Proof of Nuprl Lemma : equipollent-quotient

Step * 2 3 of Lemma equipollent-quotient

.....wf.....
1. A : Type
2. E : A ⟶ A ⟶ 𝔹
3. EquivRel(A;x,y.↑(E x y))
4. E ∈ (x,y:A//(↑(E x y))) ⟶ A ⟶ 𝔹
5. Refl(A;x,y.↑(E x y))
6. Sym(A;x,y.↑(E x y))
7. Trans(A;x,y.↑(E x y))
8. f : A ⟶ (a:x,y:A//(↑(E x y)) × {b:A| ↑(E a b)} )
⊢ istype(Bij(A;a:x,y:A//(↑(E x y)) × {b:A| ↑(E a b)} ;f))
BY
{ (Assert Bij(A;a:x,y:A//(↑(E x y)) × {b:A| ↑(E a b)} ;f) ∈ ℙ BY
(MemCD THEN Try (Trivial) THEN MemCD)) }

1
.....aux.....
1. A : Type
2. E : A ⟶ A ⟶ 𝔹
3. EquivRel(A;x,y.↑(E x y))
4. E ∈ (x,y:A//(↑(E x y))) ⟶ A ⟶ 𝔹
5. Refl(A;x,y.↑(E x y))
6. Sym(A;x,y.↑(E x y))
7. Trans(A;x,y.↑(E x y))
8. f : A ⟶ (a:x,y:A//(↑(E x y)) × {b:A| ↑(E a b)} )
⊢ x,y:A//(↑(E x y)) ∈ Type

2
.....aux.....
1. A : Type
2. E : A ⟶ A ⟶ 𝔹
3. EquivRel(A;x,y.↑(E x y))
4. E ∈ (x,y:A//(↑(E x y))) ⟶ A ⟶ 𝔹
5. Refl(A;x,y.↑(E x y))
6. Sym(A;x,y.↑(E x y))
7. Trans(A;x,y.↑(E x y))
8. f : A ⟶ (a:x,y:A//(↑(E x y)) × {b:A| ↑(E a b)} )
9. a : x,y:A//(↑(E x y))
⊢ {b:A| ↑(E a b)} ∈ Type

3
1. A : Type
2. E : A ⟶ A ⟶ 𝔹
3. EquivRel(A;x,y.↑(E x y))
4. E ∈ (x,y:A//(↑(E x y))) ⟶ A ⟶ 𝔹
5. Refl(A;x,y.↑(E x y))
6. Sym(A;x,y.↑(E x y))
7. Trans(A;x,y.↑(E x y))
8. f : A ⟶ (a:x,y:A//(↑(E x y)) × {b:A| ↑(E a b)} )
9. Bij(A;a:x,y:A//(↑(E x y)) × {b:A| ↑(E a b)} ;f) ∈ ℙ
⊢ istype(Bij(A;a:x,y:A//(↑(E x y)) × {b:A| ↑(E a b)} ;f))

Latex:

Latex:
.....wf..... 1. A : Type 2. E : A {}\mrightarrow{} A {}\mrightarrow{} \mBbbB{} 3. EquivRel(A;x,y.\muparrow{}(E x y)) 4. E \mmember{} (x,y:A//(\muparrow{}(E x y))) {}\mrightarrow{} A {}\mrightarrow{} \mBbbB{} 5. Refl(A;x,y.\muparrow{}(E x y)) 6. Sym(A;x,y.\muparrow{}(E x y)) 7. Trans(A;x,y.\muparrow{}(E x y)) 8. f : A {}\mrightarrow{} (a:x,y:A//(\muparrow{}(E x y)) \mtimes{} \{b:A| \muparrow{}(E a b)\} ) \mvdash{} istype(Bij(A;a:x,y:A//(\muparrow{}(E x y)) \mtimes{} \{b:A| \muparrow{}(E a b)\} ;f)) By Latex: (Assert Bij(A;a:x,y:A//(\muparrow{}(E x y)) \mtimes{} \{b:A| \muparrow{}(E a b)\} ;f) \mmember{} \mBbbP{} BY (MemCD THEN Try (Trivial) THEN MemCD)) Home Index