Proof of Nuprl Lemma : vdf-wf+

Step * 2 2 of Lemma vdf-wf+

1. A : Type
2. B : Type
3. C : A ⟶ B ⟶ Type
4. n : ℤ
5. 0 < n
6. vdf(A;B;a,b.C[a;b];n - 1) ∈ Type
7. ∀f:vdf(A;B;a,b.C[a;b];n - 1). ∀L:(a:A × b:B × C[a;b]) List.
((||L|| ≤ ((n - 1) + 1))
⇒

 ((vdf-eq(A;f;L) ∈ ℙ) ∧ (vdf-eq(A;f;L) ⊆r (∀[i:ℕ||L||]. ((fst(L[i])) = (f firstn(i;L) (fst(snd(L[i])))) ∈ A)))))

8. vdf(A;B;a,b.C[a;b];n) ∈ Type
9. f : vdf(A;B;a,b.C[a;b];n)
10. L : (a:A × b:B × C[a;b]) List
11. ||L|| ≤ (n + 1)

⊢ (vdf-eq(A;f;L) ∈ ℙ) ∧ (vdf-eq(A;f;L) ⊆r (∀[i:ℕ||L||]. ((fst(L[i])) = (f firstn(i;L) (fst(snd(L[i])))) ∈ A)))

BY
{ Assert ⌜∀m:ℕ
(m < ||L||
⇒ (dep-all(m;i.let a,b,c = firstn(||L|| - 1;L)[i] in

               a = (f firstn(i;firstn(||L|| - 1;L)) b) ∈ A) ~ dep-all(m;i.let a,b,c = L[i] in

               a = (f firstn(i;L) b) ∈ A)))⌝⋅ }

1
.....assertion.....
1. A : Type
2. B : Type
3. C : A ⟶ B ⟶ Type
4. n : ℤ
5. 0 < n
6. vdf(A;B;a,b.C[a;b];n - 1) ∈ Type
7. ∀f:vdf(A;B;a,b.C[a;b];n - 1). ∀L:(a:A × b:B × C[a;b]) List.
     ((||L|| ≤ ((n - 1) + 1))
     ⇒

 ((vdf-eq(A;f;L) ∈ ℙ) ∧ (vdf-eq(A;f;L) ⊆r (∀[i:ℕ||L||]. ((fst(L[i])) = (f firstn(i;L) (fst(snd(L[i])))) ∈ A)))))

8. vdf(A;B;a,b.C[a;b];n) ∈ Type
9. f : vdf(A;B;a,b.C[a;b];n)
10. L : (a:A × b:B × C[a;b]) List
11. ||L|| ≤ (n + 1)
⊢ ∀m:ℕ
    (m < ||L||
    ⇒ (dep-all(m;i.let a,b,c = firstn(||L|| - 1;L)[i] in
       a = (f firstn(i;firstn(||L|| - 1;L)) b) ∈ A) ~ dep-all(m;i.let a,b,c = L[i] in
       a = (f firstn(i;L) b) ∈ A)))

2
1. A : Type
2. B : Type
3. C : A ⟶ B ⟶ Type
4. n : ℤ
5. 0 < n
6. vdf(A;B;a,b.C[a;b];n - 1) ∈ Type
7. ∀f:vdf(A;B;a,b.C[a;b];n - 1). ∀L:(a:A × b:B × C[a;b]) List.
     ((||L|| ≤ ((n - 1) + 1))
     ⇒

 ((vdf-eq(A;f;L) ∈ ℙ) ∧ (vdf-eq(A;f;L) ⊆r (∀[i:ℕ||L||]. ((fst(L[i])) = (f firstn(i;L) (fst(snd(L[i])))) ∈ A)))))

8. vdf(A;B;a,b.C[a;b];n) ∈ Type
9. f : vdf(A;B;a,b.C[a;b];n)
10. L : (a:A × b:B × C[a;b]) List
11. ||L|| ≤ (n + 1)
12. ∀m:ℕ
      (m < ||L||
      ⇒ (dep-all(m;i.let a,b,c = firstn(||L|| - 1;L)[i] in
         a = (f firstn(i;firstn(||L|| - 1;L)) b) ∈ A) ~ dep-all(m;i.let a,b,c = L[i] in
         a = (f firstn(i;L) b) ∈ A)))

⊢ (vdf-eq(A;f;L) ∈ ℙ) ∧ (vdf-eq(A;f;L) ⊆r (∀[i:ℕ||L||]. ((fst(L[i])) = (f firstn(i;L) (fst(snd(L[i])))) ∈ A)))

Latex:

Latex:
1. A : Type 2. B : Type 3. C : A {}\mrightarrow{} B {}\mrightarrow{} Type 4. n : \mBbbZ{} 5. 0 < n 6. vdf(A;B;a,b.C[a;b];n - 1) \mmember{} Type 7. \mforall{}f:vdf(A;B;a,b.C[a;b];n - 1). \mforall{}L:(a:A \mtimes{} b:B \mtimes{} C[a;b]) List. ((||L|| \mleq{} ((n - 1) + 1)) {}\mRightarrow{} ((vdf-eq(A;f;L) \mmember{} \mBbbP{}) \mwedge{} (vdf-eq(A;f;L) \msubseteq{}r (\mforall{}[i:\mBbbN{}||L||]. ((fst(L[i])) = (f firstn(i;L) (fst(snd(L[i]))))))))) 8. vdf(A;B;a,b.C[a;b];n) \mmember{} Type 9. f : vdf(A;B;a,b.C[a;b];n) 10. L : (a:A \mtimes{} b:B \mtimes{} C[a;b]) List 11. ||L|| \mleq{} (n + 1) \mvdash{} (vdf-eq(A;f;L) \mmember{} \mBbbP{}) \mwedge{} (vdf-eq(A;f;L) \msubseteq{}r (\mforall{}[i:\mBbbN{}||L||]. ((fst(L[i])) = (f firstn(i;L) (fst(snd(L[i]))))))) By Latex: Assert \mkleeneopen{}\mforall{}m:\mBbbN{} (m < ||L|| {}\mRightarrow{} (dep-all(m;i.let a,b,c = firstn(||L|| - 1;L)[i] in a = (f firstn(i;firstn(||L|| - 1;L)) b)) \msim{} dep-all(m;i.let a,b,c = L[i] in a = (f firstn(i;L) b))))\mkleeneclose{}\mcdot{} Home Index