Proof of Nuprl Lemma : rminimum-cases

Step * 1 2 1 1 1 1 of Lemma rminimum-cases

1. n : ℤ
2. d : ℤ
3. 0 < d
4. ∀x:{n..(n + (d - 1)) + 1^-} ⟶ ℝ
(¬¬(∃a:{n..(n + (d - 1)) + 1^-}

          ((primrec(d - 1;x[n];λi,s. rmin(s;x[n + i + 1])) = x[a]) ∧ (∀j:{n..(n + (d - 1)) + 1^-}. (x[a] ≤ x[j])))))

5. 1 ≤ d
6. x : {n..(n + d) + 1^-} ⟶ ℝ
7. a : {n..(n + (d - 1)) + 1^-}
8. primrec(d - 1;x[n];λi,s. rmin(s;x[n + i + 1])) = x[a]
9. ∀j:{n..(n + (d - 1)) + 1^-}. (x[a] ≤ x[j])
10. x[a] < x[n + d]
⊢ rmin(x[a];x[n + (d - 1) + 1]) = x[a]
BY
{ (Subst' n + (d - 1) + 1 ~ n + d 0 THEN EAuto 1) }

Latex:

Latex:
1. n : \mBbbZ{} 2. d : \mBbbZ{} 3. 0 < d 4. \mforall{}x:\{n..(n + (d - 1)) + 1\msupminus{}\} {}\mrightarrow{} \mBbbR{} (\mneg{}\mneg{}(\mexists{}a:\{n..(n + (d - 1)) + 1\msupminus{}\} ((primrec(d - 1;x[n];\mlambda{}i,s. rmin(s;x[n + i + 1])) = x[a]) \mwedge{} (\mforall{}j:\{n..(n + (d - 1)) + 1\msupminus{}\}. (x[a] \mleq{} x[j]))))) 5. 1 \mleq{} d 6. x : \{n..(n + d) + 1\msupminus{}\} {}\mrightarrow{} \mBbbR{} 7. a : \{n..(n + (d - 1)) + 1\msupminus{}\} 8. primrec(d - 1;x[n];\mlambda{}i,s. rmin(s;x[n + i + 1])) = x[a] 9. \mforall{}j:\{n..(n + (d - 1)) + 1\msupminus{}\}. (x[a] \mleq{} x[j]) 10. x[a] < x[n + d] \mvdash{} rmin(x[a];x[n + (d - 1) + 1]) = x[a] By Latex: (Subst' n + (d - 1) + 1 \msim{} n + d 0 THEN EAuto 1) Home Index