Proof of Nuprl Lemma : m-regularize-mcauchy

Step * 1 2 2 1 of Lemma m-regularize-mcauchy

1. X : Type
2. d : metric(X)
3. s : ℕ ⟶ X
4. k : ℕ⁺
5. n : ℕ
6. m : ℕn
7. (6 * k) ≤ n
8. (6 * k) ≤ m
9. v : ℕ(n + 1) + 1
10. v1 : ℕ(m + 1) + 1
11. (∀n:ℕv - 1. m-not-reg(d;s;n) = ff) ∧ m-not-reg(d;s;v - 1) = tt supposing 0 < v
12. ¬0 < v1
13. v1 = 0 ∈ ℤ
14. ∀n:ℕm + 1. m-not-reg(d;s;n) = ff
15. v ≤ 0
16. v = 0 ∈ ℤ
17. ∀n:ℕn + 1. m-not-reg(d;s;n) = ff
⊢ mdist(d;s n;s m) ≤ (r1/r(k))
BY
{ (InstLemma `not-m-not-reg-3regular` [⌜X⌝;⌜d⌝;⌜s⌝;⌜n + 1⌝;⌜n⌝;⌜m⌝]⋅ THENA Auto) }

1
1. X : Type
2. d : metric(X)
3. s : ℕ ⟶ X
4. k : ℕ⁺
5. n : ℕ
6. m : ℕn
7. (6 * k) ≤ n
8. (6 * k) ≤ m
9. v : ℕ(n + 1) + 1
10. v1 : ℕ(m + 1) + 1
11. (∀n:ℕv - 1. m-not-reg(d;s;n) = ff) ∧ m-not-reg(d;s;v - 1) = tt supposing 0 < v
12. ¬0 < v1
13. v1 = 0 ∈ ℤ
14. ∀n:ℕm + 1. m-not-reg(d;s;n) = ff
15. v ≤ 0
16. v = 0 ∈ ℤ
17. ∀n:ℕn + 1. m-not-reg(d;s;n) = ff
18. mdist(d;s n;s m) ≤ ((r(3)/r(n + 1)) + (r(3)/r(m + 1)))
⊢ mdist(d;s n;s m) ≤ (r1/r(k))

Latex:

Latex:
1. X : Type 2. d : metric(X) 3. s : \mBbbN{} {}\mrightarrow{} X 4. k : \mBbbN{}\msupplus{} 5. n : \mBbbN{} 6. m : \mBbbN{}n 7. (6 * k) \mleq{} n 8. (6 * k) \mleq{} m 9. v : \mBbbN{}(n + 1) + 1 10. v1 : \mBbbN{}(m + 1) + 1 11. (\mforall{}n:\mBbbN{}v - 1. m-not-reg(d;s;n) = ff) \mwedge{} m-not-reg(d;s;v - 1) = tt supposing 0 < v 12. \mneg{}0 < v1 13. v1 = 0 14. \mforall{}n:\mBbbN{}m + 1. m-not-reg(d;s;n) = ff 15. v \mleq{} 0 16. v = 0 17. \mforall{}n:\mBbbN{}n + 1. m-not-reg(d;s;n) = ff \mvdash{} mdist(d;s n;s m) \mleq{} (r1/r(k)) By Latex: (InstLemma `not-m-not-reg-3regular` [\mkleeneopen{}X\mkleeneclose{};\mkleeneopen{}d\mkleeneclose{};\mkleeneopen{}s\mkleeneclose{};\mkleeneopen{}n + 1\mkleeneclose{};\mkleeneopen{}n\mkleeneclose{};\mkleeneopen{}m\mkleeneclose{}]\mcdot{} THENA Auto) Home Index