Proof of Nuprl Lemma : all-but-one

Step * 1 1 1 1 of Lemma all-but-one

1. [T] : Type
2. [P] : T ⟶ ℙ
3. ∀x,y:T. Dec(x = y ∈ T)
4. u : T
5. v : T List
6. 0 < ||v|| ⇒ (∀x∈v.(∀y∈v.P[x] ∨ P[y] supposing ¬(x = y ∈ T))) ⇒ (∃x∈v. (∀y∈v.P[y] supposing ¬(x = y ∈ T)))
7. 0 < ||v|| + 1
8. P[u] ∨ P[u] supposing ¬(u = u ∈ T)
9. (∀y∈v.P[u] ∨ P[y] supposing ¬(u = y ∈ T))
10. (∀x∈v.(∀y∈[u / v].P[x] ∨ P[y] supposing ¬(x = y ∈ T)))
11. 0 < ||v||
⊢ (∃x∈[u / v]. (∀y∈[u / v].P[y] supposing ¬(x = y ∈ T)))
BY
{ ThinTrivial }

1
1. [T] : Type
2. [P] : T ⟶ ℙ
3. ∀x,y:T. Dec(x = y ∈ T)
4. u : T
5. v : T List
6. 0 < ||v|| + 1
7. P[u] ∨ P[u] supposing ¬(u = u ∈ T)
8. (∀y∈v.P[u] ∨ P[y] supposing ¬(u = y ∈ T))
9. (∀x∈v.(∀y∈[u / v].P[x] ∨ P[y] supposing ¬(x = y ∈ T)))
10. 0 < ||v||
11. (∀x∈v.(∀y∈v.P[x] ∨ P[y] supposing ¬(x = y ∈ T))) ⇒ (∃x∈v. (∀y∈v.P[y] supposing ¬(x = y ∈ T)))
⊢ (∃x∈[u / v]. (∀y∈[u / v].P[y] supposing ¬(x = y ∈ T)))

Latex:

Latex:
1. [T] : Type 2. [P] : T {}\mrightarrow{} \mBbbP{} 3. \mforall{}x,y:T. Dec(x = y) 4. u : T 5. v : T List 6. 0 < ||v|| {}\mRightarrow{} (\mforall{}x\mmember{}v.(\mforall{}y\mmember{}v.P[x] \mvee{} P[y] supposing \mneg{}(x = y))) {}\mRightarrow{} (\mexists{}x\mmember{}v. (\mforall{}y\mmember{}v.P[y] supposing \mneg{}(x = y))) 7. 0 < ||v|| + 1 8. P[u] \mvee{} P[u] supposing \mneg{}(u = u) 9. (\mforall{}y\mmember{}v.P[u] \mvee{} P[y] supposing \mneg{}(u = y)) 10. (\mforall{}x\mmember{}v.(\mforall{}y\mmember{}[u / v].P[x] \mvee{} P[y] supposing \mneg{}(x = y))) 11. 0 < ||v|| \mvdash{} (\mexists{}x\mmember{}[u / v]. (\mforall{}y\mmember{}[u / v].P[y] supposing \mneg{}(x = y))) By Latex: ThinTrivial Home Index