Monotone functions – Serlo

Monotony criterion Bearbeiten

The monotony criterion is quite intuitive: if the derivative of a function (i.e. the slope) is positive, it goes up, if the derivative is negative, it goes down. Mathematically, if the derivative $f'$ of a differentiable function $f$ is non-negative or (non-positive) on an interval $(a,b)$ , then $f$ is monotonously increasing (or decreasing) on $(a,b)$ . If $f'$ is even strictly positive (or negative) $(a,b)$ , then $f$ is strictly monotonously increasing (or decreasing).

In the first case, even inversion of the statement is true: If a differentiable function is monotonously increasing on $[a,b]$ , then $f'(x)\geq 0$ and if the function is monotonously decreasing on $[a,b]$ , then then $f'(x)\geq 0$ . However, the inversion does not hold true in the strict case, monotone functions do not always have $f'(x)>0$ or $f'(x)<0$ . For instance, $f(x)=x^{3}$ is strictly monotonous, but $f'(0)=3\cdot 0^{2}=0$ .

Theorem (Monotony criterion for differentiable functions)

Let $f:[a,b]\to \mathbb {R}$ be continuous and differentiable on $(a,b)$ . Then, there is

$f'\geq 0$ on $(a,b)$ $\iff$ $f$ monotonously increasing on $[a,b]$
$f'\leq 0$ on $(a,b)$ $\iff$ $f$ monotonously decreasing on $[a,b]$
$f'>0$ on $(a,b)$ $\Longrightarrow$ $f$ strictly monotonously increasing on $[a,b]$
$f'<0$ on $(a,b)$ $\Longrightarrow$ $f$ strictly monotonously decreasing on $[a,b]$

Proof Bearbeiten

The four directions " $\Longrightarrow$ " follow from the mean value theorem. The two directions " $\Longleftarrow$ " follow by differentiability of the function:

Proof (monotony criterion for differentiable functions)

We first show the four directions " $\Longrightarrow$ " and then the two " $\Longleftarrow$ ".

1. $\Longrightarrow$ : From $f'\geq 0$ on $(a,b)$ we get that $f$ in monotonously increasing on $[a,b]$ .

Let $f'\geq 0$ for all $x\in (a,b)$ and let $x_{1},x_{2}\in [a,b]$ with $x_{1}\leq x_{2}$ . We need to show $f(x_{1})\leq f(x_{2})$ . By assumption, $f$ is continuous on $[x_{1},x_{2}]\subseteq [a,b]$ and differentiable on $(x_{1},x_{2})\subseteq (a,b)$ . By the mean-value theorem, there is a $\xi \in (x_{1},x_{2})$ with

{\frac {f(x_{2})-f(x_{1})}{x_{2}-x_{1}}}=f'(\xi )

By assumption, $f'(\xi )\geq 0$ , and hence ${\tfrac {f(x_{2})-f(x_{1})}{x_{2}-x_{1}}}\geq 0$ . Since $x_{2}>x_{1}\iff x_{2}-x_{1}>0$ we have in the enumerator $f(x_{2})-f(x_{1})\geq 0$ . This is equivalent to $f(x_{2})\geq f(x_{1})$ , i.e. $f$ is monotonously increasing.

2. $\Longrightarrow$ : From $f'\leq 0$ on $(a,b)$ we get that $f$ in monotonously decreasing on $[a,b]$ .

Let $f'\leq 0$ for all $x\in (a,b)$ and let $x_{1},x_{2}\in [a,b]$ with $x_{1}\leq x_{2}$ . We need to show $f(x_{1})\geq f(x_{2})$ . By assumption, $f$ is continuous on $[x_{1},x_{2}]\subseteq [a,b]$ and differentiable on $(x_{1},x_{2})\subseteq (a,b)$ . By the mean-value theorem, there is a $\xi \in (x_{1},x_{2})$ with

{\frac {f(x_{2})-f(x_{1})}{x_{2}-x_{1}}}=f'(\xi )

Now, $f'(\xi )\leq 0$ , and hence ${\tfrac {f(x_{2})-f(x_{1})}{x_{2}-x_{1}}}\geq 0$ . Since $x_{2}>x_{1}\iff x_{2}-x_{1}>0$ we have $f(x_{2})-f(x_{1})\leq 0$ . This is equivalent to $f(x_{2})\leq f(x_{1})$ , i.e. $f$ is monotonously decreasing.

