In Section 2.2 we explored the meaning and use of the derivative. This section starts by revisiting some of those ideas.
Recall that the derivative of a function can be used to find the slopes of lines tangent to the graph of . At , the tangent line to the graph of has equation
The tangent line can be used to find good approximations of for values of near . (This tangent line is also called the linearization of at .)
For instance, we can approximate using the tangent line to the graph of at Recall that , and . Thus the tangent line to at is:
In Figure 4.3.1(a), we see a graph of graphed along with its tangent line at . The small rectangle shows the region that is displayed in Figure 4.3.1(b). In this figure, we see how we are approximating with the tangent line, evaluated at . Together, the two figures show how close these values are.
Using this line to approximate , we have:
(We leave it to the reader to see how good of an approximation this is.)
We now generalize this concept. Given and an -value , the tangent line is . Clearly, . Let be a small number, representing a small change in value. We assert that:
since the tangent line to a function approximates well the values of that function near .
As the value changes from to , the value of changes from to . We call this change of value . That is:
Replacing with its tangent line approximation, we have
(4.3) |
This final equation is important; we’ll come back to it in Key Idea 4.3.1.
We introduce two new variables, and in the context of a formal definition.
Let be differentiable. The differential of , denoted , is any nonzero real number (usually taken to be a small number). The differential of , denoted , is
We can solve for in the above equation: . This states that the derivative of with respect to is the differential of divided by the differential of ; this is not the alternate notation for the derivative, . This latter notation was chosen because of the fraction-like qualities of the derivative, but again, it is one symbol and not a fraction.
It is helpful to organize our new concepts and notations in one place and an accompanying figure.
Let be a differentiable function.
represents a small, nonzero change in value.
represents a small, nonzero change in value (i.e., ).
is the change in value as changes by ; hence
which, by Equation (4.3), is an approximation of the change in value as changes by ; .
What is the value of differentials? Like many mathematical concepts, differentials provide both practical and theoretical benefits. We explore both here.
Watch the video:
Differentials 2 from https://youtu.be/AvM8-LUdg84
Consider . Knowing , approximate .
SolutionThe value is changing from to ; therefore, we see that . If we know how much the value changes from to (i.e., if we know ), we will know exactly what is (since we already know ). We can approximate with .
We expect the value to change by about , so we approximate
We leave it to the reader to verify this, but the preceding discussion links the differential to the tangent line of at . One can verify that the tangent line, evaluated at , also gives .
Of course, it is easy to compute the actual answer (by hand or with a calculator): (Before we get too cynical and say “Then why bother?”, note our approximation is really good!)
So why bother?
In “most” real life situations, we do not know the function that describes a particular behavior. Instead, we can only take measurements of how things change — measurements of the derivative.
Imagine water flowing down a winding channel. It is easy to measure the speed and direction (i.e., the velocity) of water at any location. It is very hard to create a function that describes the overall flow, hence it is hard to predict where a floating object placed at the beginning of the channel will end up. However, we can approximate the path of an object using differentials. Over small intervals, the path taken by a floating object is essentially linear. Differentials allow us to approximate the true path by piecing together lots of short, linear paths. This technique is called Euler’s Method, studied in introductory Differential Equations courses.
We use differentials once more to approximate the value of a function. Even though calculators are very accessible, it is neat to see how these techniques can sometimes be used to easily compute something that looks rather hard.
Approximate .
SolutionWe expect , yet we can do better. Let , and let . Thus . We can compute , so .
We approximate the difference between and using differentials, with :
The approximate change in from to is , so we approximate
Differentials are important when we discuss integration. When we study that topic, we will use notation such as
quite often. While we don’t discuss here what all of that notation means, note the existence of the differential . Proper handling of integrals comes with proper handling of differentials.
In light of that, we practice finding differentials in general.
In each of the following, find the differential .
Solution
: As , . Thus
: Let . We need , requiring the Product Rule.
We have , so
: Let ; we need , requiring the Chain Rule.
We have Thus
Finding the differential of is really no harder than finding the derivative of ; we just multiply by . It is important to remember that we are not simply adding the symbol “” at the end.
We have seen a practical use of differentials as they offer a good method of making certain approximations. Another use is error propagation. Suppose a length is measured to be , although the actual value is (where we hope is small). This measurement of may be used to compute some other value; we can think of this as for some function . As the true length is , one really should have computed . The difference between and is the propagated error.
How close are and ? This is a difference in “y” values;
We can approximate the propagated error using differentials.
A steel ball bearing is to be manufactured with a diameter of 2cm. The manufacturing process has a tolerance of mm in the diameter. Given that the density of steel is about 7.85g/cm, estimate the propagated error in the mass of the ball bearing.
SolutionThe mass of a ball bearing is found using the equation “mass = volume density.” In this situation the mass function is a product of the radius of the ball bearing, hence it is . The differential of the mass is
The radius is to be 1cm; the manufacturing tolerance in the radius is mm, or cm. The propagated error is approximately:
Is this error significant? It certainly depends on the application, but we can get an idea by computing the relative error. The ratio between amount of error to the total mass is
or %.
We leave it to the reader to confirm this, but if the diameter of the ball was supposed to be 10cm, the same manufacturing tolerance would give a propagated error in mass of g, which corresponds to a percent error of %. While the amount of error is much greater (), the percent error is much lower.
T/F: Given a differentiable function , we are generally free to choose a value for , which then determines the value of .
T/F: The symbols “” and “” represent the same concept.
T/F: The symbols “” and “” represent the same concept.
T/F: Differentials are important in the study of integration.
How are differentials and tangent lines related?
T/F:In real life, differentials are used to approximate function values when the function itself is not known.
In Exercises 7–16, use differentials to approximate the given value by hand.
In Exercises 17–30, compute the differential .
In Exercises 31–36, use the linear approximation to find an approximation for the function for values of near zero.
Exercises 37–40 use differentials to approximate propagated error
A set of plastic spheres are to be made with a diameter of 1cm. If the manufacturing process is accurate to 1mm, what is the propagated error in volume of the spheres?
What is the propagated error in the measurement of the cross sectional area of a circular log if the diameter is measured at , accurate to ?
A wall is to be painted that is exactly high and is measured to be long. Find the propagated error in the measurement of the wall’s surface area if the measurement of the length is accurate to .
Exercises 41–44 explore some issues related to surveying in which distances are approximated using other measured distances and measured angles. (Hint: Convert all angles to radians before computing.)
Answer the questions of item 41, but with a measured angle of , accurate to , measured from a point from the wall.
Consider the setup in item 43. This time, assume the angle measurement of is exact but the measured from the wall is accurate to . What is the approximate percent error?
Show that the linearization of at is .