Section3.2Using derivatives to describe families of functions
Motivating Questions
Given a family of functions that depends on one or more parameters, how does the shape of the graph of a typical function in the family depend on the value of the parameters?
How can we construct first and second derivative sign charts of functions that depend on one or more parameters while allowing those parameters to remain arbitrary constants?
Mathematicians are often interested in making general observations, say by describing patterns that hold in a large number of cases. Think about the Pythagorean Theorem: it doesn’t tell us something about a single right triangle, but rather a fact about every right triangle. In the next part of our studies, we use calculus to make general observations about families of functions that depend on one or more parameters. People who use applied mathematics, such as engineers and economists, often encounter the same types of functions where only small changes to certain constants occur. These constants are called parameters.
You are already familiar with certain families of functions. For example, is a stretched and shifted version of the sine function with amplitude , period , phase shift , and vertical shift . We know that affects the size of the oscillation, the rapidity of oscillation, and where the oscillation starts, as shown in Figure 3.2.1, while affects the vertical positioning of the graph.
As another example, every function of the form is a line with slope and -intercept . The value of affects the line’s steepness, and the value of situates the line vertically on the coordinate axes. These two parameters describe all possible non-vertical lines.
For other less familiar families of functions, we can use calculus to discover where key behavior occurs: where members of the family are increasing or decreasing, concave up or concave down, where relative extremes occur, and more, all in terms of the parameters involved. To get started, we revisit a common collection of functions to see how calculus confirms things we already know.
Subsection3.2.1Describing families of functions in terms of parameters
Our goal is to describe the key characteristics of the overall behavior of each member of a family of functions in terms of its parameters. By finding the first and second derivatives and constructing sign charts (each of which may depend on one or more of the parameters), we can often make broad conclusions about how each member of the family will appear.
Consider the two-parameter family of functions given by , where and are positive real numbers. Fully describe the behavior of a typical member of the family in terms of and , including the location of all critical numbers, where is increasing, decreasing, concave up, and concave down, and the long term behavior of .
Since we are given that and we know that for all values of , the only way this equation can hold is when . Solving for , we find , and this is therefore the only critical number of .
Because the factor is always positive, the sign of depends on the linear factor , which is positive for and negative for . Hence we can not only conclude that is always increasing for and decreasing for , but also that has a global maximum at and no local minimum.
We observe that is always positive, and thus the sign of depends on the sign of , which is zero when . Since is positive, the value of is negative for and positive for . The sign chart for is shown in Figure 3.2.4. Thus, is concave down for all and concave up for all .
All of this information now helps us produce the graph of a typical member of this family of functions without using a graphing utility (and without choosing particular values for and ), as shown in Figure 3.2.5.
Note that the value of controls the horizontal location of the global maximum and the inflection point, as neither depends on . The value of affects the vertical stretch of the graph. For example, the global maximum occurs at the point , so the larger the value of , the greater the value of the global maximum.
The work we’ve completed in Example 3.2.2 can often be replicated for other families of functions that depend on parameters. Normally we are most interested in determining all critical numbers, a first derivative sign chart, a second derivative sign chart, and the limit of the function as . Throughout, we prefer to work with the parameters as arbitrary constants. In addition, we can experiment with some particular values of the parameters present to reduce the algebraic complexity of our work. The following activities offer several key examples where we see that the values of the parameters substantially affect the behavior of individual functions within a given family.
Construct a first derivative sign chart for . What can you say about the overall behavior of if the constant is positive? Why? What if the constant is negative? In each case, describe the relative extremes of .
Find and construct a second derivative sign chart for . What does this tell you about the concavity of ? What role does play in determining the concavity of ?
Finally, use a graphing utility to test your observations above by entering and plotting the function for at least four different values of . Write several sentences to describe your overall conclusions about how the behavior of depends on .
Consider the two-parameter family of functions of the form , where and are positive real numbers.
Find the first derivative and the critical numbers of . Use these to construct a first derivative sign chart and determine for which values of the function is increasing and decreasing.
Without using a graphing utility, sketch the graph of a typical member of this family. Write several sentences to describe the overall behavior of a typical function and how this behavior depends on and .
find all values of such that and hence construct a second derivative sign chart. For which values of is a function in this family concave up? concave down?
Without using a graphing utility, sketch the graph of a typical member of this family. Write several sentences to describe the overall behavior of a typical function and how this behavior depends on ,, and number.
Explain why it is reasonable to think that the function models the growth of a population over time in a setting where the largest possible population the surrounding environment can support is .
Given a family of functions that depends on one or more parameters, by investigating how critical numbers and locations where the second derivative is zero depend on the values of these parameters, we can often accurately describe the shape of the function in terms of the parameters.
In particular, just as we can created first and second derivative sign charts for a single function, we often can do so for entire families of functions where critical numbers and possible inflection points depend on arbitrary constants. These sign charts then reveal where members of the family are increasing or decreasing, concave up or concave down, and help us to identify relative extremes and inflection points.
(Enter your maxima and minima as comma-separated xvalue,classification pairs. For example, if you found thatwas a local minimum andwas a local maximum, you should enter(-2,min), (3,max). If there were no maximum, you must drop the parentheses and enter-2,min.)
What effect does increasing the value of have on the -position of the maximum(s) you found? (Enter left, none or right if it moves left, has no effect, or moves right.)
What effect does increasing the value of have on the -position of the minimum(s) you found? (Enter left, none or right if it moves left, has no effect, or moves right.)
What effect does increasing the value of have on the -coordinate of the maximum(s) you found? (Enter up, none or down if it moves up, has no effect, or moves down.)
What effect does increasing the value of have on the -coordinate of the minimum(s) you found? (Enter up, none or down if it moves up, has no effect, or moves down.)
Describe how the location of the critical numbers and the inflection point of change as changes. That is, if the value of is increased, what happens to the critical numbers and inflection point?
Construct a first derivative sign chart for and determine whether each critical number leads to a local minimum, local maximum, or neither for the function .