Proof of Nuprl Lemma : stream-lex-monotonic

Step * 1 1 1 2 1 1 1 of Lemma stream-lex-monotonic

1. T : Type
2. ∀x,y:T.  Dec(x = y ∈ T)
3. R : T ⟶ T ⟶ ℙ
4. Trans(T;x,y.x R y)
5. AntiSym(T;x,y.x R y)
6. f : T ⟶ T ⟶ T
7. ∀x,y,u,v:T.  ((x R y) ⇒ (u R v) ⇒ ((f x u) R (f y v)))
8. ∀x,y,u,v:T.  ((x R y) ⇒ (u R v) ⇒ (¬((x = y ∈ T) ∧ (u = v ∈ T))) ⇒ (¬((f x u) = (f y v) ∈ T)))
9. x : stream(T)
10. y : stream(T)
11. a : stream(T)
12. b : stream(T)
13. c : stream(T)
14. stream-zip(f;a;c) ∈ stream(T)
15. d : stream(T)
16. stream-zip(f;b;d) ∈ stream(T)
17. s-hd(a) R s-hd(b)
18. (s-hd(a) = s-hd(b) ∈ T) ⇒ (s-tl(a) stream-lex(T;R) s-tl(b))
19. s-hd(c) R s-hd(d)
20. (f s-hd(a) s-hd(c)) = (f s-hd(b) s-hd(d)) ∈ T
21. s-tl(c) stream-lex(T;R) s-tl(d)
⊢ ∃a@0,b@0,c@0,d@0:stream(T)
   ((s-tl(stream-zip(f;a;c)) = stream-zip(f;a@0;c@0) ∈ stream(T))
   ∧ (s-tl(stream-zip(f;b;d)) = stream-zip(f;b@0;d@0) ∈ stream(T))
   ∧ (a@0 stream-lex(T;R) b@0)
   ∧ (c@0 stream-lex(T;R) d@0))
BY
{ (D (-4)
   THENA (SupposeNot
          THEN Assert ⌜¬((f s-hd(a) s-hd(c)) = (f s-hd(b) s-hd(d)) ∈ T)⌝⋅
          THEN Auto
          THEN (BackThruSomeHyp THEN Auto)
          THEN D 0
          THEN Auto)
   )⋅ }

1
1. T : Type
2. ∀x,y:T.  Dec(x = y ∈ T)
3. R : T ⟶ T ⟶ ℙ
4. Trans(T;x,y.x R y)
5. AntiSym(T;x,y.x R y)
6. f : T ⟶ T ⟶ T
7. ∀x,y,u,v:T.  ((x R y) ⇒ (u R v) ⇒ ((f x u) R (f y v)))
8. ∀x,y,u,v:T.  ((x R y) ⇒ (u R v) ⇒ (¬((x = y ∈ T) ∧ (u = v ∈ T))) ⇒ (¬((f x u) = (f y v) ∈ T)))
9. x : stream(T)
10. y : stream(T)
11. a : stream(T)
12. b : stream(T)
13. c : stream(T)
14. stream-zip(f;a;c) ∈ stream(T)
15. d : stream(T)
16. stream-zip(f;b;d) ∈ stream(T)
17. s-hd(a) R s-hd(b)
18. s-hd(c) R s-hd(d)
19. (f s-hd(a) s-hd(c)) = (f s-hd(b) s-hd(d)) ∈ T
20. s-tl(c) stream-lex(T;R) s-tl(d)
21. s-tl(a) stream-lex(T;R) s-tl(b)
⊢ ∃a@0,b@0,c@0,d@0:stream(T)
   ((s-tl(stream-zip(f;a;c)) = stream-zip(f;a@0;c@0) ∈ stream(T))
   ∧ (s-tl(stream-zip(f;b;d)) = stream-zip(f;b@0;d@0) ∈ stream(T))
   ∧ (a@0 stream-lex(T;R) b@0)
   ∧ (c@0 stream-lex(T;R) d@0))

Latex:

Latex:
1. T : Type 2. \mforall{}x,y:T. Dec(x = y) 3. R : T {}\mrightarrow{} T {}\mrightarrow{} \mBbbP{} 4. Trans(T;x,y.x R y) 5. AntiSym(T;x,y.x R y) 6. f : T {}\mrightarrow{} T {}\mrightarrow{} T 7. \mforall{}x,y,u,v:T. ((x R y) {}\mRightarrow{} (u R v) {}\mRightarrow{} ((f x u) R (f y v))) 8. \mforall{}x,y,u,v:T. ((x R y) {}\mRightarrow{} (u R v) {}\mRightarrow{} (\mneg{}((x = y) \mwedge{} (u = v))) {}\mRightarrow{} (\mneg{}((f x u) = (f y v)))) 9. x : stream(T) 10. y : stream(T) 11. a : stream(T) 12. b : stream(T) 13. c : stream(T) 14. stream-zip(f;a;c) \mmember{} stream(T) 15. d : stream(T) 16. stream-zip(f;b;d) \mmember{} stream(T) 17. s-hd(a) R s-hd(b) 18. (s-hd(a) = s-hd(b)) {}\mRightarrow{} (s-tl(a) stream-lex(T;R) s-tl(b)) 19. s-hd(c) R s-hd(d) 20. (f s-hd(a) s-hd(c)) = (f s-hd(b) s-hd(d)) 21. s-tl(c) stream-lex(T;R) s-tl(d) \mvdash{} \mexists{}a@0,b@0,c@0,d@0:stream(T) ((s-tl(stream-zip(f;a;c)) = stream-zip(f;a@0;c@0)) \mwedge{} (s-tl(stream-zip(f;b;d)) = stream-zip(f;b@0;d@0)) \mwedge{} (a@0 stream-lex(T;R) b@0) \mwedge{} (c@0 stream-lex(T;R) d@0)) By Latex: (D (-4) THENA (SupposeNot THEN Assert \mkleeneopen{}\mneg{}((f s-hd(a) s-hd(c)) = (f s-hd(b) s-hd(d)))\mkleeneclose{}\mcdot{} THEN Auto THEN (BackThruSomeHyp THEN Auto) THEN D 0 THEN Auto) )\mcdot{} Home Index