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Consider a complex power series $\sum a_n z^n \in \mathbb C[[z]]$ with radius of convergence $0\lt r\lt\infty$ and suppose that for every $w$ with $\mid w\mid =r$ the series $\sum a_n w^n $ converges .
We thus obtain a complex-valued function $f$ defined on the closed disk $\mid z\mid \leq r$ by the formula $f(z)=\sum a_n z^n$.

My question: is $f$ continuous ?

This is a naïve question which looks like it should be answered in any book on complex analysis.
But I checked quite a few books, among which the great treatises : Behnke-Sommer, Berenstein-Gay, Knopp, Krantz, Lang, Remmert, Rudin, Stein-Shakarchi, Titchmarsh, ... .
I couldn't find the answer, and yet I feel confident that it was known in the beginning of the twentieth century.

Edit
Many thanks to Julien who has answered my question: Sierpinski proved (in 1916) that there exists such a power series $\sum a_n z^n $ with radius of convergence $r=1$ and associated function $f(z)=\sum a_n z^n $ not bounded on the closed unit disk and thus certainly not continuous.

It is strange that not a single book on complex functions seems to ever have mentioned this example.

On the negative side, I must confess that I don't understand Sierpinski's article at all!
He airdrops a very complicated, weird-looking power series and proves that it has the required properties in a sequence of elementary but completely obscure computations.
I would be very grateful to anybody who would write a new answer with a few lines of explanation as to what Sierpinski is actually doing.

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  • $\begingroup$ You are right, Abel's theorem only give the convergence $\lim\limits_{t \rightarrow 1-}f( \alpha t) = f(\alpha)$ for $|\alpha|=1$, not continuity on the circle. Excuse my quick fire:) $\endgroup$
    – Marc Palm
    Oct 22, 2012 at 16:51
  • $\begingroup$ Dear @Mrc, there is nothing for me to excuse: on the contrary, I want to thank you for your so quickly trying to help. In the books I browsed there are indeed many results in the style of Abel's theorem, but they seem not to be sufficient to answer my question. $\endgroup$ Oct 22, 2012 at 17:02
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    $\begingroup$ Did you try a trigonometric series $\sum c_n e^{inx}$ converging to a discontinuous function ? (The problem is that a priori the sum is over $n \in \mathbf{Z}$.) $\endgroup$ Oct 22, 2012 at 17:08
  • $\begingroup$ This is a very interesting question! I've also wondered about this myself while thinking about this question on M.SE : math.stackexchange.com/questions/209171/… I, too, did not find anything about this in any complex analysis textbook I know. I find it quite impressive that Sierpinski seemed to know the answers to a very large quantity of these simple-sounding, natural, yet quite difficult questions. $\endgroup$ Oct 23, 2012 at 13:54
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    $\begingroup$ Here is a complex analysis book that mentions (yet just a note it seems) the result: An introduction to classical complex analysis, vol 1, by R. B. Burckel (Birkhäuser, 1979), see page 81. (Note: I did not know this either, I did not even know the book; it merely turned up in a search for the title of the mentioned paper.) $\endgroup$
    – user9072
    Oct 23, 2012 at 15:50

3 Answers 3

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I searched all over for an answer to this question back in my student days. I found the answer in a paper by Sierpinski, "Sur une série potentielle qui, étant convergente en tout point de son cercle de convergence,représente sur ce cercle une fonction discontinue ", which is featured in his collected works, see here, p282) and apparently was published in 1916.

It does confirm your expectation that this was known in the beginning of the twentieth century (I don't know whether it's the first proof or not, but from the paper it's clear that Sierpinski thought the result to be new).

EDIT: I just realized that not everybody speaks French ;-) so, to be clear: Sierpinski produces an example where the function converges everywhere on the unit circle but is discontinuous on the circle.

