Proof of Nuprl Lemma : insert-int-lex

Step * 3 1 of Lemma insert-int-lex

1. u : ℤ
2. v : ℤ List
3. ∀bs:ℤ List. ∀x:ℤ. ((↑v ≤_lex bs) ⇒ (↑insert-int(x;v) ≤_lex insert-int(x;bs)))
4. u1 : ℤ
5. v1 : ℤ List
6. ∀x:ℤ. ((↑[u / v] ≤_lex v1) ⇒ (↑insert-int(x;[u / v]) ≤_lex insert-int(x;v1)))
7. x : ℤ
8. u < u1
9. ||v|| = ||v1|| ∈ ℤ
10. u < x
11. u1 < x
⊢ ||insert-int(x;v)|| < ||insert-int(x;v1)||
∨ (u < u1 ∧ (||insert-int(x;v)|| = ||insert-int(x;v1)|| ∈ ℤ))
∨ ((u = u1 ∈ ℤ) ∧ (↑insert-int(x;v) ≤_lex insert-int(x;v1)))
BY
{ (Sel 2 (D 0) THEN Auto) }

1
1. u : ℤ
2. v : ℤ List
3. ∀bs:ℤ List. ∀x:ℤ. ((↑v ≤_lex bs) ⇒ (↑insert-int(x;v) ≤_lex insert-int(x;bs)))
4. u1 : ℤ
5. v1 : ℤ List
6. ∀x:ℤ. ((↑[u / v] ≤_lex v1) ⇒ (↑insert-int(x;[u / v]) ≤_lex insert-int(x;v1)))
7. x : ℤ
8. u < u1
9. ||v|| = ||v1|| ∈ ℤ
10. u < x
11. u1 < x
12. u < u1
⊢ ||insert-int(x;v)|| = ||insert-int(x;v1)|| ∈ ℤ

Latex:

Latex:
1. u : \mBbbZ{} 2. v : \mBbbZ{} List 3. \mforall{}bs:\mBbbZ{} List. \mforall{}x:\mBbbZ{}. ((\muparrow{}v \mleq{}\_lex bs) {}\mRightarrow{} (\muparrow{}insert-int(x;v) \mleq{}\_lex insert-int(x;bs))) 4. u1 : \mBbbZ{} 5. v1 : \mBbbZ{} List 6. \mforall{}x:\mBbbZ{}. ((\muparrow{}[u / v] \mleq{}\_lex v1) {}\mRightarrow{} (\muparrow{}insert-int(x;[u / v]) \mleq{}\_lex insert-int(x;v1))) 7. x : \mBbbZ{} 8. u < u1 9. ||v|| = ||v1|| 10. u < x 11. u1 < x \mvdash{} ||insert-int(x;v)|| < ||insert-int(x;v1)|| \mvee{} (u < u1 \mwedge{} (||insert-int(x;v)|| = ||insert-int(x;v1)||)) \mvee{} ((u = u1) \mwedge{} (\muparrow{}insert-int(x;v) \mleq{}\_lex insert-int(x;v1))) By Latex: (Sel 2 (D 0) THEN Auto) Home Index