Thomae's function

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Thomae's function is a real-valued function of a real variable that can be defined as:[1]: 531 

Point plot on the interval (0,1). The topmost point in the middle shows f(1/2) = 1/2

It is named after Carl Johannes Thomae, but has many other names: the popcorn function, the raindrop function, the countable cloud function, the modified Dirichlet function, the ruler function (not to be confused with the integer ruler function),[2] the Riemann function, or the Stars over Babylon (John Horton Conway's name).[3] Thomae mentioned it as an example for an integrable function with infinitely many discontinuities in an early textbook on Riemann's notion of integration.[4]

Since every rational number has a unique representation with coprime (also termed relatively prime) and , the function is well-defined. Note that is the only number in that is coprime to

It is a modification of the Dirichlet function, which is 1 at rational numbers and 0 elsewhere.

Properties

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  • Thomae's function   is bounded and maps all real numbers to the unit interval: 
  •   is periodic with period   for all integers n and all real x.
    Proof of periodicity

    For all   we also have   and hence  

    For all   there exist   and   such that   and   Consider  . If   divides   and  , it divides   and  . Conversely, if   divides   and  , it divides   and  . So  , and  .

  •   is discontinuous at every rational number, so its points of discontinuity are dense within the real numbers.
    Proof of discontinuity at rational numbers

    Let   be an arbitrary rational number, with   and   and   coprime.

    This establishes  

    Let   be any irrational number and define   for all  

    These   are all irrational, and so   for all  

    This implies   and  

    Let  , and given   let   For the corresponding   we have   and  

    which is exactly the definition of discontinuity of   at  .

  •   is continuous at every irrational number, so its points of continuity are dense within the real numbers.
    Proof of continuity at irrational arguments

    Since   is periodic with period   and   it suffices to check all irrational points in   Assume now   and   According to the Archimedean property of the reals, there exists   with   and there exist   such that

    for   we have  

    The minimal distance of   to its i-th lower and upper bounds equals  

    We define   as the minimum of all the finitely many     so that for all     and  

    This is to say, all these rational numbers   are outside the  -neighborhood of  

    Now let   with the unique representation   where   are coprime. Then, necessarily,   and therefore,  

    Likewise, for all irrational   and thus, if   then any choice of (sufficiently small)   gives  

    Therefore,   is continuous on  

  •   is nowhere differentiable.
    Proof of being nowhere differentiable
    • For rational numbers, this follows from non-continuity.
    • For irrational numbers:
      For any sequence of irrational numbers   with   for all   that converges to the irrational point   the sequence   is identically   and so  
      According to Hurwitz's theorem, there also exists a sequence of rational numbers   converging to   with   and   coprime and  
      Thus for all     and so   is not differentiable at all irrational  
  •   has a strict local maximum at each rational number.[citation needed]
    See the proofs for continuity and discontinuity above for the construction of appropriate neighbourhoods, where   has maxima.
  •   is Riemann integrable on any interval and the integral evaluates to   over any set.
    The Lebesgue criterion for integrability states that a bounded function is Riemann integrable if and only if the set of all discontinuities has measure zero.[5] Every countable subset of the real numbers - such as the rational numbers - has measure zero, so the above discussion shows that Thomae's function is Riemann integrable on any interval. The function's integral is equal to   over any set because the function is equal to zero almost everywhere.
  • If   is the graph of the restriction of   to  , then the box-counting dimension of   is  .[6]
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Empirical probability distributions related to Thomae's function appear in DNA sequencing.[7] The human genome is diploid, having two strands per chromosome. When sequenced, small pieces ("reads") are generated: for each spot on the genome, an integer number of reads overlap with it. Their ratio is a rational number, and typically distributed similarly to Thomae's function.

If pairs of positive integers   are sampled from a distribution   and used to generate ratios  , this gives rise to a distribution   on the rational numbers. If the integers are independent the distribution can be viewed as a convolution over the rational numbers,  . Closed form solutions exist for power-law distributions with a cut-off. If   (where   is the polylogarithm function) then  . In the case of uniform distributions on the set    , which is very similar to Thomae's function.[7]

The ruler function

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For integers, the exponent of the highest power of 2 dividing   gives 0, 1, 0, 2, 0, 1, 0, 3, 0, 1, 0, 2, 0, 1, 0, ... (sequence A007814 in the OEIS). If 1 is added, or if the 0s are removed, 1, 2, 1, 3, 1, 2, 1, 4, 1, 2, 1, 3, 1, 2, 1, ... (sequence A001511 in the OEIS). The values resemble tick-marks on a 1/16th graduated ruler, hence the name. These values correspond to the restriction of the Thomae function to the dyadic rationals: those rational numbers whose denominators are powers of 2.

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A natural follow-up question one might ask is if there is a function which is continuous on the rational numbers and discontinuous on the irrational numbers. This turns out to be impossible. The set of discontinuities of any function must be an Fσ set. If such a function existed, then the irrationals would be an Fσ set. The irrationals would then be the countable union of closed sets  , but since the irrationals do not contain an interval, neither can any of the  . Therefore, each of the   would be nowhere dense, and the irrationals would be a meager set. It would follow that the real numbers, being the union of the irrationals and the rationals (which, as a countable set, is evidently meager), would also be a meager set. This would contradict the Baire category theorem: because the reals form a complete metric space, they form a Baire space, which cannot be meager in itself.

A variant of Thomae's function can be used to show that any Fσ subset of the real numbers can be the set of discontinuities of a function. If   is a countable union of closed sets  , define  

Then a similar argument as for Thomae's function shows that   has A as its set of discontinuities.

See also

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References

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  1. ^ Beanland, Kevin; Roberts, James W.; Stevenson, Craig (2009), "Modifications of Thomae's Function and Differentiability", The American Mathematical Monthly, 116 (6): 531–535, doi:10.4169/193009709x470425, JSTOR 40391145
  2. ^ Dunham, William (2008), The Calculus Gallery: Masterpieces from Newton to Lebesgue (Paperback ed.), Princeton: Princeton University Press, page 149, chapter 10, ISBN 978-0-691-13626-4, ...the so-called ruler function, a simple but provocative example that appeared in a work of Johannes Karl Thomae ... The graph suggests the vertical markings on a ruler—hence the name.
  3. ^ John Conway. "Topic: Provenance of a function". The Math Forum. Archived from the original on 13 June 2018.
  4. ^ Thomae, J. (1875), Einleitung in die Theorie der bestimmten Integrale (in German), Halle a/S: Verlag von Louis Nebert, p. 14, §20
  5. ^ Spivak, M. (1965), Calculus on manifolds, Perseus Books, page 53, Theorem 3-8, ISBN 978-0-8053-9021-6
  6. ^ Chen, Haipeng; Fraser, Jonathan M.; Yu, Han (2022). "Dimensions of the popcorn graph". Proceedings of the American Mathematical Society. 150 (11): 4729–4742. arXiv:2007.08407. doi:10.1090/proc/15729.
  7. ^ a b Trifonov, Vladimir; Pasqualucci, Laura; Dalla-Favera, Riccardo; Rabadan, Raul (2011). "Fractal-like Distributions over the Rational Numbers in High-throughput Biological and Clinical Data". Scientific Reports. 1 (191): 191. arXiv:1010.4328. Bibcode:2011NatSR...1E.191T. doi:10.1038/srep00191. PMC 3240948. PMID 22355706.
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