Proof of Nuprl Lemma : equiv-equipollent-iff-quotient-equipollent

Step * 1 1 of Lemma equiv-equipollent-iff-quotient-equipollent

1. [A] : Type
2. [B] : Type
3. E : A ⟶ A ⟶ ℙ
4. [%] : EquivRel(A;x,y.E[x;y])
5. g : (x,y:A//E[x;y]) ⟶ A
6. ∀c:x,y:A//E[x;y]. ((g c) = c ∈ (x,y:A//E[x;y]))
7. f : (x,y:A//E[x;y]) ⟶ B
8. Inj(x,y:A//E[x;y];B;f)
9. Surj(x,y:A//E[x;y];B;f)
⊢ A ~ B mod (a1,a2.E[a1;a2])
BY
{ (D 0 With ⌜f⌝ THEN Auto) }

1
1. [A] : Type
2. [B] : Type
3. E : A ⟶ A ⟶ ℙ
4. [%] : EquivRel(A;x,y.E[x;y])
5. g : (x,y:A//E[x;y]) ⟶ A
6. ∀c:x,y:A//E[x;y]. ((g c) = c ∈ (x,y:A//E[x;y]))
7. f : (x,y:A//E[x;y]) ⟶ B
8. Inj(x,y:A//E[x;y];B;f)
9. Surj(x,y:A//E[x;y];B;f)
⊢ Surj(A;B;f)

2
1. A : Type
2. B : Type
3. E : A ⟶ A ⟶ ℙ
4. EquivRel(A;x,y.E[x;y])
5. g : (x,y:A//E[x;y]) ⟶ A
6. ∀c:x,y:A//E[x;y]. ((g c) = c ∈ (x,y:A//E[x;y]))
7. f : (x,y:A//E[x;y]) ⟶ B
8. Inj(x,y:A//E[x;y];B;f)
9. Surj(x,y:A//E[x;y];B;f)
10. Surj(A;B;f)
11. a1 : A
12. a2 : A
13. (f a1) = (f a2) ∈ B
⊢ ↓E[a1;a2]

3
1. A : Type
2. B : Type
3. E : A ⟶ A ⟶ ℙ
4. EquivRel(A;x,y.E[x;y])
5. g : (x,y:A//E[x;y]) ⟶ A
6. ∀c:x,y:A//E[x;y]. ((g c) = c ∈ (x,y:A//E[x;y]))
7. f : (x,y:A//E[x;y]) ⟶ B
8. Inj(x,y:A//E[x;y];B;f)
9. Surj(x,y:A//E[x;y];B;f)
10. Surj(A;B;f)
11. a1 : A
12. a2 : A
13. E[a1;a2]
⊢ (f a1) = (f a2) ∈ B

Latex:

Latex:
1. [A] : Type 2. [B] : Type 3. E : A {}\mrightarrow{} A {}\mrightarrow{} \mBbbP{} 4. [\%] : EquivRel(A;x,y.E[x;y]) 5. g : (x,y:A//E[x;y]) {}\mrightarrow{} A 6. \mforall{}c:x,y:A//E[x;y]. ((g c) = c) 7. f : (x,y:A//E[x;y]) {}\mrightarrow{} B 8. Inj(x,y:A//E[x;y];B;f) 9. Surj(x,y:A//E[x;y];B;f) \mvdash{} A \msim{} B mod (a1,a2.E[a1;a2]) By Latex: (D 0 With \mkleeneopen{}f\mkleeneclose{} THEN Auto) Home Index