Stolz-Cesàro Theorem

Theorem
Let $\left({a_n}\right)$ be any sequence and $\left({b_n}\right)$ a sequence of positive real numbers such that $\displaystyle \sum_{i \mathop = 0}^{\infty}b_n = \infty$.

If:
 * $\displaystyle \lim_{n \mathop \to \infty}\dfrac{a_n}{b_n} = L \in \R$

then also:
 * $\displaystyle \lim_{n \mathop \to \infty}\dfrac{a_1 + a_2+ \cdots + a_n}{b_1 + b_2 + \cdots + b_n} = L$

Proof
Define the following sums:
 * $\displaystyle A_n = \sum_{i \mathop = 1}^{n}a_i$
 * $\displaystyle B_n = \sum_{i \mathop = 1}^{n}b_i$

Let $\varepsilon > 0$ and $\mu = \dfrac{\varepsilon}{2}$.

By the definition of convergent sequences, there exists $k \in \N$ such that:


 * $\displaystyle \left({L - \mu}\right) b_n < a_n < \left({L + \mu}\right) b_n$ for all $n > k$

Rewrite the sum as:

Divide above by $B_n$:
 * $\displaystyle \frac{A_k + \left({L-\mu}\right) B_k}{B_n} + \left({L - \mu}\right) < \frac{A_n}{B_n} < \left({L + \mu}\right) + \frac{A_k + \left({L+\mu}\right) B_k}{B_n}$

Let $k$ be fixed.

From Reciprocal of Null Sequence and Combination Theorem for Sequences, sequence $\displaystyle \left({\frac{A_k + \left({L \pm \varepsilon}\right) B_k}{B_n}}\right)$ converges to zero.

By the definition of convergent sequences, there exists $N > k > 0$ such that:
 * $\displaystyle \left\vert{\frac{A_k + \left({L \pm \mu}\right) B_k}{B_n}}\right\vert < \mu$ for all $n > N$

Substitute the above into the inequation and obtain:

Hence by the definition of convergent sequences the result follows.

Remarks

 * Using the similar proof technique with limits inferior and superior, a more general version of this theorem can be obtained. In that case the limit $L$ can be either a real number or $\pm \infty$.
 * By setting $b_n = 1$ the theorem turns into Cesàro Mean for real-valued sequences.