$\newcommand{\br}{\\}$
$\newcommand{\R}{\mathbb{R}}$
$\newcommand{\Q}{\mathbb{Q}}$
$\newcommand{\Z}{\mathbb{Z}}$
$\newcommand{\N}{\mathbb{N}}$
$\newcommand{\C}{\mathbb{C}}$
$\newcommand{\P}{\mathbb{P}}$
$\newcommand{\F}{\mathbb{F}}$
$\newcommand{\L}{\mathcal{L}}$
$\newcommand{\spa}[1]{\text{span}(#1)}$
$\newcommand{\dist}[1]{\text{dist}(#1)}$
$\newcommand{\max}[1]{\text{max}(#1)}$
$\newcommand{\min}[1]{\text{min}(#1)}$
$\newcommand{\supr}{\text{sup}}$
$\newcommand{\infi}{\text{inf}}$
$\newcommand{\ite}[1]{\text{int}(#1)}$
$\newcommand{\ext}[1]{\text{ext}(#1)}$
$\newcommand{\bdry}[1]{\partial #1}$
$\newcommand{\argmax}[1]{\underset{#1}{\text{argmax }}}$
$\newcommand{\argmin}[1]{\underset{#1}{\text{argmin }}}$
$\newcommand{\set}[1]{\left\{#1\right\}}$
$\newcommand{\emptyset}{\varnothing}$
$\newcommand{\tilde}{\text{~}}$
$\newcommand{\otherwise}{\text{ otherwise }}$
$\newcommand{\if}{\text{ if }}$
$\newcommand{\proj}{\text{proj}}$
$\newcommand{\union}{\cup}$
$\newcommand{\intercept}{\cap}$
$\newcommand{\abs}[1]{\left| #1 \right|}$
$\newcommand{\norm}[1]{\left\lVert#1\right\rVert}$
$\newcommand{\pare}[1]{\left(#1\right)}$
$\newcommand{\brac}[1]{\left[#1\right]}$
$\newcommand{\t}[1]{\text{ #1 }}$
$\newcommand{\head}{\text H}$
$\newcommand{\tail}{\text T}$
$\newcommand{\d}{\text d}$
$\newcommand{\limu}[2]{\underset{#1 \to #2}\lim}$
$\newcommand{\limsupu}[2]{\underset{#1 \to #2}{\lim\supr}}$
$\newcommand{\liminfu}[2]{\underset{#1 \to #2}{\lim\infi}}$
$\newcommand{\limd}[3]{\underset{#1 \to #2; #3}\lim}$
$\newcommand{\der}[2]{\frac{\d #1}{\d #2}}$
$\newcommand{\derw}[2]{\frac{\d #1^2}{\d^2 #2}}$
$\newcommand{\pder}[2]{\frac{\partial #1}{\partial #2}}$
$\newcommand{\pderw}[2]{\frac{\partial^2 #1}{\partial #2^2}}$
$\newcommand{\pderws}[3]{\frac{\partial^2 #1}{\partial #2 \partial #3}}$
$\newcommand{\inv}[1]{{#1}^{-1}}$
$\newcommand{\inner}[2]{\langle #1, #2 \rangle}$
$\newcommand{\nullity}[1]{\text{nullity}(#1)}$
$\newcommand{\rank}[1]{\text{rank }#1}$
$\newcommand{\nullspace}[1]{\mathcal{N}\pare{#1}}$
$\newcommand{\range}[1]{\mathcal{R}\pare{#1}}$
$\newcommand{\var}[1]{\text{var}\pare{#1}}$
$\newcommand{\cov}[2]{\text{cov}(#1, #2)}$
$\newcommand{\tr}[1]{\text{tr}(#1)}$
$\newcommand{\oto}{\text{ one-to-one }}$
$\newcommand{\ot}{\text{ onto }}$
$\newcommand{\ipto}{\overset{\text{i.p.}}\longrightarrow}$
$\newcommand{\asto}{\overset{\text{a.s.}}\longrightarrow}$
$\newcommand{\expdist}[1]{\text{ ~ Exp}(#1)}$
$\newcommand{\unifdist}[1]{\text{ ~ Unif}(#1)}$
$\newcommand{\normdist}[2]{\text{ ~ N}(#1,#2)}$
$\newcommand{\poissondist}[1]{\text{ ~ Poisson}(#1)}$
$\newcommand{\ceil}[1]{\lceil#1\rceil}$
$\newcommand{\floor}[1]{\lfloor#1\rfloor}$
$\newcommand{\Re}[1]{\text{Re}(#1)}$
$\newcommand{\Im}[1]{\text{Im}(#1)}$
