Proof of Nuprl Lemma : derivative-cosine

Step * 2 2 2 of Lemma derivative-cosine

1. lim n→∞.Σ{-1^i * (x^2 * i)/(2 * i)! | 0≤i≤n} = λx.cosine(x) for x ∈ (-∞, ∞)
2. n : ℕ
3. d(Σ{r(-1^i) * (x^2 * i/r((2 * i)!)) | 0≤i≤n})/dx = λx.Σ{r(-1^i)

* (if (i =_z 0) then r0 else r(2 * i) * x^(2 * i) - 1 fi /r((2 * i)!)) | 0≤i≤n} on (-∞, ∞)

4. x : {x:ℝ| x ∈ (-∞, ∞)}

⊢ Σ{r(-1^i) * (if (i =_z 0) then r0 else r(2 * i) * x^(2 * i) - 1 fi /r((2 * i)!)) | 0≤i≤n}

= -(Σ{-1^i * (x^(2 * i) + 1)/((2 * i) + 1)! | 0≤i≤n - 1})
BY
{ (RWW "rminus-as-rmul rsum_linearity2<" 0 THENA Auto) }

1
1. lim n→∞.Σ{-1^i * (x^2 * i)/(2 * i)! | 0≤i≤n} = λx.cosine(x) for x ∈ (-∞, ∞)
2. n : ℕ
3. d(Σ{r(-1^i) * (x^2 * i/r((2 * i)!)) | 0≤i≤n})/dx = λx.Σ{r(-1^i)

* (if (i =_z 0) then r0 else r(2 * i) * x^(2 * i) - 1 fi /r((2 * i)!)) | 0≤i≤n} on (-∞, ∞)

4. x : {x:ℝ| x ∈ (-∞, ∞)}

⊢ Σ{r(-1^i) * (if (i =_z 0) then r0 else r(2 * i) * x^(2 * i) - 1 fi /r((2 * i)!)) | 0≤i≤n}

= Σ{r(-1) * -1^i * (x^(2 * i) + 1)/((2 * i) + 1)! | 0≤i≤n - 1}

Latex:

Latex:
1. lim n\mrightarrow{}\minfty{}.\mSigma{}\{-1\^{}i * (x\^{}2 * i)/(2 * i)! | 0\mleq{}i\mleq{}n\} = \mlambda{}x.cosine(x) for x \mmember{} (-\minfty{}, \minfty{}) 2. n : \mBbbN{} 3. d(\mSigma{}\{r(-1\^{}i) * (x\^{}2 * i/r((2 * i)!)) | 0\mleq{}i\mleq{}n\})/dx = \mlambda{}x.\mSigma{}\{r(-1\^{}i) * (if (i =\msubz{} 0) then r0 else r(2 * i) * x\^{}(2 * i) - 1 fi /r((2 * i)!)) | 0\mleq{}i\mleq{}n\} on (-\minfty{}, \minfty{}) 4. x : \{x:\mBbbR{}| x \mmember{} (-\minfty{}, \minfty{})\} \mvdash{} \mSigma{}\{r(-1\^{}i) * (if (i =\msubz{} 0) then r0 else r(2 * i) * x\^{}(2 * i) - 1 fi /r((2 * i)!)) | 0\mleq{}i\mleq{}n\} = -(\mSigma{}\{-1\^{}i * (x\^{}(2 * i) + 1)/((2 * i) + 1)! | 0\mleq{}i\mleq{}n - 1\}) By Latex: (RWW "rminus-as-rmul rsum\_linearity2<" 0 THENA Auto) Home Index