Discontinuities of monotone functions

In the mathematical field of analysis, a well-known theorem describes the set of discontinuities of a monotone real-valued function of a real variable; all discontinuities of such a (monotone) function are necessarily jump discontinuities and there are at most countably many of them.

Usually, this theorem appears in literature without a name. It is called Froda's theorem in some recent works; in his 1929 dissertation, Alexandru Froda stated that the result was previously well-known and had provided his own elementary proof for the sake of convenience.^[1] Prior work on discontinuities had already been discussed in the 1875 memoir of the French mathematician Jean Gaston Darboux.^[2]

Definitions[edit]

Denote the limit from the left by

f\left(x^{-}\right):=\lim _{z\nearrow x}f(z)=\lim _{\stackrel {h\to 0}{h>0}}f(x-h)

and denote the limit from the right by

f\left(x^{+}\right):=\lim _{z\searrow x}f(z)=\lim _{\stackrel {h\to 0}{h>0}}f(x+h).

If $f\left(x^{+}\right)$ and $f\left(x^{-}\right)$ exist and are finite then the difference $f\left(x^{+}\right)-f\left(x^{-}\right)$ is called the jump^[3] of $f$ at $x.$

Consider a real-valued function $f$ of real variable $x$ defined in a neighborhood of a point $x.$ If $f$ is discontinuous at the point $x$ then the discontinuity will be a removable discontinuity, or an essential discontinuity, or a jump discontinuity (also called a discontinuity of the first kind).^[4] If the function is continuous at $x$ then the jump at $x$ is zero. Moreover, if $f$ is not continuous at $x,$ the jump can be zero at $x$ if $f\left(x^{+}\right)=f\left(x^{-}\right)\neq f(x).$

Precise statement[edit]

Let $f$ be a real-valued monotone function defined on an interval $I.$ Then the set of discontinuities of the first kind is at most countable.

One can prove^[5]^[3] that all points of discontinuity of a monotone real-valued function defined on an interval are jump discontinuities and hence, by our definition, of the first kind. With this remark the theorem takes the stronger form:

Let $f$ be a monotone function defined on an interval $I.$ Then the set of discontinuities is at most countable.

Proofs[edit]

This proof starts by proving the special case where the function's domain is a closed and bounded interval $[a,b].$ ^[6]^[7] The proof of the general case follows from this special case.

Proof when the domain is closed and bounded[edit]

Two proofs of this special case are given.

Proof 1[edit]

Let $I:=[a,b]$ be an interval and let $f:I\to \mathbb {R}$ be a non-decreasing function (such as an increasing function). Then for any $a<x<b,$

f(a)~\leq ~f\left(a^{+}\right)~\leq ~f\left(x^{-}\right)~\leq ~f\left(x^{+}\right)~\leq ~f\left(b^{-}\right)~\leq ~f(b).

Let

\alpha >0

and let

x_{1}<x_{2}<\cdots <x_{n}

be

n

points inside

I

at which the jump of

f

is greater or equal to

\alpha

:

f\left(x_{i}^{+}\right)-f\left(x_{i}^{-}\right)\geq \alpha ,\ i=1,2,\ldots ,n

For any $i=1,2,\ldots ,n,$ $f\left(x_{i}^{+}\right)\leq f\left(x_{i+1}^{-}\right)$ so that $f\left(x_{i+1}^{-}\right)-f\left(x_{i}^{+}\right)\geq 0.$ Consequently,

{\begin{alignedat}{9}f(b)-f(a)&\geq f\left(x_{n}^{+}\right)-f\left(x_{1}^{-}\right)\\&=\sum _{i=1}^{n}\left[f\left(x_{i}^{+}\right)-f\left(x_{i}^{-}\right)\right]+\sum _{i=1}^{n-1}\left[f\left(x_{i+1}^{-}\right)-f\left(x_{i}^{+}\right)\right]\\&\geq \sum _{i=1}^{n}\left[f\left(x_{i}^{+}\right)-f\left(x_{i}^{-}\right)\right]\\&\geq n\alpha \end{alignedat}}

and hence

n\leq {\frac {f(b)-f(a)}{\alpha }}.

Since $f(b)-f(a)<\infty$ we have that the number of points at which the jump is greater than $\alpha$ is finite (possibly even zero).