3. $\Longrightarrow$ : $f'>0$ on $(a,b)$ implies that $f$ is strictly monotonously increasing on $[a,b]$

We prove this by contradiction: Let $f$ be not strictly monotonously increasing. That means, we have some $x_{1},x_{2}\in [a,b]$ with $x_{1}<x_{2}$ and $f(x_{1})\geq f(x_{2})$ . We need to find a $\xi \in (a,b)$ with $f'(\xi )\leq 0$ . Now, $f$ is continuous on $[x_{1},x_{2}]$ and differentiable on $(x_{1},x_{2})$ . So by the mean value theorem, we can find a $\xi \in (a,b)$ with

{\frac {f(x_{2})-f(x_{1})}{x_{2}-x_{1}}}=f'(\xi )

Since $f(x_{1})\geq f(x_{2})$ , the enumerator of the quotient is non-positive, and because of $x_{1}<x_{2}$ the denominator is positive. Thus the whole fraction is non-positive, and therefore $f'(\xi )\leq 0$ .

4. $\Longrightarrow$ : $f'<0$ on $(a,b)$ implies that $f$ is strictly monotonously increasing on $[a,b]$

Another proof by contradiction: Let $f$ be not strictly monotonously decreasing. That means, we have some $x_{1},x_{2}\in [a,b]$ with $x_{1}<x_{2}$ and $f(x_{1})\leq f(x_{2})$ . We need to find a $\xi \in (a,b)$ with $f'(\xi )\geq 0$ . Now, $f$ is continuous on $[x_{1},x_{2}]$ and differentiable on $(x_{1},x_{2})$ . So by the mean value theorem, we can find a $\xi \in (a,b)$ with

{\frac {f(x_{2})-f(x_{1})}{x_{2}-x_{1}}}=f'(\xi )

Since $f(x_{1})\leq f(x_{2})$ , the enumerator of the quotient is non-positive, and because of $x_{1}<x_{2}$ the denominator is positive. Thus the whole fraction is non-positive, and therefore $f'(\xi )\geq 0$ .

Now, the two directions " $\Longleftarrow$ " follow:

1. $\Longleftarrow$ : $f$ being monotonously increasing on $[a,b]$ implies $f'\geq 0$ on $(a,b)$

Let $x_{1},x_{2}\in [a,b]$ with $x_{1}<x_{2}$ . By monotony, $f(x_{1})\leq f(x_{2})$ . Further, let $x,{\tilde {x}}\in [x_{1},x_{2}]$ with $x\neq {\tilde {x}}$ . Then we have for the difference quotient

{\frac {f(x)-f({\tilde {x}})}{x-{\tilde {x}}}}\geq 0

If $x>{\tilde {x}}$ , then $f(x)\geq f({\tilde {x}})$ . The enumerator and denominator of the difference quotient are thus non-negative, and so is the total quotient. Similarly in the case of $x<{\tilde {x}}$ and $f(x)\leq f({\tilde {x}})$ enumerator and denominator are non-positive. Thus the whole fraction is again non-negative. Now we form the differential quotient by taking the limit $x\to {\tilde {x}}$ . This limit exists because $f$ is differentiable on $(x_{1},x_{2})$ . Furthermore, the inequality remains valid because of the monotony rule for limit values. Thus we have

f'({\tilde {x}})=\lim _{x\to {\tilde {x}}}{\frac {f(x)-f({\tilde {x}})}{x-{\tilde {x}}}}\geq 0

Since $x_{1},x_{2}\in [a,b]$ and ${\tilde {x}}\in (x_{1},x_{2})$ have been arbitrary, we get $f'\geq 0$ on all of $(a,b)$ .

