Proof of Nuprl Lemma : Riemann-integral-const

Step * 1 1 1 2 of Lemma Riemann-integral-const

1. a : ℝ
2. b : {b:ℝ| a ≤ b}
3. c : ℝ

4. ∀f:{f:[a, b] ⟶ℝ| ifun(f;[a, b])} . lim k→∞.Riemann-sum(λx.f[x];a;b;k + 1) = ∫ f[x] dx on [a, b]

5. ∀[y1,y2:ℝ].

     (y1 = y2) supposing (lim n→∞.Riemann-sum(λx.c;a;b;n + 1) = y2 and lim n→∞.Riemann-sum(λx.c;a;b;n + 1) = y1)

6. lim n→∞.c * (b - a) = c * (b - a) ⇒ lim n→∞.Riemann-sum(λx.c;a;b;n + 1) = c * (b - a)
⊢ lim n→∞.c * (b - a) = c * (b - a)
BY
{ Auto }

Latex:

Latex:
1. a : \mBbbR{} 2. b : \{b:\mBbbR{}| a \mleq{} b\} 3. c : \mBbbR{} 4. \mforall{}f:\{f:[a, b] {}\mrightarrow{}\mBbbR{}| ifun(f;[a, b])\} . lim k\mrightarrow{}\minfty{}.Riemann-sum(\mlambda{}x.f[x];a;b;k + 1) = \mint{} f[x] dx on [a, b] 5. \mforall{}[y1,y2:\mBbbR{}]. (y1 = y2) supposing (lim n\mrightarrow{}\minfty{}.Riemann-sum(\mlambda{}x.c;a;b;n + 1) = y2 and lim n\mrightarrow{}\minfty{}.Riemann-sum(\mlambda{}x.c;a;b;n + 1) = y1) 6. lim n\mrightarrow{}\minfty{}.c * (b - a) = c * (b - a) {}\mRightarrow{} lim n\mrightarrow{}\minfty{}.Riemann-sum(\mlambda{}x.c;a;b;n + 1) = c * (b - a) \mvdash{} lim n\mrightarrow{}\minfty{}.c * (b - a) = c * (b - a) By Latex: Auto Home Index