Sound Chapter 15

Topics for Sound Sound wave propertiesSound wave properties Speed of soundSpeed of sound EchoesEchoes BeatsBeats Doppler shiftDoppler shift ResonanceResonance Anatomy of EarAnatomy of Ear

Sound Wave Properties

Sound Waves are Longitudinal Waves The air molecules shown below are either compressed together, or spread apart. This creates alternating high and low pressure.

Frequency The frequency of a sound wave (or any wave) is the number of complete vibrations per second. The frequency of sound determines its pitch. Human Hearing ranges from …. 20Hz to 20KHz

The higher the frequency, the higher the pitch

Wavelength Wavelength is the distance between two high pressures, or two low pressures. This property is dependent on the velocity of the sound and it’s frequency.

The Amplitude of a Sound Wave Determines its loudness or softness

Velocity of Sound

The velocity of sound depends on The medium it travels throughThe medium it travels through In air at room temperature sound travels at 343m/s (~766 mph)In air at room temperature sound travels at 343m/s (~766 mph) v = 331 m/s + (0.6)Tv = 331 m/s + (0.6)T –v: velocity of sound in air –T: temperature of air in o C

Relationship between velocity, frequency, and wavelength V = fV = f V = velocity of soundV = velocity of sound = wavelength of sound = wavelength of sound f = frequency of soundf = frequency of sound

Sound travels faster in liquids than in airSound travels faster in liquids than in air Sound travels faster in solids than in liquidsSound travels faster in solids than in liquids Sound does not travel through a vacuumSound does not travel through a vacuum –there is no air in a vacuum so sound has no medium to travel through

Echoes: REFLECTION

Echoes are the result of the reflection of sound Sound waves leave a source, travel a distance, and bounce back to the origin.

Things that use echoes... Bats Dolphins/ Whales Submarines Ultra sound Sonar

REFRACTION OF WAVES

Refraction of Sound as the sound wave propagate into the warmer air at lower levels, they change direction, much like light passing through a prism

DIFFRACTION: THE BENDING OF WAVES THROUGH A SMALL OPENING

BENDING OF A WAVE

Beats

A beat occurs when sound waves of two different (but very much alike) frequencies are played next to each other. The result is constructive and destructive interference at regular intervals.

Sound waves move out like this:

But when they move, the front of the wave gets bunched up (smaller wavelength) and the back of the wave starts to expand (larger wavelength):

C B A Observer C hears a high pitch (high frequency) Observer B hears the correct pitch (no change in frequency) Observer A hears a low pitch (lower frequency)

Police use the Doppler Shift when measuring your speed with radar A frequency is sent out of the radar gun The sound wave hits the speeding car The frequency is changed by the car moving away from the radar and bouncing back The amount the frequency changes determines how fast you are going The faster you are going, the more the frequency is changed.

When the source goes faster, the wave fronts in the front of the source start to bunch up closer and closer together, until...

The object actually starts to go faster than the speed of sound. A sonic boom is then created.

Resonance

Resonance happens with closed pipe resonators and open pipe resonators Resonance occurs when there is a standing wave in the tube Closed pipe resonators –open end of tube is anti-node –closed end of tube is node Open pipe resonators –both ends are open –both ends are anti-nodes

Closed pipe resonator

Open pipe resonator

Anatomy of the Ear

Pinna Sound starts at the Pinna

auditory canal Then goes through the auditory canal

Tympanic Membrane The sound waves will then vibrate the Tympanic Membrane which is made of a thin layer of skin.

Malleus IncusStapes The tympanic membrane will then vibrate three tiny bones : the Malleus, the Incus, and the Stapes

Cochlea The stapes will then vibrate the Cochlea

Inside look of the Cochlea The stapes vibrates the cochleaThe stapes vibrates the cochlea The frequency of the vibrations will stimulate particular hairs inside the cochleaThe frequency of the vibrations will stimulate particular hairs inside the cochlea The intensity at which these little hairs are vibrated will determine how loud the sound is.The intensity at which these little hairs are vibrated will determine how loud the sound is. The auditory nerve will then send this signal to the brain.The auditory nerve will then send this signal to the brain. 

SOUND INTENSITY: THE LOUDNESS OF SOUND

DECIBEL MEASURES THE LOUDNESS OF SOUND RELATES TO THE AMPLITUDE OF THE WAVE EVERY INCREASE OF 20dB HAS 10x GREATER AMPLITUDE

150dBJET TAKING OFF 115dB CHAIN SAW 100dBPOWER MOWER 80dB NOISY RESTAURANT 75dB VACUUM CLEANER 50dBAVERAGE HOME 25dBPURRING CAT 20dB RUSTLING LEAVES 15dB WHISPER 0dB FAINTEST THAT CAN BE HEARD

A SOUND 10 TIMES AS INTENSE IS PERCEIVED AS BEING ONLY TWICE AS LOUD

NOISE POLLUTION · Prolonged exposure to noise greater than dBA (decibels measured on the A- scale) may cause hearing loss · Brief exposures to noise sources of dBA can cause hearing loss · A single exposure to a level of 140 dBA or higher can cause hearing loss

Hours Per Day Noise Level (dBA) *100* EXPOSURE TO LOUD NOISE --that results in hearing loss