Proof of Nuprl Lemma : pres-a0-constraint

Step * 1 2 of Lemma pres-a0-constraint

.....set predicate.....
1. G : CubicalSet{j}
2. phi : {G ⊢ _:𝔽}
3. A : {G.𝕀 ⊢ _}
4. T : {G.𝕀 ⊢ _}
5. f : {G.𝕀 ⊢ _:(T ⟶ A)}
6. t : {G.𝕀, (phi)p ⊢ _:T}
7. t0 : {G ⊢ _:(T)[0(𝕀)][phi |⟶ t[0]]}
8. cT : G.𝕀 +⊢ Compositon(T)
9. p+ ∈ G.𝕀.𝕀 ij⟶ G.𝕀
10. app(f; t) ∈ {G.𝕀, (phi)p ⊢ _:A}
11. {G.𝕀.𝕀 ⊢ _:(A)p+} ⊆r {G.𝕀, ((phi)p ∨ (q=1)).𝕀 ⊢ _:(A)p+}

12. {G.𝕀 ⊢ _:((A)p+)[1(𝕀)][((phi)p ∨ (q=1)) |⟶ ((presw(G;phi;f;t;t0;cT))p+)[1(𝕀)]]} ∈ 𝕌{[i' | j']}

13. (presw(G;phi;f;t;t0;cT))p+ ∈ {G.𝕀, ((phi)p ∨ (q=1)).𝕀 ⊢ _:(A)p+}

⊢ ((presw(G;phi;f;t;t0;cT))p+)[0(𝕀)] = (pres-a0(G;f;t0))p ∈ {G.𝕀, ((phi)p ∨ (q=1)) ⊢ _:((A)p+)[0(𝕀)]}

BY
{ SubsumeC ⌜{G.𝕀 ⊢ _:((A)p+)[0(𝕀)]}⌝⋅ }

1
1. G : CubicalSet{j}
2. phi : {G ⊢ _:𝔽}
3. A : {G.𝕀 ⊢ _}
4. T : {G.𝕀 ⊢ _}
5. f : {G.𝕀 ⊢ _:(T ⟶ A)}
6. t : {G.𝕀, (phi)p ⊢ _:T}
7. t0 : {G ⊢ _:(T)[0(𝕀)][phi |⟶ t[0]]}
8. cT : G.𝕀 +⊢ Compositon(T)
9. p+ ∈ G.𝕀.𝕀 ij⟶ G.𝕀
10. app(f; t) ∈ {G.𝕀, (phi)p ⊢ _:A}
11. {G.𝕀.𝕀 ⊢ _:(A)p+} ⊆r {G.𝕀, ((phi)p ∨ (q=1)).𝕀 ⊢ _:(A)p+}

12. {G.𝕀 ⊢ _:((A)p+)[1(𝕀)][((phi)p ∨ (q=1)) |⟶ ((presw(G;phi;f;t;t0;cT))p+)[1(𝕀)]]} ∈ 𝕌{[i' | j']}

13. (presw(G;phi;f;t;t0;cT))p+ ∈ {G.𝕀, ((phi)p ∨ (q=1)).𝕀 ⊢ _:(A)p+}
⊢ ((presw(G;phi;f;t;t0;cT))p+)[0(𝕀)] = (pres-a0(G;f;t0))p ∈ {G.𝕀 ⊢ _:((A)p+)[0(𝕀)]}

2
1. G : CubicalSet{j}
2. phi : {G ⊢ _:𝔽}
3. A : {G.𝕀 ⊢ _}
4. T : {G.𝕀 ⊢ _}
5. f : {G.𝕀 ⊢ _:(T ⟶ A)}
6. t : {G.𝕀, (phi)p ⊢ _:T}
7. t0 : {G ⊢ _:(T)[0(𝕀)][phi |⟶ t[0]]}
8. cT : G.𝕀 +⊢ Compositon(T)
9. p+ ∈ G.𝕀.𝕀 ij⟶ G.𝕀
10. app(f; t) ∈ {G.𝕀, (phi)p ⊢ _:A}
11. {G.𝕀.𝕀 ⊢ _:(A)p+} ⊆r {G.𝕀, ((phi)p ∨ (q=1)).𝕀 ⊢ _:(A)p+}

12. {G.𝕀 ⊢ _:((A)p+)[1(𝕀)][((phi)p ∨ (q=1)) |⟶ ((presw(G;phi;f;t;t0;cT))p+)[1(𝕀)]]} ∈ 𝕌{[i' | j']}

13. (presw(G;phi;f;t;t0;cT))p+ ∈ {G.𝕀, ((phi)p ∨ (q=1)).𝕀 ⊢ _:(A)p+}
14. ((presw(G;phi;f;t;t0;cT))p+)[0(𝕀)] = (pres-a0(G;f;t0))p ∈ {G.𝕀 ⊢ _:((A)p+)[0(𝕀)]}
⊢ {G.𝕀 ⊢ _:((A)p+)[0(𝕀)]} ⊆r {G.𝕀, ((phi)p ∨ (q=1)) ⊢ _:((A)p+)[0(𝕀)]}

Latex:

Latex:
.....set predicate..... 1. G : CubicalSet\{j\} 2. phi : \{G \mvdash{} \_:\mBbbF{}\} 3. A : \{G.\mBbbI{} \mvdash{} \_\} 4. T : \{G.\mBbbI{} \mvdash{} \_\} 5. f : \{G.\mBbbI{} \mvdash{} \_:(T {}\mrightarrow{} A)\} 6. t : \{G.\mBbbI{}, (phi)p \mvdash{} \_:T\} 7. t0 : \{G \mvdash{} \_:(T)[0(\mBbbI{})][phi |{}\mrightarrow{} t[0]]\} 8. cT : G.\mBbbI{} +\mvdash{} Compositon(T) 9. p+ \mmember{} G.\mBbbI{}.\mBbbI{} ij{}\mrightarrow{} G.\mBbbI{} 10. app(f; t) \mmember{} \{G.\mBbbI{}, (phi)p \mvdash{} \_:A\} 11. \{G.\mBbbI{}.\mBbbI{} \mvdash{} \_:(A)p+\} \msubseteq{}r \{G.\mBbbI{}, ((phi)p \mvee{} (q=1)).\mBbbI{} \mvdash{} \_:(A)p+\} 12. \{G.\mBbbI{} \mvdash{} \_:((A)p+)[1(\mBbbI{})][((phi)p \mvee{} (q=1)) |{}\mrightarrow{} ((presw(G;phi;f;t;t0;cT))p+)[1(\mBbbI{})]]\} \mmember{} \mBbbU{}\{[i' | j']\} 13. (presw(G;phi;f;t;t0;cT))p+ \mmember{} \{G.\mBbbI{}, ((phi)p \mvee{} (q=1)).\mBbbI{} \mvdash{} \_:(A)p+\} \mvdash{} ((presw(G;phi;f;t;t0;cT))p+)[0(\mBbbI{})] = (pres-a0(G;f;t0))p By Latex: SubsumeC \mkleeneopen{}\{G.\mBbbI{} \mvdash{} \_:((A)p+)[0(\mBbbI{})]\}\mkleeneclose{}\mcdot{} Home Index