Download - Properties of Sound - UMD
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Properties of Sound
• What is sound? • Wavelength, period, frequency • Interference and the linearity of sound • Sound attenuation
– Spreading loss – Acoustic impedance – Scattering
• Reading in Chap 2 – box 2.3 but not 2.1 or 2.2
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How does a cicada sing?
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Sound is a pressure wave
• Period (τ) = the time between successive waveform peaks
• Frequency (in cycles/sec or Hertz) = 1/period, • Thus f = 1/τ
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Wavelength depends on speed of sound
• Wavelength of a sound is the distance traveled in one cycle (or period)
• Wavelength = period • speed of sound in medium ( c )
• Thus wavelength = c / frequency
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Acoustical property comparisons
Property Air Water Rock
Speed (m/s) 340 1500 2000-5000
Density (g/cm3) 0.001 1 2-3
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Wavelength problem
Which sound has a shorter wavelength: 1 kHz in air or 3 kHz in water?
Wavelength = speed of sound / frequency Air: 340 m/s / 1000 cycle/s = 0.34 m/cycle Water: 1500 m/s / 3000 cycle/s = 0.5 m/cycle Therefore, the answer is 1 kHz in air
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Frequencies and wavelengths in air
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Pressure vs particle movements
Close to a sound source, pressure and particle displacement are out of phase, but one wavelength from source they are in phase
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Near field vs far field • Near field
– molecular displacements > pressure differences
– About 1-2 wavelengths from source
• Far field – pressure displacement >
molecular displacements – travels as a wave away
from source
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The Doppler shift
• When the sound source is moving, the frequency of the sound will be altered. This is known as the Doppler shift
• Approaching sounds are higher in frequency • Receding sounds are lower in frequency • See demonstration at
– http://www.walter-fendt.de/ph14e/dopplereff.htm
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Sound linearity and interference
• Sound pressure waves combine additively • Waves that start together are in phase
– Sounds in phase increase in amplitude (positive interference)
– Sounds out of phase cancel each other out (negative interference)
– Sounds partially out of phase create varying amplitudes (beats)
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Positive interference
Summed Waveform
+
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Negative Interference
Summed Waveform
+
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Interference produces Beats
Summed Waveform
+
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Amplitude measures Peak Peak-to-peak Root-mean-squared (RMS)
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Amplitude scale • Sound pressure is measured in decibels (dB) on a
log10 scale relative to a reference level • dB = 20 log10 P1/Pr where Pr is a reference
pressure level • A common reference pressure level is the
threshold of human hearing at 1 kHz, referred to as sound pressure level (SPL)
• A sound with twice the SPL is 6 dB louder – i.e. 20 log10 (2) = 20(0.3) = 6
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Sample sound pressure levels
• soft whisper 20 dB • nearby songbird, office hum 50 dB • barking dog 70 dB • roaring lion , heavy truck 90 dB • echolocating big brown bat 100 dB • jet take-off 120 dB
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Amplitude problems • If sound A has 10 times the SPL of sound B,
how much louder in dB is A than B? dB = 20 log10 10 = 20 dB louder • If sound A is 100 db and sound B is 80 db, how
much louder is A than B? 20 db • If an 80 db sound is combined with a 40 db
sound, how loud is the sound (approximately)? 80 db
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Sound attenuation
• Spherical spreading
• Absorption
– Temperature and humidity effects
• Reflective scattering – Due to impedance differences
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Spherical spreading
• Loss in sound intensity follows the inverse square law – pressure drops in half for each doubling of
distance, i.e. for each doubling of distance sound is 6 dB less
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Atmospheric attenuation Nonlinear with humidity Increases with
square of frequency
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Acoustic impedance • The degree to which a medium is
compressible by sound pressure • Acoustic impedance = speed of sound •
density of medium • Transmission between media with different
impedances is difficult – Sounds reflect off animals in air, but can pass
through them in water • Dictates efficiency of sound production and
reception by organisms
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Acoustical property comparisons Property Air Water Rock
Speed (m/s) 340 1500 2000-5000
Density (g/cm3) 0.001 1 2-3
Impedance(rayls) 30 1.5 x 105 4-5 x 105
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Reflection and refraction
• If medium 2 is more dense than medium 1 – Most of the energy in a sound wave will be reflected from the boundary between media – If the incidence angle exceeds a threshold (see book), some energy will be refracted into
media 2, with a reduced angle
• Reflection depends on size of media 2 object
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Reflective Scattering
• Type of scattering depends on ratio of wavelength and reflecting object – Rayleigh scattering (object << wavelength)
• sound scattered equally in all directions
– Diffractive or Mie scattering (object = wavelength) • both a reflected and diffracted wave
– Simple scattering (object > wavelength) • single reflected wave
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Scattering and wavelengths
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Diffractive scattering
• Part of sound wave is diffracted around object (creeping wave)
• Reflected wave is out of phase with creeping wave.
• Can cause negative interference