Proof of Nuprl Lemma : flattice-equiv-equiv

Step * 1 1 of Lemma flattice-equiv-equiv

1. X : Type
2. ((X + X) List List) ⊆r Point(free-dl(X + X))
3. a : Base
4. a1 : Base

5. a = a1 ∈ pertype(λas,bs. ((as ∈ (X + X) List List) ∧ (bs ∈ (X + X) List List) ∧ dlattice-eq(X + X;as;bs)))

6. a ∈ (X + X) List List
7. a1 ∈ (X + X) List List
8. dlattice-eq(X + X;a;a1)
⊢ Ax ∈ flattice-equiv(X;a;a)
BY
{ (RepUR ``flattice-equiv`` 0 THEN MemTypeCD THEN InstConcl [⌜a⌝;⌜a⌝]⋅ THEN Auto) }

1
1. X : Type
2. ((X + X) List List) ⊆r Point(free-dl(X + X))
3. a : Base
4. a1 : Base

5. a = a1 ∈ pertype(λas,bs. ((as ∈ (X + X) List List) ∧ (bs ∈ (X + X) List List) ∧ dlattice-eq(X + X;as;bs)))

6. a ∈ (X + X) List List
7. a1 ∈ (X + X) List List
8. dlattice-eq(X + X;a;a1)
9. a = a ∈ Point(free-dl(X + X))
10. a = a ∈ Point(free-dl(X + X))
⊢ flattice-order(X;a;a)

Latex:

Latex:
1. X : Type 2. ((X + X) List List) \msubseteq{}r Point(free-dl(X + X)) 3. a : Base 4. a1 : Base 5. a = a1 6. a \mmember{} (X + X) List List 7. a1 \mmember{} (X + X) List List 8. dlattice-eq(X + X;a;a1) \mvdash{} Ax \mmember{} flattice-equiv(X;a;a) By Latex: (RepUR ``flattice-equiv`` 0 THEN MemTypeCD THEN InstConcl [\mkleeneopen{}a\mkleeneclose{};\mkleeneopen{}a\mkleeneclose{}]\mcdot{} THEN Auto) Home Index