Proof of Nuprl Lemma : rcos-seq-positive

Step * 2 1 of Lemma rcos-seq-positive

1. n : ℤ
2. [%1] : 0 < n
3. (r0 < rcos-seq(n - 1)) ∧ (∀t:{t:ℝ| t ∈ [r0, rcos-seq(n - 1)]} . (r0 < rcos(t)))
4. rcos-seq((n - 1) + 1) = (rcos-seq(n - 1) + rcos(rcos-seq(n - 1)))

⊢ (r0 < rcos-seq((n - 1) + 1)) ∧ (∀t:{t:ℝ| (r0 ≤ t) ∧ (t ≤ rcos-seq((n - 1) + 1))} . (r0 < rcos(t)))

BY
{ Assert ⌜(r0 < (rcos-seq(n - 1) + rcos(rcos-seq(n - 1))))

          ∧ (∀t:{t:ℝ| (r0 ≤ t) ∧ (t ≤ (rcos-seq(n - 1) + rcos(rcos-seq(n - 1))))} . (r0 < rcos(t)))⌝⋅ }

1
.....assertion.....
1. n : ℤ
2. [%1] : 0 < n
3. (r0 < rcos-seq(n - 1)) ∧ (∀t:{t:ℝ| t ∈ [r0, rcos-seq(n - 1)]} . (r0 < rcos(t)))
4. rcos-seq((n - 1) + 1) = (rcos-seq(n - 1) + rcos(rcos-seq(n - 1)))
⊢ (r0 < (rcos-seq(n - 1) + rcos(rcos-seq(n - 1))))
∧ (∀t:{t:ℝ| (r0 ≤ t) ∧ (t ≤ (rcos-seq(n - 1) + rcos(rcos-seq(n - 1))))} . (r0 < rcos(t)))

2
1. n : ℤ
2. [%1] : 0 < n
3. (r0 < rcos-seq(n - 1)) ∧ (∀t:{t:ℝ| t ∈ [r0, rcos-seq(n - 1)]} . (r0 < rcos(t)))
4. rcos-seq((n - 1) + 1) = (rcos-seq(n - 1) + rcos(rcos-seq(n - 1)))
5. (r0 < (rcos-seq(n - 1) + rcos(rcos-seq(n - 1))))
∧ (∀t:{t:ℝ| (r0 ≤ t) ∧ (t ≤ (rcos-seq(n - 1) + rcos(rcos-seq(n - 1))))} . (r0 < rcos(t)))

⊢ (r0 < rcos-seq((n - 1) + 1)) ∧ (∀t:{t:ℝ| (r0 ≤ t) ∧ (t ≤ rcos-seq((n - 1) + 1))} . (r0 < rcos(t)))

Latex:

Latex:
1. n : \mBbbZ{} 2. [\%1] : 0 < n 3. (r0 < rcos-seq(n - 1)) \mwedge{} (\mforall{}t:\{t:\mBbbR{}| t \mmember{} [r0, rcos-seq(n - 1)]\} . (r0 < rcos(t))) 4. rcos-seq((n - 1) + 1) = (rcos-seq(n - 1) + rcos(rcos-seq(n - 1))) \mvdash{} (r0 < rcos-seq((n - 1) + 1)) \mwedge{} (\mforall{}t:\{t:\mBbbR{}| (r0 \mleq{} t) \mwedge{} (t \mleq{} rcos-seq((n - 1) + 1))\} . (r0 < rcos(t))) By Latex: Assert \mkleeneopen{}(r0 < (rcos-seq(n - 1) + rcos(rcos-seq(n - 1)))) \mwedge{} (\mforall{}t:\{t:\mBbbR{}| (r0 \mleq{} t) \mwedge{} (t \mleq{} (rcos-seq(n - 1) + rcos(rcos-seq(n - 1))))\} . (r0 < rcos(t)))\mkleeneclose{}\mcdot{} Home Index