Proof of Nuprl Lemma : eu-colinear-cons

Step * 4 2 1 of Lemma eu-colinear-cons

1. e : EuclideanPlane
2. L : Point List
3. A : Point
4. ∀A:Point. ((A ∈ L) ⇒ (∀B∈L.(∀C∈L.(¬(A = B ∈ Point)) ⇒ Colinear(A;B;C))))
5. (∀B∈L.(∀C∈L.(¬(A = B ∈ Point)) ⇒ Colinear(A;B;C)))
6. A@0 : Point
7. (A@0 ∈ L)
8. ∀B:Point. ((B ∈ L) ⇒ (∀C∈L.(¬(A@0 = B ∈ Point)) ⇒ Colinear(A@0;B;C)))
9. (∀C∈[A / L].(¬(A@0 = A ∈ Point)) ⇒ Colinear(A@0;A;C))
10. B : Point
11. (B ∈ L)
12. (∀C∈L.(¬(A@0 = B ∈ Point)) ⇒ Colinear(A@0;B;C))
⊢ (∀C∈[A / L].(¬(A@0 = B ∈ Point)) ⇒ Colinear(A@0;B;C))
BY
{ (RWO "l_all_cons" 0 THEN Auto) }

1
1. e : EuclideanPlane
2. L : Point List
3. A : Point
4. ∀A:Point. ((A ∈ L) ⇒ (∀B∈L.(∀C∈L.(¬(A = B ∈ Point)) ⇒ Colinear(A;B;C))))
5. (∀B∈L.(∀C∈L.(¬(A = B ∈ Point)) ⇒ Colinear(A;B;C)))
6. A@0 : Point
7. (A@0 ∈ L)
8. ∀B:Point. ((B ∈ L) ⇒ (∀C∈L.(¬(A@0 = B ∈ Point)) ⇒ Colinear(A@0;B;C)))
9. (∀C∈[A / L].(¬(A@0 = A ∈ Point)) ⇒ Colinear(A@0;A;C))
10. B : Point
11. (B ∈ L)
12. (∀C∈L.(¬(A@0 = B ∈ Point)) ⇒ Colinear(A@0;B;C))
13. ¬(A@0 = B ∈ Point)
⊢ Colinear(A@0;B;A)

Latex:

Latex:
1. e : EuclideanPlane 2. L : Point List 3. A : Point 4. \mforall{}A:Point. ((A \mmember{} L) {}\mRightarrow{} (\mforall{}B\mmember{}L.(\mforall{}C\mmember{}L.(\mneg{}(A = B)) {}\mRightarrow{} Colinear(A;B;C)))) 5. (\mforall{}B\mmember{}L.(\mforall{}C\mmember{}L.(\mneg{}(A = B)) {}\mRightarrow{} Colinear(A;B;C))) 6. A@0 : Point 7. (A@0 \mmember{} L) 8. \mforall{}B:Point. ((B \mmember{} L) {}\mRightarrow{} (\mforall{}C\mmember{}L.(\mneg{}(A@0 = B)) {}\mRightarrow{} Colinear(A@0;B;C))) 9. (\mforall{}C\mmember{}[A / L].(\mneg{}(A@0 = A)) {}\mRightarrow{} Colinear(A@0;A;C)) 10. B : Point 11. (B \mmember{} L) 12. (\mforall{}C\mmember{}L.(\mneg{}(A@0 = B)) {}\mRightarrow{} Colinear(A@0;B;C)) \mvdash{} (\mforall{}C\mmember{}[A / L].(\mneg{}(A@0 = B)) {}\mRightarrow{} Colinear(A@0;B;C)) By Latex: (RWO "l\_all\_cons" 0 THEN Auto) Home Index