Proof of Nuprl Lemma : tarski-erect-perp-or

Step * 1 1 of Lemma tarski-erect-perp-or

1. e : HeytingGeometry
2. a : Point
3. b : Point
4. c : Point
5. c # ba
6. x : Point
7. Colinear(a;b;x)
8. ab ⊥x cx
9. Colinear(a;b;x)
10. Colinear(c;x;x)
11. ∀u,v:Point. (Colinear(a;b;u) ⇒ Colinear(c;x;v) ⇒ Ruxv)
12. Raxc
13. Rbxc
⊢ ∃p,t:Point. (((ab ⊥ pa ∨ ab ⊥ pb) ∧ Colinear(a;b;t)) ∧ p-t-c)
BY

{ ((Duplicate 5 THEN (Assert c ≠ x BY (InstLemma `lsep-colinear-sep` [⌜e⌝;⌜c⌝;⌜b⌝;⌜a⌝;⌜x⌝]⋅ THEN Auto)))

   THEN (gProperProlong ⌜c⌝⌜x⌝`c\''⌜c⌝⌜x⌝⋅ THENA Auto)
   ) }

1
1. e : HeytingGeometry
2. a : Point
3. b : Point
4. c : Point
5. c # ba
6. x : Point
7. Colinear(a;b;x)
8. ab  ⊥x cx
9. Colinear(a;b;x)
10. Colinear(c;x;x)
11. ∀u,v:Point.  (Colinear(a;b;u) ⇒ Colinear(c;x;v) ⇒ Ruxv)
12. Raxc
13. Rbxc
14. c # ba
15. c ≠ x
16. c' : Point
17. c-x-c' ∧ xc' ≅ cx
⊢ ∃p,t:Point. (((ab ⊥ pa ∨ ab ⊥ pb) ∧ Colinear(a;b;t)) ∧ p-t-c)

Latex:

Latex:
1. e : HeytingGeometry 2. a : Point 3. b : Point 4. c : Point 5. c \# ba 6. x : Point 7. Colinear(a;b;x) 8. ab \mbot{}x cx 9. Colinear(a;b;x) 10. Colinear(c;x;x) 11. \mforall{}u,v:Point. (Colinear(a;b;u) {}\mRightarrow{} Colinear(c;x;v) {}\mRightarrow{} Ruxv) 12. Raxc 13. Rbxc \mvdash{} \mexists{}p,t:Point. (((ab \mbot{} pa \mvee{} ab \mbot{} pb) \mwedge{} Colinear(a;b;t)) \mwedge{} p-t-c) By Latex: ((Duplicate 5 THEN (Assert c \mneq{} x BY (InstLemma `lsep-colinear-sep` [\mkleeneopen{}e\mkleeneclose{};\mkleeneopen{}c\mkleeneclose{};\mkleeneopen{}b\mkleeneclose{};\mkleeneopen{}a\mkleeneclose{};\mkleeneopen{}x\mkleeneclose{}]\mcdot{} THEN Auto)) ) THEN (gProperProlong \mkleeneopen{}c\mkleeneclose{}\mkleeneopen{}x\mkleeneclose{}`c\mbackslash{}''\mkleeneopen{}c\mkleeneclose{}\mkleeneopen{}x\mkleeneclose{}\mcdot{} THENA Auto) ) Home Index