Template:Short description Musical acoustics or music acoustics is a multidisciplinary field that combines knowledge from physics,<ref>Template:Cite book</ref><ref>Template:Cite book</ref><ref>Template:Cite book</ref> psychophysics,<ref>Template:Cite book</ref> organology<ref>Template:Cite book</ref> (classification of the instruments), physiology,<ref>Template:Cite book</ref> music theory,<ref name=":0">Template:Cite book</ref> ethnomusicology,<ref>Template:Cite book</ref> signal processing and instrument building,<ref>Template:Cite book</ref> among other disciplines. As a branch of acoustics, it is concerned with researching and describing the physics of music – how sounds are employed to make music. Examples of areas of study are the function of musical instruments, the human voice (the physics of speech and singing), computer analysis of melody, and in the clinical use of music in music therapy.
The pioneer of music acoustics was Hermann von Helmholtz, a German polymath of the 19th century who was an influential physician, physicist, physiologist, musician, mathematician and philosopher. His book On the Sensations of Tone as a Physiological Basis for the Theory of Music<ref name=":0" /> is a revolutionary compendium of several studies and approaches that provided a complete new perspective to music theory, musical performance, music psychology and the physical behaviour of musical instruments.
Methods and fields of studyEdit
- The physics of musical instruments
- Frequency range of music
- Fourier analysis
- Computer analysis of musical structure
- Synthesis of musical sounds
- Music cognition, based on physics (also known as psychoacoustics)
Physical aspectsEdit
Whenever two different pitches are played at the same time, their sound waves interact with each other – the highs and lows in the air pressure reinforce each other to produce a different sound wave. Any repeating sound wave that is not a sine wave can be modeled by many different sine waves of the appropriate frequencies and amplitudes (a frequency spectrum). In humans the hearing apparatus (composed of the ears and brain) can usually isolate these tones and hear them distinctly. When two or more tones are played at once, a variation of air pressure at the ear "contains" the pitches of each, and the ear and/or brain isolate and decode them into distinct tones.
When the original sound sources are perfectly periodic, the note consists of several related sine waves (which mathematically add to each other) called the fundamental and the harmonics, partials, or overtones. The sounds have harmonic frequency spectra. The lowest frequency present is the fundamental, and is the frequency at which the entire wave vibrates. The overtones vibrate faster than the fundamental, but must vibrate at integer multiples of the fundamental frequency for the total wave to be exactly the same each cycle. Real instruments are close to periodic, but the frequencies of the overtones are slightly imperfect, so the shape of the wave changes slightly over time.Template:Citation needed
Subjective aspectsEdit
Variations in air pressure against the ear drum, and the subsequent physical and neurological processing and interpretation, give rise to the subjective experience called sound. Most sound that people recognize as musical is dominated by periodic or regular vibrations rather than non-periodic ones; that is, musical sounds typically have a definite pitch. The transmission of these variations through air is via a sound wave. In a very simple case, the sound of a sine wave, which is considered the most basic model of a sound waveform, causes the air pressure to increase and decrease in a regular fashion, and is heard as a very pure tone. Pure tones can be produced by tuning forks or whistling. The rate at which the air pressure oscillates is the frequency of the tone, which is measured in oscillations per second, called hertz. Frequency is the primary determinant of the perceived pitch. Frequency of musical instruments can change with altitude due to changes in air pressure.
