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P. Erdös; J. O. Shallit
New bounds on the length of finite pierce and Engel series
Journal de théorie des nombres de Bordeaux, 3 no. 1 (1991), p. 43-53, doi: 10.5802/jtnb.41
Article PDF | Analyses MR 1116100 | Zbl 0727.11003
Mots clés: Pierce series, Engel series

Résumé - Abstract

Every real number $x, 0 < x \le 1$, has an essentially unique expansion as a Pierce series :

$$ x = \frac{1}{x^1}- \frac{1}{x^1 x^2} + \frac{1}{x^1 x^2 x^3} - \cdots $$

where the $x_i$ form a strictly increasing sequence of positive integers. The expansion terminates if and only if $x$ is rational. Similarly, every positive real number $y$ has a unique expansion as an Engel series :

$$ y = \frac{1}{y^1}- \frac{1}{y^1 y^2} + \frac{1}{y^1 y^2 y^3} + \cdots $$

where the $y_i$ form a (not necessarily strictly) increasing sequence of positive integers. If the expansion is infinite, we require that the sequence yi be not eventually constant. Again, such an expansion terminates if and only if $y$ is rational. In this paper we obtain some new upper and lower bounds on the lengths of these series on rational inputs $a/b$. In the case of the Engel series, this answers an open question of Erdös, Rényi, and Szüsz. However, our upper and lower bounds are widely separated.


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