Abel criterion

This category corresponds roughly to MSC {{{id}}} {{{title}}}; see {{{id}}} at MathSciNet and {{{id}}} at zbMATH.

This category corresponds roughly to MSC {{{id}}} {{{title}}}; see {{{id}}} at MathSciNet and {{{id}}} at zbMATH.

This category corresponds roughly to MSC {{{id}}} {{{title}}}; see {{{id}}} at MathSciNet and {{{id}}} at zbMATH.

The term might refer to

• a criterion for the convergence of series of real numbers
• a related criterion for the convergence of series of complex numbers, used often to determine the convergence of power series at the radius of convergence
• a related criterion for the uniform convergence of a series of functions.

All these criteria can be proved using summation by parts, which is also called Abel's lemma or Abel's transformation and it is a discrete version of integration by parts.

If $\sum a_n$ is a convergent series of real numbers and $\{b_n\}$ is a bounded monotone sequence of real numbers, then $\sum_n a_n b_n$ converges.

Assume that $\{a_n\}$ is a vanishing and monotonically decreasing sequence of real numbers such that the radius of convergence of the power series $\sum_n a_n z^n$ is $1$. Then the series converges at every $z$ with $|z|=1$, except possibly for $z=1$. A notable application is given by the power series \begin{equation}\label{e:log} \sum_{n\geq 1} \frac{z^n}{n}\, \end{equation} the power expansion of (a branch of) the logarithmic function $\ln (1-z)$. The Abel criterion implies that the series converges at every $z\neq 1$ with $|z|=1$. Observe that the series reduces to the Harmonic series at $z=1$, where it diverges.

Let $g_n: A \to \mathbb R$ a bounded sequence of functions such that $g_{n+1}\leq g_n$ and $f_n: A\to \mathbb C$ (or more generally $f_n : A \to \mathbb R^k$) a sequence of functions such that $\sum_n f_n$ converges uniformly. Then also the series $\sum_n f_n g_n$ converges uniformly.

0.00 (0 votes) From The Encyclopedia of Math: Abel criterion.