Proof of Nuprl Lemma : derivative-rpolynomial

Step * 2 1 2 2 1 of Lemma derivative-rpolynomial

1. n : ℤ
2. n ≠ 0
3. 0 < n
4. ∀a:ℕ(n - 1) + 1 ⟶ ℝ. ∀I:Interval.
     d((Σi≤n - 1. a_i * x^i))/dx = λx.if (n - 1 =_z 0)
     then r0
     else (Σi≤n - 1 - 1. λi.(r(i + 1) * (a (i + 1)))_i * x^i)
     fi  on I
5. a : ℕn + 1 ⟶ ℝ
6. I : Interval
7. d(((a n) * x^n) + (Σi≤n - 1. a_i * x^i))/dx = λx.(r(n) * (a n) * x^n - 1)

+ if (n - 1 =_z 0) then r0 else (Σi≤n - 1 - 1. λi.(r(i + 1) * (a (i + 1)))_i * x^i) fi  on I

8. x : {x:ℝ| x ∈ I}
9. (n - 1) = 0 ∈ ℤ
⊢ ((r(n) * (a n) * x^n - 1) + r0) = (r1 * (a 1))
BY
{ (HypSubst' (-1) 0 THEN Reduce 0) }

1
1. n : ℤ
2. n ≠ 0
3. 0 < n
4. ∀a:ℕ(n - 1) + 1 ⟶ ℝ. ∀I:Interval.
     d((Σi≤n - 1. a_i * x^i))/dx = λx.if (n - 1 =_z 0)
     then r0
     else (Σi≤n - 1 - 1. λi.(r(i + 1) * (a (i + 1)))_i * x^i)
     fi  on I
5. a : ℕn + 1 ⟶ ℝ
6. I : Interval
7. d(((a n) * x^n) + (Σi≤n - 1. a_i * x^i))/dx = λx.(r(n) * (a n) * x^n - 1)

+ if (n - 1 =_z 0) then r0 else (Σi≤n - 1 - 1. λi.(r(i + 1) * (a (i + 1)))_i * x^i) fi  on I

8. x : {x:ℝ| x ∈ I}
9. (n - 1) = 0 ∈ ℤ
⊢ ((r(n) * (a n) * r1) + r0) = (r1 * (a 1))

Latex:

Latex:
1. n : \mBbbZ{} 2. n \mneq{} 0 3. 0 < n 4. \mforall{}a:\mBbbN{}(n - 1) + 1 {}\mrightarrow{} \mBbbR{}. \mforall{}I:Interval. d((\mSigma{}i\mleq{}n - 1. a\_i * x\^{}i))/dx = \mlambda{}x.if (n - 1 =\msubz{} 0) then r0 else (\mSigma{}i\mleq{}n - 1 - 1. \mlambda{}i.(r(i + 1) * (a (i + 1)))\_i * x\^{}i) fi on I 5. a : \mBbbN{}n + 1 {}\mrightarrow{} \mBbbR{} 6. I : Interval 7. d(((a n) * x\^{}n) + (\mSigma{}i\mleq{}n - 1. a\_i * x\^{}i))/dx = \mlambda{}x.(r(n) * (a n) * x\^{}n - 1) + if (n - 1 =\msubz{} 0) then r0 else (\mSigma{}i\mleq{}n - 1 - 1. \mlambda{}i.(r(i + 1) * (a (i + 1)))\_i * x\^{}i) fi on I 8. x : \{x:\mBbbR{}| x \mmember{} I\} 9. (n - 1) = 0 \mvdash{} ((r(n) * (a n) * x\^{}n - 1) + r0) = (r1 * (a 1)) By Latex: (HypSubst' (-1) 0 THEN Reduce 0) Home Index