Proof of Nuprl Lemma : rational-inner-approx-property

Step * 1 of Lemma rational-inner-approx-property

1. x : ℝ
2. n : ℕ⁺
3. a : ℤ
4. (x (2 * n)) = a ∈ ℤ
5. |x - (r(a))/2 * 2 * n| ≤ (r1/r(2 * n))
6. 4 < a
⊢ (|(r(a - 2))/2 * 2 * n| ≤ |x|) ∧ (|x - (r(a - 2))/2 * 2 * n| ≤ (r(2)/r(n)))
BY
{ Assert ⌜(r(a - 2))/2 * 2 * n = ((r(a))/2 * 2 * n - (r1/r(2 * n)))⌝⋅ }

1
.....assertion.....
1. x : ℝ
2. n : ℕ⁺
3. a : ℤ
4. (x (2 * n)) = a ∈ ℤ
5. |x - (r(a))/2 * 2 * n| ≤ (r1/r(2 * n))
6. 4 < a
⊢ (r(a - 2))/2 * 2 * n = ((r(a))/2 * 2 * n - (r1/r(2 * n)))

2
1. x : ℝ
2. n : ℕ⁺
3. a : ℤ
4. (x (2 * n)) = a ∈ ℤ
5. |x - (r(a))/2 * 2 * n| ≤ (r1/r(2 * n))
6. 4 < a
7. (r(a - 2))/2 * 2 * n = ((r(a))/2 * 2 * n - (r1/r(2 * n)))
⊢ (|(r(a - 2))/2 * 2 * n| ≤ |x|) ∧ (|x - (r(a - 2))/2 * 2 * n| ≤ (r(2)/r(n)))

Latex:

Latex:
1. x : \mBbbR{} 2. n : \mBbbN{}\msupplus{} 3. a : \mBbbZ{} 4. (x (2 * n)) = a 5. |x - (r(a))/2 * 2 * n| \mleq{} (r1/r(2 * n)) 6. 4 < a \mvdash{} (|(r(a - 2))/2 * 2 * n| \mleq{} |x|) \mwedge{} (|x - (r(a - 2))/2 * 2 * n| \mleq{} (r(2)/r(n))) By Latex: Assert \mkleeneopen{}(r(a - 2))/2 * 2 * n = ((r(a))/2 * 2 * n - (r1/r(2 * n)))\mkleeneclose{}\mcdot{} Home Index