Proof of Nuprl Lemma : omega_step

Step * 1 2 2 2 of Lemma omega_step_measure

1. n : ℕ
2. eqs : {L:ℤ List| ||L|| = (n + 1) ∈ ℤ}  List
3. ¬(eqs = [] ∈ ({L:ℤ List| ||L|| = (n + 1) ∈ ℤ}  List))
4. ineqs : {L:ℤ List| ||L|| = (n + 1) ∈ ℤ}  List
5. 0 < dim(inl <eqs, ineqs>)
6. ¬(n = 0 ∈ ℤ)
7. first-success(λL.find-exact-eq-constraint(L);eqs) ∈ i:ℕ||eqs||
   × x:{x:ℤ List| x = eqs[i] ∈ (ℤ List)}
   × {i@0:ℕ⁺||eqs[i]||| |eqs[i][i@0]| = 1 ∈ ℤ} ?
8. y : Unit
9. first-success(λL.find-exact-eq-constraint(L);eqs)
= (inr y )

∈ (i:ℕ||eqs|| × x:{x:ℤ List| x = eqs[i] ∈ (ℤ List)}  × {i@0:ℕ⁺||eqs[i]||| |eqs[i][i@0]| = 1 ∈ ℤ} ?)

10. LL : {L:ℤ List| ||L|| = (n + 1) ∈ ℤ} List

11. ((eager-map(λeq.eager-map(λx.(-x);eq);eqs) @ eqs) @ ineqs) = LL ∈ ({L:ℤ List| ||L|| = (n + 1) ∈ ℤ}  List)

⊢ (¬dim(inl <[], LL>) < dim(inl <eqs, ineqs>)) ⇒

 (¬((dim(inl <[], LL>) = dim(inl <eqs, ineqs>) ∈ ℤ) ∧ num-eq-constraint\000Cs(inl <[], LL>) < num-eq-constraints(inl <eqs, ineqs>)))

⇒ False
BY
{ TACTIC:Subst' dim(inl <[], LL>) ~ dim(inl <eqs, ineqs>) 0 }

1
.....equality.....
1. n : ℕ
2. eqs : {L:ℤ List| ||L|| = (n + 1) ∈ ℤ}  List
3. ¬(eqs = [] ∈ ({L:ℤ List| ||L|| = (n + 1) ∈ ℤ}  List))
4. ineqs : {L:ℤ List| ||L|| = (n + 1) ∈ ℤ}  List
5. 0 < dim(inl <eqs, ineqs>)
6. ¬(n = 0 ∈ ℤ)
7. first-success(λL.find-exact-eq-constraint(L);eqs) ∈ i:ℕ||eqs||
   × x:{x:ℤ List| x = eqs[i] ∈ (ℤ List)}
   × {i@0:ℕ⁺||eqs[i]||| |eqs[i][i@0]| = 1 ∈ ℤ} ?
8. y : Unit
9. first-success(λL.find-exact-eq-constraint(L);eqs)
= (inr y )

∈ (i:ℕ||eqs|| × x:{x:ℤ List| x = eqs[i] ∈ (ℤ List)}  × {i@0:ℕ⁺||eqs[i]||| |eqs[i][i@0]| = 1 ∈ ℤ} ?)

10. LL : {L:ℤ List| ||L|| = (n + 1) ∈ ℤ} List

11. ((eager-map(λeq.eager-map(λx.(-x);eq);eqs) @ eqs) @ ineqs) = LL ∈ ({L:ℤ List| ||L|| = (n + 1) ∈ ℤ}  List)

⊢ dim(inl <[], LL>) ~ dim(inl <eqs, ineqs>)

2
1. n : ℕ
2. eqs : {L:ℤ List| ||L|| = (n + 1) ∈ ℤ}  List
3. ¬(eqs = [] ∈ ({L:ℤ List| ||L|| = (n + 1) ∈ ℤ}  List))
4. ineqs : {L:ℤ List| ||L|| = (n + 1) ∈ ℤ}  List
5. 0 < dim(inl <eqs, ineqs>)
6. ¬(n = 0 ∈ ℤ)
7. first-success(λL.find-exact-eq-constraint(L);eqs) ∈ i:ℕ||eqs||
   × x:{x:ℤ List| x = eqs[i] ∈ (ℤ List)}
   × {i@0:ℕ⁺||eqs[i]||| |eqs[i][i@0]| = 1 ∈ ℤ} ?
8. y : Unit
9. first-success(λL.find-exact-eq-constraint(L);eqs)
= (inr y )

∈ (i:ℕ||eqs|| × x:{x:ℤ List| x = eqs[i] ∈ (ℤ List)}  × {i@0:ℕ⁺||eqs[i]||| |eqs[i][i@0]| = 1 ∈ ℤ} ?)

10. LL : {L:ℤ List| ||L|| = (n + 1) ∈ ℤ} List

11. ((eager-map(λeq.eager-map(λx.(-x);eq);eqs) @ eqs) @ ineqs) = LL ∈ ({L:ℤ List| ||L|| = (n + 1) ∈ ℤ}  List)

⊢ (¬dim(inl <eqs, ineqs>) < dim(inl <eqs, ineqs>)) ⇒

 (¬((dim(inl <eqs, ineqs>) = dim(inl <eqs, ineqs>) ∈ ℤ) ∧ num-eq-co\000Cnstraints(inl <[], LL>) < num-eq-constraints(inl <eqs, ineqs>)))

⇒ False

Latex:

Latex:
1. n : \mBbbN{} 2. eqs : \{L:\mBbbZ{} List| ||L|| = (n + 1)\} List 3. \mneg{}(eqs = []) 4. ineqs : \{L:\mBbbZ{} List| ||L|| = (n + 1)\} List 5. 0 < dim(inl <eqs, ineqs>) 6. \mneg{}(n = 0) 7. first-success(\mlambda{}L.find-exact-eq-constraint(L);eqs) \mmember{} i:\mBbbN{}||eqs|| \mtimes{} x:\{x:\mBbbZ{} List| x = eqs[i]\} \mtimes{} \{i@0:\mBbbN{}\msupplus{}||eqs[i]||| |eqs[i][i@0]| = 1\} ? 8. y : Unit 9. first-success(\mlambda{}L.find-exact-eq-constraint(L);eqs) = (inr y ) 10. LL : \{L:\mBbbZ{} List| ||L|| = (n + 1)\} List 11. ((eager-map(\mlambda{}eq.eager-map(\mlambda{}x.(-x);eq);eqs) @ eqs) @ ineqs) = LL \mvdash{} (\mneg{}dim(inl <[], LL>) < dim(inl <eqs, ineqs>)) {}\mRightarrow{} (\mneg{}((dim(inl <[], LL>) = dim(inl <eqs, ineqs>)) \mwedge{} n\000Cum-eq-constraints(inl <[], LL>) < num-eq-constraints(inl <eqs, ineqs>))) {}\mRightarrow{} False By Latex: TACTIC:Subst' dim(inl <[], LL>) \msim{} dim(inl <eqs, ineqs>) 0 Home Index