If you have ever hiked along a mountain ridge, you know all about hills and valleys. These hills and valleys are quite similar to those of maxima and minima of a function.
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Jetzt kostenlos anmeldenIf you have ever hiked along a mountain ridge, you know all about hills and valleys. These hills and valleys are quite similar to those of maxima and minima of a function.
And, if you have ever had that hiking buddy who tells your group that you have made it to the top, only for you all to have to hike up again, you know these hills were merely local maximum heights you reached.
Where is the maximum height of your hike? Well, just like where you start and stop your hike, a function that is on a closed interval has a beginning and end point. And, just like you can view an elevation map of your hike, you can look at the graph of a function and determine the absolute maxima and minima it has!
If you studied the maxima and minima article, then you already know that
the absolute maximum (also called the global maximum) of a function is the largest output value of a function on its entire domain, and
the absolute minimum (also called the global minimum) of a function is the smallest output value of a function on its entire domain.
But what about a more formal definition?
To formally define absolute maxima and absolute minima, consider the functions
\[ f(x) = x^{2} + 1 \]
and
\[ g(x) = -x^{2} -1, \]
each over the interval of \( ( - \infty, \infty ) \).
Consider their graphs as well:
For \( f(x) \):
As \( x \to \pm \infty, f(x) \to \infty \).
This shows you that \( f(x) \) has no absolute maximum value.
But, since \( x^{2} \geq 1 \) for all real numbers of \( x \) and \( x^{2} + 1 = 1 \) when \( x = 0 \), you know that \( f(x) \) has a smallest value – an absolute minimum – of \( 1 \) when \( x = 0 \).
For \( g(x) \):
As \( x \to \pm \infty, g(x) \to - \infty \).
This shows you that \( g(x) \) has no absolute minimum value.
But, since \( -x^{2} \leq -1 \) for all real numbers of \( x \) and \( -x^{2} - 1 = -1 \) when \( x = 0 \), you know that \( g(x) \) has a largest value – an absolute maximum – of \( -1 \) when \( x = 0 \).
This leads you to conclude that the formal definition of absolute maxima, absolute minima, and absolute extremum are as follows:
Let a function \( f \) be defined over an interval \( I \) with a value \( c \) that is a subset of \( I \).
But, before moving on, there are two issues of note regarding these definitions:
Consider the function
\[ f(x) = \frac{1}{x^{2} + 1} \]
over the interval \( ( - \infty, \infty) \).
Because
\[ f(0) = 1 \ge \frac{1}{x^{2} + 1} = f(x) \]
for all real numbers \( x \), you say that \( f(x) \) has an absolute maximum over the interval \( ( - \infty, \infty) \) at \( x = 0 \). The absolute maximum is \( f(0) = 1 \), and it occurs at \( x = 0 \).
A function may have:
The graphs below show several possibilities regarding how many of which absolute extrema a function could have.
(f) The function \( f(x) = \frac{x}{2-x} \) on the interval \( [0, 2) \) has an absolute minimum of \( 0 \) at \( x = 0 \) and no absolute maximum.
The first three graphs, graphs (a), (b), and (c), show how a function with a domain of \( (-\infty, \infty) \) can have either:
no absolute extrema,
one absolute extrema, or
both an absolute maximum and an absolute minimum.
The second three graphs, graphs (d), (e), and (f), show how a function on a bounded interval can have either:
a single absolute extremum, or
both an absolute maximum and an absolute minimum.
A function can NOT have more than one absolute maximum or more than one absolute minimum! However, as in graph (c) above, the absolute maximum and absolute minimum can occur at more than one value of \( x \).
The Extreme Value Theorem states that a function that is continuous over a closed and bounded interval has both an absolute maximum and an absolute minimum. The formal statement of the Extreme Value Theorem is below.
If a function \( f \) is continuous over a closed and bounded interval \( [a, b] \), then
For the extreme value theorem to apply, the function must be continuous over a closed and bounded interval. If, for example, the interval is open, or the function has even one point of discontinuity, it is possible that the function could not have an absolute maximum or an absolute minimum.
Reconsider the functions shown in the second three graphs above – graphs (d), (e), and (f).
All three of these functions are defined over bounded, but not necessarily closed, intervals.
The extreme value theorem cannot be applied to the functions in graphs (d) and (f) because neither of these functions is continuous over a closed and bounded interval.
