4.3 Related Ratesap Calculus



AP® CALCULUS AB 2007 SCORING COMMENTARY Question 5 Overview The problem presented students with a table of values for the rate of change of the radius of an expanding spherical balloon over a time interval of 12 minutes. Students were told that the radius was modeled by a twice-differentiable function whose graph was concave down. Problems 21-29 are applications of related rates. 21 (Calculus classic) The bottom of a 10-foot ladder is going away from the wall at dx/dt = 2 feet per second. How fast is the top going down the wall? Draw the right triangle to find dy/dt when the height y is (a) 6 feet (b) 5 feet (c) zero. 22 The top of the 10-foot ladder can go faster than. 4.3.3 Explain how to find the critical points of a function over a closed interval. 4.3.4 Describe how to use critical points to locate absolute extrema over a closed interval. Given a particular function, we are often interested in determining the largest and smallest values of the function. In related rates problems we are give the rate of change of one quantity in a problem and asked to determine the rate of one (or more) quantities in the problem. This is often one of the more difficult sections for students.

The radius of a sphere is increasing at a rate of 2 meters per second. At what rate is the volume increasing when the radius is equal to 4 meters?

This type of problem is known as a 'related rate' problem. In this sort of problem, we know the rate of change of one variable (in this case, the radius) and need to find the rate of change of another variable (in this case, the volume), at a certain point in time (in this case, when r = 4). The reason why such a problem can be solved is that the variables themselves have a certain relation between them that can be used to find the relation between the known rate of change and the unknown rate of change.

Related rate problems can be solved through the following steps:
Step one: Separate 'general' and 'particular' information.
General information is information contained in the problem that is true at all times. Particular information is information that is true only at the particular instant that the problem is asking about.

For example, in this problem, the general information is that the radius is growing at a rate of 2 meters per second. Thus, if we let the radius of the sphere be represented by r, we can say that r'(t)=2 m/s.

The particular information is that at the moment of interest, r(t) = 4.

It is important to separate out these two types of information because information about the particular case must be set aside and must not be used until the very last step of solving the problem. One mistake that students frequently make is to use the particular information too early. This invariably leads to incorrect answers.


Step two: Draw a sketch of the situation using the general information only.This often helps to illuminate the relationship between the variables.
In this case, the general information leads to the following sketch:

Although we know the rate of change of r, we cannot depict a rate in the sketch.

Note here that it would be a mistake to write 'r = 4' in the sketch, since this is only true at one particular instant.


Step three: Identify the known rate and the desired rate

In this case, we know , and we want to find , the rate of change of the volume.


Step four: Use geometry or trigonometry to relate the variable with the known rate of change to the variable with the unknown rate of change.

The appropriate relation will often involve one of the following:

  1. Spheres: Radius vs. Surface area (4Πr2)vs. Volume (Πr3)
  2. Circles: Radius vs. Area (Πr2) vs. Circumference (2Πr)
  3. Cylinders: Radius and Height vs. Volume (Πr2h)
  4. Cones: Radius and Height vs. Volume (Πr2h) Also see similar triangles below.
  5. Right Triangles: Pythagorean Theorem (a2 + b2 = c2)
  6. Similar Triangles: = =
  7. Angles: Problems with angles will typically involve a trigonometric relation. Recall the 'SOHCAHTOA' relations (sin = , cos = , and tan = )
      In this case, the appropriate relation is
      Recall that both V and r are variables with change with time. Therefore, it is best to write the relation in a way that indicates this fact:
      V(t) = Πr(t)


      Step Five: Differentiate both sides of the equation with respect to timeNow that we have found a relationship between the variables, we must differentiate both sides of the equation to find a relationship between their rates of change (i.e., their derivatives). It is crucial to remember to use the chain rule here, since we are taking derivatives with respect to t:




      Step 6: Plug in the particular information to solve for the desired rate.Now, we can finally use the particular fact that r = 4 to solve for the unknown rate:


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      = 4Πr(t)
      = 4Π42
      = 128Π

      So, when the radius is 4 meters long, the volume is increasing at a rate of 128Π cubic meters per second.

The radius of a sphere is increasing at a rate of 2 meters per second. At what rate is the volume increasing when the radius is equal to 4 meters?

This type of problem is known as a 'related rate' problem. In this sort of problem, we know the rate of change of one variable (in this case, the radius) and need to find the rate of change of another variable (in this case, the volume), at a certain point in time (in this case, when r = 4). The reason why such a problem can be solved is that the variables themselves have a certain relation between them that can be used to find the relation between the known rate of change and the unknown rate of change.

Related rate problems can be solved through the following steps:
Step one: Separate 'general' and 'particular' information.
General information is information contained in the problem that is true at all times. Particular information is information that is true only at the particular instant that the problem is asking about.

For example, in this problem, the general information is that the radius is growing at a rate of 2 meters per second. Thus, if we let the radius of the sphere be represented by r, we can say that r'(t)=2 m/s.

The particular information is that at the moment of interest, r(t) = 4.

4.3 Related Ratesap Calculus

It is important to separate out these two types of information because information about the particular case must be set aside and must not be used until the very last step of solving the problem. One mistake that students frequently make is to use the particular information too early. This invariably leads to incorrect answers.


Step two: Draw a sketch of the situation using the general information only.This often helps to illuminate the relationship between the variables.
In this case, the general information leads to the following sketch:

Although we know the rate of change of r, we cannot depict a rate in the sketch.

Note here that it would be a mistake to write 'r = 4' in the sketch, since this is only true at one particular instant.

4.3


Step three: Identify the known rate and the desired rate

Related

In this case, we know , and we want to find , the rate of change of the volume.


Step four: Use geometry or trigonometry to relate the variable with the known rate of change to the variable with the unknown rate of change.

The appropriate relation will often involve one of the following:

4.3 Related Ratesap Calculus Calculator

  1. Spheres: Radius vs. Surface area (4Πr2)vs. Volume (Πr3)
  2. Circles: Radius vs. Area (Πr2) vs. Circumference (2Πr)
  3. Cylinders: Radius and Height vs. Volume (Πr2h)
  4. Cones: Radius and Height vs. Volume (Πr2h) Also see similar triangles below.
  5. Right Triangles: Pythagorean Theorem (a2 + b2 = c2)
  6. Similar Triangles: = =
  7. Angles: Problems with angles will typically involve a trigonometric relation. Recall the 'SOHCAHTOA' relations (sin = , cos = , and tan = )
      In this case, the appropriate relation is
      Recall that both V and r are variables with change with time. Therefore, it is best to write the relation in a way that indicates this fact:
      V(t) = Πr(t)


      Step Five: Differentiate both sides of the equation with respect to timeNow that we have found a relationship between the variables, we must differentiate both sides of the equation to find a relationship between their rates of change (i.e., their derivatives). It is crucial to remember to use the chain rule here, since we are taking derivatives with respect to t:




      Step 6: Plug in the particular information to solve for the desired rate.Now, we can finally use the particular fact that r = 4 to solve for the unknown rate:


      = 4Πr(t)
      = 4Π42
      = 128Π

      So, when the radius is 4 meters long, the volume is increasing at a rate of 128Π cubic meters per second.