r t : Set ℝ := Ici ((Complex.abs z).log.log - r) yt : (-p.log).log ∈ t lt : (Complex.abs z).log.log ∈ t b : ℝ hb : dene ((Complex.abs z).log.log - r) = b b0 : 0 ≤ b x : ℝ m : (Complex.abs z).log.log - iter_error d c z ≤ x ⊢ dene x ≤ dene ((Complex.abs z).log.log - iter_error d c z)	no goals	Please generate a tactic in lean4 to solve the state. STATE: c✝ z✝ : 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 s : Super (f d) d OnePoint.infty := superF d z3 : 3 ≤ Complex.abs z z0 : 0 < Complex.abs z l2 : 0 < (Complex.abs z).log p : ℝ p0 : 0 < p lp0 : 0 < -p.log r : ℝ hr : iter_error d c z = r h : \|(-p.log).log - (Complex.abs z).log.log\| ≤ r r0 : 0 ≤ r t : Set ℝ := Ici ((Complex.abs z).log.log - r) yt : (-p.log).log ∈ t lt : (Complex.abs z).log.log ∈ t b : ℝ hb : dene ((Complex.abs z).log.log - r) = b b0 : 0 ≤ b x : ℝ m : (Complex.abs z).log.log - iter_error d c z ≤ x ⊢ dene x ≤ dene ((Complex.abs z).log.log - iter_error d c z) TACTIC:
https://github.com/girving/ray.git	0be790285dd0fce78913b0cb9bddaffa94bd25f9	Ray/Dynamics/Multibrot/Potential.lean	potential_approx	[262, 1]	[295, 40]	bound	c✝ z✝ : 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 s : Super (f d) d OnePoint.infty := superF d z3 : 3 ≤ Complex.abs z z0 : 0 < Complex.abs z l2 : 0 < (Complex.abs z).log p : ℝ p0 : 0 < p lp0 : 0 < -p.log r : ℝ hr : iter_error d c z = r h : \|(-p.log).log - (Complex.abs z).log.log\| ≤ r r0 : 0 ≤ r t : Set ℝ := Ici ((Complex.abs z).log.log - r) yt : (-p.log).log ∈ t lt : (Complex.abs z).log.log ∈ t b : ℝ hb : dene ((Complex.abs z).log.log - r) = b b0 : 0 ≤ b bound : ∀ x ∈ t, ‖deriv ene x‖ ≤ b m : \|ene (-p.log).log - ene (Complex.abs z).log.log\| ≤ b * \|(-p.log).log - (Complex.abs z).log.log\| ⊢ 0 ≤ b	no goals	Please generate a tactic in lean4 to solve the state. STATE: c✝ z✝ : 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 s : Super (f d) d OnePoint.infty := superF d z3 : 3 ≤ Complex.abs z z0 : 0 < Complex.abs z l2 : 0 < (Complex.abs z).log p : ℝ p0 : 0 < p lp0 : 0 < -p.log r : ℝ hr : iter_error d c z = r h : \|(-p.log).log - (Complex.abs z).log.log\| ≤ r r0 : 0 ≤ r t : Set ℝ := Ici ((Complex.abs z).log.log - r) yt : (-p.log).log ∈ t lt : (Complex.abs z).log.log ∈ t b : ℝ hb : dene ((Complex.abs z).log.log - r) = b b0 : 0 ≤ b bound : ∀ x ∈ t, ‖deriv ene x‖ ≤ b m : \|ene (-p.log).log - ene (Complex.abs z).log.log\| ≤ b * \|(-p.log).log - (Complex.abs z).log.log\| ⊢ 0 ≤ b TACTIC:
https://github.com/girving/ray.git	0be790285dd0fce78913b0cb9bddaffa94bd25f9	Ray/Misc/Bounds.lean	late_iff_disjoint_range	[27, 1]	[30, 83]	simp only [Late, ge_iff_le, Finset.disjoint_iff_ne, Finset.mem_range, ne_eq]	m : ℕ A : Finset ℕ ⊢ Late A m ↔ Disjoint A (Finset.range m)	m : ℕ A : Finset ℕ ⊢ (∀ n ∈ A, m ≤ n) ↔ ∀ a ∈ A, ∀ b < m, ¬a = b	Please generate a tactic in lean4 to solve the state. STATE: m : ℕ A : Finset ℕ ⊢ Late A m ↔ Disjoint A (Finset.range m) TACTIC:
https://github.com/girving/ray.git	0be790285dd0fce78913b0cb9bddaffa94bd25f9	Ray/Misc/Bounds.lean	late_iff_disjoint_range	[27, 1]	[30, 83]	constructor	m : ℕ A : Finset ℕ ⊢ (∀ n ∈ A, m ≤ n) ↔ ∀ a ∈ A, ∀ b < m, ¬a = b	case mp m : ℕ A : Finset ℕ ⊢ (∀ n ∈ A, m ≤ n) → ∀ a ∈ A, ∀ b < m, ¬a = b case mpr m : ℕ A : Finset ℕ ⊢ (∀ a ∈ A, ∀ b < m, ¬a = b) → ∀ n ∈ A, m ≤ n	Please generate a tactic in lean4 to solve the state. STATE: m : ℕ A : Finset ℕ ⊢ (∀ n ∈ A, m ≤ n) ↔ ∀ a ∈ A, ∀ b < m, ¬a = b TACTIC:
https://github.com/girving/ray.git	0be790285dd0fce78913b0cb9bddaffa94bd25f9	Ray/Misc/Bounds.lean	late_iff_disjoint_range	[27, 1]	[30, 83]	intro h n na b bm	case mp m : ℕ A : Finset ℕ ⊢ (∀ n ∈ A, m ≤ n) → ∀ a ∈ A, ∀ b < m, ¬a = b	case mp m : ℕ A : Finset ℕ h : ∀ n ∈ A, m ≤ n n : ℕ na : n ∈ A b : ℕ bm : b < m ⊢ ¬n = b	Please generate a tactic in lean4 to solve the state. STATE: case mp m : ℕ A : Finset ℕ ⊢ (∀ n ∈ A, m ≤ n) → ∀ a ∈ A, ∀ b < m, ¬a = b TACTIC:
https://github.com/girving/ray.git	0be790285dd0fce78913b0cb9bddaffa94bd25f9	Ray/Misc/Bounds.lean	late_iff_disjoint_range	[27, 1]	[30, 83]	linarith [h _ na]	case mp m : ℕ A : Finset ℕ h : ∀ n ∈ A, m ≤ n n : ℕ na : n ∈ A b : ℕ bm : b < m ⊢ ¬n = b	no goals	Please generate a tactic in lean4 to solve the state. STATE: case mp m : ℕ A : Finset ℕ h : ∀ n ∈ A, m ≤ n n : ℕ na : n ∈ A b : ℕ bm : b < m ⊢ ¬n = b TACTIC:
https://github.com/girving/ray.git	0be790285dd0fce78913b0cb9bddaffa94bd25f9	Ray/Misc/Bounds.lean	late_iff_disjoint_range	[27, 1]	[30, 83]	intro h n na	case mpr m : ℕ A : Finset ℕ ⊢ (∀ a ∈ A, ∀ b < m, ¬a = b) → ∀ n ∈ A, m ≤ n	case mpr m : ℕ A : Finset ℕ h : ∀ a ∈ A, ∀ b < m, ¬a = b n : ℕ na : n ∈ A ⊢ m ≤ n	Please generate a tactic in lean4 to solve the state. STATE: case mpr m : ℕ A : Finset ℕ ⊢ (∀ a ∈ A, ∀ b < m, ¬a = b) → ∀ n ∈ A, m ≤ n TACTIC:
https://github.com/girving/ray.git	0be790285dd0fce78913b0cb9bddaffa94bd25f9	Ray/Misc/Bounds.lean	late_iff_disjoint_range	[27, 1]	[30, 83]	specialize h n na n	case mpr m : ℕ A : Finset ℕ h : ∀ a ∈ A, ∀ b < m, ¬a = b n : ℕ na : n ∈ A ⊢ m ≤ n	case mpr m : ℕ A : Finset ℕ n : ℕ na : n ∈ A h : n < m → ¬n = n ⊢ m ≤ n	Please generate a tactic in lean4 to solve the state. STATE: case mpr m : ℕ A : Finset ℕ h : ∀ a ∈ A, ∀ b < m, ¬a = b n : ℕ na : n ∈ A ⊢ m ≤ n TACTIC:
https://github.com/girving/ray.git	0be790285dd0fce78913b0cb9bddaffa94bd25f9	Ray/Misc/Bounds.lean	late_iff_disjoint_range	[27, 1]	[30, 83]	simpa [not_true, imp_false, not_lt] using h	case mpr m : ℕ A : Finset ℕ n : ℕ na : n ∈ A h : n < m → ¬n = n ⊢ m ≤ n	no goals	Please generate a tactic in lean4 to solve the state. STATE: case mpr m : ℕ A : Finset ℕ n : ℕ na : n ∈ A h : n < m → ¬n = n ⊢ m ≤ n TACTIC:
https://github.com/girving/ray.git	0be790285dd0fce78913b0cb9bddaffa94bd25f9	Ray/Misc/Bounds.lean	sdiff_late	[32, 1]	[38, 17]	intro Bm n nAB	m : ℕ B A : Finset ℕ ⊢ B ≥ Finset.range m → Late (A \ B) m	m : ℕ B A : Finset ℕ Bm : B ≥ Finset.range m n : ℕ nAB : n ∈ A \ B ⊢ n ≥ m	Please generate a tactic in lean4 to solve the state. STATE: m : ℕ B A : Finset ℕ ⊢ B ≥ Finset.range m → Late (A \ B) m TACTIC:
https://github.com/girving/ray.git	0be790285dd0fce78913b0cb9bddaffa94bd25f9	Ray/Misc/Bounds.lean	sdiff_late	[32, 1]	[38, 17]	rw [Finset.mem_sdiff] at nAB	m : ℕ B A : Finset ℕ Bm : B ≥ Finset.range m n : ℕ nAB : n ∈ A \ B ⊢ n ≥ m	m : ℕ B A : Finset ℕ Bm : B ≥ Finset.range m n : ℕ nAB : n ∈ A ∧ n ∉ B ⊢ n ≥ m	Please generate a tactic in lean4 to solve the state. STATE: m : ℕ B A : Finset ℕ Bm : B ≥ Finset.range m n : ℕ nAB : n ∈ A \ B ⊢ n ≥ m TACTIC:
https://github.com/girving/ray.git	0be790285dd0fce78913b0cb9bddaffa94bd25f9	Ray/Misc/Bounds.lean	sdiff_late	[32, 1]	[38, 17]	by_contra h	m : ℕ B A : Finset ℕ Bm : B ≥ Finset.range m n : ℕ nAB : n ∈ A ∧ n ∉ B ⊢ n ≥ m	m : ℕ B A : Finset ℕ Bm : B ≥ Finset.range m n : ℕ nAB : n ∈ A ∧ n ∉ B h : ¬n ≥ m ⊢ False	Please generate a tactic in lean4 to solve the state. STATE: m : ℕ B A : Finset ℕ Bm : B ≥ Finset.range m n : ℕ nAB : n ∈ A ∧ n ∉ B ⊢ n ≥ m TACTIC:
https://github.com/girving/ray.git	0be790285dd0fce78913b0cb9bddaffa94bd25f9	Ray/Misc/Bounds.lean	sdiff_late	[32, 1]	[38, 17]	simp only [not_le] at h	m : ℕ B A : Finset ℕ Bm : B ≥ Finset.range m n : ℕ nAB : n ∈ A ∧ n ∉ B h : ¬n ≥ m ⊢ False	m : ℕ B A : Finset ℕ Bm : B ≥ Finset.range m n : ℕ nAB : n ∈ A ∧ n ∉ B h : n < m ⊢ False	Please generate a tactic in lean4 to solve the state. STATE: m : ℕ B A : Finset ℕ Bm : B ≥ Finset.range m n : ℕ nAB : n ∈ A ∧ n ∉ B h : ¬n ≥ m ⊢ False TACTIC:
https://github.com/girving/ray.git	0be790285dd0fce78913b0cb9bddaffa94bd25f9	Ray/Misc/Bounds.lean	sdiff_late	[32, 1]	[38, 17]	have nr := Finset.mem_range.mpr h	m : ℕ B A : Finset ℕ Bm : B ≥ Finset.range m n : ℕ nAB : n ∈ A ∧ n ∉ B h : n < m ⊢ False	m : ℕ B A : Finset ℕ Bm : B ≥ Finset.range m n : ℕ nAB : n ∈ A ∧ n ∉ B h : n < m nr : n ∈ Finset.range m ⊢ False	Please generate a tactic in lean4 to solve the state. STATE: m : ℕ B A : Finset ℕ Bm : B ≥ Finset.range m n : ℕ nAB : n ∈ A ∧ n ∉ B h : n < m ⊢ False TACTIC:
https://github.com/girving/ray.git	0be790285dd0fce78913b0cb9bddaffa94bd25f9	Ray/Misc/Bounds.lean	sdiff_late	[32, 1]	[38, 17]	have nB := Finset.mem_of_subset Bm nr	m : ℕ B A : Finset ℕ Bm : B ≥ Finset.range m n : ℕ nAB : n ∈ A ∧ n ∉ B h : n < m nr : n ∈ Finset.range m ⊢ False	m : ℕ B A : Finset ℕ Bm : B ≥ Finset.range m n : ℕ nAB : n ∈ A ∧ n ∉ B h : n < m nr : n ∈ Finset.range m nB : n ∈ B ⊢ False	Please generate a tactic in lean4 to solve the state. STATE: m : ℕ B A : Finset ℕ Bm : B ≥ Finset.range m n : ℕ nAB : n ∈ A ∧ n ∉ B h : n < m nr : n ∈ Finset.range m ⊢ False TACTIC:
https://github.com/girving/ray.git	0be790285dd0fce78913b0cb9bddaffa94bd25f9	Ray/Misc/Bounds.lean	sdiff_late	[32, 1]	[38, 17]	exact nAB.2 nB	m : ℕ B A : Finset ℕ Bm : B ≥ Finset.range m n : ℕ nAB : n ∈ A ∧ n ∉ B h : n < m nr : n ∈ Finset.range m nB : n ∈ B ⊢ False	no goals	Please generate a tactic in lean4 to solve the state. STATE: m : ℕ B A : Finset ℕ Bm : B ≥ Finset.range m n : ℕ nAB : n ∈ A ∧ n ∉ B h : n < m nr : n ∈ Finset.range m nB : n ∈ B ⊢ False TACTIC:
https://github.com/girving/ray.git	0be790285dd0fce78913b0cb9bddaffa94bd25f9	Ray/Misc/Bounds.lean	partial_geometric_bound	[41, 1]	[44, 57]	intro n _	a : ℝ N : Finset ℕ a0 : 0 ≤ a a1 : a < 1 ⊢ ∀ n ∉ N, 0 ≤ a ^ n	a : ℝ N : Finset ℕ a0 : 0 ≤ a a1 : a < 1 n : ℕ a✝ : n ∉ N ⊢ 0 ≤ a ^ n	Please generate a tactic in lean4 to solve the state. STATE: a : ℝ N : Finset ℕ a0 : 0 ≤ a a1 : a < 1 ⊢ ∀ n ∉ N, 0 ≤ a ^ n TACTIC:
https://github.com/girving/ray.git	0be790285dd0fce78913b0cb9bddaffa94bd25f9	Ray/Misc/Bounds.lean	partial_geometric_bound	[41, 1]	[44, 57]	bound	a : ℝ N : Finset ℕ a0 : 0 ≤ a a1 : a < 1 n : ℕ a✝ : n ∉ N ⊢ 0 ≤ a ^ n	no goals	Please generate a tactic in lean4 to solve the state. STATE: a : ℝ N : Finset ℕ a0 : 0 ≤ a a1 : a < 1 n : ℕ a✝ : n ∉ N ⊢ 0 ≤ a ^ n TACTIC:
https://github.com/girving/ray.git	0be790285dd0fce78913b0cb9bddaffa94bd25f9	Ray/Misc/Bounds.lean	partial_scaled_geometric_bound	[46, 1]	[49, 42]	rw [←Finset.mul_sum]	a : ℝ c : ℝ≥0 N : Finset ℕ a0 : 0 ≤ a a1 : a < 1 ⊢ (N.sum fun n => ↑c * a ^ n) ≤ ↑c * (1 - a)⁻¹	a : ℝ c : ℝ≥0 N : Finset ℕ a0 : 0 ≤ a a1 : a < 1 ⊢ (↑c * N.sum fun i => a ^ i) ≤ ↑c * (1 - a)⁻¹	Please generate a tactic in lean4 to solve the state. STATE: a : ℝ c : ℝ≥0 N : Finset ℕ a0 : 0 ≤ a a1 : a < 1 ⊢ (N.sum fun n => ↑c * a ^ n) ≤ ↑c * (1 - a)⁻¹ TACTIC:
https://github.com/girving/ray.git	0be790285dd0fce78913b0cb9bddaffa94bd25f9	Ray/Misc/Bounds.lean	partial_scaled_geometric_bound	[46, 1]	[49, 42]	bound [partial_geometric_bound N a0 a1]	a : ℝ c : ℝ≥0 N : Finset ℕ a0 : 0 ≤ a a1 : a < 1 ⊢ (↑c * N.sum fun i => a ^ i) ≤ ↑c * (1 - a)⁻¹	no goals	Please generate a tactic in lean4 to solve the state. STATE: a : ℝ c : ℝ≥0 N : Finset ℕ a0 : 0 ≤ a a1 : a < 1 ⊢ (↑c * N.sum fun i => a ^ i) ≤ ↑c * (1 - a)⁻¹ TACTIC:
https://github.com/girving/ray.git	0be790285dd0fce78913b0cb9bddaffa94bd25f9	Ray/Misc/Bounds.lean	late_series_sum	[52, 1]	[66, 44]	set Ns := Finset.image (fun n ↦ n - m) N	m : ℕ N : Finset ℕ h : Late N m f : ℕ → ℝ ⊢ N.sum f = (Finset.image (fun n => n - m) N).sum fun n => f (n + m)	m : ℕ N : Finset ℕ h : Late N m f : ℕ → ℝ Ns : Finset ℕ := Finset.image (fun n => n - m) N ⊢ N.sum f = Ns.sum fun n => f (n + m)	Please generate a tactic in lean4 to solve the state. STATE: m : ℕ N : Finset ℕ h : Late N m f : ℕ → ℝ ⊢ N.sum f = (Finset.image (fun n => n - m) N).sum fun n => f (n + m) TACTIC:
https://github.com/girving/ray.git	0be790285dd0fce78913b0cb9bddaffa94bd25f9	Ray/Misc/Bounds.lean	late_series_sum	[52, 1]	[66, 44]	rw [NNs]	m : ℕ N : Finset ℕ h : Late N m f : ℕ → ℝ Ns : Finset ℕ := Finset.image (fun n => n - m) N NNs : N = Finset.image (fun n => n + m) Ns ⊢ N.sum f = Ns.sum fun n => f (n + m)	m : ℕ N : Finset ℕ h : Late N m f : ℕ → ℝ Ns : Finset ℕ := Finset.image (fun n => n - m) N NNs : N = Finset.image (fun n => n + m) Ns ⊢ (Finset.image (fun n => n + m) Ns).sum f = Ns.sum fun n => f (n + m)	Please generate a tactic in lean4 to solve the state. STATE: m : ℕ N : Finset ℕ h : Late N m f : ℕ → ℝ Ns : Finset ℕ := Finset.image (fun n => n - m) N NNs : N = Finset.image (fun n => n + m) Ns ⊢ N.sum f = Ns.sum fun n => f (n + m) TACTIC:
https://github.com/girving/ray.git	0be790285dd0fce78913b0cb9bddaffa94bd25f9	Ray/Misc/Bounds.lean	late_series_sum	[52, 1]	[66, 44]	apply Finset.sum_image	m : ℕ N : Finset ℕ h : Late N m f : ℕ → ℝ Ns : Finset ℕ := Finset.image (fun n => n - m) N NNs : N = Finset.image (fun n => n + m) Ns ⊢ (Finset.image (fun n => n + m) Ns).sum f = Ns.sum fun n => f (n + m)	case a m : ℕ N : Finset ℕ h : Late N m f : ℕ → ℝ Ns : Finset ℕ := Finset.image (fun n => n - m) N NNs : N = Finset.image (fun n => n + m) Ns ⊢ ∀ x ∈ Ns, ∀ y ∈ Ns, x + m = y + m → x = y	Please generate a tactic in lean4 to solve the state. STATE: m : ℕ N : Finset ℕ h : Late N m f : ℕ → ℝ Ns : Finset ℕ := Finset.image (fun n => n - m) N NNs : N = Finset.image (fun n => n + m) Ns ⊢ (Finset.image (fun n => n + m) Ns).sum f = Ns.sum fun n => f (n + m) TACTIC:
https://github.com/girving/ray.git	0be790285dd0fce78913b0cb9bddaffa94bd25f9	Ray/Misc/Bounds.lean	late_series_sum	[52, 1]	[66, 44]	intro a _ b _	case a m : ℕ N : Finset ℕ h : Late N m f : ℕ → ℝ Ns : Finset ℕ := Finset.image (fun n => n - m) N NNs : N = Finset.image (fun n => n + m) Ns ⊢ ∀ x ∈ Ns, ∀ y ∈ Ns, x + m = y + m → x = y	case a m : ℕ N : Finset ℕ h : Late N m f : ℕ → ℝ Ns : Finset ℕ := Finset.image (fun n => n - m) N NNs : N = Finset.image (fun n => n + m) Ns a : ℕ a✝¹ : a ∈ Ns b : ℕ a✝ : b ∈ Ns ⊢ a + m = b + m → a = b	Please generate a tactic in lean4 to solve the state. STATE: case a m : ℕ N : Finset ℕ h : Late N m f : ℕ → ℝ Ns : Finset ℕ := Finset.image (fun n => n - m) N NNs : N = Finset.image (fun n => n + m) Ns ⊢ ∀ x ∈ Ns, ∀ y ∈ Ns, x + m = y + m → x = y TACTIC:
https://github.com/girving/ray.git	0be790285dd0fce78913b0cb9bddaffa94bd25f9	Ray/Misc/Bounds.lean	late_series_sum	[52, 1]	[66, 44]	exact Nat.add_right_cancel	case a m : ℕ N : Finset ℕ h : Late N m f : ℕ → ℝ Ns : Finset ℕ := Finset.image (fun n => n - m) N NNs : N = Finset.image (fun n => n + m) Ns a : ℕ a✝¹ : a ∈ Ns b : ℕ a✝ : b ∈ Ns ⊢ a + m = b + m → a = b	no goals	Please generate a tactic in lean4 to solve the state. STATE: case a m : ℕ N : Finset ℕ h : Late N m f : ℕ → ℝ Ns : Finset ℕ := Finset.image (fun n => n - m) N NNs : N = Finset.image (fun n => n + m) Ns a : ℕ a✝¹ : a ∈ Ns b : ℕ a✝ : b ∈ Ns ⊢ a + m = b + m → a = b TACTIC:
https://github.com/girving/ray.git	0be790285dd0fce78913b0cb9bddaffa94bd25f9	Ray/Misc/Bounds.lean	late_series_sum	[52, 1]	[66, 44]	apply Finset.ext	m : ℕ N : Finset ℕ h : Late N m f : ℕ → ℝ Ns : Finset ℕ := Finset.image (fun n => n - m) N ⊢ N = Finset.image (fun n => n + m) Ns	case a m : ℕ N : Finset ℕ h : Late N m f : ℕ → ℝ Ns : Finset ℕ := Finset.image (fun n => n - m) N ⊢ ∀ (a : ℕ), a ∈ N ↔ a ∈ Finset.image (fun n => n + m) Ns	Please generate a tactic in lean4 to solve the state. STATE: m : ℕ N : Finset ℕ h : Late N m f : ℕ → ℝ Ns : Finset ℕ := Finset.image (fun n => n - m) N ⊢ N = Finset.image (fun n => n + m) Ns TACTIC:
https://github.com/girving/ray.git	0be790285dd0fce78913b0cb9bddaffa94bd25f9	Ray/Misc/Bounds.lean	late_series_sum	[52, 1]	[66, 44]	intro k	case a m : ℕ N : Finset ℕ h : Late N m f : ℕ → ℝ Ns : Finset ℕ := Finset.image (fun n => n - m) N ⊢ ∀ (a : ℕ), a ∈ N ↔ a ∈ Finset.image (fun n => n + m) Ns	case a m : ℕ N : Finset ℕ h : Late N m f : ℕ → ℝ Ns : Finset ℕ := Finset.image (fun n => n - m) N k : ℕ ⊢ k ∈ N ↔ k ∈ Finset.image (fun n => n + m) Ns	Please generate a tactic in lean4 to solve the state. STATE: case a m : ℕ N : Finset ℕ h : Late N m f : ℕ → ℝ Ns : Finset ℕ := Finset.image (fun n => n - m) N ⊢ ∀ (a : ℕ), a ∈ N ↔ a ∈ Finset.image (fun n => n + m) Ns TACTIC:
https://github.com/girving/ray.git	0be790285dd0fce78913b0cb9bddaffa94bd25f9	Ray/Misc/Bounds.lean	late_series_sum	[52, 1]	[66, 44]	rw [Finset.image_image, Finset.mem_image]	case a m : ℕ N : Finset ℕ h : Late N m f : ℕ → ℝ Ns : Finset ℕ := Finset.image (fun n => n - m) N k : ℕ ⊢ k ∈ N ↔ k ∈ Finset.image (fun n => n + m) Ns	case a m : ℕ N : Finset ℕ h : Late N m f : ℕ → ℝ Ns : Finset ℕ := Finset.image (fun n => n - m) N k : ℕ ⊢ k ∈ N ↔ ∃ a ∈ N, ((fun n => n + m) ∘ fun n => n - m) a = k	Please generate a tactic in lean4 to solve the state. STATE: case a m : ℕ N : Finset ℕ h : Late N m f : ℕ → ℝ Ns : Finset ℕ := Finset.image (fun n => n - m) N k : ℕ ⊢ k ∈ N ↔ k ∈ Finset.image (fun n => n + m) Ns TACTIC:
https://github.com/girving/ray.git	0be790285dd0fce78913b0cb9bddaffa94bd25f9	Ray/Misc/Bounds.lean	late_series_sum	[52, 1]	[66, 44]	simp	case a m : ℕ N : Finset ℕ h : Late N m f : ℕ → ℝ Ns : Finset ℕ := Finset.image (fun n => n - m) N k : ℕ ⊢ k ∈ N ↔ ∃ a ∈ N, ((fun n => n + m) ∘ fun n => n - m) a = k	case a m : ℕ N : Finset ℕ h : Late N m f : ℕ → ℝ Ns : Finset ℕ := Finset.image (fun n => n - m) N k : ℕ ⊢ k ∈ N ↔ ∃ a ∈ N, a - m + m = k	Please generate a tactic in lean4 to solve the state. STATE: case a m : ℕ N : Finset ℕ h : Late N m f : ℕ → ℝ Ns : Finset ℕ := Finset.image (fun n => n - m) N k : ℕ ⊢ k ∈ N ↔ ∃ a ∈ N, ((fun n => n + m) ∘ fun n => n - m) a = k TACTIC:
https://github.com/girving/ray.git	0be790285dd0fce78913b0cb9bddaffa94bd25f9	Ray/Misc/Bounds.lean	late_series_sum	[52, 1]	[66, 44]	apply Iff.intro	case a m : ℕ N : Finset ℕ h : Late N m f : ℕ → ℝ Ns : Finset ℕ := Finset.image (fun n => n - m) N k : ℕ ⊢ k ∈ N ↔ ∃ a ∈ N, a - m + m = k	case a.mp m : ℕ N : Finset ℕ h : Late N m f : ℕ → ℝ Ns : Finset ℕ := Finset.image (fun n => n - m) N k : ℕ ⊢ k ∈ N → ∃ a ∈ N, a - m + m = k case a.mpr m : ℕ N : Finset ℕ h : Late N m f : ℕ → ℝ Ns : Finset ℕ := Finset.image (fun n => n - m) N k : ℕ ⊢ (∃ a ∈ N, a - m + m = k) → k ∈ N	Please generate a tactic in lean4 to solve the state. STATE: case a m : ℕ N : Finset ℕ h : Late N m f : ℕ → ℝ Ns : Finset ℕ := Finset.image (fun n => n - m) N k : ℕ ⊢ k ∈ N ↔ ∃ a ∈ N, a - m + m = k TACTIC:
https://github.com/girving/ray.git	0be790285dd0fce78913b0cb9bddaffa94bd25f9	Ray/Misc/Bounds.lean	late_series_sum	[52, 1]	[66, 44]	intro kN	case a.mp m : ℕ N : Finset ℕ h : Late N m f : ℕ → ℝ Ns : Finset ℕ := Finset.image (fun n => n - m) N k : ℕ ⊢ k ∈ N → ∃ a ∈ N, a - m + m = k	case a.mp m : ℕ N : Finset ℕ h : Late N m f : ℕ → ℝ Ns : Finset ℕ := Finset.image (fun n => n - m) N k : ℕ kN : k ∈ N ⊢ ∃ a ∈ N, a - m + m = k	Please generate a tactic in lean4 to solve the state. STATE: case a.mp m : ℕ N : Finset ℕ h : Late N m f : ℕ → ℝ Ns : Finset ℕ := Finset.image (fun n => n - m) N k : ℕ ⊢ k ∈ N → ∃ a ∈ N, a - m + m = k TACTIC:
