Proof of Nuprl Lemma : approx-iter-arcsine

Step * 2 1 1 1 of Lemma approx-iter-arcsine_wf

.....set predicate.....
1. a : {a:ℝ| (r(-1) < a) ∧ (a < r1)}
2. n : ℤ
3. n ≠ 0
4. 0 < n

5. ∀[k:ℕ⁺]. (approx-iter-arcsine(a;k;n - 1) ∈ {y:ℤ| |arcsine-contraction^n - 1(a) - (r(y))/2 * k| ≤ (r(2)/r(k))} )

6. k : ℕ⁺

7. approx-iter-arcsine(a;6 * k;n - 1) ∈ {y:ℤ| |arcsine-contraction^n - 1(a) - (r(y))/2 * 6 * k| ≤ (r(2)/r(6 * k))}

8. v : ℤ
9. |arcsine-contraction^n - 1(a) - (r(v))/2 * 6 * k| ≤ (r(2)/r(6 * k))

10. approx-iter-arcsine(a;6 * k;n - 1) = v ∈ {y:ℤ| |arcsine-contraction^n - 1(a) - (r(y))/2 * 6 * k| ≤ (r(2)/r(6 * k))}

⊢ |arcsine-contraction(a;arcsine-contraction^n - 1(a)) - (r(arcsine-contraction(a;(r(v))/2 * 6 * k) k))/2
* k| ≤ (r(2)/r(k))
BY
{ (MoveToConcl (-2) THEN (GenConcl ⌜arcsine-contraction^n - 1(a) = y ∈ ℝ⌝⋅ THENA Auto)) }

1
1. a : {a:ℝ| (r(-1) < a) ∧ (a < r1)}
2. n : ℤ
3. n ≠ 0
4. 0 < n

5. ∀[k:ℕ⁺]. (approx-iter-arcsine(a;k;n - 1) ∈ {y:ℤ| |arcsine-contraction^n - 1(a) - (r(y))/2 * k| ≤ (r(2)/r(k))} )

6. k : ℕ⁺

7. approx-iter-arcsine(a;6 * k;n - 1) ∈ {y:ℤ| |arcsine-contraction^n - 1(a) - (r(y))/2 * 6 * k| ≤ (r(2)/r(6 * k))}

8. v : ℤ

9. approx-iter-arcsine(a;6 * k;n - 1) = v ∈ {y:ℤ| |arcsine-contraction^n - 1(a) - (r(y))/2 * 6 * k| ≤ (r(2)/r(6 * k))}

10. y : ℝ
11. arcsine-contraction^n - 1(a) = y ∈ ℝ
⊢ (|y - (r(v))/2 * 6 * k| ≤ (r(2)/r(6 * k)))
⇒ (|arcsine-contraction(a;y) - (r(arcsine-contraction(a;(r(v))/2 * 6 * k) k))/2 * k| ≤ (r(2)/r(k)))

Latex:

Latex:
.....set predicate..... 1. a : \{a:\mBbbR{}| (r(-1) < a) \mwedge{} (a < r1)\} 2. n : \mBbbZ{} 3. n \mneq{} 0 4. 0 < n 5. \mforall{}[k:\mBbbN{}\msupplus{}] (approx-iter-arcsine(a;k;n - 1) \mmember{} \{y:\mBbbZ{}| |arcsine-contraction\^{}n - 1(a) - (r(y))/2 * k| \mleq{} (r(2)/r(k))\} ) 6. k : \mBbbN{}\msupplus{} 7. approx-iter-arcsine(a;6 * k;n - 1) \mmember{} \{y:\mBbbZ{}| |arcsine-contraction\^{}n - 1(a) - (r(y))/2 * 6 * k| \mleq{} (r(2)/r(6 * k))\} 8. v : \mBbbZ{} 9. |arcsine-contraction\^{}n - 1(a) - (r(v))/2 * 6 * k| \mleq{} (r(2)/r(6 * k)) 10. approx-iter-arcsine(a;6 * k;n - 1) = v \mvdash{} |arcsine-contraction(a;arcsine-contraction\^{}n - 1(a)) - (r(arcsine-contraction(a;(r(v))/2 * 6 * k) k))/2 * k| \mleq{} (r(2)/r(k)) By Latex: (MoveToConcl (-2) THEN (GenConcl \mkleeneopen{}arcsine-contraction\^{}n - 1(a) = y\mkleeneclose{}\mcdot{} THENA Auto)) Home Index