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

Step * 2 1 2 of Lemma Taylor-series-converges-everywhere

1. a : ℝ
2. F : ℕ ⟶ ℝ ⟶ ℝ
3. ∀k:ℕ. ∀x,y:ℝ. ((x = y) ⇒ (F[k;x] = F[k;y]))
4. ∀i:ℕ. d(F[i;x])/dx = λx.F[i + 1;x] on (-∞, ∞)
5. ∀r:{r:ℝ| r0 ≤ r} . lim k→∞.r^k * (F[k + 1;x]/r((k)!)) = λx.r0 for x ∈ (-∞, ∞)
6. m : ℕ⁺
7. [%4] : icompact([r(-m), r(m)])
8. t : {t:ℝ| r0 < t}
9. [r(-m), r(m)] ⊆ (a - t, a + t)
10. i : ℕ
11. d(F[i;x])/dx = λx.F[i + 1;x] on (-∞, ∞)
12. (a - t, a + t) ⊆ (-∞, ∞)
⊢ d(F[i;x])/dx = λx.F[i + 1;x] on (a - t, a + t)
BY
{ (FLemma `derivative_functionality_wrt_subinterval` [-1;-2]⋅ THEN Auto) }

Latex:

Latex:
1. a : \mBbbR{} 2. F : \mBbbN{} {}\mrightarrow{} \mBbbR{} {}\mrightarrow{} \mBbbR{} 3. \mforall{}k:\mBbbN{}. \mforall{}x,y:\mBbbR{}. ((x = y) {}\mRightarrow{} (F[k;x] = F[k;y])) 4. \mforall{}i:\mBbbN{}. d(F[i;x])/dx = \mlambda{}x.F[i + 1;x] on (-\minfty{}, \minfty{}) 5. \mforall{}r:\{r:\mBbbR{}| r0 \mleq{} r\} . lim k\mrightarrow{}\minfty{}.r\^{}k * (F[k + 1;x]/r((k)!)) = \mlambda{}x.r0 for x \mmember{} (-\minfty{}, \minfty{}) 6. m : \mBbbN{}\msupplus{} 7. [\%4] : icompact([r(-m), r(m)]) 8. t : \{t:\mBbbR{}| r0 < t\} 9. [r(-m), r(m)] \msubseteq{} (a - t, a + t) 10. i : \mBbbN{} 11. d(F[i;x])/dx = \mlambda{}x.F[i + 1;x] on (-\minfty{}, \minfty{}) 12. (a - t, a + t) \msubseteq{} (-\minfty{}, \minfty{}) \mvdash{} d(F[i;x])/dx = \mlambda{}x.F[i + 1;x] on (a - t, a + t) By Latex: (FLemma `derivative\_functionality\_wrt\_subinterval` [-1;-2]\mcdot{} THEN Auto) Home Index