Proof of Nuprl Lemma : fpf-join-assoc

Step * of Lemma fpf-join-assoc

∀[A:Type]. ∀[B:A ⟶ Type]. ∀[eq:EqDecider(A)]. ∀[f,g,h:a:A fp-> B[a]].  (f ⊕ g ⊕ h = f ⊕ g ⊕ h ∈ a:A fp-> B[a])

BY
{ (Repeat (Unfolds ``fpf fpf-join fpf-cap fpf-ap fpf-dom`` 0)
   THEN Auto
   THEN DVar `f'
   THEN DVar `g'
   THEN DVar `h'
   THEN All Reduce
   THEN EqCD
   THEN Auto) }

1
.....subterm..... T:t
1:n
1. A : Type
2. B : A ⟶ Type
3. eq : EqDecider(A)
4. d : A List
5. f1 : a:{a:A| (a ∈ d)}  ⟶ B[a]
6. d1 : A List
7. g1 : a:{a:A| (a ∈ d1)}  ⟶ B[a]
8. d2 : A List
9. h1 : a:{a:A| (a ∈ d2)}  ⟶ B[a]
⊢ (d @ filter(λa.(¬_ba ∈_b d);d1 @ filter(λa.(¬_ba ∈_b d1);d2)))
= ((d @ filter(λa.(¬_ba ∈_b d);d1)) @ filter(λa.(¬_ba ∈_b d @ filter(λa.(¬_ba ∈_b d);d1));d2))
∈ (A List)

2
.....subterm..... T:t
2:n
1. A : Type
2. B : A ⟶ Type
3. eq : EqDecider(A)
4. d : A List
5. f1 : a:{a:A| (a ∈ d)}  ⟶ B[a]
6. d1 : A List
7. g1 : a:{a:A| (a ∈ d1)}  ⟶ B[a]
8. d2 : A List
9. h1 : a:{a:A| (a ∈ d2)}  ⟶ B[a]
⊢ (λa.if a ∈_b d then f1 a
      if a ∈_b d1 then g1 a
      else h1 a
      fi )

= (λa.if a ∈_b d @ filter(λa.(¬_ba ∈_b d);d1) then if a ∈_b d then f1 a else g1 a fi  else h1 a fi )

∈ (a:{a:A| (a ∈ d @ filter(λa.(¬_ba ∈_b d);d1 @ filter(λa.(¬_ba ∈_b d1);d2)))} ⟶ B[a])

Latex:

Latex:
\mforall{}[A:Type]. \mforall{}[B:A {}\mrightarrow{} Type]. \mforall{}[eq:EqDecider(A)]. \mforall{}[f,g,h:a:A fp-> B[a]]. (f \moplus{} g \moplus{} h = f \moplus{} g \moplus{} h) By Latex: (Repeat (Unfolds ``fpf fpf-join fpf-cap fpf-ap fpf-dom`` 0) THEN Auto THEN DVar `f' THEN DVar `g' THEN DVar `h' THEN All Reduce THEN EqCD THEN Auto) Home Index