Proof of Nuprl Lemma : poly-approx-aux-property

Step * 2 1 1 1 of Lemma poly-approx-aux-property

.....aux.....
1. k : ℤ
2. 0 < k
3. a : ℕ ⟶ ℝ
4. x : ℝ
5. xM : ℤ
6. M : ℕ⁺
7. ∀[n:ℕ]
     ((|x| ≤ (r1/r(4)))
     ⇒ 1-approx(x;M;xM)
     ⇒ (k - 1) + 1-approx(Σ{(a (n + i)) * x^i | 0≤i≤k - 1};M;poly-approx-aux(a;x;xM;M;n;k - 1)))
8. n : ℕ
9. |x| ≤ (r1/r(4))
10. 1-approx(x;M;xM)
11. k-approx(Σ{(a ((n + 1) + i)) * x^i | 0≤i≤k - 1};M;poly-approx-aux(a;x;xM;M;n + 1;k - 1))

⊢ Σ{(a (n + i + 1)) * x^i + 1 | 0≤i≤k - 1} = (x * Σ{(a ((n + 1) + i)) * x^i | 0≤i≤k - 1})

{ ((RWO "rsum_linearity2<" 0 THEN Auto) THEN (BLemma `rsum_functionality` THEN Auto) THEN D 0 THEN Auto) }

Latex:

Latex:
.....aux..... 1. k : \mBbbZ{} 2. 0 < k 3. a : \mBbbN{} {}\mrightarrow{} \mBbbR{} 4. x : \mBbbR{} 5. xM : \mBbbZ{} 6. M : \mBbbN{}\msupplus{} 7. \mforall{}[n:\mBbbN{}] ((|x| \mleq{} (r1/r(4))) {}\mRightarrow{} 1-approx(x;M;xM) {}\mRightarrow{} (k - 1) + 1-approx(\mSigma{}\{(a (n + i)) * x\^{}i | 0\mleq{}i\mleq{}k - 1\};M;poly-approx-aux(a;x;xM;M;n;k - 1))) 8. n : \mBbbN{} 9. |x| \mleq{} (r1/r(4)) 10. 1-approx(x;M;xM) 11. k-approx(\mSigma{}\{(a ((n + 1) + i)) * x\^{}i | 0\mleq{}i\mleq{}k - 1\};M;poly-approx-aux(a;x;xM;M;n + 1;k - 1)) \mvdash{} \mSigma{}\{(a (n + i + 1)) * x\^{}i + 1 | 0\mleq{}i\mleq{}k - 1\} = (x * \mSigma{}\{(a ((n + 1) + i)) * x\^{}i | 0\mleq{}i\mleq{}k - 1\}) By Latex: ((RWO "rsum\_linearity2<" 0 THEN Auto) THEN (BLemma `rsum\_functionality` THEN Auto) THEN D 0 THEN Auto) Home Index