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The purpose of this lab is to acquaint you with techniques for finding
and classifying local and global extreme values of functions of two
To assist you, there is a worksheet associated with this lab that
contains examples. You can
copy that worksheet to your home directory with the following command,
which must be run in a terminal window, not in Maple.
cp ~bfarr/Extrema2D_start.mws ~
You can copy the worksheet now, but you should read through the lab
before you load it into Maple. Once you have read to the exercises,
start up Maple, load
the worksheet Extrema2D_start.mws, and go through it
carefully. Then you can start working on the exercises.
Many applications of calculus involve finding the maximum and minimum
values of functions. For example, suppose that there is a network of
electrical power generating stations, each with its own cost for
producing power, with the cost per unit of power at each station
changing with the amount of power it generates. An important problem
for the network operators
is to determine how much power each station should generate to
minimize the total cost of generating a given amount of power.
A crucial first step in solving such problems is being able to find
and classify local extreme values of a function. What we mean by a
function having a local extreme value at a point is
that for values of near ,
for a local maximum and
for a local minimum.
calculus, we found that we could locate candidates for local extreme
values by finding points where the first derivative vanishes. For
functions of two dimensions, the condition is that both first order
partial derivatives must vanish at a local extreme value candidate
point. Such a point is called a stationary point. It is also one of
the three types of points called critical points.
Note carefully that the condition does not say that a point where the partial
derivatives vanish must be a local extreme point. Rather, it says that
stationary points are candidates for local extrema. Just as was the case
for functions of a single variable, there can be stationary points that
are not extrema. For example, the saddle surface
has a stationary point at the origin, but it is not a local extremum.
Finding and classifying the local extreme values of a function
requires several steps. First, the partial derivatives must
be computed. Then the stationary points must be solved for, which is not
always a simple task. Next, one must check for the presence of
singular points, which might also be local extreme
values. Finally, each
critical point must be classified
as a local maximum, local minimum, or neither. The examples in the
Getting Started worksheet
are intended to help you learn how to use Maple to simplify these tasks.
In one-dimensional calculus, the absolute or global extreme values of
a function occur either at a point where the derivative is zero, a
boundary point, or where the derivative fails to exist. The situation
for a function of two variables is very similar, but the problem is
much more difficult because the boundary now consists of curves
instead of just endpoints of intervals. For example, suppose that we
wanted to find the global extreme values of a function on the
. The boundary of this rectangle consists of the four line
segments given below.
The basic theorem on the existence of global maximum and minimum values is
This theorem only says that the extrema exist, but doesn't help at all
in finding them. However, we know that the global extrema occur either
at local extrema, on the boundary of the region, or at points where
one or the other partial derivative fails to exist. For example, to
find the extreme values of a
function on the rectangle given above, you would first have to
find the interior critical points and then find the extreme values for
the four one-dimensional functions
is continuous on a closed, bounded set
attains its absolute
maximum value at some point
and absolute minimum value at
- Find and classify the stationary points for the following
(Hint - there are 4.)
- Consider the function
Find the absolute extrema of this function on the
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William W. Farr