Alfred Tauber

Alfred Tauber (5 November 1866 – 26 July 1942) was an Austrian Empire-born Austrian mathematician, known for his contribution to mathematical analysis and to the theory of functions of a complex variable: he is the eponym of an important class of theorems with applications ranging from mathematical and harmonic analysis to number theory. He was murdered in the Theresienstadt concentration camp.

Life and academic career
Born in Pressburg, Kingdom of Hungary, Austrian Empire (now Bratislava, Slovakia), he began studying mathematics at Vienna University in 1884, obtained his Ph.D. in 1889, and his habilitation in 1891. Starting from 1892, he worked as chief mathematician at the Phönix insurance company until 1908, when he became an a.o. professor at the University of Vienna, though, already from 1901, he had been honorary professor at TU Vienna and director of its insurance mathematics chair. In 1933, he was awarded the Grand Decoration of Honour in Silver for Services to the Republic of Austria, and retired as emeritus extraordinary professor. However, he continued lecturing as a privatdozent until 1938, when he was forced to resign as a consequence of the "Anschluss". On 28–29 June 1942, he was deported with transport IV/2, č. 621 to Theresienstadt, where he was murdered on 26 July 1942.

Work
list 35 publications in the bibliography appended to his obituary, and also a search performed on the "Jahrbuch über die Fortschritte der Mathematik" database results in a list 35 mathematical works authored by him, spanning a period of time from 1891 to 1940. However, cites two papers on actuarial mathematics which do not appear in these two bibliographical lists and #|Binder's bibliography of Tauber's works (1984, pp. 163–166), while listing 71 entries including the ones in the bibliography of  and the two cited by Hlawka, does not includes the short note  so the exact number of his works is not known. According to, his scientific research can be divided into three areas: the first one comprises his work on the theory of functions of a complex variable and on potential theory, the second one includes works on linear differential equations and on the Gamma function, while the last one includes his contributions to actuarial science. give a more detailed list of research topics Tauber worked on, though it is restricted to mathematical analysis and geometric topics: some of them are infinite series, Fourier series, spherical harmonics, the theory of quaternions, analytic and descriptive geometry. Tauber's most important scientific contributions belong to the first of his research areas, even if his work on potential theory has been overshadowed by the one of Aleksandr Lyapunov.

Tauberian theorems
His most important article is. In this paper, he succeeded in proving a converse to Abel's theorem for the first time: this result was the starting point of numerous investigations, leading to the proof and to applications of several theorems of such kind for various summability methods. The statement of these theorems has a standard structure: if a series $&sum; an$ is summable according to a given summability method and satisfies an additional condition, called "Tauberian condition", then it is a convergent series. Starting from 1913 onward, G. H. Hardy and J. E. Littlewood used the term Tauberian to identify this class of theorems. Describing with a little more detail #|Tauber's 1897 work, it can be said that his main achievements are the following two theorems:


 * $ο$. If the series $&sum; an$ is Abel summable to sum $$, i.e. $limx→ 1− &sum; +∞ an xn = s$, and if $an = ο(n−1)$, then $&sum; ak$ converges to $s$.

This theorem is, according to, the forerunner of all Tauberian theory: the condition $an = ο(n−1)$ is the first Tauberian condition, which later had many profound generalizations. In the remaining part of his paper, by using the theorem above, Tauber proved the following, more general result:


 * $s$. The series $&sum; an$ converges to sum $$ if and only if the two following conditions are satisfied:


 * 1) $&sum; an$ is Abel summable and

This result is not a trivial consequence of $$. The greater generality of this result with respect to the former one is due to the fact it proves the exact equivalence between ordinary convergence on one side and Abel summability (condition 1) jointly with Tauberian condition (condition 2) on the other. claims that this latter result must have appeared to Tauber much more complete and satisfying respect to the $s$ as it states a necessary and sufficient condition for the convergence of a series while the former one was simply a stepping stone to it: the only reason why Tauber's second theorem is not mentioned very often seems to be that it has no profound generalization as the first one has, though it has its rightful place in all detailed developments of summability of series.

Contributions to the theory of Hilbert transform
writes that Tauber contributed at an early stage to theory of the now called "Hilbert transform", anticipating with his contribution the works of Hilbert and Hardy in such a way that the transform should perhaps bear their three names. Precisely, considers the real part $&sum; n k ak = ο(n)$ and imaginary part $φ$ of a power series $ψ$,


 * $$f(z)=\sum_{k=1}^{+\infty} c_kz^k =\varphi(\theta)+\mathrm{i} \psi(\theta)$$

where
 * $f$ with $z = reiθ$ being the absolute value of the given complex variable,
 * $r = | z |$ for every natural number $ck rk = ak + ibk$,
 * $k$ and $k$ are trigonometric series and therefore periodic functions, expressing the real and imaginary part of the given power series.

Under the hypothesis that $φ$ is less than the convergence radius $ψ$ of the power series $r$, Tauber proves that $φ(θ) = &sum; +∞ akcos(kθ) − bksin(kθ)$ and $ψ(θ) = &sum; +∞ aksin(kθ) + bkcos(kθ)$ satisfy the two following equations:


 * $$$$\varphi(\theta)=\frac{1}{2\pi}\int_0^\pi \left\{\psi(\theta+\phi) - \psi(\theta-\phi)\right\}\cot\left(\frac{\phi}{2}\right)\,\mathrm{d}\phi$$


 * $$$$\psi(\theta)=-\frac{1}{2\pi}\int_0^\pi \left\{\varphi(\theta+\phi) - \varphi(\theta-\phi)\right\}\cot\left(\frac{\phi}{2}\right)\mathrm{d}\phi$$

Assuming then $r$, he is also able to prove that the above equations still hold if $Rf$ and $f$ are only absolutely integrable: this result is equivalent to defining the Hilbert transform on the circle since, after some calculations exploiting the periodicity of the functions involved, it can be proved that $$ and $$ are equivalent to the following pair of Hilbert transforms:

\varphi(\theta)=\frac{1}{2\pi}\int_{-\pi}^\pi \psi(\phi) \cot\left(\frac{\theta-\phi}{2}\right)\mathrm{d}\phi \qquad \psi(\theta)=\frac{1}{2\pi}\int_{-\pi}^\pi \varphi(\phi) \cot\left(\frac{\theta-\phi}{2}\right)\mathrm{d}\phi $$ Finally, it is perhaps worth pointing out an application of the results of, given (without proof) by Tauber himself in the short research announce :
 * the complex valued continuous function $φ$ defined on a given circle is the boundary value of a holomorphic function defined in its open disk if and only if the two following conditions are satisfied


 * 1) the function $ψ$ is uniformly integrable in every neighborhood of the point $r = Rf$, and
 * 2) the function $φ$ satisfies $$.

Scientific references

 * , and also.
 * , 2nd Edition published by Chelsea Publishing Company, 1991,, ISBN 0828403341.