Define the following sets:

S_{1}:=\left\{x:x\in I,f\left(x^{+}\right)-f\left(x^{-}\right)\geq 1\right\},

S_{n}:=\left\{x:x\in I,{\frac {1}{n}}\leq f\left(x^{+}\right)-f\left(x^{-}\right)<{\frac {1}{n-1}}\right\},\ n\geq 2.

Each set $S_{n}$ is finite or the empty set. The union $S=\bigcup _{n=1}^{\infty }S_{n}$ contains all points at which the jump is positive and hence contains all points of discontinuity. Since every $S_{i},\ i=1,2,\ldots$ is at most countable, their union $S$ is also at most countable.

If $f$ is non-increasing (or decreasing) then the proof is similar. This completes the proof of the special case where the function's domain is a closed and bounded interval. $\blacksquare$

Proof 2[edit]

So let $f:[a,b]\to \mathbb {R}$ is a monotone function and let $D$ denote the set of all points $d\in [a,b]$ in the domain of $f$ at which $f$ is discontinuous (which is necessarily a jump discontinuity).

Because $f$ has a jump discontinuity at $d\in D,$ $f\left(d^{-}\right)\neq f\left(d^{+}\right)$ so there exists some rational number $y_{d}\in \mathbb {Q}$ that lies strictly in between $f\left(d^{-}\right){\text{ and }}f\left(d^{+}\right)$ (specifically, if $f\nearrow$ then pick $y_{d}\in \mathbb {Q}$ so that $f\left(d^{-}\right)<y_{d}<f\left(d^{+}\right)$ while if $f\searrow$ then pick $y_{d}\in \mathbb {Q}$ so that $f\left(d^{-}\right)>y_{d}>f\left(d^{+}\right)$ holds).

It will now be shown that if $d,e\in D$ are distinct, say with $d<e,$ then $y_{d}\neq y_{e}.$ If $f\nearrow$ then $d<e$ implies $f\left(d^{+}\right)\leq f\left(e^{-}\right)$ so that $y_{d}<f\left(d^{+}\right)\leq f\left(e^{-}\right)<y_{e}.$ If on the other hand $f\searrow$ then $d<e$ implies $f\left(d^{+}\right)\geq f\left(e^{-}\right)$ so that $y_{d}>f\left(d^{+}\right)\geq f\left(e^{-}\right)>y_{e}.$ Either way, $y_{d}\neq y_{e}.$

Thus every $d\in D$ is associated with a unique rational number (said differently, the map $D\to \mathbb {Q}$ defined by $d\mapsto y_{d}$ is injective). Since $\mathbb {Q}$ is countable, the same must be true of $D.$ $\blacksquare$

Proof of general case[edit]

Suppose that the domain of $f$ (a monotone real-valued function) is equal to a union of countably many closed and bounded intervals; say its domain is $\bigcup _{n}\left[a_{n},b_{n}\right]$ (no requirements are placed on these closed and bounded intervals^[a]). It follows from the special case proved above that for every index $n,$ the restriction $f{\big \vert }_{\left[a_{n},b_{n}\right]}:\left[a_{n},b_{n}\right]\to \mathbb {R}$ of $f$ to the interval $\left[a_{n},b_{n}\right]$ has at most countably many discontinuities; denote this (countable) set of discontinuities by $D_{n}.$ If $f$ has a discontinuity at a point $x_{0}\in \bigcup _{n}\left[a_{n},b_{n}\right]$ in its domain then either $x_{0}$ is equal to an endpoint of one of these intervals (that is, $x_{0}\in \left\{a_{1},b_{1},a_{2},b_{2},\ldots \right\}$ ) or else there exists some index $n$ such that $a_{n}<x_{0}<b_{n},$ in which case $x_{0}$ must be a point of discontinuity for $f{\big \vert }_{\left[a_{n},b_{n}\right]}$ (that is, $x_{0}\in D_{n}$ ). Thus the set $D$ of all points of at which $f$ is discontinuous is a subset of $\left\{a_{1},b_{1},a_{2},b_{2},\ldots \right\}\cup \bigcup _{n}D_{n},$ which is a countable set (because it is a union of countably many countable sets) so that its subset $D$ must also be countable (because every subset of a countable set is countable).

In particular, because every interval (including open intervals and half open/closed intervals) of real numbers can be written as a countable union of closed and bounded intervals, it follows that any monotone real-valued function defined on an interval has at most countable many discontinuities.

