| import Mathlib | |
| set_option linter.unusedVariables.analyzeTactics true | |
| open NNReal Nat BigOperators Finset | |
| -- imo-official.org/problems/IMO2007SL.pdf | |
| lemma aux1 | |
| (a : β β NNReal) | |
| (m : β) | |
| (hmβ : Nat.succ 4 β€ m) : | |
| a (m - 1) ^ 2 + a m ^ 2 + a 1 ^ 2 + a 2 ^ 2 β€ β x β Finset.range m, a (x + 1) ^ 2 := by | |
| let fs: Finset β := {0, 1, m-2, m-1} | |
| have hβ: fs = {0, 1, m-2, m-1} := by rfl | |
| have hβ: fs β Finset.range m := by | |
| refine insert_subset ?_ ?_ | |
| . refine mem_range.mpr ?_ | |
| exact zero_lt_of_lt hmβ | |
| . refine insert_subset ?_ ?_ | |
| . refine mem_range.mpr ?_ | |
| linarith | |
| . refine insert_subset ?_ ?_ | |
| . refine mem_range.mpr ?_ | |
| refine sub_lt ?_ (by norm_num) | |
| exact zero_lt_of_lt hmβ | |
| . refine singleton_subset_iff.mpr ?_ | |
| refine mem_range.mpr ?_ | |
| exact sub_one_lt_of_lt hmβ | |
| rw [β Finset.sum_sdiff hβ] | |
| have hβ: β x β fs, a (x + 1) ^ 2 = a (m - 1) ^ 2 + a m ^ 2 + a 1 ^ 2 + a 2 ^ 2 := by | |
| rw [hβ] | |
| have gβ: 0 β fs := by exact mem_insert_self 0 {1, m - 2, m - 1} | |
| rw [β Finset.add_sum_erase fs _ gβ] | |
| simp | |
| have gβ: 4 β€ m - 1 := by exact Nat.le_sub_one_of_lt hmβ | |
| have gβ: 3 β€ m - 2 := by exact le_sub_of_add_le hmβ | |
| have gβ: fs.erase 0 = ({1, m - 2, m - 1}:(Finset β)) := by | |
| rw [hβ] | |
| refine erase_insert ?h | |
| refine forall_mem_not_eq'.mp ?_ | |
| intros b hbβ hbβ | |
| rw [hbβ] at hbβ | |
| norm_num at hbβ | |
| cases' hbβ with hbβ hbβ | |
| . rw [β hbβ] at gβ | |
| linarith | |
| . rw [β hbβ] at gβ | |
| linarith | |
| rw [gβ] | |
| have gβ: (1:β) β ({1, m - 2, m - 1}:(Finset β)) := by | |
| exact mem_insert_self 1 {m - 2, m - 1} | |
| rw [β Finset.add_sum_erase _ _ gβ] | |
| simp | |
| rw [Finset.erase_eq_self.mpr ?_] | |
| . have gβ : (m - 2) β ({m - 2, m - 1}:(Finset β)) := by | |
| exact mem_insert_self (m - 2) {m - 1} | |
| rw [β Finset.add_sum_erase _ _ gβ ] | |
| simp | |
| rw [Finset.erase_eq_self.mpr ?_] | |
| . rw [Finset.sum_singleton, Nat.sub_add_cancel (by linarith)] | |
| rw [β Nat.sub_add_comm (by linarith)] | |
| simp | |
| ring_nf | |
| . refine Finset.not_mem_singleton.mpr ?_ | |
| omega | |
| . refine forall_mem_not_eq'.mp ?_ | |
| intros b hbβ hbβ | |
| rw [hbβ] at hbβ | |
| simp at hbβ | |
| cases' hbβ with hbβ hbβ | |
| . rw [β hbβ] at gβ | |
| linarith | |
| . rw [β hbβ] at gβ | |
| linarith | |
| rw [add_comm _ (β x β fs, a (x + 1) ^ 2), hβ] | |
| exact le_self_add | |
| lemma aux2 | |
| (a : β β NNReal) : | |
| β (n : β), | |
| 4 < n β§ n < 101 β | |
| (β (x y : β), x % n = y % n β a (x + 1) = a (y + 1)) β | |
| β x β range n, (a (x + 1) ^ 4 + 2 * a (x + 1) ^ 2 * a (x + 2) ^ 2 + 2 * a (x + 1) ^ 2 * a (x + 3) ^ 2) β€ | |
| (β x β range n, a (x + 1) ^ 2) ^ 2 := by | |
| intro n hnβ hnβ | |
| cases' hnβ with hnβ hnβ | |
