Proof of Nuprl Lemma : small-rexp-remainder

Step * 2 1 of Lemma small-rexp-remainder

1. x : {x:ℝ| |x| ≤ (r1/r(4))}
2. n : ℕ
3. ¬(n = 0 ∈ ℤ)
4. e : {e:ℝ| r0 < e}
5. c : ℝ
6. rmin(r0;x) ≤ c
7. c ≤ rmax(r0;x)
8. |Taylor-remainder((-∞, ∞);n;x;r0;k,x.e^x) - (x - c^n * (e^c/r((n)!))) * (x - r0)| ≤ e
⊢ |e^x - Σ{(x^k/r((k)!)) | 0≤k≤n}| ≤ ((r1/r(4^n * 3 * (n)!)) + e)
BY
{ Assert ⌜(e^x - Σ{(x^k/r((k)!)) | 0≤k≤n}) = Taylor-remainder((-∞, ∞);n;x;r0;k,x.e^x)⌝⋅ }

1
.....assertion.....
1. x : {x:ℝ| |x| ≤ (r1/r(4))}
2. n : ℕ
3. ¬(n = 0 ∈ ℤ)
4. e : {e:ℝ| r0 < e}
5. c : ℝ
6. rmin(r0;x) ≤ c
7. c ≤ rmax(r0;x)
8. |Taylor-remainder((-∞, ∞);n;x;r0;k,x.e^x) - (x - c^n * (e^c/r((n)!))) * (x - r0)| ≤ e
⊢ (e^x - Σ{(x^k/r((k)!)) | 0≤k≤n}) = Taylor-remainder((-∞, ∞);n;x;r0;k,x.e^x)

2
1. x : {x:ℝ| |x| ≤ (r1/r(4))}
2. n : ℕ
3. ¬(n = 0 ∈ ℤ)
4. e : {e:ℝ| r0 < e}
5. c : ℝ
6. rmin(r0;x) ≤ c
7. c ≤ rmax(r0;x)
8. |Taylor-remainder((-∞, ∞);n;x;r0;k,x.e^x) - (x - c^n * (e^c/r((n)!))) * (x - r0)| ≤ e
9. (e^x - Σ{(x^k/r((k)!)) | 0≤k≤n}) = Taylor-remainder((-∞, ∞);n;x;r0;k,x.e^x)
⊢ |e^x - Σ{(x^k/r((k)!)) | 0≤k≤n}| ≤ ((r1/r(4^n * 3 * (n)!)) + e)

Latex:

Latex:
1. x : \{x:\mBbbR{}| |x| \mleq{} (r1/r(4))\} 2. n : \mBbbN{} 3. \mneg{}(n = 0) 4. e : \{e:\mBbbR{}| r0 < e\} 5. c : \mBbbR{} 6. rmin(r0;x) \mleq{} c 7. c \mleq{} rmax(r0;x) 8. |Taylor-remainder((-\minfty{}, \minfty{});n;x;r0;k,x.e\^{}x) - (x - c\^{}n * (e\^{}c/r((n)!))) * (x - r0)| \mleq{} e \mvdash{} |e\^{}x - \mSigma{}\{(x\^{}k/r((k)!)) | 0\mleq{}k\mleq{}n\}| \mleq{} ((r1/r(4\^{}n * 3 * (n)!)) + e) By Latex: Assert \mkleeneopen{}(e\^{}x - \mSigma{}\{(x\^{}k/r((k)!)) | 0\mleq{}k\mleq{}n\}) = Taylor-remainder((-\minfty{}, \minfty{});n;x;r0;k,x.e\^{}x)\mkleeneclose{}\mcdot{} Home Index