Proof of Nuprl Lemma : interval-fun-maps-compact

Step * 1 of Lemma interval-fun-maps-compact

1. J : Interval
2. n : ℕ⁺
3. a : ℝ
4. b : ℝ
5. a ≤ b
6. g : [a, b] ⟶ℝ
7. interval-fun([a, b];J;x.g[x])
8. real-fun(g;a;b)
⊢ ∃m:{m:ℕ⁺| icompact(i-approx(J;m))} . ∀x:{x:ℝ| x ∈ [a, b]} . (g[x] ∈ i-approx(J;m))
BY
{ ((InstLemma `real-fun-uniformly-greater` [⌜a⌝;⌜b⌝;⌜g⌝]⋅ THENA Auto)
   THEN (InstLemma `real-fun-uniformly-less` [⌜a⌝;⌜b⌝;⌜g⌝]⋅ THENA Auto)
   THEN (InstLemma `real-fun-bounded` [⌜a⌝;⌜b⌝;⌜g⌝]⋅ THENA Auto)
   THEN ExRepD) }

1
1. J : Interval
2. n : ℕ⁺
3. a : ℝ
4. b : ℝ
5. a ≤ b
6. g : [a, b] ⟶ℝ
7. interval-fun([a, b];J;x.g[x])
8. real-fun(g;a;b)
9. ∀c:ℝ. ((∀x:{x:ℝ| x ∈ [a, b]} . (c < (g x))) ⇒ (∃c':{c':ℝ| c < c'} . ∀x:{x:ℝ| x ∈ [a, b]} . (c' ≤ (g x))))
10. ∀c:ℝ. ((∀x:{x:ℝ| x ∈ [a, b]} . ((g x) < c)) ⇒ (∃c':{c':ℝ| c' < c} . ∀x:{x:ℝ| x ∈ [a, b]} . ((g x) ≤ c')))
11. bnd : ℝ
12. r0 ≤ bnd
13. ∀x:ℝ. ((x ∈ [a, b]) ⇒ (|g x| ≤ bnd))
⊢ ∃m:{m:ℕ⁺| icompact(i-approx(J;m))} . ∀x:{x:ℝ| x ∈ [a, b]} . (g[x] ∈ i-approx(J;m))

Latex:

Latex:
1. J : Interval 2. n : \mBbbN{}\msupplus{} 3. a : \mBbbR{} 4. b : \mBbbR{} 5. a \mleq{} b 6. g : [a, b] {}\mrightarrow{}\mBbbR{} 7. interval-fun([a, b];J;x.g[x]) 8. real-fun(g;a;b) \mvdash{} \mexists{}m:\{m:\mBbbN{}\msupplus{}| icompact(i-approx(J;m))\} . \mforall{}x:\{x:\mBbbR{}| x \mmember{} [a, b]\} . (g[x] \mmember{} i-approx(J;m)) By Latex: ((InstLemma `real-fun-uniformly-greater` [\mkleeneopen{}a\mkleeneclose{};\mkleeneopen{}b\mkleeneclose{};\mkleeneopen{}g\mkleeneclose{}]\mcdot{} THENA Auto) THEN (InstLemma `real-fun-uniformly-less` [\mkleeneopen{}a\mkleeneclose{};\mkleeneopen{}b\mkleeneclose{};\mkleeneopen{}g\mkleeneclose{}]\mcdot{} THENA Auto) THEN (InstLemma `real-fun-bounded` [\mkleeneopen{}a\mkleeneclose{};\mkleeneopen{}b\mkleeneclose{};\mkleeneopen{}g\mkleeneclose{}]\mcdot{} THENA Auto) THEN ExRepD) Home Index