Proof of Nuprl Lemma : prod-metric-space-complete

Step * 1 1 1 1 1 of Lemma prod-metric-space-complete

1. k : ℕ
2. X : ℕk ⟶ MetricSpace
3. ∀i:ℕk. mcomplete(X i)
4. prod-metric(k;λi.(snd((X i)))) ∈ metric(i:ℕk ⟶ (fst((X i))))
5. x : ℕ ⟶ i:ℕk ⟶ (fst((X i)))
6. mcauchy(prod-metric(k;λi.(snd((X i))));n.x n)
7. ∀i:ℕk. mcauchy(snd((X i));n.x n i)
8. ∀i:ℕk. ∃y:fst((X i)). lim n→∞.x n i = y
9. f : i:ℕk ⟶ (fst((X i)))
10. ∀i:ℕk. lim n→∞.x n i = f i
11. m : ℕ⁺
12. k = 0 ∈ ℤ
⊢ ∃N:ℕ [(∀n:ℕ. ((N ≤ n) ⇒ (mdist(prod-metric(0;λi.(snd((X i))));x n;f) ≤ (r1/r(m)))))]
BY
{ (RepUR ``mdist prod-metric`` 0 THEN D 0 With ⌜0⌝ THEN Auto) }

1
1. k : ℕ
2. X : ℕk ⟶ MetricSpace
3. ∀i:ℕk. mcomplete(X i)
4. prod-metric(k;λi.(snd((X i)))) ∈ metric(i:ℕk ⟶ (fst((X i))))
5. x : ℕ ⟶ i:ℕk ⟶ (fst((X i)))
6. mcauchy(prod-metric(k;λi.(snd((X i))));n.x n)
7. ∀i:ℕk. mcauchy(snd((X i));n.x n i)
8. ∀i:ℕk. ∃y:fst((X i)). lim n→∞.x n i = y
9. f : i:ℕk ⟶ (fst((X i)))
10. ∀i:ℕk. lim n→∞.x n i = f i
11. m : ℕ⁺
12. k = 0 ∈ ℤ
13. n : ℕ
14. 0 ≤ n
⊢ Σ{(snd((X i))) (x n i) (f i) | 0≤i≤-1} ≤ (r1/r(m))

Latex:

Latex:
1. k : \mBbbN{} 2. X : \mBbbN{}k {}\mrightarrow{} MetricSpace 3. \mforall{}i:\mBbbN{}k. mcomplete(X i) 4. prod-metric(k;\mlambda{}i.(snd((X i)))) \mmember{} metric(i:\mBbbN{}k {}\mrightarrow{} (fst((X i)))) 5. x : \mBbbN{} {}\mrightarrow{} i:\mBbbN{}k {}\mrightarrow{} (fst((X i))) 6. mcauchy(prod-metric(k;\mlambda{}i.(snd((X i))));n.x n) 7. \mforall{}i:\mBbbN{}k. mcauchy(snd((X i));n.x n i) 8. \mforall{}i:\mBbbN{}k. \mexists{}y:fst((X i)). lim n\mrightarrow{}\minfty{}.x n i = y 9. f : i:\mBbbN{}k {}\mrightarrow{} (fst((X i))) 10. \mforall{}i:\mBbbN{}k. lim n\mrightarrow{}\minfty{}.x n i = f i 11. m : \mBbbN{}\msupplus{} 12. k = 0 \mvdash{} \mexists{}N:\mBbbN{} [(\mforall{}n:\mBbbN{}. ((N \mleq{} n) {}\mRightarrow{} (mdist(prod-metric(0;\mlambda{}i.(snd((X i))));x n;f) \mleq{} (r1/r(m)))))] By Latex: (RepUR ``mdist prod-metric`` 0 THEN D 0 With \mkleeneopen{}0\mkleeneclose{} THEN Auto) Home Index