Proof of Nuprl Lemma : non-forking-wellfounded-linorder

Step * 1 1 1 1 1 1 of Lemma non-forking-wellfounded-linorder

.....equality.....
1. T : Type
2. R : T ⟶ T ⟶ ℙ
3. decidable-non-minimal(T;x,y.R[x;y])
4. WellFnd{i}(T;x,y.R[x;y])
5. m : T
6. unique-minimal(T;x,y.R[x;y];m)
7. non-forking(T;x,y.R[x;y])
8. ∀y:T. (↓∃n:ℕ. (m λx,y. R[x;y]^n y))
9. Order(T;x,y.∃n:ℕ. (x R^n y))
10. x : T
11. y : T
12. n1 : ℕ
13. m R^n1 x
14. n : ℕ
15. m R^n y
16. n1 < n
17. (m R^n1 + (n - n1) y) ⇐ ∃y@0:T. ((m R^n1 y@0) ∧ (y@0 R^n - n1 y))
18. z : T
19. m R^n1 z
20. z R^n - n1 y
⊢ z = x ∈ T
BY
{ xxx(Assert ⌜non-forking(T;x,y.x R^n1 y)⌝⋅ THEN Auto)xxx }

1
.....assertion.....
1. T : Type
2. R : T ⟶ T ⟶ ℙ
3. decidable-non-minimal(T;x,y.R[x;y])
4. WellFnd{i}(T;x,y.R[x;y])
5. m : T
6. unique-minimal(T;x,y.R[x;y];m)
7. non-forking(T;x,y.R[x;y])
8. ∀y:T. (↓∃n:ℕ. (m λx,y. R[x;y]^n y))
9. Order(T;x,y.∃n:ℕ. (x R^n y))
10. x : T
11. y : T
12. n1 : ℕ
13. m R^n1 x
14. n : ℕ
15. m R^n y
16. n1 < n
17. (m R^n1 + (n - n1) y) ⇐ ∃y@0:T. ((m R^n1 y@0) ∧ (y@0 R^n - n1 y))
18. z : T
19. m R^n1 z
20. z R^n - n1 y
⊢ non-forking(T;x,y.x R^n1 y)

Latex:

Latex:
.....equality..... 1. T : Type 2. R : T {}\mrightarrow{} T {}\mrightarrow{} \mBbbP{} 3. decidable-non-minimal(T;x,y.R[x;y]) 4. WellFnd\{i\}(T;x,y.R[x;y]) 5. m : T 6. unique-minimal(T;x,y.R[x;y];m) 7. non-forking(T;x,y.R[x;y]) 8. \mforall{}y:T. (\mdownarrow{}\mexists{}n:\mBbbN{}. (m rel\_exp(T; \mlambda{}x,y. R[x;y]; n) y)) 9. Order(T;x,y.\mexists{}n:\mBbbN{}. (x rel\_exp(T; R; n) y)) 10. x : T 11. y : T 12. n1 : \mBbbN{} 13. m rel\_exp(T; R; n1) x 14. n : \mBbbN{} 15. m rel\_exp(T; R; n) y 16. n1 < n 17. (m rel\_exp(T; R; n1 + (n - n1)) y) \mLeftarrow{}{} \mexists{}y@0:T ((m R\^{}n1 y@0) \mwedge{} (y@0 R\^{}n - n1 y)) 18. z : T 19. m rel\_exp(T; R; n1) z 20. z rel\_exp(T; R; n - n1) y \mvdash{} z = x By Latex: xxx(Assert \mkleeneopen{}non-forking(T;x,y.x rel\_exp(T; R; n1) y)\mkleeneclose{}\mcdot{} THEN Auto)xxx Home Index