2. $\Longleftarrow$ : $f$ being monotonously decreasing on $[a,b]$ implies $f'\leq 0$ on $(a,b)$

Let again $x_{1},x_{2}\in [a,b]$ with $x_{1}<x_{2}$ . By monotony, $f(x_{1})\geq f(x_{2})$ . Further, let $x,{\tilde {x}}\in [x_{1},x_{2}]$ with $x\neq {\tilde {x}}$ . Then we have for the difference quotient

{\frac {f(x)-f({\tilde {x}})}{x-{\tilde {x}}}}\leq 0

If $x>{\tilde {x}}$ , then $f(x)\leq f({\tilde {x}})$ and thus the total quotient is non-positive. An analogous statement holds in the case $x<{\tilde {x}}$ and $f(x)\geq f({\tilde {x}})$ . By forming the differential quotient we now obtain

f'({\tilde {x}})=\lim _{x\to {\tilde {x}}}{\frac {f(x)-f({\tilde {x}})}{x-{\tilde {x}}}}\leq 0

Since $x_{1},x_{2}$ and ${\tilde {x}}$ have been arbitrary, we get $f'\leq 0$ on all of $(a,b)$ .

Examples: monotony criterion Bearbeiten

Quadratic and cubic functions Bearbeiten

Example (Monotony of quadratic and cubic functions)

Graphs of the functions

f

and

g

Graphs of the functions

f'

and

g'

For the quadratic power function $f:\mathbb {R} \to \mathbb {R} ,\ f(x)=x^{2}$ there is

f'(x)=2x\ {\begin{cases}>0&{\text{ if }}x>0,\\<0&{\text{ if }}x<0\end{cases}}

So $f$ is strictly monotonously decreasing by the monotony criterion on $(-\infty ,0]$ and strictly monotonously increasing on $[0,\infty )$ .

For the cubic power function $g:\mathbb {R} \to \mathbb {R} ,\ g(x)=x^{3}$ there is

g'(x)=3x^{2}\ {\begin{cases}\geq 0&{\text{ for all }}x\in \mathbb {R} ,\\>0&{\text{ for all }}x\in \mathbb {R} \setminus \{0\}\end{cases}}

So by the monotony criterion, $g$ is monotonously increasing on $\mathbb {R}$ and strictly monotonously increasing on $(-\infty ,0]$ and $[0,\infty )$ . The cubic power function $g(x)=x^{3}$ is even strictly monotonously increasing on all of $\mathbb {R}$ .

The fact that $g$ with $g(x)=x^{3}$ is strictly' monotonously increasing, although only $f'\geq 0$ and not $f'>0$ , stems from its derivative being zero at only a single point (namely 0). In the end of this article, we will treat a criterion, which tells us when a function is strictly monotonous, even if there is not everywhere $f'>0$ .

Question: Why is $g:\mathbb {R} \to \mathbb {R} :x\mapsto x^{3}$ strictly monotonously increasing on $\mathbb {R}$ ?

We must show: From $x,y\in \mathbb {R}$ with $x<y$ we get $g(x)<g(y)$ . For the cases $x<y\leq 0$ and $0\leq x<y$ we have already shown this with the monotony criterion. So we only have to look at the case $x<0<y$ . Here there is with the arrangement axioms (missing):

g(x)=x^{3}=\underbrace {x} _{<0}\cdot \underbrace {x^{2}} _{>0}<0<\underbrace {y} _{>0}\cdot \underbrace {y^{2}} _{>0}=y^{3}=g(y)

So $g$ is strictly monotonously increasing on all of $\mathbb {R}$ .

Warning

In the example $x\mapsto x^{3}$ we have seen that the statement " $f'>0$ implies strict monotony" does not hold true! This means that from the fact that $f$ increases strictly monotonous, we can in general not conclude that $f'>0$ . In the example of the function $h:\mathbb {R} \to \mathbb {R} :x\mapsto -x^{3}$ one can also see that the statement " $f'<0$ implies strictly monotonous falling" does not hold true in general.

Exponential and logarithm function Bearbeiten

Example (Monotony of the exponential and logarithm function)

For the exponential function $f:\mathbb {R} \to \mathbb {R} ,\ f(x)=\exp(x)$ there is for all $x\in \mathbb {R}$ :

f'(x)=\exp(x)>0

Therefore, according to the monotony criterion, $\exp$ is strictly monotonously increasing on all of $\mathbb {R}$ . For the (natural) logarithm function $g:\mathbb {R} ^{+}\to \mathbb {R} ,\ g(x)=\ln(x)$ there is for all $x\in \mathbb {R} ^{+}$ :

g'(x)={\frac {1}{x}}>0

So $\ln$ is strictly monotonously increasing on $\mathbb {R} ^{+}$ (not including the 0).

