Proof of Nuprl Lemma : AX3

Step * 1 of Lemma AX3

1. e : EuclideanParPlane@i'
2. l2 : Line@i
3. p1 : Point@i
4. l4 : n:{n:Line| p1 I n}  × p1 # l2@i
5. l1 : Line@i
6. p : Point@i
7. m2 : n:{n:Line| p I n}  × p # l1@i
8. p2 : Point@i
9. l : Line@i
10. n : Line@i
11. P3 : p2 I n ∧ p2 # l@i
12. ¬P_point-line-sep(e;<p2, l, n, P3>;<l2, p1, l4>)
13. P_point-line-sep(e;<p2, l, n, P3>;<l1, p, m2>)
14. ∀l,m,n:Line.  (l \/ m ⇒ (l \/ n ∨ m \/ n))
⊢ ∃P:P_point(e). ((¬P_point-line-sep(e;P;<l2, p1, l4>)) ∧ (¬P_point-line-sep(e;P;<l1, p, m2>)))
BY
{ (RepUR ``P_point-line-sep`` -2 THEN RepUR ``P_point-line-sep`` -3) }

1
1. e : EuclideanParPlane@i'
2. l2 : Line@i
3. p1 : Point@i
4. l4 : n:{n:Line| p1 I n}  × p1 # l2@i
5. l1 : Line@i
6. p : Point@i
7. m2 : n:{n:Line| p I n}  × p # l1@i
8. p2 : Point@i
9. l : Line@i
10. n : Line@i
11. P3 : p2 I n ∧ p2 # l@i
12. ¬((l \/ l2 ∨ n \/ l2) ∧ (∀x:{x:Point| x I l ∧ x I n} . x # l2))
13. (l \/ l1 ∨ n \/ l1) ∧ (∀x:{x:Point| x I l ∧ x I n} . x # l1)
14. ∀l,m,n:Line.  (l \/ m ⇒ (l \/ n ∨ m \/ n))
⊢ ∃P:P_point(e). ((¬P_point-line-sep(e;P;<l2, p1, l4>)) ∧ (¬P_point-line-sep(e;P;<l1, p, m2>)))

Latex:

Latex:
1. e : EuclideanParPlane@i' 2. l2 : Line@i 3. p1 : Point@i 4. l4 : n:\{n:Line| p1 I n\} \mtimes{} p1 \# l2@i 5. l1 : Line@i 6. p : Point@i 7. m2 : n:\{n:Line| p I n\} \mtimes{} p \# l1@i 8. p2 : Point@i 9. l : Line@i 10. n : Line@i 11. P3 : p2 I n \mwedge{} p2 \# l@i 12. \mneg{}P\_point-line-sep(e;<p2, l, n, P3><l2, p1, l4>) 13. P\_point-line-sep(e;<p2, l, n, P3><l1, p, m2>) 14. \mforall{}l,m,n:Line. (l \mbackslash{}/ m {}\mRightarrow{} (l \mbackslash{}/ n \mvee{} m \mbackslash{}/ n)) \mvdash{} \mexists{}P:P\_point(e). ((\mneg{}P\_point-line-sep(e;P;<l2, p1, l4>)) \mwedge{} (\mneg{}P\_point-line-sep(e;P;<l1, p, m2>))) By Latex: (RepUR ``P\_point-line-sep`` -2 THEN RepUR ``P\_point-line-sep`` -3) Home Index