Proof of Nuprl Lemma : ireal-approx-rmul2

Step * 1 1 1 of Lemma ireal-approx-rmul2

.....assertion.....
1. x : ℝ
2. y : ℝ
3. j : ℕ⁺
4. M : ℕ⁺
5. a : ℤ
6. b : ℤ
7. k : ℕ⁺
8. |x| ≤ (r1/r(2))
9. |b| ≤ k
10. |x - (r(a)/r(2 * k))| ≤ (r(j)/r(k))
11. |y - (r(b)/r(2 * 2 * M))| ≤ (r(j)/r(2 * M))
12. |(x * y) - (r(a)/r(2 * k)) * (r(b)/r(2 * 2 * M))| ≤ ((|x| * (r(j)/r(2 * M)))
+ (|(r(b)/r(2 * 2 * M))| * (r(j)/r(k))))
⊢ |((r(a)/r(2 * k)) * (r(b)/r(2 * 2 * M))) - (r((a * b) ÷ 4 * k)/r(2 * M))| ≤ (r1/r(2 * M))
BY
{ (Using [`y',⌜|r(4 * k)|⌝] (BLemma `rmul_preserves_rleq`)⋅ THENA Auto) }

1
1. x : ℝ
2. y : ℝ
3. j : ℕ⁺
4. M : ℕ⁺
5. a : ℤ
6. b : ℤ
7. k : ℕ⁺
8. |x| ≤ (r1/r(2))
9. |b| ≤ k
10. |x - (r(a)/r(2 * k))| ≤ (r(j)/r(k))
11. |y - (r(b)/r(2 * 2 * M))| ≤ (r(j)/r(2 * M))
12. |(x * y) - (r(a)/r(2 * k)) * (r(b)/r(2 * 2 * M))| ≤ ((|x| * (r(j)/r(2 * M)))
+ (|(r(b)/r(2 * 2 * M))| * (r(j)/r(k))))
⊢ r0 < |r(4 * k)|

2
1. x : ℝ
2. y : ℝ
3. j : ℕ⁺
4. M : ℕ⁺
5. a : ℤ
6. b : ℤ
7. k : ℕ⁺
8. |x| ≤ (r1/r(2))
9. |b| ≤ k
10. |x - (r(a)/r(2 * k))| ≤ (r(j)/r(k))
11. |y - (r(b)/r(2 * 2 * M))| ≤ (r(j)/r(2 * M))
12. |(x * y) - (r(a)/r(2 * k)) * (r(b)/r(2 * 2 * M))| ≤ ((|x| * (r(j)/r(2 * M)))
+ (|(r(b)/r(2 * 2 * M))| * (r(j)/r(k))))

⊢ (|((r(a)/r(2 * k)) * (r(b)/r(2 * 2 * M))) - (r((a * b) ÷ 4 * k)/r(2 * M))| * |r(4 * k)|) ≤ ((r1/r(2 * M))

* |r(4 * k)|)

Latex:

Latex:
.....assertion..... 1. x : \mBbbR{} 2. y : \mBbbR{} 3. j : \mBbbN{}\msupplus{} 4. M : \mBbbN{}\msupplus{} 5. a : \mBbbZ{} 6. b : \mBbbZ{} 7. k : \mBbbN{}\msupplus{} 8. |x| \mleq{} (r1/r(2)) 9. |b| \mleq{} k 10. |x - (r(a)/r(2 * k))| \mleq{} (r(j)/r(k)) 11. |y - (r(b)/r(2 * 2 * M))| \mleq{} (r(j)/r(2 * M)) 12. |(x * y) - (r(a)/r(2 * k)) * (r(b)/r(2 * 2 * M))| \mleq{} ((|x| * (r(j)/r(2 * M))) + (|(r(b)/r(2 * 2 * M))| * (r(j)/r(k)))) \mvdash{} |((r(a)/r(2 * k)) * (r(b)/r(2 * 2 * M))) - (r((a * b) \mdiv{} 4 * k)/r(2 * M))| \mleq{} (r1/r(2 * M)) By Latex: (Using [`y',\mkleeneopen{}|r(4 * k)|\mkleeneclose{}] (BLemma `rmul\_preserves\_rleq`)\mcdot{} THENA Auto) Home Index