| have hnβ: n = (n - 2) + 1 + 1 := by omega | |
| nth_rw 1 [hnβ,] | |
| rw [Finset.sum_range_succ, sum_range_succ] | |
| have hnβ: a (n - 2 + 1) = a (n - 1) := by | |
| refine congrArg a (by omega) | |
| have hnβ : a (n - 2 + 3) = a 1 := by | |
| refine hnβ (n - 2 + 2) 0 ?_ | |
| rw [Nat.zero_mod, Nat.sub_add_cancel ?_] | |
| . rw [Nat.mod_self n] | |
| . linarith | |
| have hnβ: a (n - 2 + 1 + 3) = a 2 := by | |
| refine hnβ (n - 2 + 3) 1 ?_ | |
| symm | |
| rw [Nat.mod_eq_of_lt (by linarith)] | |
| have gβ: n - 2 + 3 = n + 1 := by linarith | |
| rw [gβ] | |
| refine Eq.symm (mod_eq_of_modEq ?_ (by linarith)) | |
| exact Nat.add_modEq_left | |
| rw [β hnβ, hnβ, hnβ , hnβ] | |
| refine le_induction ?_ ?_ n hnβ | |
| . repeat rw [Finset.sum_range_succ] | |
| simp | |
| ring_nf | |
| repeat refine add_le_add_right ?_ _ | |
| refine le_of_eq ?_ | |
| rfl | |
| . intros m hmβ hmβ | |
| have hmβ: m + 1 - 2 = m - 2 + 1 := by | |
| rw [add_comm, add_comm _ 1, Nat.add_sub_assoc ?_ 1] | |
| omega | |
| rw [hmβ, Finset.sum_range_succ, sum_range_succ] | |
| have hmβ: m - 2 + 1 = m - 1 := by exact id (Eq.symm hmβ) | |
| have hmβ: m - 2 + 2 = m := by exact Eq.symm ((fun {m n} => pred_eq_succ_iff.mp) hmβ) | |
| have hmβ : m - 2 + 3 = m + 1 := by omega | |
| have hmβ: m + 1 - 1 = m := by exact rfl | |
| rw [hmβ, hmβ, hmβ , hmβ] | |
| clear hmβ hmβ hmβ hmβ | |
| rw [add_sq, add_assoc ((β x β Finset.range m, a (x + 1) ^ 2) ^ 2)] | |
| have hβ β: 2 * a (m - 1) ^ 2 * a (m + 1) ^ 2 + 2 * a m ^ 2 * a (m + 1) ^ 2 | |
| + 2 * a (m + 1) ^ 2 * a 1 ^ 2 + 2 * a (m + 1) ^ 2 * a 2 ^ 2 + a (m + 1) ^ 4 β€ | |
| (2 * β x β Finset.range m, a (x + 1) ^ 2) * a (m + 1) ^ 2 + (a (m + 1) ^ 2) ^ 2 := by | |
| rw [β pow_mul] | |
| simp | |
| have hβ β: 2 * a (m - 1) ^ 2 * a (m + 1) ^ 2 + 2 * a m ^ 2 * a (m + 1) ^ 2 + 2 * a (m + 1) ^ 2 * a 1 ^ 2 + | |
| 2 * a (m + 1) ^ 2 * a 2 ^ 2 = | |
| 2 * a (m + 1) ^ 2 * (a (m - 1) ^ 2 + a m ^ 2 + a 1 ^ 2 + a 2 ^ 2) := by | |
| ring_nf | |
| rw [hβ β, mul_assoc 2 _ (a (m + 1) ^ 2), mul_comm (β x β Finset.range m, a (x + 1) ^ 2), β mul_assoc 2] | |
| have hβ β: a (m - 1) ^ 2 + a m ^ 2 + a 1 ^ 2 + a 2 ^ 2 β€ β x β Finset.range m, a (x + 1) ^ 2 := by | |
| exact aux1 a m hmβ | |
| refine mul_le_mul ?_ ?_ ?_ ?_ | |
| . exact le_of_eq (by rfl) | |
| . exact hβ β | |
| . exact _root_.zero_le (a (m - 1) ^ 2 + a m ^ 2 + a 1 ^ 2 + a 2 ^ 2) | |
| . exact _root_.zero_le (2 * a (m + 1) ^ 2) | |
| have hβ β: β x β Finset.range (m - 2), (a (x + 1) ^ 4 + 2 * a (x + 1) ^ 2 * a (x + 2) ^ 2 + 2 * a (x + 1) ^ 2 * a (x + 3) ^ 2) + | |
| a (m - 1) ^ 4 + 2 * a (m - 1) ^ 2 * a m ^ 2 + a m ^ 4 + 2 * a m ^ 2 * a 1 ^ 2 | |
| β€ (β x β Finset.range m, a (x + 1) ^ 2) ^ 2 := by | |
| have hβ β: β x β Finset.range (m - 2), (a (x + 1) ^ 4 + 2 * a (x + 1) ^ 2 * a (x + 2) ^ 2 + 2 * a (x + 1) ^ 2 * a (x + 3) ^ 2) + | |
