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Waves and SoundWaves and Sound
Honors Physics Honors Physics
Chapter 14Chapter 14
Definition of a waveDefinition of a wave
A disturbance that propagates A disturbance that propagates from 1 place to another. from 1 place to another.
Characterized by a large transfer Characterized by a large transfer of energy without a large transfer of energy without a large transfer of medium of medium
Types of wavesTypes of waves
Mechanical waves:Mechanical waves: require a require a medium (air, water, ropes) to travelmedium (air, water, ropes) to travel
Electromagnetic waves:Electromagnetic waves: do not do not require a medium to travel (light, require a medium to travel (light, radio) radio)
Matter waves:Matter waves: produced by produced by electrons and particles electrons and particles
Mechanical WavesMechanical Waves
Transverse:Transverse: the displacement of the the displacement of the individual particles is perpendicular to individual particles is perpendicular to the direction of propagation.the direction of propagation.
Mechanical WavesMechanical Waves
Longitudinal:Longitudinal: The displacement of The displacement of the individual particles is parallel to the individual particles is parallel to the direction of propagation.the direction of propagation.
Mechanical WavesMechanical WavesSurface waves:Surface waves: the displacement the displacement
of individual particles is circular of individual particles is circular (result of both transverse and (result of both transverse and longitudinal motion)longitudinal motion)
Waves in motionWaves in motion
Longitudinal and Transverse Wave Motion
Properties of wavesProperties of waves1.1. AmplitudeAmplitude (A): the maximum displacement (A): the maximum displacement
from equilibrium position, measured in meters.from equilibrium position, measured in meters.2.2. WavelengthWavelength ( λ): the distance between 2 ( λ): the distance between 2
particles that are in phase with each other, particles that are in phase with each other, measured in meters. measured in meters.
Wave diagramWave diagram
Properties of wavesProperties of waves
3.3. Frequency (f): number of (f): number of complete waves that pass a complete waves that pass a point in one second, measured point in one second, measured in 1/seconds or Hertz (Hz) in 1/seconds or Hertz (Hz)
4.4. PeriodPeriod (T): the time it takes for (T): the time it takes for one complete wave to pass a one complete wave to pass a given point, measured in given point, measured in seconds. seconds.
Properties of wavesProperties of waves
Velocity of propagationVelocity of propagation (v): (v): horizontal speed of a point on horizontal speed of a point on a wave as it propagates, a wave as it propagates, measured in m/s.measured in m/s.
Relationships/equationsRelationships/equations
T =1/ fT =1/ f
or f = 1/Tor f = 1/Tv = f × λv = f × λ
PhasePhase
In-phase: when waves In-phase: when waves are synchronized (crest are synchronized (crest meets crest)meets crest)
Out-of-phase: waves are Out-of-phase: waves are not synchronized not synchronized Opposite phase (180Opposite phase (180º º
out-of-phase): crest out-of-phase): crest meets troughmeets trough
ReflectionsReflections Fixed End: Fixed End:
Explanation Animation
Open End:Open End: Explanation Animation
Between different mediums scroll down scroll down
(What do you notice about the (What do you notice about the phases? Transmitted? Reflected?)phases? Transmitted? Reflected?)
Principle of SuperpositionPrinciple of SuperpositionOccurs when two waves travel Occurs when two waves travel
through the same medium at the through the same medium at the same time.same time.
Each wave affects the medium Each wave affects the medium independently.independently.
The displacement of the medium is The displacement of the medium is the algebraic sum of the the algebraic sum of the displacements.displacements.
Animation (scroll down)(scroll down)
InterferenceInterference
Constructive:Constructive: occurs when wave occurs when wave displacements are in the same displacements are in the same direction (in-phase)direction (in-phase)
Destructive:Destructive: occurs when wave occurs when wave displacement are in different displacement are in different directions (out-of-phase)directions (out-of-phase)
animation
What is Sound?What is Sound? Longitudinal Longitudinal MechanicalMechanical Rarefaction: low Rarefaction: low
air pressureair pressure Compression: Compression:
high air high air pressurepressure
module
Speed of soundSpeed of sound
Depends on…Depends on… TemperatureTemperature
• V air = 331m/s +(0.6 m/s/V air = 331m/s +(0.6 m/s/ºC)*T ºC)*T Density/kind of mediumDensity/kind of medium
• Gases <liquids<solidsGases <liquids<solids
• Chart of speeds
Speed of soundSpeed of sound
PitchPitchHow we perceive variations in How we perceive variations in
frequencyfrequencyAudible range 20-20,000 Hz Audible range 20-20,000 Hz ((listen))
Most sensitive to 1,000 to 5,000HzMost sensitive to 1,000 to 5,000HzLoudness can distort our perception of Loudness can distort our perception of
pitch pitch (listen tape)(listen tape)
module
Doppler EffectDoppler EffectVariation in the frequency of Variation in the frequency of
sound due to the relative sound due to the relative motion of the sound source or motion of the sound source or the listener.the listener.
Animation1Picture of a sonic boomVideo of sonic boomSpace shuttle breaking sound barri
er and and mythbuster
Doppler Effect ResultsDoppler Effect Results
As an moving sound source approaches As an moving sound source approaches a listener the frequency (pitch) increase.a listener the frequency (pitch) increase.
