Proof of Nuprl Lemma : ip-inner-Pasch1

Step * 1 1 1 1 1 of Lemma ip-inner-Pasch1

1. rv : InnerProductSpace
2. a : Point
3. b : Point
4. c : Point
5. p : Point
6. q : Point
7. a # p
8. b # c
9. a # c
10. t : ℝ
11. r0 ≤ t
12. t ≤ r1
13. q ≡ t*b + r1 - t*c
14. s : ℝ
15. r0 ≤ s
16. s ≤ r1
17. p ≡ s*a + r1 - s*c
18. s < r1
19. r0 < (r1 - s * t)
20. u : ℝ
21. (t - s * t/r1 - s * t) = u ∈ ℝ
22. v : ℝ
23. (s - s * t/r1 - s * t) = v ∈ ℝ
24. ((r1 - u) * s) = v
25. ((r1 - v) * t) = u
⊢ (u ∈ [r0, r1])
⇒ (v ∈ [r0, r1))
⇒ (∃x:Point
     (a_x_q
     ∧ b_x_p
     ∧ (a # q ⇒ x # a)
     ∧ ((a # q ∧ p # c ∧ b # q) ⇒ x # q)
     ∧ ((b # p ∧ b # q) ⇒ x # b)
     ∧ ((b # p ∧ q # c) ⇒ x # p)))
BY
{ ((Assert (s * u) = (s - v) BY
          (nRNorm (-2) THEN nRAdd ⌜(s * u) - v⌝ (-2)⋅ THEN nRNorm 0 THEN Auto))
   THEN (Assert (t * v) = (t - u) BY
               (nRNorm (-2) THEN nRAdd ⌜(t * v) - u⌝ (-2)⋅ THEN nRNorm 0 THEN Auto))
   THEN (Assert ((r1 - u) * (r1 - s)) = ((r1 - v) * (r1 - t)) BY

               ((nRNorm 0 THENA Auto) THEN (RWO "-2 -1" 0 THEN Auto) THEN nRNorm 0 THEN Auto))) }

1
1. rv : InnerProductSpace
2. a : Point
3. b : Point
4. c : Point
5. p : Point
6. q : Point
7. a # p
8. b # c
9. a # c
10. t : ℝ
11. r0 ≤ t
12. t ≤ r1
13. q ≡ t*b + r1 - t*c
14. s : ℝ
15. r0 ≤ s
16. s ≤ r1
17. p ≡ s*a + r1 - s*c
18. s < r1
19. r0 < (r1 - s * t)
20. u : ℝ
21. (t - s * t/r1 - s * t) = u ∈ ℝ
22. v : ℝ
23. (s - s * t/r1 - s * t) = v ∈ ℝ
24. ((r1 - u) * s) = v
25. ((r1 - v) * t) = u
26. (s * u) = (s - v)
27. (t * v) = (t - u)
28. ((r1 - u) * (r1 - s)) = ((r1 - v) * (r1 - t))
⊢ (u ∈ [r0, r1])
⇒ (v ∈ [r0, r1))
⇒ (∃x:Point
     (a_x_q
     ∧ b_x_p
     ∧ (a # q ⇒ x # a)
     ∧ ((a # q ∧ p # c ∧ b # q) ⇒ x # q)
     ∧ ((b # p ∧ b # q) ⇒ x # b)
     ∧ ((b # p ∧ q # c) ⇒ x # p)))

Latex:

Latex:
1. rv : InnerProductSpace 2. a : Point 3. b : Point 4. c : Point 5. p : Point 6. q : Point 7. a \# p 8. b \# c 9. a \# c 10. t : \mBbbR{} 11. r0 \mleq{} t 12. t \mleq{} r1 13. q \mequiv{} t*b + r1 - t*c 14. s : \mBbbR{} 15. r0 \mleq{} s 16. s \mleq{} r1 17. p \mequiv{} s*a + r1 - s*c 18. s < r1 19. r0 < (r1 - s * t) 20. u : \mBbbR{} 21. (t - s * t/r1 - s * t) = u 22. v : \mBbbR{} 23. (s - s * t/r1 - s * t) = v 24. ((r1 - u) * s) = v 25. ((r1 - v) * t) = u \mvdash{} (u \mmember{} [r0, r1]) {}\mRightarrow{} (v \mmember{} [r0, r1)) {}\mRightarrow{} (\mexists{}x:Point (a\_x\_q \mwedge{} b\_x\_p \mwedge{} (a \# q {}\mRightarrow{} x \# a) \mwedge{} ((a \# q \mwedge{} p \# c \mwedge{} b \# q) {}\mRightarrow{} x \# q) \mwedge{} ((b \# p \mwedge{} b \# q) {}\mRightarrow{} x \# b) \mwedge{} ((b \# p \mwedge{} q \# c) {}\mRightarrow{} x \# p))) By Latex: ((Assert (s * u) = (s - v) BY (nRNorm (-2) THEN nRAdd \mkleeneopen{}(s * u) - v\mkleeneclose{} (-2)\mcdot{} THEN nRNorm 0 THEN Auto)) THEN (Assert (t * v) = (t - u) BY (nRNorm (-2) THEN nRAdd \mkleeneopen{}(t * v) - u\mkleeneclose{} (-2)\mcdot{} THEN nRNorm 0 THEN Auto)) THEN (Assert ((r1 - u) * (r1 - s)) = ((r1 - v) * (r1 - t)) BY ((nRNorm 0 THENA Auto) THEN (RWO "-2 -1" 0 THEN Auto) THEN nRNorm 0 THEN Auto))) Home Index