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Chapter 9: Problem 18

A CD starts from rest and speeds up to the operating angular frequency of the CD player. Compare the angular velocity and acceleration of a point on the edge of the CD to those of a point halfway between the center and the edge of the CD. Do the same for the linear velocity and acceleration.

Short Answer

Expert verified
Answer: The angular velocity and acceleration are the same for both points since they are on the same rotating CD. However, the linear velocity and acceleration of the point on the edge are twice the linear velocity and acceleration of the point halfway between the center and the edge.

Step by step solution

01

Identify knowns and unknowns

In this problem, we know the CD starts from rest and accelerates to its operating angular frequency (ω). We are asked to find the angular and linear values of velocity and acceleration for two points on the CD. Let's define two points: - Point A: On the edge of the CD - Point B: Halfway between the center and the edge of the CD As both points are on the same CD, they share the same angular characteristics, i.e. ω and α. We just need to find the linear variables, v and a, for each point.
02

Angular Variables

Since both points are on the same rotating CD, they will have the same angular velocity (ω) and angular acceleration (α). Therefore: ω_A = ω_B = ω α_A = α_B = α
03

Linear Variables

For the linear variables, we can use the following relationships: v = rω a = rα To find the exact values, we need the radius of the CD and the distance between the center and point B. However, as our task is to compare the two points, we can analyze them using ratios. Let R be the radius of the CD. Then, we have: v_A = Rω v_B = (R/2)ω Now, we can see that the linear velocity of point A is twice the linear velocity of point B: v_A = 2v_B Next, let's analyze the linear acceleration: a_A = Rα a_B = (R/2)α Similarly, the linear acceleration of point A is twice the linear acceleration of point B: a_A = 2a_B
04

Conclusion

In this exercise, we have compared the angular and linear variables of velocity and acceleration of two points on a CD. We have found that, since both points are on the same rotating CD, they have the same angular velocity (ω) and angular acceleration (α): ω_A = ω_B = ω α_A = α_B = α However, the linear velocity and acceleration are different due to their varying distances from the center: v_A = 2v_B a_A = 2a_B Thus, the point on the edge of the CD (point A) experiences twice the linear velocity and acceleration as the point halfway between the center and the edge (point B).

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Most popular questions from this chapter

Suppose you are riding on a roller coaster, which moves through a vertical circular loop. Show that your apparent weight at the bottom of the loop is six times your weight when you experience weightlessness at the top, independent of the size of the loop. Assume that friction is negligible.

A particular Ferris wheel takes riders in a vertical circle of radius \(9.0 \mathrm{~m}\) once every \(12.0 \mathrm{~s} .\) a) Calculate the speed of the riders, assuming it to be constant. b) Draw a free-body diagram for a rider at a time when she is at the bottom of the circle. Calculate the normal force exerted by the seat on the rider at that point in the ride. c) Perform the same analysis as in part (b) for a point at the top of the ride.

In a department store toy display, a small disk (disk 1) of radius \(0.100 \mathrm{~m}\) is driven by a motor and turns a larger disk (disk 2) of radius \(0.500 \mathrm{~m}\). Disk 2 , in turn, drives disk 3 , whose radius is \(1.00 \mathrm{~m}\). The three disks are in contact and there is no slipping. Disk 3 is observed to sweep through one complete revolution every \(30.0 \mathrm{~s}\) a) What is the angular speed of disk \(3 ?\) b) What is the ratio of the tangential velocities of the rims of the three disks? c) What is the angular speed of disks 1 and \(2 ?\) d) If the motor malfunctions, resulting in an angular acceleration of \(0.100 \mathrm{rad} / \mathrm{s}^{2}\) for disk 1 , what are disks 2 and 3's angular accelerations?

A carousel at a carnival has a diameter of \(6.00 \mathrm{~m}\). The ride starts from rest and accelerates at a constant angular acceleration to an angular speed of 0.600 rev/s in \(8.00 \mathrm{~s}\). a) What is the value of the angular acceleration? b) What are the centripetal and angular accelerations of a seat on the carousel that is \(2.75 \mathrm{~m}\) from the rotation axis? c) What is the total acceleration, magnitude and direction, \(8.00 \mathrm{~s}\) after the angular acceleration starts?

In a tape recorder, the magnetic tape moves at a constant linear speed of \(5.6 \mathrm{~cm} / \mathrm{s}\). To maintain this constant linear speed, the angular speed of the driving spool (the take-up spool) has to change accordingly. a) What is the angular speed of the take-up spool when it is empty, with radius \(r_{1}=0.80 \mathrm{~cm} ?\) b) What is the angular speed when the spool is full, with radius \(r_{2}=2.20 \mathrm{~cm} ?\) c) If the total length of the tape is \(100.80 \mathrm{~m}\), what is the average angular acceleration of the take-up spool while the tape is being played?
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