Proof of Nuprl Lemma : closures-meet-sq

Step * 1 1 of Lemma closures-meet-sq

1. [P] : ℝ ⟶ ℙ
2. [Q] : ℝ ⟶ ℙ
3. a0 : {a:ℝ| P a}
4. b0 : ℝ
5. [%4] : (Q b0) ∧ (a0 ≤ b0)
6. c : ℝ
7. [%5] : (r0 ≤ c) ∧ (c < r1)
8. ∀a:{a:ℝ| P a} . ∀b:{b:ℝ| (Q b) ∧ (a ≤ b)} .

     ∃a':{a':ℝ| P a'} . (∃b':{b':ℝ| (Q b') ∧ (a' ≤ b')}  [((a ≤ a') ∧ (b' ≤ b) ∧ ((b' - a') ≤ ((b - a) * c)))])

9. <a0, b0> ∈ a:{a:ℝ| P a} × {b:ℝ| (Q b) ∧ (a ≤ b)}
⊢ ∃s:ℕ ⟶ (a:{a:ℝ| P a} × {b:ℝ| (Q b) ∧ (a ≤ b)} ) [(∀n:ℕ

                                                   (((fst(s[n])) ≤ (fst(s[n + 1])))

                                                   ∧ ((snd(s[n + 1])) ≤ (snd(s[n])))

                                                   ∧ (((snd(s[n + 1])) - fst(s[n + 1])) ≤ (((snd(s[n])) - fst(s[n]))

                                                     * c))))]
BY
{ Assert ⌜∀ab:a:{a:ℝ| P a}  × {b:ℝ| (Q b) ∧ (a ≤ b)}
            ∃ab':a:{a:ℝ| P a}  × {b:ℝ| (Q b) ∧ (a ≤ b)}
             (((fst(ab)) ≤ (fst(ab')))
             ∧ ((snd(ab')) ≤ (snd(ab)))
             ∧ (((snd(ab')) - fst(ab')) ≤ (((snd(ab)) - fst(ab)) * c)))⌝⋅ }

1
.....assertion.....
1. [P] : ℝ ⟶ ℙ
2. [Q] : ℝ ⟶ ℙ
3. a0 : {a:ℝ| P a}
4. b0 : ℝ
5. [%4] : (Q b0) ∧ (a0 ≤ b0)
6. c : ℝ
7. [%5] : (r0 ≤ c) ∧ (c < r1)
8. ∀a:{a:ℝ| P a} . ∀b:{b:ℝ| (Q b) ∧ (a ≤ b)} .

     ∃a':{a':ℝ| P a'} . (∃b':{b':ℝ| (Q b') ∧ (a' ≤ b')}  [((a ≤ a') ∧ (b' ≤ b) ∧ ((b' - a') ≤ ((b - a) * c)))])

9. <a0, b0> ∈ a:{a:ℝ| P a}  × {b:ℝ| (Q b) ∧ (a ≤ b)}
⊢ ∀ab:a:{a:ℝ| P a}  × {b:ℝ| (Q b) ∧ (a ≤ b)}
    ∃ab':a:{a:ℝ| P a}  × {b:ℝ| (Q b) ∧ (a ≤ b)}

     (((fst(ab)) ≤ (fst(ab'))) ∧ ((snd(ab')) ≤ (snd(ab))) ∧ (((snd(ab')) - fst(ab')) ≤ (((snd(ab)) - fst(ab)) * c)))

2
1. [P] : ℝ ⟶ ℙ
2. [Q] : ℝ ⟶ ℙ
3. a0 : {a:ℝ| P a}
4. b0 : ℝ
5. [%4] : (Q b0) ∧ (a0 ≤ b0)
6. c : ℝ
7. [%5] : (r0 ≤ c) ∧ (c < r1)
8. ∀a:{a:ℝ| P a} . ∀b:{b:ℝ| (Q b) ∧ (a ≤ b)} .

