Exercises: Continuity – Serlo

Lipschitz continuous functions are uniformly continuous

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Exercise

Let   be Lipschitz continuous with Lipschitz constant  . That is

 

for all  . Prove that   is uniformly continuous.

How to get to the proof?

We need to show that for all   , there is a   , such that for all   with   there is  . By our assumption, we have

 

In order for   to hold, it suffices to have  . We can reach this by taking  .

Proof

Let   be arbitrary. We choose  . Then, for all   with  :

 

Continuity at the origin

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Exercise

Prove that the following function is continuous at the origin  :

 

with a real number  

How to get to the proof?

In order to establish continuity at the origin   , we make use of the epsilon-delta criterion. That means, for all   we have to find a   such that the inequality   holds at all   with   . The question now is how to find a suitable   for any given   . To answer this question, we take a look at the function   around  :

Since at    , there is

 

This inequality also holds at  , since  . Visually, the inequality above means that the graph of the function   fits inside the "double wedge" given by  , where   tells us, how much the wedge is "stretched" in  -direction. So if we choose  , then at any   with   , there is

 

Which we can use to carry through the proof (see below).

Note: We can also "move the double wedge" to any   when investigating continuity at   . If the graph fits inside the "moved double wedge"   , then for any  , there is

 

So any function fitting in such a double wedge is continuous. The converse does not hold true. There are functions which do not fit in any double wedge around   but are continuous at  . An example is the square root function   around  .

Proof

Let  . We choose  . Let   be any real number with  . Then:

 

This shows that   is continuous at   .

Extreme value theorem

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Exercise (Maximum and minimum of a function)

Prove that the function   defined on   attains a maximum, but not a minimum.

Solution (Maximum and minimum of a function)

Proof step:   attains a maximum

The function   is continuous on  , since it is composed by continuous functions and the denominator is strictly positive ( ). The enumerator is also strictly positive, so   for  ,  , and

 

That means, there is an   with   for all  . The extreme value theorem implies that   attains a maximum on   . One may even show that the maximum is even global. However, computing the maximum explicitly would require us to solve   , which is quite a computational effort and can be even harder for other functions  . The extreme value theorem just allowed us to quickly show that there is a maximum - and saved us from the tedious solution of  .

Proof step:   does not attain a minimum

There is   on   . And indeed,   approaches 0 (see the previous proof step). But it does not attain 0. Since   and by continuity, there can not be a minimum (if there was an attained minimum  , then by  , there would by   for some  , which is a contradiction ).

Exercise (How often is a value attained #1)

  1. Show that there is no continuous function   , which attains each of its function values exactly twice.
  2. Is there a continuous function   , which attains each of its function values exactly three times?

Exercise (How often is a value attained #2)

Let   with  . Show: There is no continuous function   , which attains each of its function values exactly   times.

Intermediate value theorem and zeros

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Exercise (Zero of a function)

Prove that the function

 

has exactly one zero inside the interval   .

Solution (Zero of a function)

Proof step:   has at least one zero

  is continuous as it is composed by the continuous functions   and  . In addition,

 

and

 

By means of the intermediate value theorem, there must be an   with  .

Proof step:   has exactly one zero

  is strictly monotonously increasing on   . The function   is also monotonously increasing on   , so   is decreasing and   again increasing. Hence there can be only one zero   with   , since a function with two zeros   is never strictly monotonously increasing (it would either have to stay constant or go "down again" between   and  ).

Exercise (Solution of an equation)

Let   with  . Prove that the equation

 

Has at least three solutions.

Solution (Solution of an equation)

It is a powerful trick in mathematics, to transform the problem of finding solutions   to   as zeros of an auxiliary function   (if  , then   and vice versa). In our case, the continuous auxiliary function is

 

When approaching   and  , this function goes to

 

and

 

Therefore, there must be two arguments   with   and   (  is close to   and   close to  ). By the intermediate value theorem, there must hence be a zero   with  . This zero   is one solution of the above equation.

The same argument works between   and  . Since   and   , we can use the intermediate value theorem and get a zero   with   .This is the second solution we have been looking for.

The third solution follows by a similar argument. There is   and  . So the intermediate value theorem renders a   with   . The equation has therefore at least three solutions.

Exercise (Solution of an equation)

Let   be continuous with  . Prove that there is a   with   .

