Proof of Nuprl Lemma : i-member-implies

Step * 6 1 of Lemma i-member-implies

1. y : ℝ
2. y1 : Top
3. r : ℝ
4. b : ℕ⁺
5. r(b) < r(b + 1)
6. r(-(b + 1)) < r(-b)
7. r(-b) ≤ r
8. r ≤ r(b)
9. m : ℕ⁺
10. y ≤ (r - (r1/r(m)))
11. ∃M:ℕ⁺. ((y ≤ (r - (r1/r(M)))) ∧ (r ≤ r(M)))
⊢ ∃n,M:ℕ⁺
   ((((y + (r1/r(n))) ≤ r) ∧ (r ≤ r(n)))
   ∧ (∀y@0:{y@0:ℝ| y < y@0}
        ((((r - (r1/r(M))) ≤ y@0) ∧ (y@0 ≤ (r + (r1/r(M))))) ⇒ (((y + (r1/r(n))) ≤ y@0) ∧ (y@0 ≤ r(n)))))
   ∧ (((True ∧ False) ⇒ (y < case ⊥ of inl(b) => b | inr(b) => b)) ⇒ (True ∧ True) ⇒ ((y + (r1/r(n))) < r(n))))
BY
{ (ThinVar `m'
   THEN ThinVar `b'
   THEN D -1
   THEN (Assert (r1/r(2 * M)) < (r1/r(M)) BY
               Auto)
   THEN (Assert (r1/r(M)) = (r(2) * (r1/r(2 * M))) BY
               (nRNorm 0 THEN Auto))) }

1
1. y : ℝ
2. y1 : Top
3. r : ℝ
4. M : ℕ⁺
5. (y ≤ (r - (r1/r(M)))) ∧ (r ≤ r(M))
6. (r1/r(2 * M)) < (r1/r(M))
7. (r1/r(M)) = (r(2) * (r1/r(2 * M)))
⊢ ∃n,M:ℕ⁺
   ((((y + (r1/r(n))) ≤ r) ∧ (r ≤ r(n)))
   ∧ (∀y@0:{y@0:ℝ| y < y@0}
        ((((r - (r1/r(M))) ≤ y@0) ∧ (y@0 ≤ (r + (r1/r(M))))) ⇒ (((y + (r1/r(n))) ≤ y@0) ∧ (y@0 ≤ r(n)))))
   ∧ (((True ∧ False) ⇒ (y < case ⊥ of inl(b) => b | inr(b) => b)) ⇒ (True ∧ True) ⇒ ((y + (r1/r(n))) < r(n))))

Latex:

Latex:
1. y : \mBbbR{} 2. y1 : Top 3. r : \mBbbR{} 4. b : \mBbbN{}\msupplus{} 5. r(b) < r(b + 1) 6. r(-(b + 1)) < r(-b) 7. r(-b) \mleq{} r 8. r \mleq{} r(b) 9. m : \mBbbN{}\msupplus{} 10. y \mleq{} (r - (r1/r(m))) 11. \mexists{}M:\mBbbN{}\msupplus{}. ((y \mleq{} (r - (r1/r(M)))) \mwedge{} (r \mleq{} r(M))) \mvdash{} \mexists{}n,M:\mBbbN{}\msupplus{} ((((y + (r1/r(n))) \mleq{} r) \mwedge{} (r \mleq{} r(n))) \mwedge{} (\mforall{}y@0:\{y@0:\mBbbR{}| y < y@0\} ((((r - (r1/r(M))) \mleq{} y@0) \mwedge{} (y@0 \mleq{} (r + (r1/r(M))))) {}\mRightarrow{} (((y + (r1/r(n))) \mleq{} y@0) \mwedge{} (y@0 \mleq{} r(n))))) \mwedge{} (((True \mwedge{} False) {}\mRightarrow{} (y < case \mbot{} of inl(b) => b | inr(b) => b)) {}\mRightarrow{} (True \mwedge{} True) {}\mRightarrow{} ((y + (r1/r(n))) < r(n)))) By Latex: (ThinVar `m' THEN ThinVar `b' THEN D -1 THEN (Assert (r1/r(2 * M)) < (r1/r(M)) BY Auto) THEN (Assert (r1/r(M)) = (r(2) * (r1/r(2 * M))) BY (nRNorm 0 THEN Auto))) Home Index