Proof of Nuprl Lemma : es-prior-interface-vals-property

Step * 1 1 of Lemma es-prior-interface-vals-property

.....truecase.....
1. Info : Type@i'
2. es : EO+(Info)@i'
3. A : Type@i'
4. X : EClass(A)@i'
5. e : E@i
6. ∀e1:E. ((e1 < e) ⇒ (X(<e1) = if e1 ∈_b prior(X) then X(<prior(X)(e1)) @ [X(prior(X)(e1))] else [] fi  ∈ (A List)))
7. ↑e ∈_b prior(X)
⊢ X(<e) = (X(<prior(X)(e)) @ [X(prior(X)(e))]) ∈ (A List)
BY
{ (RW (AddrC [2] (UnfoldC `es-prior-interface-vals`)) 0
   THEN RecUnfold `es-before` 0
   THEN (SplitOnConclITE THENA Auto)) }

1
.....truecase.....
1. Info : Type@i'
2. es : EO+(Info)@i'
3. A : Type@i'
4. X : EClass(A)@i'
5. e : E@i
6. ∀e1:E. ((e1 < e) ⇒ (X(<e1) = if e1 ∈_b prior(X) then X(<prior(X)(e1)) @ [X(prior(X)(e1))] else [] fi  ∈ (A List)))
7. ↑e ∈_b prior(X)
8. ↑first(e)
⊢ mapfilter(λe.X(e);λe.e ∈_b X;[]) = (X(<prior(X)(e)) @ [X(prior(X)(e))]) ∈ (A List)

2
.....falsecase.....
1. Info : Type@i'
2. es : EO+(Info)@i'
3. A : Type@i'
4. X : EClass(A)@i'
5. e : E@i
6. ∀e1:E. ((e1 < e) ⇒ (X(<e1) = if e1 ∈_b prior(X) then X(<prior(X)(e1)) @ [X(prior(X)(e1))] else [] fi  ∈ (A List)))
7. ↑e ∈_b prior(X)
8. ¬↑first(e)

⊢ mapfilter(λe.X(e);λe.e ∈_b X;before(pred(e)) @ [pred(e)]) = (X(<prior(X)(e)) @ [X(prior(X)(e))]) ∈ (A List)

Latex:

Latex:
.....truecase..... 1. Info : Type@i' 2. es : EO+(Info)@i' 3. A : Type@i' 4. X : EClass(A)@i' 5. e : E@i 6. \mforall{}e1:E ((e1 < e) {}\mRightarrow{} (X(<e1) = if e1 \mmember{}\msubb{} prior(X) then X(<prior(X)(e1)) @ [X(prior(X)(e1))] else [] fi )) 7. \muparrow{}e \mmember{}\msubb{} prior(X) \mvdash{} X(<e) = (X(<prior(X)(e)) @ [X(prior(X)(e))]) By Latex: (RW (AddrC [2] (UnfoldC `es-prior-interface-vals`)) 0 THEN RecUnfold `es-before` 0 THEN (SplitOnConclITE THENA Auto)) Home Index