https://github.com/girving/ray.git	0be790285dd0fce78913b0cb9bddaffa94bd25f9	Ray/Misc/Bounds.lean	late_series_sum	[52, 1]	[66, 44]	exists k	case a.mp m : ℕ N : Finset ℕ h : Late N m f : ℕ → ℝ Ns : Finset ℕ := Finset.image (fun n => n - m) N k : ℕ kN : k ∈ N ⊢ ∃ a ∈ N, a - m + m = k	case a.mp m : ℕ N : Finset ℕ h : Late N m f : ℕ → ℝ Ns : Finset ℕ := Finset.image (fun n => n - m) N k : ℕ kN : k ∈ N ⊢ k ∈ N ∧ k - m + m = k	Please generate a tactic in lean4 to solve the state. STATE: case a.mp m : ℕ N : Finset ℕ h : Late N m f : ℕ → ℝ Ns : Finset ℕ := Finset.image (fun n => n - m) N k : ℕ kN : k ∈ N ⊢ ∃ a ∈ N, a - m + m = k TACTIC:
https://github.com/girving/ray.git	0be790285dd0fce78913b0cb9bddaffa94bd25f9	Ray/Misc/Bounds.lean	late_series_sum	[52, 1]	[66, 44]	apply And.intro	case a.mp m : ℕ N : Finset ℕ h : Late N m f : ℕ → ℝ Ns : Finset ℕ := Finset.image (fun n => n - m) N k : ℕ kN : k ∈ N ⊢ k ∈ N ∧ k - m + m = k	case a.mp.left m : ℕ N : Finset ℕ h : Late N m f : ℕ → ℝ Ns : Finset ℕ := Finset.image (fun n => n - m) N k : ℕ kN : k ∈ N ⊢ k ∈ N case a.mp.right m : ℕ N : Finset ℕ h : Late N m f : ℕ → ℝ Ns : Finset ℕ := Finset.image (fun n => n - m) N k : ℕ kN : k ∈ N ⊢ k - m + m = k	Please generate a tactic in lean4 to solve the state. STATE: case a.mp m : ℕ N : Finset ℕ h : Late N m f : ℕ → ℝ Ns : Finset ℕ := Finset.image (fun n => n - m) N k : ℕ kN : k ∈ N ⊢ k ∈ N ∧ k - m + m = k TACTIC:
https://github.com/girving/ray.git	0be790285dd0fce78913b0cb9bddaffa94bd25f9	Ray/Misc/Bounds.lean	late_series_sum	[52, 1]	[66, 44]	assumption	case a.mp.left m : ℕ N : Finset ℕ h : Late N m f : ℕ → ℝ Ns : Finset ℕ := Finset.image (fun n => n - m) N k : ℕ kN : k ∈ N ⊢ k ∈ N case a.mp.right m : ℕ N : Finset ℕ h : Late N m f : ℕ → ℝ Ns : Finset ℕ := Finset.image (fun n => n - m) N k : ℕ kN : k ∈ N ⊢ k - m + m = k	case a.mp.right m : ℕ N : Finset ℕ h : Late N m f : ℕ → ℝ Ns : Finset ℕ := Finset.image (fun n => n - m) N k : ℕ kN : k ∈ N ⊢ k - m + m = k	Please generate a tactic in lean4 to solve the state. STATE: case a.mp.left m : ℕ N : Finset ℕ h : Late N m f : ℕ → ℝ Ns : Finset ℕ := Finset.image (fun n => n - m) N k : ℕ kN : k ∈ N ⊢ k ∈ N case a.mp.right m : ℕ N : Finset ℕ h : Late N m f : ℕ → ℝ Ns : Finset ℕ := Finset.image (fun n => n - m) N k : ℕ kN : k ∈ N ⊢ k - m + m = k TACTIC:
https://github.com/girving/ray.git	0be790285dd0fce78913b0cb9bddaffa94bd25f9	Ray/Misc/Bounds.lean	late_series_sum	[52, 1]	[66, 44]	exact Nat.sub_add_cancel (h k kN)	case a.mp.right m : ℕ N : Finset ℕ h : Late N m f : ℕ → ℝ Ns : Finset ℕ := Finset.image (fun n => n - m) N k : ℕ kN : k ∈ N ⊢ k - m + m = k	no goals	Please generate a tactic in lean4 to solve the state. STATE: case a.mp.right m : ℕ N : Finset ℕ h : Late N m f : ℕ → ℝ Ns : Finset ℕ := Finset.image (fun n => n - m) N k : ℕ kN : k ∈ N ⊢ k - m + m = k TACTIC:
https://github.com/girving/ray.git	0be790285dd0fce78913b0cb9bddaffa94bd25f9	Ray/Misc/Bounds.lean	late_series_sum	[52, 1]	[66, 44]	intro ha	case a.mpr m : ℕ N : Finset ℕ h : Late N m f : ℕ → ℝ Ns : Finset ℕ := Finset.image (fun n => n - m) N k : ℕ ⊢ (∃ a ∈ N, a - m + m = k) → k ∈ N	case a.mpr m : ℕ N : Finset ℕ h : Late N m f : ℕ → ℝ Ns : Finset ℕ := Finset.image (fun n => n - m) N k : ℕ ha : ∃ a ∈ N, a - m + m = k ⊢ k ∈ N	Please generate a tactic in lean4 to solve the state. STATE: case a.mpr m : ℕ N : Finset ℕ h : Late N m f : ℕ → ℝ Ns : Finset ℕ := Finset.image (fun n => n - m) N k : ℕ ⊢ (∃ a ∈ N, a - m + m = k) → k ∈ N TACTIC:
https://github.com/girving/ray.git	0be790285dd0fce78913b0cb9bddaffa94bd25f9	Ray/Misc/Bounds.lean	late_series_sum	[52, 1]	[66, 44]	rcases ha with ⟨a, aN, ak⟩	case a.mpr m : ℕ N : Finset ℕ h : Late N m f : ℕ → ℝ Ns : Finset ℕ := Finset.image (fun n => n - m) N k : ℕ ha : ∃ a ∈ N, a - m + m = k ⊢ k ∈ N	case a.mpr.intro.intro m : ℕ N : Finset ℕ h : Late N m f : ℕ → ℝ Ns : Finset ℕ := Finset.image (fun n => n - m) N k a : ℕ aN : a ∈ N ak : a - m + m = k ⊢ k ∈ N	Please generate a tactic in lean4 to solve the state. STATE: case a.mpr m : ℕ N : Finset ℕ h : Late N m f : ℕ → ℝ Ns : Finset ℕ := Finset.image (fun n => n - m) N k : ℕ ha : ∃ a ∈ N, a - m + m = k ⊢ k ∈ N TACTIC:
https://github.com/girving/ray.git	0be790285dd0fce78913b0cb9bddaffa94bd25f9	Ray/Misc/Bounds.lean	late_series_sum	[52, 1]	[66, 44]	rw [Nat.sub_add_cancel (h a aN)] at ak	case a.mpr.intro.intro m : ℕ N : Finset ℕ h : Late N m f : ℕ → ℝ Ns : Finset ℕ := Finset.image (fun n => n - m) N k a : ℕ aN : a ∈ N ak : a - m + m = k ⊢ k ∈ N	case a.mpr.intro.intro m : ℕ N : Finset ℕ h : Late N m f : ℕ → ℝ Ns : Finset ℕ := Finset.image (fun n => n - m) N k a : ℕ aN : a ∈ N ak : a = k ⊢ k ∈ N	Please generate a tactic in lean4 to solve the state. STATE: case a.mpr.intro.intro m : ℕ N : Finset ℕ h : Late N m f : ℕ → ℝ Ns : Finset ℕ := Finset.image (fun n => n - m) N k a : ℕ aN : a ∈ N ak : a - m + m = k ⊢ k ∈ N TACTIC:
https://github.com/girving/ray.git	0be790285dd0fce78913b0cb9bddaffa94bd25f9	Ray/Misc/Bounds.lean	late_series_sum	[52, 1]	[66, 44]	rw [← ak]	case a.mpr.intro.intro m : ℕ N : Finset ℕ h : Late N m f : ℕ → ℝ Ns : Finset ℕ := Finset.image (fun n => n - m) N k a : ℕ aN : a ∈ N ak : a = k ⊢ k ∈ N	case a.mpr.intro.intro m : ℕ N : Finset ℕ h : Late N m f : ℕ → ℝ Ns : Finset ℕ := Finset.image (fun n => n - m) N k a : ℕ aN : a ∈ N ak : a = k ⊢ a ∈ N	Please generate a tactic in lean4 to solve the state. STATE: case a.mpr.intro.intro m : ℕ N : Finset ℕ h : Late N m f : ℕ → ℝ Ns : Finset ℕ := Finset.image (fun n => n - m) N k a : ℕ aN : a ∈ N ak : a = k ⊢ k ∈ N TACTIC:
https://github.com/girving/ray.git	0be790285dd0fce78913b0cb9bddaffa94bd25f9	Ray/Misc/Bounds.lean	late_series_sum	[52, 1]	[66, 44]	assumption	case a.mpr.intro.intro m : ℕ N : Finset ℕ h : Late N m f : ℕ → ℝ Ns : Finset ℕ := Finset.image (fun n => n - m) N k a : ℕ aN : a ∈ N ak : a = k ⊢ a ∈ N	no goals	Please generate a tactic in lean4 to solve the state. STATE: case a.mpr.intro.intro m : ℕ N : Finset ℕ h : Late N m f : ℕ → ℝ Ns : Finset ℕ := Finset.image (fun n => n - m) N k a : ℕ aN : a ∈ N ak : a = k ⊢ a ∈ N TACTIC:
https://github.com/girving/ray.git	0be790285dd0fce78913b0cb9bddaffa94bd25f9	Ray/Misc/Bounds.lean	late_series_sum'	[69, 1]	[72, 28]	exists Finset.image (fun n ↦ n - m) N	m : ℕ N : Finset ℕ h : Late N m f : ℕ → ℝ ⊢ ∃ M, N.sum f = M.sum fun n => f (n + m)	m : ℕ N : Finset ℕ h : Late N m f : ℕ → ℝ ⊢ N.sum f = (Finset.image (fun n => n - m) N).sum fun n => f (n + m)	Please generate a tactic in lean4 to solve the state. STATE: m : ℕ N : Finset ℕ h : Late N m f : ℕ → ℝ ⊢ ∃ M, N.sum f = M.sum fun n => f (n + m) TACTIC:
https://github.com/girving/ray.git	0be790285dd0fce78913b0cb9bddaffa94bd25f9	Ray/Misc/Bounds.lean	late_series_sum'	[69, 1]	[72, 28]	exact late_series_sum h f	m : ℕ N : Finset ℕ h : Late N m f : ℕ → ℝ ⊢ N.sum f = (Finset.image (fun n => n - m) N).sum fun n => f (n + m)	no goals	Please generate a tactic in lean4 to solve the state. STATE: m : ℕ N : Finset ℕ h : Late N m f : ℕ → ℝ ⊢ N.sum f = (Finset.image (fun n => n - m) N).sum fun n => f (n + m) TACTIC:
https://github.com/girving/ray.git	0be790285dd0fce78913b0cb9bddaffa94bd25f9	Ray/Misc/Bounds.lean	late_geometric_bound	[74, 1]	[83, 35]	rcases late_series_sum' h (fun n ↦ a^n) with ⟨M,L⟩	m : ℕ a : ℝ N : Finset ℕ h : Late N m a0 : 0 ≤ a a1 : a < 1 ⊢ (N.sum fun n => a ^ n) ≤ a ^ m * (1 - a)⁻¹	case intro m : ℕ a : ℝ N : Finset ℕ h : Late N m a0 : 0 ≤ a a1 : a < 1 M : Finset ℕ L : (N.sum fun n => a ^ n) = M.sum fun n => a ^ (n + m) ⊢ (N.sum fun n => a ^ n) ≤ a ^ m * (1 - a)⁻¹	Please generate a tactic in lean4 to solve the state. STATE: m : ℕ a : ℝ N : Finset ℕ h : Late N m a0 : 0 ≤ a a1 : a < 1 ⊢ (N.sum fun n => a ^ n) ≤ a ^ m * (1 - a)⁻¹ TACTIC:
https://github.com/girving/ray.git	0be790285dd0fce78913b0cb9bddaffa94bd25f9	Ray/Misc/Bounds.lean	late_geometric_bound	[74, 1]	[83, 35]	rw [L]	case intro m : ℕ a : ℝ N : Finset ℕ h : Late N m a0 : 0 ≤ a a1 : a < 1 M : Finset ℕ L : (N.sum fun n => a ^ n) = M.sum fun n => a ^ (n + m) ⊢ (N.sum fun n => a ^ n) ≤ a ^ m * (1 - a)⁻¹	case intro m : ℕ a : ℝ N : Finset ℕ h : Late N m a0 : 0 ≤ a a1 : a < 1 M : Finset ℕ L : (N.sum fun n => a ^ n) = M.sum fun n => a ^ (n + m) ⊢ (M.sum fun n => a ^ (n + m)) ≤ a ^ m * (1 - a)⁻¹	Please generate a tactic in lean4 to solve the state. STATE: case intro m : ℕ a : ℝ N : Finset ℕ h : Late N m a0 : 0 ≤ a a1 : a < 1 M : Finset ℕ L : (N.sum fun n => a ^ n) = M.sum fun n => a ^ (n + m) ⊢ (N.sum fun n => a ^ n) ≤ a ^ m * (1 - a)⁻¹ TACTIC:
https://github.com/girving/ray.git	0be790285dd0fce78913b0cb9bddaffa94bd25f9	Ray/Misc/Bounds.lean	late_geometric_bound	[74, 1]	[83, 35]	clear L	case intro m : ℕ a : ℝ N : Finset ℕ h : Late N m a0 : 0 ≤ a a1 : a < 1 M : Finset ℕ L : (N.sum fun n => a ^ n) = M.sum fun n => a ^ (n + m) ⊢ (M.sum fun n => a ^ (n + m)) ≤ a ^ m * (1 - a)⁻¹	case intro m : ℕ a : ℝ N : Finset ℕ h : Late N m a0 : 0 ≤ a a1 : a < 1 M : Finset ℕ ⊢ (M.sum fun n => a ^ (n + m)) ≤ a ^ m * (1 - a)⁻¹	Please generate a tactic in lean4 to solve the state. STATE: case intro m : ℕ a : ℝ N : Finset ℕ h : Late N m a0 : 0 ≤ a a1 : a < 1 M : Finset ℕ L : (N.sum fun n => a ^ n) = M.sum fun n => a ^ (n + m) ⊢ (M.sum fun n => a ^ (n + m)) ≤ a ^ m * (1 - a)⁻¹ TACTIC:
https://github.com/girving/ray.git	0be790285dd0fce78913b0cb9bddaffa94bd25f9	Ray/Misc/Bounds.lean	late_geometric_bound	[74, 1]	[83, 35]	have pa : (fun n ↦ a^(n + m)) = (fun n ↦ a^n * a^m) := by apply funext; intro n; rw [pow_add]	case intro m : ℕ a : ℝ N : Finset ℕ h : Late N m a0 : 0 ≤ a a1 : a < 1 M : Finset ℕ ⊢ (M.sum fun n => a ^ (n + m)) ≤ a ^ m * (1 - a)⁻¹	case intro m : ℕ a : ℝ N : Finset ℕ h : Late N m a0 : 0 ≤ a a1 : a < 1 M : Finset ℕ pa : (fun n => a ^ (n + m)) = fun n => a ^ n * a ^ m ⊢ (M.sum fun n => a ^ (n + m)) ≤ a ^ m * (1 - a)⁻¹	Please generate a tactic in lean4 to solve the state. STATE: case intro m : ℕ a : ℝ N : Finset ℕ h : Late N m a0 : 0 ≤ a a1 : a < 1 M : Finset ℕ ⊢ (M.sum fun n => a ^ (n + m)) ≤ a ^ m * (1 - a)⁻¹ TACTIC:
https://github.com/girving/ray.git	0be790285dd0fce78913b0cb9bddaffa94bd25f9	Ray/Misc/Bounds.lean	late_geometric_bound	[74, 1]	[83, 35]	calc M.sum (fun n ↦ a^(n + m)) = M.sum (fun n ↦ a^n * a^m) := by rw [ pa ] _ = M.sum (fun n ↦ a^n) * a^m := (Finset.sum_mul _ _ _).symm _ ≤ (1 - a)⁻¹ * a^m := by bound [partial_geometric_bound M a0 a1] _ = a^m * (1 - a)⁻¹ := by ring	case intro m : ℕ a : ℝ N : Finset ℕ h : Late N m a0 : 0 ≤ a a1 : a < 1 M : Finset ℕ pa : (fun n => a ^ (n + m)) = fun n => a ^ n * a ^ m ⊢ (M.sum fun n => a ^ (n + m)) ≤ a ^ m * (1 - a)⁻¹	no goals	Please generate a tactic in lean4 to solve the state. STATE: case intro m : ℕ a : ℝ N : Finset ℕ h : Late N m a0 : 0 ≤ a a1 : a < 1 M : Finset ℕ pa : (fun n => a ^ (n + m)) = fun n => a ^ n * a ^ m ⊢ (M.sum fun n => a ^ (n + m)) ≤ a ^ m * (1 - a)⁻¹ TACTIC:
https://github.com/girving/ray.git	0be790285dd0fce78913b0cb9bddaffa94bd25f9	Ray/Misc/Bounds.lean	late_geometric_bound	[74, 1]	[83, 35]	apply funext	m : ℕ a : ℝ N : Finset ℕ h : Late N m a0 : 0 ≤ a a1 : a < 1 M : Finset ℕ ⊢ (fun n => a ^ (n + m)) = fun n => a ^ n * a ^ m	case h m : ℕ a : ℝ N : Finset ℕ h : Late N m a0 : 0 ≤ a a1 : a < 1 M : Finset ℕ ⊢ ∀ (x : ℕ), a ^ (x + m) = a ^ x * a ^ m	Please generate a tactic in lean4 to solve the state. STATE: m : ℕ a : ℝ N : Finset ℕ h : Late N m a0 : 0 ≤ a a1 : a < 1 M : Finset ℕ ⊢ (fun n => a ^ (n + m)) = fun n => a ^ n * a ^ m TACTIC:
https://github.com/girving/ray.git	0be790285dd0fce78913b0cb9bddaffa94bd25f9	Ray/Misc/Bounds.lean	late_geometric_bound	[74, 1]	[83, 35]	intro n	case h m : ℕ a : ℝ N : Finset ℕ h : Late N m a0 : 0 ≤ a a1 : a < 1 M : Finset ℕ ⊢ ∀ (x : ℕ), a ^ (x + m) = a ^ x * a ^ m	case h m : ℕ a : ℝ N : Finset ℕ h : Late N m a0 : 0 ≤ a a1 : a < 1 M : Finset ℕ n : ℕ ⊢ a ^ (n + m) = a ^ n * a ^ m	Please generate a tactic in lean4 to solve the state. STATE: case h m : ℕ a : ℝ N : Finset ℕ h : Late N m a0 : 0 ≤ a a1 : a < 1 M : Finset ℕ ⊢ ∀ (x : ℕ), a ^ (x + m) = a ^ x * a ^ m TACTIC:
https://github.com/girving/ray.git	0be790285dd0fce78913b0cb9bddaffa94bd25f9	Ray/Misc/Bounds.lean	late_geometric_bound	[74, 1]	[83, 35]	rw [pow_add]	case h m : ℕ a : ℝ N : Finset ℕ h : Late N m a0 : 0 ≤ a a1 : a < 1 M : Finset ℕ n : ℕ ⊢ a ^ (n + m) = a ^ n * a ^ m	no goals	Please generate a tactic in lean4 to solve the state. STATE: case h m : ℕ a : ℝ N : Finset ℕ h : Late N m a0 : 0 ≤ a a1 : a < 1 M : Finset ℕ n : ℕ ⊢ a ^ (n + m) = a ^ n * a ^ m TACTIC:
https://github.com/girving/ray.git	0be790285dd0fce78913b0cb9bddaffa94bd25f9	Ray/Misc/Bounds.lean	late_geometric_bound	[74, 1]	[83, 35]	rw [ pa ]	m : ℕ a : ℝ N : Finset ℕ h : Late N m a0 : 0 ≤ a a1 : a < 1 M : Finset ℕ pa : (fun n => a ^ (n + m)) = fun n => a ^ n * a ^ m ⊢ (M.sum fun n => a ^ (n + m)) = M.sum fun n => a ^ n * a ^ m	no goals	Please generate a tactic in lean4 to solve the state. STATE: m : ℕ a : ℝ N : Finset ℕ h : Late N m a0 : 0 ≤ a a1 : a < 1 M : Finset ℕ pa : (fun n => a ^ (n + m)) = fun n => a ^ n * a ^ m ⊢ (M.sum fun n => a ^ (n + m)) = M.sum fun n => a ^ n * a ^ m TACTIC:
https://github.com/girving/ray.git	0be790285dd0fce78913b0cb9bddaffa94bd25f9	Ray/Misc/Bounds.lean	late_geometric_bound	[74, 1]	[83, 35]	bound [partial_geometric_bound M a0 a1]	m : ℕ a : ℝ N : Finset ℕ h : Late N m a0 : 0 ≤ a a1 : a < 1 M : Finset ℕ pa : (fun n => a ^ (n + m)) = fun n => a ^ n * a ^ m ⊢ (M.sum fun n => a ^ n) * a ^ m ≤ (1 - a)⁻¹ * a ^ m	no goals	Please generate a tactic in lean4 to solve the state. STATE: m : ℕ a : ℝ N : Finset ℕ h : Late N m a0 : 0 ≤ a a1 : a < 1 M : Finset ℕ pa : (fun n => a ^ (n + m)) = fun n => a ^ n * a ^ m ⊢ (M.sum fun n => a ^ n) * a ^ m ≤ (1 - a)⁻¹ * a ^ m TACTIC:
https://github.com/girving/ray.git	0be790285dd0fce78913b0cb9bddaffa94bd25f9	Ray/Misc/Bounds.lean	late_geometric_bound	[74, 1]	[83, 35]	ring	m : ℕ a : ℝ N : Finset ℕ h : Late N m a0 : 0 ≤ a a1 : a < 1 M : Finset ℕ pa : (fun n => a ^ (n + m)) = fun n => a ^ n * a ^ m ⊢ (1 - a)⁻¹ * a ^ m = a ^ m * (1 - a)⁻¹	no goals	Please generate a tactic in lean4 to solve the state. STATE: m : ℕ a : ℝ N : Finset ℕ h : Late N m a0 : 0 ≤ a a1 : a < 1 M : Finset ℕ pa : (fun n => a ^ (n + m)) = fun n => a ^ n * a ^ m ⊢ (1 - a)⁻¹ * a ^ m = a ^ m * (1 - a)⁻¹ TACTIC:
https://github.com/girving/ray.git	0be790285dd0fce78913b0cb9bddaffa94bd25f9	Ray/Misc/Bounds.lean	finset_partition	[85, 1]	[95, 21]	apply Finset.ext	A B : Finset ℕ ⊢ A = A \ B ∪ A ∩ B	case a A B : Finset ℕ ⊢ ∀ (a : ℕ), a ∈ A ↔ a ∈ A \ B ∪ A ∩ B	Please generate a tactic in lean4 to solve the state. STATE: A B : Finset ℕ ⊢ A = A \ B ∪ A ∩ B TACTIC:
https://github.com/girving/ray.git	0be790285dd0fce78913b0cb9bddaffa94bd25f9	Ray/Misc/Bounds.lean	finset_partition	[85, 1]	[95, 21]	simp only [Finset.mem_union, Finset.mem_sdiff, Finset.mem_inter]	case a A B : Finset ℕ ⊢ ∀ (a : ℕ), a ∈ A ↔ a ∈ A \ B ∪ A ∩ B	case a A B : Finset ℕ ⊢ ∀ (a : ℕ), a ∈ A ↔ a ∈ A ∧ a ∉ B ∨ a ∈ A ∧ a ∈ B	Please generate a tactic in lean4 to solve the state. STATE: case a A B : Finset ℕ ⊢ ∀ (a : ℕ), a ∈ A ↔ a ∈ A \ B ∪ A ∩ B TACTIC:
https://github.com/girving/ray.git	0be790285dd0fce78913b0cb9bddaffa94bd25f9	Ray/Misc/Bounds.lean	finset_partition	[85, 1]	[95, 21]	intro x	case a A B : Finset ℕ ⊢ ∀ (a : ℕ), a ∈ A ↔ a ∈ A ∧ a ∉ B ∨ a ∈ A ∧ a ∈ B	case a A B : Finset ℕ x : ℕ ⊢ x ∈ A ↔ x ∈ A ∧ x ∉ B ∨ x ∈ A ∧ x ∈ B	Please generate a tactic in lean4 to solve the state. STATE: case a A B : Finset ℕ ⊢ ∀ (a : ℕ), a ∈ A ↔ a ∈ A ∧ a ∉ B ∨ a ∈ A ∧ a ∈ B TACTIC:
https://github.com/girving/ray.git	0be790285dd0fce78913b0cb9bddaffa94bd25f9	Ray/Misc/Bounds.lean	finset_partition	[85, 1]	[95, 21]	constructor	case a A B : Finset ℕ x : ℕ ⊢ x ∈ A ↔ x ∈ A ∧ x ∉ B ∨ x ∈ A ∧ x ∈ B	case a.mp A B : Finset ℕ x : ℕ ⊢ x ∈ A → x ∈ A ∧ x ∉ B ∨ x ∈ A ∧ x ∈ B case a.mpr A B : Finset ℕ x : ℕ ⊢ x ∈ A ∧ x ∉ B ∨ x ∈ A ∧ x ∈ B → x ∈ A	Please generate a tactic in lean4 to solve the state. STATE: case a A B : Finset ℕ x : ℕ ⊢ x ∈ A ↔ x ∈ A ∧ x ∉ B ∨ x ∈ A ∧ x ∈ B TACTIC:
https://github.com/girving/ray.git	0be790285dd0fce78913b0cb9bddaffa94bd25f9	Ray/Misc/Bounds.lean	finset_partition	[85, 1]	[95, 21]	intro a	case a.mp A B : Finset ℕ x : ℕ ⊢ x ∈ A → x ∈ A ∧ x ∉ B ∨ x ∈ A ∧ x ∈ B	case a.mp A B : Finset ℕ x : ℕ a : x ∈ A ⊢ x ∈ A ∧ x ∉ B ∨ x ∈ A ∧ x ∈ B	Please generate a tactic in lean4 to solve the state. STATE: case a.mp A B : Finset ℕ x : ℕ ⊢ x ∈ A → x ∈ A ∧ x ∉ B ∨ x ∈ A ∧ x ∈ B TACTIC:
https://github.com/girving/ray.git	0be790285dd0fce78913b0cb9bddaffa94bd25f9	Ray/Misc/Bounds.lean	finset_partition	[85, 1]	[95, 21]	by_cases b : x ∈ B	case a.mp A B : Finset ℕ x : ℕ a : x ∈ A ⊢ x ∈ A ∧ x ∉ B ∨ x ∈ A ∧ x ∈ B	case pos A B : Finset ℕ x : ℕ a : x ∈ A b : x ∈ B ⊢ x ∈ A ∧ x ∉ B ∨ x ∈ A ∧ x ∈ B case neg A B : Finset ℕ x : ℕ a : x ∈ A b : x ∉ B ⊢ x ∈ A ∧ x ∉ B ∨ x ∈ A ∧ x ∈ B	Please generate a tactic in lean4 to solve the state. STATE: case a.mp A B : Finset ℕ x : ℕ a : x ∈ A ⊢ x ∈ A ∧ x ∉ B ∨ x ∈ A ∧ x ∈ B TACTIC:
https://github.com/girving/ray.git	0be790285dd0fce78913b0cb9bddaffa94bd25f9	Ray/Misc/Bounds.lean	finset_partition	[85, 1]	[95, 21]	right	case pos A B : Finset ℕ x : ℕ a : x ∈ A b : x ∈ B ⊢ x ∈ A ∧ x ∉ B ∨ x ∈ A ∧ x ∈ B	case pos.h A B : Finset ℕ x : ℕ a : x ∈ A b : x ∈ B ⊢ x ∈ A ∧ x ∈ B	Please generate a tactic in lean4 to solve the state. STATE: case pos A B : Finset ℕ x : ℕ a : x ∈ A b : x ∈ B ⊢ x ∈ A ∧ x ∉ B ∨ x ∈ A ∧ x ∈ B TACTIC:
https://github.com/girving/ray.git	0be790285dd0fce78913b0cb9bddaffa94bd25f9	Ray/Misc/Bounds.lean	finset_partition	[85, 1]	[95, 21]	use a,b	case pos.h A B : Finset ℕ x : ℕ a : x ∈ A b : x ∈ B ⊢ x ∈ A ∧ x ∈ B	no goals	Please generate a tactic in lean4 to solve the state. STATE: case pos.h A B : Finset ℕ x : ℕ a : x ∈ A b : x ∈ B ⊢ x ∈ A ∧ x ∈ B TACTIC:
https://github.com/girving/ray.git	0be790285dd0fce78913b0cb9bddaffa94bd25f9	Ray/Misc/Bounds.lean	finset_partition	[85, 1]	[95, 21]	left	case neg A B : Finset ℕ x : ℕ a : x ∈ A b : x ∉ B ⊢ x ∈ A ∧ x ∉ B ∨ x ∈ A ∧ x ∈ B	case neg.h A B : Finset ℕ x : ℕ a : x ∈ A b : x ∉ B ⊢ x ∈ A ∧ x ∉ B	Please generate a tactic in lean4 to solve the state. STATE: case neg A B : Finset ℕ x : ℕ a : x ∈ A b : x ∉ B ⊢ x ∈ A ∧ x ∉ B ∨ x ∈ A ∧ x ∈ B TACTIC:
https://github.com/girving/ray.git	0be790285dd0fce78913b0cb9bddaffa94bd25f9	Ray/Misc/Bounds.lean	finset_partition	[85, 1]	[95, 21]	use a,b	case neg.h A B : Finset ℕ x : ℕ a : x ∈ A b : x ∉ B ⊢ x ∈ A ∧ x ∉ B	no goals	Please generate a tactic in lean4 to solve the state. STATE: case neg.h A B : Finset ℕ x : ℕ a : x ∈ A b : x ∉ B ⊢ x ∈ A ∧ x ∉ B TACTIC:
https://github.com/girving/ray.git	0be790285dd0fce78913b0cb9bddaffa94bd25f9	Ray/Misc/Bounds.lean	finset_partition	[85, 1]	[95, 21]	intro h	case a.mpr A B : Finset ℕ x : ℕ ⊢ x ∈ A ∧ x ∉ B ∨ x ∈ A ∧ x ∈ B → x ∈ A	case a.mpr A B : Finset ℕ x : ℕ h : x ∈ A ∧ x ∉ B ∨ x ∈ A ∧ x ∈ B ⊢ x ∈ A	Please generate a tactic in lean4 to solve the state. STATE: case a.mpr A B : Finset ℕ x : ℕ ⊢ x ∈ A ∧ x ∉ B ∨ x ∈ A ∧ x ∈ B → x ∈ A TACTIC:

https://github.com/girving/ray.git

0be790285dd0fce78913b0cb9bddaffa94bd25f9

Ray/Dynamics/Multibrot/Potential.lean

iter_error_le_log_log_abs

[245, 1]

[259, 83]

positivity

c✝ z✝ : 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 hl : 1.38 ≤ (Complex.abs z).log hll : 0.32 ≤ (Complex.abs z).log.log ⊢ 0 ≤ 1.38

no goals

Please generate a tactic in lean4 to solve the state. STATE: c✝ z✝ : 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 hl : 1.38 ≤ (Complex.abs z).log hll : 0.32 ≤ (Complex.abs z).log.log ⊢ 0 ≤ 1.38 TACTIC:

https://github.com/girving/ray.git

0be790285dd0fce78913b0cb9bddaffa94bd25f9

Ray/Dynamics/Multibrot/Potential.lean

iter_error_le_log_log_abs

[245, 1]

[259, 83]

positivity

c✝ z✝ : 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 hl : 1.38 ≤ (Complex.abs z).log hll : 0.32 ≤ (Complex.abs z).log.log ⊢ 0 ≤ Complex.abs z

no goals

Please generate a tactic in lean4 to solve the state. STATE: c✝ z✝ : 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 hl : 1.38 ≤ (Complex.abs z).log hll : 0.32 ≤ (Complex.abs z).log.log ⊢ 0 ≤ Complex.abs z TACTIC:

https://github.com/girving/ray.git

0be790285dd0fce78913b0cb9bddaffa94bd25f9

Ray/Dynamics/Multibrot/Potential.lean

potential_approx

[262, 1]

[295, 40]

set s := superF d

c✝ z✝ : 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 ⊢ |⋯.potential c ↑z - 1 / Complex.abs z| ≤ potential_error d c z

c✝ z✝ : 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 s : Super (f d) d OnePoint.infty := superF d ⊢ |s.potential c ↑z - 1 / Complex.abs z| ≤ potential_error d c z

Please generate a tactic in lean4 to solve the state. STATE: c✝ z✝ : 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 ⊢ |⋯.potential c ↑z - 1 / Complex.abs z| ≤ potential_error d c z TACTIC:

https://github.com/girving/ray.git

0be790285dd0fce78913b0cb9bddaffa94bd25f9

Ray/Dynamics/Multibrot/Potential.lean

potential_approx

[262, 1]

[295, 40]

have z3 : 3 ≤ abs z := le_trans (by norm_num) z4

c✝ z✝ : 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 s : Super (f d) d OnePoint.infty := superF d ⊢ |s.potential c ↑z - 1 / Complex.abs z| ≤ potential_error d c z

c✝ z✝ : 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 s : Super (f d) d OnePoint.infty := superF d z3 : 3 ≤ Complex.abs z ⊢ |s.potential c ↑z - 1 / Complex.abs z| ≤ potential_error d c z

Please generate a tactic in lean4 to solve the state. STATE: c✝ z✝ : 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 s : Super (f d) d OnePoint.infty := superF d ⊢ |s.potential c ↑z - 1 / Complex.abs z| ≤ potential_error d c z TACTIC:

https://github.com/girving/ray.git

0be790285dd0fce78913b0cb9bddaffa94bd25f9

Ray/Dynamics/Multibrot/Potential.lean

potential_approx

[262, 1]

[295, 40]

have z0 : 0 < abs z := lt_of_lt_of_le (by norm_num) z3

c✝ z✝ : 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 s : Super (f d) d OnePoint.infty := superF d z3 : 3 ≤ Complex.abs z ⊢ |s.potential c ↑z - 1 / Complex.abs z| ≤ potential_error d c z

c✝ z✝ : 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 s : Super (f d) d OnePoint.infty := superF d z3 : 3 ≤ Complex.abs z z0 : 0 < Complex.abs z ⊢ |s.potential c ↑z - 1 / Complex.abs z| ≤ potential_error d c z

Please generate a tactic in lean4 to solve the state. STATE: c✝ z✝ : 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 s : Super (f d) d OnePoint.infty := superF d z3 : 3 ≤ Complex.abs z ⊢ |s.potential c ↑z - 1 / Complex.abs z| ≤ potential_error d c z TACTIC:

https://github.com/girving/ray.git

0be790285dd0fce78913b0cb9bddaffa94bd25f9

Ray/Dynamics/Multibrot/Potential.lean

potential_approx

[262, 1]

[295, 40]

have l2 : 0 < log (abs z) := Real.log_pos (by linarith)

c✝ z✝ : 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 s : Super (f d) d OnePoint.infty := superF d z3 : 3 ≤ Complex.abs z z0 : 0 < Complex.abs z ⊢ |s.potential c ↑z - 1 / Complex.abs z| ≤ potential_error d c z

c✝ z✝ : 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 s : Super (f d) d OnePoint.infty := superF d z3 : 3 ≤ Complex.abs z z0 : 0 < Complex.abs z l2 : 0 < (Complex.abs z).log ⊢ |s.potential c ↑z - 1 / Complex.abs z| ≤ potential_error d c z

Please generate a tactic in lean4 to solve the state. STATE: c✝ z✝ : 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 s : Super (f d) d OnePoint.infty := superF d z3 : 3 ≤ Complex.abs z z0 : 0 < Complex.abs z ⊢ |s.potential c ↑z - 1 / Complex.abs z| ≤ potential_error d c z TACTIC:

https://github.com/girving/ray.git

0be790285dd0fce78913b0cb9bddaffa94bd25f9

Ray/Dynamics/Multibrot/Potential.lean

potential_approx

[262, 1]

[295, 40]

have h := log_neg_log_potential_approx d z3 cz

c✝ z✝ : 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 s : Super (f d) d OnePoint.infty := superF d z3 : 3 ≤ Complex.abs z z0 : 0 < Complex.abs z l2 : 0 < (Complex.abs z).log ⊢ |s.potential c ↑z - 1 / Complex.abs z| ≤ potential_error d c z

c✝ z✝ : 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 s : Super (f d) d OnePoint.infty := superF d z3 : 3 ≤ Complex.abs z z0 : 0 < Complex.abs z l2 : 0 < (Complex.abs z).log h : |(-(⋯.potential c ↑z).log).log - (Complex.abs z).log.log| ≤ iter_error d c z ⊢ |s.potential c ↑z - 1 / Complex.abs z| ≤ potential_error d c z

Please generate a tactic in lean4 to solve the state. STATE: c✝ z✝ : 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 s : Super (f d) d OnePoint.infty := superF d z3 : 3 ≤ Complex.abs z z0 : 0 < Complex.abs z l2 : 0 < (Complex.abs z).log ⊢ |s.potential c ↑z - 1 / Complex.abs z| ≤ potential_error d c z TACTIC:

https://github.com/girving/ray.git

0be790285dd0fce78913b0cb9bddaffa94bd25f9

Ray/Dynamics/Multibrot/Potential.lean

potential_approx

[262, 1]

[295, 40]

have p0 : 0 < s.potential c z := potential_pos

c✝ z✝ : 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 s : Super (f d) d OnePoint.infty := superF d z3 : 3 ≤ Complex.abs z z0 : 0 < Complex.abs z l2 : 0 < (Complex.abs z).log h : |(-(⋯.potential c ↑z).log).log - (Complex.abs z).log.log| ≤ iter_error d c z ⊢ |s.potential c ↑z - 1 / Complex.abs z| ≤ potential_error d c z

c✝ z✝ : 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 s : Super (f d) d OnePoint.infty := superF d z3 : 3 ≤ Complex.abs z z0 : 0 < Complex.abs z l2 : 0 < (Complex.abs z).log h : |(-(⋯.potential c ↑z).log).log - (Complex.abs z).log.log| ≤ iter_error d c z p0 : 0 < s.potential c ↑z ⊢ |s.potential c ↑z - 1 / Complex.abs z| ≤ potential_error d c z

Please generate a tactic in lean4 to solve the state. STATE: c✝ z✝ : 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 s : Super (f d) d OnePoint.infty := superF d z3 : 3 ≤ Complex.abs z z0 : 0 < Complex.abs z l2 : 0 < (Complex.abs z).log h : |(-(⋯.potential c ↑z).log).log - (Complex.abs z).log.log| ≤ iter_error d c z ⊢ |s.potential c ↑z - 1 / Complex.abs z| ≤ potential_error d c z TACTIC:

https://github.com/girving/ray.git

0be790285dd0fce78913b0cb9bddaffa94bd25f9

Ray/Dynamics/Multibrot/Potential.lean

potential_approx

[262, 1]

[295, 40]

have lp0 : 0 < -log (s.potential c z) := neg_pos.mpr (Real.log_neg p0 (potential_lt_one_of_two_lt (by linarith) cz))

c✝ z✝ : 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 s : Super (f d) d OnePoint.infty := superF d z3 : 3 ≤ Complex.abs z z0 : 0 < Complex.abs z l2 : 0 < (Complex.abs z).log h : |(-(⋯.potential c ↑z).log).log - (Complex.abs z).log.log| ≤ iter_error d c z p0 : 0 < s.potential c ↑z ⊢ |s.potential c ↑z - 1 / Complex.abs z| ≤ potential_error d c z

c✝ z✝ : 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 s : Super (f d) d OnePoint.infty := superF d z3 : 3 ≤ Complex.abs z z0 : 0 < Complex.abs z l2 : 0 < (Complex.abs z).log h : |(-(⋯.potential c ↑z).log).log - (Complex.abs z).log.log| ≤ iter_error d c z p0 : 0 < s.potential c ↑z lp0 : 0 < -(s.potential c ↑z).log ⊢ |s.potential c ↑z - 1 / Complex.abs z| ≤ potential_error d c z

Please generate a tactic in lean4 to solve the state. STATE: c✝ z✝ : 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 s : Super (f d) d OnePoint.infty := superF d z3 : 3 ≤ Complex.abs z z0 : 0 < Complex.abs z l2 : 0 < (Complex.abs z).log h : |(-(⋯.potential c ↑z).log).log - (Complex.abs z).log.log| ≤ iter_error d c z p0 : 0 < s.potential c ↑z ⊢ |s.potential c ↑z - 1 / Complex.abs z| ≤ potential_error d c z TACTIC:

https://github.com/girving/ray.git

0be790285dd0fce78913b0cb9bddaffa94bd25f9

Ray/Dynamics/Multibrot/Potential.lean

potential_approx

[262, 1]

