Proof of Nuprl Lemma : mk-bounded-distributive-lattice-from-order

Step * 2 1 of Lemma mk-bounded-distributive-lattice-from-order

1. T : Type
2. m : T ⟶ T ⟶ T
3. j : T ⟶ T ⟶ T
4. z : T
5. o : T
6. R : T ⟶ T ⟶ ℙ
7. Order(T;x,y.R[x;y])
∧ (∀[a,b:T].  least-upper-bound(T;x,y.R[x;y];a;b;j[a;b]))
∧ (∀[a,b:T].  greatest-lower-bound(T;x,y.R[x;y];a;b;m[a;b]))
∧ (∀[a:T]. R[a;o])
∧ (∀[a:T]. R[z;a])
∧ (∀[a,b,c:T].  (m[a;j[b;c]] = j[m[a;b];m[a;c]] ∈ T))
⊢ lattice-axioms(mk-bounded-lattice(T;m;j;z;o)) ∧ bounded-lattice-axioms(mk-bounded-lattice(T;m;j;z;o))
BY
{ D 0 }

1
1. T : Type
2. m : T ⟶ T ⟶ T
3. j : T ⟶ T ⟶ T
4. z : T
5. o : T
6. R : T ⟶ T ⟶ ℙ
7. Order(T;x,y.R[x;y])
∧ (∀[a,b:T].  least-upper-bound(T;x,y.R[x;y];a;b;j[a;b]))
∧ (∀[a,b:T].  greatest-lower-bound(T;x,y.R[x;y];a;b;m[a;b]))
∧ (∀[a:T]. R[a;o])
∧ (∀[a:T]. R[z;a])
∧ (∀[a,b,c:T].  (m[a;j[b;c]] = j[m[a;b];m[a;c]] ∈ T))
⊢ lattice-axioms(mk-bounded-lattice(T;m;j;z;o))

2
1. T : Type
2. m : T ⟶ T ⟶ T
3. j : T ⟶ T ⟶ T
4. z : T
5. o : T
6. R : T ⟶ T ⟶ ℙ
7. Order(T;x,y.R[x;y])
∧ (∀[a,b:T].  least-upper-bound(T;x,y.R[x;y];a;b;j[a;b]))
∧ (∀[a,b:T].  greatest-lower-bound(T;x,y.R[x;y];a;b;m[a;b]))
∧ (∀[a:T]. R[a;o])
∧ (∀[a:T]. R[z;a])
∧ (∀[a,b,c:T].  (m[a;j[b;c]] = j[m[a;b];m[a;c]] ∈ T))
⊢ bounded-lattice-axioms(mk-bounded-lattice(T;m;j;z;o))

Latex:

Latex:
1. T : Type 2. m : T {}\mrightarrow{} T {}\mrightarrow{} T 3. j : T {}\mrightarrow{} T {}\mrightarrow{} T 4. z : T 5. o : T 6. R : T {}\mrightarrow{} T {}\mrightarrow{} \mBbbP{} 7. Order(T;x,y.R[x;y]) \mwedge{} (\mforall{}[a,b:T]. least-upper-bound(T;x,y.R[x;y];a;b;j[a;b])) \mwedge{} (\mforall{}[a,b:T]. greatest-lower-bound(T;x,y.R[x;y];a;b;m[a;b])) \mwedge{} (\mforall{}[a:T]. R[a;o]) \mwedge{} (\mforall{}[a:T]. R[z;a]) \mwedge{} (\mforall{}[a,b,c:T]. (m[a;j[b;c]] = j[m[a;b];m[a;c]])) \mvdash{} lattice-axioms(mk-bounded-lattice(T;m;j;z;o)) \mwedge{} bounded-lattice-axioms(mk-bounded-lattice(T;m;j;z;o)) By Latex: D 0 Home Index