Proof of Nuprl Lemma : adjacent-full-partition-points

Step * 1 2 1 2 1 of Lemma adjacent-full-partition-points

.....equality.....
1. I : Interval
2. icompact(I)
3. p : partition(I)
4. i : ℕ||p|| + 1
5. (¬0 < ||p||) ⇒ r0≤right-endpoint(I) - left-endpoint(I)≤partition-mesh(I;p)
6. 0 < ||p||
7. r0≤p[0] - left-endpoint(I)≤partition-mesh(I;p)
8. ∀i:ℕ||p|| - 1. r0≤p[i + 1] - p[i]≤partition-mesh(I;p)
9. r0≤right-endpoint(I) - last(p)≤partition-mesh(I;p)
10. ¬(i = 0 ∈ ℤ)
11. ¬i < ||p||
⊢ p @ [right-endpoint(I)][(i + 1) - 1] ~ right-endpoint(I)
BY
{ ((RWO "select-append" 0 THENA Auto) THEN AutoSplit) }

1
1. I : Interval
2. icompact(I)
3. p : partition(I)
4. i : ℕ||p|| + 1
5. ¬(i + 1) - 1 < ||p||
6. (¬0 < ||p||) ⇒ r0≤right-endpoint(I) - left-endpoint(I)≤partition-mesh(I;p)
7. 0 < ||p||
8. r0≤p[0] - left-endpoint(I)≤partition-mesh(I;p)
9. ∀i:ℕ||p|| - 1. r0≤p[i + 1] - p[i]≤partition-mesh(I;p)
10. r0≤right-endpoint(I) - last(p)≤partition-mesh(I;p)
11. ¬(i = 0 ∈ ℤ)
12. ¬i < ||p||
⊢ [right-endpoint(I)][(i + 1) - 1 - ||p||] ~ right-endpoint(I)

Latex:

Latex:
.....equality..... 1. I : Interval 2. icompact(I) 3. p : partition(I) 4. i : \mBbbN{}||p|| + 1 5. (\mneg{}0 < ||p||) {}\mRightarrow{} r0\mleq{}right-endpoint(I) - left-endpoint(I)\mleq{}partition-mesh(I;p) 6. 0 < ||p|| 7. r0\mleq{}p[0] - left-endpoint(I)\mleq{}partition-mesh(I;p) 8. \mforall{}i:\mBbbN{}||p|| - 1. r0\mleq{}p[i + 1] - p[i]\mleq{}partition-mesh(I;p) 9. r0\mleq{}right-endpoint(I) - last(p)\mleq{}partition-mesh(I;p) 10. \mneg{}(i = 0) 11. \mneg{}i < ||p|| \mvdash{} p @ [right-endpoint(I)][(i + 1) - 1] \msim{} right-endpoint(I) By Latex: ((RWO "select-append" 0 THENA Auto) THEN AutoSplit) Home Index