[295, 40]

generalize s.potential c z = p at h p0 lp0

c✝ z✝ : 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 s : Super (f d) d OnePoint.infty := superF d z3 : 3 ≤ Complex.abs z z0 : 0 < Complex.abs z l2 : 0 < (Complex.abs z).log h : |(-(⋯.potential c ↑z).log).log - (Complex.abs z).log.log| ≤ iter_error d c z p0 : 0 < s.potential c ↑z lp0 : 0 < -(s.potential c ↑z).log ⊢ |s.potential c ↑z - 1 / Complex.abs z| ≤ potential_error d c z

c✝ z✝ : 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 s : Super (f d) d OnePoint.infty := superF d z3 : 3 ≤ Complex.abs z z0 : 0 < Complex.abs z l2 : 0 < (Complex.abs z).log p : ℝ h : |(-p.log).log - (Complex.abs z).log.log| ≤ iter_error d c z p0 : 0 < p lp0 : 0 < -p.log ⊢ |p - 1 / Complex.abs z| ≤ potential_error d c z

Please generate a tactic in lean4 to solve the state. STATE: c✝ z✝ : 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 s : Super (f d) d OnePoint.infty := superF d z3 : 3 ≤ Complex.abs z z0 : 0 < Complex.abs z l2 : 0 < (Complex.abs z).log h : |(-(⋯.potential c ↑z).log).log - (Complex.abs z).log.log| ≤ iter_error d c z p0 : 0 < s.potential c ↑z lp0 : 0 < -(s.potential c ↑z).log ⊢ |s.potential c ↑z - 1 / Complex.abs z| ≤ potential_error d c z TACTIC:

https://github.com/girving/ray.git

0be790285dd0fce78913b0cb9bddaffa94bd25f9

Ray/Dynamics/Multibrot/Potential.lean

potential_approx

[262, 1]

[295, 40]

generalize hr : iter_error d c z = r at h

c✝ z✝ : 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 s : Super (f d) d OnePoint.infty := superF d z3 : 3 ≤ Complex.abs z z0 : 0 < Complex.abs z l2 : 0 < (Complex.abs z).log p : ℝ h : |(-p.log).log - (Complex.abs z).log.log| ≤ iter_error d c z p0 : 0 < p lp0 : 0 < -p.log ⊢ |p - 1 / Complex.abs z| ≤ potential_error d c z

c✝ z✝ : 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 s : Super (f d) d OnePoint.infty := superF d z3 : 3 ≤ Complex.abs z z0 : 0 < Complex.abs z l2 : 0 < (Complex.abs z).log p : ℝ p0 : 0 < p lp0 : 0 < -p.log r : ℝ hr : iter_error d c z = r h : |(-p.log).log - (Complex.abs z).log.log| ≤ r ⊢ |p - 1 / Complex.abs z| ≤ potential_error d c z

Please generate a tactic in lean4 to solve the state. STATE: c✝ z✝ : 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 s : Super (f d) d OnePoint.infty := superF d z3 : 3 ≤ Complex.abs z z0 : 0 < Complex.abs z l2 : 0 < (Complex.abs z).log p : ℝ h : |(-p.log).log - (Complex.abs z).log.log| ≤ iter_error d c z p0 : 0 < p lp0 : 0 < -p.log ⊢ |p - 1 / Complex.abs z| ≤ potential_error d c z TACTIC:

https://github.com/girving/ray.git

0be790285dd0fce78913b0cb9bddaffa94bd25f9

Ray/Dynamics/Multibrot/Potential.lean

potential_approx

[262, 1]

[295, 40]

have r0 : 0 ≤ r := le_trans (abs_nonneg _) h

c✝ z✝ : 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 s : Super (f d) d OnePoint.infty := superF d z3 : 3 ≤ Complex.abs z z0 : 0 < Complex.abs z l2 : 0 < (Complex.abs z).log p : ℝ p0 : 0 < p lp0 : 0 < -p.log r : ℝ hr : iter_error d c z = r h : |(-p.log).log - (Complex.abs z).log.log| ≤ r ⊢ |p - 1 / Complex.abs z| ≤ potential_error d c z

c✝ z✝ : 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 s : Super (f d) d OnePoint.infty := superF d z3 : 3 ≤ Complex.abs z z0 : 0 < Complex.abs z l2 : 0 < (Complex.abs z).log p : ℝ p0 : 0 < p lp0 : 0 < -p.log r : ℝ hr : iter_error d c z = r h : |(-p.log).log - (Complex.abs z).log.log| ≤ r r0 : 0 ≤ r ⊢ |p - 1 / Complex.abs z| ≤ potential_error d c z

Please generate a tactic in lean4 to solve the state. STATE: c✝ z✝ : 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 s : Super (f d) d OnePoint.infty := superF d z3 : 3 ≤ Complex.abs z z0 : 0 < Complex.abs z l2 : 0 < (Complex.abs z).log p : ℝ p0 : 0 < p lp0 : 0 < -p.log r : ℝ hr : iter_error d c z = r h : |(-p.log).log - (Complex.abs z).log.log| ≤ r ⊢ |p - 1 / Complex.abs z| ≤ potential_error d c z TACTIC:

https://github.com/girving/ray.git

0be790285dd0fce78913b0cb9bddaffa94bd25f9

Ray/Dynamics/Multibrot/Potential.lean

potential_approx

[262, 1]

[295, 40]

set t := Ici (log (log (abs z)) - r)

c✝ z✝ : 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 s : Super (f d) d OnePoint.infty := superF d z3 : 3 ≤ Complex.abs z z0 : 0 < Complex.abs z l2 : 0 < (Complex.abs z).log p : ℝ p0 : 0 < p lp0 : 0 < -p.log r : ℝ hr : iter_error d c z = r h : |(-p.log).log - (Complex.abs z).log.log| ≤ r r0 : 0 ≤ r ⊢ |p - 1 / Complex.abs z| ≤ potential_error d c z

c✝ z✝ : 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 s : Super (f d) d OnePoint.infty := superF d z3 : 3 ≤ Complex.abs z z0 : 0 < Complex.abs z l2 : 0 < (Complex.abs z).log p : ℝ p0 : 0 < p lp0 : 0 < -p.log r : ℝ hr : iter_error d c z = r h : |(-p.log).log - (Complex.abs z).log.log| ≤ r r0 : 0 ≤ r t : Set ℝ := Ici ((Complex.abs z).log.log - r) ⊢ |p - 1 / Complex.abs z| ≤ potential_error d c z

Please generate a tactic in lean4 to solve the state. STATE: c✝ z✝ : 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 s : Super (f d) d OnePoint.infty := superF d z3 : 3 ≤ Complex.abs z z0 : 0 < Complex.abs z l2 : 0 < (Complex.abs z).log p : ℝ p0 : 0 < p lp0 : 0 < -p.log r : ℝ hr : iter_error d c z = r h : |(-p.log).log - (Complex.abs z).log.log| ≤ r r0 : 0 ≤ r ⊢ |p - 1 / Complex.abs z| ≤ potential_error d c z TACTIC:

https://github.com/girving/ray.git

0be790285dd0fce78913b0cb9bddaffa94bd25f9

Ray/Dynamics/Multibrot/Potential.lean

potential_approx

[262, 1]

[295, 40]

have yt : log (-log p) ∈ t := by simp only [abs_le, neg_le_sub_iff_le_add, tsub_le_iff_right, add_comm r] at h simp only [mem_Ici, tsub_le_iff_right, h, t]

c✝ z✝ : 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 s : Super (f d) d OnePoint.infty := superF d z3 : 3 ≤ Complex.abs z z0 : 0 < Complex.abs z l2 : 0 < (Complex.abs z).log p : ℝ p0 : 0 < p lp0 : 0 < -p.log r : ℝ hr : iter_error d c z = r h : |(-p.log).log - (Complex.abs z).log.log| ≤ r r0 : 0 ≤ r t : Set ℝ := Ici ((Complex.abs z).log.log - r) ⊢ |p - 1 / Complex.abs z| ≤ potential_error d c z

c✝ z✝ : 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 s : Super (f d) d OnePoint.infty := superF d z3 : 3 ≤ Complex.abs z z0 : 0 < Complex.abs z l2 : 0 < (Complex.abs z).log p : ℝ p0 : 0 < p lp0 : 0 < -p.log r : ℝ hr : iter_error d c z = r h : |(-p.log).log - (Complex.abs z).log.log| ≤ r r0 : 0 ≤ r t : Set ℝ := Ici ((Complex.abs z).log.log - r) yt : (-p.log).log ∈ t ⊢ |p - 1 / Complex.abs z| ≤ potential_error d c z

Please generate a tactic in lean4 to solve the state. STATE: c✝ z✝ : 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 s : Super (f d) d OnePoint.infty := superF d z3 : 3 ≤ Complex.abs z z0 : 0 < Complex.abs z l2 : 0 < (Complex.abs z).log p : ℝ p0 : 0 < p lp0 : 0 < -p.log r : ℝ hr : iter_error d c z = r h : |(-p.log).log - (Complex.abs z).log.log| ≤ r r0 : 0 ≤ r t : Set ℝ := Ici ((Complex.abs z).log.log - r) ⊢ |p - 1 / Complex.abs z| ≤ potential_error d c z TACTIC:

https://github.com/girving/ray.git

0be790285dd0fce78913b0cb9bddaffa94bd25f9

Ray/Dynamics/Multibrot/Potential.lean

potential_approx

[262, 1]

[295, 40]

have lt : log (log (abs z)) ∈ t := by simp only [mem_Ici, tsub_le_iff_right, le_add_iff_nonneg_right, r0, t]

c✝ z✝ : 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 s : Super (f d) d OnePoint.infty := superF d z3 : 3 ≤ Complex.abs z z0 : 0 < Complex.abs z l2 : 0 < (Complex.abs z).log p : ℝ p0 : 0 < p lp0 : 0 < -p.log r : ℝ hr : iter_error d c z = r h : |(-p.log).log - (Complex.abs z).log.log| ≤ r r0 : 0 ≤ r t : Set ℝ := Ici ((Complex.abs z).log.log - r) yt : (-p.log).log ∈ t ⊢ |p - 1 / Complex.abs z| ≤ potential_error d c z

c✝ z✝ : 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 s : Super (f d) d OnePoint.infty := superF d z3 : 3 ≤ Complex.abs z z0 : 0 < Complex.abs z l2 : 0 < (Complex.abs z).log p : ℝ p0 : 0 < p lp0 : 0 < -p.log r : ℝ hr : iter_error d c z = r h : |(-p.log).log - (Complex.abs z).log.log| ≤ r r0 : 0 ≤ r t : Set ℝ := Ici ((Complex.abs z).log.log - r) yt : (-p.log).log ∈ t lt : (Complex.abs z).log.log ∈ t ⊢ |p - 1 / Complex.abs z| ≤ potential_error d c z

Please generate a tactic in lean4 to solve the state. STATE: c✝ z✝ : 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 s : Super (f d) d OnePoint.infty := superF d z3 : 3 ≤ Complex.abs z z0 : 0 < Complex.abs z l2 : 0 < (Complex.abs z).log p : ℝ p0 : 0 < p lp0 : 0 < -p.log r : ℝ hr : iter_error d c z = r h : |(-p.log).log - (Complex.abs z).log.log| ≤ r r0 : 0 ≤ r t : Set ℝ := Ici ((Complex.abs z).log.log - r) yt : (-p.log).log ∈ t ⊢ |p - 1 / Complex.abs z| ≤ potential_error d c z TACTIC:

https://github.com/girving/ray.git

0be790285dd0fce78913b0cb9bddaffa94bd25f9

Ray/Dynamics/Multibrot/Potential.lean

potential_approx

[262, 1]

[295, 40]

generalize hb : dene (log (log (abs z)) - r) = b

c✝ z✝ : 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 s : Super (f d) d OnePoint.infty := superF d z3 : 3 ≤ Complex.abs z z0 : 0 < Complex.abs z l2 : 0 < (Complex.abs z).log p : ℝ p0 : 0 < p lp0 : 0 < -p.log r : ℝ hr : iter_error d c z = r h : |(-p.log).log - (Complex.abs z).log.log| ≤ r r0 : 0 ≤ r t : Set ℝ := Ici ((Complex.abs z).log.log - r) yt : (-p.log).log ∈ t lt : (Complex.abs z).log.log ∈ t ⊢ |p - 1 / Complex.abs z| ≤ potential_error d c z

c✝ z✝ : 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 s : Super (f d) d OnePoint.infty := superF d z3 : 3 ≤ Complex.abs z z0 : 0 < Complex.abs z l2 : 0 < (Complex.abs z).log p : ℝ p0 : 0 < p lp0 : 0 < -p.log r : ℝ hr : iter_error d c z = r h : |(-p.log).log - (Complex.abs z).log.log| ≤ r r0 : 0 ≤ r t : Set ℝ := Ici ((Complex.abs z).log.log - r) yt : (-p.log).log ∈ t lt : (Complex.abs z).log.log ∈ t b : ℝ hb : dene ((Complex.abs z).log.log - r) = b ⊢ |p - 1 / Complex.abs z| ≤ potential_error d c z

Please generate a tactic in lean4 to solve the state. STATE: c✝ z✝ : 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 s : Super (f d) d OnePoint.infty := superF d z3 : 3 ≤ Complex.abs z z0 : 0 < Complex.abs z l2 : 0 < (Complex.abs z).log p : ℝ p0 : 0 < p lp0 : 0 < -p.log r : ℝ hr : iter_error d c z = r h : |(-p.log).log - (Complex.abs z).log.log| ≤ r r0 : 0 ≤ r t : Set ℝ := Ici ((Complex.abs z).log.log - r) yt : (-p.log).log ∈ t lt : (Complex.abs z).log.log ∈ t ⊢ |p - 1 / Complex.abs z| ≤ potential_error d c z TACTIC:

https://github.com/girving/ray.git

0be790285dd0fce78913b0cb9bddaffa94bd25f9

Ray/Dynamics/Multibrot/Potential.lean

potential_approx

[262, 1]

[295, 40]

have b0 : 0 ≤ b := by rw [←hb]; exact dene_nonneg

c✝ z✝ : 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 s : Super (f d) d OnePoint.infty := superF d z3 : 3 ≤ Complex.abs z z0 : 0 < Complex.abs z l2 : 0 < (Complex.abs z).log p : ℝ p0 : 0 < p lp0 : 0 < -p.log r : ℝ hr : iter_error d c z = r h : |(-p.log).log - (Complex.abs z).log.log| ≤ r r0 : 0 ≤ r t : Set ℝ := Ici ((Complex.abs z).log.log - r) yt : (-p.log).log ∈ t lt : (Complex.abs z).log.log ∈ t b : ℝ hb : dene ((Complex.abs z).log.log - r) = b ⊢ |p - 1 / Complex.abs z| ≤ potential_error d c z

c✝ z✝ : 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 s : Super (f d) d OnePoint.infty := superF d z3 : 3 ≤ Complex.abs z z0 : 0 < Complex.abs z l2 : 0 < (Complex.abs z).log p : ℝ p0 : 0 < p lp0 : 0 < -p.log r : ℝ hr : iter_error d c z = r h : |(-p.log).log - (Complex.abs z).log.log| ≤ r r0 : 0 ≤ r t : Set ℝ := Ici ((Complex.abs z).log.log - r) yt : (-p.log).log ∈ t lt : (Complex.abs z).log.log ∈ t b : ℝ hb : dene ((Complex.abs z).log.log - r) = b b0 : 0 ≤ b ⊢ |p - 1 / Complex.abs z| ≤ potential_error d c z

Please generate a tactic in lean4 to solve the state. STATE: c✝ z✝ : 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 s : Super (f d) d OnePoint.infty := superF d z3 : 3 ≤ Complex.abs z z0 : 0 < Complex.abs z l2 : 0 < (Complex.abs z).log p : ℝ p0 : 0 < p lp0 : 0 < -p.log r : ℝ hr : iter_error d c z = r h : |(-p.log).log - (Complex.abs z).log.log| ≤ r r0 : 0 ≤ r t : Set ℝ := Ici ((Complex.abs z).log.log - r) yt : (-p.log).log ∈ t lt : (Complex.abs z).log.log ∈ t b : ℝ hb : dene ((Complex.abs z).log.log - r) = b ⊢ |p - 1 / Complex.abs z| ≤ potential_error d c z TACTIC:

https://github.com/girving/ray.git

0be790285dd0fce78913b0cb9bddaffa94bd25f9

Ray/Dynamics/Multibrot/Potential.lean

potential_approx

[262, 1]

[295, 40]

have bound : ∀ x, x ∈ t → ‖deriv ene x‖ ≤ b := by intro x m simp only [Real.dist_eq, mem_Ici, ←hr, t] at m simp only [deriv_ene, norm_neg, Real.norm_of_nonneg dene_nonneg, ←hb, ←hr] apply dene_anti (sub_nonneg.mpr (iter_error_le_log_log_abs d z4 cz)) m

c✝ z✝ : 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 s : Super (f d) d OnePoint.infty := superF d z3 : 3 ≤ Complex.abs z z0 : 0 < Complex.abs z l2 : 0 < (Complex.abs z).log p : ℝ p0 : 0 < p lp0 : 0 < -p.log r : ℝ hr : iter_error d c z = r h : |(-p.log).log - (Complex.abs z).log.log| ≤ r r0 : 0 ≤ r t : Set ℝ := Ici ((Complex.abs z).log.log - r) yt : (-p.log).log ∈ t lt : (Complex.abs z).log.log ∈ t b : ℝ hb : dene ((Complex.abs z).log.log - r) = b b0 : 0 ≤ b ⊢ |p - 1 / Complex.abs z| ≤ potential_error d c z

c✝ z✝ : 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 s : Super (f d) d OnePoint.infty := superF d z3 : 3 ≤ Complex.abs z z0 : 0 < Complex.abs z l2 : 0 < (Complex.abs z).log p : ℝ p0 : 0 < p lp0 : 0 < -p.log r : ℝ hr : iter_error d c z = r h : |(-p.log).log - (Complex.abs z).log.log| ≤ r r0 : 0 ≤ r t : Set ℝ := Ici ((Complex.abs z).log.log - r) yt : (-p.log).log ∈ t lt : (Complex.abs z).log.log ∈ t b : ℝ hb : dene ((Complex.abs z).log.log - r) = b b0 : 0 ≤ b bound : ∀ x ∈ t, ‖deriv ene x‖ ≤ b ⊢ |p - 1 / Complex.abs z| ≤ potential_error d c z

Please generate a tactic in lean4 to solve the state. STATE: c✝ z✝ : 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 s : Super (f d) d OnePoint.infty := superF d z3 : 3 ≤ Complex.abs z z0 : 0 < Complex.abs z l2 : 0 < (Complex.abs z).log p : ℝ p0 : 0 < p lp0 : 0 < -p.log r : ℝ hr : iter_error d c z = r h : |(-p.log).log - (Complex.abs z).log.log| ≤ r r0 : 0 ≤ r t : Set ℝ := Ici ((Complex.abs z).log.log - r) yt : (-p.log).log ∈ t lt : (Complex.abs z).log.log ∈ t b : ℝ hb : dene ((Complex.abs z).log.log - r) = b b0 : 0 ≤ b ⊢ |p - 1 / Complex.abs z| ≤ potential_error d c z TACTIC:

https://github.com/girving/ray.git

0be790285dd0fce78913b0cb9bddaffa94bd25f9

Ray/Dynamics/Multibrot/Potential.lean

potential_approx

[262, 1]

[295, 40]

have m := Convex.norm_image_sub_le_of_norm_deriv_le (fun x _ ↦ (hasDerivAt_ene x).differentiableAt) bound (convex_Ici _) lt yt

c✝ z✝ : 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 s : Super (f d) d OnePoint.infty := superF d z3 : 3 ≤ Complex.abs z z0 : 0 < Complex.abs z l2 : 0 < (Complex.abs z).log p : ℝ p0 : 0 < p lp0 : 0 < -p.log r : ℝ hr : iter_error d c z = r h : |(-p.log).log - (Complex.abs z).log.log| ≤ r r0 : 0 ≤ r t : Set ℝ := Ici ((Complex.abs z).log.log - r) yt : (-p.log).log ∈ t lt : (Complex.abs z).log.log ∈ t b : ℝ hb : dene ((Complex.abs z).log.log - r) = b b0 : 0 ≤ b bound : ∀ x ∈ t, ‖deriv ene x‖ ≤ b ⊢ |p - 1 / Complex.abs z| ≤ potential_error d c z

c✝ z✝ : 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 s : Super (f d) d OnePoint.infty := superF d z3 : 3 ≤ Complex.abs z z0 : 0 < Complex.abs z l2 : 0 < (Complex.abs z).log p : ℝ p0 : 0 < p lp0 : 0 < -p.log r : ℝ hr : iter_error d c z = r h : |(-p.log).log - (Complex.abs z).log.log| ≤ r r0 : 0 ≤ r t : Set ℝ := Ici ((Complex.abs z).log.log - r) yt : (-p.log).log ∈ t lt : (Complex.abs z).log.log ∈ t b : ℝ hb : dene ((Complex.abs z).log.log - r) = b b0 : 0 ≤ b bound : ∀ x ∈ t, ‖deriv ene x‖ ≤ b m : ‖ene (-p.log).log - ene (Complex.abs z).log.log‖ ≤ b * ‖(-p.log).log - (Complex.abs z).log.log‖ ⊢ |p - 1 / Complex.abs z| ≤ potential_error d c z

Please generate a tactic in lean4 to solve the state. STATE: c✝ z✝ : 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 s : Super (f d) d OnePoint.infty := superF d z3 : 3 ≤ Complex.abs z z0 : 0 < Complex.abs z l2 : 0 < (Complex.abs z).log p : ℝ p0 : 0 < p lp0 : 0 < -p.log r : ℝ hr : iter_error d c z = r h : |(-p.log).log - (Complex.abs z).log.log| ≤ r r0 : 0 ≤ r t : Set ℝ := Ici ((Complex.abs z).log.log - r) yt : (-p.log).log ∈ t lt : (Complex.abs z).log.log ∈ t b : ℝ hb : dene ((Complex.abs z).log.log - r) = b b0 : 0 ≤ b bound : ∀ x ∈ t, ‖deriv ene x‖ ≤ b ⊢ |p - 1 / Complex.abs z| ≤ potential_error d c z TACTIC:

https://github.com/girving/ray.git

0be790285dd0fce78913b0cb9bddaffa94bd25f9

Ray/Dynamics/Multibrot/Potential.lean

potential_approx

[262, 1]

[295, 40]

simp only [Real.norm_eq_abs] at m

c✝ z✝ : 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 s : Super (f d) d OnePoint.infty := superF d z3 : 3 ≤ Complex.abs z z0 : 0 < Complex.abs z l2 : 0 < (Complex.abs z).log p : ℝ p0 : 0 < p lp0 : 0 < -p.log r : ℝ hr : iter_error d c z = r h : |(-p.log).log - (Complex.abs z).log.log| ≤ r r0 : 0 ≤ r t : Set ℝ := Ici ((Complex.abs z).log.log - r) yt : (-p.log).log ∈ t lt : (Complex.abs z).log.log ∈ t b : ℝ hb : dene ((Complex.abs z).log.log - r) = b b0 : 0 ≤ b bound : ∀ x ∈ t, ‖deriv ene x‖ ≤ b m : ‖ene (-p.log).log - ene (Complex.abs z).log.log‖ ≤ b * ‖(-p.log).log - (Complex.abs z).log.log‖ ⊢ |p - 1 / Complex.abs z| ≤ potential_error d c z

c✝ z✝ : 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 s : Super (f d) d OnePoint.infty := superF d z3 : 3 ≤ Complex.abs z z0 : 0 < Complex.abs z l2 : 0 < (Complex.abs z).log p : ℝ p0 : 0 < p lp0 : 0 < -p.log r : ℝ hr : iter_error d c z = r h : |(-p.log).log - (Complex.abs z).log.log| ≤ r r0 : 0 ≤ r t : Set ℝ := Ici ((Complex.abs z).log.log - r) yt : (-p.log).log ∈ t lt : (Complex.abs z).log.log ∈ t b : ℝ hb : dene ((Complex.abs z).log.log - r) = b b0 : 0 ≤ b bound : ∀ x ∈ t, ‖deriv ene x‖ ≤ b m : |ene (-p.log).log - ene (Complex.abs z).log.log| ≤ b * |(-p.log).log - (Complex.abs z).log.log| ⊢ |p - 1 / Complex.abs z| ≤ potential_error d c z