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  • $\begingroup$ @quid: thanks for fixing the link! I thought my url was OK but it was adding %20 instead of spaces - is that just a copy/paste issue? $\endgroup$ Oct 22, 2012 at 17:44
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    $\begingroup$ here is a Zentralblatt/JFM review (of course, in German :)) of the paper in question: zentralblatt-math.org/zmath/en/search/?q=an:46.1466.03 "Beispiel einer Potenzreihe, die den Einheitskreis als Konvergenzkreis hat, überall auf demselben konvergiert und dortselbst unstetig ist in der Art, dass sie in der Umgebung des Punktes 1 unbeschränkt ist. (Prof. Rademacher)" $\endgroup$ Oct 23, 2012 at 6:31
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    $\begingroup$ You're welcome! It was just idle curiosity that got me and a friend interested in this question (we were preparing for the "agregation" - meaning that for a few months we were going over undergraduate material and trying to think about what kind of questions one could ask about it). At this time I discovered Sierpinski's work and was fascinated -I still am, in some ways; he was an incredible mathematician) . As it turns out, my research interests are close to some of Sierpinski's (related to descriptive set theory) but nowhere near complex analysis (though I still find it a beautiful topic). $\endgroup$ Oct 23, 2012 at 12:42
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    $\begingroup$ Cher Julien: je suis heureux que les jurys n'aient jamais posé cette question à mes agrégatifs. Et que ces derniers ne me l'aient jamis posée non plus... :-) $\endgroup$ Oct 23, 2012 at 12:56
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    $\begingroup$ Cher @François: yes, "serie potentielle" made me chuckle too and Sierpinski's general style is quite endearing. Not to mention the nostalgia for a time when French was a world language for science... $\endgroup$ Oct 23, 2012 at 18:58
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This answer is in response to final sentence, "I would be very grateful to anybody who would write a new answer with a few lines of explanation as to what Sierpinski is actually doing". In fact, it is easy to construct power series converging on the circle of convergence, but are unbounded. For example, $$ f(z)=\sum_{n=1}^\infty\frac1{n^5(1+in^{-3}-z)} $$ defines a function whose power series expansion has radius of convergence 1 and converges everywhere on the unit circle, but is unbounded in a neighbourhood of 1.

A method of constructing such functions is as an infinite sum $$ f(z)=\sum_{n=1}^\infty f_n(z). $$ Here, $f_n(z)$ are chosen to have a power series expansion converging everywhere on the closed unit ball. Let $f^{(r)}_n(z)$ denote the sum of the first $r$ terms in the power series expansion of $f_n$. We need to arrange it so that $f^{(r)}(z)\equiv\sum_nf_n^{(r)}(z)$ converges on the closed unit ball, and that $f(z)=\lim_{r\to\infty}f^{(r)}(z)$ holds. That is, we need to be able to commute the limit $r\to\infty$ with the summation over $n$. A sufficient condition to be able to do this is that $\sum_n\sup_r\lvert f^{(r)}_n(z)\rvert < \infty$, for all $\lvert z\rvert\le1$. That this allows us to commute the summation with the limit is just a special case of dominated convergence.

Next, to ensure that $f(z)$ is unbounded on the unit ball, we want to choose $f_n$ such that there exists $q_n$ in the closed unit ball with $f_n(q_n)$ large, and such that it does not get cancelled out in the summation, so that $f(q_n)$ is large and diverges as $n\to\infty$.

For example, choose positive reals $\delta_n,\epsilon_n$ tending to zero, and setting $a_n=1+i\epsilon_n$, and $$ f_n(z)=\frac{\delta_n}{a_n-z}=\sum_{m=0}^\infty \delta_na_n^{-m-1}z^m. $$ These are all well-defined as power series with radius of convergence greater than 1. Furthermore, the partial sums are $$ f^{(r)}_n(z)=\delta_n\frac{1-(z/a_n)^r}{a_n-z}, $$ which are bounded by $2\delta_n/\lvert a_n-z\rvert$. As $a_n\to1$, this is bounded by a multiple of $\delta_n$ for each fixed $z\not=1$, so the dominated convergence condition is satisfied when $\sum_n\delta_n$ is finite. On the other hand, if $z=1$, then $\lvert a_n-z\rvert=\epsilon_n$, so the dominated convergence condition is satisfied everywhere whenever $\sum_n\delta_n/\epsilon_n$ is finite. Next, $f_n(z)$ achieves its largest value on the unit ball at $q_n=a_n/\lvert a_n\rvert$, and its real part there is given by $$ \Re f_n(q_n)=\frac{\delta_n}{\sqrt{1+\epsilon_n^2}(\sqrt{1+\epsilon_n^2}-1)}\ge\frac{2\delta_n}{\epsilon_n^2\sqrt{1+\epsilon_n^2}}. $$ As $f_m(z)$ has positive real part for all $m$, this bound also holds for $f(q_n)$, and we get that $f$ is unbounded whenever $\delta_n/\epsilon_n^2\to\infty$. These conditions are satisfied by taking $\epsilon_n=n^{-3}$ and $\delta_n=n^{-5}$.

