The sound is a longitudinal, mechanical wave.
Sound can travel through any medium, but it cannot travel through a vacuum. There is no sound in outer space.
The sound is a variation in pressure. A region of increased pressure on a sound wave is called a compression (or condensation). A region of decreased pressure on a sound wave is called a rarefaction (or dilation).
The sources of sound
- vibrating solids
- rapid expansion or compression (explosions and implositons)
- Smooth (laminar) airflow around blunt obstacles may result in the formation of vorticies (the plural of vortex) that snap off or shed with a characteristic frequency. This process is called vortex shedding and is another means by which sound waves are formed. This is how a whistle or flute produces sound. Also the aeolian harp effect of singing power lines and fluttering Venetian blinds.
What are the different characteristics of a wave? What are the things that can be measured by waves? Amplitude, frequency (and period), wavelength, speed, and maybe phase. Deal with each one in that order.
amplitude, intensity, loudness, volume
Amplitude goes with intensity, loudness, or volume. That’s the basic idea. The details go in a separate section.
- Unlike our ears and hydrophones, fish ears don’t detect sound pressure, which is the compression of molecules. Instead, they perceive something called particle motion, the tiny back-and-forth movements of particles in response to sound waves.
the speed of sound
The speed of sound depends upon the type of medium and its state. It is generally affected by two things: elasticity and inertia. This is the Newton-Laplace equation. Laplace added the γ (gamma) correction factor for ideal gases.
|v = √||E|
|E =||Young’s modulus|
|v = √||K|
|K =||bulk modulus|
|v = √||K||= √||γP||= √||γRT||= √||γkT|
|K =||bulk modulus|
|γ =||cP/cV (specific heat ratio)|
|P =||absolute pressure|
|T =||absolute temperature|
|R =||gas constant|
|M =||molar mass|
|k =||boltzmann’s constant|
|m =||molecular mass|
Acoustic Thermometry of Ocean Climates (ATOC)
- in water, sounds below 1 kHz travel much farther than higher frequencies
- “shipping noise is loudest in the 30 to 200 Hz range [lowest piano note to middle of cello]”
- “blue and fin wales are the loudest sound in the 17 to 30 Hz range”
- “In pre-industrial times, the low frequency range of 15 to 300 Hz in which most of the baleen whales sing was the quietest part of the sound spectrum, nestled between the subsonic ramblings of earthquakes and the higher pitched rattle of wind, waves and rain.” Bob Holmes. “Noises Off.” New Scientist. 1 March 1997: 30–33.
- As with any wave the speed of sound depends on the medium in which it is propagating.
- Sound generally travels faster in solids and liquids than in gases.
- The speed of sound is faster in materials that have some stiffness like steel and slower in softer materials like rubber.
- Factors Which Affect the Speed of Sound in Air.
- The speed of sound in air is approximately 330 m/s (about 1,200 kph or 700 mph).
- The speed of sound in air is nearly the same for all frequencies and amplitudes.
- It increases with temperature.
- Determining the Distance to a Lightning Bolt: Sound waves take approximately 5 seconds to travel 1 mile. Using this information, it is possible to measure one’s distance from a lightning bolt. Begin counting immediately after you see the flash. Every five seconds counted is roughly equivalent to one mile of distance.
|solids||v (m/s)||liquids||v (m/s)|
|cork||500||gases (STP)||v (m/s)|
|glass, crown||5100||air, 000 ℃||331|
|glass, flint||3980||air, 020 ℃||343|
|rubber, butyl||1830||oxygen (O2)||316|
|rubber, vulcanized||54||water vapor, 134 ℃||494|
|silver||3650||biological materials||v (m/s)|
|steel, mild||5960||soft tissues||1540|
frequency, pitch, tone
The frequency of a sound wave is called it pitch. High-frequency sounds are said to be “high pitched” or just “high”; low-frequency sounds are said to be “low pitched” or just “low”.
|f (THz)||device, event, phenomena, process|
|0.1–2||SASER (sound laser)|
|f (MHz)||device, event, phenomena, process|
|f (kHz)||device, event, phenomena, process|
|25–80||bat sonar clicks|
|32.768||quartz timing crystal|
|18–20||upper limit of human hearing|
|4–5||field cricket (Teleogryllus oceanicus)|
|2–5||maximum sensitivity of the human hear|
|f (Hz)||device, event, phenomena, process|
|300–3000||voice frequency (VF), important for understanding speech|
|2048||C7 scientific scale, highest note of a soprano singer (approximate)|
|440||A4 American standard pitch, tv test pattern tone|
|435||A4 international pitch|
|426.67||A4 scientific scale|
|261.63||C4 American standard pitch|
|258.65||C4 international pitch|
|256||C4 scientific scale, a typical fundamental frequency for female vocal cords|
|128||C3 scientific scale, typical fundamental frequency for male vocal cords|
|64||C2 scientific scale, lowest note of a bass singer (approximate)|
|90||ruby-throated hummingbird in flight|
|60||alternating current hum (US and Japan)|
|50||alternating current hum (Europe)|
|8–20||lower limit of human hearing|
|17–30||blue and fin wales are the loudest marine sounds in this range|
human hearing and speech
Humans are generally capable of hearing sounds between 20 Hz and 20 kHz (although I can’t hear sounds above 13 kHz). Sounds with frequencies above the range of human hearing are called ultrasound. Sounds with frequencies below the range of human hearing are called infrasound.