As a moving sound source passes by a As a moving sound source passes by a listener the frequency (pitch) decreases.listener the frequency (pitch) decreases. *Same effect if sound source is stationary *Same effect if sound source is stationary
and listener is moving.and listener is moving.
Calculating Frequency changeCalculating Frequency change
f’ = f (v ± vf’ = f (v ± vRR / v± v / v± vss))f’ = new frequencyf’ = new frequency
• f = original frequency of f = original frequency of source soundsource sound
•v: velocity of soundv: velocity of sound
•vvRR: velocity of receiver: velocity of receiver
•vvss: velocity of source: velocity of source
Loudness Loudness
How we perceive variations in How we perceive variations in amplitude and intensity.amplitude and intensity.Module
In general, sound waves of In general, sound waves of higher intensity sound louder higher intensity sound louder but we are not equally but we are not equally sensitive to all frequencies.sensitive to all frequencies.
Sound IntensitySound Intensity The amount of energy that passes The amount of energy that passes
through a given area in a given time.through a given area in a given time. I=I=P/AP/A
• P=power (watts)P=power (watts)• A = area (mA = area (m22))•I = I = intensity (W / mintensity (W / m22))
Directly proportional to the square of Directly proportional to the square of the amplitude.the amplitude.
Inversely proportional to the square of Inversely proportional to the square of the distance from the source.the distance from the source.
Relative IntensityRelative Intensity
Logarithmic scale used to indicate Logarithmic scale used to indicate the intensity level of a sound.the intensity level of a sound.
Measured in decibels or dBMeasured in decibels or dBββ= 10 log (= 10 log (I / II / Ioo))
IIo o =1×10=1×10-12-12 W/m W/m22 (intensity of the (intensity of the
faintest sound that can be heard)faintest sound that can be heard) I = I = intensity of sound in W/mintensity of sound in W/m22
How loud is a decibel?How loud is a decibel? Threshold of hearing( Threshold of hearing( IIoo )= 0dB (air )= 0dB (air
pressure 2×10pressure 2×10-5 -5 Pa)Pa) Threshold of pain = 120 dB (air Threshold of pain = 120 dB (air
pressure = 20 Pa)pressure = 20 Pa) We perceive a 10 dB increase as twice We perceive a 10 dB increase as twice
as loud.as loud. Every 20 decibels air pressure Every 20 decibels air pressure
increases 10 timesincreases 10 timesTable of sound levels
ResonanceResonanceCausing the vibration of an object by the Causing the vibration of an object by the
influence of another vibrating body.influence of another vibrating body. Must match the natural frequency of Must match the natural frequency of
vibration of the object vibration of the object Whole-number multiple of the natural Whole-number multiple of the natural
frequency work too.frequency work too. DEMO DEMO (wood blocks) (wood blocks) Breaking a glass with resonance
Standing wavesStanding wavesCaused by the interference of reflected Caused by the interference of reflected
waves with incident waves from the waves with incident waves from the source.source.
Nodes:Nodes: pts of no displacement pts of no displacementAntinodesAntinodes: pts of maximum : pts of maximum
displacementdisplacementAnimationAnimationappletapplet
Vibrating Columns of AirVibrating Columns of AirColumn will emit a sound when the air Column will emit a sound when the air
inside achieves resonance.inside achieves resonance. DEMO DEMO (cardboard moose call)(cardboard moose call)
Frequency of vibration depend onFrequency of vibration depend onLength of columnLength of columnType of columnType of column
• Open endOpen end• Closed endClosed end
Fundamentals and HarmonicsFundamentals and Harmonics
Fundamental Frequency:Fundamental Frequency: lowest lowest frequency of vibrationfrequency of vibration
Harmonics:Harmonics: whole number whole number multiples of the fundamentalmultiples of the fundamental Note: the fundamental frequency is Note: the fundamental frequency is
the 1the 1stst harmonic. harmonic.Animation Animation
Closed (at one end) pipeClosed (at one end) pipe
The standing wave created hasThe standing wave created hasNode at closed-endNode at closed-endAntinode at open-endAntinode at open-end
NN AA
Calculations for closed pipeCalculations for closed pipeFundamental frequency Fundamental frequency
ff11= v /4L (L=length of air column)= v /4L (L=length of air column)
HarmonicsHarmonics ffnn = nf = nf11 (n=1,3,5,…) (n=1,3,5,…) λλ =4L/n =4L/n
Note: only ODD harmonics are producedNote: only ODD harmonics are producedAnimationAnimation
Open pipeOpen pipe
The standing wave created hasThe standing wave created has Antinode at both endsAntinode at both ends
AAAA
Calculations for open pipeCalculations for open pipeFundamental frequency Fundamental frequency
ff11= v /2L (L=length of air column)= v /2L (L=length of air column)
HarmonicsHarmonics ffnn = nf = nf11 (n=1,2,3,…) (n=1,2,3,…)λλ =2L/n =2L/n
Note: ALL harmonics are producedNote: ALL harmonics are producedanimationanimation
FrequencyFrequency
LightLight Sound (listen)Sound (listen)
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