Proof of Nuprl Lemma : context-adjoin-subset0

Step * 3 1 of Lemma context-adjoin-subset0

1. H : CubicalSet{j}
2. phi : {H ⊢ _:𝔽}
3. T : {H ⊢ _}
4. ∀A:fset(ℕ). ∀rho:alpha:H(A) × T(alpha).  ((phi)p(rho) ∈ Point(face_lattice(A)))
5. trans : A:fset(ℕ)
⟶ {rho:alpha:H(A) × T(alpha)| (phi)p(rho) = 1 ∈ Point(face_lattice(A))}
⟶ (alpha:{rho:H(A)| phi(rho) = 1 ∈ Point(face_lattice(A))}  × T(alpha))
⊢ istype(∀A,B:fset(ℕ). ∀g:B ⟶ A.
           ((λx.<g(fst((trans A x))), (snd((trans A x)) fst((trans A x)) g)>)
           = (λx.(trans B <g(fst(x)), (snd(x) fst(x) g)>))

           ∈ ({rho:alpha:H(A) × T(alpha)| (phi)p(rho) = 1 ∈ Point(face_lattice(A))}  ⟶ (alpha:{rho:H(B)|

                                                                                              phi(rho)

                                                                                              = 1

                                                                                              ∈ Point(face_lattice(B))}

                                                                                      × T(alpha)))))

BY
{ (Auto THEN MemTypeCD THEN Auto) }

1
.....set predicate.....
1. H : CubicalSet{j}
2. phi : {H ⊢ _:𝔽}
3. T : {H ⊢ _}
4. ∀A:fset(ℕ). ∀rho:alpha:H(A) × T(alpha).  ((phi)p(rho) ∈ Point(face_lattice(A)))
5. trans : A:fset(ℕ)
⟶ {rho:alpha:H(A) × T(alpha)| (phi)p(rho) = 1 ∈ Point(face_lattice(A))}
⟶ (alpha:{rho:H(A)| phi(rho) = 1 ∈ Point(face_lattice(A))}  × T(alpha))
6. A : fset(ℕ)
7. B : fset(ℕ)
8. g : B ⟶ A
9. ∀rho:alpha:H(A) × T(alpha). ((phi)p(rho) = 1 ∈ Point(face_lattice(A)) ∈ 𝕌{[2 | j' | i 0]})
10. x : alpha:H(A) × T(alpha)
11. (phi)p(x) = 1 ∈ Point(face_lattice(A))
⊢ phi(g(fst((trans A x)))) = 1 ∈ Point(face_lattice(B))

2
.....set predicate.....
1. H : CubicalSet{j}
2. phi : {H ⊢ _:𝔽}
3. T : {H ⊢ _}
4. ∀A:fset(ℕ). ∀rho:alpha:H(A) × T(alpha).  ((phi)p(rho) ∈ Point(face_lattice(A)))
5. trans : A:fset(ℕ)
⟶ {rho:alpha:H(A) × T(alpha)| (phi)p(rho) = 1 ∈ Point(face_lattice(A))}
⟶ (alpha:{rho:H(A)| phi(rho) = 1 ∈ Point(face_lattice(A))}  × T(alpha))
6. A : fset(ℕ)
7. B : fset(ℕ)
8. g : B ⟶ A
9. ∀rho:alpha:H(A) × T(alpha). ((phi)p(rho) = 1 ∈ Point(face_lattice(A)) ∈ 𝕌{[2 | j' | i 0]})
10. x : alpha:H(A) × T(alpha)
11. (phi)p(x) = 1 ∈ Point(face_lattice(A))
⊢ (phi)p(<g(fst(x)), (snd(x) fst(x) g)>) = 1 ∈ Point(face_lattice(B))

Latex:

Latex:
1. H : CubicalSet\{j\} 2. phi : \{H \mvdash{} \_:\mBbbF{}\} 3. T : \{H \mvdash{} \_\} 4. \mforall{}A:fset(\mBbbN{}). \mforall{}rho:alpha:H(A) \mtimes{} T(alpha). ((phi)p(rho) \mmember{} Point(face\_lattice(A))) 5. trans : A:fset(\mBbbN{}) {}\mrightarrow{} \{rho:alpha:H(A) \mtimes{} T(alpha)| (phi)p(rho) = 1\} {}\mrightarrow{} (alpha:\{rho:H(A)| phi(rho) = 1\} \mtimes{} T(alpha)) \mvdash{} istype(\mforall{}A,B:fset(\mBbbN{}). \mforall{}g:B {}\mrightarrow{} A. ((\mlambda{}x.<g(fst((trans A x))), (snd((trans A x)) fst((trans A x)) g)>) = (\mlambda{}x.(trans B <g(fst(x)), (snd(x) fst(x) g)>)))) By Latex: (Auto THEN MemTypeCD THEN Auto) Home Index