     ∃a':{a':ℝ| P a'} . (∃b':{b':ℝ| (Q b') ∧ (a' ≤ b')}  [((a ≤ a') ∧ (b' ≤ b) ∧ ((b' - a') ≤ ((b - a) * c)))])

9. <a0, b0> ∈ a:{a:ℝ| P a}  × {b:ℝ| (Q b) ∧ (a ≤ b)}
10. ∀ab:a:{a:ℝ| P a}  × {b:ℝ| (Q b) ∧ (a ≤ b)}
      ∃ab':a:{a:ℝ| P a}  × {b:ℝ| (Q b) ∧ (a ≤ b)}

       (((fst(ab)) ≤ (fst(ab'))) ∧ ((snd(ab')) ≤ (snd(ab))) ∧ (((snd(ab')) - fst(ab')) ≤ (((snd(ab)) - fst(ab)) * c)))

⊢ ∃s:ℕ ⟶ (a:{a:ℝ| P a} × {b:ℝ| (Q b) ∧ (a ≤ b)} ) [(∀n:ℕ

                                                   (((fst(s[n])) ≤ (fst(s[n + 1])))

                                                   ∧ ((snd(s[n + 1])) ≤ (snd(s[n])))

                                                   ∧ (((snd(s[n + 1])) - fst(s[n + 1])) ≤ (((snd(s[n])) - fst(s[n]))

* c))))]

Latex:

Latex:
1. [P] : \mBbbR{} {}\mrightarrow{} \mBbbP{} 2. [Q] : \mBbbR{} {}\mrightarrow{} \mBbbP{} 3. a0 : \{a:\mBbbR{}| P a\} 4. b0 : \mBbbR{} 5. [\%4] : (Q b0) \mwedge{} (a0 \mleq{} b0) 6. c : \mBbbR{} 7. [\%5] : (r0 \mleq{} c) \mwedge{} (c < r1) 8. \mforall{}a:\{a:\mBbbR{}| P a\} . \mforall{}b:\{b:\mBbbR{}| (Q b) \mwedge{} (a \mleq{} b)\} . \mexists{}a':\{a':\mBbbR{}| P a'\} . (\mexists{}b':\{b':\mBbbR{}| (Q b') \mwedge{} (a' \mleq{} b')\} [((a \mleq{} a') \mwedge{} (b' \mleq{} b) \mwedge{} ((b' - a') \mleq{} ((b - \000Ca) * c)))]) 9. <a0, b0> \mmember{} a:\{a:\mBbbR{}| P a\} \mtimes{} \{b:\mBbbR{}| (Q b) \mwedge{} (a \mleq{} b)\} \mvdash{} \mexists{}s:\mBbbN{} {}\mrightarrow{} (a:\{a:\mBbbR{}| P a\} \mtimes{} \{b:\mBbbR{}| (Q b) \mwedge{} (a \mleq{} b)\} ) [(\mforall{}n:\mBbbN{} (((fst(s[n])) \mleq{} (fst(s[n + 1]))) \mwedge{} ((snd(s[n + 1])) \mleq{} (snd(s[n]))) \mwedge{} (((snd(s[n + 1])) - fst(s[n + 1])) \mleq{} (((snd(s[n])) - fst(s[n])) * c))))] By Latex: Assert \mkleeneopen{}\mforall{}ab:a:\{a:\mBbbR{}| P a\} \mtimes{} \{b:\mBbbR{}| (Q b) \mwedge{} (a \mleq{} b)\} \mexists{}ab':a:\{a:\mBbbR{}| P a\} \mtimes{} \{b:\mBbbR{}| (Q b) \mwedge{} (a \mleq{} b)\} (((fst(ab)) \mleq{} (fst(ab'))) \mwedge{} ((snd(ab')) \mleq{} (snd(ab))) \mwedge{} (((snd(ab')) - fst(ab')) \mleq{} (((snd(ab)) - fst(ab)) * c)))\mkleeneclose{}\mcdot{} Home Index