| a (m - 1) ^ 4 + 2 * a (m - 1) ^ 2 * a m ^ 2 + a m ^ 4 + 2 * a m ^ 2 * a 1 ^ 2 | |
| β€ β x β Finset.range (m - 2), (a (x + 1) ^ 4 + 2 * a (x + 1) ^ 2 * a (x + 2) ^ 2 + 2 * a (x + 1) ^ 2 * a (x + 3) ^ 2) + | |
| (a (m - 1) ^ 4 + 2 * a (m - 1) ^ 2 * a m ^ 2 + 2 * a (m - 1) ^ 2 * a 1 ^ 2) + | |
| (a m ^ 4 + 2 * a m ^ 2 * a 1 ^ 2 + 2 * a m ^ 2 * a 2 ^ 2) := by | |
| repeat rw [add_assoc] | |
| repeat refine add_le_add_left ?_ _ | |
| have hβ β : 2 * a (m - 1) ^ 2 * a 1 ^ 2 + (a m ^ 4 + (2 * a m ^ 2 * a 1 ^ 2 + 2 * a m ^ 2 * a 2 ^ 2)) = | |
| (a m ^ 4 + 2 * a m ^ 2 * a 1 ^ 2) + (2 * a (m - 1) ^ 2 * a 1 ^ 2 + 2 * a m ^ 2 * a 2 ^ 2) := by | |
| ring_nf | |
| rw [hβ β ] | |
| exact le_self_add | |
| exact le_trans hβ β hmβ | |
| apply add_le_add hβ β at hβ β | |
| have hβ β: β x β Finset.range (m - 2), (a (x + 1) ^ 4 + 2 * a (x + 1) ^ 2 * a (x + 2) ^ 2 + 2 * a (x + 1) ^ 2 * a (x + 3) ^ 2) | |
| + a (m - 1) ^ 4 + 2 * a (m - 1) ^ 2 * a m ^ 2 + a m ^ 4 + 2 * a m ^ 2 * a 1 ^ 2 | |
| + (2 * a (m - 1) ^ 2 * a (m + 1) ^ 2 + 2 * a m ^ 2 * a (m + 1) ^ 2 + 2 * a (m + 1) ^ 2 * a 1 ^ 2 | |
| + 2 * a (m + 1) ^ 2 * a 2 ^ 2 + a (m + 1) ^ 4) | |
| = β x β Finset.range (m - 2), (a (x + 1) ^ 4 + 2 * a (x + 1) ^ 2 * a (x + 2) ^ 2 + 2 * a (x + 1) ^ 2 * a (x + 3) ^ 2) + | |
| (a (m - 1) ^ 4 + 2 * a (m - 1) ^ 2 * a m ^ 2 + 2 * a (m - 1) ^ 2 * a (m + 1) ^ 2) + | |
| (a m ^ 4 + 2 * a m ^ 2 * a (m + 1) ^ 2 + 2 * a m ^ 2 * a 1 ^ 2) + | |
| (a (m + 1) ^ 4 + 2 * a (m + 1) ^ 2 * a 1 ^ 2 + 2 * a (m + 1) ^ 2 * a 2 ^ 2) := by | |
| repeat rw [add_assoc] | |
| simp | |
| ring_nf | |
| rw [β hβ β] | |
| exact hβ β | |
| theorem imo_2007_p6 | |
| (a : β β NNReal) | |
| (hβ : β x β Finset.range 100, ((a (x + 1)) ^ 2) = 1) | |
| (hβ : β x y, x % 100 = y % 100 β a (x + 1) = a (y + 1)) : | |
| β x β Finset.range (99), ((a (x + 1)) ^ 2 * a (x + 2)) + (a 100) ^ 2 * a 1 < (12:NNReal) / (25:NNReal) := by | |
| have hβ: β x, 2 * a x ^ 2 * a (x + 1) * a (x + 2) β€ | |
| (a x * a (x + 1)) ^ 2 + (a x * a (x + 2)) ^ 2 := by | |
| intro x | |
| have hββ: 2 * (a x * a (x + 1)) * (a x * a (x + 2)) β€ | |
| (a x * a (x + 1)) ^ 2 + (a x * a (x + 2)) ^ 2 := by | |
| exact two_mul_le_add_sq (a x * a (x + 1)) (a x * a (x + 2)) | |
| have hββ: 2 * (a x * a (x + 1)) * (a x * a (x + 2)) = 2 * a x ^ 2 * a (x + 1) * a (x + 2) := by | |
| rw [pow_two] | |
| ring_nf | |
| exact le_of_eq_of_le (id (Eq.symm hββ)) hββ | |
| have hβ: β x β Finset.range 100, a (x + 1) β€ 1 := by | |
| intros x hxβ | |
| by_contra hxβ | |
| push_neg at hxβ | |
| let fsx : Finset β := {x} | |
| have hxβ: 1 < β x β range 100, a (x + 1) ^ 2 := by | |
| have hxβ: 0 β€ β x β (range 100 \ fsx), a (x + 1) ^ 2 := by | |
| exact _root_.zero_le (β x β range 100 \ fsx, a (x + 1) ^ 2) | |
| have hxβ: 1 < β x β (fsx), a (x + 1) ^ 2 := by | |
| rw [Finset.sum_singleton] | |
| refine one_lt_powβ hxβ ?_ | |
| norm_num | |