The extreme value theorem says that a continuous function over a closed and bounded interval must have an absolute maximum and an absolute minimum.
As shown in the graphs above, one or both of these absolute extrema could occur at an endpoint of the function.
If, however, an absolute extremum does not occur at an endpoint of the function, it must occur at an interior point.
This means that the absolute extremum is also a local extremum.
Therefore, by Fermat's Theorem, the point \( c \) at which the local extremum occurs must be a critical point.
Theorem – The Location of Absolute Extrema
Let a function \( f \) be continuous over a closed and bounded interval \( I \).
With this in mind, let's develop the strategy for finding the absolute extrema of a function.
To locate the absolute extrema of a function, the function must be continuous and defined over a closed and bounded interval \( [a, b] \).
Solve the function at its endpoints, i.e., where \( x = a \) and \( x = b \).
Find all the critical points of the function that are on the open interval \( (a, b) \) and solve the function at each critical point.
Take the first derivative of the given function.
Set \( f'(x) = 0 \) and solve for \( x \) to find all critical points.
Take the second derivative of the given function.
Plug in the critical points from step \( 2 \) into the second derivative.
If \( f''(c) < 0 \), then the critical point of \( f(x) \) is a maximum.
If \( f''(c) > 0 \), then the critical point of \( f(x) \) is a minimum.
Compare all the values from steps \( 1 \) and \( 2 \).
The largest of the values is the absolute maximum of the function.
The smallest of the values is the absolute minimum of the function.
All other values are relative/local extrema of the function.
Let's review these steps in an example.
Find the absolute maximum and the absolute minimum of the function
\[ f(x) = x^{2} + 2 \]
over the interval \( [-2, 3] \).
Solution:
So, in this case, \( f(x) \) is continuous and defined over the closed and bounded interval of \( [-2, 3] \).
Solve the function at its endpoints, i.e., where \( x = a \) and \( x = b \).
For \( x = a = -2 \):\[ f(a) = f(-2) = (-2)^{2} + 2 = 6 \]
For \( x = b = 3 \):\[ f(b) = f(3) = (3)^{2} + 2 = 11 \]
Find all the critical points of the function that are on the open interval \( (a, b) \) and solve the function at each critical point.
Take the first derivative of the given function.\[ f'(x) = 2x \]
Set \( f'(x) = 0 \) and solve for \( x \) to find all critical points.\[ \begin{align}f'(x) = 0 &= 2x \\0 &= 2x \\x &= 0\end{align} \]
Take the second derivative of the given function.\[ f''(x) = 2 \]
Plug in the critical points from step \( 2 \) into the second derivative.\[ f''(0) = 2 \]
If \( f''(c) < 0 \), then the critical point of \( f(x) \) is a maximum.
If \( f''(c) > 0 \), then the critical point of \( f(x) \) is a minimum.
Compare all the values from steps \( 1 \) and \( 2 \).
The largest of the values is the absolute maximum of the function.
The smallest of the values is the absolute minimum of the function.
All other values are relative/local extrema of the function.
\( x \) | \( f(x) \) | Conclusion |
\( -2 \) | \( 6 \) | relative max |
\( 0 \) | \( 2 \) | absolute min |
\( 3 \) | \( 11 \) | absolute max |
You can graph the function on its closed and bounded interval to validate your conclusions from the table above:
Therefore,
Most functions you deal with in calculus do not have an absolute maximum or an absolute minimum value over their entire domain.
However, some functions do have an absolute extremum over their entire domain. For example, the function,
\[ f(x) = xe^{3x}. \]
If you take the derivative of this function, you get,
\[ f'(x) = e^{3x}(1+3x). \]The only critical point of this function is where \( x = -\frac{1}{3} \).
Looking at the graph of this function, you can see that, over its entire domain, it definitely has an absolute minimum at \( x = -\frac{1}{3} \), but it has no absolute maximum.
To locate absolute maxima and minima over a function's entire domain, you follow the same process as you would to find local maxima and minima, as there are no endpoints. The steps are summarized below.
Take the first derivative of the given function.
Set \( f'(x) = 0 \) and solve for \( x \) to find all critical points.
Take the second derivative of the given function.
Plug in the critical points from step \( 2 \) into the second derivative.
If \( f''(c) < 0 \), then the critical point of \( f(x) \) is a maximum.
If \( f''(c) > 0 \), then the critical point of \( f(x) \) is a minimum.