Please generate a tactic in lean4 to solve the state. STATE: c✝ z✝ : 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 s : Super (f d) d OnePoint.infty := superF d z3 : 3 ≤ Complex.abs z z0 : 0 < Complex.abs z l2 : 0 < (Complex.abs z).log p : ℝ p0 : 0 < p lp0 : 0 < -p.log r : ℝ hr : iter_error d c z = r h : |(-p.log).log - (Complex.abs z).log.log| ≤ r r0 : 0 ≤ r t : Set ℝ := Ici ((Complex.abs z).log.log - r) yt : (-p.log).log ∈ t lt : (Complex.abs z).log.log ∈ t b : ℝ hb : dene ((Complex.abs z).log.log - r) = b b0 : 0 ≤ b bound : ∀ x ∈ t, ‖deriv ene x‖ ≤ b m : ‖ene (-p.log).log - ene (Complex.abs z).log.log‖ ≤ b * ‖(-p.log).log - (Complex.abs z).log.log‖ ⊢ |p - 1 / Complex.abs z| ≤ potential_error d c z TACTIC:

https://github.com/girving/ray.git

0be790285dd0fce78913b0cb9bddaffa94bd25f9

Ray/Dynamics/Multibrot/Potential.lean

potential_approx

[262, 1]

[295, 40]

replace m := le_trans m (mul_le_mul_of_nonneg_left h (by bound))

c✝ z✝ : 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 s : Super (f d) d OnePoint.infty := superF d z3 : 3 ≤ Complex.abs z z0 : 0 < Complex.abs z l2 : 0 < (Complex.abs z).log p : ℝ p0 : 0 < p lp0 : 0 < -p.log r : ℝ hr : iter_error d c z = r h : |(-p.log).log - (Complex.abs z).log.log| ≤ r r0 : 0 ≤ r t : Set ℝ := Ici ((Complex.abs z).log.log - r) yt : (-p.log).log ∈ t lt : (Complex.abs z).log.log ∈ t b : ℝ hb : dene ((Complex.abs z).log.log - r) = b b0 : 0 ≤ b bound : ∀ x ∈ t, ‖deriv ene x‖ ≤ b m : |ene (-p.log).log - ene (Complex.abs z).log.log| ≤ b * |(-p.log).log - (Complex.abs z).log.log| ⊢ |p - 1 / Complex.abs z| ≤ potential_error d c z

c✝ z✝ : 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 s : Super (f d) d OnePoint.infty := superF d z3 : 3 ≤ Complex.abs z z0 : 0 < Complex.abs z l2 : 0 < (Complex.abs z).log p : ℝ p0 : 0 < p lp0 : 0 < -p.log r : ℝ hr : iter_error d c z = r h : |(-p.log).log - (Complex.abs z).log.log| ≤ r r0 : 0 ≤ r t : Set ℝ := Ici ((Complex.abs z).log.log - r) yt : (-p.log).log ∈ t lt : (Complex.abs z).log.log ∈ t b : ℝ hb : dene ((Complex.abs z).log.log - r) = b b0 : 0 ≤ b bound : ∀ x ∈ t, ‖deriv ene x‖ ≤ b m : |ene (-p.log).log - ene (Complex.abs z).log.log| ≤ b * r ⊢ |p - 1 / Complex.abs z| ≤ potential_error d c z

Please generate a tactic in lean4 to solve the state. STATE: c✝ z✝ : 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 s : Super (f d) d OnePoint.infty := superF d z3 : 3 ≤ Complex.abs z z0 : 0 < Complex.abs z l2 : 0 < (Complex.abs z).log p : ℝ p0 : 0 < p lp0 : 0 < -p.log r : ℝ hr : iter_error d c z = r h : |(-p.log).log - (Complex.abs z).log.log| ≤ r r0 : 0 ≤ r t : Set ℝ := Ici ((Complex.abs z).log.log - r) yt : (-p.log).log ∈ t lt : (Complex.abs z).log.log ∈ t b : ℝ hb : dene ((Complex.abs z).log.log - r) = b b0 : 0 ≤ b bound : ∀ x ∈ t, ‖deriv ene x‖ ≤ b m : |ene (-p.log).log - ene (Complex.abs z).log.log| ≤ b * |(-p.log).log - (Complex.abs z).log.log| ⊢ |p - 1 / Complex.abs z| ≤ potential_error d c z TACTIC:

https://github.com/girving/ray.git

0be790285dd0fce78913b0cb9bddaffa94bd25f9

Ray/Dynamics/Multibrot/Potential.lean

potential_approx

[262, 1]

[295, 40]

simp only [ene, Real.exp_log lp0, neg_neg, Real.exp_log p0, Real.exp_log l2, Real.exp_neg, Real.exp_log z0, inv_eq_one_div] at m

c✝ z✝ : 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 s : Super (f d) d OnePoint.infty := superF d z3 : 3 ≤ Complex.abs z z0 : 0 < Complex.abs z l2 : 0 < (Complex.abs z).log p : ℝ p0 : 0 < p lp0 : 0 < -p.log r : ℝ hr : iter_error d c z = r h : |(-p.log).log - (Complex.abs z).log.log| ≤ r r0 : 0 ≤ r t : Set ℝ := Ici ((Complex.abs z).log.log - r) yt : (-p.log).log ∈ t lt : (Complex.abs z).log.log ∈ t b : ℝ hb : dene ((Complex.abs z).log.log - r) = b b0 : 0 ≤ b bound : ∀ x ∈ t, ‖deriv ene x‖ ≤ b m : |ene (-p.log).log - ene (Complex.abs z).log.log| ≤ b * r ⊢ |p - 1 / Complex.abs z| ≤ potential_error d c z

c✝ z✝ : 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 s : Super (f d) d OnePoint.infty := superF d z3 : 3 ≤ Complex.abs z z0 : 0 < Complex.abs z l2 : 0 < (Complex.abs z).log p : ℝ p0 : 0 < p lp0 : 0 < -p.log r : ℝ hr : iter_error d c z = r h : |(-p.log).log - (Complex.abs z).log.log| ≤ r r0 : 0 ≤ r t : Set ℝ := Ici ((Complex.abs z).log.log - r) yt : (-p.log).log ∈ t lt : (Complex.abs z).log.log ∈ t b : ℝ hb : dene ((Complex.abs z).log.log - r) = b b0 : 0 ≤ b bound : ∀ x ∈ t, ‖deriv ene x‖ ≤ b m : |p - 1 / Complex.abs z| ≤ b * r ⊢ |p - 1 / Complex.abs z| ≤ potential_error d c z

Please generate a tactic in lean4 to solve the state. STATE: c✝ z✝ : 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 s : Super (f d) d OnePoint.infty := superF d z3 : 3 ≤ Complex.abs z z0 : 0 < Complex.abs z l2 : 0 < (Complex.abs z).log p : ℝ p0 : 0 < p lp0 : 0 < -p.log r : ℝ hr : iter_error d c z = r h : |(-p.log).log - (Complex.abs z).log.log| ≤ r r0 : 0 ≤ r t : Set ℝ := Ici ((Complex.abs z).log.log - r) yt : (-p.log).log ∈ t lt : (Complex.abs z).log.log ∈ t b : ℝ hb : dene ((Complex.abs z).log.log - r) = b b0 : 0 ≤ b bound : ∀ x ∈ t, ‖deriv ene x‖ ≤ b m : |ene (-p.log).log - ene (Complex.abs z).log.log| ≤ b * r ⊢ |p - 1 / Complex.abs z| ≤ potential_error d c z TACTIC:

https://github.com/girving/ray.git

0be790285dd0fce78913b0cb9bddaffa94bd25f9

Ray/Dynamics/Multibrot/Potential.lean

potential_approx

[262, 1]

[295, 40]

refine le_trans m (le_of_eq ?_)

c✝ z✝ : 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 s : Super (f d) d OnePoint.infty := superF d z3 : 3 ≤ Complex.abs z z0 : 0 < Complex.abs z l2 : 0 < (Complex.abs z).log p : ℝ p0 : 0 < p lp0 : 0 < -p.log r : ℝ hr : iter_error d c z = r h : |(-p.log).log - (Complex.abs z).log.log| ≤ r r0 : 0 ≤ r t : Set ℝ := Ici ((Complex.abs z).log.log - r) yt : (-p.log).log ∈ t lt : (Complex.abs z).log.log ∈ t b : ℝ hb : dene ((Complex.abs z).log.log - r) = b b0 : 0 ≤ b bound : ∀ x ∈ t, ‖deriv ene x‖ ≤ b m : |p - 1 / Complex.abs z| ≤ b * r ⊢ |p - 1 / Complex.abs z| ≤ potential_error d c z

c✝ z✝ : 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 s : Super (f d) d OnePoint.infty := superF d z3 : 3 ≤ Complex.abs z z0 : 0 < Complex.abs z l2 : 0 < (Complex.abs z).log p : ℝ p0 : 0 < p lp0 : 0 < -p.log r : ℝ hr : iter_error d c z = r h : |(-p.log).log - (Complex.abs z).log.log| ≤ r r0 : 0 ≤ r t : Set ℝ := Ici ((Complex.abs z).log.log - r) yt : (-p.log).log ∈ t lt : (Complex.abs z).log.log ∈ t b : ℝ hb : dene ((Complex.abs z).log.log - r) = b b0 : 0 ≤ b bound : ∀ x ∈ t, ‖deriv ene x‖ ≤ b m : |p - 1 / Complex.abs z| ≤ b * r ⊢ b * r = potential_error d c z

Please generate a tactic in lean4 to solve the state. STATE: c✝ z✝ : 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 s : Super (f d) d OnePoint.infty := superF d z3 : 3 ≤ Complex.abs z z0 : 0 < Complex.abs z l2 : 0 < (Complex.abs z).log p : ℝ p0 : 0 < p lp0 : 0 < -p.log r : ℝ hr : iter_error d c z = r h : |(-p.log).log - (Complex.abs z).log.log| ≤ r r0 : 0 ≤ r t : Set ℝ := Ici ((Complex.abs z).log.log - r) yt : (-p.log).log ∈ t lt : (Complex.abs z).log.log ∈ t b : ℝ hb : dene ((Complex.abs z).log.log - r) = b b0 : 0 ≤ b bound : ∀ x ∈ t, ‖deriv ene x‖ ≤ b m : |p - 1 / Complex.abs z| ≤ b * r ⊢ |p - 1 / Complex.abs z| ≤ potential_error d c z TACTIC:

https://github.com/girving/ray.git

0be790285dd0fce78913b0cb9bddaffa94bd25f9

Ray/Dynamics/Multibrot/Potential.lean

potential_approx

[262, 1]

[295, 40]

simp only [←hr, ←hb, potential_error]

c✝ z✝ : 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 s : Super (f d) d OnePoint.infty := superF d z3 : 3 ≤ Complex.abs z z0 : 0 < Complex.abs z l2 : 0 < (Complex.abs z).log p : ℝ p0 : 0 < p lp0 : 0 < -p.log r : ℝ hr : iter_error d c z = r h : |(-p.log).log - (Complex.abs z).log.log| ≤ r r0 : 0 ≤ r t : Set ℝ := Ici ((Complex.abs z).log.log - r) yt : (-p.log).log ∈ t lt : (Complex.abs z).log.log ∈ t b : ℝ hb : dene ((Complex.abs z).log.log - r) = b b0 : 0 ≤ b bound : ∀ x ∈ t, ‖deriv ene x‖ ≤ b m : |p - 1 / Complex.abs z| ≤ b * r ⊢ b * r = potential_error d c z

no goals

Please generate a tactic in lean4 to solve the state. STATE: c✝ z✝ : 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 s : Super (f d) d OnePoint.infty := superF d z3 : 3 ≤ Complex.abs z z0 : 0 < Complex.abs z l2 : 0 < (Complex.abs z).log p : ℝ p0 : 0 < p lp0 : 0 < -p.log r : ℝ hr : iter_error d c z = r h : |(-p.log).log - (Complex.abs z).log.log| ≤ r r0 : 0 ≤ r t : Set ℝ := Ici ((Complex.abs z).log.log - r) yt : (-p.log).log ∈ t lt : (Complex.abs z).log.log ∈ t b : ℝ hb : dene ((Complex.abs z).log.log - r) = b b0 : 0 ≤ b bound : ∀ x ∈ t, ‖deriv ene x‖ ≤ b m : |p - 1 / Complex.abs z| ≤ b * r ⊢ b * r = potential_error d c z TACTIC:

https://github.com/girving/ray.git

0be790285dd0fce78913b0cb9bddaffa94bd25f9

Ray/Dynamics/Multibrot/Potential.lean

potential_approx

[262, 1]

[295, 40]

norm_num

c✝ z✝ : 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 s : Super (f d) d OnePoint.infty := superF d ⊢ 3 ≤ 4

no goals

Please generate a tactic in lean4 to solve the state. STATE: c✝ z✝ : 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 s : Super (f d) d OnePoint.infty := superF d ⊢ 3 ≤ 4 TACTIC:

https://github.com/girving/ray.git

0be790285dd0fce78913b0cb9bddaffa94bd25f9

Ray/Dynamics/Multibrot/Potential.lean

potential_approx

[262, 1]

[295, 40]

norm_num

c✝ z✝ : 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 s : Super (f d) d OnePoint.infty := superF d z3 : 3 ≤ Complex.abs z ⊢ 0 < 3

no goals

Please generate a tactic in lean4 to solve the state. STATE: c✝ z✝ : 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 s : Super (f d) d OnePoint.infty := superF d z3 : 3 ≤ Complex.abs z ⊢ 0 < 3 TACTIC:

https://github.com/girving/ray.git

0be790285dd0fce78913b0cb9bddaffa94bd25f9

Ray/Dynamics/Multibrot/Potential.lean

potential_approx

[262, 1]

[295, 40]

linarith

c✝ z✝ : 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 s : Super (f d) d OnePoint.infty := superF d z3 : 3 ≤ Complex.abs z z0 : 0 < Complex.abs z ⊢ 1 < Complex.abs z

no goals

Please generate a tactic in lean4 to solve the state. STATE: c✝ z✝ : 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 s : Super (f d) d OnePoint.infty := superF d z3 : 3 ≤ Complex.abs z z0 : 0 < Complex.abs z ⊢ 1 < Complex.abs z TACTIC:

https://github.com/girving/ray.git

0be790285dd0fce78913b0cb9bddaffa94bd25f9

Ray/Dynamics/Multibrot/Potential.lean

potential_approx

[262, 1]

[295, 40]

linarith

c✝ z✝ : 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 s : Super (f d) d OnePoint.infty := superF d z3 : 3 ≤ Complex.abs z z0 : 0 < Complex.abs z l2 : 0 < (Complex.abs z).log h : |(-(⋯.potential c ↑z).log).log - (Complex.abs z).log.log| ≤ iter_error d c z p0 : 0 < s.potential c ↑z ⊢ 2 < Complex.abs z

no goals

Please generate a tactic in lean4 to solve the state. STATE: c✝ z✝ : 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 s : Super (f d) d OnePoint.infty := superF d z3 : 3 ≤ Complex.abs z z0 : 0 < Complex.abs z l2 : 0 < (Complex.abs z).log h : |(-(⋯.potential c ↑z).log).log - (Complex.abs z).log.log| ≤ iter_error d c z p0 : 0 < s.potential c ↑z ⊢ 2 < Complex.abs z TACTIC:

https://github.com/girving/ray.git

0be790285dd0fce78913b0cb9bddaffa94bd25f9

Ray/Dynamics/Multibrot/Potential.lean

potential_approx

[262, 1]

[295, 40]

simp only [abs_le, neg_le_sub_iff_le_add, tsub_le_iff_right, add_comm r] at h

c✝ z✝ : 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 s : Super (f d) d OnePoint.infty := superF d z3 : 3 ≤ Complex.abs z z0 : 0 < Complex.abs z l2 : 0 < (Complex.abs z).log p : ℝ p0 : 0 < p lp0 : 0 < -p.log r : ℝ hr : iter_error d c z = r h : |(-p.log).log - (Complex.abs z).log.log| ≤ r r0 : 0 ≤ r t : Set ℝ := Ici ((Complex.abs z).log.log - r) ⊢ (-p.log).log ∈ t

c✝ z✝ : 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 s : Super (f d) d OnePoint.infty := superF d z3 : 3 ≤ Complex.abs z z0 : 0 < Complex.abs z l2 : 0 < (Complex.abs z).log p : ℝ p0 : 0 < p lp0 : 0 < -p.log r : ℝ hr : iter_error d c z = r r0 : 0 ≤ r t : Set ℝ := Ici ((Complex.abs z).log.log - r) h : (Complex.abs z).log.log ≤ (-p.log).log + r ∧ (-p.log).log ≤ (Complex.abs z).log.log + r ⊢ (-p.log).log ∈ t

Please generate a tactic in lean4 to solve the state. STATE: c✝ z✝ : 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 s : Super (f d) d OnePoint.infty := superF d z3 : 3 ≤ Complex.abs z z0 : 0 < Complex.abs z l2 : 0 < (Complex.abs z).log p : ℝ p0 : 0 < p lp0 : 0 < -p.log r : ℝ hr : iter_error d c z = r h : |(-p.log).log - (Complex.abs z).log.log| ≤ r r0 : 0 ≤ r t : Set ℝ := Ici ((Complex.abs z).log.log - r) ⊢ (-p.log).log ∈ t TACTIC:

https://github.com/girving/ray.git

0be790285dd0fce78913b0cb9bddaffa94bd25f9

Ray/Dynamics/Multibrot/Potential.lean

potential_approx

[262, 1]

[295, 40]

simp only [mem_Ici, tsub_le_iff_right, h, t]

c✝ z✝ : 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 s : Super (f d) d OnePoint.infty := superF d z3 : 3 ≤ Complex.abs z z0 : 0 < Complex.abs z l2 : 0 < (Complex.abs z).log p : ℝ p0 : 0 < p lp0 : 0 < -p.log r : ℝ hr : iter_error d c z = r r0 : 0 ≤ r t : Set ℝ := Ici ((Complex.abs z).log.log - r) h : (Complex.abs z).log.log ≤ (-p.log).log + r ∧ (-p.log).log ≤ (Complex.abs z).log.log + r ⊢ (-p.log).log ∈ t

no goals

Please generate a tactic in lean4 to solve the state. STATE: c✝ z✝ : 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 s : Super (f d) d OnePoint.infty := superF d z3 : 3 ≤ Complex.abs z z0 : 0 < Complex.abs z l2 : 0 < (Complex.abs z).log p : ℝ p0 : 0 < p lp0 : 0 < -p.log r : ℝ hr : iter_error d c z = r r0 : 0 ≤ r t : Set ℝ := Ici ((Complex.abs z).log.log - r) h : (Complex.abs z).log.log ≤ (-p.log).log + r ∧ (-p.log).log ≤ (Complex.abs z).log.log + r ⊢ (-p.log).log ∈ t TACTIC:

https://github.com/girving/ray.git

0be790285dd0fce78913b0cb9bddaffa94bd25f9

Ray/Dynamics/Multibrot/Potential.lean

potential_approx

[262, 1]

[295, 40]

simp only [mem_Ici, tsub_le_iff_right, le_add_iff_nonneg_right, r0, t]

c✝ z✝ : 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 s : Super (f d) d OnePoint.infty := superF d z3 : 3 ≤ Complex.abs z z0 : 0 < Complex.abs z l2 : 0 < (Complex.abs z).log p : ℝ p0 : 0 < p lp0 : 0 < -p.log r : ℝ hr : iter_error d c z = r h : |(-p.log).log - (Complex.abs z).log.log| ≤ r r0 : 0 ≤ r t : Set ℝ := Ici ((Complex.abs z).log.log - r) yt : (-p.log).log ∈ t ⊢ (Complex.abs z).log.log ∈ t

no goals

Please generate a tactic in lean4 to solve the state. STATE: c✝ z✝ : 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 s : Super (f d) d OnePoint.infty := superF d z3 : 3 ≤ Complex.abs z z0 : 0 < Complex.abs z l2 : 0 < (Complex.abs z).log p : ℝ p0 : 0 < p lp0 : 0 < -p.log r : ℝ hr : iter_error d c z = r h : |(-p.log).log - (Complex.abs z).log.log| ≤ r r0 : 0 ≤ r t : Set ℝ := Ici ((Complex.abs z).log.log - r) yt : (-p.log).log ∈ t ⊢ (Complex.abs z).log.log ∈ t TACTIC:

https://github.com/girving/ray.git

0be790285dd0fce78913b0cb9bddaffa94bd25f9

Ray/Dynamics/Multibrot/Potential.lean

potential_approx

[262, 1]

[295, 40]

rw [←hb]

c✝ z✝ : 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 s : Super (f d) d OnePoint.infty := superF d z3 : 3 ≤ Complex.abs z z0 : 0 < Complex.abs z l2 : 0 < (Complex.abs z).log p : ℝ p0 : 0 < p lp0 : 0 < -p.log r : ℝ hr : iter_error d c z = r h : |(-p.log).log - (Complex.abs z).log.log| ≤ r r0 : 0 ≤ r t : Set ℝ := Ici ((Complex.abs z).log.log - r) yt : (-p.log).log ∈ t lt : (Complex.abs z).log.log ∈ t b : ℝ hb : dene ((Complex.abs z).log.log - r) = b ⊢ 0 ≤ b

c✝ z✝ : 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 s : Super (f d) d OnePoint.infty := superF d z3 : 3 ≤ Complex.abs z z0 : 0 < Complex.abs z l2 : 0 < (Complex.abs z).log p : ℝ p0 : 0 < p lp0 : 0 < -p.log r : ℝ hr : iter_error d c z = r h : |(-p.log).log - (Complex.abs z).log.log| ≤ r r0 : 0 ≤ r t : Set ℝ := Ici ((Complex.abs z).log.log - r) yt : (-p.log).log ∈ t lt : (Complex.abs z).log.log ∈ t b : ℝ hb : dene ((Complex.abs z).log.log - r) = b ⊢ 0 ≤ dene ((Complex.abs z).log.log - r)

Please generate a tactic in lean4 to solve the state. STATE: c✝ z✝ : 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 s : Super (f d) d OnePoint.infty := superF d z3 : 3 ≤ Complex.abs z z0 : 0 < Complex.abs z l2 : 0 < (Complex.abs z).log p : ℝ p0 : 0 < p lp0 : 0 < -p.log r : ℝ hr : iter_error d c z = r h : |(-p.log).log - (Complex.abs z).log.log| ≤ r r0 : 0 ≤ r t : Set ℝ := Ici ((Complex.abs z).log.log - r) yt : (-p.log).log ∈ t lt : (Complex.abs z).log.log ∈ t b : ℝ hb : dene ((Complex.abs z).log.log - r) = b ⊢ 0 ≤ b TACTIC:

https://github.com/girving/ray.git

0be790285dd0fce78913b0cb9bddaffa94bd25f9

Ray/Dynamics/Multibrot/Potential.lean

potential_approx

[262, 1]

