Proof of Nuprl Lemma : mcomplete-stable-union

Step * 1 1 1 of Lemma mcomplete-stable-union

.....assertion.....
1. X : Type
2. d : metric(X)
3. T : Type
4. P : T ⟶ X ⟶ ℙ
5. ∀i:T. ∀x,y:X.  (P[i;x] ⇒ y ≡ x ⇒ P[i;y])
6. finite(T)
7. ∀x:ℕ ⟶ X. (mcauchy(d;n.x n) ⇒ x n↓ as n→∞)
8. cmp : ∀i:T. mcompact({x:X| P[i;x]} ;d)
9. x : ℕ ⟶ stable-union(X;T;i,x.P[i;x])
10. mcauchy(d;n.x n)
11. y : X
12. lim n→∞.x n = y
13. ∀i:T. ∃n:ℕ⁺. ∀a:{x:X| P[i;x]} . ((r1/r(n)) ≤ mdist(d;y;a))
⊢ ∃n:ℕ⁺. ∀i:T. ∀a:{x:X| P[i;x]} .  ((r1/r(n)) ≤ mdist(d;y;a))
BY
{ (D 6 THEN (Assert ℕn ~ T BY EAuto 1) THEN D -1) }

1
1. X : Type
2. d : metric(X)
3. T : Type
4. P : T ⟶ X ⟶ ℙ
5. ∀i:T. ∀x,y:X.  (P[i;x] ⇒ y ≡ x ⇒ P[i;y])
6. n : ℕ
7. T ~ ℕn
8. ∀x:ℕ ⟶ X. (mcauchy(d;n.x n) ⇒ x n↓ as n→∞)
9. cmp : ∀i:T. mcompact({x:X| P[i;x]} ;d)
10. x : ℕ ⟶ stable-union(X;T;i,x.P[i;x])
11. mcauchy(d;n.x n)
12. y : X
13. lim n→∞.x n = y
14. ∀i:T. ∃n:ℕ⁺. ∀a:{x:X| P[i;x]} . ((r1/r(n)) ≤ mdist(d;y;a))
15. f : ℕn ⟶ T
16. Bij(ℕn;T;f)
⊢ ∃n:ℕ⁺. ∀i:T. ∀a:{x:X| P[i;x]} .  ((r1/r(n)) ≤ mdist(d;y;a))

Latex:

Latex:
.....assertion..... 1. X : Type 2. d : metric(X) 3. T : Type 4. P : T {}\mrightarrow{} X {}\mrightarrow{} \mBbbP{} 5. \mforall{}i:T. \mforall{}x,y:X. (P[i;x] {}\mRightarrow{} y \mequiv{} x {}\mRightarrow{} P[i;y]) 6. finite(T) 7. \mforall{}x:\mBbbN{} {}\mrightarrow{} X. (mcauchy(d;n.x n) {}\mRightarrow{} x n\mdownarrow{} as n\mrightarrow{}\minfty{}) 8. cmp : \mforall{}i:T. mcompact(\{x:X| P[i;x]\} ;d) 9. x : \mBbbN{} {}\mrightarrow{} stable-union(X;T;i,x.P[i;x]) 10. mcauchy(d;n.x n) 11. y : X 12. lim n\mrightarrow{}\minfty{}.x n = y 13. \mforall{}i:T. \mexists{}n:\mBbbN{}\msupplus{}. \mforall{}a:\{x:X| P[i;x]\} . ((r1/r(n)) \mleq{} mdist(d;y;a)) \mvdash{} \mexists{}n:\mBbbN{}\msupplus{}. \mforall{}i:T. \mforall{}a:\{x:X| P[i;x]\} . ((r1/r(n)) \mleq{} mdist(d;y;a)) By Latex: (D 6 THEN (Assert \mBbbN{}n \msim{} T BY EAuto 1) THEN D -1) Home Index