Let's review these steps with an example.
Find any absolute extrema of the function
\[ f(x) = xe^{x} \].
Solution:
Take the first derivative of the given function.\[ f'(x) = e^{x}(1 + x) \]
Set \( f'(x) = 0 \) and solve for \( x \) to find all critical points.\[ \begin{align}f'(x) = 0 &= e^{x}(1 + x) \\0 &= 1 + x \\x &= -1\end{align} \]
Take the second derivative of the given function.\[ f''(x) = e^{x}(x + 2) \]
Plug in the critical points from step \( 2 \) into the second derivative.\[ \begin{align}f''(-1) &= e^{-1}(-1 + 2) \\&= e^{-1}(1) \\&= e^{-1} = 0.37\end{align} \]
If \( f''(c) < 0 \), then the critical point of \( f(x) \) is a maximum.
If \( f''(c) > 0 \), then the critical point of \( f(x) \) is a minimum.
You can graph the function to validate your conclusions:
Therefore, the only absolute extremum of the function is an absolute minimum of \( -0.37 \) that occurs where \( x = -1 \).
Find the absolute maximum and the absolute minimum of the function
\[ f(x) = -2x^{2} + 3x - 2 \]
over the interval \( [-1, 3] \).
State where the absolute extremum occur.
Solution:
Solve the function at its endpoints, i.e., where \( x = -1 \) and \( x = 3 \).
For \( x = -1 \):\[ f(-1) = -2(-1)^{2} + 3(-1) - 2 = -7 \]
For \( x = 3 \):\[ f(3) = -2(3)^{2} + 3(3) - 2 = -11 \]
Find all the critical points of the function that are on the open interval \( (1, 3) \) and solve the function at each critical point.
Take the first derivative of the given function.\[ f'(x) = -4x + 3 \]
Set \( f'(x) = 0 \) and solve for \( x \) to find all critical points.\[ \begin{align}f'(x) = 0 &= -4x + 3 \\4x &= 3 \\x &= \frac{3}{4}\end{align} \]
Take the second derivative of the given function.\[ f''(x) = -4 \]
Plug in the critical points from step \( 2 \) into the second derivative.\[ f''(\frac{3}{4}) = -4 \]
Since \( f''(\frac{3}{4}) < 0 \), then the critical point of \( f(x) \) is a maximum.
Compare all the values from steps \( 1 \) and \( 2 \).
\( x \) | \( f(x) \) | Conclusion |
\( -1 \) | \( -7 \) | |
\( \frac{3}{4} \) | \( \frac{7}{8} \) | absolute max |
\( 3 \) | \( -11 \) | absolute min |
Therefore,
An absolute maximum of a function is the largest output value of a function on its entire domain.
An absolute minimum of a function is the smallest output value of a function on its entire domain.
To find the absolute extrema of a function, it must be continuous and defined over a closed interval [a, b].
The difference between local maxima and absolute maxima is the same as the difference between local minima and absolute minima.
Local maxima and maxima are the maximum and minimum values of a function in a specific region (or over a certain interval).
Absolute maxima and minima are the maximum and minimum values of the function over its entire domain.
There is no formula for absolute maxima and minima. However, there is a problem-solving strategy to find them.
What is the absolute maximum of a function?
The absolute maximum (also called the global maximum) of a function is the largest output value of a function on its entire domain.
What is the absolute minimum of a function?
The absolute minimum (also called the global minimum) of a function is the smallest output value of a function on its entire domain.
The formal definition of absolute maxima is
Let a function \( f \) be defined over an interval \( I \) with a value \( c \) that is a subset of \( I \).
You say that \( f \) has an absolute maximum on \( I \) at \( c \) if \( f(c) \geq f(x) \) for all \( x \) that is a subset of \( I \).
The formal definition of absolute minima is
Let a function \( f \) be defined over an interval \( I \) with a value \( c \) that is a subset of \( I \).
You say that \( f \) has an absolute minimum on \( I \) at \( c \) if \( f(c) \leq f(x) \) for all \( x \) that is a subset of \( I \).
The formal definition of absolute extremum is
Let a function \( f \) be defined over an interval \( I \) with a value \( c \) that is a subset of \( I \).
If \( f \) has either an absolute maximum or an absolute minimum on \( I \) at \( c \), you say that \( f \) has an absolute extremum on \( I \) at \( c \).
Absolute extrema can be
positive
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