Proof of Nuprl Lemma : llex-linear

Step * 2 2 1 of Lemma llex-linear

1. [A] : Type
2. [<] : A ⟶ A ⟶ ℙ
3. ∀a,b:A. (<[a;b] ∨ (a = b ∈ A) ∨ <[b;a])
4. u : A
5. v : A List
6. ∀L2:A List. ((v llex(A;a,b.<[a;b]) L2) ∨ (v = L2 ∈ (A List)) ∨ (L2 llex(A;a,b.<[a;b]) v))
7. u1 : A
8. v1 : A List

9. ([u / v] llex(A;a,b.<[a;b]) v1) ∨ ([u / v] = v1 ∈ (A List)) ∨ (v1 llex(A;a,b.<[a;b]) [u / v])

10. <[u;u1]

⊢ ([u / v] llex(A;a,b.<[a;b]) [u1 / v1]) ∨ ([u / v] = [u1 / v1] ∈ (A List)) ∨ ([u1 / v1] llex(A;a,b.<[a;b]) [u / v])

BY
{ (((Sel 1 (D 0) THEN Auto) THEN RepUR ``llex`` 0) THEN OrRight THEN Auto) }

1
1. [A] : Type
2. [<] : A ⟶ A ⟶ ℙ
3. ∀a,b:A. (<[a;b] ∨ (a = b ∈ A) ∨ <[b;a])
4. u : A
5. v : A List
6. ∀L2:A List. ((v llex(A;a,b.<[a;b]) L2) ∨ (v = L2 ∈ (A List)) ∨ (L2 llex(A;a,b.<[a;b]) v))
7. u1 : A
8. v1 : A List

9. ([u / v] llex(A;a,b.<[a;b]) v1) ∨ ([u / v] = v1 ∈ (A List)) ∨ (v1 llex(A;a,b.<[a;b]) [u / v])

10. <[u;u1]

⊢ ∃i:ℕ. (i < ||v|| + 1 ∧ i < ||v1|| + 1 ∧ (∀j:ℕi. ([u / v][j] = [u1 / v1][j] ∈ A)) ∧ <[[u / v][i];[u1 / v1][i]])

Latex:

Latex:
1. [A] : Type 2. [<] : A {}\mrightarrow{} A {}\mrightarrow{} \mBbbP{} 3. \mforall{}a,b:A. (<[a;b] \mvee{} (a = b) \mvee{} <[b;a]) 4. u : A 5. v : A List 6. \mforall{}L2:A List. ((v llex(A;a,b.<[a;b]) L2) \mvee{} (v = L2) \mvee{} (L2 llex(A;a,b.<[a;b]) v)) 7. u1 : A 8. v1 : A List 9. ([u / v] llex(A;a,b.<[a;b]) v1) \mvee{} ([u / v] = v1) \mvee{} (v1 llex(A;a,b.<[a;b]) [u / v]) 10. <[u;u1] \mvdash{} ([u / v] llex(A;a,b.<[a;b]) [u1 / v1]) \mvee{} ([u / v] = [u1 / v1]) \mvee{} ([u1 / v1] llex(A;a,b.<[a;b]) [u / v]) By Latex: (((Sel 1 (D 0) THEN Auto) THEN RepUR ``llex`` 0) THEN OrRight THEN Auto) Home Index