Thomae's function

Thomae's function, named after Carl Johannes Thomae, has many names: the popcorn function, the raindrop function, the countable cloud function, the modified Dirichlet function, the ruler function,^[1] the Riemann function, or the Stars over Babylon (John Horton Conway's name).^[2] This real-valued function of a real variable can be defined as:^[3]

f(x)={\begin{cases}{\frac {1}{q}}&{\text{if }}x={\tfrac {p}{q}}\quad (x{\text{ is rational), with }}p\in \mathbb {Z} {\text{ and }}q\in \mathbb {N} {\text{ coprime}}\\0&{\text{if }}x{\text{ is irrational.}}\end{cases}}

Since every rational number has a unique representation with coprime (also termed relatively prime) $p\in \mathbb {Z}$ and $q\in \mathbb {N}$ , the function is well-defined. Note that $q=+1$ is the only number in $\mathbb {N}$ that is coprime to $p=0.$

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

Properties

Thomae's function $f$ is bounded and maps all real numbers to the unit interval: $\;f:\mathbb {R} \;\rightarrow \;[0,\;1].$
$f$ is periodic with period $1:\;f(x+n)=f(x)$ for all integers $n$ and all real $x$ .

Proof of periodicity

For all $x\in \mathbb {R} \smallsetminus \mathbb {Q} ,$ we also have $x+n\in \mathbb {R} \smallsetminus \mathbb {Q}$ and hence $f(x+n)=f(x)=0,$

For all $x\in \mathbb {Q} ,\;$ there exist $p\in \mathbb {Z}$ and $q\in \mathbb {N}$ such that $\;x=p/q,\;$ and $\gcd(p,\;q)=1.$ Consider $x+n=(p+nq)/q$ . If $d$ divides $p$ and $q$ , it divides $p+nq$ and $p$ . Conversely, if $d$ divides $p+nq$ and $q$ , it divides $(p+nq)-nq=p$ and $q$ . So $\gcd(p+nq,q)=\gcd(p,q)=1$ , and $f(x+n)=1/q=f(x)$ .

$f$ is discontinuous at all rational numbers, dense within the real numbers.

Proof of discontinuity at rational numbers

Let $x_{0}=p/q$ be an arbitrary rational number, with $\;p\in \mathbb {Z} ,\;q\in \mathbb {N} ,$ and $p$ and $q$ coprime.

This establishes $f(x_{0})=1/q.$

Let $\;\alpha \in \mathbb {R} \smallsetminus \mathbb {Q} \;$ be any irrational number and define $x_{n}=x_{0}+{\frac {\alpha }{n}}$ for all $n\in \mathbb {N} .$

These $x_{n}$ are all irrational, and so $f(x_{n})=0$ for all $n\in \mathbb {N} .$

This implies $|x_{0}-x_{n}|={\frac {\alpha }{n}},\quad$ and $\quad |f(x_{0})-f(x_{n})|={\frac {1}{q}}.$

Let $\;\varepsilon =1/q\;$ , and given $\delta >0$ let $n=1+\left\lceil {\frac {\alpha }{\delta }}\right\rceil .$ For the corresponding $\;x_{n}$ we have

|f(x_{0})-f(x_{n})|=1/q\geq \varepsilon \quad

and

$|x_{0}-x_{n}|={\frac {\alpha }{n}}={\frac {\alpha }{1+\left\lceil {\frac {\alpha }{\delta }}\right\rceil }}<{\frac {\alpha }{\left\lceil {\frac {\alpha }{\delta }}\right\rceil }}\leq \delta ,$

which is exactly the definition of discontinuity of $f$ at $x_{0}$ .

$f$ is continuous at all irrational numbers, also dense within the real numbers.

Proof of continuity at irrational arguments

Since $f$ is periodic with period $1$ and $0\in \mathbb {Q} ,\;$ it suffices to check all irrational points in $I=(0,\;1).\;$ Assume now $\varepsilon >0,\;i\in \mathbb {N} \;$ and $x_{0}\in I\smallsetminus \mathbb {Q} .\;$ According to the Archimedean property of the reals, there exists $r\in \mathbb {N} \;$ with $\;1/r<\varepsilon ,\;$ and there exist $\;k_{i}\in \mathbb {N} ,\;$ such that

for $i=1,...,r$ we have $0<{\frac {k_{i}}{i}}<x_{0}<{\frac {(k_{i}+1)}{i}}.$

The minimal distance of $x_{0}$ to its i-th lower and upper bounds equals

d_{i}:=\min\{\;|x_{0}-{\frac {k_{i}}{i}}|,\;|x_{0}-{\frac {(k_{i}+1)}{i}}|\;\}.

We define $\delta$ as the minimum of all the finitely many $d_{i}.$

\delta :=\min _{1\leq i\leq r}\{d_{i}\},\;

so that

for all $i=1,...,r,$ $\quad |x_{0}-k_{i}/i|\geq \delta \quad$ and $\quad |x_{0}-(k_{i}+1)/i|\geq \delta .$

This is to say, all these rational numbers $k_{i}/i,\;(k_{i}+1)/i,\;$ are outside the $\delta$ -neighborhood of $x_{0}.$

Now let $x\in \mathbb {Q} \cap (x_{0}-\delta ,x_{0}+\delta )$ with the unique representation $x=p/q$ where $p,q\in \mathbb {N}$ are coprime. Then, necessarily, $q>r,\;$ and therefore,

f(x)=1/q<1/r<\varepsilon .

Likewise, for all irrational $x\in I,\;f(x)=0=f(x_{0}),\;$ and thus, if $\varepsilon >0$ then any choice of (sufficiently small) $\delta >0$ gives

|x-x_{0}|<\delta \implies |f(x_{0})-f(x)|=f(x)<\varepsilon .