To make this argument more concrete, suppose that the domain of $f$ is an interval $I$ that is not closed and bounded (and hence by Heine–Borel theorem not compact). Then the interval can be written as a countable union of closed and bounded intervals $I_{n}$ with the property that any two consecutive intervals have an endpoint in common: $I=\cup _{n=1}^{\infty }I_{n}.$ If $I=(a,b]{\text{ with }}a\geq -\infty$ then $I_{1}=\left[\alpha _{1},b\right],\ I_{2}=\left[\alpha _{2},\alpha _{1}\right],\ldots ,I_{n}=\left[\alpha _{n},\alpha _{n-1}\right],\ldots$ where $\left(\alpha _{n}\right)_{n=1}^{\infty }$ is a strictly decreasing sequence such that $\alpha _{n}\rightarrow a.$ In a similar way if $I=[a,b),{\text{ with }}b\leq +\infty$ or if $I=(a,b){\text{ with }}-\infty \leq a<b\leq \infty .$ In any interval $I_{n},$ there are at most countable many points of discontinuity, and since a countable union of at most countable sets is at most countable, it follows that the set of all discontinuities is at most countable. $\blacksquare$

Jump functions[edit]

Examples. Let $x$ ₁ < $x$ ₂ < $x$ ₃ < ⋅⋅⋅ be a countable subset of the compact interval [ $a$ , $b$ ] and let μ₁, μ₂, μ₃, ... be a positive sequence with finite sum. Set

f(x)=\sum _{n=1}^{\infty }\mu _{n}\chi _{[x_{n},b]}(x)

where χ_A denotes the characteristic function of a compact interval $A$ . Then $f$ is a non-decreasing function on [ $a$ , $b$ ], which is continuous except for jump discontinuities at $x$ _$n$ for $n$ ≥ 1. In the case of finitely many jump discontinuities, $f$ is a step function. The examples above are generalised step functions; they are very special cases of what are called jump functions or saltus-functions.^[8]^[9]

More generally, the analysis of monotone functions has been studied by many mathematicians, starting from Abel, Jordan and Darboux. Following Riesz & Sz.-Nagy (1990), replacing a function by its negative if necessary, only the case of non-negative non-decreasing functions has to be considered. The domain [ $a$ , $b$ ] can be finite or have ∞ or −∞ as endpoints.

The main task is to construct monotone functions — generalising step functions — with discontinuities at a given denumerable set of points and with prescribed left and right discontinuities at each of these points. Let $x n$ ( $n$ ≥ 1) lie in ( $a$ , $b$ ) and take λ₁, λ₂, λ₃, ... and μ₁, μ₂, μ₃, ... non-negative with finite sum and with λ_$n$ + μ_$n$ > 0 for each $n$ . Define

f_{n}(x)=0\,\,

for

\,\,x<x_{n},\,\,f_{n}(x_{n})=\lambda _{n},\,\,f_{n}(x)=\lambda _{n}+\mu _{n}\,\,

for

\,\,x>x_{n}.

Then the jump function, or saltus-function, defined by

f(x)=\,\,\sum _{n=1}^{\infty }f_{n}(x)=\,\,\sum _{x_{n}\leq x}\lambda _{n}+\sum _{x_{n}<x}\mu _{n},

is non-decreasing on [ $a$ , $b$ ] and is continuous except for jump discontinuities at $x n$ for $n$ ≥ 1.^[10]^[11]^[12]^[13]

To prove this, note that sup | $f$ _$n$| = λ_$n$ + μ_$n$, so that Σ $f$ _$n$ converges uniformly to $f$ . Passing to the limit, it follows that

f(x_{n})-f(x_{n}-0)=\lambda _{n},\,\,\,f(x_{n}+0)-f(x_{n})=\mu _{n},\,\,\,

and

\,\,f(x\pm 0)=f(x)

if $x$ is not one of the $x$ _$n$'s.^[10]

Conversely, by a differentiation theorem of Lebesgue, the jump function $f$ is uniquely determined by the properties:^[14] (1) being non-decreasing and non-positive; (2) having given jump data at its points of discontinuity $x$ _$n$; (3) satisfying the boundary condition $f$ ( $a$ ) = 0; and (4) having zero derivative almost everywhere.

Proof that a jump function has zero derivative almost everywhere.

Property (4) can be checked following Riesz & Sz.-Nagy (1990), Rubel (1963) and Komornik (2016). Without loss of generality, it can be assumed that $f$ is a non-negative jump function defined on the compact [ $a$ , $b$ ], with discontinuities only in ( $a$ , $b$ ).

