Concept explainers
A nylon string has mass 5.50 g and length L = 86.0 cm. The lower end is tied to the floor, and the upper end is tied to a small set of wheels through a slot in a track on which the wheels move (Fig. P14.56). The wheels have a mass that is negligible compared with that of the string, and they roll without friction on the track so that the upper end of the string is essentially free. At equilibrium, the string is vertical and motionless. When it is carrying a small-amplitude wave, you may assume the string is always under uniform tension 1.30 N. (a) Find the speed of transverse waves on the string. (b) The string’s vibration possibilities are a set of standing-wave states, each with a node at the fixed bottom end and an anti-node at the free top end. Find the node–antinode distances for each of the three simplest states. (c) Find the frequency of each of these states.
Figure P14.56
(a)
The speed with which the transverse waves travel
Answer to Problem 56P
The speed of the transverse waves is
Explanation of Solution
Write the equation for the speed of the transverse wave.
Here,
Write the equation for the mass per unit length of the string.
Here,
Conclusion:
Substitute
Therefore, the speed of the transverse waves is
(b)
The distance between the node and the antinode
Answer to Problem 56P
The node-antinode distance for the three simplest states is
Explanation of Solution
The distance between an adjacent node and antinode is on-quarter of a wavelength of the standing wave. There can only be odd number of node-antinode pairs as there is a node at the bottom and an antinode at the top.
Conclusion:
The simplest pattern is one node-antinode pair given as
Here,
The next simplest pattern is three node-antinode pairs given as
Therefore, there are three node-antinode pairs. Write the equation for the distance between the node and antinode in this pattern of three pairs.
Here,
Similarly, the next simplest pattern is
Here,
Therefore, from equation (II), equation (III) and equation (IV), the node-antinode distance for the three simplest states is
(c)
The frequency of the simplest states
Answer to Problem 56P
The frequency of the each of the simplest states is
Explanation of Solution
Write the equation for the frequency of the states.
Here,
Conclusion:
Substitute
Substitute equation (II) in equation (VI) and also
Substitute
Substitute equation (III) in equation (VIII) and also
Substitute
Substitute equation (IV) in equation (X) and also
Therefore, from equation (VII), equation (IX) and equation (XI), the frequency of the simplest states is
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Chapter 14 Solutions
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