Chapter 2 Skill Building
Chapter 2 Skill Building
Chapter 2 Skill Building
Part A Which graph best represents the function x(t), describing the object's position vs. time? ANSWER: 1 2 3 4
Part B
Which of the following graphs best represents the function v(t), describing the object's velocity as a function of time? Part B.1 Part not displayed Hint B.2 Hint not displayed Part B.3 Part not displayed Part B.4 Part not displayed ANSWER: Part C Which of the following graphs best represents the function a(t), describing the acceleration of this object? Part C.1 Part not displayed Part C.2 Part not displayed Hint C.3 Hint not displayed ANSWER: 1 2 3 4 1 2 3 4
A PSS is a problem solving strategy. They appear throughout the text. Pay serious attention to learning how to apply the strategy to all of your homework problems. In particular, get in the habit of using motion diagrams, and pictorial and graphical representations.
Learning Goal: To practice Problem-Solving Strategy 2.1 for problems involving kinematics with constant acceleration. A car is traveling at a constant velocity of magnitude when the driver notices a garbage can on the road in front of him. At that moment, the distance between the garbage can and the front of the car is . A time after noticing the garbage can, the driver applies the brakes and slows down at a constant rate before coming to a halt just before the garbage can. What is the magnitude of the car's acceleration after the brakes are applied?
MODEL: Use the particle model. Make other appropriate simplifying assumptions. VISUALIZE: Use different representations of the information in the problem.
s s
s s
Draw a motion diagram. Motion diagrams are part of the physical representation. Draw a pictorial representation. This helps you assess the information you are given and starts the process of translating that information into mathematical symbols. Use a graphical representation if appropriate for the problem. Go back and forth between these three representations as needed.
and .
s s
Use or , as appropriate to the problem, rather than the generic . If necessary, replace subscripts i and f with numerical subscripts defined in the pictorial representation. Recall that, for uniform motion with constant velocity, .
ASSESS: Is your result believable? Does it have appropriate units? Does it make sense?
The car should be treated as ANSWER: a solid macroscopic object of certain shape and size. a pointlike particle. a thin straight line.
Now draw a motion diagram and pictorial representation, including all the elements listed in the problem-solving strategy. Use your sketch to answer the following questions. Part B Consider the incomplete pictorial representation shown here: . Missing from this figure are the arrows representing the acceleration of the car for the two different segments of the motion. These arrows should appear below the symbols and . For each segment of the motion, indicate whether the acceleration of the car should be drawn as pointing to the right, as pointing to the left, or as having zero magnitude (and therefore no direction). Enter R for right, L for left, or 0 for each of the two accelerations. Separate your two answers with a comma. ANSWER: 0, L The list of known and unknown quantities are also missing from the diagram. You'll need to figure these out for yourself before you go on. Part C
Which diagram correctly shows position, velocity, and acceleration of the moving car after the brakes are applied?
ANSWER: Part D
Diagram (a) in the previous part is incorrect because it leads to which of the following incorrect conclusions about the motion of the car? A. B. C. D. E. F. G. The car is moving at constant speed. The car is speeding up. The car is not moving in a straight line. The direction of acceleration of the car does not agree with the velocity vectors. The acceleration of the car is decreasing. The acceleration of the car is increasing. The acceleration of the car is changing direction.