Solution (Solution of an equation)

We consider the following auxiliary function:

 

Finding a   with   now amounts to finding a zero of  . Since   is continuous, so is   . In addition, at the endpoints of the interval, there is

 

and

 

Fall 1:  

This means  , or equivalently

 

So we have found a solution   to  .

Fall 2:  

We will first consider the case  . Since   , there is  . The intermediate value theorem now yields a   with

 

This   is a zero of   and hence a desired solution for  . The other case   can be treated using exactly the same arguments.

So for any choice of  , there is a   with  .

Exercise (Existence of exactly one zero)

Let   be a natural number. We define the function  . Prove that   has exactly one positive zero.

Solution (Existence of exactly one zero)

We need to show two things: At first, we need to show that a zero exists inside the interval  . Second, we need to assure that there is indeed only one such zero.

The function   is a polynomial function and hence continuous. At the beginning of the interval   , there is   i.e. the graph of the function runs below the  -axis. At infinity, there is  , meaning that for large   , the graph runs above the  -axis. As   is continuous, we can apply the intermediate value theorem and get a zero  .

Now we need to show that there is at most one zero. Both   and   are strictly monotonously increasing functions for   . So we may assume that   is also strictly monotonous, there. We can prove this assumption be taking the first derivative:

For   there is:  .

One may show with a bit of effort that differentiable functions with positive derivative   are strictly monotonous in the sense that   for  . If there were two zeros  , we would have   although there is   . This would contradict   being monotonous and in hence excluded. Therefore,   can have at most one zero (as all strictly monotonous functions).

Note: We could also prove that   has at most one zero, only using that   is differentiable with  :

Assume that, the function   would have two zeros   with  . Since the function   is differentiable and  , we may use Rolle's theorem and get that some   exists wit  . But this is a contradiction to the first derivative of   being strictly positive   . So this is a second way to exclude the existence of two zeros.

Continuity of the inverse function

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Exercise (Continuity of the inverse function 1)

Let   be defined by

 
  1. Prove that   is continuous, strictly monotonous and injective.
  2. Prove that   ist surjectiive (so it is a 1-to-1-map from   to   an inverse function exists).
  3. Why is the inverse function   continuous, monotonously increasing and bijective? Explicitly determine  .

Solution (Continuity of the inverse function 1)

Part 1:   is continuous on   since it is the quotient of the continuous polynomials   and  . Note that   for all  .

Let   with  . Then, strict monotony holds:

 

Therefore,   is also injective.

Part 2: The function runs towards infinity at the end points of the open interval   as follows:

  and  

Since   is continuous, the intermediate value theorem ensures that for each   there is a   mapped onto it:  . Therefore,   is also surjective:  .

Part 3: Since   is bijective, the inverse map exists and is bijective, as well:

 

The theorem about continuity of the inverse function tells us that   is continuous and strictly monotonously increasing. Now, let us compute  . That means, we need to bring   into the form   - i.e. we need to get   standing alone on the left side of the equation:

 

Fall 1:  

 

Fall 2:  

We can use the quadratic solution formula in order to solve for  :

 

Since   for  , the only reasonable solution is   . Putting all together, the full definition for the inverse function reads

 

Hint

The distinction of two cases above is not very convenient. We can avoid it using a little trick: In case   enumerator and denominator of   can be multiplied by a factor of  :

 

Plugging in   , we get that   is described correctly. So we can use the definition above for all   and avoid the case distinction.

Exercise (Continuity of the inverse function 2)

Let

 
  1. Prove that   is injective.
  2. Determine the range   of all attained values.
  3. Why is the inverse function   continuous?

Solution (Continuity of the inverse function 2)

Part 1:

  is continuous, as it is composed by the continuous functions  ,  ,   and   on  .

The logarithm is strictly monotonously increasing (and its inverse is decreasing): for   with   , there is:

 

Now,   for  . Since in addition,   is strictly monotonously decreasing on  , we have

 

So the  -term is also strictly monotonously increasing and so is  :

 

Therefore,   is also injective.

Part 2:

At the ends of the domain of definition, there is

 

and

 

this implies

 

  is continuous on the interval  . Hence, we can use a corollary of the intermediate value theorem, and get that   is again an interval. Since   is strictly monotonously increasing and   , we can conclude

 

Part 3:

Since   is an interval and   in bijective, we can use the theorem about continuity of the inverse function. I tells us that

 

is indeed continuous.