[295, 40]

exact dene_nonneg

c✝ z✝ : 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 s : Super (f d) d OnePoint.infty := superF d z3 : 3 ≤ Complex.abs z z0 : 0 < Complex.abs z l2 : 0 < (Complex.abs z).log p : ℝ p0 : 0 < p lp0 : 0 < -p.log r : ℝ hr : iter_error d c z = r h : |(-p.log).log - (Complex.abs z).log.log| ≤ r r0 : 0 ≤ r t : Set ℝ := Ici ((Complex.abs z).log.log - r) yt : (-p.log).log ∈ t lt : (Complex.abs z).log.log ∈ t b : ℝ hb : dene ((Complex.abs z).log.log - r) = b ⊢ 0 ≤ dene ((Complex.abs z).log.log - r)

no goals

Please generate a tactic in lean4 to solve the state. STATE: c✝ z✝ : 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 s : Super (f d) d OnePoint.infty := superF d z3 : 3 ≤ Complex.abs z z0 : 0 < Complex.abs z l2 : 0 < (Complex.abs z).log p : ℝ p0 : 0 < p lp0 : 0 < -p.log r : ℝ hr : iter_error d c z = r h : |(-p.log).log - (Complex.abs z).log.log| ≤ r r0 : 0 ≤ r t : Set ℝ := Ici ((Complex.abs z).log.log - r) yt : (-p.log).log ∈ t lt : (Complex.abs z).log.log ∈ t b : ℝ hb : dene ((Complex.abs z).log.log - r) = b ⊢ 0 ≤ dene ((Complex.abs z).log.log - r) TACTIC:

https://github.com/girving/ray.git

0be790285dd0fce78913b0cb9bddaffa94bd25f9

Ray/Dynamics/Multibrot/Potential.lean

potential_approx

[262, 1]

[295, 40]

intro x m

c✝ z✝ : 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 s : Super (f d) d OnePoint.infty := superF d z3 : 3 ≤ Complex.abs z z0 : 0 < Complex.abs z l2 : 0 < (Complex.abs z).log p : ℝ p0 : 0 < p lp0 : 0 < -p.log r : ℝ hr : iter_error d c z = r h : |(-p.log).log - (Complex.abs z).log.log| ≤ r r0 : 0 ≤ r t : Set ℝ := Ici ((Complex.abs z).log.log - r) yt : (-p.log).log ∈ t lt : (Complex.abs z).log.log ∈ t b : ℝ hb : dene ((Complex.abs z).log.log - r) = b b0 : 0 ≤ b ⊢ ∀ x ∈ t, ‖deriv ene x‖ ≤ b

c✝ z✝ : 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 s : Super (f d) d OnePoint.infty := superF d z3 : 3 ≤ Complex.abs z z0 : 0 < Complex.abs z l2 : 0 < (Complex.abs z).log p : ℝ p0 : 0 < p lp0 : 0 < -p.log r : ℝ hr : iter_error d c z = r h : |(-p.log).log - (Complex.abs z).log.log| ≤ r r0 : 0 ≤ r t : Set ℝ := Ici ((Complex.abs z).log.log - r) yt : (-p.log).log ∈ t lt : (Complex.abs z).log.log ∈ t b : ℝ hb : dene ((Complex.abs z).log.log - r) = b b0 : 0 ≤ b x : ℝ m : x ∈ t ⊢ ‖deriv ene x‖ ≤ b

Please generate a tactic in lean4 to solve the state. STATE: c✝ z✝ : 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 s : Super (f d) d OnePoint.infty := superF d z3 : 3 ≤ Complex.abs z z0 : 0 < Complex.abs z l2 : 0 < (Complex.abs z).log p : ℝ p0 : 0 < p lp0 : 0 < -p.log r : ℝ hr : iter_error d c z = r h : |(-p.log).log - (Complex.abs z).log.log| ≤ r r0 : 0 ≤ r t : Set ℝ := Ici ((Complex.abs z).log.log - r) yt : (-p.log).log ∈ t lt : (Complex.abs z).log.log ∈ t b : ℝ hb : dene ((Complex.abs z).log.log - r) = b b0 : 0 ≤ b ⊢ ∀ x ∈ t, ‖deriv ene x‖ ≤ b TACTIC:

https://github.com/girving/ray.git

0be790285dd0fce78913b0cb9bddaffa94bd25f9

Ray/Dynamics/Multibrot/Potential.lean

potential_approx

[262, 1]

[295, 40]

simp only [Real.dist_eq, mem_Ici, ←hr, t] at m

c✝ z✝ : 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 s : Super (f d) d OnePoint.infty := superF d z3 : 3 ≤ Complex.abs z z0 : 0 < Complex.abs z l2 : 0 < (Complex.abs z).log p : ℝ p0 : 0 < p lp0 : 0 < -p.log r : ℝ hr : iter_error d c z = r h : |(-p.log).log - (Complex.abs z).log.log| ≤ r r0 : 0 ≤ r t : Set ℝ := Ici ((Complex.abs z).log.log - r) yt : (-p.log).log ∈ t lt : (Complex.abs z).log.log ∈ t b : ℝ hb : dene ((Complex.abs z).log.log - r) = b b0 : 0 ≤ b x : ℝ m : x ∈ t ⊢ ‖deriv ene x‖ ≤ b

c✝ z✝ : 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 s : Super (f d) d OnePoint.infty := superF d z3 : 3 ≤ Complex.abs z z0 : 0 < Complex.abs z l2 : 0 < (Complex.abs z).log p : ℝ p0 : 0 < p lp0 : 0 < -p.log r : ℝ hr : iter_error d c z = r h : |(-p.log).log - (Complex.abs z).log.log| ≤ r r0 : 0 ≤ r t : Set ℝ := Ici ((Complex.abs z).log.log - r) yt : (-p.log).log ∈ t lt : (Complex.abs z).log.log ∈ t b : ℝ hb : dene ((Complex.abs z).log.log - r) = b b0 : 0 ≤ b x : ℝ m : (Complex.abs z).log.log - iter_error d c z ≤ x ⊢ ‖deriv ene x‖ ≤ b

Please generate a tactic in lean4 to solve the state. STATE: c✝ z✝ : 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 s : Super (f d) d OnePoint.infty := superF d z3 : 3 ≤ Complex.abs z z0 : 0 < Complex.abs z l2 : 0 < (Complex.abs z).log p : ℝ p0 : 0 < p lp0 : 0 < -p.log r : ℝ hr : iter_error d c z = r h : |(-p.log).log - (Complex.abs z).log.log| ≤ r r0 : 0 ≤ r t : Set ℝ := Ici ((Complex.abs z).log.log - r) yt : (-p.log).log ∈ t lt : (Complex.abs z).log.log ∈ t b : ℝ hb : dene ((Complex.abs z).log.log - r) = b b0 : 0 ≤ b x : ℝ m : x ∈ t ⊢ ‖deriv ene x‖ ≤ b TACTIC:

https://github.com/girving/ray.git

0be790285dd0fce78913b0cb9bddaffa94bd25f9

Ray/Dynamics/Multibrot/Potential.lean

potential_approx

[262, 1]

[295, 40]

simp only [deriv_ene, norm_neg, Real.norm_of_nonneg dene_nonneg, ←hb, ←hr]

c✝ z✝ : 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 s : Super (f d) d OnePoint.infty := superF d z3 : 3 ≤ Complex.abs z z0 : 0 < Complex.abs z l2 : 0 < (Complex.abs z).log p : ℝ p0 : 0 < p lp0 : 0 < -p.log r : ℝ hr : iter_error d c z = r h : |(-p.log).log - (Complex.abs z).log.log| ≤ r r0 : 0 ≤ r t : Set ℝ := Ici ((Complex.abs z).log.log - r) yt : (-p.log).log ∈ t lt : (Complex.abs z).log.log ∈ t b : ℝ hb : dene ((Complex.abs z).log.log - r) = b b0 : 0 ≤ b x : ℝ m : (Complex.abs z).log.log - iter_error d c z ≤ x ⊢ ‖deriv ene x‖ ≤ b

c✝ z✝ : 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 s : Super (f d) d OnePoint.infty := superF d z3 : 3 ≤ Complex.abs z z0 : 0 < Complex.abs z l2 : 0 < (Complex.abs z).log p : ℝ p0 : 0 < p lp0 : 0 < -p.log r : ℝ hr : iter_error d c z = r h : |(-p.log).log - (Complex.abs z).log.log| ≤ r r0 : 0 ≤ r t : Set ℝ := Ici ((Complex.abs z).log.log - r) yt : (-p.log).log ∈ t lt : (Complex.abs z).log.log ∈ t b : ℝ hb : dene ((Complex.abs z).log.log - r) = b b0 : 0 ≤ b x : ℝ m : (Complex.abs z).log.log - iter_error d c z ≤ x ⊢ dene x ≤ dene ((Complex.abs z).log.log - iter_error d c z)

Please generate a tactic in lean4 to solve the state. STATE: c✝ z✝ : 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 s : Super (f d) d OnePoint.infty := superF d z3 : 3 ≤ Complex.abs z z0 : 0 < Complex.abs z l2 : 0 < (Complex.abs z).log p : ℝ p0 : 0 < p lp0 : 0 < -p.log r : ℝ hr : iter_error d c z = r h : |(-p.log).log - (Complex.abs z).log.log| ≤ r r0 : 0 ≤ r t : Set ℝ := Ici ((Complex.abs z).log.log - r) yt : (-p.log).log ∈ t lt : (Complex.abs z).log.log ∈ t b : ℝ hb : dene ((Complex.abs z).log.log - r) = b b0 : 0 ≤ b x : ℝ m : (Complex.abs z).log.log - iter_error d c z ≤ x ⊢ ‖deriv ene x‖ ≤ b TACTIC:

https://github.com/girving/ray.git

0be790285dd0fce78913b0cb9bddaffa94bd25f9

Ray/Dynamics/Multibrot/Potential.lean

potential_approx

[262, 1]

[295, 40]

apply dene_anti (sub_nonneg.mpr (iter_error_le_log_log_abs d z4 cz)) m

c✝ z✝ : 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 s : Super (f d) d OnePoint.infty := superF d z3 : 3 ≤ Complex.abs z z0 : 0 < Complex.abs z l2 : 0 < (Complex.abs z).log p : ℝ p0 : 0 < p lp0 : 0 < -p.log r : ℝ hr : iter_error d c z = r h : |(-p.log).log - (Complex.abs z).log.log| ≤ r r0 : 0 ≤ r t : Set ℝ := Ici ((Complex.abs z).log.log - r) yt : (-p.log).log ∈ t lt : (Complex.abs z).log.log ∈ t b : ℝ hb : dene ((Complex.abs z).log.log - r) = b b0 : 0 ≤ b x : ℝ m : (Complex.abs z).log.log - iter_error d c z ≤ x ⊢ dene x ≤ dene ((Complex.abs z).log.log - iter_error d c z)

no goals

Please generate a tactic in lean4 to solve the state. STATE: c✝ z✝ : 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 s : Super (f d) d OnePoint.infty := superF d z3 : 3 ≤ Complex.abs z z0 : 0 < Complex.abs z l2 : 0 < (Complex.abs z).log p : ℝ p0 : 0 < p lp0 : 0 < -p.log r : ℝ hr : iter_error d c z = r h : |(-p.log).log - (Complex.abs z).log.log| ≤ r r0 : 0 ≤ r t : Set ℝ := Ici ((Complex.abs z).log.log - r) yt : (-p.log).log ∈ t lt : (Complex.abs z).log.log ∈ t b : ℝ hb : dene ((Complex.abs z).log.log - r) = b b0 : 0 ≤ b x : ℝ m : (Complex.abs z).log.log - iter_error d c z ≤ x ⊢ dene x ≤ dene ((Complex.abs z).log.log - iter_error d c z) TACTIC:

https://github.com/girving/ray.git

0be790285dd0fce78913b0cb9bddaffa94bd25f9

Ray/Dynamics/Multibrot/Potential.lean

potential_approx

[262, 1]

[295, 40]

bound

c✝ z✝ : 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 s : Super (f d) d OnePoint.infty := superF d z3 : 3 ≤ Complex.abs z z0 : 0 < Complex.abs z l2 : 0 < (Complex.abs z).log p : ℝ p0 : 0 < p lp0 : 0 < -p.log r : ℝ hr : iter_error d c z = r h : |(-p.log).log - (Complex.abs z).log.log| ≤ r r0 : 0 ≤ r t : Set ℝ := Ici ((Complex.abs z).log.log - r) yt : (-p.log).log ∈ t lt : (Complex.abs z).log.log ∈ t b : ℝ hb : dene ((Complex.abs z).log.log - r) = b b0 : 0 ≤ b bound : ∀ x ∈ t, ‖deriv ene x‖ ≤ b m : |ene (-p.log).log - ene (Complex.abs z).log.log| ≤ b * |(-p.log).log - (Complex.abs z).log.log| ⊢ 0 ≤ b

no goals

Please generate a tactic in lean4 to solve the state. STATE: c✝ z✝ : 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 s : Super (f d) d OnePoint.infty := superF d z3 : 3 ≤ Complex.abs z z0 : 0 < Complex.abs z l2 : 0 < (Complex.abs z).log p : ℝ p0 : 0 < p lp0 : 0 < -p.log r : ℝ hr : iter_error d c z = r h : |(-p.log).log - (Complex.abs z).log.log| ≤ r r0 : 0 ≤ r t : Set ℝ := Ici ((Complex.abs z).log.log - r) yt : (-p.log).log ∈ t lt : (Complex.abs z).log.log ∈ t b : ℝ hb : dene ((Complex.abs z).log.log - r) = b b0 : 0 ≤ b bound : ∀ x ∈ t, ‖deriv ene x‖ ≤ b m : |ene (-p.log).log - ene (Complex.abs z).log.log| ≤ b * |(-p.log).log - (Complex.abs z).log.log| ⊢ 0 ≤ b TACTIC:

https://github.com/girving/ray.git

0be790285dd0fce78913b0cb9bddaffa94bd25f9

Ray/Misc/Bounds.lean

late_iff_disjoint_range

[27, 1]

[30, 83]

simp only [Late, ge_iff_le, Finset.disjoint_iff_ne, Finset.mem_range, ne_eq]

m : ℕ A : Finset ℕ ⊢ Late A m ↔ Disjoint A (Finset.range m)

m : ℕ A : Finset ℕ ⊢ (∀ n ∈ A, m ≤ n) ↔ ∀ a ∈ A, ∀ b < m, ¬a = b

Please generate a tactic in lean4 to solve the state. STATE: m : ℕ A : Finset ℕ ⊢ Late A m ↔ Disjoint A (Finset.range m) TACTIC:

https://github.com/girving/ray.git

0be790285dd0fce78913b0cb9bddaffa94bd25f9

Ray/Misc/Bounds.lean

late_iff_disjoint_range

[27, 1]

[30, 83]

constructor

m : ℕ A : Finset ℕ ⊢ (∀ n ∈ A, m ≤ n) ↔ ∀ a ∈ A, ∀ b < m, ¬a = b

case mp m : ℕ A : Finset ℕ ⊢ (∀ n ∈ A, m ≤ n) → ∀ a ∈ A, ∀ b < m, ¬a = b case mpr m : ℕ A : Finset ℕ ⊢ (∀ a ∈ A, ∀ b < m, ¬a = b) → ∀ n ∈ A, m ≤ n

Please generate a tactic in lean4 to solve the state. STATE: m : ℕ A : Finset ℕ ⊢ (∀ n ∈ A, m ≤ n) ↔ ∀ a ∈ A, ∀ b < m, ¬a = b TACTIC:

https://github.com/girving/ray.git

0be790285dd0fce78913b0cb9bddaffa94bd25f9

Ray/Misc/Bounds.lean

late_iff_disjoint_range

[27, 1]

[30, 83]

intro h n na b bm

case mp m : ℕ A : Finset ℕ ⊢ (∀ n ∈ A, m ≤ n) → ∀ a ∈ A, ∀ b < m, ¬a = b

case mp m : ℕ A : Finset ℕ h : ∀ n ∈ A, m ≤ n n : ℕ na : n ∈ A b : ℕ bm : b < m ⊢ ¬n = b

Please generate a tactic in lean4 to solve the state. STATE: case mp m : ℕ A : Finset ℕ ⊢ (∀ n ∈ A, m ≤ n) → ∀ a ∈ A, ∀ b < m, ¬a = b TACTIC:

https://github.com/girving/ray.git

0be790285dd0fce78913b0cb9bddaffa94bd25f9

Ray/Misc/Bounds.lean

late_iff_disjoint_range

[27, 1]

[30, 83]

linarith [h _ na]

case mp m : ℕ A : Finset ℕ h : ∀ n ∈ A, m ≤ n n : ℕ na : n ∈ A b : ℕ bm : b < m ⊢ ¬n = b

no goals

Please generate a tactic in lean4 to solve the state. STATE: case mp m : ℕ A : Finset ℕ h : ∀ n ∈ A, m ≤ n n : ℕ na : n ∈ A b : ℕ bm : b < m ⊢ ¬n = b TACTIC:

https://github.com/girving/ray.git

0be790285dd0fce78913b0cb9bddaffa94bd25f9

Ray/Misc/Bounds.lean

late_iff_disjoint_range

[27, 1]

[30, 83]

intro h n na

case mpr m : ℕ A : Finset ℕ ⊢ (∀ a ∈ A, ∀ b < m, ¬a = b) → ∀ n ∈ A, m ≤ n

case mpr m : ℕ A : Finset ℕ h : ∀ a ∈ A, ∀ b < m, ¬a = b n : ℕ na : n ∈ A ⊢ m ≤ n

Please generate a tactic in lean4 to solve the state. STATE: case mpr m : ℕ A : Finset ℕ ⊢ (∀ a ∈ A, ∀ b < m, ¬a = b) → ∀ n ∈ A, m ≤ n TACTIC:

https://github.com/girving/ray.git

0be790285dd0fce78913b0cb9bddaffa94bd25f9

Ray/Misc/Bounds.lean

late_iff_disjoint_range

[27, 1]

[30, 83]

specialize h n na n

case mpr m : ℕ A : Finset ℕ h : ∀ a ∈ A, ∀ b < m, ¬a = b n : ℕ na : n ∈ A ⊢ m ≤ n

case mpr m : ℕ A : Finset ℕ n : ℕ na : n ∈ A h : n < m → ¬n = n ⊢ m ≤ n

Please generate a tactic in lean4 to solve the state. STATE: case mpr m : ℕ A : Finset ℕ h : ∀ a ∈ A, ∀ b < m, ¬a = b n : ℕ na : n ∈ A ⊢ m ≤ n TACTIC:

https://github.com/girving/ray.git

0be790285dd0fce78913b0cb9bddaffa94bd25f9

Ray/Misc/Bounds.lean

late_iff_disjoint_range

[27, 1]

[30, 83]

simpa [not_true, imp_false, not_lt] using h

case mpr m : ℕ A : Finset ℕ n : ℕ na : n ∈ A h : n < m → ¬n = n ⊢ m ≤ n

no goals

Please generate a tactic in lean4 to solve the state. STATE: case mpr m : ℕ A : Finset ℕ n : ℕ na : n ∈ A h : n < m → ¬n = n ⊢ m ≤ n TACTIC:

https://github.com/girving/ray.git

0be790285dd0fce78913b0cb9bddaffa94bd25f9

Ray/Misc/Bounds.lean

sdiff_late

[32, 1]

[38, 17]

intro Bm n nAB

m : ℕ B A : Finset ℕ ⊢ B ≥ Finset.range m → Late (A \ B) m

m : ℕ B A : Finset ℕ Bm : B ≥ Finset.range m n : ℕ nAB : n ∈ A \ B ⊢ n ≥ m

Please generate a tactic in lean4 to solve the state. STATE: m : ℕ B A : Finset ℕ ⊢ B ≥ Finset.range m → Late (A \ B) m TACTIC:

https://github.com/girving/ray.git

0be790285dd0fce78913b0cb9bddaffa94bd25f9

Ray/Misc/Bounds.lean

sdiff_late

[32, 1]

[38, 17]

rw [Finset.mem_sdiff] at nAB

m : ℕ B A : Finset ℕ Bm : B ≥ Finset.range m n : ℕ nAB : n ∈ A \ B ⊢ n ≥ m

m : ℕ B A : Finset ℕ Bm : B ≥ Finset.range m n : ℕ nAB : n ∈ A ∧ n ∉ B ⊢ n ≥ m

Please generate a tactic in lean4 to solve the state. STATE: m : ℕ B A : Finset ℕ Bm : B ≥ Finset.range m n : ℕ nAB : n ∈ A \ B ⊢ n ≥ m TACTIC:

https://github.com/girving/ray.git

0be790285dd0fce78913b0cb9bddaffa94bd25f9

Ray/Misc/Bounds.lean

sdiff_late

[32, 1]

[38, 17]

by_contra h

m : ℕ B A : Finset ℕ Bm : B ≥ Finset.range m n : ℕ nAB : n ∈ A ∧ n ∉ B ⊢ n ≥ m

m : ℕ B A : Finset ℕ Bm : B ≥ Finset.range m n : ℕ nAB : n ∈ A ∧ n ∉ B h : ¬n ≥ m ⊢ False

Please generate a tactic in lean4 to solve the state. STATE: m : ℕ B A : Finset ℕ Bm : B ≥ Finset.range m n : ℕ nAB : n ∈ A ∧ n ∉ B ⊢ n ≥ m TACTIC:

https://github.com/girving/ray.git

0be790285dd0fce78913b0cb9bddaffa94bd25f9

Ray/Misc/Bounds.lean

sdiff_late

[32, 1]

[38, 17]

simp only [not_le] at h

m : ℕ B A : Finset ℕ Bm : B ≥ Finset.range m n : ℕ nAB : n ∈ A ∧ n ∉ B h : ¬n ≥ m ⊢ False

m : ℕ B A : Finset ℕ Bm : B ≥ Finset.range m n : ℕ nAB : n ∈ A ∧ n ∉ B h : n < m ⊢ False

Please generate a tactic in lean4 to solve the state. STATE: m : ℕ B A : Finset ℕ Bm : B ≥ Finset.range m n : ℕ nAB : n ∈ A ∧ n ∉ B h : ¬n ≥ m ⊢ False TACTIC:

https://github.com/girving/ray.git

0be790285dd0fce78913b0cb9bddaffa94bd25f9

Ray/Misc/Bounds.lean

sdiff_late

[32, 1]

[38, 17]

have nr := Finset.mem_range.mpr h

m : ℕ B A : Finset ℕ Bm : B ≥ Finset.range m n : ℕ nAB : n ∈ A ∧ n ∉ B h : n < m ⊢ False

m : ℕ B A : Finset ℕ Bm : B ≥ Finset.range m n : ℕ nAB : n ∈ A ∧ n ∉ B h : n < m nr : n ∈ Finset.range m ⊢ False

Please generate a tactic in lean4 to solve the state. STATE: m : ℕ B A : Finset ℕ Bm : B ≥ Finset.range m n : ℕ nAB : n ∈ A ∧ n ∉ B h : n < m ⊢ False TACTIC:

https://github.com/girving/ray.git

0be790285dd0fce78913b0cb9bddaffa94bd25f9

Ray/Misc/Bounds.lean

sdiff_late

[32, 1]

[38, 17]

have nB := Finset.mem_of_subset Bm nr

m : ℕ B A : Finset ℕ Bm : B ≥ Finset.range m n : ℕ nAB : n ∈ A ∧ n ∉ B h : n < m nr : n ∈ Finset.range m ⊢ False

m : ℕ B A : Finset ℕ Bm : B ≥ Finset.range m n : ℕ nAB : n ∈ A ∧ n ∉ B h : n < m nr : n ∈ Finset.range m nB : n ∈ B ⊢ False