Alternatively, for an example closer to Sierpinski's, consider choosing a sequence $a_n\to1$ on the unit circle and positive reals $K_n$, and set $$ f_n(z)=K_n2^{-n}\sum_{k=0}^{2^n-1}a_n^{2^n-1-k}z^k=2^{-n}K_n\frac{a_n^{2^n}-z^{2^n}}{a_n-z}. $$ The partial sums of the power series expansion of $f_n(z)$ are bounded by $2^{1-n}K_n/\lvert a_n-z\rvert$, so the dominated convergence condition is satisfied for $z\not=1$ so long as $\sum_n2^{1-n}K_n$ is finite. Sierpinski chooses $a_n=(n^2-1+2ni)/(n^2+1)$ so that $a_n-1$ goes to zero at rate $1/n$. The dominated convergence condition is therefore satisfied whenever $\sum_n2^{-n}K_nn$ is finite.

Now, $f_n(z)$ is maximized at $z=a_n$ where $\lvert f_n(a_n)\rvert=K_n$. So, $$ \lvert f(a_n)\rvert\ge K_n-\sum_{m\not=n}\frac{2^{1-m}K_m}{\lvert a_m-a_n\rvert}. $$ As $a_m-a_n$ is bounded below by a multiple of $1/m^2$, the summation on the right is bounded whenever $\sum_m2^{-m}K_mm^2$ is finite, and $f(a_n)$ is unbounded if we also take $K_n$ going to infinity. Sierpinski takes $K_n=n^2$ here. Finally, in Sierpinski's example, he multiplies $f_n$ by $z^{2^n}$. This changes nothing, except to separate out the non-zero terms of the power series of $f_n(z)$, so that the power series of $f(z)$ can be written easily term by term.

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Just to complete the previous answer, Sierpiński's example is mentioned (without details, though) in at least one book, namely An introduction to classical complex analysis by R. B. Burckel (Vol. 1, Chap. 3, p. 81).

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    $\begingroup$ A power series that converges everywhere on its circle of convergence must necessarily define a discontinuous function. For if D is the closed disk of radius r whose boundary is that circle, then D is compact and any continuous function defined on D must be bounded everywhere on D. But if the power series is bounded throughout the interior of D then r cannot be its radius of convergence. So the question should really be "can such a power series exist?" and Sierpinski has given an example of one. $\endgroup$ Oct 23, 2012 at 19:26
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    $\begingroup$ @Garabed Gulbenkian: Perhaps I am confused, but wouldn't $\sum x^n/n^2$ we a powerseries converging everywhere on its circle of convergence? $\endgroup$
    – user9072
    Oct 23, 2012 at 20:24
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    $\begingroup$ @Garabed Gulbenkian : I'm not sure I understand. It is easy to give an example of a power series that converges everywhere on its circle of convergence, just take $\sum_n z^n/n^2$. Why does the fact that the series is bounded in $D$ implies that its radius of convergence cannot be $r$? $\endgroup$ Oct 23, 2012 at 20:30
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    $\begingroup$ @quid : Well if you are confused, then you are not the only one ;) $\endgroup$ Oct 23, 2012 at 20:32
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    $\begingroup$ Probably, Gulbenkian thinks that the only reason a series has radius of convergence $r$ is that there must be a pole at this distance. Alas, other kinds of singularity (such as branch points) exists... $\endgroup$ Oct 23, 2012 at 22:47

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