Proof of Nuprl Lemma : mcompact_functionality_wrt

Step * 1 of Lemma mcompact_functionality_wrt_homeomorphic+

1. X : Type
2. Y : Type
3. d : metric(X)
4. d' : metric(Y)
5. f : FUN(Y ⟶ X)
6. g : FUN(X ⟶ Y)
7. [%6] : (∀x:Y. g (f x) ≡ x) ∧ (∀y:X. f (g y) ≡ y)
8. B : ℕ⁺
9. [%5] : ∀x1,x2:Y. (mdist(d;f x1;f x2) ≤ (r(B) * mdist(d';x1;x2)))
10. mcomplete(X with d)
11. ∀k:ℕ. ∃n:ℕ⁺. ∃xs:ℕn ⟶ X. ∀x:X. ∃i:ℕn. (mdist(d;x;xs i) ≤ (r1/r(k + 1)))
12. UC(g:X ⟶ Y)
⊢ mcomplete(Y with d')
BY
{ (ParallelOp -3 THEN All Reduce THEN Auto) }

1
1. X : Type
2. Y : Type
3. d : metric(X)
4. d' : metric(Y)
5. f : FUN(Y ⟶ X)
6. g : FUN(X ⟶ Y)
7. [%6] : (∀x:Y. g (f x) ≡ x) ∧ (∀y:X. f (g y) ≡ y)
8. B : ℕ⁺
9. [%5] : ∀x1,x2:Y. (mdist(d;f x1;f x2) ≤ (r(B) * mdist(d';x1;x2)))
10. ∀x:ℕ ⟶ X. (mcauchy(d;n.x n) ⇒ x n↓ as n→∞)
11. ∀k:ℕ. ∃n:ℕ⁺. ∃xs:ℕn ⟶ X. ∀x:X. ∃i:ℕn. (mdist(d;x;xs i) ≤ (r1/r(k + 1)))
12. UC(g:X ⟶ Y)
13. x : ℕ ⟶ Y
14. mcauchy(d';n.x n)
⊢ x n↓ as n→∞

Latex:

Latex:
1. X : Type 2. Y : Type 3. d : metric(X) 4. d' : metric(Y) 5. f : FUN(Y {}\mrightarrow{} X) 6. g : FUN(X {}\mrightarrow{} Y) 7. [\%6] : (\mforall{}x:Y. g (f x) \mequiv{} x) \mwedge{} (\mforall{}y:X. f (g y) \mequiv{} y) 8. B : \mBbbN{}\msupplus{} 9. [\%5] : \mforall{}x1,x2:Y. (mdist(d;f x1;f x2) \mleq{} (r(B) * mdist(d';x1;x2))) 10. mcomplete(X with d) 11. \mforall{}k:\mBbbN{}. \mexists{}n:\mBbbN{}\msupplus{}. \mexists{}xs:\mBbbN{}n {}\mrightarrow{} X. \mforall{}x:X. \mexists{}i:\mBbbN{}n. (mdist(d;x;xs i) \mleq{} (r1/r(k + 1))) 12. UC(g:X {}\mrightarrow{} Y) \mvdash{} mcomplete(Y with d') By Latex: (ParallelOp -3 THEN All Reduce THEN Auto) Home Index