Proof of Nuprl Lemma : tree-flow-convergent

Step * 1 2 1 of Lemma tree-flow-convergent

1. Info : Type
2. es : EO+(Info)
3. X : EClass(Top)
4. f : E(X) ─→ E(X)
5. ∀x,y:E(X).  ((¬((f x) = x ∈ E(X))) ⇒ (¬((f y) = y ∈ E(X))) ⇒ (loc(f x) = loc(f y) ∈ Id) ⇒ (loc(x) = loc(y) ∈ Id))
6. R : Id ─→ Id ─→ ℙ
7. Trans(Id;i,j.R[i;j])
8. Irrefl(Id;i,j.R[i;j])
9. ∀x:E(X). ((¬((f x) = x ∈ E)) ⇒ R[loc(f x);loc(x)])
10. a : E(X)@i
11. a' : E(X)@i
12. z : E(X)@i
13. a = (f a') ∈ E(X)
14. ¬(a = a' ∈ E(X))
15. a' is f*(z)@i
16. (¬(a' = z ∈ E)) ⇒ R[loc(a');loc(z)]@i
17. ¬(a = z ∈ E)@i
⊢ R[loc(a);loc(z)]
BY
{ (Assert R[loc(f a');loc(a')] BY
         Auto) }

1
1. Info : Type
2. es : EO+(Info)
3. X : EClass(Top)
4. f : E(X) ─→ E(X)
5. ∀x,y:E(X).  ((¬((f x) = x ∈ E(X))) ⇒ (¬((f y) = y ∈ E(X))) ⇒ (loc(f x) = loc(f y) ∈ Id) ⇒ (loc(x) = loc(y) ∈ Id))
6. R : Id ─→ Id ─→ ℙ
7. Trans(Id;i,j.R[i;j])
8. Irrefl(Id;i,j.R[i;j])
9. ∀x:E(X). ((¬((f x) = x ∈ E)) ⇒ R[loc(f x);loc(x)])
10. a : E(X)@i
11. a' : E(X)@i
12. z : E(X)@i
13. a = (f a') ∈ E(X)
14. ¬(a = a' ∈ E(X))
15. a' is f*(z)@i
16. (¬(a' = z ∈ E)) ⇒ R[loc(a');loc(z)]@i
17. ¬(a = z ∈ E)@i
18. R[loc(f a');loc(a')]
⊢ R[loc(a);loc(z)]

Latex:

1. Info : Type 2. es : EO+(Info) 3. X : EClass(Top) 4. f : E(X) {}\mrightarrow{} E(X) 5. \mforall{}x,y:E(X). ((\mneg{}((f x) = x)) {}\mRightarrow{} (\mneg{}((f y) = y)) {}\mRightarrow{} (loc(f x) = loc(f y)) {}\mRightarrow{} (loc(x) = loc(y))) 6. R : Id {}\mrightarrow{} Id {}\mrightarrow{} \mBbbP{} 7. Trans(Id;i,j.R[i;j]) 8. Irrefl(Id;i,j.R[i;j]) 9. \mforall{}x:E(X). ((\mneg{}((f x) = x)) {}\mRightarrow{} R[loc(f x);loc(x)]) 10. a : E(X)@i 11. a' : E(X)@i 12. z : E(X)@i 13. a = (f a') 14. \mneg{}(a = a') 15. a' is f*(z)@i 16. (\mneg{}(a' = z)) {}\mRightarrow{} R[loc(a');loc(z)]@i 17. \mneg{}(a = z)@i \mvdash{} R[loc(a);loc(z)] By (Assert R[loc(f a');loc(a')] BY Auto) Home Index