Question: What is the monotonicity behaviour of the logarithm function extended to $\mathbb {R} ^{-}$ , i.e. $:\mathbb {R} \setminus \{0\}\to \mathbb {R} ,\ h(x)=\ln |x|$ ?

There is

h(x)={\begin{cases}\ln(x)&{\text{ for }}x>0\\\ln(-x)&{\text{ for }}x<0\end{cases}}

Above we have shown that $h'(x)>0$ for $x\in \mathbb {R} ^{+}$ . So $h$ is strictly monotonously increasing on $\mathbb {R} ^{+}$ , as well . For $x<0$ on the other hand there is $h'(x)={\frac {1}{-x}}\cdot (-1)={\frac {1}{x}}<0$ . So $h$ is strictly monotonously decreasing on $\mathbb {R} ^{-}$ .

Trigonometric functions Bearbeiten

Example (Monotony of the sine function)

For the sine function $f:\mathbb {R} \to \mathbb {R} ,\ f(x)=\sin(x)$ there is

f'(x)=\cos(x)\ {\begin{cases}>0&{\text{ for }}x\in (-{\tfrac {\pi }{2}}+2\pi k,{\tfrac {\pi }{2}}+2\pi k),\ k\in \mathbb {Z} ,\\<0&{\text{ for }}x\in ({\tfrac {\pi }{2}}+2\pi k,{\tfrac {3\pi }{2}}+2\pi k),\ k\in \mathbb {Z} \end{cases}}

So for all $k\in \mathbb {Z}$ , the $\sin$ is strictly monotonously increasing on the intervals $[-{\tfrac {\pi }{2}}+2\pi k,{\tfrac {\pi }{2}}+2\pi k]$ and strictly monotonously decreasing on the intervals $[{\tfrac {\pi }{2}}+2\pi k,{\tfrac {3\pi }{2}}+2\pi k]$ .

Question: Where does the cosine function $g:\mathbb {R} \to \mathbb {R} ,\ g(x)=\cos(x)$ show monotonous behaviour?

Here, $g'(x)=-\sin(x)\ {\begin{cases}>0&{\text{ for }}x\in (\pi +2\pi k,2\pi +2\pi k),\ k\in \mathbb {Z} ,\\<0&{\text{ for }}x\in (2\pi k,{\tfrac {3\pi }{2}}+\pi +2\pi k),\ k\in \mathbb {Z} \end{cases}}$ .

So for all $k\in \mathbb {Z}$ , the $\cos$ is strictly monotonously increasing on the intervals $[\pi +2\pi k,2\pi +2\pi k]$ and strictly monotonously decreasing on the intervals $[2\pi k,\pi +2\pi k]$ .

Example (Monotony of the tangent function)

For the tangent function $\tan :D=\mathbb {R} \setminus \{{\tfrac {\pi }{2}}+k\pi \mid k\in \mathbb {Z} \}\to \mathbb {R} ,\ \tan(x)={\tfrac {\sin(x)}{\cos(x)}}$ there is for all $x\in D$ :

\tan '(x)=1+\underbrace {\tan ^{2}(x)} _{\geq 0}\geq 1>0

Hence, for all $k\in \mathbb {Z}$ , the $\tan$ is strictly monotonously increasing on the intervals $(-{\tfrac {\pi }{2}}+k\pi ,{\tfrac {\pi }{2}}+k\pi )$ .

Question: Where does the cotangent function $\cot :{\tilde {D}}=\mathbb {R} \setminus \{k\pi \mid k\in \mathbb {Z} \}\to \mathbb {R} ,\ \cot(x)={\tfrac {\cos(x)}{\sin(x)}}$ show monotonous behaviour?

For all $x\in {\tilde {D}}$ , there is

\cot '(x)=-1-\underbrace {\tan ^{2}(x)} _{\geq 0}\leq -1<0

So for all $k\in \mathbb {Z}$ , the $\cot$ is strictly monotonously decreasing on the intervals $(k\pi ,\pi +k\pi )$ .

Exercise Bearbeiten

Monotony intervals and existence of a zero Bearbeiten

Exercise (Monotony intervals and existence of a zero)

Where is the following polynomial function monotonous?

f:\mathbb {R} \to \mathbb {R} ,\ f(x)=x^{3}-x-1

Prove that $f$ has exactly one zero.