- Typical sounds produced by human speech have freqeuncies on the order of 100 to 1,000 Hz.
- The peak sensitivity of human hearing is around 4000 Hz.
- locating the source of sound
- Interaural Time Difference (ITD)
- Interaural Phase Difference (IPD) Phase differences are one way we localize sounds. Only effective for wavelengths greater than 2 head diameters (ear-to-ear distances).
- Interaural Level Difference (ILD) Sound waves diffract easily at wavelengths larger than the diameter of the human head (around 500 Hz wavelength equals 69 cm). At higher frequencies, the head casts a “shadow”. Sounds in one ear will be louder than the other.
- The human ear can distinguish some…
- 1400 different pitches
- three (four?) vocal registers
- (whistle register?)
- modal — the usual speaking register
- vocal fry — the lowest of the three vocal registers
More in the next section.
- avalanches: location, depth, duration
- meteors: altitude, direction, type, size, location
- ocean waves: storms at sea, magnitude, spectra
- severe weather: location, intensity
- tornadoes: detection, location, warning, core radius, funnel shape, precursors
- turbulence: aircraft avoidance, altitude, strength, extent
- earthquakes: precursors, seismic-acoustic coupling
- volcanoes: location, intensity
- Elephants, whales, hippos, rhinoceros, giraffe, okapi, and alligator are just a few examples of animals that create infrasound.
- Some migratory birds are able to hear the infrasonic sounds produced when ocean waves break. This allows them to orient themselves with coastlines.
- An elephant is capable of hearing sound waves well below our the human hearing limitation (approximately 30 Hertz). Typically, an elephant’s numerous different rumbles will span between 14 and 35 Hertz. The far reaching use of high-pressure infrasound opens the elephant’s spatial experience far beyond our limited capabilities.
- Silent Thunder, Katy Payne
- animal echolocation
- microchiropterans a.k.a. microbats: carnivorous bats (not fruit bats or flying foxes)
- cetaceans: dolphins, porpoises, orcas, whales
- two bird species: swiftlets and oilbirds
- some visually impaired humans have learned this technique
- sonar (an acronym for sound navigation and ranging) including
- echo sounding
- fish finders
- medical ultrasonography (the images generated are called sonograms).
|imaging, echo||1||–||20||0.05||1.75||0.2||–||1 μs|
|imaging, doppler||1||–||20||0.15||15.7||0.3||–||10 μs|
|surgery||0.5||–||10||~ 200||1,500||1||–||16 s|
|fish||–||actinopterygii||frequency range (Hz)|
|american shad||–||Alosa sapidissima||200||–||180,000m|
|atlantic cod||–||Gadus morhua||2||–||500m|
|amphibians||–||amphibia||frequency range (Hz)|
|tree frog||–||… …||50||–||4,0001|
|cave salamander||–||Proteus anguinus||10||–||10,000i|
|reptiles||–||reptilia, sauropsida||frequency range (Hz)|
|red-eared slider||–||Trachemys scripta elegans||68||–||8402|
|spectacled caiman||–||Caiman crocodilus||20||–||6,000a|
|birds||–||aves||frequency range (Hz)|
|mallard duck||–||Anus platyrhynchus||300||–||8,000b|
|mammals||–||mammalia||frequency range (Hz)|
|pig||–||Sus scrofa domestica||45||–||45,0002|
|dog||–||Canis lupus familiaris||67||–||45,0001,2|
|cat||–||Felis silvestris catus||45||–||64,0001,4|
|ferret||–||Mustela putorius furo||16||–||44,0001|
|blue whale||–||Balaenoptera musculus||5||–||12,000d|
|humpback whale||–||Megaptera novaeangliae||30||–||28,0004|
|risso’s dolphin||–||Grampus griseus||8,000||–||100,000j|
|beluga whale||–||Delphinapterus leucas||1,000||–||123,0001|
|atlantic bottlenose dolphin||–||Tursiops truncatus||75||–||150,0001,4|
|greater horseshoe bat||–||Rhinolophus ferrumequinum||2,000||–||110,0001,4|
|jamaican fruit bat||–||Artibeus jamaicensis||2,800||–||131,000e|
|northern quoll||–||Dasyurus hallucatus||500||–||40,000f|
|japanese macaque||–||Macaca fuscata||28||–||34,5002|
|old world monkeys||–||… …||60||–||40,000g|
|asian elephant||–||Elephas maximus||16||–||12,0001|
|guinea pig||–||Cavia porcellus||54||–||50,0001,2|
|manatee||–||Trichechus manatus latirostris||400||–||46,000h|
|insects||–||insecta||frequency range (Hz)|
|noctuid moth||–||… …||1,000||–||240,0003|