Proof of Nuprl Lemma : partition-split-cons-mesh

Step * 2 1 of Lemma partition-split-cons-mesh

1. [I] : Interval
2. [%] : icompact(I)
3. [a] : ℝ
4. [bs] : ℝ List
5. partitions(I;[a / bs])
6. partitions([left-endpoint(I), a];[])
7. partitions([a, right-endpoint(I)];bs)
8. partitions([left-endpoint(I), a];[])
9. partitions([a, right-endpoint(I)];bs)
10. left-endpoint(I) ≤ a
11. a ≤ right-endpoint(I)
⊢ |[left-endpoint(I), a]| ≤ partition-mesh(I;[a / bs])
BY
{ (InstLemma `adjacent-full-partition-points` [⌜I⌝;⌜[a / bs]⌝;⌜0⌝]⋅ THENA Auto) }

1
.....wf.....
1. I : Interval
2. icompact(I)
3. a : ℝ
4. bs : ℝ List
5. partitions(I;[a / bs])
6. partitions([left-endpoint(I), a];[])
7. partitions([a, right-endpoint(I)];bs)
8. partitions([left-endpoint(I), a];[])
9. partitions([a, right-endpoint(I)];bs)
10. left-endpoint(I) ≤ a
11. a ≤ right-endpoint(I)
⊢ 0 ∈ ℕ||full-partition(I;[a / bs])|| - 1

2
1. [I] : Interval
2. [%] : icompact(I)
3. [a] : ℝ
4. [bs] : ℝ List
5. partitions(I;[a / bs])
6. partitions([left-endpoint(I), a];[])
7. partitions([a, right-endpoint(I)];bs)
8. partitions([left-endpoint(I), a];[])
9. partitions([a, right-endpoint(I)];bs)
10. left-endpoint(I) ≤ a
11. a ≤ right-endpoint(I)
12. r0≤full-partition(I;[a / bs])[0 + 1] - full-partition(I;[a / bs])[0]≤partition-mesh(I;[a / bs])
⊢ |[left-endpoint(I), a]| ≤ partition-mesh(I;[a / bs])

Latex:

Latex:
1. [I] : Interval 2. [\%] : icompact(I) 3. [a] : \mBbbR{} 4. [bs] : \mBbbR{} List 5. partitions(I;[a / bs]) 6. partitions([left-endpoint(I), a];[]) 7. partitions([a, right-endpoint(I)];bs) 8. partitions([left-endpoint(I), a];[]) 9. partitions([a, right-endpoint(I)];bs) 10. left-endpoint(I) \mleq{} a 11. a \mleq{} right-endpoint(I) \mvdash{} |[left-endpoint(I), a]| \mleq{} partition-mesh(I;[a / bs]) By Latex: (InstLemma `adjacent-full-partition-points` [\mkleeneopen{}I\mkleeneclose{};\mkleeneopen{}[a / bs]\mkleeneclose{};\mkleeneopen{}0\mkleeneclose{}]\mcdot{} THENA Auto) Home Index