# Can a limit of an integral be moved inside the integral?

After coming across this question: How to verify this limit, I have the following question:

When taking the limit of an integral, is it valid to move the limit inside the integral, providing the limit does not affect the limits of integration?

For instance in the question, the OP is trying to determine that:

$$\lim_{n\to\infty}\int_{0}^{1}{\frac{dx}{(1+\frac{x}{n})^{n}}}=1-\rm{e}^{-1}$$

The answers to the question involve evaluating the integral and then taking the limit to prove the result; but I was wondering if it would be valid to move the integral inside the limit, that is:

$$\lim_{n\to\infty}{\int_{0}^{1}{\frac{dx}{(1+\frac{x}{n})^{n}}}}=\int_{0}^{1}{\lim_{n\to\infty}\frac{dx}{(1+\frac{x}{n})^{n}}}=\int_{0}^{1}{\frac{dx}{{\rm{e}}^x}}=\rm{e}^{0}-\rm{e}^{-1}=1-\rm{e}^{-1}$$

As required. So is this a valid technique, or is it just coincidental that this works?

Check :

\displaystyle\begin{align}\lim\limits_{n\to\infty}\int_0^1&\dfrac{dx}{\left(1+\dfrac xn\right)^n}=\lim\limits_{n\to\infty}\left[\dfrac{-n}{n-1}\left(1+\dfrac xn\right)^{1-n}\,\right]_0^1=\\ &=\lim\limits_{n\to\infty}\dfrac{-n}{n-1}\left[\left(1+\dfrac1n\right)^{1-n}-1\right]=\\ &=\lim\limits_{n\to\infty}\dfrac n{n-1}\left[1-\left(1+\dfrac1n\right)^{1-n}\,\right]=\\ &=\lim\limits_{n\to\infty}\dfrac n{n-1}\left[1-\dfrac{\left(1+\dfrac1n\right)}{\left(1+\dfrac1n\right)^n}\,\right]=\\ &=1\cdot\left[1-\dfrac1{\rm{e}}\right]=\\ &=1-\rm{e}^{-1} \end{align}

\displaystyle\begin{align}\int_0^1 \lim\limits_{n\to\infty}\dfrac{dx}{\left(1+\dfrac xn\right)^n}&=\int_0^1\dfrac{dx}{{\rm{e}}^x}=\bigg[\!-{\rm{e}}^{-x}\bigg]_0^1=\\ &=\rm{e}^0-\rm{e}^{-1}=1-\rm{e}^{-1} \end{align}

• If $\: f_n \longrightarrow f \:$ uniformly and the interval is finite, then you are allowed to do so. $\hspace{1.2 in}$
– user57159
Commented Dec 8, 2012 at 11:31

Taking the limit inside the integral is not always allowed. There are several theorems that allow you to do so. The major ones being Lebesgue dominated convergence theorem and Monotone convergence theorem.

The uniform convergence mentioned in the comments is a special case of Dominated convergence theorem.

• If you know that the limit function is integrable, uniform convergence is enough. DCT and MCT go a step further and ensure that the limit is also integrable. Commented Feb 4, 2019 at 21:53
• Can I get an explaination to why it is a special case of the Dominated convergence theorem?
– Algo
Commented May 10, 2022 at 19:45
• @Cantor could you please explain how this is a special case of DCT? Commented Dec 29, 2022 at 17:24

The limit can be moved inside the integral if the convergence of the integrand is uniform. In our case if $$f_n(x)=(1+\frac{x}{n})^{-n}$$, then $$\lim_{n\to +\infty}f_n(x)=e^{-x}=f(x)$$ We need to show that on $$[0,1]$$, $$\left\|f_n-f \right\|_{\infty}\to 0$$ But $$\left\|f_n-f \right\|_{\infty}=\sup_{x\in [0,1]}\left|f_n(x)-f(x)\right|= \sup_{x\in [0,1]}\left|(1+\frac{x}{n})^{-n}-e^{-x}\right|$$ We need to determine the maximum of $$g_n(x)=(1+\frac{x}{n})^{-n}-e^{-x}$$ on $$[0,1]$$ or at least show it converges to $$0$$.

$$g_n(0)=0$$, $$g_n(1)=(1+\frac1n)^{-n}-e^{-1}$$ and $$g_n^{\prime}(x_0)=0\Leftrightarrow (1+\frac{x_0}{n})^{-n-1}=e^{-x_0}$$ Whenever the latter is true, $$g_n(x_0)=\frac{x_0}{n}e^{-x_0}$$. Therefore, $$\left\|f_n-f \right\|_{\infty}=\max_{x\in [0,1]}\left|g_n(x)\right|=\max\left\{g_n(0),g_n(1),g_n(x_0)\right\}=\max\left\{0,(1+\frac1n)^{-n}-e^{-1},\frac{x_0}{n}e^{-x_0}\right\}\to 0$$ as $$n\to +\infty$$. Uniform convergence on $$[0,1]$$ is proven and the limit-integral interchange can be done

• Why the $g_n(x_0)$ is not equal to $e^{-x_0}\frac{x_0}{n}$ ? Commented Sep 17, 2018 at 11:11
• Hi @Nameless! I'm obviously a newbie here. So pardon me to ask this. Why is it sufficient to show that $\| f_n-f\|_{\infty} \rightarrow 0$ to show that $f_n$ converges uniformly? :) Commented Feb 28, 2019 at 2:56
• The expression $\|f_n - f\|_\infty \to 0$ is equivalent with $\forall \epsilon>0 :\exists N \in \mathbb N: \forall n > N: \sup_{x \in \mathbb R} |f_n(x) - f(x)| < \epsilon$. By the definition of supremum, we get that $|f_n(x) - f(x)| < \epsilon$ for all $x \in \mathbb R$. In other words, for all $\epsilon>0$, we find an $N$, independent of $x$ such that if $n>N$, $|f_n(x) - f(x) | < \epsilon$ for all $x \in \mathbb R$, which is exactly the definition of uniform convergence. Commented Mar 13, 2019 at 14:13

There's a recent paper that exactly answers this question.

Kamihigashi, T. Interchanging a limit and an integral: necessary and sufficient conditions. J Inequal Appl 2020, 243 (2020).

https://doi.org/10.1186/s13660-020-02502-w

The main result gives a necessary and sufficient condition under which the limit can be moved inside the integral. The exact condition is somewhat complicated, but it's strictly weaker than uniform integrability.

• Interesting. Doesn't seem as easy to apply, but very interesting that it's both necessary and sufficient. And there's a nice example. If I were an analyst I'd be all over this thing. Commented Apr 26, 2021 at 5:35