Pitch ranges of musical instrumentsEdit
Template:Accessibility dispute <timeline> ImageSize = width:700 height:2000 PlotArea = left:0 right:0 top:0 bottom:20 AlignBars = justify Colors =
id:b value:rgb(0.85,0.85,0.85) # instruments id:f value:gray(0.8) # background bar
id:heading value:rgb(0,0.6,0.5) # class id:subhead value:rgb(0,0.7,0.5) # subclass id:2x-subhead value:rgb(0,0.8,0.5) # sub-subclass id:3x-subhead value:rgb(0,0.9,0) # sub-sub-subclass id:4x-subhead value:rgb(0,1,0.5) # families
id:paleGray value:rgb(0.86,0.86,0.86) # grids
BarData =
bar:pitch bar:Hz barset:ranges bar:pitch2 bar:Hz2
Period = from:0 till:651 ScaleMajor = increment:72 start:2 gridcolor:paleGray TimeAxis = orientation:horizontal
Define $cc2 = 2 Define $cc1 = 74 Define $cc = 146 Define $c = 218 Define $c1 = 290 Define $c2 = 362 Define $c3 = 434 Define $c4 = 506 Define $c5 = 578 Define $c6 = 650 Define $dd2 = 14 Define $dd1 = 86 Define $dd = 158 Define $d = 230 Define $d1 = 302 Define $d2 = 374 Define $d3 = 446 Define $d4 = 518 Define $d5 = 590 Define $ee2 = 26 Define $ee1 = 98 Define $ee = 170 Define $e = 242 Define $e1 = 314 Define $e2 = 386 Define $e3 = 458 Define $e4 = 530 Define $e5 = 602 Define $ff2 = 32 Define $ff1 = 104 Define $ff = 176 Define $f = 248 Define $f1 = 320 Define $f2 = 392 Define $f3 = 464 Define $f4 = 536 Define $f5 = 608 Define $gg2 = 44 Define $gg1 = 116 Define $gg = 188 Define $g = 260 Define $g1 = 332 Define $g2 = 404 Define $g3 = 476 Define $g4 = 548 Define $g5 = 620 Define $aa2 = 56 Define $aa1 = 128 Define $aa = 200 Define $a = 272 Define $a1 = 344 Define $a2 = 416 Define $a3 = 488 Define $a4 = 560 Define $a5 = 632 Define $hh2 = 68 Define $hh1 = 140 Define $hh = 212 Define $h = 284 Define $h1 = 356 Define $h2 = 428 Define $h3 = 500 Define $h4 = 572 Define $h5 = 644
Define $max = 650 PlotData=
align:center textcolor:black fontsize:10 mark:(line,black) width:10 shift:(0,-4) barset:ranges color:heading from:$ee till:$c3 text:human voice color:b from:$ee till:$e1 text:bass color:b from:$aa till:$a1 text:baritone color:b from:$c till:$c2 text:tenor color:b from:$f till:$f2 text:alto color:b from:$a till:$a2 text:mezzo-soprano color:b from:$c1 till:$c3 text:soprano
color:heading from:$cc2 till:$c5 text:chordophones color:3x-subhead from:$cc2 till:$a4 text:bowed color:4x-subhead from:$cc2 till:$a4 text:violin family color:b from:$cc2 till:$aa1 text:octobass color:b from:$cc1 till:$a2 text:double bass color:b from:$cc till:$a3 text:cello color:b from:$c till:$d4 text:viola color:b from:$g till:$a4 text:violin
color:3x-subhead from:$hh2 till:$f4 text:plucked color:b from:$hh2 till:$f4 text:harp color:b from:$ff1 till:$f3 text:harpsichord color:b from:$ee1 till:$g1 text:bass guitar color:b from:$hh1 till:$h2 text:baritone guitar color:b from:$ee till:$e3 text:guitar color:b from:$g till:$d4 text:mandolin color:b from:$d till:$a2 text:5-string banjo color:b from:$c1 till:$c3 text:ukulele
color:3x-subhead from:$aa2 till:$c5 text:zither color:b from:$aa2 till:$c5 text:piano color:b from:$d till:$d3 text:hammered dulcimer color:b from:$aa1 till:$a3 text:cymbalum
color:heading from:$cc2 till:$c6 text:aerophones color:subhead from:$cc2 till:$c6 text:woodwind instruments color:2x-subhead from:$hh2 till:$a3 text:double reed color:3x-subhead from:$hh2 till:$a3 text:exposed color:4x-subhead from:$hh2 till:$f2 text:bassoons color:b from:$hh2 till:$c1 text:contrabassoon color:b from:$hh1 till:$f2 text:bassoon
color:4x-subhead from:$aa till:$a3 text:oboes color:b from:$aa till:$g2 text:heckelphone color:b from:$e till:$c3 text:cor anglais color:b from:$g till:$f3 text:oboe d'amore color:b from:$h till:$a3 text:oboe
color:2x-subhead from:$dd2 till:$a4 text:single reed color:4x-subhead from:$dd2 till:$a4 text:clarinet family color:b from:$dd2 till:$h text:octocontrabass clarinet color:b from:$gg2 till:$e1 text:octocontra-alto clarinet color:b from:$dd1 till:$h1 text:contrabass clarinet color:b from:$gg1 till:$e2 text:contra-alto clarinet color:b from:$dd till:$h2 text:bass clarinet color:b from:$gg till:$e3 text:alto clarinet color:b from:$d till:$h3 text:soprano clarinet color:b from:$c1 till:$a4 text:sopranino clarinet