List alphabetically the letters corresponding to the statements describing the incorrect implications of diagram (a). Do not use commas. For instance, if you think that statements A, B, and C describe the errors in the diagram, enter ABC. ANSWER: BD Part E
Of the following list of variables, which represent known quantities? A. B. C. D. E. F. Enter the letters of the correct answers in alphabetical order. Do not use commas. ANSWER: BCDE Among the other variables in the pictorial representation provided in Part B, and . quantity and you can assume that is a known
Now use the information and the insights that you have accumulated to construct the necessary mathematical expressions and to derive the solution. Part F Find , the magnitude of the acceleration of the car. Part F.1 Part not displayed Hint F.2 Hint not displayed Express the magnitude of the acceleration in terms of the variables given in the problem introduction: , , and . You may or may not use all of them. ANSWER: =
When you work on a problem on your own, without the computer-provided feedback, only you can assess whether your answer seems right. The following questions will help you practice the skills necessary for such an assessment. Part G
Which of the following algebraic expressions have the dimensions of acceleration? A. B. C. D. E. List alphabetically the letters corresponding to all the expressions that have the correct dimensions. Do not use commas. For instance, if you think that expressions A, B, and C have the correct dimensions, enter ABC. ANSWER: ABDE Part H Imagine a situation exactly as given in the problem introduction except that the driver continues for a longer time between noticing the can and hitting the brakes. If he is still to stop just before hitting the can, how would the magnitude of his acceleration compare to that derived in the Solve step above? ANSWER: It would be the same. It would be greater. It would be smaller.
From the answer you derived, you can see that if increases, then the magnitude of the acceleration will increase. Of course, the driver cannot wait so long before hitting the brakes that ; otherwise he will already have collided with the can. Part I Imagine a situation exactly as given in the problem introduction except that the driver notices the garbage can from farther away. If he is still to stop just before hitting the can, how would the magnitude of his acceleration compare to that derived in the Solve step above? ANSWER: It would be the same. It would be greater. It would be smaller.
From the answer you derived, you can see that if acceleration will decrease.
ANSWER:
= 75.0
Part C What is the average acceleration Hint C.1 of the particle over the first 20.0 seconds? Hint not displayed Hint C.2 Hint not displayed Express your answer in meters per second per second. ANSWER: 7.5010 = 2 The average acceleration of a particle between two instants of time is the slope of the line connecting the two corresponding points in a v vs. t graph. Part D What is the instantaneous acceleration Hint D.1 Hint not displayed Hint D.2 Hint not displayed ANSWER: = The instantaneous acceleration of a particle at any point on a v vs. t graph is the slope of the line tangent to the curve at that point. Since in the last 10 seconds of motion, between and , the curve is a straight line, the tangent line is the curve itself. Physically, this means that the instantaneous acceleration of the particle is constant over that time interval. This is true for any motion where velocity increases linearly with time. In the case at hand, can you think of another time interval in which the acceleration of the particle is constant? Now that you have reviewed how to plot variables as a function of time, you can use the same technique and draw an acceleration vs. time graph, that is, the graph of (instantaneous) acceleration as a function of time. As usual in these types of graphs, time is plotted on the horizontal axis, while the vertical axis is used to indicate acceleration . 1 0.20 -0.20 0.022 -0.022 of the particle at ?
Part E Which of the graphs shown below is the correct acceleration vs. time plot for the motion described in the previous parts? Hint E.1 Hint not displayed Part E.2 Part not displayed Part E.3 Part not displayed Part E.4 Part not displayed
ANSWER:
Graph A
Graph B
Graph C
Graph D
motion. If read correctly, they can provide you with all the information you need to study the motion.
