Proof of Nuprl Lemma : nearby-separated-partition-sum-no-mc

Step * 1 of Lemma nearby-separated-partition-sum-no-mc

1. I : Interval@i
2. icompact(I)
3. iproper(I)
4. f : {f:I ⟶ℝ| ifun(f;I)} @i
5. alpha : {alpha:ℝ| r0 < alpha} @i
6. e : {e:ℝ| r0 < e} @i
7. p : partition(I)@i
8. q : partition(I)@i
9. x : partition-choice(full-partition(I;p))@i
10. y : partition-choice(full-partition(I;q))@i
11. r0 < (alpha/r(2))
12. r0 < (e/r(2))
13. e1 : {e:ℝ| r0 < e}
14. ∀q:partition(I). ∀y:partition-choice(full-partition(I;q)).
      (nearby-partitions(e1;p;q)
      ⇒ (∀i:ℕ||p|| + 1. (|x[i] - y[i]| ≤ e1))
      ⇒ (|S(f;full-partition(I;q)) - S(f;full-partition(I;p))| ≤ (alpha/r(2))))
15. e2 : {e:ℝ| r0 < e}
16. ∀q@0:partition(I). ∀y@0:partition-choice(full-partition(I;q@0)).
      (nearby-partitions(e2;q;q@0)
      ⇒ (∀i:ℕ||q|| + 1. (|y[i] - y@0[i]| ≤ e2))
      ⇒ (|S(f;full-partition(I;q@0)) - S(f;full-partition(I;q))| ≤ (alpha/r(2))))
⊢ ∃p':partition(I)
   ∃x':partition-choice(full-partition(I;p'))
    ((partition-mesh(I;p') ≤ (partition-mesh(I;p) + e))
    ∧ (∃q':partition(I)
        ∃y':partition-choice(full-partition(I;q'))
         (separated-partitions(p';q')
         ∧ (partition-mesh(I;q') ≤ (partition-mesh(I;q) + e))
         ∧ (|S(f;full-partition(I;p)) - S(f;full-partition(I;q))| ≤ (|S(f;full-partition(I;p'))
           - S(f;full-partition(I;q'))|
           + alpha)))))
BY
{ ((Assert r0 < rmin((e/r(2));rmin(e1;e2)) BY
          (RWW "rmin_strict_ub<" 0 THEN Auto))

   THEN (InstLemma `nearby-separated-partitions` [⌜I⌝;⌜p⌝;⌜q⌝;⌜rmin((e/r(2));rmin(e1;e2))⌝]⋅ THENA Auto)

   THEN ParallelLast) }

1
1. I : Interval@i
2. icompact(I)
3. iproper(I)
4. f : {f:I ⟶ℝ| ifun(f;I)} @i
5. alpha : {alpha:ℝ| r0 < alpha} @i
6. e : {e:ℝ| r0 < e} @i
7. p : partition(I)@i
8. q : partition(I)@i
9. x : partition-choice(full-partition(I;p))@i
10. y : partition-choice(full-partition(I;q))@i
11. r0 < (alpha/r(2))
12. r0 < (e/r(2))
13. e1 : {e:ℝ| r0 < e}
14. ∀q:partition(I). ∀y:partition-choice(full-partition(I;q)).
      (nearby-partitions(e1;p;q)
      ⇒ (∀i:ℕ||p|| + 1. (|x[i] - y[i]| ≤ e1))
      ⇒ (|S(f;full-partition(I;q)) - S(f;full-partition(I;p))| ≤ (alpha/r(2))))
15. e2 : {e:ℝ| r0 < e}
16. ∀q@0:partition(I). ∀y@0:partition-choice(full-partition(I;q@0)).
      (nearby-partitions(e2;q;q@0)
      ⇒ (∀i:ℕ||q|| + 1. (|y[i] - y@0[i]| ≤ e2))
      ⇒ (|S(f;full-partition(I;q@0)) - S(f;full-partition(I;q))| ≤ (alpha/r(2))))
17. r0 < rmin((e/r(2));rmin(e1;e2))
18. p' : partition(I)
19. ∃q':partition(I)
     (separated-partitions(p';q')
     ∧ nearby-partitions(rmin((e/r(2));rmin(e1;e2));p;p')
     ∧ nearby-partitions(rmin((e/r(2));rmin(e1;e2));q;q'))
⊢ ∃x':partition-choice(full-partition(I;p'))
   ((partition-mesh(I;p') ≤ (partition-mesh(I;p) + e))
   ∧ (∃q':partition(I)
       ∃y':partition-choice(full-partition(I;q'))
        (separated-partitions(p';q')
        ∧ (partition-mesh(I;q') ≤ (partition-mesh(I;q) + e))
        ∧ (|S(f;full-partition(I;p)) - S(f;full-partition(I;q))| ≤ (|S(f;full-partition(I;p'))
          - S(f;full-partition(I;q'))|
          + alpha)))))

