Equal temperament

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An equal temperament is a musical temperament, or system of tuning, in which an interval, usually the octave, is divided into a series of equal steps (equal frequency ratios). For modern Western music, the most common tuning system is twelve-tone equal temperament, sometimes abbreviated as 12-TET, which divides the octave into 12 equal parts. This system is usually tuned relative to a standard pitch of 440Hz.

Other equal temperaments do exist (some music has been written in 19-TET and 31-TET for example, and Arabian music is based on a twenty four tone equal temperament), but in the Western world when people use the term equal temperament without qualification, it is usually understood that they are talking about 12-TET.

Equal temperaments may also divide some interval other than the octave, a pseudo-octave, into a whole number of equal steps. An example is an equally-tempered Bohlen-Pierce scale. To avoid ambiguity, the term Equal Division of the Octave, or EDO is sometimes preferred. According to this naming system, 12-TET is called 12-EDO, 31-TET is called 31-EDO, and so on.

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[edit] History

Vincenzo Galilei (father of Galileo Galilei) may have been the first person to advocate equal temperament (in a 1581 treatise), although his countryman and fellow lutenist Giacomo Gorzanis wrote music based on equal temperament by 1567. The first person known to have attempted a numerical specification for equal temperament is probably Zhu Zaiyu (朱載堉) in the Ming Dynasty, who published a theory of the temperament in 1584. It is possible that this idea was spread to Europe by way of trade, which had been intensified just at the moment when Zhu Zaiyu went into print with his new theory. Within fifty-two years of Chu's publication, the same ideas had been published by Marin Mersenne and Simon Stevin.

From 1450 to about 1800 there is evidence that musicians expected much less mistuning (than that of Equal Temperament) in the most common keys, such as C major. Instead, they used approximations that emphasized the tuning of thirds or fifths in these keys, such as meantone temperament. Some theorists, such as Giuseppe Tartini, were opposed to the adoption of Equal Temperament; they felt that degrading the purity of each chord degraded the aesthetic appeal of music. Some listeners claim that the equal-tempered difference is especially troubling in the lower register, and had somewhat constrained composers in the classical and romantic eras from writing chords narrower than octave for the left hand in keyboard music, while such examples in cello parts of string quartets are more common. Others take issue with dissonance in the higher register, where beating between harmonics of mistuned consonances is faster, and combinational tones are more pronounced.

String ensembles and vocal groups, who have no mechanical tuning limitations, often use a tuning much closer to just intonation, as it is naturally more consonant. Other instruments, such as wind, keyboard, and fretted-instruments, often only approximate equal temperament, where technical limitations prevent exact tunings.

J. S. Bach wrote The Well-Tempered Clavier to demonstrate the musical possibilities of well temperament, where in some keys the consonances are even more degraded than in equal temperament. It is reasonable to believe that when composers and theoreticians of earlier times wrote of the moods and "colors" of the keys, they described the subtly different dissonances of particular tuning methods, though it is difficult to determine with any exactness the actual tunings used in different places at different times by any composer. (Correspondingly, there is a great deal of variety in the particular opinions of composers about the moods and colors of particular keys.)

Twelve tone equal temperament took hold for a variety of reasons. It conveniently fit the existing keyboard design, and was a better approximation to just intonation than the nearby alternative equal temperaments. It permitted total harmonic freedom at the expense of just a little purity in every interval. This allowed greater expression through modulation, which became extremely important in the 19th century music of composers such as Chopin, Schumann, Liszt, and others.

A precise equal temperament was not attainable until Johann Heinrich Scheibler developed a tuning fork tonometer in 1834 to accurately measure pitches. The use of this device was not widespread, and it was not until the early 20th century that a practical aural method of tuning the piano to equal temperament with precision was developed and disseminated.

It is in the environment of equal temperament that the new styles of symmetrical tonality and polytonality, atonal music such as that written with the twelve tone technique or serialism, and jazz (at least its piano component) developed and flourished.

[edit] General properties of equal temperament

In an equal temperament, the distance between each step of the scale is the same interval. Because the perceived identity of an interval depends on its ratio, this scale in even steps is a geometric sequence of multiplications. Specifically, the smallest interval in an equal tempered scale is the ratio:

r^n_{}=p
r=\sqrt[n]{p}

Where the ratio r divides the ratio p (often the octave, which is 2/1) into n equal parts. (See Twelve-tone equal temperament below.)

Scales are often measured in cents, which divide the octave into 1200 equal intervals (each called a cent). This logarithmic scale makes comparison of different tuning systems easier than comparing ratios, and has considerable use in Ethnomusicology. The basic step in cents for any equal temperament can by found by taking the width of p above in cents (usually the octave, which is 1200 cents wide), called below w, and dividing it into n parts:

c = \frac{w}{n}

In musical analysis, material belonging to an equal temperament is often given an integer notation, meaning a single integer is used to represent each pitch. This simplifies and generalizes discussion of pitch material within the temperament in the same way that taking the logarithm of a multiplication reduces it to addition. Furthermore, by applying the modular arithmetic where the modulo is the number of divisions of the octave (usually 12), these integers can be reduced to pitch classes, which removes the distinction (or acknowledges the similarity) between pitches of the same name, e.g. 'C' is 0 regardless of octave register.

[edit] Twelve-tone equal temperament

In twelve-tone equal temperament, which divides the octave into 12 equal parts, the ratio of frequencies between two adjacent semitones is the twelfth root of two:

r = \sqrt[12]{2} \approx 1.05946309

This interval is equal to 100 cents. (The cent is sometimes for this reason defined as one hundredth of a semitone.)

[edit] Calculating absolute frequencies

To find the frequency, P^{}_n, of a note in 12-TET, the following definition may be used:

P_n=P_a \times 2^\frac{n-a}{12}

In this formula P^{}_n refers to the pitch, or frequency (usually in hertz), you are trying to find. P^{}_a refers to the frequency of a reference pitch (usually 440Hz). n and a refer to numbers assigned to the desired pitch and the reference pitch, respectively. These two numbers are from a list of consecutive integers assigned to consecutive semitones. For example, A4 (the reference pitch) is the 49th key from the left end of a piano (tuned to 440Hz), and C4 (middle C) is the 40th key. These numbers can be used to find the frequency of C4:

P_{40} = 440_{Hz} \times 2^\frac{40-49}{12} \approx 261.626_{Hz}

See Piano key frequencies for a list of 12-TET frequencies tuned to A-440.

[edit] Comparison to just intonation

The following table shows the values of the intervals of 12 TET, along with one interval from just intonation that each approximates, and the percentage by which they differ. Negative percentages indicate the equally tempered interval is narrower than the just interval; positive percentages indicate it is wider:

Name Exact value in 12-TET Decimal value in 12-TET Just intonation interval Percent difference
Unison 2^\frac{0}{12} = 1 1.000000 \begin{matrix} \frac{1}{1} \end{matrix} = 1.000000 0.00%
Minor second 2^\frac{1}{12} = \sqrt[12]{2} 1.059463 \begin{matrix} \frac{16}{15} \end{matrix} = 1.066667 -0.68%
Major second 2^\frac{2}{12} = \sqrt[6]{2} 1.122462 \begin{matrix} \frac{9}{8} \end{matrix} = 1.125000 -0.23%
Minor third 2^\frac{3}{12} = \sqrt[4]{2} 1.189207 \begin{matrix} \frac{6}{5} \end{matrix} = 1.200000 -0.91%
Major third 2^\frac{4}{12} = \sqrt[3]{2} 1.259921 \begin{matrix} \frac{5}{4} \end{matrix} = 1.250000 +0.79%
Perfect fourth 2^\frac{5}{12} = \sqrt[12]{32} 1.334840 \begin{matrix} \frac{4}{3} \end{matrix} = 1.333333 +0.11%
Diminished fifth 2^\frac{6}{12} = \sqrt{2} 1.414214 \begin{matrix} \frac{7}{5} \end{matrix} = 1.400000 +1.02%
Perfect fifth 2^\frac{7}{12} = \sqrt[12]{128} 1.498307 \begin{matrix} \frac{3}{2} \end{matrix} = 1.500000 -0.11%
Minor sixth 2^\frac{8}{12} = \sqrt[3]{4} 1.587401 \begin{matrix} \frac{8}{5} \end{matrix} = 1.600000 -0.79%
Major sixth 2^\frac{9}{12} = \sqrt[4]{8} 1.681793 \begin{matrix} \frac{5}{3} \end{matrix} = 1.666667 +0.90%
Minor seventh 2^\frac{10}{12} = \sqrt[6]{32} 1.781797 \begin{matrix} \frac{16}{9} \end{matrix} = 1.777778 +0.23%
Major seventh 2^\frac{11}{12} = \sqrt[12]{2048} 1.887749 \begin{matrix} \frac{15}{8} \end{matrix} = 1.875000 +0.68%
Octave 2^\frac{12}{12} = {2} 2.000000 \begin{matrix} \frac{2}{1} \end{matrix} = 2.000000 0.00%

(These mappings from equal temperament to just intonation are by no means unique. The minor seventh, for example, can be meaningfully said to approximate 9/5, 7/4, or 16/9 depending on context.)

[edit] Cent values of equal temperament

Tone C1 D♭ D E♭ E F F♯ G A♭ A B♭ B C2
Cents 0 100 200 300 400 500 600 700 800 900 1000 1100 1200

[edit] Other equal temperaments

[edit] 5 and 7 tone temperaments in ethnomusicology

Five and seven tone equal temperament (5-TET and 7-TET), with 240 and 171 cent steps respectively, are fairly common. A Thai xylophone measured by Morton (1974) "varied only plus or minus 5 cents," from 7-TET. A Ugandan Chopi xylophone measured by Haddon (1952) was also tuned to this system. Indonesian gamelans are tuned to 5-TET according to Kunst (1949), but according to Hood (1966) and McPhee (1966) their tuning varies widely, and according to Tenzer (2000) they contain stretched octaves. It is now well-accepted that of the two primary tuning systems in gamelan music, slendro and pelog, only slendro somewhat resembles five-tone equal temperament while pelog is highly unequal; however, Surjodiningrat et al. (1972) has analyzed pelog as a seven-note subset of nine-tone equal temperament. A South American Indian scale from a preinstrumental culture measured by Boiles (1969) featured 175 cent equal temperament, which stretches the octave slightly as with instrumental gamelan music.

[edit] Various Western equal temperaments

Many systems that divide the octave equally can be considered relative to other systems of temperament. 19-TET and especially 31-TET are extended varieties of Meantone temperament and approximate most just intonation intervals considerably better than 12-TET. They have been used sporadically since the 16th century, with 31-TET particularly popular in Holland, there advocated by Christiaan Huygens and Adriaan Fokker.

In the 20th century, standardized Western pitch and notation practices having been placed on a 12-TET foundation made the quarter tone scale (or 24-TET) a popular microtonal tuning. Though it only improved non-traditonal consonances, such as 11/4, 24-TET can be easily constructed by superimposing two 12-TET systems tuned half a semitone apart. It is based on steps of 50 cents, or \sqrt[24]{2}.

53-TET is better at approximating the traditional just intonation consonances than 19 or 31-TET, but has had very little use. It doesn't fit the Meantone mold that shaped the development of Western harmony and tonality since the Rennaissance, though it does accommodate both the Pythagorean tuning of medieval music (with its extremely just perfect fifths) as well as schismatic temperament, and is sometimes used in Turkish music theory. In 53-TET, some traditional compositions would have to make subtle microtonal pitch shifts or have a drifting pitch level in order to make use of the tuning's excellent just intonation triads. (Another tuning which has seen some use in practice and is not a meantone system is 22-TET.)

55-TET, not as close as 53 to just intonation, was a bit closer to common practice. As an excellent representative of the variety of meantone temperament popular in the 18th century, 55-TET it was considered ideal by Georg Philipp Telemann and other prominent musicians. Wolfgang Amadeus Mozart's surviving violin lessons conform closely to such a model.[citation needed]

Another extension of 12-TET is 72-TET (dividing the semitone into 6 equal parts), which though not a meantone tuning, approximates well most just intonation intervals, even less traditional ones such as 7/4, 9/7, 11/5, 11/6 and 11/7. 72-TET has been taught, written and performed in practice by Joe Maneri and his students (whose atonal inclinations interestingly typically avoid any reference to just intonation whatsoever).

Other equal divisions of the octave that have found occasional use include 15-TET, 34-TET, 41-TET, 46-TET, 48-TET, 99-TET, and 171-TET.

[edit] Equal temperaments of non-octave intervals

The equal tempered version of the Bohlen-Pierce scale consists of the ratio 3:1, 1902 cents, conventionally a perfect fifth wider than an octave, called in this theory a tritave, and split into a thirteen equal parts. This provides a very close match to justly tuned ratios consisting only of odd numbers. Each step is 146.3 cents, or \sqrt[13]{3}.

Wendy Carlos discovered three unusual equal temperaments after a thorough study of the properties of possible temperaments having a step size between 30 and 120 cents. These were called alpha, beta, and gamma. None of the three divides any rational interval equally, but each of them provides a very good approximation of several just intervals.[1] Their step sizes:

  • alpha: 78.0 cents
  • beta: 63.8 cents
  • gamma: 35.1 cents

Alpha and Beta may be heard on the title track of her 1986 album Beauty in the Beast.

[edit] See also

[edit] Sources

  • Burns, Edward M. (1999). "Intervals, Scales, and Tuning", The Psychology of Music second edition. Deutsch, Diana, ed. San Diego: Academic Press. ISBN 0-12-213564-4. Cited:
    • Ellis, C. (1965). "Pre-instrumental scales", Journal of the Acoustical Society of America, 9, 126-144.
    • Morton, D. (1974). "Vocal tones in traditional Thai music", Selected reports in ethnomusicology (Vol. 2, p.88-99). Los Angeles: Institute for Ethnomusicology, UCLA.
    • Haddon, E. (1952). "Possible origin of the Chopi Timbila xylophone", African Music Society Newsletter, 1, 61-67.
    • Kunst, J. (1949). Music in Java (Vol. II). The Hague: Marinus Nijhoff.
    • Hood, M. (1966). "Slendro and Pelog redefined", Selected Reports in Ethnomusicology, Institute of Ethnomusicology, UCLA, 1, 36-48.
    • Temple, Robert K. G. (1986)."The Genius of China". ISBN 0-671-62028-2
    • Tenzer, (2000). Gamelan Gong Kebyar: The Art of Twentieth-Century Balinese Music. ISBN 0-226-79281-1 and ISBN 0-226-79283-8
    • Boiles, J. (1969). "Terpehua though-song", Ethnomusicology, 13, 42-47.
    • Wachsmann, K. (1950). "An equal-stepped tuning in a Ganda harp", Nature (Longdon), 165, 40.
    • Cho, Gene Jinsiong. (2003). The Discovery of Musical Equal Temperament in China and Europe in the Sixteenth Century. Lewiston, NY: The Edwin Mellen Press.
  • Jorgensen, Owen. Tuning. Michigan State University Press, 1991. ISBN 0-87013-290-3
  • Surjodiningrat,W., Sudarjana, P.J., and Susanto, A. (1972) Tone measurements of outstanding Javanese gamelans in Jogjakarta and Surakarta, Gadjah Mada University Press, Jogjakarta 1972. Cited on http://web.telia.com/~u57011259/pelog_main.htm, accessed May 19, 2006.

[edit] External links

Tunings edit
Pythagorean · Just intonation · Harry Partch's 43-tone scale
Regular temperaments
Equal temperaments :   12-tone · 19-tone · 22-tone · 24-tone · 31-tone · 53-tone · 72-tone
Non-equal temperaments :   Meantone (Quarter-comma; Lucy tuning; Septimal) · Schismatic · Miracle
Irregular temperaments
Well temperament