Kinematic Vocabulary
One of the difficulties in studying mechanics is that many common words are used with highly specific technical meanings, among them velocity, acceleratio n, position, speed, and displacement. The series of questions in this problem is designed to get you to try to think of these quantities like a physicist. Answer the questions in this problem using words from the following list: A. B. C. D. E. F. G. H. I. J. K. position direction displacement coordinates velocity acceleration distance magnitude vector scalar components
Part A Velocity differs from speed in that velocity indicates a particle's __________ of motion. Enter the letter from the list given in the problem introduction that best completes the sentence. ANSWER: B Part B Unlike speed, velocity is a __________ quantity. Enter the letter from the list given in the problem introduction that best completes the sentence. ANSWER: I Part C
A vector has, by definition, both __________ and direction. Enter the letter from the list given in the problem introduction that best completes the sentence. ANSWER: H Part D Once you have selected a coordinate system, you can express a two-dimensional vector using a pair of quantities known collectively as __________. Enter the letter from the list given in the problem introduction that best completes the sentence. ANSWER: D Part E Speed differs from velocity in the same way that __________ differs from displacement. Hint E.1 Hint not displayed Enter the letter from the list given in the problem introduction that best completes the sentence. ANSWER: G Part F Consider a physical situation in which a particle moves from point A to point B. This process is described from two coordinate systems that are identical except that they have different origins. The __________ of the particle at point A differ(s) as expressed in one coordinate system compared to the other, but the __________ from A to B is/are the same as expressed in both coordinate systems. Type the letters from the list given in the problem introduction that best complete the sentence. Separate the letters with commas. ANSWER: A, C The coordinates of a point will depend on the coordinate system that is chosen, but there are several other quantities that are independent of the choice of origin for a coordinate system: in particular, distance, displacement, direction, and velocity. In working physics problems, unless you are interested in the position of an object or event relative to a specific origin, you can usually choose the coordinate system origin to be wherever is most convenient or intuitive. Note that the vector indicating a displacement from A to B is usually represented as
. Part G Which of the following physical quantities are scalars? A. B. C. D. E. F. G. position velocity displacement speed acceleration average velocity distance
Type the letters of all the correct answers in alphabetical order. For this question do not separate your answers with commas. ANSWER: DG The other quantities are vectors.
is the velocity of the particle; is the initial velocity of the particle; is the acceleration of the particle. .
In anwering the following questions, assume that the acceleration is constant and nonzero: Part A The quantity represented by ANSWER: true false is a function of time (i.e., is not constant).
Part B The quantity represented by ANSWER: true false is a function of time (i.e., is not constant).
Recall that represents an initial value, not a variable. It refers to the position of an object at some initial moment. Part C The quantity represented by ANSWER: true false is a function of time (i.e., is not constant).
Part D The quantity represented by ANSWER: true false always varies with time when the linear acceleration is nonzero. is a function of time (i.e., is not constant).
Which of the given equations is not an explicit function of know or don't need the time? ANSWER:
Part F A particle moves with constant acceleration . The expression velocity at what instant in time? ANSWER: at time at the "initial" time when a time has passed since the particle's velocity was More generally, the equations of motion can be written as represents the particle's
and . Here is the time that has elapsed since the beginning of the particle's motion, that is,
, where is the current time and is the time at which we start measuring the particle's . As you can now motion. The terms and are, respectively, the position and velocity at , which is a see, the equations given at the beginning of this problem correspond to the case convenient choice if there is only one particle of interest. To illustrate the use of these more general equations, consider the motion of two particles, A and B. . That is, particle A starts The position of particle A depends on time as moving at time with velocity , from . At time , particle B has . twice the acceleration, half the velocity, and the same position that particle A had at time
Part G What is the equation describing the position of particle B? Hint G.1 Hint not displayed ANSWER:
Part H At what time does the velocity of particle B equal that of particle A? Part H.1 Part not displayed Part H.2 Part not displayed ANSWER:
Hint not displayed Hint A.2 Hint not displayed Express your answer in meters. ANSWER: = 30.0 Part B What is the average velocity Hint B.1 Hint not displayed Hint B.2 Hint not displayed Express your answer in meters per second. ANSWER: = 0.600 The average velocity of a particle between two positions is equal to the slope of the line connecting the two corresponding points in an x vs. t graph. Part C of the particle over the time interval ?
