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Measure theoretic properties of large products of consecutive partial quotients (2405.10538v1)

Published 17 May 2024 in math.NT

Abstract: The theory of uniform approximation of real numbers motivates the study of products of consecutive partial quotients in regular continued fractions. For any non-decreasing positive function $\varphi:\mathbb{N}\to\mathbb{R}{>0}$ and $\ell\in \mathbb{N}$, we determine the Lebesgue measure and Hausdorff dimension of the set $\mathcal{F}{\ell}(\varphi)$ of irrational numbers $x$ whose regular continued fraction $x~=~[a_1(x),a_2(x),\ldots]$ is such that for infinitely many $n\in\mathbb{N}$ there are two numbers $1\leq j<k \leq n$ satisfying [ a_{k}(x)\cdots a_{k+\ell-1}(x)\geq \varphi(n), \; a_{j}(x)\cdots a_{j+\ell-1}(x)\geq \varphi(n). ] One of the consequences of the results is that the strong law of large numbers for products of $\ell$ consecutive partial quotients is impossible even if the block with the largest product is removed.

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References (28)
  1. The generalised Hausdorff measure of sets of Dirichlet non-improvable numbers. Proc. Amer. Math. Soc., 151(5):1823–1838, 2023.
  2. Y. Bugeaud. Approximation by algebraic numbers, volume 160 of Cambridge Tracts in Mathematics. Cambridge University Press, Cambridge, 2004.
  3. K. L. Chung and P. Erdös. On the application of the Borel-Cantelli lemma. Trans. Amer. Math. Soc., 72:179–186, 1952.
  4. Estimates for partial sums of continued fraction partial quotients. Pacific J. Math., 122(1):73–82, 1986.
  5. K. Falconer. Fractal geometry. John Wiley & Sons, Ltd., Chichester, third edition, 2014. Mathematical foundations and applications.
  6. Appendix to the paper by T. łuczak—a simple proof of the lower bound: “On the fractional dimension of sets of continued fractions”. Mathematika, 44(1):54–55, 1997.
  7. Thermodynamic formalism and multifractal analysis of conformal infinite iterated function systems. Acta Math. Hungar., 96(1-2):27–98, 2002.
  8. The Approximate Functional Equation in the Theory of the Zeta-Function, with Applications to the Divisor-Problems of Dirichlet and Piltz. Proc. London Math. Soc. (2), 21:39–74, 1923.
  9. D. Hensley. Continued fractions. World Scientific Publishing Co. Pte. Ltd., Hackensack, NJ, 2006.
  10. Limit theorems for sums of products of consecutive partial quotients of continued fractions. Nonlinearity, 34(12):8143–8173, 2021.
  11. Metric properties of the product of consecutive partial quotients in continued fractions. Israel J. Math., 238(2):901–943, 2020.
  12. Hausdorff measure of sets of Dirichlet non-improvable numbers. Mathematika, 64(2):502–518, 2018.
  13. M. Hussain and N. Shulga. Metrical properties of finite product of partial quotients in arithmetic progressions. In press: Ann. Sc. Norm. Super. Pisa Cl. Sci., 2024.
  14. M. Hussain and N. Shulga. Metrical properties of exponentially growing partial quotients. arXiv:2309.10529, preprint 2023.
  15. O. Kallenberg. Foundations of modern probability, volume 99 of Probability Theory and Stochastic Modelling. Springer, Cham, third edition, [2021] ©2021.
  16. A. Y. Khinchin. Continued fractions. University of Chicago Press, Chicago, Ill.-London, 1964.
  17. A. Khintchine. Metrische Kettenbruchprobleme. Compositio Math., 1:361–382, 1935.
  18. D. Kleinbock and N. Wadleigh. An inhomogeneous Dirichlet theorem via shrinking targets. Compos. Math., 155(7):1402–1423, 2019.
  19. K. Knopp. Mengentheoretische behandlung einiger probleme der diophantischen approximationen und der transfiniten wahrscheinlichkeiten. Mathematische Annalen, 95:409–426, 1926.
  20. The shrinking target problem in the dynamical system of continued fractions. Proc. Lond. Math. Soc. (3), 108(1):159–186, 2014.
  21. T. Łuczak. On the fractional dimension of sets of continued fractions. Mathematika, 44(1):50–53, 1997.
  22. R. D. Mauldin and M. Urbański. Graph directed Markov systems, volume 148 of Cambridge Tracts in Mathematics. Cambridge University Press, Cambridge, 2003. Geometry and dynamics of limit sets.
  23. W. Philipp. Limit theorems for sums of partial quotients of continued fractions. Monatsh. Math., 105(3):195–206, 1988.
  24. V. G. Sprindžuk. Metric theory of Diophantine approximations. Scripta Series in Mathematics. V. H. Winston & Sons, Washington, DC; John Wiley & Sons, New York-Toronto-London, 1979. With a foreword by Donald J. Newman, A Halsted Press Book.
  25. The distribution of the large partial quotients in continued fraction expansions. Sci. China Math., 66(5):935–956, 2023.
  26. B. Tan and Q.-L. Zhou. Metrical properties of the large products of partial quotients in continued fractions. Nonlinearity, 37(2):Paper No. 025008, 28, 2024.
  27. B.-W. Wang and J. Wu. Hausdorff dimension of certain sets arising in continued fraction expansions. Adv. Math., 218(5):1319–1339, 2008.
  28. J. Wu. A remark on the growth of the denominators of convergents. Monatsh. Math., 147(3):259–264, 2006.

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