AP Physics C: Mechanics : Rotational Motion and Torque

Study concepts, example questions & explanations for AP Physics C: Mechanics

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Example Questions

Example Question #1 : Rotational Motion And Torque

What is the rotational equivalent of mass?

Possible Answers:

Angular momentum 

Torque

Radius

Moment of inertia 

Correct answer:

Moment of inertia 

Explanation:

The correct answer is moment of inertia. For linear equations, mass is what resists force and causes lower linear accelerations. Similarly, in rotational equations, moment of inertia resists torque and causes lower angular accelerations. 

Example Question #2 : Rotational Motion And Torque

In rotational kinematics equations, what quantity is analogous to force in linear kinematics equations?

Possible Answers:

Angular acceleration

Torque

Moment of inertia

Impulse

Correct answer:

Torque

Explanation:

Just as force causes linear acceleration, torque causes angular acceleration. This can be seen most in the linear-rotational comparison of Newton's second law:

Example Question #1 : Understanding Linear Rotational Equivalents

A boot is put in a  stick which is attached to a rotor. The rotor turns with an angular velocity of . What is the linear velocity of the boot?

Possible Answers:

Correct answer:

Explanation:

Linear (tangential) velocity,  is given by the following equation: 

Here,  is the angular velocity in radians per second and  is the radius in meters.

Solve.

 

Example Question #1 : Circular And Rotational Motion

Angular momentum of a particle

A particle is moving at constant speed in a straight line past a fixed point in space, c. How does the angular momentum of the particle about the fixed point in space change as the particle moves from point a to point b?

Possible Answers:

The angular momentum decreases

The angular momentum increases

The particle does not have angular momentum since it is not rotating

It cannot be determined without knowing the mass of the particle

The angular momentum does not change

Correct answer:

The angular momentum does not change

Explanation:

The angular momentum of a particle about a fixed axis is . As the particle draws nearer the fixed axis, both  and  change. However, the product  remains constant. If you imagine a triangle connecting the three points, the product  represents the  "of closest approach", labeled "" in the diagram.

Angular momentum of a particle solution

Example Question #51 : Motion

Doing which of the following would allow you to find the center of mass of an object? 

Possible Answers:

Spinning it 

Sliding it along a flat surface

Hanging it from a fixed point

Recording its shape

Correct answer:

Spinning it 

Explanation:

Center of mass can be found by spinning an object. It will naturally spin around its center of mass, due to the concept of even distribution of mass in relation to the center of mass. Shape and mass are important factors in this property, but the most improtant factor is the mass distribution.

Example Question #52 : Motion

If the fulcrum of a balanced scale is shifted to the left, what type of adjustment must be made to rebalance the scale?

Possible Answers:

Apply more mass to the right end

Apply the same amount of mass to both ends

Apply more mass to the left end

Apply more mass to the new position of the fulcrum

If the scale was initially balanced, moving the fulcrum will not change this

Correct answer:

Apply more mass to the left end

Explanation:

Changing the position of the fulcrum by moving it to the left means the center of mass will be to the right of the new position. Therefore, the scale will tip right. Adding more mass to the left end will rebalance the scale. None of the other options make sense. Adding more mass to the new fulcrum position will not change the balance of the scale because that mass is a negligible distance from the new fulcrum position and does nothing to change the masses on either side.

Example Question #53 : Motion

If two masses,  and  are placed on a seesaw of length , where must the fulcrum be placed such that the seesaw remains level?

Possible Answers:

Correct answer:

Explanation:

This question asks us to find the center of mass for this system. We know that the center of mass resides a distance  from the first mass such that:

 

In this case:

Plug in known values and solve.

Example Question #1 : Rotational Motion And Torque

Three  point masses are at the points ,  and


and a  point mass is at the point .

How far from the origin is the center of mass of the system?

Possible Answers:

Correct answer:

Explanation:

To find the center of mass, we have to take the weighted average of the x coordinates and the y coordinates.

 Measures:                                        Measures

                             

 

First, we take the weighted measurement of the x-axis:

We can see that the result of the x-axis contribution is equal to .

Now, let's look at the y-axis contribution:

This equals to 

Now that we have the x and y components, we take the root of squares to get the final answer:

This will give us 

Example Question #1 : Using Torque Equations

An object starts from rest and accelerates to an angular velocity of  in three seconds under a constant torque of . How many revolutions has the object made in this time?

Possible Answers:

Correct answer:

Explanation:

Since it is experiencing a constant torque and constant angular acceleration, the angular displacement can be calculated using:

The angular acceleration is easily calculated using the angular velocity and the time:

Using this value, we can find the angular displacement:

Convert the angular displacement to revolutions by diving by :

Example Question #1 : Using Torque Equations

A circular disk of radius 0.5m and mass 3kg has a force of 25N exerted perpendicular to its edge, causing it to spin. What is the angular acceleration of the disk?

Possible Answers:

Correct answer:

Explanation:

We can find the angular acceleration using the rotaional motion equivalent of Newton's second law. In rotational motion, torque is the product of moment of inertia and angular acceleration: 

The moment of inertia for a circular disk is:

The tourque is the product of force and distance (in this case, the radius):

We can plug these into our first equation:

Simplify and rearrange to derive an equation for angular acceleration:

Use our given values to solve:

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