Interference Phenomena and Standing Waves in Musical Instruments
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CHAPTER 17
Interference
Constructive and Destructive Interference: BEATS
Standing Waves:
Transverse-Stringed Instruments
and
Longitudinal-Wind Instruments.
Diffraction
Speakers
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Musical instruments in the wind
family depend on
longitudinal
standing waves in producing sound.
Since wind instruments (trumpet,
flute, clarinet, pipe organ, etc.) are
modified tubes or columns of air, it
is useful to examine the standing
waves that can be set up in such
tubes.
Open tube of air
A pictorial representation of
longitudinal
standing waves
on a Slinky (left side) and in a tube of air (right side) that
is open at both ends (A, antinode; N, node).
Closed tube of air
A pictorial representation of the
longitudinal
standing waves
on a Slinky (left side) and in a tube of air (right side) that is
open only at one end (A, antinode; N, node).
17.7
Complex Sound Waves
The
sound
wave
corresponding to a
note produced by a musical
instrument or a singer is called a
complex sound wave.
It consists of a mixture of the
fundamental and harmonic
frequencies.
http://phet.colorado.edu/en/simulation/fourier
Spectrum Analyzer
A microphone detects a complex
sound
wave
, and a
spectrum analyzer determines the amplitude and
frequency
of each harmonic present in the wave.
P41: Sound
enters the ear, travels through the auditory canal,
and reaches the eardrum. The auditory canal is approximately a
tube open at only one end. The other end is closed by the
eardrum. A typical length for the auditory canal in an adult is
about 2.9 cm. The speed of sound is 343 m/s. What is the
fundamental
frequency
of the canal? (Interestingly, the
fundamental frequency is in the frequency range where human
hearing is most sensitive.)
The Sensitivity of the Human Ear
Explore the principle of linear superposition, constructive and destructive interference, beats, and standing waves in transverse and longitudinal instruments. Discover the complexity of sound waves and how spectrum analyzers analyze harmonic frequencies. Calculate the fundamental frequency in a human ear canal and delve into the sensitivity of the human ear. Visuals aid in understanding the concepts discussed.
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Presentation Transcript
CHAPTER 17 The Principle of Linear Superposition and Interference Phenomena Interference Constructive and Destructive Interference: BEATS Standing Waves: Transverse-Stringed Instruments and Longitudinal-Wind Instruments. Diffraction Speakers
17.6 Longitudinal Standing Waves Musical instruments in the wind family depend on longitudinal standing waves in producing sound. Since wind instruments (trumpet, flute, clarinet, pipe organ, etc.) are modified tubes or columns of air, it is useful to examine the standing waves that can be set up in such tubes.
Open tube of air A pictorial representation of longitudinal standing waves on a Slinky (left side) and in a tube of air (right side) that is open at both ends (A, antinode; N, node).
Closed tube of air A pictorial representation of the longitudinal standing waves on a Slinky (left side) and in a tube of air (right side) that is open only at one end (A, antinode; N, node).
17.7 Complex Sound Waves The sound wave corresponding to a note produced by a musical instrument or a singer is called a complex sound wave. It consists of a mixture of the fundamental and harmonic frequencies. http://phet.colorado.edu/en/simulation/fourier
Spectrum Analyzer A microphone detects a complex sound wave, and a spectrum analyzer determines the amplitude and frequency of each harmonic present in the wave.
P41: Sound enters the ear, travels through the auditory canal, and reaches the eardrum. The auditory canal is approximately a tube open at only one end. The other end is closed by the eardrum. A typical length for the auditory canal in an adult is about 2.9 cm. The speed of sound is 343 m/s. What is the fundamental frequency of the canal? (Interestingly, the fundamental frequency is in the frequency range where human hearing is most sensitive.) The Sensitivity of the Human Ear
