Proof of Nuprl Lemma : parallelogram-construction2

Step * 1 1 of Lemma parallelogram-construction2

1. e : EuclideanPlane
2. a : Point
3. b : Point
4. c : Point
5. x : Point
6. y : Point
7. a # bc
8. a-x-b
9. a-y-c
10. a # xy
11. ∃m:Point. (x=m=y ∧ x # m)
⊢ ∃t:Point
   (geo-parallel-points(e;b;x;y;t)
   ∧ bx ≅ yt
   ∧ xt ≅ by
   ∧ xby ≅_a xty
   ∧ (¬¬((a leftof bc ⇒ (t leftof ac ∧ t leftof bc)) ∧ (a leftof cb ⇒ (t leftof ca ∧ t leftof cb)))))
BY
{ (ExRepD
   THEN (Assert b # m BY

               ((Assert a # xm BY Auto) THEN InstLemma  `out-preserves-lsep` [⌜e⌝;⌜a⌝;⌜x⌝;⌜m⌝;⌜b⌝;⌜m⌝]⋅ THEN EAuto 1))

   ) }

1
1. e : EuclideanPlane
2. a : Point
3. b : Point
4. c : Point
5. x : Point
6. y : Point
7. a # bc
8. a-x-b
9. a-y-c
10. a # xy
11. m : Point
12. x=m=y
13. x # m
14. b # m
⊢ ∃t:Point
   (geo-parallel-points(e;b;x;y;t)
   ∧ bx ≅ yt
   ∧ xt ≅ by
   ∧ xby ≅_a xty
   ∧ (¬¬((a leftof bc ⇒ (t leftof ac ∧ t leftof bc)) ∧ (a leftof cb ⇒ (t leftof ca ∧ t leftof cb)))))

Latex:

Latex:
1. e : EuclideanPlane 2. a : Point 3. b : Point 4. c : Point 5. x : Point 6. y : Point 7. a \# bc 8. a-x-b 9. a-y-c 10. a \# xy 11. \mexists{}m:Point. (x=m=y \mwedge{} x \# m) \mvdash{} \mexists{}t:Point (geo-parallel-points(e;b;x;y;t) \mwedge{} bx \mcong{} yt \mwedge{} xt \mcong{} by \mwedge{} xby \mcong{}\msuba{} xty \mwedge{} (\mneg{}\mneg{}((a leftof bc {}\mRightarrow{} (t leftof ac \mwedge{} t leftof bc)) \mwedge{} (a leftof cb {}\mRightarrow{} (t leftof ca \mwedge{} t leftof cb))))) By Latex: (ExRepD THEN (Assert b \# m BY ((Assert a \# xm BY Auto) THEN InstLemma `out-preserves-lsep` [\mkleeneopen{}e\mkleeneclose{};\mkleeneopen{}a\mkleeneclose{};\mkleeneopen{}x\mkleeneclose{};\mkleeneopen{}m\mkleeneclose{};\mkleeneopen{}b\mkleeneclose{};\mkleeneopen{}m\mkleeneclose{}]\mcdot{} THEN EAuto 1)) ) Home Index