Please generate a tactic in lean4 to solve the state. STATE: m : ℕ B A : Finset ℕ Bm : B ≥ Finset.range m n : ℕ nAB : n ∈ A ∧ n ∉ B h : n < m nr : n ∈ Finset.range m ⊢ False TACTIC:

https://github.com/girving/ray.git

0be790285dd0fce78913b0cb9bddaffa94bd25f9

Ray/Misc/Bounds.lean

sdiff_late

[32, 1]

[38, 17]

exact nAB.2 nB

m : ℕ B A : Finset ℕ Bm : B ≥ Finset.range m n : ℕ nAB : n ∈ A ∧ n ∉ B h : n < m nr : n ∈ Finset.range m nB : n ∈ B ⊢ False

no goals

Please generate a tactic in lean4 to solve the state. STATE: m : ℕ B A : Finset ℕ Bm : B ≥ Finset.range m n : ℕ nAB : n ∈ A ∧ n ∉ B h : n < m nr : n ∈ Finset.range m nB : n ∈ B ⊢ False TACTIC:

https://github.com/girving/ray.git

0be790285dd0fce78913b0cb9bddaffa94bd25f9

Ray/Misc/Bounds.lean

partial_geometric_bound

[41, 1]

[44, 57]

intro n _

a : ℝ N : Finset ℕ a0 : 0 ≤ a a1 : a < 1 ⊢ ∀ n ∉ N, 0 ≤ a ^ n

a : ℝ N : Finset ℕ a0 : 0 ≤ a a1 : a < 1 n : ℕ a✝ : n ∉ N ⊢ 0 ≤ a ^ n

Please generate a tactic in lean4 to solve the state. STATE: a : ℝ N : Finset ℕ a0 : 0 ≤ a a1 : a < 1 ⊢ ∀ n ∉ N, 0 ≤ a ^ n TACTIC:

https://github.com/girving/ray.git

0be790285dd0fce78913b0cb9bddaffa94bd25f9

Ray/Misc/Bounds.lean

partial_geometric_bound

[41, 1]

[44, 57]

bound

a : ℝ N : Finset ℕ a0 : 0 ≤ a a1 : a < 1 n : ℕ a✝ : n ∉ N ⊢ 0 ≤ a ^ n

no goals

Please generate a tactic in lean4 to solve the state. STATE: a : ℝ N : Finset ℕ a0 : 0 ≤ a a1 : a < 1 n : ℕ a✝ : n ∉ N ⊢ 0 ≤ a ^ n TACTIC:

https://github.com/girving/ray.git

0be790285dd0fce78913b0cb9bddaffa94bd25f9

Ray/Misc/Bounds.lean

partial_scaled_geometric_bound

[46, 1]

[49, 42]

rw [←Finset.mul_sum]

a : ℝ c : ℝ≥0 N : Finset ℕ a0 : 0 ≤ a a1 : a < 1 ⊢ (N.sum fun n => ↑c * a ^ n) ≤ ↑c * (1 - a)⁻¹

a : ℝ c : ℝ≥0 N : Finset ℕ a0 : 0 ≤ a a1 : a < 1 ⊢ (↑c * N.sum fun i => a ^ i) ≤ ↑c * (1 - a)⁻¹

Please generate a tactic in lean4 to solve the state. STATE: a : ℝ c : ℝ≥0 N : Finset ℕ a0 : 0 ≤ a a1 : a < 1 ⊢ (N.sum fun n => ↑c * a ^ n) ≤ ↑c * (1 - a)⁻¹ TACTIC:

https://github.com/girving/ray.git

0be790285dd0fce78913b0cb9bddaffa94bd25f9

Ray/Misc/Bounds.lean

partial_scaled_geometric_bound

[46, 1]

[49, 42]

bound [partial_geometric_bound N a0 a1]

a : ℝ c : ℝ≥0 N : Finset ℕ a0 : 0 ≤ a a1 : a < 1 ⊢ (↑c * N.sum fun i => a ^ i) ≤ ↑c * (1 - a)⁻¹

no goals

Please generate a tactic in lean4 to solve the state. STATE: a : ℝ c : ℝ≥0 N : Finset ℕ a0 : 0 ≤ a a1 : a < 1 ⊢ (↑c * N.sum fun i => a ^ i) ≤ ↑c * (1 - a)⁻¹ TACTIC:

https://github.com/girving/ray.git

0be790285dd0fce78913b0cb9bddaffa94bd25f9

Ray/Misc/Bounds.lean

late_series_sum

[52, 1]

[66, 44]

set Ns := Finset.image (fun n ↦ n - m) N

m : ℕ N : Finset ℕ h : Late N m f : ℕ → ℝ ⊢ N.sum f = (Finset.image (fun n => n - m) N).sum fun n => f (n + m)

m : ℕ N : Finset ℕ h : Late N m f : ℕ → ℝ Ns : Finset ℕ := Finset.image (fun n => n - m) N ⊢ N.sum f = Ns.sum fun n => f (n + m)

Please generate a tactic in lean4 to solve the state. STATE: m : ℕ N : Finset ℕ h : Late N m f : ℕ → ℝ ⊢ N.sum f = (Finset.image (fun n => n - m) N).sum fun n => f (n + m) TACTIC:

https://github.com/girving/ray.git

0be790285dd0fce78913b0cb9bddaffa94bd25f9

Ray/Misc/Bounds.lean

late_series_sum

[52, 1]

[66, 44]

rw [NNs]

m : ℕ N : Finset ℕ h : Late N m f : ℕ → ℝ Ns : Finset ℕ := Finset.image (fun n => n - m) N NNs : N = Finset.image (fun n => n + m) Ns ⊢ N.sum f = Ns.sum fun n => f (n + m)

m : ℕ N : Finset ℕ h : Late N m f : ℕ → ℝ Ns : Finset ℕ := Finset.image (fun n => n - m) N NNs : N = Finset.image (fun n => n + m) Ns ⊢ (Finset.image (fun n => n + m) Ns).sum f = Ns.sum fun n => f (n + m)

Please generate a tactic in lean4 to solve the state. STATE: m : ℕ N : Finset ℕ h : Late N m f : ℕ → ℝ Ns : Finset ℕ := Finset.image (fun n => n - m) N NNs : N = Finset.image (fun n => n + m) Ns ⊢ N.sum f = Ns.sum fun n => f (n + m) TACTIC:

https://github.com/girving/ray.git

0be790285dd0fce78913b0cb9bddaffa94bd25f9

Ray/Misc/Bounds.lean

late_series_sum

[52, 1]

[66, 44]

apply Finset.sum_image

m : ℕ N : Finset ℕ h : Late N m f : ℕ → ℝ Ns : Finset ℕ := Finset.image (fun n => n - m) N NNs : N = Finset.image (fun n => n + m) Ns ⊢ (Finset.image (fun n => n + m) Ns).sum f = Ns.sum fun n => f (n + m)

case a m : ℕ N : Finset ℕ h : Late N m f : ℕ → ℝ Ns : Finset ℕ := Finset.image (fun n => n - m) N NNs : N = Finset.image (fun n => n + m) Ns ⊢ ∀ x ∈ Ns, ∀ y ∈ Ns, x + m = y + m → x = y

Please generate a tactic in lean4 to solve the state. STATE: m : ℕ N : Finset ℕ h : Late N m f : ℕ → ℝ Ns : Finset ℕ := Finset.image (fun n => n - m) N NNs : N = Finset.image (fun n => n + m) Ns ⊢ (Finset.image (fun n => n + m) Ns).sum f = Ns.sum fun n => f (n + m) TACTIC:

https://github.com/girving/ray.git

0be790285dd0fce78913b0cb9bddaffa94bd25f9

Ray/Misc/Bounds.lean

late_series_sum

[52, 1]

[66, 44]

intro a _ b _

case a m : ℕ N : Finset ℕ h : Late N m f : ℕ → ℝ Ns : Finset ℕ := Finset.image (fun n => n - m) N NNs : N = Finset.image (fun n => n + m) Ns ⊢ ∀ x ∈ Ns, ∀ y ∈ Ns, x + m = y + m → x = y

case a m : ℕ N : Finset ℕ h : Late N m f : ℕ → ℝ Ns : Finset ℕ := Finset.image (fun n => n - m) N NNs : N = Finset.image (fun n => n + m) Ns a : ℕ a✝¹ : a ∈ Ns b : ℕ a✝ : b ∈ Ns ⊢ a + m = b + m → a = b

Please generate a tactic in lean4 to solve the state. STATE: case a m : ℕ N : Finset ℕ h : Late N m f : ℕ → ℝ Ns : Finset ℕ := Finset.image (fun n => n - m) N NNs : N = Finset.image (fun n => n + m) Ns ⊢ ∀ x ∈ Ns, ∀ y ∈ Ns, x + m = y + m → x = y TACTIC:

https://github.com/girving/ray.git

0be790285dd0fce78913b0cb9bddaffa94bd25f9

Ray/Misc/Bounds.lean

late_series_sum

[52, 1]

[66, 44]

exact Nat.add_right_cancel

case a m : ℕ N : Finset ℕ h : Late N m f : ℕ → ℝ Ns : Finset ℕ := Finset.image (fun n => n - m) N NNs : N = Finset.image (fun n => n + m) Ns a : ℕ a✝¹ : a ∈ Ns b : ℕ a✝ : b ∈ Ns ⊢ a + m = b + m → a = b

no goals

Please generate a tactic in lean4 to solve the state. STATE: case a m : ℕ N : Finset ℕ h : Late N m f : ℕ → ℝ Ns : Finset ℕ := Finset.image (fun n => n - m) N NNs : N = Finset.image (fun n => n + m) Ns a : ℕ a✝¹ : a ∈ Ns b : ℕ a✝ : b ∈ Ns ⊢ a + m = b + m → a = b TACTIC:

https://github.com/girving/ray.git

0be790285dd0fce78913b0cb9bddaffa94bd25f9

Ray/Misc/Bounds.lean

late_series_sum

[52, 1]

[66, 44]

apply Finset.ext

m : ℕ N : Finset ℕ h : Late N m f : ℕ → ℝ Ns : Finset ℕ := Finset.image (fun n => n - m) N ⊢ N = Finset.image (fun n => n + m) Ns

case a m : ℕ N : Finset ℕ h : Late N m f : ℕ → ℝ Ns : Finset ℕ := Finset.image (fun n => n - m) N ⊢ ∀ (a : ℕ), a ∈ N ↔ a ∈ Finset.image (fun n => n + m) Ns

Please generate a tactic in lean4 to solve the state. STATE: m : ℕ N : Finset ℕ h : Late N m f : ℕ → ℝ Ns : Finset ℕ := Finset.image (fun n => n - m) N ⊢ N = Finset.image (fun n => n + m) Ns TACTIC:

https://github.com/girving/ray.git

0be790285dd0fce78913b0cb9bddaffa94bd25f9

Ray/Misc/Bounds.lean

late_series_sum

[52, 1]

[66, 44]

intro k

case a m : ℕ N : Finset ℕ h : Late N m f : ℕ → ℝ Ns : Finset ℕ := Finset.image (fun n => n - m) N ⊢ ∀ (a : ℕ), a ∈ N ↔ a ∈ Finset.image (fun n => n + m) Ns

case a m : ℕ N : Finset ℕ h : Late N m f : ℕ → ℝ Ns : Finset ℕ := Finset.image (fun n => n - m) N k : ℕ ⊢ k ∈ N ↔ k ∈ Finset.image (fun n => n + m) Ns

Please generate a tactic in lean4 to solve the state. STATE: case a m : ℕ N : Finset ℕ h : Late N m f : ℕ → ℝ Ns : Finset ℕ := Finset.image (fun n => n - m) N ⊢ ∀ (a : ℕ), a ∈ N ↔ a ∈ Finset.image (fun n => n + m) Ns TACTIC:

https://github.com/girving/ray.git

0be790285dd0fce78913b0cb9bddaffa94bd25f9

Ray/Misc/Bounds.lean

late_series_sum

[52, 1]

[66, 44]

rw [Finset.image_image, Finset.mem_image]

case a m : ℕ N : Finset ℕ h : Late N m f : ℕ → ℝ Ns : Finset ℕ := Finset.image (fun n => n - m) N k : ℕ ⊢ k ∈ N ↔ k ∈ Finset.image (fun n => n + m) Ns

case a m : ℕ N : Finset ℕ h : Late N m f : ℕ → ℝ Ns : Finset ℕ := Finset.image (fun n => n - m) N k : ℕ ⊢ k ∈ N ↔ ∃ a ∈ N, ((fun n => n + m) ∘ fun n => n - m) a = k

Please generate a tactic in lean4 to solve the state. STATE: case a m : ℕ N : Finset ℕ h : Late N m f : ℕ → ℝ Ns : Finset ℕ := Finset.image (fun n => n - m) N k : ℕ ⊢ k ∈ N ↔ k ∈ Finset.image (fun n => n + m) Ns TACTIC:

https://github.com/girving/ray.git

0be790285dd0fce78913b0cb9bddaffa94bd25f9

Ray/Misc/Bounds.lean

late_series_sum

[52, 1]

[66, 44]

simp

case a m : ℕ N : Finset ℕ h : Late N m f : ℕ → ℝ Ns : Finset ℕ := Finset.image (fun n => n - m) N k : ℕ ⊢ k ∈ N ↔ ∃ a ∈ N, ((fun n => n + m) ∘ fun n => n - m) a = k

case a m : ℕ N : Finset ℕ h : Late N m f : ℕ → ℝ Ns : Finset ℕ := Finset.image (fun n => n - m) N k : ℕ ⊢ k ∈ N ↔ ∃ a ∈ N, a - m + m = k

Please generate a tactic in lean4 to solve the state. STATE: case a m : ℕ N : Finset ℕ h : Late N m f : ℕ → ℝ Ns : Finset ℕ := Finset.image (fun n => n - m) N k : ℕ ⊢ k ∈ N ↔ ∃ a ∈ N, ((fun n => n + m) ∘ fun n => n - m) a = k TACTIC:

https://github.com/girving/ray.git

0be790285dd0fce78913b0cb9bddaffa94bd25f9

Ray/Misc/Bounds.lean

late_series_sum

[52, 1]

[66, 44]

apply Iff.intro

case a m : ℕ N : Finset ℕ h : Late N m f : ℕ → ℝ Ns : Finset ℕ := Finset.image (fun n => n - m) N k : ℕ ⊢ k ∈ N ↔ ∃ a ∈ N, a - m + m = k

case a.mp m : ℕ N : Finset ℕ h : Late N m f : ℕ → ℝ Ns : Finset ℕ := Finset.image (fun n => n - m) N k : ℕ ⊢ k ∈ N → ∃ a ∈ N, a - m + m = k case a.mpr m : ℕ N : Finset ℕ h : Late N m f : ℕ → ℝ Ns : Finset ℕ := Finset.image (fun n => n - m) N k : ℕ ⊢ (∃ a ∈ N, a - m + m = k) → k ∈ N

Please generate a tactic in lean4 to solve the state. STATE: case a m : ℕ N : Finset ℕ h : Late N m f : ℕ → ℝ Ns : Finset ℕ := Finset.image (fun n => n - m) N k : ℕ ⊢ k ∈ N ↔ ∃ a ∈ N, a - m + m = k TACTIC:

https://github.com/girving/ray.git

0be790285dd0fce78913b0cb9bddaffa94bd25f9

Ray/Misc/Bounds.lean

late_series_sum

[52, 1]

[66, 44]

intro kN

case a.mp m : ℕ N : Finset ℕ h : Late N m f : ℕ → ℝ Ns : Finset ℕ := Finset.image (fun n => n - m) N k : ℕ ⊢ k ∈ N → ∃ a ∈ N, a - m + m = k

case a.mp m : ℕ N : Finset ℕ h : Late N m f : ℕ → ℝ Ns : Finset ℕ := Finset.image (fun n => n - m) N k : ℕ kN : k ∈ N ⊢ ∃ a ∈ N, a - m + m = k

Please generate a tactic in lean4 to solve the state. STATE: case a.mp m : ℕ N : Finset ℕ h : Late N m f : ℕ → ℝ Ns : Finset ℕ := Finset.image (fun n => n - m) N k : ℕ ⊢ k ∈ N → ∃ a ∈ N, a - m + m = k TACTIC:

https://github.com/girving/ray.git

0be790285dd0fce78913b0cb9bddaffa94bd25f9

Ray/Misc/Bounds.lean

late_series_sum

[52, 1]

[66, 44]

exists k

case a.mp m : ℕ N : Finset ℕ h : Late N m f : ℕ → ℝ Ns : Finset ℕ := Finset.image (fun n => n - m) N k : ℕ kN : k ∈ N ⊢ ∃ a ∈ N, a - m + m = k

case a.mp m : ℕ N : Finset ℕ h : Late N m f : ℕ → ℝ Ns : Finset ℕ := Finset.image (fun n => n - m) N k : ℕ kN : k ∈ N ⊢ k ∈ N ∧ k - m + m = k

Please generate a tactic in lean4 to solve the state. STATE: case a.mp m : ℕ N : Finset ℕ h : Late N m f : ℕ → ℝ Ns : Finset ℕ := Finset.image (fun n => n - m) N k : ℕ kN : k ∈ N ⊢ ∃ a ∈ N, a - m + m = k TACTIC:

https://github.com/girving/ray.git

0be790285dd0fce78913b0cb9bddaffa94bd25f9

Ray/Misc/Bounds.lean

late_series_sum

[52, 1]

[66, 44]

apply And.intro

case a.mp m : ℕ N : Finset ℕ h : Late N m f : ℕ → ℝ Ns : Finset ℕ := Finset.image (fun n => n - m) N k : ℕ kN : k ∈ N ⊢ k ∈ N ∧ k - m + m = k

case a.mp.left m : ℕ N : Finset ℕ h : Late N m f : ℕ → ℝ Ns : Finset ℕ := Finset.image (fun n => n - m) N k : ℕ kN : k ∈ N ⊢ k ∈ N case a.mp.right m : ℕ N : Finset ℕ h : Late N m f : ℕ → ℝ Ns : Finset ℕ := Finset.image (fun n => n - m) N k : ℕ kN : k ∈ N ⊢ k - m + m = k

Please generate a tactic in lean4 to solve the state. STATE: case a.mp m : ℕ N : Finset ℕ h : Late N m f : ℕ → ℝ Ns : Finset ℕ := Finset.image (fun n => n - m) N k : ℕ kN : k ∈ N ⊢ k ∈ N ∧ k - m + m = k TACTIC:

https://github.com/girving/ray.git

0be790285dd0fce78913b0cb9bddaffa94bd25f9

Ray/Misc/Bounds.lean

late_series_sum

[52, 1]

[66, 44]

assumption

case a.mp.left m : ℕ N : Finset ℕ h : Late N m f : ℕ → ℝ Ns : Finset ℕ := Finset.image (fun n => n - m) N k : ℕ kN : k ∈ N ⊢ k ∈ N case a.mp.right m : ℕ N : Finset ℕ h : Late N m f : ℕ → ℝ Ns : Finset ℕ := Finset.image (fun n => n - m) N k : ℕ kN : k ∈ N ⊢ k - m + m = k

case a.mp.right m : ℕ N : Finset ℕ h : Late N m f : ℕ → ℝ Ns : Finset ℕ := Finset.image (fun n => n - m) N k : ℕ kN : k ∈ N ⊢ k - m + m = k

Please generate a tactic in lean4 to solve the state. STATE: case a.mp.left m : ℕ N : Finset ℕ h : Late N m f : ℕ → ℝ Ns : Finset ℕ := Finset.image (fun n => n - m) N k : ℕ kN : k ∈ N ⊢ k ∈ N case a.mp.right m : ℕ N : Finset ℕ h : Late N m f : ℕ → ℝ Ns : Finset ℕ := Finset.image (fun n => n - m) N k : ℕ kN : k ∈ N ⊢ k - m + m = k TACTIC:

https://github.com/girving/ray.git

0be790285dd0fce78913b0cb9bddaffa94bd25f9

Ray/Misc/Bounds.lean

late_series_sum

[52, 1]

[66, 44]

exact Nat.sub_add_cancel (h k kN)

case a.mp.right m : ℕ N : Finset ℕ h : Late N m f : ℕ → ℝ Ns : Finset ℕ := Finset.image (fun n => n - m) N k : ℕ kN : k ∈ N ⊢ k - m + m = k

no goals

Please generate a tactic in lean4 to solve the state. STATE: case a.mp.right m : ℕ N : Finset ℕ h : Late N m f : ℕ → ℝ Ns : Finset ℕ := Finset.image (fun n => n - m) N k : ℕ kN : k ∈ N ⊢ k - m + m = k TACTIC:

https://github.com/girving/ray.git

0be790285dd0fce78913b0cb9bddaffa94bd25f9

Ray/Misc/Bounds.lean

late_series_sum

[52, 1]

[66, 44]

intro ha

case a.mpr m : ℕ N : Finset ℕ h : Late N m f : ℕ → ℝ Ns : Finset ℕ := Finset.image (fun n => n - m) N k : ℕ ⊢ (∃ a ∈ N, a - m + m = k) → k ∈ N

case a.mpr m : ℕ N : Finset ℕ h : Late N m f : ℕ → ℝ Ns : Finset ℕ := Finset.image (fun n => n - m) N k : ℕ ha : ∃ a ∈ N, a - m + m = k ⊢ k ∈ N

Please generate a tactic in lean4 to solve the state. STATE: case a.mpr m : ℕ N : Finset ℕ h : Late N m f : ℕ → ℝ Ns : Finset ℕ := Finset.image (fun n => n - m) N k : ℕ ⊢ (∃ a ∈ N, a - m + m = k) → k ∈ N TACTIC:

https://github.com/girving/ray.git

0be790285dd0fce78913b0cb9bddaffa94bd25f9

Ray/Misc/Bounds.lean

late_series_sum

[52, 1]

[66, 44]

rcases ha with ⟨a, aN, ak⟩

case a.mpr m : ℕ N : Finset ℕ h : Late N m f : ℕ → ℝ Ns : Finset ℕ := Finset.image (fun n => n - m) N k : ℕ ha : ∃ a ∈ N, a - m + m = k ⊢ k ∈ N

case a.mpr.intro.intro m : ℕ N : Finset ℕ h : Late N m f : ℕ → ℝ Ns : Finset ℕ := Finset.image (fun n => n - m) N k a : ℕ aN : a ∈ N ak : a - m + m = k ⊢ k ∈ N

Please generate a tactic in lean4 to solve the state. STATE: case a.mpr m : ℕ N : Finset ℕ h : Late N m f : ℕ → ℝ Ns : Finset ℕ := Finset.image (fun n => n - m) N k : ℕ ha : ∃ a ∈ N, a - m + m = k ⊢ k ∈ N TACTIC:

https://github.com/girving/ray.git

0be790285dd0fce78913b0cb9bddaffa94bd25f9

Ray/Misc/Bounds.lean

late_series_sum

[52, 1]

[66, 44]

rw [Nat.sub_add_cancel (h a aN)] at ak

case a.mpr.intro.intro m : ℕ N : Finset ℕ h : Late N m f : ℕ → ℝ Ns : Finset ℕ := Finset.image (fun n => n - m) N k a : ℕ aN : a ∈ N ak : a - m + m = k ⊢ k ∈ N

case a.mpr.intro.intro m : ℕ N : Finset ℕ h : Late N m f : ℕ → ℝ Ns : Finset ℕ := Finset.image (fun n => n - m) N k a : ℕ aN : a ∈ N ak : a = k ⊢ k ∈ N