| have hxβ : β x β (range 100 \ fsx), a (x + 1) ^ 2 + β x β (fsx), a (x + 1) ^ 2 = | |
| β x β range 100, a (x + 1) ^ 2 := by | |
| rw [β Finset.sum_union ?_] | |
| . rw [Finset.sdiff_union_self_eq_union] | |
| have hxβ: range 100 βͺ fsx = range 100 := by | |
| refine Finset.union_eq_left.mpr ?_ | |
| exact singleton_subset_iff.mpr hxβ | |
| rw [hxβ] | |
| . exact sdiff_disjoint | |
| rw [β hxβ ] | |
| exact lt_add_of_nonneg_of_lt hxβ hxβ | |
| simp_all only [mem_range, lt_self_iff_false] | |
| have hβ: (β x β Finset.range 100, (a (x + 2) * (a (x + 1) ^ 2 + 2 * a (x + 2) * a (x + 3)))) ^ 2 β€ | |
| β x β Finset.range 100, (a (x + 1) ^ 4 + 6 * a (x + 1) ^ 2 * a (x + 2) ^ 2 + 2 * a (x + 1) ^ 2 * a (x + 3) ^ 2) := by | |
| have hββ: (β x β Finset.range 100, (a (x + 2) * (a (x + 1) ^ 2 + 2 * a (x + 2) * a (x + 3)))) ^ 2 β€ | |
| (β x β Finset.range 100, (a (x + 2) ^ 2)) * | |
| (β x β Finset.range 100, ((a (x + 1) ^ 2 + 2 * a (x + 2) * a (x + 3))) ^ 2) := by | |
| refine sum_mul_sq_le_sq_mul_sq (range 100) (fun i => a (i + 2)) _ | |
| have hββ: β x β Finset.range 100, (a (x + 2) ^ 2) = 1 := by | |
| rw [Finset.sum_range_succ'] at hβ | |
| simp at hβ | |
| rw [Finset.sum_range_succ] | |
| have hβββ: a 1 = a 101 := by exact hβ 0 100 rfl | |
| rw [β hβββ] | |
| exact hβ | |
| have hββ: β x β Finset.range 100, ((a (x + 1) ^ 2 + 2 * a (x + 2) * a (x + 3))) ^ 2 = | |
| β x β Finset.range 100, ((a (x + 1) ^ 4 + 4 * a (x + 1) ^ 2 * a (x + 2) * a (x + 3) | |
| + 4 * a (x + 2) ^ 2 * a (x + 3) ^ 2)) := by | |
| refine Finset.sum_congr (rfl) ?_ | |
| intros x _ | |
| rw [add_sq] | |
| ring_nf | |
| rw [hββ, one_mul, hββ] at hββ | |
| have hββ: β x β Finset.range 100, ((a (x + 1) ^ 4 + 4 * a (x + 1) ^ 2 * a (x + 2) * a (x + 3) | |
| + 4 * a (x + 2) ^ 2 * a (x + 3) ^ 2)) β€ | |
| β x β Finset.range 100, ((a (x + 1) ^ 4 + 2 * a (x + 1) ^ 2 * (a (x + 2) ^ 2 + a (x + 3) ^ 2) | |
| + 4 * a (x + 2) ^ 2 * a (x + 3) ^ 2)) := by | |
| refine Finset.sum_le_sum ?_ | |
| intros x _ | |
| rw [add_comm (a (x + 1) ^ 4) _, add_comm (a (x + 1) ^ 4) _] | |
| rw [add_assoc, add_assoc] | |
| refine add_le_add ?_ ?_ | |
| . have hxβ: 2 * a (x + 1) ^ 2 * a (x + 1 + 1) * a (x + 1 + 2) β€ | |
| (a (x + 1) * a (x + 1 + 1)) ^ 2 + (a (x + 1) * a (x + 1 + 2)) ^ 2 := by | |
| exact hβ (x + 1) | |
| have hxβ: 2 * a (x + 1) ^ 2 * a (x + 2) * a (x + 3) β€ | |
| a (x + 1) ^ 2 * (a (x + 2) ^ 2 + a (x + 3) ^ 2) := by | |
| rw [mul_add] | |
| refine le_of_le_of_eq hxβ ?_ | |
| ring_nf | |
| have hxβ: (4:NNReal) = 2 * 2 := by norm_num | |
| rw [hxβ] | |
| repeat rw [mul_assoc] | |
| have hxβ: 0 < (2:NNReal) := by norm_num | |
| refine (mul_le_mul_left hxβ).mpr ?_ | |
| ring_nf | |
| ring_nf at hxβ | |
| exact hxβ | |
| . exact Preorder.le_refl (a (x + 1) ^ 4 + 4 * a (x + 2) ^ 2 * a (x + 3) ^ 2) | |
| have hββ: β x β Finset.range 100, ((a (x + 1) ^ 4 + 2 * a (x + 1) ^ 2 * (a (x + 2) ^ 2 + a (x + 3) ^ 2) | |