Therefore, $f$ is continuous on $\mathbb {R} \smallsetminus \mathbb {Q} .\quad$

$f$ 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

(a_{n})_{n=1}^{\infty }

with

a_{n}\neq x_{0}

for all

n\in \mathbb {N} _{+}

that converges to the irrational point

x_{0},\;

the sequence

(f(a_{n}))_{n=1}^{\infty }

is identically

0,\;

and so

\lim _{n\to \infty }\left|{\frac {f(a_{n})-f(x_{0})}{a_{n}-x_{0}}}\right|=0.

According to Hurwitz's theorem, there also exists a sequence of rational numbers

(b_{n})_{n=1}^{\infty }=(k_{n}/n)_{n=1}^{\infty },\;

converging to

x_{0},\;

with

k_{n}\in \mathbb {Z}

and

n\in \mathbb {N}

coprime and

|k_{n}/n-x_{0}|<{\frac {1}{{\sqrt {5}}\cdot n^{2}}}.\;

Thus for all

n,

\left|{\frac {f(b_{n})-f(x_{0})}{b_{n}-x_{0}}}\right|>{\frac {1/n-0}{1/({\sqrt {5}}\cdot n^{2})}}={\sqrt {5}}\cdot n\neq 0\;

and so

f

is not differentiable at all irrational

x_{0}.

$f$ 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

f

has maxima.

$f$ is Riemann integrable on any interval and the integral evaluates to $0$ 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.^[4] 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

0

over any set because the function is equal to zero almost everywhere.

Related probability distributions

Empirical probability distributions related to Thomae's function appear in DNA sequencing.^[5] 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 $m,n$ are sampled from a distribution $f(n,m)$ and used to generate ratios $q=n/(n+m)$ , this gives rise to a distribution $g(q)$ on the rational numbers. If the integers are independent the distribution can be viewed as a convolution over the rational numbers, $g(a/(a+b))=\sum _{t=1}^{\infty }f(ta)f(tb)$ . Closed form solutions exist for power-law distributions with a cut-off. If $f(k)=k^{-\alpha }e^{-\beta k}/\mathrm {Li} _{\alpha }(e^{-\beta })$ (where $\mathrm {Li} _{\alpha }$ is the polylogarithm function) then $g(a/(a+b))=(ab)^{-\alpha }\mathrm {Li} _{2\alpha }(e^{-(a+b)\beta })/\mathrm {Li} _{\alpha }^{2}(e^{-\beta })$ . In the case of uniform distributions on the set $\{1,2,\ldots ,L\}$ $g(a/(a+b))=(1/L^{2})\lfloor L/\max(a,b)\rfloor$ , which is very similar to Thomae's function. Both their graphs have fractal dimension 3/2.^[5]

The ruler function

For integers, the exponent of the highest power of 2 dividing $n$ 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.

Related functions

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 $F σ$ set. If such a function existed, then the irrationals would be an $F σ$ set. The irrationals would then be the countable union of closed sets $\textstyle \bigcup _{i=0}^{\infty }C_{i}$ , but since the irrationals do not contain an interval, nor can any of the $C_{i}$ . Therefore, each of the $C_{i}$ would be nowhere dense, and the irrationals would be a meager set. It would follow that the real numbers, being a union of the irrationals and the rationals (which 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 $F σ$ subset of the real numbers can be the set of discontinuities of a function. If $A=\textstyle \bigcup _{n=1}^{\infty }F_{n}$ is a countable union of closed sets $F_{n}$ , define

f_{A}(x)={\begin{cases}{\frac {1}{n}}&{\text{if }}x{\text{ is rational and }}n{\text{ is minimal so that }}x\in F_{n}\\-{\frac {1}{n}}&{\text{if }}x{\text{ is irrational and }}n{\text{ is minimal so that }}x\in F_{n}\\0&{\text{if }}x\notin A\end{cases}}

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

For a general construction on arbitrary metric space, see this article Kim, Sung Soo. "A Characterization of the Set of Points of Continuity of a Real Function." American Mathematical Monthly 106.3 (1999): 258-259.

Notes

^ "…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." (Dunham 2008, p. 149, chapter 10)
^ John Conway. "Topic: Provenance of a function". The Math Forum. Archived from the original on 13 June 2018.
^ Beanland, Roberts & Stevenson 2009, p. 531
^ Spivak 1965, p. 53, Theorem 3-8
^ ^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). doi:10.1038/srep00191. PMC 3240948. PMID 22355706.

References

Abbott, Stephen (2016), Understanding Analysis (Softcover reprint of the original 2nd ed.), New York: Springer, ISBN 978-1-4939-5026-3
Bartle, Robert G.; Sherbert, Donald R. (1999), Introduction to Real Analysis (3rd ed.), Wiley, ISBN 978-0-471-32148-4 (Example 5.1.6 (h))
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
Dunham, William (2008), The Calculus Gallery: Masterpieces from Newton to Lebesgue (Paperback ed.), Princeton: Princeton University Press, ISBN 978-0-691-13626-4
Spivak, M. (1965), Calculus on manifolds, Perseus Books, ISBN 978-0-8053-9021-6

External links

"Dirichlet-function", Encyclopedia of Mathematics, EMS Press, 2001 [1994]
Weisstein, Eric W. "Dirichlet Function". MathWorld.

[1] "…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." (Dunham 2008, p. 149, chapter 10)

[2] John Conway. "Topic: Provenance of a function". The Math Forum. Archived from the original on 13 June 2018.

[3] Beanland, Roberts & Stevenson 2009, p. 531

[4] Spivak 1965, p. 53, Theorem 3-8

[Trifonov-5] 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). doi:10.1038/srep00191. PMC 3240948. PMID 22355706.

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