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Superposition and Standing Waves (Cont.)

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Title: Superposition and Standing Waves (Cont.)


1
Chapter 18
  • Superposition and Standing Waves (Cont.)

2
Outline
  • Standing waves
  • Standing waves in a string fixed at both ends
  • Standing waves in air columns
  • Resonance

3
Standing waves
  • Standing wave An oscillation pattern with a
    stationary outline that results from the
    superposition of two identical waves traveling in
    opposite directions.
  • y1 A sin(kx - ?t), y2 A sin(kx ?t)
  • y y1 y2 (2A sinkx) cos ?t
  • Nodes The points of zero displacement are called
    nodes Antinodes The positions in the medium at
    which the maximum displacement of 2A occurs.
  • The distance between adjacent antinodes ?/2
    The distance between adjacent nodes ?/2 The
    distance between a node and an adjacent antinode
    ?/4.
  • Important features for a standing wave
  • It is not a traveling wave.
  • Every particle of the medium oscillates in
    simple harmonic motion with the same frequency ?.
  • The amplitude of a given particle depends on the
    location x of the particle.

4
Problem 14
  • Two waves in a long string are given by
  • where y1, y2, and x are in meters and t is in
    seconds.
  • (a) Determine the positions of the nodes of the
    resulting standing wave.
  • (b) What is the maximum transverse position of an
    element of the string at the position x 0.400 m?

5
Standing waves in a string fixed at both ends
  • Normal modes Natural patterns of oscillation,
    each of which has a characteristic frequency.
  • Wavelengths of the normal modes ?n 2L/n,
    n1,2,3
  • Index n Refers to the nth normal mode of
    oscillation.
  • Natural frequencies of normal modes
  • Fundamental (frequency)
  • fn nf1- harmonic series and the normal modes
    are called harmonics.

6
Example 18.4
  • The high E string on a guitar measures 64.0cm in
    length and has a fundamental frequency of 330Hz.
    By pressing down on it at the first fret
    (Fug.18.8), the string is shortened so that it
    plays an F note that has a frequency of 350 Hz.
    Haw far is the fret from the neck end of the
    string?

7
Standing waves in air columns
  • Standing waves can be set up in a tube of air.
  • (1) In a pipe open at both ends, natural
    frequencies of oscillation fnnv/(2L), n1,2,3
  • (2) In a pipe closed at one end and open at the
    other, natural frequencies of oscillation fn
    nv/(4L), n1,3,5

8
Resonance
  • Resonance If a periodic force is applied to a
    system, the amplitude of the resulting motion is
    greater than normal when the frequency of the
    applied force is equal or nearly equal to one of
    the natural frequencies (resonant frequencies) of
    the system.
  • An example of resonance

9
Example 18.6
  • A vertical pipe open at both ends is partially
    submerged in water, and a tuning fork vibrating
    at an unknown frequency is placed near the top of
    the pipe. The length L of the air column can be
    adjusted by moving the pipe vertically. The sound
    waves generated by the fork are reinforced when L
    corresponds to one of the resonance frequencies
    of the pipe. For a certain tube, the smallest
    value of L for which a peak occurs in the sound
    intensity is 9.00 cm. What are
  • (a) the frequency of the tuning fork?
  • (b) the value of L for the next two resonance
    frequencies?

10
Homework
  • Ch. 18, Problems 14, 25, 42, 46.
  • Hints on 42
  • The change in volume ?V and the change in the
    height ?h of a cylinder are related by ?V
    (?r2) ?h or ?h ?V/(?r2).
  • Since the volume flow rate is R, i.e. ?V/?t R,
    the height flow rate is ?h/?t R/(?r2).
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