Please generate a tactic in lean4 to solve the state. STATE: case a.mpr.intro.intro m : ℕ N : Finset ℕ h : Late N m f : ℕ → ℝ Ns : Finset ℕ := Finset.image (fun n => n - m) N k a : ℕ aN : a ∈ N ak : a - m + m = k ⊢ k ∈ N TACTIC:

https://github.com/girving/ray.git

0be790285dd0fce78913b0cb9bddaffa94bd25f9

Ray/Misc/Bounds.lean

late_series_sum

[52, 1]

[66, 44]

rw [← ak]

case a.mpr.intro.intro m : ℕ N : Finset ℕ h : Late N m f : ℕ → ℝ Ns : Finset ℕ := Finset.image (fun n => n - m) N k a : ℕ aN : a ∈ N ak : a = k ⊢ k ∈ N

case a.mpr.intro.intro m : ℕ N : Finset ℕ h : Late N m f : ℕ → ℝ Ns : Finset ℕ := Finset.image (fun n => n - m) N k a : ℕ aN : a ∈ N ak : a = k ⊢ a ∈ N

Please generate a tactic in lean4 to solve the state. STATE: case a.mpr.intro.intro m : ℕ N : Finset ℕ h : Late N m f : ℕ → ℝ Ns : Finset ℕ := Finset.image (fun n => n - m) N k a : ℕ aN : a ∈ N ak : a = k ⊢ k ∈ N TACTIC:

https://github.com/girving/ray.git

0be790285dd0fce78913b0cb9bddaffa94bd25f9

Ray/Misc/Bounds.lean

late_series_sum

[52, 1]

[66, 44]

assumption

case a.mpr.intro.intro m : ℕ N : Finset ℕ h : Late N m f : ℕ → ℝ Ns : Finset ℕ := Finset.image (fun n => n - m) N k a : ℕ aN : a ∈ N ak : a = k ⊢ a ∈ N

no goals

Please generate a tactic in lean4 to solve the state. STATE: case a.mpr.intro.intro m : ℕ N : Finset ℕ h : Late N m f : ℕ → ℝ Ns : Finset ℕ := Finset.image (fun n => n - m) N k a : ℕ aN : a ∈ N ak : a = k ⊢ a ∈ N TACTIC:

https://github.com/girving/ray.git

0be790285dd0fce78913b0cb9bddaffa94bd25f9

Ray/Misc/Bounds.lean

late_series_sum'

[69, 1]

[72, 28]

exists Finset.image (fun n ↦ n - m) N

m : ℕ N : Finset ℕ h : Late N m f : ℕ → ℝ ⊢ ∃ M, N.sum f = M.sum fun n => f (n + m)

m : ℕ N : Finset ℕ h : Late N m f : ℕ → ℝ ⊢ N.sum f = (Finset.image (fun n => n - m) N).sum fun n => f (n + m)

Please generate a tactic in lean4 to solve the state. STATE: m : ℕ N : Finset ℕ h : Late N m f : ℕ → ℝ ⊢ ∃ M, N.sum f = M.sum fun n => f (n + m) TACTIC:

https://github.com/girving/ray.git

0be790285dd0fce78913b0cb9bddaffa94bd25f9

Ray/Misc/Bounds.lean

late_series_sum'

[69, 1]

[72, 28]

exact late_series_sum h f

m : ℕ N : Finset ℕ h : Late N m f : ℕ → ℝ ⊢ N.sum f = (Finset.image (fun n => n - m) N).sum fun n => f (n + m)

no goals

Please generate a tactic in lean4 to solve the state. STATE: m : ℕ N : Finset ℕ h : Late N m f : ℕ → ℝ ⊢ N.sum f = (Finset.image (fun n => n - m) N).sum fun n => f (n + m) TACTIC:

https://github.com/girving/ray.git

0be790285dd0fce78913b0cb9bddaffa94bd25f9

Ray/Misc/Bounds.lean

late_geometric_bound

[74, 1]

[83, 35]

rcases late_series_sum' h (fun n ↦ a^n) with ⟨M,L⟩

m : ℕ a : ℝ N : Finset ℕ h : Late N m a0 : 0 ≤ a a1 : a < 1 ⊢ (N.sum fun n => a ^ n) ≤ a ^ m * (1 - a)⁻¹

case intro m : ℕ a : ℝ N : Finset ℕ h : Late N m a0 : 0 ≤ a a1 : a < 1 M : Finset ℕ L : (N.sum fun n => a ^ n) = M.sum fun n => a ^ (n + m) ⊢ (N.sum fun n => a ^ n) ≤ a ^ m * (1 - a)⁻¹

Please generate a tactic in lean4 to solve the state. STATE: m : ℕ a : ℝ N : Finset ℕ h : Late N m a0 : 0 ≤ a a1 : a < 1 ⊢ (N.sum fun n => a ^ n) ≤ a ^ m * (1 - a)⁻¹ TACTIC:

https://github.com/girving/ray.git

0be790285dd0fce78913b0cb9bddaffa94bd25f9

Ray/Misc/Bounds.lean

late_geometric_bound

[74, 1]

[83, 35]

rw [L]

case intro m : ℕ a : ℝ N : Finset ℕ h : Late N m a0 : 0 ≤ a a1 : a < 1 M : Finset ℕ L : (N.sum fun n => a ^ n) = M.sum fun n => a ^ (n + m) ⊢ (N.sum fun n => a ^ n) ≤ a ^ m * (1 - a)⁻¹

case intro m : ℕ a : ℝ N : Finset ℕ h : Late N m a0 : 0 ≤ a a1 : a < 1 M : Finset ℕ L : (N.sum fun n => a ^ n) = M.sum fun n => a ^ (n + m) ⊢ (M.sum fun n => a ^ (n + m)) ≤ a ^ m * (1 - a)⁻¹

Please generate a tactic in lean4 to solve the state. STATE: case intro m : ℕ a : ℝ N : Finset ℕ h : Late N m a0 : 0 ≤ a a1 : a < 1 M : Finset ℕ L : (N.sum fun n => a ^ n) = M.sum fun n => a ^ (n + m) ⊢ (N.sum fun n => a ^ n) ≤ a ^ m * (1 - a)⁻¹ TACTIC:

https://github.com/girving/ray.git

0be790285dd0fce78913b0cb9bddaffa94bd25f9

Ray/Misc/Bounds.lean

late_geometric_bound

[74, 1]

[83, 35]

clear L

case intro m : ℕ a : ℝ N : Finset ℕ h : Late N m a0 : 0 ≤ a a1 : a < 1 M : Finset ℕ L : (N.sum fun n => a ^ n) = M.sum fun n => a ^ (n + m) ⊢ (M.sum fun n => a ^ (n + m)) ≤ a ^ m * (1 - a)⁻¹

case intro m : ℕ a : ℝ N : Finset ℕ h : Late N m a0 : 0 ≤ a a1 : a < 1 M : Finset ℕ ⊢ (M.sum fun n => a ^ (n + m)) ≤ a ^ m * (1 - a)⁻¹

Please generate a tactic in lean4 to solve the state. STATE: case intro m : ℕ a : ℝ N : Finset ℕ h : Late N m a0 : 0 ≤ a a1 : a < 1 M : Finset ℕ L : (N.sum fun n => a ^ n) = M.sum fun n => a ^ (n + m) ⊢ (M.sum fun n => a ^ (n + m)) ≤ a ^ m * (1 - a)⁻¹ TACTIC:

https://github.com/girving/ray.git

0be790285dd0fce78913b0cb9bddaffa94bd25f9

Ray/Misc/Bounds.lean

late_geometric_bound

[74, 1]

[83, 35]

have pa : (fun n ↦ a^(n + m)) = (fun n ↦ a^n * a^m) := by apply funext; intro n; rw [pow_add]

case intro m : ℕ a : ℝ N : Finset ℕ h : Late N m a0 : 0 ≤ a a1 : a < 1 M : Finset ℕ ⊢ (M.sum fun n => a ^ (n + m)) ≤ a ^ m * (1 - a)⁻¹

case intro m : ℕ a : ℝ N : Finset ℕ h : Late N m a0 : 0 ≤ a a1 : a < 1 M : Finset ℕ pa : (fun n => a ^ (n + m)) = fun n => a ^ n * a ^ m ⊢ (M.sum fun n => a ^ (n + m)) ≤ a ^ m * (1 - a)⁻¹

Please generate a tactic in lean4 to solve the state. STATE: case intro m : ℕ a : ℝ N : Finset ℕ h : Late N m a0 : 0 ≤ a a1 : a < 1 M : Finset ℕ ⊢ (M.sum fun n => a ^ (n + m)) ≤ a ^ m * (1 - a)⁻¹ TACTIC:

https://github.com/girving/ray.git

0be790285dd0fce78913b0cb9bddaffa94bd25f9

Ray/Misc/Bounds.lean

late_geometric_bound

[74, 1]

[83, 35]

calc M.sum (fun n ↦ a^(n + m)) = M.sum (fun n ↦ a^n * a^m) := by rw [ pa ] _ = M.sum (fun n ↦ a^n) * a^m := (Finset.sum_mul _ _ _).symm _ ≤ (1 - a)⁻¹ * a^m := by bound [partial_geometric_bound M a0 a1] _ = a^m * (1 - a)⁻¹ := by ring

case intro m : ℕ a : ℝ N : Finset ℕ h : Late N m a0 : 0 ≤ a a1 : a < 1 M : Finset ℕ pa : (fun n => a ^ (n + m)) = fun n => a ^ n * a ^ m ⊢ (M.sum fun n => a ^ (n + m)) ≤ a ^ m * (1 - a)⁻¹

no goals

Please generate a tactic in lean4 to solve the state. STATE: case intro m : ℕ a : ℝ N : Finset ℕ h : Late N m a0 : 0 ≤ a a1 : a < 1 M : Finset ℕ pa : (fun n => a ^ (n + m)) = fun n => a ^ n * a ^ m ⊢ (M.sum fun n => a ^ (n + m)) ≤ a ^ m * (1 - a)⁻¹ TACTIC:

https://github.com/girving/ray.git

0be790285dd0fce78913b0cb9bddaffa94bd25f9

Ray/Misc/Bounds.lean

late_geometric_bound

[74, 1]

[83, 35]

apply funext

m : ℕ a : ℝ N : Finset ℕ h : Late N m a0 : 0 ≤ a a1 : a < 1 M : Finset ℕ ⊢ (fun n => a ^ (n + m)) = fun n => a ^ n * a ^ m

case h m : ℕ a : ℝ N : Finset ℕ h : Late N m a0 : 0 ≤ a a1 : a < 1 M : Finset ℕ ⊢ ∀ (x : ℕ), a ^ (x + m) = a ^ x * a ^ m

Please generate a tactic in lean4 to solve the state. STATE: m : ℕ a : ℝ N : Finset ℕ h : Late N m a0 : 0 ≤ a a1 : a < 1 M : Finset ℕ ⊢ (fun n => a ^ (n + m)) = fun n => a ^ n * a ^ m TACTIC:

https://github.com/girving/ray.git

0be790285dd0fce78913b0cb9bddaffa94bd25f9

Ray/Misc/Bounds.lean

late_geometric_bound

[74, 1]

[83, 35]

intro n

case h m : ℕ a : ℝ N : Finset ℕ h : Late N m a0 : 0 ≤ a a1 : a < 1 M : Finset ℕ ⊢ ∀ (x : ℕ), a ^ (x + m) = a ^ x * a ^ m

case h m : ℕ a : ℝ N : Finset ℕ h : Late N m a0 : 0 ≤ a a1 : a < 1 M : Finset ℕ n : ℕ ⊢ a ^ (n + m) = a ^ n * a ^ m

Please generate a tactic in lean4 to solve the state. STATE: case h m : ℕ a : ℝ N : Finset ℕ h : Late N m a0 : 0 ≤ a a1 : a < 1 M : Finset ℕ ⊢ ∀ (x : ℕ), a ^ (x + m) = a ^ x * a ^ m TACTIC:

https://github.com/girving/ray.git

0be790285dd0fce78913b0cb9bddaffa94bd25f9

Ray/Misc/Bounds.lean

late_geometric_bound

[74, 1]

[83, 35]

rw [pow_add]

case h m : ℕ a : ℝ N : Finset ℕ h : Late N m a0 : 0 ≤ a a1 : a < 1 M : Finset ℕ n : ℕ ⊢ a ^ (n + m) = a ^ n * a ^ m

no goals

Please generate a tactic in lean4 to solve the state. STATE: case h m : ℕ a : ℝ N : Finset ℕ h : Late N m a0 : 0 ≤ a a1 : a < 1 M : Finset ℕ n : ℕ ⊢ a ^ (n + m) = a ^ n * a ^ m TACTIC:

https://github.com/girving/ray.git

0be790285dd0fce78913b0cb9bddaffa94bd25f9

Ray/Misc/Bounds.lean

late_geometric_bound

[74, 1]

[83, 35]

rw [ pa ]

m : ℕ a : ℝ N : Finset ℕ h : Late N m a0 : 0 ≤ a a1 : a < 1 M : Finset ℕ pa : (fun n => a ^ (n + m)) = fun n => a ^ n * a ^ m ⊢ (M.sum fun n => a ^ (n + m)) = M.sum fun n => a ^ n * a ^ m

no goals

Please generate a tactic in lean4 to solve the state. STATE: m : ℕ a : ℝ N : Finset ℕ h : Late N m a0 : 0 ≤ a a1 : a < 1 M : Finset ℕ pa : (fun n => a ^ (n + m)) = fun n => a ^ n * a ^ m ⊢ (M.sum fun n => a ^ (n + m)) = M.sum fun n => a ^ n * a ^ m TACTIC:

https://github.com/girving/ray.git

0be790285dd0fce78913b0cb9bddaffa94bd25f9

Ray/Misc/Bounds.lean

late_geometric_bound

[74, 1]

[83, 35]

bound [partial_geometric_bound M a0 a1]

m : ℕ a : ℝ N : Finset ℕ h : Late N m a0 : 0 ≤ a a1 : a < 1 M : Finset ℕ pa : (fun n => a ^ (n + m)) = fun n => a ^ n * a ^ m ⊢ (M.sum fun n => a ^ n) * a ^ m ≤ (1 - a)⁻¹ * a ^ m

no goals

Please generate a tactic in lean4 to solve the state. STATE: m : ℕ a : ℝ N : Finset ℕ h : Late N m a0 : 0 ≤ a a1 : a < 1 M : Finset ℕ pa : (fun n => a ^ (n + m)) = fun n => a ^ n * a ^ m ⊢ (M.sum fun n => a ^ n) * a ^ m ≤ (1 - a)⁻¹ * a ^ m TACTIC:

https://github.com/girving/ray.git

0be790285dd0fce78913b0cb9bddaffa94bd25f9

Ray/Misc/Bounds.lean

late_geometric_bound

[74, 1]

[83, 35]

ring

m : ℕ a : ℝ N : Finset ℕ h : Late N m a0 : 0 ≤ a a1 : a < 1 M : Finset ℕ pa : (fun n => a ^ (n + m)) = fun n => a ^ n * a ^ m ⊢ (1 - a)⁻¹ * a ^ m = a ^ m * (1 - a)⁻¹

no goals

Please generate a tactic in lean4 to solve the state. STATE: m : ℕ a : ℝ N : Finset ℕ h : Late N m a0 : 0 ≤ a a1 : a < 1 M : Finset ℕ pa : (fun n => a ^ (n + m)) = fun n => a ^ n * a ^ m ⊢ (1 - a)⁻¹ * a ^ m = a ^ m * (1 - a)⁻¹ TACTIC:

https://github.com/girving/ray.git

0be790285dd0fce78913b0cb9bddaffa94bd25f9

Ray/Misc/Bounds.lean

finset_partition

[85, 1]

[95, 21]

apply Finset.ext

A B : Finset ℕ ⊢ A = A \ B ∪ A ∩ B

case a A B : Finset ℕ ⊢ ∀ (a : ℕ), a ∈ A ↔ a ∈ A \ B ∪ A ∩ B

Please generate a tactic in lean4 to solve the state. STATE: A B : Finset ℕ ⊢ A = A \ B ∪ A ∩ B TACTIC:

https://github.com/girving/ray.git

0be790285dd0fce78913b0cb9bddaffa94bd25f9

Ray/Misc/Bounds.lean

finset_partition

[85, 1]

[95, 21]

simp only [Finset.mem_union, Finset.mem_sdiff, Finset.mem_inter]

case a A B : Finset ℕ ⊢ ∀ (a : ℕ), a ∈ A ↔ a ∈ A \ B ∪ A ∩ B

case a A B : Finset ℕ ⊢ ∀ (a : ℕ), a ∈ A ↔ a ∈ A ∧ a ∉ B ∨ a ∈ A ∧ a ∈ B

Please generate a tactic in lean4 to solve the state. STATE: case a A B : Finset ℕ ⊢ ∀ (a : ℕ), a ∈ A ↔ a ∈ A \ B ∪ A ∩ B TACTIC:

https://github.com/girving/ray.git

0be790285dd0fce78913b0cb9bddaffa94bd25f9

Ray/Misc/Bounds.lean

finset_partition

[85, 1]

[95, 21]

intro x

case a A B : Finset ℕ ⊢ ∀ (a : ℕ), a ∈ A ↔ a ∈ A ∧ a ∉ B ∨ a ∈ A ∧ a ∈ B

case a A B : Finset ℕ x : ℕ ⊢ x ∈ A ↔ x ∈ A ∧ x ∉ B ∨ x ∈ A ∧ x ∈ B

Please generate a tactic in lean4 to solve the state. STATE: case a A B : Finset ℕ ⊢ ∀ (a : ℕ), a ∈ A ↔ a ∈ A ∧ a ∉ B ∨ a ∈ A ∧ a ∈ B TACTIC:

https://github.com/girving/ray.git

0be790285dd0fce78913b0cb9bddaffa94bd25f9

Ray/Misc/Bounds.lean

finset_partition

[85, 1]

[95, 21]

constructor

case a A B : Finset ℕ x : ℕ ⊢ x ∈ A ↔ x ∈ A ∧ x ∉ B ∨ x ∈ A ∧ x ∈ B

case a.mp A B : Finset ℕ x : ℕ ⊢ x ∈ A → x ∈ A ∧ x ∉ B ∨ x ∈ A ∧ x ∈ B case a.mpr A B : Finset ℕ x : ℕ ⊢ x ∈ A ∧ x ∉ B ∨ x ∈ A ∧ x ∈ B → x ∈ A

Please generate a tactic in lean4 to solve the state. STATE: case a A B : Finset ℕ x : ℕ ⊢ x ∈ A ↔ x ∈ A ∧ x ∉ B ∨ x ∈ A ∧ x ∈ B TACTIC:

https://github.com/girving/ray.git

0be790285dd0fce78913b0cb9bddaffa94bd25f9

Ray/Misc/Bounds.lean

finset_partition

[85, 1]

[95, 21]

intro a

case a.mp A B : Finset ℕ x : ℕ ⊢ x ∈ A → x ∈ A ∧ x ∉ B ∨ x ∈ A ∧ x ∈ B

case a.mp A B : Finset ℕ x : ℕ a : x ∈ A ⊢ x ∈ A ∧ x ∉ B ∨ x ∈ A ∧ x ∈ B

Please generate a tactic in lean4 to solve the state. STATE: case a.mp A B : Finset ℕ x : ℕ ⊢ x ∈ A → x ∈ A ∧ x ∉ B ∨ x ∈ A ∧ x ∈ B TACTIC:

https://github.com/girving/ray.git

0be790285dd0fce78913b0cb9bddaffa94bd25f9

Ray/Misc/Bounds.lean

finset_partition

[85, 1]

[95, 21]

by_cases b : x ∈ B

case a.mp A B : Finset ℕ x : ℕ a : x ∈ A ⊢ x ∈ A ∧ x ∉ B ∨ x ∈ A ∧ x ∈ B

case pos A B : Finset ℕ x : ℕ a : x ∈ A b : x ∈ B ⊢ x ∈ A ∧ x ∉ B ∨ x ∈ A ∧ x ∈ B case neg A B : Finset ℕ x : ℕ a : x ∈ A b : x ∉ B ⊢ x ∈ A ∧ x ∉ B ∨ x ∈ A ∧ x ∈ B

Please generate a tactic in lean4 to solve the state. STATE: case a.mp A B : Finset ℕ x : ℕ a : x ∈ A ⊢ x ∈ A ∧ x ∉ B ∨ x ∈ A ∧ x ∈ B TACTIC:

https://github.com/girving/ray.git

0be790285dd0fce78913b0cb9bddaffa94bd25f9

Ray/Misc/Bounds.lean

finset_partition

[85, 1]

[95, 21]

right

case pos A B : Finset ℕ x : ℕ a : x ∈ A b : x ∈ B ⊢ x ∈ A ∧ x ∉ B ∨ x ∈ A ∧ x ∈ B

case pos.h A B : Finset ℕ x : ℕ a : x ∈ A b : x ∈ B ⊢ x ∈ A ∧ x ∈ B

Please generate a tactic in lean4 to solve the state. STATE: case pos A B : Finset ℕ x : ℕ a : x ∈ A b : x ∈ B ⊢ x ∈ A ∧ x ∉ B ∨ x ∈ A ∧ x ∈ B TACTIC:

https://github.com/girving/ray.git

0be790285dd0fce78913b0cb9bddaffa94bd25f9

Ray/Misc/Bounds.lean

finset_partition

[85, 1]

[95, 21]

use a,b

case pos.h A B : Finset ℕ x : ℕ a : x ∈ A b : x ∈ B ⊢ x ∈ A ∧ x ∈ B

no goals

Please generate a tactic in lean4 to solve the state. STATE: case pos.h A B : Finset ℕ x : ℕ a : x ∈ A b : x ∈ B ⊢ x ∈ A ∧ x ∈ B TACTIC:

https://github.com/girving/ray.git

0be790285dd0fce78913b0cb9bddaffa94bd25f9

Ray/Misc/Bounds.lean

finset_partition

[85, 1]

[95, 21]

left

case neg A B : Finset ℕ x : ℕ a : x ∈ A b : x ∉ B ⊢ x ∈ A ∧ x ∉ B ∨ x ∈ A ∧ x ∈ B

case neg.h A B : Finset ℕ x : ℕ a : x ∈ A b : x ∉ B ⊢ x ∈ A ∧ x ∉ B

Please generate a tactic in lean4 to solve the state. STATE: case neg A B : Finset ℕ x : ℕ a : x ∈ A b : x ∉ B ⊢ x ∈ A ∧ x ∉ B ∨ x ∈ A ∧ x ∈ B TACTIC:

https://github.com/girving/ray.git

0be790285dd0fce78913b0cb9bddaffa94bd25f9

Ray/Misc/Bounds.lean

finset_partition

[85, 1]

[95, 21]

use a,b

case neg.h A B : Finset ℕ x : ℕ a : x ∈ A b : x ∉ B ⊢ x ∈ A ∧ x ∉ B

no goals

Please generate a tactic in lean4 to solve the state. STATE: case neg.h A B : Finset ℕ x : ℕ a : x ∈ A b : x ∉ B ⊢ x ∈ A ∧ x ∉ B TACTIC:

https://github.com/girving/ray.git

0be790285dd0fce78913b0cb9bddaffa94bd25f9

Ray/Misc/Bounds.lean

finset_partition

[85, 1]

[95, 21]

intro h

case a.mpr A B : Finset ℕ x : ℕ ⊢ x ∈ A ∧ x ∉ B ∨ x ∈ A ∧ x ∈ B → x ∈ A

case a.mpr A B : Finset ℕ x : ℕ h : x ∈ A ∧ x ∉ B ∨ x ∈ A ∧ x ∈ B ⊢ x ∈ A

Please generate a tactic in lean4 to solve the state. STATE: case a.mpr A B : Finset ℕ x : ℕ ⊢ x ∈ A ∧ x ∉ B ∨ x ∈ A ∧ x ∈ B → x ∈ A TACTIC: