Proof of Nuprl Lemma : strong-fun-connected-induction

Step * 1 1 2 1 2 1 of Lemma strong-fun-connected-induction

1. [T] : Type
2. f : T ⟶ T
3. [R] : T ⟶ T ⟶ ℙ
4. h : T ⟶ ℕ
5. ∀x:T. (((f x) = x ∈ T) ∨ h (f x) < h x)
6. ∀x:T. R[x;x]
7. ∀x,y,z:T.
     (y is f*(z) ⇒ (∀u:T. (y is f*(u) ⇒ u is f*(z) ⇒ R[u;z])) ⇒ R[x;z]) supposing
        ((¬(x = y ∈ T)) and
        (x = (f y) ∈ T))
8. n : ℤ
9. [%4] : 0 < n
10. ∀x,y:T.  (x is f*(y) ⇒ (h y) - h x < n - 1 ⇒ R[x;y])
11. x : T
12. y : T
13. z : T
14. x = (f y) ∈ T
15. ¬(x = y ∈ T)
16. y is f*(z)
17. (h z) - h y < n ⇒ R[y;z]
18. (h z) - h x < n
19. h x < h y
20. u : T
21. y is f*(u)
22. u is f*(z)
⊢ R[u;z]
BY
{ (BHyp 10 THEN Auto)⋅ }

1
1. T : Type
2. f : T ⟶ T
3. R : T ⟶ T ⟶ ℙ
4. h : T ⟶ ℕ
5. ∀x:T. (((f x) = x ∈ T) ∨ h (f x) < h x)
6. ∀x:T. R[x;x]
7. ∀x,y,z:T.
     (y is f*(z) ⇒ (∀u:T. (y is f*(u) ⇒ u is f*(z) ⇒ R[u;z])) ⇒ R[x;z]) supposing
        ((¬(x = y ∈ T)) and
        (x = (f y) ∈ T))
8. n : ℤ
9. 0 < n
10. ∀x,y:T.  (x is f*(y) ⇒ (h y) - h x < n - 1 ⇒ R[x;y])
11. x : T
12. y : T
13. z : T
14. x = (f y) ∈ T
15. ¬(x = y ∈ T)
16. y is f*(z)
17. (h z) - h y < n ⇒ R[y;z]
18. (h z) - h x < n
19. h x < h y
20. u : T
21. y is f*(u)
22. u is f*(z)
⊢ (h z) - h u < n - 1

Latex:

Latex:
1. [T] : Type 2. f : T {}\mrightarrow{} T 3. [R] : T {}\mrightarrow{} T {}\mrightarrow{} \mBbbP{} 4. h : T {}\mrightarrow{} \mBbbN{} 5. \mforall{}x:T. (((f x) = x) \mvee{} h (f x) < h x) 6. \mforall{}x:T. R[x;x] 7. \mforall{}x,y,z:T. (y is f*(z) {}\mRightarrow{} (\mforall{}u:T. (y is f*(u) {}\mRightarrow{} u is f*(z) {}\mRightarrow{} R[u;z])) {}\mRightarrow{} R[x;z]) supposing ((\mneg{}(x = y)) and (x = (f y))) 8. n : \mBbbZ{} 9. [\%4] : 0 < n 10. \mforall{}x,y:T. (x is f*(y) {}\mRightarrow{} (h y) - h x < n - 1 {}\mRightarrow{} R[x;y]) 11. x : T 12. y : T 13. z : T 14. x = (f y) 15. \mneg{}(x = y) 16. y is f*(z) 17. (h z) - h y < n {}\mRightarrow{} R[y;z] 18. (h z) - h x < n 19. h x < h y 20. u : T 21. y is f*(u) 22. u is f*(z) \mvdash{} R[u;z] By Latex: (BHyp 10 THEN Auto)\mcdot{} Home Index