Step
*
2
1
1
1
1
of Lemma
m-closed-iff-complete
1. [X] : Type
2. d : metric(X)
3. mcomplete(X with d)
4. [A] : Type
5. metric-subspace(X;d;A)
6. d ∈ metric(A)
7. x : X
8. ∀k:ℕ+. ∃a:A. (mdist(d;x;a) ≤ (r1/r(k)))
9. ∀a:A. (mdist(d;x;a) ∈ ℝ)
10. c : k:ℕ+ ⟶ A
11. ∀k:ℕ+. (mdist(d;x;c k) ≤ (r1/r(k)))
12. mcauchy(d;n.(λn.(c (n + 1))) n) ⇒ (λn.(c (n + 1))) n↓ as n→∞
⊢ x ∈ A
BY
{ Assert ⌜mcauchy(d;n.(λn.(c (n + 1))) n)⌝⋅ }
1
.....assertion.....
1. [X] : Type
2. d : metric(X)
3. mcomplete(X with d)
4. [A] : Type
5. metric-subspace(X;d;A)
6. d ∈ metric(A)
7. x : X
8. ∀k:ℕ+. ∃a:A. (mdist(d;x;a) ≤ (r1/r(k)))
9. ∀a:A. (mdist(d;x;a) ∈ ℝ)
10. c : k:ℕ+ ⟶ A
11. ∀k:ℕ+. (mdist(d;x;c k) ≤ (r1/r(k)))
12. mcauchy(d;n.(λn.(c (n + 1))) n) ⇒ (λn.(c (n + 1))) n↓ as n→∞
⊢ mcauchy(d;n.(λn.(c (n + 1))) n)
2
1. [X] : Type
2. d : metric(X)
3. mcomplete(X with d)
4. [A] : Type
5. metric-subspace(X;d;A)
6. d ∈ metric(A)
7. x : X
8. ∀k:ℕ+. ∃a:A. (mdist(d;x;a) ≤ (r1/r(k)))
9. ∀a:A. (mdist(d;x;a) ∈ ℝ)
10. c : k:ℕ+ ⟶ A
11. ∀k:ℕ+. (mdist(d;x;c k) ≤ (r1/r(k)))
12. mcauchy(d;n.(λn.(c (n + 1))) n) ⇒ (λn.(c (n + 1))) n↓ as n→∞
13. mcauchy(d;n.(λn.(c (n + 1))) n)
⊢ x ∈ A
Latex:
Latex:
1. [X] : Type
2. d : metric(X)
3. mcomplete(X with d)
4. [A] : Type
5. metric-subspace(X;d;A)
6. d \mmember{} metric(A)
7. x : X
8. \mforall{}k:\mBbbN{}\msupplus{}. \mexists{}a:A. (mdist(d;x;a) \mleq{} (r1/r(k)))
9. \mforall{}a:A. (mdist(d;x;a) \mmember{} \mBbbR{})
10. c : k:\mBbbN{}\msupplus{} {}\mrightarrow{} A
11. \mforall{}k:\mBbbN{}\msupplus{}. (mdist(d;x;c k) \mleq{} (r1/r(k)))
12. mcauchy(d;n.(\mlambda{}n.(c (n + 1))) n) {}\mRightarrow{} (\mlambda{}n.(c (n + 1))) n\mdownarrow{} as n\mrightarrow{}\minfty{}
\mvdash{} x \mmember{} A
By
Latex:
Assert \mkleeneopen{}mcauchy(d;n.(\mlambda{}n.(c (n + 1))) n)\mkleeneclose{}\mcdot{}
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