| + 4 * a (x + 2) ^ 2 * a (x + 3) ^ 2)) = | |
| β x β Finset.range 100, (a (x + 1) ^ 4 + 6 * a (x + 1) ^ 2 * a (x + 2) ^ 2 + 2 | |
| * a (x + 1) ^ 2 * a (x + 3) ^ 2) := by | |
| rw [Finset.sum_add_distrib] | |
| have hβββ: β x β range 100, 4 * a (x + 2) ^ 2 * a (x + 3) ^ 2 = | |
| β x β range 100, 4 * a (x + 1) ^ 2 * a (x + 2) ^ 2 := by | |
| rw [Finset.sum_range_succ _ 99, sum_range_succ' _ 99] | |
| have gβ: a 101 = a 1 := by exact hβ 100 0 rfl | |
| have gβ: a 102 = a 2 := by exact hβ 101 1 rfl | |
| rw [gβ, gβ] | |
| rw [hβββ, β Finset.sum_add_distrib] | |
| refine Finset.sum_congr (rfl) ?_ | |
| intros x _ | |
| rw [mul_add] | |
| ring_nf | |
| rw [hββ] at hββ | |
| exact le_trans hββ hββ | |
| have hβ: β x β range 100, 4 * a (x + 1) ^ 2 * a (x + 2) ^ 2 β€ 1 := by | |
| have hββ: β x β range 100, 4 * a (x + 1) ^ 2 * a (x + 2) ^ 2 = | |
| β x β range 100, 4 * (a (x + 1) ^ 2 * a (x + 2) ^ 2) := by | |
| refine Finset.sum_congr rfl ?_ | |
| intros x _ | |
| ring_nf | |
| rw [hββ, β Finset.mul_sum] | |
| let fsβ := Finset.range (100) | |
| let fsβ : Finset β := fsβ.filter (fun x => Odd x) | |
| let fsβ : Finset β := fsβ.filter (fun x => Even x) | |
| have hββ : Disjoint fsβ fsβ := by | |
| refine Finset.sdiff_eq_self_iff_disjoint.mp (by rfl) | |
| have hββ : fsβ βͺ fsβ = fsβ := by | |
| symm | |
| refine Finset.ext_iff.mpr ?_ | |
| intro a | |
| constructor | |
| . intro haβ | |
| refine mem_union.mpr ?mp.a | |
| have haβ: Odd a β¨ Even a := by exact Or.symm (even_or_odd a) | |
| cases' haβ with haβ haβ | |
| . left | |
| refine mem_filter.mpr ?mp.a.inl.h.a | |
| exact And.symm β¨haβ, haββ© | |
| . right | |
| refine mem_filter.mpr ?mp.a.inl.h.b | |
| exact And.symm β¨haβ, haββ© | |
| . intro haβ | |
| apply mem_union.mp at haβ | |
| cases' haβ with haβ haβ | |
| . exact mem_of_mem_filter a haβ | |
| . exact mem_of_mem_filter a haβ | |
| have hββ: 4 * β i β fsβ, a (i + 1) ^ 2 * a (i + 2) ^ 2 β€ | |
| 4 * ((β i β fsβ, (a (i + 1) ^ 2)) * (β i β fsβ, (a (i + 1) ^ 2))) := by | |
| refine mul_le_mul (by norm_num) ?_ ?_ (by norm_num) | |
| . rw [β hββ, Finset.sum_union hββ] | |
| have gβ: β i β fsβ, a (i + 1) ^ 2 = β i β fsβ, (a i) ^ 2 := by | |
| refine sum_bij ?_ ?h.b2 ?h.b3 ?h.b4 ?h.b5 | |
| . intros b _ | |
| exact (b + 1) | |
| . intros b hbβ | |
| apply mem_filter.mp at hbβ | |
| cases' hbβ with hbβ hbβ | |
| have hbβ: Odd (b + 1) := by exact Even.add_one hbβ | |
| have hbβ: b β€ 98 := by | |
| by_contra hcβ | |
| apply mem_range.mp at hbβ | |
| interval_cases b | |
| have hcβ: Β¬ Even 99 := by decide | |
| exact hcβ hbβ | |
| have hbβ: b + 1 < 100 := by linarith | |
| have hbβ : (b + 1) β fsβ := by exact mem_range.mpr hbβ | |
| refine mem_filter.mpr ?_ | |
| exact And.symm β¨hbβ, hbβ β© | |
| . intros b _ c _ hbβ | |
| linarith | |
| . intros b hbβ | |
| use (b - 1) | |
| refine exists_prop.mpr ?h.a | |
