Proof of Nuprl Lemma : Degree-implies-BrowerFPT

Step * 1 1 1 1 1 2 of Lemma Degree-implies-BrowerFPT

1. n : ℕ
2. ind : sphere-map(n) ⟶ ℤ
3. ∀f,g:sphere-map(n).  (sphere-map-eq(n;f;g) ⇒ ((ind f) = (ind g) ∈ ℤ))
4. ∀p:S(n). ((ind const-sphere-map(p)) = 0 ∈ ℤ)
5. (ind id-sphere-map()) = 1 ∈ ℤ
6. g : B(n + 1) ⟶ B(n + 1)
7. ∀x,y:B(n + 1).  (req-vec(n + 1;x;y) ⇒ req-vec(n + 1;g x;g y))
8. ∀x:B(n + 1). (||g x|| = r1)
9. ∀x:B(n + 1). ((||x|| = r1) ⇒ req-vec(n + 1;g x;x))
10. ∀h:{h:B(n + 1) ⟶ B(n + 1)| ∀p,q:B(n + 1).  (req-vec(n + 1;p;q) ⇒ req-vec(n + 1;h p;h q))} . (g o h ∈ sphere-map(n)\000C)
11. ∀t:{t:ℝ| t ∈ [r0, r1]} . ∀p:B(n + 1).  (t*p ∈ B(n + 1))
12. ∀t:{t:ℝ| t ∈ [r0, r1]} . (λp.t*p ∈ B(n + 1) ⟶ B(n + 1))
13. ∀t:{t:ℝ| t ∈ [r0, r1]}
      (λp.t*p ∈ {h:B(n + 1) ⟶ B(n + 1)| ∀p,q:B(n + 1).  (req-vec(n + 1;p;q) ⇒ req-vec(n + 1;h p;h q))} )
14. ∀t:{t:ℝ| t ∈ [r0, r1]} . (g o (λp.t*p) ∈ sphere-map(n))
15. ∀t,s:{t:ℝ| t ∈ [r0, r1]} .  ((t = s) ⇒ sphere-map-eq(n;g o (λp.t*p);g o (λp.s*p)))
16. ∀t,s:{t:ℝ| t ∈ [r0, r1]} .  ((t = s) ⇒ ((ind (g o (λp.t*p))) = (ind (g o (λp.s*p))) ∈ ℤ))
17. ∃F:{t:ℝ| t ∈ [r0, r1]}  ⟶ ℤ
     ((∀t,s:{t:ℝ| t ∈ [r0, r1]} .  ((t = s) ⇒ ((F t) = (F s) ∈ ℤ))) ∧ ((F r0) = 0 ∈ ℤ) ∧ ((F r1) = 1 ∈ ℤ))
⊢ False
BY
{ (ExRepD
   THEN (InstLemma `extensional-discrete-real-fun-is-constant` [⌜r0⌝;⌜r1⌝;⌜F⌝]⋅ THENA Auto)
   THEN InstHyp [⌜r0⌝;⌜r1⌝] (-1)⋅
   THEN Auto) }

Latex:

Latex:
1. n : \mBbbN{} 2. ind : sphere-map(n) {}\mrightarrow{} \mBbbZ{} 3. \mforall{}f,g:sphere-map(n). (sphere-map-eq(n;f;g) {}\mRightarrow{} ((ind f) = (ind g))) 4. \mforall{}p:S(n). ((ind const-sphere-map(p)) = 0) 5. (ind id-sphere-map()) = 1 6. g : B(n + 1) {}\mrightarrow{} B(n + 1) 7. \mforall{}x,y:B(n + 1). (req-vec(n + 1;x;y) {}\mRightarrow{} req-vec(n + 1;g x;g y)) 8. \mforall{}x:B(n + 1). (||g x|| = r1) 9. \mforall{}x:B(n + 1). ((||x|| = r1) {}\mRightarrow{} req-vec(n + 1;g x;x)) 10. \mforall{}h:\{h:B(n + 1) {}\mrightarrow{} B(n + 1)| \mforall{}p,q:B(n + 1). (req-vec(n + 1;p;q) {}\mRightarrow{} req-vec(n + 1;h p;h q))\} (g o h \mmember{} sphere-map(n)) 11. \mforall{}t:\{t:\mBbbR{}| t \mmember{} [r0, r1]\} . \mforall{}p:B(n + 1). (t*p \mmember{} B(n + 1)) 12. \mforall{}t:\{t:\mBbbR{}| t \mmember{} [r0, r1]\} . (\mlambda{}p.t*p \mmember{} B(n + 1) {}\mrightarrow{} B(n + 1)) 13. \mforall{}t:\{t:\mBbbR{}| t \mmember{} [r0, r1]\} (\mlambda{}p.t*p \mmember{} \{h:B(n + 1) {}\mrightarrow{} B(n + 1)| \mforall{}p,q:B(n + 1). (req-vec(n + 1;p;q) {}\mRightarrow{} req-vec(n + 1;h p;h q))\} ) 14. \mforall{}t:\{t:\mBbbR{}| t \mmember{} [r0, r1]\} . (g o (\mlambda{}p.t*p) \mmember{} sphere-map(n)) 15. \mforall{}t,s:\{t:\mBbbR{}| t \mmember{} [r0, r1]\} . ((t = s) {}\mRightarrow{} sphere-map-eq(n;g o (\mlambda{}p.t*p);g o (\mlambda{}p.s*p))) 16. \mforall{}t,s:\{t:\mBbbR{}| t \mmember{} [r0, r1]\} . ((t = s) {}\mRightarrow{} ((ind (g o (\mlambda{}p.t*p))) = (ind (g o (\mlambda{}p.s*p))))) 17. \mexists{}F:\{t:\mBbbR{}| t \mmember{} [r0, r1]\} {}\mrightarrow{} \mBbbZ{} ((\mforall{}t,s:\{t:\mBbbR{}| t \mmember{} [r0, r1]\} . ((t = s) {}\mRightarrow{} ((F t) = (F s)))) \mwedge{} ((F r0) = 0) \mwedge{} ((F r1) = 1)) \mvdash{} False By Latex: (ExRepD THEN (InstLemma `extensional-discrete-real-fun-is-constant` [\mkleeneopen{}r0\mkleeneclose{};\mkleeneopen{}r1\mkleeneclose{};\mkleeneopen{}F\mkleeneclose{}]\mcdot{} THENA Auto) THEN InstHyp [\mkleeneopen{}r0\mkleeneclose{};\mkleeneopen{}r1\mkleeneclose{}] (-1)\mcdot{} THEN Auto) Home Index