Note that an open set $U$ of ( $a$ , $b$ ) is canonically the disjoint union of at most countably many open intervals $I$ _$m$; that allows the total length to be computed ℓ( $U$ )= Σ ℓ( $I$ _$m$). Recall that a null set $A$ is a subset such that, for any arbitrarily small ε' > 0, there is an open $U$ containing $A$ with ℓ( $U$ ) < ε'. A crucial property of length is that, if $U$ and $V$ are open in ( $a$ , $b$ ), then ℓ( $U$ ) + ℓ( $V$ ) = ℓ( $U$ ∪ $V$ ) + ℓ( $U$ ∩ $V$ ).^[15] It implies immediately that the union of two null sets is null; and that a finite or countable set is null.^[16]^[17]

Proposition 1. For $c$ > 0 and a normalised non-negative jump function $f$ , let $U$ _$c$( $f$ ) be the set of points $x$ such that

{f(t)-f(s) \over t-s}>c

for some $s$ , $t$ with $s$ < $x$ < $t$ . Then $U$ _$c$( $f$ ) is open and has total length ℓ( $U$ _$c$( $f$ )) ≤ 4 $c$ ⁻¹ ( $f$ ( $b$ ) – $f$ ( $a$ )).

Note that $U$ _$c$( $f$ ) consists the points $x$ where the slope of $h$ is greater that $c$ near $x$ . By definition $U$ _$c$( $f$ ) is an open subset of ( $a$ , $b$ ), so can be written as a disjoint union of at most countably many open intervals $I$ _$k$ = ( $a$ _$k$, $b$ _$k$). Let $J$ _$k$ be an interval with closure in $I$ _$k$ and ℓ( $J$ _$k$) = ℓ( $I$ _$k$)/2. By compactness, there are finitely many open intervals of the form ( $s$ , $t$ ) covering the closure of $J$ _$k$. On the other hand, it is elementary that, if three fixed bounded open intervals have a common point of intersection, then their union contains one of the three intervals: indeed just take the supremum and infimum points to identify the endpoints. As a result, the finite cover can be taken as adjacent open intervals ( $s$ _$k,1$, $t$ _$k,1$), ( $s$ _$k,2$, $t$ _$k,2$), ... only intersecting at consecutive intervals.^[18] Hence

\ell (J_{k})\leq \sum _{m}(t_{k,m}-s_{k,m})\leq \sum _{m}c^{-1}(f(t_{k,m})-f(s_{k,m}))\leq 2c^{-1}(f(b_{k})-f(a_{k})).

Finally sum both sides over $k$ .^[16]^[17]

Proposition 2. If $f$ is a jump function, then $f$ '( $x$ ) = 0 almost everywhere.

To prove this, define

Df(x)=\limsup _{s,t\rightarrow x,\,\,s<x<t}{f(t)-f(s) \over t-s},

a variant of the Dini derivative of $f$ . It will suffice to prove that for any fixed $c$ > 0, the Dini derivative satisfies $D$ $f$ ( $x$ ) ≤ $c$ almost everywhere, i.e. on a null set.

Choose ε > 0, arbitrarily small. Starting from the definition of the jump function $f$ = Σ $f$ _$n$, write $f$ = $g$ + $h$ with $g$ = Σ_{$n$ ≤ $N$} $f$ _$n$ and h = Σ_{$n$ > $N$} $f$ _$n$ where $N$ ≥ 1. Thus $g$ is a step function having only finitely many discontinuities at $x$ _$n$ for $n$ ≤ $N$ and $h$ is a non-negative jump function. It follows that $D$ $f$ = $g$ ' + $D$ $h$ = $D$ $h$ except at the $N$ points of discontinuity of $g$ . Choosing $N$ sufficiently large so that Σ_{$n$ > $N$} λ_$n$ + μ_$n$ < ε, it follows that $h$ is a jump function such that $h$ ( $b$ ) − $h$ ( $a$ ) < ε and $Dh$ ≤ $c$ off an open set with length less than 4ε/ $c$ .