color:4x-subhead from:$aa2 till:$d4 text:saxophone family color:b from:$aa2 till:$e text:subcontrabass saxophone color:b from:$dd1 till:$a text:contrabass saxophone color:b from:$aa1 till:$e1 text:bass saxophone color:b from:$dd till:$a1 text:baritone saxophone color:b from:$aa till:$e2 text:tenor saxophone color:b from:$d till:$a2 text:alto saxophone color:b from:$a till:$e3 text:soprano saxophone color:b from:$d1 till:$a3 text:sopranino saxophone color:b from:$a1 till:$d4 text:sopranissimo saxophone
color:2x-subhead from:$cc till:$d4 text:free reed color:b from:$cc till:$c4 text:harmonium color:b from:$gg till:$a3 text:accordion color:b from:$c till:$d4 text:16-hole harmonica color:b from:$c1 till:$c4 text:typical C harmonica
color:2x-subhead from:$cc2 till:$c6 text:flutes color:3x-subhead from:$cc2 till:$c5 text:side blown color:4x-subhead from:$cc2 till:$c5 text:western concert flute family color:b from:$cc2 till:$c text:hyperbass flute color:b from:$cc1 till:$c1 text:double contrabass flute color:b from:$gg1 till:$g1 text:subcontrabass flute color:b from:$cc till:$c2 text:contrabass flute color:b from:$gg till:$g2 text:contra-alto flute color:b from:$c till:$c3 text:bass flute color:b from:$g till:$g3 text:alto flute color:b from:$c1 till:$c4 text:flute color:b from:$c2 till:$c5 text:piccolo
color:3x-subhead from:$cc2 till:$c6 text:internal duct (fipple) color:4x-subhead from:$ff1 till:$g5 text:recorders color:b from:$ff1 till:$c1 text:sub-contrabass recorder color:b from:$cc till:$g1 text:sub-great bass recorder color:b from:$ff till:$c2 text:contrabass recorder color:b from:$c till:$g2 text:great bass recorder color:b from:$f till:$c3 text:bass recorder color:b from:$c1 till:$g3 text:tenor recorder color:b from:$f1 till:$c4 text:alto recorder color:b from:$c2 till:$g4 text:soprano recorder color:b from:$f2 till:$c5 text:sopranino recorder color:b from:$c3 till:$g5 text:garklein recorder
color:b from:$cc2 till:$c6 text:organ*
color:subhead from:$cc2 till:$f4 text:brass instruments color:4x-subhead from:$cc2 till:$f2 text:tubas color:b from:$cc2 till:$f text:subcontrabass tuba* color:b from:$aa2 till:$f1 text:contrabass tuba color:b from:$dd1 till:$h1 text:bass tuba color:b from:$aa1 till:$f2 text:euphonium
color:4x-subhead from:$hh2 till:$f4 text:trombones color:b from:$hh2 till:$e1 text:contrabass trombone color:b from:$hh2 till:$c2 text:bass trombone color:b from:$ee1 till:$f2 text:tenor trombone color:b from:$aa till:$h2 text:alto trombone color:b from:$e till:$f3 text:soprano trombone color:b from:$a till:$h3 text:sopranino trombone color:b from:$e1 till:$f4 text:piccolo trombone color:b from:$ff1 till:$f1 text:cimbasso
color:4x-subhead from:$ff1 till:$f3 text:horns color:b from:$ff1 till:$f2 text:french horn color:b from:$ee till:$f2 text:baritone horn color:b from:$aa till:$h2 text:alto horn color:b from:$e till:$f3 text:flugelhorn color:b from:$hh1 till:$c2 text:bass wagner tuba color:b from:$ee till:$f2 text:tenor wagner tuba
color:4x-subhead from:$ee till:$f4 text:trumpets color:b from:$ee till:$f2 text:bass trumpet color:b from:$e till:$f3 text:cornet color:b from:$e till:$f3 text:trumpet color:b from:$e1 till:$f4 text:piccolo trumpet
color:heading from:$cc till:$d1 text:membranophones color:4x-subhead from:$cc till:$d1 text:timpani color:b from:$cc till:$aa text:32-inch color:b from:$ee till:$c text:29-inch color:b from:$aa till:$f text:26-inch color:b from:$d till:$h text:23-inch color:b from:$f till:$d1 text:20-inch
color:heading from:$cc till:$f5 text:idiophones color:4x-subhead from:$cc till:$c5 text:xylophones color:b from:$cc till:$c4 text:marimba color:b from:$c1 till:$c5 text:xylophone color:4x-subhead from:$c till:$f5 text:metallophones color:b from:$c till:$f5 text:celesta color:b from:$c till:$f3 text:vibraphone color:b from:$c2 till:$f5 text:glockenspiel color:b from:$c3 till:$f5 text:crotales color:4x-subhead from:$e till:$g2 text:tubes color:b from:$e till:$g2 text:tubular bells color:4x-subhead from:$cc till:$g2 text:vessels color:b from:$cc till:$g2 text:gong
color:f textcolor:blue align:left fontsize:S mark:(line,white) shift:(3,-4) bar:pitch fontsize:M from:0 till:$max at:$cc2 text:C₀ at:$cc1 text:C₁ at:$cc text:C₂ at:$c text:C₃ at:$c1 text:C₄ at:$c2 text:C₅ at:$c3 text:C₆ at:$c4 text:C₇ at:$c5 text:C₈
bar:Hz fontsize:S from:0 till:$max at:23 text:20 at:65 text:30 at:105 text:44 at:153 text:70 at:190 text:100 at:232 text:150 at:262 text:200 at:304 text:300 at:344 text:440 at:392 text:700 at:430 text:1000 at:472 text:1500 at:502 text:2000 at:544 text:3000 at:583 text:4400 Hz
bar:pitch2 fontsize:M # exact copy of bar:pitch from:0 till:$max at:$cc2 text:C₀ at:$cc1 text:C₁ at:$cc text:C₂ at:$c text:C₃ at:$c1 text:C₄ at:$c2 text:C₅ at:$c3 text:C₆ at:$c4 text:C₇ at:$c5 text:C₈
bar:Hz2 fontsize:S # exact copy of bar:Hz from:0 till:$max at:23 text:20 at:65 text:30 at:105 text:44 at:153 text:70 at:190 text:100 at:232 text:150 at:262 text:200 at:304 text:300 at:344 text:440 at:392 text:700 at:430 text:1000 at:472 text:1500 at:502 text:2000 at:544 text:3000 at:583 text:4400 Hz
</timeline>
*This chart only displays down to C0, though some pipe organs, such as the Boardwalk Hall Auditorium Organ, extend down to C−1 (one octave below C0). Also, the fundamental frequency of the subcontrabass tuba is BTemplate:Music−1.
Harmonics, partials, and overtonesEdit
The fundamental is the frequency at which the entire wave vibrates. Overtones are other sinusoidal components present at frequencies above the fundamental. All of the frequency components that make up the total waveform, including the fundamental and the overtones, are called partials. Together they form the harmonic series.
Overtones that are perfect integer multiples of the fundamental are called harmonics. When an overtone is near to being harmonic, but not exact, it is sometimes called a harmonic partial, although they are often referred to simply as harmonics. Sometimes overtones are created that are not anywhere near a harmonic, and are just called partials or inharmonic overtones.
The fundamental frequency is considered the first harmonic and the first partial. The numbering of the partials and harmonics is then usually the same; the second partial is the second harmonic, etc. But if there are inharmonic partials, the numbering no longer coincides. Overtones are numbered as they appear above the fundamental. So strictly speaking, the first overtone is the second partial (and usually the second harmonic). As this can result in confusion, only harmonics are usually referred to by their numbers, and overtones and partials are described by their relationships to those harmonics.
Harmonics and non-linearitiesEdit
When a periodic wave is composed of a fundamental and only odd harmonics (Template:Mvar, Template:Math, Template:Math, Template:Math, ...), the summed wave is half-wave symmetric; it can be inverted and phase shifted and be exactly the same. If the wave has any even harmonics (Template:Math, Template:Math, Template:Math, ...), it is asymmetrical; the top half of the plotted wave form does not mirror image the bottom.
Conversely, a system that changes the shape of the wave (beyond simple scaling or shifting) creates additional harmonics (harmonic distortion). This is called a non-linear system. If it affects the wave symmetrically, the harmonics produced are all odd. If it affects the harmonics asymmetrically, at least one even harmonic is produced (and probably also odd harmonics).
HarmonyEdit
{{#invoke:Labelled list hatnote|labelledList|Main article|Main articles|Main page|Main pages}}
If two notes are simultaneously played, with frequency ratios that are simple fractions (e.g. Template:Small, Template:Small, or Template:Small), the composite wave is still periodic, with a short period – and the combination sounds consonant. For instance, a note vibrating at 200 Hz and a note vibrating at 300 Hz (a perfect fifth, or Template:Nobr above 200 Hz) add together to make a wave that repeats at 100 Hz: Every Template:Small of a second, the 300 Hz wave repeats three times and the 200 Hz wave repeats twice. Note that the combined wave repeats at 100 Hz, even though there is no actual 100 Hz sinusoidal component contributed by an individual sound source.
Additionally, the two notes from acoustical instruments will have overtone partials that will include many that share the same frequency. For instance, a note with the frequency of its fundamental harmonic at 200 Hz can have harmonic overtones at: 400, 600, 800, Template:Gaps, Template:Gaps, Template:Gaps, Template:Gaps, Template:Gaps, ... Hz. A note with fundamental frequency of 300 Hz can have overtones at: 600, 900, Template:Gaps, Template:Gaps, Template:Gaps, ... Hz. The two notes share harmonics at 600, Template:Gaps, Template:Nobr and more that coincide with each other, further along in the each series.
Although the mechanism of human hearing that accomplishes it is still incompletely understood, practical musical observations for nearly Template:Nobr<ref>Template:Cite book</ref> The combination of composite waves with short fundamental frequencies and shared or closely related partials is what causes the sensation of harmony: When two frequencies are near to a simple fraction, but not exact, the composite wave cycles slowly enough to hear the cancellation of the waves as a steady pulsing instead of a tone. This is called beating, and is considered unpleasant, or dissonant.
The frequency of beating is calculated as the difference between the frequencies of the two notes. When two notes are close in pitch they beat slowly enough that a human can measure the frequency difference by ear, with a stopwatch; beat timing is how tuning pianos, harps, and harpsichords to complicated temperaments was managed before affordable tuning meters.
- For the example above, Template:Nobr
- As another example from modulation theory, a combination of Template:Nobr and Template:Nobr would beat once per second, since Template:Nobr
The difference between consonance and dissonance is not clearly defined, but the higher the beat frequency, the more likely the interval is dissonant. Helmholtz proposed that maximum dissonance would arise between two pure tones when the beat rate is roughly 35 Hz.<ref>{{#invoke:citation/CS1|citation |CitationClass=web }}</ref>
ScalesEdit
{{#invoke:Labelled list hatnote|labelledList|Main article|Main articles|Main page|Main pages}}
The material of a musical composition is usually taken from a collection of pitches known as a scale. Because most people cannot adequately determine absolute frequencies, the identity of a scale lies in the ratios of frequencies between its tones (known as intervals).
{{#invoke:Labelled list hatnote|labelledList|Main article|Main articles|Main page|Main pages}}
The diatonic scale appears in writing throughout history, consisting of seven tones in each octave. In just intonation the diatonic scale may be easily constructed using the three simplest intervals within the octave, the perfect fifth (3/2), perfect fourth (4/3), and the major third (5/4). As forms of the fifth and third are naturally present in the overtone series of harmonic resonators, this is a very simple process.
The following table shows the ratios between the frequencies of all the notes of the just major scale and the fixed frequency of the first note of the scale.
| C | D | E | F | G | A | B | C |
|---|---|---|---|---|---|---|---|
| 1 | 9/8 | 5/4 | 4/3 | 3/2 | 5/3 | 15/8 | 2 |
There are other scales available through just intonation, for example the minor scale. Scales that do not adhere to just intonation, and instead have their intervals adjusted to meet other needs are called temperaments, of which equal temperament is the most used. Temperaments, though they obscure the acoustical purity of just intervals, often have desirable properties, such as a closed circle of fifths.
See alsoEdit
- Acoustic resonance
- Cymatics
- Mathematics of musical scales
- String resonance
- Vibrating string
- 3rd bridge (harmonic resonance based on equal string divisions)
- Basic physics of the violin
ReferencesEdit
<references />
External linksEdit
- Music acoustics - sound files, animations and illustrations - University of New South Wales
- Acoustics collection - descriptions, photos, and video clips of the apparatus for research in musical acoustics by Prof. Dayton Miller
- The Technical Committee on Musical Acoustics (TCMU) of the Acoustical Society of America (ASA)
- The Musical Acoustics Research Library (MARL)
- Acoustics Group/Acoustics and Music Technology courses - University of Edinburgh
- Acoustics Research Group - Open University
- The music acoustics group at Speech, Music and Hearing KTH
- The physics of harpsichord sound
- Visual music
- Savart Journal - The open access online journal of science and technology of stringed musical instruments
- Interference and Consonance from Physclips
- Curso de Acústica Musical (Spanish)