| have hbβ: b β fsβ β§ Odd b := by exact mem_filter.mp hbβ | |
| have hbβ: 1 β€ b := by | |
| by_contra hc | |
| interval_cases b | |
| have hbβ: Β¬ Odd 0 := by decide | |
| exact hbβ hbβ.2 | |
| constructor | |
| . cases' hbβ with hbβ hbβ | |
| have hbβ: Even (b - 1) := by exact Nat.Odd.sub_odd hbβ (by decide) | |
| have hbβ : (b - 1) β fsβ := by | |
| refine mem_range.mpr ?_ | |
| have hbβ: b < 100 := by exact List.mem_range.mp hbβ | |
| omega | |
| refine mem_filter.mpr ?_ | |
| exact And.symm β¨hbβ, hbβ β© | |
| . exact Nat.sub_add_cancel hbβ | |
| . exact fun a_1 _ => rfl | |
| have gβ: β x β fsβ, a (x + 1) ^ 2 * a (x + 2) ^ 2 = | |
| β x β fsβ, a (x) ^ 2 * a (x + 1) ^ 2 := by | |
| refine sum_bij ?_ ?_ ?_ ?_ ?_ | |
| . intros b _ | |
| exact (b + 1) | |
| . intros b hbβ | |
| apply mem_filter.mp at hbβ | |
| cases' hbβ with hbβ hbβ | |
| have hbβ: Odd (b + 1) := by exact Even.add_one hbβ | |
| have hbβ: b β€ 98 := by | |
| by_contra hcβ | |
| apply mem_range.mp at hbβ | |
| interval_cases b | |
| have hcβ: Β¬ Even 99 := by decide | |
| exact hcβ hbβ | |
| have hbβ: b + 1 < 100 := by linarith | |
| have hbβ : (b + 1) β fsβ := by exact mem_range.mpr hbβ | |
| refine mem_filter.mpr ?_ | |
| exact And.symm β¨hbβ, hbβ β© | |
| . intros b _ c _ hbβ | |
| linarith | |
| . intros b hbβ | |
| use (b - 1) | |
| refine exists_prop.mpr ?h.b | |
| have hbβ: b β fsβ β§ Odd b := by exact mem_filter.mp hbβ | |
| have hbβ: 1 β€ b := by | |
| by_contra hc | |
| interval_cases b | |
| have hbβ: Β¬ Odd 0 := by decide | |
| exact hbβ hbβ.2 | |
| constructor | |
| . cases' hbβ with hbβ hbβ | |
| have hbβ: Even (b - 1) := by exact Nat.Odd.sub_odd hbβ (by decide) | |
| have hbβ : (b - 1) β fsβ := by | |
| refine mem_range.mpr ?_ | |
| have hbβ: b < 100 := by exact List.mem_range.mp hbβ | |
| omega | |
| refine mem_filter.mpr ?_ | |
| exact And.symm β¨hbβ, hbβ β© | |
| . exact Nat.sub_add_cancel hbβ | |
| . exact fun a_1 _ => rfl | |
| rw [gβ, gβ, Finset.sum_mul_sum, add_comm, β sum_add_distrib] | |
| refine sum_le_sum ?_ | |
| intros x hxβ | |
| apply mem_filter.mp at hxβ | |
| cases' hxβ with hxβ hxβ | |
| apply mem_range.mp at hxβ | |
| by_cases hxβ: x < 99 | |
| . clear hβ hβ hβ hβ hβ hββ gβ gβ | |
| let fsβ : Finset β := {x, (x + 2)} | |
| have hxβ: fsβ β fsβ := by | |
| intros b hbβ | |
| have hbβ: b = x β¨ b = x + 2 := by | |
| have gβ: fsβ = {x, x + 2} := by rfl | |
| simp_all only [mem_insert, mem_singleton] | |
| cases' hbβ with hbβ hbβ | |
| . rw [hbβ] | |
| refine mem_filter.mpr ?_ | |
| apply mem_range.mpr at hxβ | |
| exact And.symm β¨hxβ, hxββ© | |
| . rw [hbβ] | |
| refine mem_filter.mpr ?_ | |
| constructor | |
| . have hxβ: x < 98 := by | |
| by_contra hc | |
| interval_cases x | |
| have hxβ : Β¬ Odd 98 := by decide | |
| apply hxβ hxβ | |
| refine mem_range.mpr ?_ | |
| linarith | |