Solution (Monotony intervals and existence of a zero)

Graph of the function

f(x)=x^{3}-x-1

Monotony intervals:

The function $f$ is differentiable on all of $\mathbb {R}$ , with

f'(x)=3x^{2}-1=3\left(x^{2}-{\tfrac {1}{3}}\right)=3\left(x+{\tfrac {1}{\sqrt {3}}}\right)\left(x-{\tfrac {1}{\sqrt {3}}}\right)

So

f'(x)>0\iff {\begin{cases}x+{\tfrac {1}{\sqrt {3}}}>0{\text{ and }}x-{\tfrac {1}{\sqrt {3}}}>0\iff x>-{\tfrac {1}{\sqrt {3}}}{\text{ and }}x>{\tfrac {1}{\sqrt {3}}}\iff x>{\tfrac {1}{\sqrt {3}}}\\x+{\tfrac {1}{\sqrt {3}}}<0{\text{ and }}x-{\tfrac {1}{\sqrt {3}}}<0\iff x<-{\tfrac {1}{\sqrt {3}}}{\text{ and }}x<{\tfrac {1}{\sqrt {3}}}\iff x<-{\tfrac {1}{\sqrt {3}}}\end{cases}}

According to the monotony criterion, $f$ is strictly monotonously increasing on $\left(-\infty ,-{\tfrac {1}{\sqrt {3}}}\right)$ and on $\left({\tfrac {1}{\sqrt {3}}},\infty \right)$ . Further,

f'(x)<0\iff {\begin{cases}x+{\tfrac {1}{\sqrt {3}}}>0{\text{ and }}x-{\tfrac {1}{\sqrt {3}}}<0\iff x>-{\tfrac {1}{\sqrt {3}}}{\text{ and }}x<{\tfrac {1}{\sqrt {3}}}\iff -{\tfrac {1}{\sqrt {3}}}<x<{\tfrac {1}{\sqrt {3}}}\\x+{\tfrac {1}{\sqrt {3}}}<0{\text{ and }}x-{\tfrac {1}{\sqrt {3}}}>0\iff x<-{\tfrac {1}{\sqrt {3}}}{\text{ and }}x>{\tfrac {1}{\sqrt {3}}}\iff {\text{ not possible}}\end{cases}}

According to the monotony criterion, $f$ is strictly monotonously decreasing on $\left(-{\tfrac {1}{\sqrt {3}}},{\tfrac {1}{\sqrt {3}}}\right)$ .

$f$ has exactly one zero:

For $f$ , we have the following table of values:

{\begin{array}{|c||c|c|c|c|c|c|}\hline x&-1&-{\tfrac {1}{\sqrt {3}}}&0&{\tfrac {1}{\sqrt {3}}}&1&2\\\hline f(x)&-1&-1+{\tfrac {2}{3{\sqrt {3}}}}&-1&-1-{\tfrac {2}{3{\sqrt {3}}}}&-1&5\\\hline \end{array}}

Based on the monotonicity properties and the continuity of $f$ that we have previously investigated, we can read off that:

On $\left(-\infty ,-{\tfrac {1}{\sqrt {3}}}\right)$ is $f$ strictly monotonously increasing. Because of $f\left(-{\tfrac {1}{\sqrt {3}}}\right)=-1+{\tfrac {2}{3{\sqrt {3}}}}<0$ there is $f(x)<0$ for all $x\in \left(-\infty ,-{\tfrac {1}{\sqrt {3}}}\right)$ .
On $\left(-{\tfrac {1}{\sqrt {3}}},{\tfrac {1}{\sqrt {3}}}\right)$ is $f$ then strictly monotonously decreasing. So there is also $f(x)<0$ for all $x\in \left(-{\tfrac {1}{\sqrt {3}}},{\tfrac {1}{\sqrt {3}}}\right)$ .
Subsequently $f$ increases on $\left({\tfrac {1}{\sqrt {3}}},\infty \right)$ again strictly monotonously. Because of $f(1)=-1<0$ and $f(2)=5>0$ , there must be an $x_{0}\in (1,2)$ with $f(x_{0})=0$ by the mean value theorem. Because of the strict monotony of $f$ on $\left({\tfrac {1}{\sqrt {3}}},\infty \right)$ , there cannot be any further zeros.

