Proof of Nuprl Lemma : Taylor-remainder-as-integral

Step * 1 1 3 1 2 of Lemma Taylor-remainder-as-integral

1. I : Interval
2. iproper(I)
3. a : {a:ℝ| a ∈ I}
4. b : {a:ℝ| a ∈ I}
5. [rmin(a;b), rmax(a;b)] ⊆ I
6. F : ℕ2 ⟶ I ⟶ℝ
7. ∀k:ℕ2. ∀x,y:{a:ℝ| a ∈ I} .  ((x = y) ⇒ (F[k;x] = F[k;y]))
8. finite-deriv-seq(I;1;i,x.F[i;x])
9. a_∫^-b F[1;t] dt = (F[0;b] - F[0;a])
10. a_∫^-b (F[1;t]/r1) * r1 dt = a_∫^-b F[1;t] dt
⊢ (F[0;b] - (F[0;a]/r((0)!)) * b - a^0) = a_∫^-b (F[1;t]/r1) * r1 dt
BY
{ (RWO  "-1" 0 THENA Auto) }

1
1. I : Interval
2. iproper(I)
3. a : ℝ
4. a ∈ I
5. b : ℝ
6. b ∈ I
7. [rmin(a;b), rmax(a;b)] ⊆ I
8. F : ℕ2 ⟶ I ⟶ℝ
9. ∀k:ℕ2. ∀x,y:{a:ℝ| a ∈ I} .  ((x = y) ⇒ ((F k x) = (F k y)))
10. finite-deriv-seq(I;1;i,x.F i x)
11. a_∫^-b F 1 t dt = ((F 0 b) - F 0 a)
12. a_∫^-b (F 1 t/r1) * r1 dt = a_∫^-b F 1 t dt
13. x : {x:ℝ| x ∈ [rmin(a;b), rmax(a;b)]}
14. y : {x:ℝ| x ∈ [rmin(a;b), rmax(a;b)]}
15. x = y
⊢ ((F 1 x/r1) * r1) = ((F 1 y/r1) * r1)

2
1. I : Interval
2. iproper(I)
3. a : {a:ℝ| a ∈ I}
4. b : {a:ℝ| a ∈ I}
5. [rmin(a;b), rmax(a;b)] ⊆ I
6. F : ℕ2 ⟶ I ⟶ℝ
7. ∀k:ℕ2. ∀x,y:{a:ℝ| a ∈ I} .  ((x = y) ⇒ (F[k;x] = F[k;y]))
8. finite-deriv-seq(I;1;i,x.F[i;x])
9. a_∫^-b F[1;t] dt = (F[0;b] - F[0;a])
10. a_∫^-b (F[1;t]/r1) * r1 dt = a_∫^-b F[1;t] dt
⊢ (F[0;b] - (F[0;a]/r((0)!)) * b - a^0) = a_∫^-b F[1;t] dt

Latex:

Latex:
1. I : Interval 2. iproper(I) 3. a : \{a:\mBbbR{}| a \mmember{} I\} 4. b : \{a:\mBbbR{}| a \mmember{} I\} 5. [rmin(a;b), rmax(a;b)] \msubseteq{} I 6. F : \mBbbN{}2 {}\mrightarrow{} I {}\mrightarrow{}\mBbbR{} 7. \mforall{}k:\mBbbN{}2. \mforall{}x,y:\{a:\mBbbR{}| a \mmember{} I\} . ((x = y) {}\mRightarrow{} (F[k;x] = F[k;y])) 8. finite-deriv-seq(I;1;i,x.F[i;x]) 9. a\_\mint{}\msupminus{}b F[1;t] dt = (F[0;b] - F[0;a]) 10. a\_\mint{}\msupminus{}b (F[1;t]/r1) * r1 dt = a\_\mint{}\msupminus{}b F[1;t] dt \mvdash{} (F[0;b] - (F[0;a]/r((0)!)) * b - a\^{}0) = a\_\mint{}\msupminus{}b (F[1;t]/r1) * r1 dt By Latex: (RWO "-1" 0 THENA Auto) Home Index