of the particle at
Hint not displayed Express your answer in meters per second. ANSWER: = 0.600 The instantaneous velocity of a particle at any point on its x vs. t graph is the slope of the line tangent to the curve at that point. Since in the case at hand the curve is a straight line, the tangent line is the curve itself. Physically, this means that the instantaneous velocity of the particle is constant over the entire time interval of motion. This is true for any motion where distance increases linearly with time. Another common graphical representation of motion along a straight line is the v vs. t graph, that is, the graph of (instantaneous) velocity as a function of time. In this graph, time is plotted on the horizontal axis and velocity on the vertical axis. Note that by definition, velocity and acceleration are vector quantities. In straight-line motion, however, these vectors have only one nonzero component in the direction of motion. Thus, in this problem, we will call the velocity and the acceleration, even though they are really the components of the velocity and acceleration vectors in the direction of motion. Part D Which of the graphs shown is the correct v vs. t plot for the motion described in the previous parts? Hint D.1 Hint not displayed
ANSWER:
Graph A
Graph B
Graph C
Graph D
Whenever a particle moves with constant nonzero velocity, its x vs. t graph is a straight line with a nonzero slope, and its v vs. t curve is a horizontal line. Part E Shown in the figure is the v vs. t curve selected in the previous part. What is the area shaded region under the curve? of the
Hint E.1 Hint not displayed Express your answer in meters. ANSWER: = 30.0 Compare this result with what you found in Part A. As you can see, the area of the region under the v vs. t curve equals the total distance traveled by the particle. This is true for any velocity curve and any time interval: The area of the region that extends over a time interval under the v vs. t curve is always equal to the distance traveled in .
ANSWER: =
Part B If the bottom of your window is a height above the ground, what is the velocity of the pot as it hits the ground? You may introduce the new variable , the speed at the bottom of the window, defined by .
Hint B.1 Hint not displayed Part B.2 Part not displayed Express your answer in terms of some or all of the variables ANSWER: = , , , , and .
If the ball that is thrown downward has an acceleration of magnitude at the instant of its release (i.e., when there is no longer any force on the ball due to the woman's hand), what is the relationship between and , the magnitude of the acceleration of gravity? ANSWER:
Part B Which ball has the greater acceleration at the instant of release? ANSWER: the ball thrown upward the ball thrown downward Neither; the accelerations of both balls are the same.
Part C Which ball has the greater speed at the instant of release? Hint C.1 Hint not displayed ANSWER: the ball thrown upward the ball thrown downward Neither; the speeds are the same.
Part D Which ball has the greater average speed during the 1-s interval after release (assuming neither hits the ground during that time)? Hint D.1 Hint not displayed ANSWER: the ball thrown upward the ball thrown downward Neither; the average speeds of both balls are the same.
Part E Which ball hits the ground with greater speed? ANSWER: the ball thrown upward the ball thrown downward Neither; the balls hit the ground with the same speed.
Part A At which of the times do the two cars pass? Hint A.1 Hint not displayed ANSWER: Part B Are the two cars traveling in the same direction when they pass? ANSWER: Part C yes no D
At which of the lettered times, if any, does car #1 momentarily stop? Hint C.1 Hint not displayed ANSWER: Part D At which of the lettered times, if any, does car #2 momentarily stop? Hint D.1 Hint not displayed ANSWER: Part E At which of the lettered times are the cars moving at approximately the same velocity? Hint E.1 Hint not displayed ANSWER: A C none
Part A During which trial or trials is the object's velocity not constant? A. B. C. D. Trial A Trial B Trial C Trial D
Hint A.1 Hint not displayed Hint A.2 Hint not displayed Enter the letters of the correct statement (s) in alphabetical order. For example, if A and C are correct, enter AC. ANSWER: B The graph of the motion during Trail B has a changing slope and therefore is not constant. The other trials all have graphs with constant slope and thus correspond to motion with constant velocity. Part B During which trial or trials does the object have the greatest average velocity? A. B. C. D. Trial A Trial B Trial C Trial D
Hint B.1 Hint not displayed Enter the letters of the correct statement(s) in alphabetical order. For example, if A and C are correct, enter AC. ANSWER: B
You recognized that although the magnitudes of the average velocity in Trial B and Trial D are equal, their directions are opposite. This makes the average velocity in Trial D less than the average velocity in Trial B. The object does not move during Trial C, so it has an average velocity of zero. During Trial A the object has a positive average velocity but its magnitude is less than that in Trial B.