Proof of Nuprl Lemma : Taylor-theorem-case1

Step * 1 1 of Lemma Taylor-theorem-case1

1. I : Interval
2. n : ℕ
3. F : ℕn + 2 ⟶ I ⟶ℝ
4. ∀b:{a:ℝ| a ∈ I}
     ((∀k:ℕn + 2. ∀x,y:{a:ℝ| a ∈ I} .  ((x = y) ⇒ (F[k;x] = F[k;y])))
     ⇒ finite-deriv-seq(I;n + 1;i,x.F[i;x])
     ⇒ d(Taylor-approx(n;a;b;i,x.F[i;x]))/da = λx.b - x^n * (F[n + 1;x]/r((n)!)) on I)
5. a : {a:ℝ| a ∈ I}
6. b : {a:ℝ| a ∈ I}
7. ∀k:ℕn + 2. ∀x,y:{a:ℝ| a ∈ I} .  ((x = y) ⇒ (F[k;x] = F[k;y]))
8. finite-deriv-seq(I;n + 1;i,x.F[i;x])
9. d(Taylor-approx(n;a;b;i,x.F[i;x]))/da = λx.b - x^n * (F[n + 1;x]/r((n)!)) on I
10. b - a ≠ r0
11. e : ℝ
12. r0 < e
13. R : ℝ
14. Taylor-remainder(I;n;b;a;k,x.F[k;x]) = R ∈ ℝ

⊢ ∃c:ℝ. ((rmin(a;b) ≤ c) ∧ (c ≤ rmax(a;b)) ∧ (|R - (b - c^n * (F[n + 1;c]/r((n)!))) * (b - a)| ≤ e))

BY
{ ((Assert [rmin(a;b), rmax(a;b)] ⊆ I  BY
          (BLemma `rcc-subinterval` THEN EAuto 1))
   THEN (Assert rmin(a;b) < rmax(a;b) BY
               (BLemma `rmax_strict_ub`
                THEN Auto
                THEN Unfold `rneq` 10
                THEN ParallelOp 10
                THEN BLemma `rmin_strict_lb`
                THEN Auto
                THEN nRAdd ⌜a⌝ 10⋅
                THEN Auto))
   ) }

1
1. I : Interval
2. n : ℕ
3. F : ℕn + 2 ⟶ I ⟶ℝ
4. ∀b:{a:ℝ| a ∈ I}
     ((∀k:ℕn + 2. ∀x,y:{a:ℝ| a ∈ I} .  ((x = y) ⇒ (F[k;x] = F[k;y])))
     ⇒ finite-deriv-seq(I;n + 1;i,x.F[i;x])
     ⇒ d(Taylor-approx(n;a;b;i,x.F[i;x]))/da = λx.b - x^n * (F[n + 1;x]/r((n)!)) on I)
5. a : {a:ℝ| a ∈ I}
6. b : {a:ℝ| a ∈ I}
7. ∀k:ℕn + 2. ∀x,y:{a:ℝ| a ∈ I} .  ((x = y) ⇒ (F[k;x] = F[k;y]))
8. finite-deriv-seq(I;n + 1;i,x.F[i;x])
9. d(Taylor-approx(n;a;b;i,x.F[i;x]))/da = λx.b - x^n * (F[n + 1;x]/r((n)!)) on I
10. b - a ≠ r0
11. e : ℝ
12. r0 < e
13. R : ℝ
14. Taylor-remainder(I;n;b;a;k,x.F[k;x]) = R ∈ ℝ
15. [rmin(a;b), rmax(a;b)] ⊆ I
16. rmin(a;b) < rmax(a;b)

⊢ ∃c:ℝ. ((rmin(a;b) ≤ c) ∧ (c ≤ rmax(a;b)) ∧ (|R - (b - c^n * (F[n + 1;c]/r((n)!))) * (b - a)| ≤ e))

Latex:

Latex:
1. I : Interval 2. n : \mBbbN{} 3. F : \mBbbN{}n + 2 {}\mrightarrow{} I {}\mrightarrow{}\mBbbR{} 4. \mforall{}b:\{a:\mBbbR{}| a \mmember{} I\} ((\mforall{}k:\mBbbN{}n + 2. \mforall{}x,y:\{a:\mBbbR{}| a \mmember{} I\} . ((x = y) {}\mRightarrow{} (F[k;x] = F[k;y]))) {}\mRightarrow{} finite-deriv-seq(I;n + 1;i,x.F[i;x]) {}\mRightarrow{} d(Taylor-approx(n;a;b;i,x.F[i;x]))/da = \mlambda{}x.b - x\^{}n * (F[n + 1;x]/r((n)!)) on I) 5. a : \{a:\mBbbR{}| a \mmember{} I\} 6. b : \{a:\mBbbR{}| a \mmember{} I\} 7. \mforall{}k:\mBbbN{}n + 2. \mforall{}x,y:\{a:\mBbbR{}| a \mmember{} I\} . ((x = y) {}\mRightarrow{} (F[k;x] = F[k;y])) 8. finite-deriv-seq(I;n + 1;i,x.F[i;x]) 9. d(Taylor-approx(n;a;b;i,x.F[i;x]))/da = \mlambda{}x.b - x\^{}n * (F[n + 1;x]/r((n)!)) on I 10. b - a \mneq{} r0 11. e : \mBbbR{} 12. r0 < e 13. R : \mBbbR{} 14. Taylor-remainder(I;n;b;a;k,x.F[k;x]) = R \mvdash{} \mexists{}c:\mBbbR{}. ((rmin(a;b) \mleq{} c) \mwedge{} (c \mleq{} rmax(a;b)) \mwedge{} (|R - (b - c\^{}n * (F[n + 1;c]/r((n)!))) * (b - a)| \mleq{} e)) By Latex: ((Assert [rmin(a;b), rmax(a;b)] \msubseteq{} I BY (BLemma `rcc-subinterval` THEN EAuto 1)) THEN (Assert rmin(a;b) < rmax(a;b) BY (BLemma `rmax\_strict\_ub` THEN Auto THEN Unfold `rneq` 10 THEN ParallelOp 10 THEN BLemma `rmin\_strict\_lb` THEN Auto THEN nRAdd \mkleeneopen{}a\mkleeneclose{} 10\mcdot{} THEN Auto)) ) Home Index