Proof of Nuprl Lemma : finite-acyclic-rel

Step * 1 1 1 2 1 1 1 1 1 of Lemma finite-acyclic-rel

.....assertion.....
1. T : Type
2. R : T ⟶ T ⟶ ℙ
3. ∀x,y:T.  Dec(x R y)
4. m : ℤ
5. 0 < m
6. ∀[T':Type]. ((T' ⊆r T) ⇒ T' ~ ℕm - 1 ⇒ acyclic-rel(T';R) ⇒ SWellFounded(x R y))
7. T' : Type
8. T' ⊆r T
9. f : T' ⟶ ℕm
10. Bij(T';ℕm;f)
11. ∀x:T'. (¬(x R⁺ x))
12. g : ℕm ⟶ T'
13. ∀b:ℕm. ((f (g b)) = b ∈ ℕm)
14. ∀a:T'. ((g (f a)) = a ∈ T')
15. x : ℕm
16. x λi,j. ((g i) R (g j))⁺ x
⊢ ∀x,y:ℕm.  ((x λi,j. ((g i) R (g j))⁺ y) ⇒ ((g x) R⁺ (g y)))
BY
{ ThinVar `x' }

1
1. T : Type
2. R : T ⟶ T ⟶ ℙ
3. ∀x,y:T.  Dec(x R y)
4. m : ℤ
5. 0 < m
6. ∀[T':Type]. ((T' ⊆r T) ⇒ T' ~ ℕm - 1 ⇒ acyclic-rel(T';R) ⇒ SWellFounded(x R y))
7. T' : Type
8. T' ⊆r T
9. f : T' ⟶ ℕm
10. Bij(T';ℕm;f)
11. ∀x:T'. (¬(x R⁺ x))
12. g : ℕm ⟶ T'
13. ∀b:ℕm. ((f (g b)) = b ∈ ℕm)
14. ∀a:T'. ((g (f a)) = a ∈ T')
⊢ ∀x,y:ℕm.  ((x λi,j. ((g i) R (g j))⁺ y) ⇒ ((g x) R⁺ (g y)))

Latex:

Latex:
.....assertion..... 1. T : Type 2. R : T {}\mrightarrow{} T {}\mrightarrow{} \mBbbP{} 3. \mforall{}x,y:T. Dec(x R y) 4. m : \mBbbZ{} 5. 0 < m 6. \mforall{}[T':Type]. ((T' \msubseteq{}r T) {}\mRightarrow{} T' \msim{} \mBbbN{}m - 1 {}\mRightarrow{} acyclic-rel(T';R) {}\mRightarrow{} SWellFounded(x R y)) 7. T' : Type 8. T' \msubseteq{}r T 9. f : T' {}\mrightarrow{} \mBbbN{}m 10. Bij(T';\mBbbN{}m;f) 11. \mforall{}x:T'. (\mneg{}(x R\msupplus{} x)) 12. g : \mBbbN{}m {}\mrightarrow{} T' 13. \mforall{}b:\mBbbN{}m. ((f (g b)) = b) 14. \mforall{}a:T'. ((g (f a)) = a) 15. x : \mBbbN{}m 16. x \mlambda{}i,j. ((g i) R (g j))\msupplus{} x \mvdash{} \mforall{}x,y:\mBbbN{}m. ((x \mlambda{}i,j. ((g i) R (g j))\msupplus{} y) {}\mRightarrow{} ((g x) R\msupplus{} (g y))) By Latex: ThinVar `x' Home Index