| . refine Odd.add_even hxβ ?_ | |
| decide | |
| have hxβ : β j β fsβ, a (x + 1) ^ 2 * a j ^ 2 = a (x + 1) ^ 2 * a x ^ 2 + a (x + 1) ^ 2 * a (x + 2) ^ 2 := by | |
| have hxβ: fsβ = {x, x + 2} := by rfl | |
| refine Finset.sum_eq_add_of_mem (x) (x + 2) ?_ ?_ (by norm_num) ?_ | |
| . rw [hxβ] | |
| exact mem_insert_self x {x + 2} | |
| . rw [hxβ] | |
| simp | |
| . intros c hcβ hcβ | |
| exfalso | |
| rw [hxβ] at hcβ | |
| simp only [mem_insert, mem_singleton] at hcβ | |
| have hcβ: Β¬ (c β x β§ c β x + 2) := by | |
| omega | |
| exact hcβ hcβ | |
| rw [β Finset.sum_sdiff hxβ, hxβ ] | |
| refine le_add_left ?_ | |
| refine le_of_eq ?_ | |
| rw [mul_comm (a x ^ 2) (a (x + 1) ^ 2)] | |
| . interval_cases x | |
| norm_num | |
| have hxβ: a 101 = a 1 := by exact hβ 100 0 rfl | |
| let fsβ: Finset β := {1, 99} | |
| have hxβ : fsβ β fsβ := by | |
| refine Finset.subset_iff.mpr ?_ | |
| intros b hbβ | |
| have hbβ: b = 1 β¨ b = 99 := by exact List.mem_pair.mp hbβ | |
| cases' hbβ with hbβ hbβ | |
| . refine mem_filter.mpr ?_ | |
| rw [hbβ] | |
| constructor | |
| . refine mem_range.mpr (by decide) | |
| . decide | |
| . rw [hbβ] | |
| refine mem_filter.mpr ?_ | |
| constructor | |
| . exact self_mem_range_succ 99 | |
| . decide | |
| have hxβ: β x β fsβ, a 100 ^ 2 * a x ^ 2 = a 100 ^ 2 * a 99 ^ 2 + a 100 ^ 2 * a 1 ^ 2 := by | |
| clear hβ hβ hβ hβ hβ hββ | |
| have hxβ: fsβ = {1, 99} := by rfl | |
| refine Finset.sum_eq_add_of_mem (99:β) (1:β) ?_ ?_ (by norm_num) ?_ | |
| . rw [hxβ] | |
| decide | |
| . rw [hxβ] | |
| decide | |
| . intros c hcβ hcβ | |
| exfalso | |
| have hcβ: c = 99 β¨ c = 1 := by | |
| refine Or.symm ?_ | |
| exact List.mem_pair.mp hcβ | |
| have hcβ: Β¬ (c β 99 β§ c β 1) := by omega | |
| exact hcβ hcβ | |
| rw [β Finset.sum_sdiff hxβ , hxβ, hxβ] | |
| refine le_add_left ?_ | |
| refine le_of_eq ?_ | |
| rw [mul_comm (a 99 ^ 2) (a 100 ^ 2)] | |
| . exact _root_.zero_le (β i β range 100, a (i + 1) ^ 2 * a (i + 2) ^ 2) | |
| have hββ: 4 * ((β i β fsβ, (a (i + 1) ^ 2)) * (β i β fsβ, (a (i + 1) ^ 2))) β€ | |
| (β i β fsβ, (a (i + 1) ^ 2) + β i β fsβ, (a (i + 1) ^ 2)) ^ 2 := by | |
| have gβ: β x y : β, 4 * x * y β€ (x + y) ^ 2 := by | |
| intros x y | |
| rw [add_sq] | |
| have gβ: 2 * x * y β€ x ^ 2 + y ^ 2 := by exact two_mul_le_add_sq x y | |
| linarith | |
| rw [β mul_assoc] | |
| let x := (β i β fsβ, a (i + 1) ^ 2) | |
| let y := (β i β fsβ, a (i + 1) ^ 2) | |
| refine gβ x y | |
| have hββ : (β i β fsβ, (a (i + 1) ^ 2) + β i β fsβ, (a (i + 1) ^ 2)) ^ 2 = 1 := by | |
| rw [β Finset.sum_union hββ, hββ, hβ] | |
| exact one_pow 2 | |
| refine le_trans hββ ?_ | |
| refine le_trans hββ ?_ | |
| rw [hββ ] | |
| let S : NNReal := β x β Finset.range 99, ((a (x + 1)) ^ 2 * a (x + 2)) + (a 100) ^ 2 * a 1 | |
| have hS : S = β x β Finset.range 99, ((a (x + 1)) ^ 2 * a (x + 2)) + (a 100) ^ 2 * a 1 := by rfl | |
| rw [β hS] | |
