Proof of Nuprl Lemma : ip-extend-lemma

Step * 1 1 2 of Lemma ip-extend-lemma

1. rv : InnerProductSpace
2. a : Point(rv)
3. b : {b:Point(rv)| a # b}
4. dcd : {d:ℝ| r0 ≤ d}
5. r0 < ||a - b||
6. r0 ≤ dcd
7. (-(dcd)/||a - b||) = (r1 - (||a - b|| + dcd/||a - b||))
8. a ≡ (||a - b|| + dcd/||a - b||)*b + r1 - (||a - b|| + dcd/||a - b||)*a
⇒ b ≡ (||a - b|| + dcd/||a - b||)*b + r1 - (||a - b|| + dcd/||a - b||)*a
9. a # (||a - b|| + dcd/||a - b||)*b + r1 - (||a - b|| + dcd/||a - b||)*a

⊢ ∃t:ℝ. ((t ∈ [r0, r1]) ∧ b ≡ t*a + r1 - t*(||a - b|| + dcd/||a - b||)*b + r1 - (||a - b|| + dcd/||a - b||)*a)

BY
{ (Assert r0 < (||a - b|| + dcd) BY
((Assert r0 ≤ dcd BY Auto) THEN (RWO "-1<" 0 THENM nRNorm 0) THEN Auto)) }

1
1. rv : InnerProductSpace
2. a : Point(rv)
3. b : {b:Point(rv)| a # b}
4. dcd : {d:ℝ| r0 ≤ d}
5. r0 < ||a - b||
6. r0 ≤ dcd
7. (-(dcd)/||a - b||) = (r1 - (||a - b|| + dcd/||a - b||))
8. a ≡ (||a - b|| + dcd/||a - b||)*b + r1 - (||a - b|| + dcd/||a - b||)*a
⇒ b ≡ (||a - b|| + dcd/||a - b||)*b + r1 - (||a - b|| + dcd/||a - b||)*a
9. a # (||a - b|| + dcd/||a - b||)*b + r1 - (||a - b|| + dcd/||a - b||)*a
10. r0 < (||a - b|| + dcd)

⊢ ∃t:ℝ. ((t ∈ [r0, r1]) ∧ b ≡ t*a + r1 - t*(||a - b|| + dcd/||a - b||)*b + r1 - (||a - b|| + dcd/||a - b||)*a)

Latex:

Latex:
1. rv : InnerProductSpace 2. a : Point(rv) 3. b : \{b:Point(rv)| a \# b\} 4. dcd : \{d:\mBbbR{}| r0 \mleq{} d\} 5. r0 < ||a - b|| 6. r0 \mleq{} dcd 7. (-(dcd)/||a - b||) = (r1 - (||a - b|| + dcd/||a - b||)) 8. a \mequiv{} (||a - b|| + dcd/||a - b||)*b + r1 - (||a - b|| + dcd/||a - b||)*a {}\mRightarrow{} b \mequiv{} (||a - b|| + dcd/||a - b||)*b + r1 - (||a - b|| + dcd/||a - b||)*a 9. a \# (||a - b|| + dcd/||a - b||)*b + r1 - (||a - b|| + dcd/||a - b||)*a \mvdash{} \mexists{}t:\mBbbR{} ((t \mmember{} [r0, r1]) \mwedge{} b \mequiv{} t*a + r1 - t*(||a - b|| + dcd/||a - b||)*b + r1 - (||a - b|| + dcd/||a - b||)*a) By Latex: (Assert r0 < (||a - b|| + dcd) BY ((Assert r0 \mleq{} dcd BY Auto) THEN (RWO "-1<" 0 THENM nRNorm 0) THEN Auto)) Home Index