Proof of Nuprl Lemma : no-retraction-case-1

Step * 1 2 of Lemma no-retraction-case-1

1. k : ℕ
2. K : 1-dim-complex
3. 0 < ||K||
4. f : |K| ⟶ |∂(K)|
5. f:FUN(|K|;|∂(K)|)
6. ∀a:|∂(K)|. f a ≡ a
7. ∀x:|∂(K)|. ∃i:ℕ||∂(K)||. req-vec(k;x;λj.rat2real(fst((∂(K)[i] j))))
8. g : x:|∂(K)| ⟶ ℕ||∂(K)||
9. ∀x:|∂(K)|. req-vec(k;x;λj.rat2real(fst((∂(K)[g x] j))))
10. ∀x,y:|∂(K)|. (x ≡ y ⇒ ((g x) = (g y) ∈ ℤ))
⊢ False
BY
{ (Assert ∀x,y:|K|. (x ≡ y ⇒ ((g (f x)) = (g (f y)) ∈ ℤ)) BY

         (Unfold `is-mfun` 5 THEN ParallelOp 5 THEN RepeatFor 2 (ParallelLast) THEN BackThruSomeHyp THEN Auto)) }

1
1. k : ℕ
2. K : 1-dim-complex
3. 0 < ||K||
4. f : |K| ⟶ |∂(K)|
5. f:FUN(|K|;|∂(K)|)
6. ∀a:|∂(K)|. f a ≡ a
7. ∀x:|∂(K)|. ∃i:ℕ||∂(K)||. req-vec(k;x;λj.rat2real(fst((∂(K)[i] j))))
8. g : x:|∂(K)| ⟶ ℕ||∂(K)||
9. ∀x:|∂(K)|. req-vec(k;x;λj.rat2real(fst((∂(K)[g x] j))))
10. ∀x,y:|∂(K)|. (x ≡ y ⇒ ((g x) = (g y) ∈ ℤ))
11. ∀x,y:|K|. (x ≡ y ⇒ ((g (f x)) = (g (f y)) ∈ ℤ))
⊢ False

Latex:

Latex:
1. k : \mBbbN{} 2. K : 1-dim-complex 3. 0 < ||K|| 4. f : |K| {}\mrightarrow{} |\mpartial{}(K)| 5. f:FUN(|K|;|\mpartial{}(K)|) 6. \mforall{}a:|\mpartial{}(K)|. f a \mequiv{} a 7. \mforall{}x:|\mpartial{}(K)|. \mexists{}i:\mBbbN{}||\mpartial{}(K)||. req-vec(k;x;\mlambda{}j.rat2real(fst((\mpartial{}(K)[i] j)))) 8. g : x:|\mpartial{}(K)| {}\mrightarrow{} \mBbbN{}||\mpartial{}(K)|| 9. \mforall{}x:|\mpartial{}(K)|. req-vec(k;x;\mlambda{}j.rat2real(fst((\mpartial{}(K)[g x] j)))) 10. \mforall{}x,y:|\mpartial{}(K)|. (x \mequiv{} y {}\mRightarrow{} ((g x) = (g y))) \mvdash{} False By Latex: (Assert \mforall{}x,y:|K|. (x \mequiv{} y {}\mRightarrow{} ((g (f x)) = (g (f y)))) BY (Unfold `is-mfun` 5 THEN ParallelOp 5 THEN RepeatFor 2 (ParallelLast) THEN BackThruSomeHyp THEN Auto)) Home Index