By construction $Df$ ≤ $c$ off an open set with length less than 4ε/ $c$ . Now set ε' = 4ε/ $c$ — then ε' and $c$ are arbitrarily small and $Df$ ≤ $c$ off an open set of length less than ε'. Thus $Df$ ≤ $c$ almost everywhere. Since $c$ could be taken arbitrarily small, $Df$ and hence also $f$ ' must vanish almost everywhere.^[16]^[17]

As explained in Riesz & Sz.-Nagy (1990), every non-decreasing non-negative function $F$ can be decomposed uniquely as a sum of a jump function $f$ and a continuous monotone function $g$ : the jump function $f$ is constructed by using the jump data of the original monotone function $F$ and it is easy to check that $g$ = $F$ − $f$ is continuous and monotone.^[10]

Notes[edit]

^ So for instance, these intervals need not be pairwise disjoint nor is it required that they intersect only at endpoints. It is even possible that $\left[a_{n},b_{n}\right]\subseteq \left[a_{n+1},b_{n+1}\right]$ for all $n$

References[edit]

^ Froda, Alexandre (3 December 1929). Sur la distribution des propriétés de voisinage des functions de variables réelles (PDF) (Thesis). Paris: Hermann. JFM 55.0742.02.
^ Jean Gaston Darboux, Mémoire sur les fonctions discontinues, Annales Scientifiques de l'École Normale Supérieure, 2-ème série, t. IV, 1875, Chap VI.
^ ^a ^b Nicolescu, Dinculeanu & Marcus 1971, p. 213.
^ Rudin 1964, Def. 4.26, pp. 81–82.
^ Rudin 1964, Corollary, p. 83.
^ Apostol 1957, pp. 162–3.
^ Hobson 1907, p. 245.
^ Apostol 1957.
^ Riesz & Sz.-Nagy 1990.
^ ^a ^b ^c Riesz & Sz.-Nagy 1990, pp. 13–15
^ Saks 1937.
^ Natanson 1955.
^ Łojasiewicz 1988.
^
For more details, see
^ Burkill 1951, pp. 10−11.
^ ^a ^b ^c Rubel 1963
^ ^a ^b ^c Komornik 2016
^ This is a simple example of how Lebesgue covering dimension applies in one real dimension; see for example Edgar (2008).

Bibliography[edit]

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[8] So for instance, these intervals need not be pairwise disjoint nor is it required that they intersect only at endpoints. It is even possible that $\left[a_{n},b_{n}\right]\subseteq \left[a_{n+1},b_{n+1}\right]$ for all $n$

[1] Froda, Alexandre (3 December 1929). Sur la distribution des propriétés de voisinage des functions de variables réelles (PDF) (Thesis). Paris: Hermann. JFM 55.0742.02.

[2] Jean Gaston Darboux, Mémoire sur les fonctions discontinues, Annales Scientifiques de l'École Normale Supérieure, 2-ème série, t. IV, 1875, Chap VI.

[FOOTNOTENicolescuDinculeanuMarcus1971213-3] Nicolescu, Dinculeanu & Marcus 1971, p. 213.

[FOOTNOTERudin1964Def._4.26,_pp._81–82-4] Rudin 1964, Def. 4.26, pp. 81–82.

[FOOTNOTERudin1964Corollary,_p._83-5] Rudin 1964, Corollary, p. 83.

[FOOTNOTEApostol1957162–3-6] Apostol 1957, pp. 162–3.

[FOOTNOTEHobson1907245-7] Hobson 1907, p. 245.

[FOOTNOTEApostol1957-9] Apostol 1957.

[FOOTNOTERieszSz.-Nagy1990-10] Riesz & Sz.-Nagy 1990.

[RSzN-11] Riesz & Sz.-Nagy 1990, pp. 13–15

[FOOTNOTESaks1937-12] Saks 1937.

[FOOTNOTENatanson1955-13] Natanson 1955.

[FOOTNOTEŁojasiewicz1988-14] Łojasiewicz 1988.

[15] For more details, see
Riesz & Sz.-Nagy 1990

Young & Young 1911

von Neumann 1950

Boas 1961

Lipiński 1961

Rubel 1963

Komornik 2016

[16] Riesz & Sz.-Nagy 1990

[17] Young & Young 1911

[18] von Neumann 1950

[19] Boas 1961

[20] Lipiński 1961

[21] Rubel 1963

[22] Komornik 2016

[FOOTNOTEBurkill195110−11-16] Burkill 1951, pp. 10−11.

[Ru-17] Rubel 1963

[Ko-18] Komornik 2016

[19] This is a simple example of how Lebesgue covering dimension applies in one real dimension; see for example Edgar (2008).

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