| have hSβ : S = β x β Finset.range 100, ((a (x + 1)) ^ 2 * a (x + 2)) := by | |
| rw [Finset.sum_range_succ] | |
| norm_num | |
| have gβ: a 101 = a 1 := by exact hβ 100 0 rfl | |
| rw [gβ] | |
| have hβ: (3 * S) ^ 2 β€ 2 := by | |
| have hββ: 3 * S = β x β Finset.range 100, (a (x + 2) * (a (x + 1) ^ 2 + 2 * a (x + 2) * a (x + 3))) := by | |
| have gβ: β x β Finset.range 100, (a (x + 2) * (a (x + 1) ^ 2 + 2 * a (x + 2) * a (x + 3))) = | |
| β x β Finset.range 100, (a (x + 1) ^ 2 * a (x + 2) + 2 * a (x + 2) ^ 2 * a (x + 3)) := by | |
| refine Finset.sum_congr rfl ?_ | |
| intros x _ | |
| ring_nf | |
| have gβ: (3:NNReal) = 1 + 2 := by norm_num | |
| rw [gβ, Finset.sum_add_distrib] | |
| rw [gβ, hSβ, add_mul, one_mul, Finset.mul_sum] | |
| simp | |
| rw [Finset.sum_range_succ' _ 99, sum_range_succ _ 99] | |
| norm_num | |
| have gβ: a 101 = a 1 := by exact hβ 100 0 rfl | |
| have gβ: a 102 = a 2 := by exact hβ 101 1 rfl | |
| rw [gβ, gβ, β mul_assoc 2] | |
| simp | |
| refine Finset.sum_congr rfl ?_ | |
| intros x _ | |
| ring_nf | |
| rw [β hββ] at hβ | |
| refine le_trans hβ ?_ | |
| have hββ: β x β range 100, (a (x + 1) ^ 4 + 6 * a (x + 1) ^ 2 * a (x + 2) ^ 2 + 2 * a (x + 1) ^ 2 * a (x + 3) ^ 2) = | |
| β x β range 100, (a (x + 1) ^ 4 + 2 * a (x + 1) ^ 2 * a (x + 2) ^ 2 + 2 * a (x + 1) ^ 2 * a (x + 3) ^ 2) + | |
| β x β range 100, 4 * a (x + 1) ^ 2 * a (x + 2) ^ 2 := by | |
| rw [β Finset.sum_add_distrib] | |
| refine Finset.sum_congr rfl ?_ | |
| intros x _ | |
| ring_nf | |
| have hββ: β x β range 100, (a (x + 1) ^ 4 + 2 * a (x + 1) ^ 2 * a (x + 2) ^ 2 + 2 * a (x + 1) ^ 2 * a (x + 3) ^ 2) β€ 1 := by | |
| refine le_trans (aux2 a 100 ?_ hβ) ?_ | |
| . omega | |
| . refine (sq_le_one_iffβ ?_).mpr ?_ | |
| . exact _root_.zero_le (β x β range 100, a (x + 1) ^ 2) | |
| . rw [β hβ] | |
| rw [hββ, β one_add_one_eq_two] | |
| refine add_le_add ?_ hβ | |
| norm_num | |
| exact hββ | |
| have hβ : S β€ (NNReal.sqrt 2) / (3:NNReal) := by | |
| have hββ: NNReal.sqrt (((3:NNReal) * S) ^ 2) β€ NNReal.sqrt 2 := by | |
| exact NNReal.sqrt_le_sqrt.mpr hβ | |
| rw [sqrt_sq, mul_comm] at hββ | |
| refine (le_div_iffβ (by norm_num)).mpr hββ | |
| have hβ: (NNReal.sqrt 2) / (3:NNReal) < (12:NNReal) / (25:NNReal) := by | |
| have hββ: 2 < 144 / (625:NNReal) * 9 := by | |
| refine (one_lt_div (by norm_num)).mp ?_ | |
| rw [mul_comm_div, β mul_div_assoc, div_div] | |
| norm_num | |
| refine (one_lt_div (by norm_num)).mpr ?_ | |
| norm_num | |
| have hββ: (NNReal.sqrt 2 / 3:NNReal) ^ 2 < (12 / 25:NNReal) ^ 2 := by | |
| rw [div_pow, div_pow] | |
| norm_num | |
| refine (div_lt_iffβ ?_).mpr hββ | |
| exact ofNat_pos' | |
| have hββ: NNReal.sqrt ((NNReal.sqrt 2 / 3) ^ 2) < NNReal.sqrt ((12 / 25) ^ 2) := by | |
| exact sqrt_lt_sqrt.mpr hββ | |
| rw [sqrt_sq, sqrt_sq] at hββ | |
| exact hββ | |
| exact lt_of_le_of_lt hβ hβ | |