Latex:

Latex:
1. I : Interval@i 2. icompact(I) 3. iproper(I) 4. f : \{f:I {}\mrightarrow{}\mBbbR{}| ifun(f;I)\} @i 5. alpha : \{alpha:\mBbbR{}| r0 < alpha\} @i 6. e : \{e:\mBbbR{}| r0 < e\} @i 7. p : partition(I)@i 8. q : partition(I)@i 9. x : partition-choice(full-partition(I;p))@i 10. y : partition-choice(full-partition(I;q))@i 11. r0 < (alpha/r(2)) 12. r0 < (e/r(2)) 13. e1 : \{e:\mBbbR{}| r0 < e\} 14. \mforall{}q:partition(I). \mforall{}y:partition-choice(full-partition(I;q)). (nearby-partitions(e1;p;q) {}\mRightarrow{} (\mforall{}i:\mBbbN{}||p|| + 1. (|x[i] - y[i]| \mleq{} e1)) {}\mRightarrow{} (|S(f;full-partition(I;q)) - S(f;full-partition(I;p))| \mleq{} (alpha/r(2)))) 15. e2 : \{e:\mBbbR{}| r0 < e\} 16. \mforall{}q@0:partition(I). \mforall{}y@0:partition-choice(full-partition(I;q@0)). (nearby-partitions(e2;q;q@0) {}\mRightarrow{} (\mforall{}i:\mBbbN{}||q|| + 1. (|y[i] - y@0[i]| \mleq{} e2)) {}\mRightarrow{} (|S(f;full-partition(I;q@0)) - S(f;full-partition(I;q))| \mleq{} (alpha/r(2)))) \mvdash{} \mexists{}p':partition(I) \mexists{}x':partition-choice(full-partition(I;p')) ((partition-mesh(I;p') \mleq{} (partition-mesh(I;p) + e)) \mwedge{} (\mexists{}q':partition(I) \mexists{}y':partition-choice(full-partition(I;q')) (separated-partitions(p';q') \mwedge{} (partition-mesh(I;q') \mleq{} (partition-mesh(I;q) + e)) \mwedge{} (|S(f;full-partition(I;p)) - S(f;full-partition(I;q))| \mleq{} (|S(f;full-partition(I;p')) - S(f;full-partition(I;q'))| + alpha))))) By Latex: ((Assert r0 < rmin((e/r(2));rmin(e1;e2)) BY (RWW "rmin\_strict\_ub<" 0 THEN Auto)) THEN (InstLemma `nearby-separated-partitions` [\mkleeneopen{}I\mkleeneclose{};\mkleeneopen{}p\mkleeneclose{};\mkleeneopen{}q\mkleeneclose{};\mkleeneopen{}rmin((e/r(2));rmin(e1;e2))\mkleeneclose{}]\mcdot{} THENA Auto ) THEN ParallelLast) Home Index