Proof of Nuprl Lemma : Taylor-series-bounded-converges-everywhere

Step * 1 1 1 1 1 1 of Lemma Taylor-series-bounded-converges-everywhere

1. F : ℕ ⟶ ℝ ⟶ ℝ
2. ∀k:ℕ. ∀x,y:ℝ. ((x = y) ⇒ (F[k;x] = F[k;y]))
3. infinite-deriv-seq((-∞, ∞);i,x.F[i;x])
4. r : {r:ℝ| r0 ≤ r}
5. m : {m:ℕ⁺| icompact([r(-m), r(m)])}
6. j : ℕ⁺
7. N : ℕ
8. c : ℝ
9. r0 < c
10. ∀k:{N...}. ∀x:{x:ℝ| |x| ≤ r(m)} . (|F[k;x]| ≤ c)
11. r0 < |c|
12. r0 < r(j)
13. v : ℝ
14. (|c| * r(j)) = v ∈ ℝ
15. r0 < v
⊢ ∃M:ℕ⁺. ∀k:{M...}. (|(r^k/r((k)!))| ≤ (r1/v))
BY

{ (InstLemma `small-reciprocal-real` [⌜(r1/v)⌝]⋅ THENA (Auto THEN MemTypeCD THEN Try (nRMul ⌜v⌝ 0⋅) THEN Auto)) }

1
1. F : ℕ ⟶ ℝ ⟶ ℝ
2. ∀k:ℕ. ∀x,y:ℝ. ((x = y) ⇒ (F[k;x] = F[k;y]))
3. infinite-deriv-seq((-∞, ∞);i,x.F[i;x])
4. r : {r:ℝ| r0 ≤ r}
5. m : {m:ℕ⁺| icompact([r(-m), r(m)])}
6. j : ℕ⁺
7. N : ℕ
8. c : ℝ
9. r0 < c
10. ∀k:{N...}. ∀x:{x:ℝ| |x| ≤ r(m)} . (|F[k;x]| ≤ c)
11. r0 < |c|
12. r0 < r(j)
13. v : ℝ
14. (|c| * r(j)) = v ∈ ℝ
15. r0 < v
16. ∃k:ℕ⁺. ((r1/r(k)) < (r1/v))
⊢ ∃M:ℕ⁺. ∀k:{M...}. (|(r^k/r((k)!))| ≤ (r1/v))

Latex:

Latex:
1. F : \mBbbN{} {}\mrightarrow{} \mBbbR{} {}\mrightarrow{} \mBbbR{} 2. \mforall{}k:\mBbbN{}. \mforall{}x,y:\mBbbR{}. ((x = y) {}\mRightarrow{} (F[k;x] = F[k;y])) 3. infinite-deriv-seq((-\minfty{}, \minfty{});i,x.F[i;x]) 4. r : \{r:\mBbbR{}| r0 \mleq{} r\} 5. m : \{m:\mBbbN{}\msupplus{}| icompact([r(-m), r(m)])\} 6. j : \mBbbN{}\msupplus{} 7. N : \mBbbN{} 8. c : \mBbbR{} 9. r0 < c 10. \mforall{}k:\{N...\}. \mforall{}x:\{x:\mBbbR{}| |x| \mleq{} r(m)\} . (|F[k;x]| \mleq{} c) 11. r0 < |c| 12. r0 < r(j) 13. v : \mBbbR{} 14. (|c| * r(j)) = v 15. r0 < v \mvdash{} \mexists{}M:\mBbbN{}\msupplus{}. \mforall{}k:\{M...\}. (|(r\^{}k/r((k)!))| \mleq{} (r1/v)) By Latex: (InstLemma `small-reciprocal-real` [\mkleeneopen{}(r1/v)\mkleeneclose{}]\mcdot{} THENA (Auto THEN MemTypeCD THEN Try (nRMul \mkleeneopen{}v\mkleeneclose{} 0\mcdot{}) THEN Auto) ) Home Index