Necessary and sufficient criterion for strict monotony Bearbeiten

Exercise (Necessary and sufficient criterion for strict monotony)

Prove that: a continuous function $f:[a,b]\to \mathbb {R}$ which is differentiable to $(a,b)$ is strictly monotonously increasing exactly when there is

$f'(x)\geq 0$ for all $x\in (a,b)$
The zero set of $f'$ contains no open interval.

As an application: Show that the function $f:\mathbb {R} \to \mathbb {R} ,f(x)=x-\sin(x)$ is strictly monotonously increasing on all of $\mathbb {R}$ .

Proof (Necessary and sufficient criterion for strict monotony)

From the monotony criterion we already know that $f$ is monotonously increasing exactly when $f'(x)\geq 0$ . So we only have to show that $f$ is strictly monotonously increasing exactly when the second condition is additionally fulfilled.

$\Longrightarrow$ : $f$ strictly monotonously increasing $\Longrightarrow$ the set of zeros of $f'$ does not contain an open interval.

We perform a proof by contradiction. In other words, we show: If the set of zeros of $f'$ contains an open interval, $f$ is not strictly monotonously increasing. Assume there is $a_{1},b_{1}\in (a,b)$ with $f'(x)=0$ for all $x\in (a_{1},b_{1})$ . Then, by the mean value theorem there is a $\xi \in (a_{1},b_{1})$ with

f(b_{1})-f(a_{1})=\underbrace {f'(\xi )} _{=0}(b_{1}-a_{1})=0

So $f(a_{1})=f(b_{1})$ . If now $x\in (a_{1},b_{1})\iff a_{1}<x<b_{1}$ , then since $f$ is monotonously increasing, there is

f(a_{1})\leq f(x)\leq f(b_{1})

So there is $f(x)=f(b_{1})$ for all $x\in (a_{1},b_{1})$ . Hence, $f$ is not strictly monotonously increasing.

$\Longleftarrow$ : the set of zeros of $f'$ does not contain an open interval $\Longrightarrow$ $f$ strictly monotonously increasing

We perform a proof by contradiction. In other words, we show: if $f$ is monotonously, but not strictly monotonously increasing, then the zero set of $f'$ contains an open interval. Assume there is $a_{2},b_{2}\in (a,b)$ with $a_{2}<b_{2}$ with $f(a_{2})=f(b_{2})$ . Because of the monotony of $f$ there is

f(a_{2})\leq f(x)\leq f(b_{2})

So $f(x)=f(b_{2})$ for all $x\in (a_{1},b_{1})$ . That means $f$ is constant on $(a_{2},b_{2})$ . Hence there is for all $x\in (a_{2},b_{2})$ :

f'(x)=0

so the set of zeros of $f'$ does contain an open interval and we get a contradiction.

Exercise: $f:\mathbb {R} \to \mathbb {R} ,\ f(x)=x-\sin(x)$ is strictly monotonously increasing

$f$ is differentiable for all $x\in \mathbb {R}$ where

f'(x)=1-\cos(x)\geq 0

as $\cos(x)\leq 1$ for all $x\in \mathbb {R}$ . Hence $f$ is monotonously increasing. Further there is

{\begin{aligned}&f'(x)=1-\cos(x)=0\\\iff {}&\cos(x)=1\\\iff {}&x\in \{2\pi k\mid k\in \mathbb {Z} \}\end{aligned}}

So the set of zeros of $f'$ contains only isolated points, and thus no open interval. Therefore $f$ is strictly monotonously increasing on $\mathbb {R}$ .

Derivative and local extrema →

Feedback? Do you want to join?

If you have questions concerning the content, or didn't understand something, the feel free to contact us! We would love to answer your questions! Also we are thankful for critics and/or comments! If you share our vision to explain university math in an comprehensible way, then contact us under:

E-Mail: en@serlo.org

This article is licensed under the free license CC-BY-SA 3.0. With that you can use it, modify it or share it freely, as long as you name „Serlo“ as source and put you changes under the same CC-BY-SA 3.0 oder an compatible license. On the page „Kopier uns!“ we explain you what you have to pay attention to, when using our texts, picture or videos.