Proof of Nuprl Lemma : stream-lex

Step * 2 1 2 of Lemma stream-lex_transitivity-proof2

1. T : Type
2. R : T ⟶ T ⟶ ℙ
3. Trans(T;x,y.x R y)
4. AntiSym(T;x,y.x R y)
5. ∀R':stream(T) ⟶ stream(T) ⟶ ℙ
(R' => λs1,s2. ((s-hd(s1) R s-hd(s2)) ∧ ((s-hd(s1) = s-hd(s2) ∈ T) ⇒ (s-tl(s1) R' s-tl(s2)))) ⇒ R' => stream-lex(\000CT;R))
6. x : stream(T)
7. y : stream(T)
8. s : stream(T)
9. x stream-lex(T;R) s
10. s stream-lex(T;R) y
11. s-hd(x) R s-hd(y)
12. s-hd(x) = s-hd(y) ∈ T
⊢ ∃s:stream(T). ((s-tl(x) stream-lex(T;R) s) ∧ (s stream-lex(T;R) s-tl(y)))
BY
{ (Thin (-2) THEN ((RWO "stream-lex-iff" (-3) THENA Auto) THEN RWO "stream-lex-iff" (-2) THEN Auto)⋅) }

1
1. T : Type
2. R : T ⟶ T ⟶ ℙ
3. Trans(T;x,y.x R y)
4. AntiSym(T;x,y.x R y)
5. ∀R':stream(T) ⟶ stream(T) ⟶ ℙ
(R' => λs1,s2. ((s-hd(s1) R s-hd(s2)) ∧ ((s-hd(s1) = s-hd(s2) ∈ T) ⇒ (s-tl(s1) R' s-tl(s2)))) ⇒ R' => stream-lex(\000CT;R))
6. x : stream(T)
7. y : stream(T)
8. s : stream(T)
9. s-hd(x) R s-hd(s)
10. (s-hd(x) = s-hd(s) ∈ T) ⇒ (s-tl(x) stream-lex(T;R) s-tl(s))
11. s-hd(s) R s-hd(y)
12. (s-hd(s) = s-hd(y) ∈ T) ⇒ (s-tl(s) stream-lex(T;R) s-tl(y))
13. s-hd(x) = s-hd(y) ∈ T
⊢ ∃s:stream(T). ((s-tl(x) stream-lex(T;R) s) ∧ (s stream-lex(T;R) s-tl(y)))

Latex:

Latex:
1. T : Type 2. R : T {}\mrightarrow{} T {}\mrightarrow{} \mBbbP{} 3. Trans(T;x,y.x R y) 4. AntiSym(T;x,y.x R y) 5. \mforall{}R':stream(T) {}\mrightarrow{} stream(T) {}\mrightarrow{} \mBbbP{} (R' => \mlambda{}s1,s2. ((s-hd(s1) R s-hd(s2)) \mwedge{} ((s-hd(s1) = s-hd(s2)) {}\mRightarrow{} (s-tl(s1) R' s-tl(s2)))) {}\mRightarrow{} R' => stream-lex(T;R)) 6. x : stream(T) 7. y : stream(T) 8. s : stream(T) 9. x stream-lex(T;R) s 10. s stream-lex(T;R) y 11. s-hd(x) R s-hd(y) 12. s-hd(x) = s-hd(y) \mvdash{} \mexists{}s:stream(T). ((s-tl(x) stream-lex(T;R) s) \mwedge{} (s stream-lex(T;R) s-tl(y))) By Latex: (Thin (-2) THEN ((RWO "stream-lex-iff" (-3) THENA Auto) THEN RWO "stream-lex-iff" (-2) THEN Auto)\mcdot{}) Home Index