Proof of Nuprl Lemma : arctan-poly-approx-1

Step * 2 1 2 1 of Lemma arctan-poly-approx-1

1. ∀x:ℝ. (r0 < (r1 + x^2))
2. ∀x:ℝ. -(x^2) ≠ r1
3. x : {x:ℝ| r0 ≤ x}
4. k : ℕ

5. r0_∫^-x (r1/r1 + x^2) - Σ{-(x^2)^i | 0≤i≤k} dx = (arctangent(x) - r0_∫^-x Σ{-(x^2)^i | 0≤i≤k} dx)

6. (arctangent(x) - arctan-poly(x;k)) = (arctangent(x) - r0_∫^-x Σ{-(x^2)^i | 0≤i≤k} dx)
7. r0_∫^-x (r1/r1 + x^2) - Σ{-(x^2)^i | 0≤i≤k} dx = r0_∫^-x (-(x^2)^k + 1/r1 + x^2) dx
⊢ |r0_∫^-x (-(x^2)^k + 1/r1 + x^2) dx| ≤ (x^(2 * k) + 3/r((2 * k) + 3))
BY

{ (Assert r0_∫^-x (-(x^2)^k + 1/r1 + x^2) dx = (r(-1)^k + 1 * r0_∫^-x (x^2^k + 1/r1 + x^2) dx) BY

(RWO "integral-rmul-const<" 0 THENA Auto)) }

1
1. ∀x:ℝ. (r0 < (r1 + x^2))
2. ∀x:ℝ. -(x^2) ≠ r1
3. x : {x:ℝ| r0 ≤ x}
4. k : ℕ

5. r0_∫^-x (r1/r1 + x^2) - Σ{-(x^2)^i | 0≤i≤k} dx = (arctangent(x) - r0_∫^-x Σ{-(x^2)^i | 0≤i≤k} dx)

6. (arctangent(x) - arctan-poly(x;k)) = (arctangent(x) - r0_∫^-x Σ{-(x^2)^i | 0≤i≤k} dx)
7. r0_∫^-x (r1/r1 + x^2) - Σ{-(x^2)^i | 0≤i≤k} dx = r0_∫^-x (-(x^2)^k + 1/r1 + x^2) dx
⊢ r0_∫^-x (-(x^2)^k + 1/r1 + x^2) dx = r0_∫^-x r(-1)^k + 1 * (x^2^k + 1/r1 + x^2) dx

2
1. ∀x:ℝ. (r0 < (r1 + x^2))
2. ∀x:ℝ. -(x^2) ≠ r1
3. x : {x:ℝ| r0 ≤ x}
4. k : ℕ

5. r0_∫^-x (r1/r1 + x^2) - Σ{-(x^2)^i | 0≤i≤k} dx = (arctangent(x) - r0_∫^-x Σ{-(x^2)^i | 0≤i≤k} dx)

6. (arctangent(x) - arctan-poly(x;k)) = (arctangent(x) - r0_∫^-x Σ{-(x^2)^i | 0≤i≤k} dx)
7. r0_∫^-x (r1/r1 + x^2) - Σ{-(x^2)^i | 0≤i≤k} dx = r0_∫^-x (-(x^2)^k + 1/r1 + x^2) dx
8. r0_∫^-x (-(x^2)^k + 1/r1 + x^2) dx = (r(-1)^k + 1 * r0_∫^-x (x^2^k + 1/r1 + x^2) dx)
⊢ |r0_∫^-x (-(x^2)^k + 1/r1 + x^2) dx| ≤ (x^(2 * k) + 3/r((2 * k) + 3))

Latex:

Latex:
1. \mforall{}x:\mBbbR{}. (r0 < (r1 + x\^{}2)) 2. \mforall{}x:\mBbbR{}. -(x\^{}2) \mneq{} r1 3. x : \{x:\mBbbR{}| r0 \mleq{} x\} 4. k : \mBbbN{} 5. r0\_\mint{}\msupminus{}x (r1/r1 + x\^{}2) - \mSigma{}\{-(x\^{}2)\^{}i | 0\mleq{}i\mleq{}k\} dx = (arctangent(x) - r0\_\mint{}\msupminus{}x \mSigma{}\{-(x\^{}2)\^{}i | 0\mleq{}i\mleq{}k\} dx) 6. (arctangent(x) - arctan-poly(x;k)) = (arctangent(x) - r0\_\mint{}\msupminus{}x \mSigma{}\{-(x\^{}2)\^{}i | 0\mleq{}i\mleq{}k\} dx) 7. r0\_\mint{}\msupminus{}x (r1/r1 + x\^{}2) - \mSigma{}\{-(x\^{}2)\^{}i | 0\mleq{}i\mleq{}k\} dx = r0\_\mint{}\msupminus{}x (-(x\^{}2)\^{}k + 1/r1 + x\^{}2) dx \mvdash{} |r0\_\mint{}\msupminus{}x (-(x\^{}2)\^{}k + 1/r1 + x\^{}2) dx| \mleq{} (x\^{}(2 * k) + 3/r((2 * k) + 3)) By Latex: (Assert r0\_\mint{}\msupminus{}x (-(x\^{}2)\^{}k + 1/r1 + x\^{}2) dx = (r(-1)\^{}k + 1 * r0\_\mint{}\msupminus{}x (x\^{}2\^{}k + 1/r1 + x\^{}2) dx) BY (RWO "integral-rmul-const<" 0 THENA Auto)) Home Index