Proof of Nuprl Lemma : compact-dist-positive

Step * 1 of Lemma compact-dist-positive

1. [X] : Type
2. d : metric(X)
3. A : Type
4. A ⊆r X
5. c : mcompact(A;d)
6. x : X
7. dist-fun(d;x) ∈ FUN(A ⟶ ℝ)
8. (∀x@0:A. (dist(x;A) ≤ (dist-fun(d;x) x@0))) ∧ (∀e:ℝ. ((r0 < e) ⇒ (∃x@0:A. ((dist-fun(d;x) x@0) < (dist(x;A) + e)))))
9. r0 < dist(x;A)
⊢ ∃n:ℕ⁺. ∀a:A. ((r1/r(n)) ≤ mdist(d;x;a))
BY
{ (ExRepD
   THEN (InstLemma `small-reciprocal-real` [⌜dist(x;A)⌝]⋅ THENA Auto)
   THEN D -1
   THEN (D 0 With ⌜k⌝  THENW (Try (D 0) THEN Try ((Assert a ∈ X BY Auto)) THEN Auto))
   THEN ParallelOp -5
   THEN RepUR ``dist-fun`` -1
   THEN (Assert a ∈ X BY
               Auto)
   THEN Auto) }

Latex:

Latex:
1. [X] : Type 2. d : metric(X) 3. A : Type 4. A \msubseteq{}r X 5. c : mcompact(A;d) 6. x : X 7. dist-fun(d;x) \mmember{} FUN(A {}\mrightarrow{} \mBbbR{}) 8. (\mforall{}x@0:A. (dist(x;A) \mleq{} (dist-fun(d;x) x@0))) \mwedge{} (\mforall{}e:\mBbbR{}. ((r0 < e) {}\mRightarrow{} (\mexists{}x@0:A. ((dist-fun(d;x) x@0) < (dist(x;A) + e))))) 9. r0 < dist(x;A) \mvdash{} \mexists{}n:\mBbbN{}\msupplus{}. \mforall{}a:A. ((r1/r(n)) \mleq{} mdist(d;x;a)) By Latex: (ExRepD THEN (InstLemma `small-reciprocal-real` [\mkleeneopen{}dist(x;A)\mkleeneclose{}]\mcdot{} THENA Auto) THEN D -1 THEN (D 0 With \mkleeneopen{}k\mkleeneclose{} THENW (Try (D 0) THEN Try ((Assert a \mmember{} X BY Auto)) THEN Auto)) THEN ParallelOp -5 THEN RepUR ``dist-fun`` -1 THEN (Assert a \mmember{} X BY Auto) THEN Auto) Home Index