Proof of Nuprl Lemma : fpf-rename-ap

Step * of Lemma fpf-rename-ap

∀[A,C:Type]. ∀[B:A ─→ Type]. ∀[eqa:EqDecider(A)]. ∀[eqc:EqDecider(C)]. ∀[r:A ─→ C]. ∀[f:a:A fp-> B[a]]. ∀[a:A].

  (rename(r;f)(r a) = f(a) ∈ B[a]) supposing ((↑a ∈ dom(f)) and Inj(A;C;r))
BY
{ (((UnivCD THENA Auto)
    THEN Unfolds ``fpf-rename fpf-ap`` 0
    THEN DVar `f'
    THEN Reduce 0
    THEN (InstLemma `hd-filter` [A; λ₂y.eqc (r y) (r a); d])⋅)
   THENA Auto
   ) }

1
.....antecedent.....
1. A : Type
2. C : Type
3. B : A ─→ Type
4. eqa : EqDecider(A)
5. eqc : EqDecider(C)
6. r : A ─→ C
7. d : A List
8. f1 : a:{a:A| (a ∈ d)}  ─→ B[a]
9. a : A
10. Inj(A;C;r)
11. ↑a ∈ dom(<d, f1>)
⊢ ∃a@0:A. ((a@0 ∈ d) ∧ (↑(eqc (r a@0) (r a))))

2
1. A : Type
2. C : Type
3. B : A ─→ Type
4. eqa : EqDecider(A)
5. eqc : EqDecider(C)
6. r : A ─→ C
7. d : A List
8. f1 : a:{a:A| (a ∈ d)}  ─→ B[a]
9. a : A
10. Inj(A;C;r)
11. ↑a ∈ dom(<d, f1>)
12. (hd(filter(λa@0.(eqc (r a@0) (r a));d)) ∈ A)

c∧ ((hd(filter(λa@0.(eqc (r a@0) (r a));d)) ∈ d) ∧ (↑(eqc (r hd(filter(λa@0.(eqc (r a@0) (r a));d))) (r a))))

⊢ (f1 hd(filter(λy.(eqc (r y) (r a));d))) = (f1 a) ∈ B[a]

Latex:

\mforall{}[A,C:Type]. \mforall{}[B:A {}\mrightarrow{} Type]. \mforall{}[eqa:EqDecider(A)]. \mforall{}[eqc:EqDecider(C)]. \mforall{}[r:A {}\mrightarrow{} C]. \mforall{}[f:a:A fp-> B[a]]. \mforall{}[a:A]. (rename(r;f)(r a) = f(a)) supposing ((\muparrow{}a \mmember{} dom(f)) and Inj(A;C;r)) By (((UnivCD THENA Auto) THEN Unfolds ``fpf-rename fpf-ap`` 0 THEN DVar `f' THEN Reduce 0 THEN (InstLemma `hd-filter` [A; \mlambda{}\msubtwo{}y.eqc (r y) (r a); d])\mcdot{}) THENA Auto ) Home Index