$\newcommand{\dom}[1]{\text{dom}(#1)}$
$\newcommand{\fnext}[1]{\overset{\sim}{#1}}$
$\newcommand{\transpose}[1]{{#1}^{\text{T}}}$
$\newcommand{\b}[1]{\boldsymbol{#1}}$
$\newcommand{\None}[1]{}$
$\newcommand{\Vcw}[2]{\begin{bmatrix} #1 \br #2 \end{bmatrix}}$
$\newcommand{\Vce}[3]{\begin{bmatrix} #1 \br #2 \br #3 \end{bmatrix}}$
$\newcommand{\Vcr}[4]{\begin{bmatrix} #1 \br #2 \br #3 \br #4 \end{bmatrix}}$
$\newcommand{\Vct}[5]{\begin{bmatrix} #1 \br #2 \br #3 \br #4 \br #5 \end{bmatrix}}$
$\newcommand{\Vcy}[6]{\begin{bmatrix} #1 \br #2 \br #3 \br #4 \br #5 \br #6 \end{bmatrix}}$
$\newcommand{\Vcu}[7]{\begin{bmatrix} #1 \br #2 \br #3 \br #4 \br #5 \br #6 \br #7 \end{bmatrix}}$
$\newcommand{\vcw}[2]{\begin{matrix} #1 \br #2 \end{matrix}}$
$\newcommand{\vce}[3]{\begin{matrix} #1 \br #2 \br #3 \end{matrix}}$
$\newcommand{\vcr}[4]{\begin{matrix} #1 \br #2 \br #3 \br #4 \end{matrix}}$
$\newcommand{\vct}[5]{\begin{matrix} #1 \br #2 \br #3 \br #4 \br #5 \end{matrix}}$
$\newcommand{\vcy}[6]{\begin{matrix} #1 \br #2 \br #3 \br #4 \br #5 \br #6 \end{matrix}}$
$\newcommand{\vcu}[7]{\begin{matrix} #1 \br #2 \br #3 \br #4 \br #5 \br #6 \br #7 \end{matrix}}$
$\newcommand{\Mqw}[2]{\begin{bmatrix} #1 & #2 \end{bmatrix}}$
$\newcommand{\Mqe}[3]{\begin{bmatrix} #1 & #2 & #3 \end{bmatrix}}$
$\newcommand{\Mqr}[4]{\begin{bmatrix} #1 & #2 & #3 & #4 \end{bmatrix}}$
$\newcommand{\Mqt}[5]{\begin{bmatrix} #1 & #2 & #3 & #4 & #5 \end{bmatrix}}$
$\newcommand{\Mwq}[2]{\begin{bmatrix} #1 \br #2 \end{bmatrix}}$
$\newcommand{\Meq}[3]{\begin{bmatrix} #1 \br #2 \br #3 \end{bmatrix}}$
$\newcommand{\Mrq}[4]{\begin{bmatrix} #1 \br #2 \br #3 \br #4 \end{bmatrix}}$
$\newcommand{\Mtq}[5]{\begin{bmatrix} #1 \br #2 \br #3 \br #4 \br #5 \end{bmatrix}}$
$\newcommand{\Mqw}[2]{\begin{bmatrix} #1 & #2 \end{bmatrix}}$
$\newcommand{\Mwq}[2]{\begin{bmatrix} #1 \br #2 \end{bmatrix}}$
$\newcommand{\Mww}[4]{\begin{bmatrix} #1 & #2 \br #3 & #4 \end{bmatrix}}$
$\newcommand{\Mqe}[3]{\begin{bmatrix} #1 & #2 & #3 \end{bmatrix}}$
$\newcommand{\Meq}[3]{\begin{bmatrix} #1 \br #2 \br #3 \end{bmatrix}}$
$\newcommand{\Mwe}[6]{\begin{bmatrix} #1 & #2 & #3\br #4 & #5 & #6 \end{bmatrix}}$
$\newcommand{\Mew}[6]{\begin{bmatrix} #1 & #2 \br #3 & #4 \br #5 & #6 \end{bmatrix}}$
$\newcommand{\Mee}[9]{\begin{bmatrix} #1 & #2 & #3 \br #4 & #5 & #6 \br #7 & #8 & #9 \end{bmatrix}}$
Theorem
Let $ [a, b] $ be an interval, and for each integer $ n \geq 1 $, let $ f^{(n)}: [a, b] \to \R$ be a Riemann-integrable function. Suppose $ f^{(n)} $ converges uniformly on $ [a, b] $ to a function $ f:[a, b] \to \R $. Then $ f $ is also Rieman integrable, and
$$\limu{ n }{ \infty } \int_{ [a,b] } f^{(n)} = \int_{ [a,b] } f $$
Proof
</span>
</span>
<span class="proof__expand"><a>[expand]</a></span>