If I have that $|\sum |a_n| - |a_n|^2|$ is bounded and know that $\sum|a_n|^2$ converges can I conclude anything about $\sum a_n$?
$|\sum |a_n| - |a_n|^2|$ is bounded and $\sum|a_n|^2$ converges , what can be concluded about $\sum a_n$?
3
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sequences-and-series
convergence-divergence
2 Answers
3
By the triangular inequality, $ \sum_n|a_n|\leqslant\left|\sum_n|a_n|-|a_n|^2\right|+\sum_n|a_n|^2 $ is bounded, hence $\sum\limits_na_n$ converges absolutely. In particular, $\sum\limits_na_n$ converges.
2
Since $\sum_{n\geq 1}|a_n|^2$ is convergent, in particular $a_n\to 0$ so for $n\geq n_0$ we have $|a_n|\leq 1$. We get that \sum_{n\geq n_0}|a_n|= \sum_{n\geq n_0}\left(|a_n|-|a_n|^2\right)+\sum_{n\geq n_0}|a_n|^2\leq \sup_{N\in \mathbb N}\left|\sum_{j=1}^N|a_j|-|a_j|^2\right|+\left|\sum_{j=1}^{n_0}|a_j|-|a_j|^2\right|+\sum_{k\geq 1}|a_k|^2<\infty, so the series $\sum_n|a_n|$ is convergent.