Proof of Nuprl Lemma : rat-complex-boundary-boundary

Step * 2 2 1 1 1 1 of Lemma rat-complex-boundary-boundary

1. k : ℕ
2. n : ℕ
3. K : n-dim-complex
4. 2 ≤ n
5. ∀[L:ℚCube(k) List]. L ~ [] supposing ∀x:ℚCube(k). (¬(x ∈ L))
6. x : ℚCube(k)
7. ↑isOdd(||filter(λc.is-rat-cube-face(k;x;c);∂(K))||)
8. dim(x) = (n - 1 - 1) ∈ ℤ
9. Σ(||filter(λv.is-rat-cube-face(k;v;t);filter(λv.is-rat-cube-face(k;x;v);face-complex(k;K)))|| | t ∈ K)
= (Σ(||filter(λt.is-rat-cube-face(k;s;t);K)|| | s ∈ filter(λv.is-rat-cube-face(k;x;v);∂(K)))
+ Σ(||filter(λt.is-rat-cube-face(k;s;t);K)|| | s ∈ filter(λs.(¬_bin-complex-boundary(k;s;K));

                                                            filter(λv.is-rat-cube-face(k;x;v);face-complex(k;K)))))

∈ ℤ
⊢ False
BY
{ Assert ⌜↑isEven(Σ(||filter(λv.is-rat-cube-face(k;v;t);filter(λv.is-rat-cube-face(k;x;v);

                                                               face-complex(k;K)))|| | t ∈ K))⌝⋅ }

1
.....assertion.....
1. k : ℕ
2. n : ℕ
3. K : n-dim-complex
4. 2 ≤ n
5. ∀[L:ℚCube(k) List]. L ~ [] supposing ∀x:ℚCube(k). (¬(x ∈ L))
6. x : ℚCube(k)
7. ↑isOdd(||filter(λc.is-rat-cube-face(k;x;c);∂(K))||)
8. dim(x) = (n - 1 - 1) ∈ ℤ
9. Σ(||filter(λv.is-rat-cube-face(k;v;t);filter(λv.is-rat-cube-face(k;x;v);face-complex(k;K)))|| | t ∈ K)
= (Σ(||filter(λt.is-rat-cube-face(k;s;t);K)|| | s ∈ filter(λv.is-rat-cube-face(k;x;v);∂(K)))
+ Σ(||filter(λt.is-rat-cube-face(k;s;t);K)|| | s ∈ filter(λs.(¬_bin-complex-boundary(k;s;K));

                                                            filter(λv.is-rat-cube-face(k;x;v);face-complex(k;K)))))

∈ ℤ

⊢ ↑isEven(Σ(||filter(λv.is-rat-cube-face(k;v;t);filter(λv.is-rat-cube-face(k;x;v);face-complex(k;K)))|| | t ∈ K))

2
1. k : ℕ
2. n : ℕ
3. K : n-dim-complex
4. 2 ≤ n
5. ∀[L:ℚCube(k) List]. L ~ [] supposing ∀x:ℚCube(k). (¬(x ∈ L))
6. x : ℚCube(k)
7. ↑isOdd(||filter(λc.is-rat-cube-face(k;x;c);∂(K))||)
8. dim(x) = (n - 1 - 1) ∈ ℤ
9. Σ(||filter(λv.is-rat-cube-face(k;v;t);filter(λv.is-rat-cube-face(k;x;v);face-complex(k;K)))|| | t ∈ K)
= (Σ(||filter(λt.is-rat-cube-face(k;s;t);K)|| | s ∈ filter(λv.is-rat-cube-face(k;x;v);∂(K)))
+ Σ(||filter(λt.is-rat-cube-face(k;s;t);K)|| | s ∈ filter(λs.(¬_bin-complex-boundary(k;s;K));

                                                            filter(λv.is-rat-cube-face(k;x;v);face-complex(k;K)))))

∈ ℤ

10. ↑isEven(Σ(||filter(λv.is-rat-cube-face(k;v;t);filter(λv.is-rat-cube-face(k;x;v);face-complex(k;K)))|| | t ∈ K))

⊢ False

Latex:

Latex:
1. k : \mBbbN{} 2. n : \mBbbN{} 3. K : n-dim-complex 4. 2 \mleq{} n 5. \mforall{}[L:\mBbbQ{}Cube(k) List]. L \msim{} [] supposing \mforall{}x:\mBbbQ{}Cube(k). (\mneg{}(x \mmember{} L)) 6. x : \mBbbQ{}Cube(k) 7. \muparrow{}isOdd(||filter(\mlambda{}c.is-rat-cube-face(k;x;c);\mpartial{}(K))||) 8. dim(x) = (n - 1 - 1) 9. \mSigma{}(||filter(\mlambda{}v.is-rat-cube-face(k;v;t);filter(\mlambda{}v.is-rat-cube-face(k;x;v); face-complex(k;K)))|| | t \mmember{} K) = (\mSigma{}(||filter(\mlambda{}t.is-rat-cube-face(k;s;t);K)|| | s \mmember{} filter(\mlambda{}v.is-rat-cube-face(k;x;v);\mpartial{}(K))) + \mSigma{}(||filter(\mlambda{}t.is-rat-cube-face(k;s;t);K)|| | s \mmember{} filter(\mlambda{}s.(\mneg{}\msubb{}in-complex-boundary(k;s;K)); filter(\mlambda{}v.is-rat-cube-face(k;x;v); face-complex(k;K))))) \mvdash{} False By Latex: Assert \mkleeneopen{}\muparrow{}isEven(\mSigma{}(||filter(\mlambda{}v.is-rat-cube-face(k;v;t);filter(\mlambda{}v.is-rat-cube-face(k;x;v); face-complex(k;K)))|| | t \mmember{} K))\mkleeneclose{}\mcdot{} Home Index