Quarter tone (Redirected from Undecimal quarter tone)

Quarter tone on C

A quarter tone is a pitch halfway between the usual notes of a chromatic scale or an interval about half as wide (orally, or logarithmically) as a semitone, which itself is half a whole tone. Quarter tones divide the octave by 50 cents each, and have 24 different pitches.

Trumpet with 3 normal valves and a quartering on the extension valve (right)

Quarter tones have their roots in the music of the Middle East and more specifically in Persian traditional music. However, the first evidenced proposal of the equally-tempered quarter tone scale, or 24 equal temperament, was made by 19th-century music theorists Heinrich Richter in 1823 and Mikhail Mishaqa about 1840. Composers who have written music using this scale include: Pierre Boulez, Julián Carrillo, Mildred Couper, George Enescu, Alberto Ginastera, Gérard Grisey, Alois Hába, Ljubica Marić, Charles Ives, Tristan Murail, Krzysztof Penderecki, Giacinto Scelsi, Ammar El Sherei, Karlheinz Stockhausen, Tui St. George Tucker, Ivan Wyschnegradsky, Iannis Xenakis, and Seppe Gebruers (See List of quarter tone pieces.)

Types

Equal-tempered tuning systems

Composer Charles Ives chose the four-note chord above (C–Dthree quarter sharp–G–Athree quarter sharp) as good possibility for a "fundamental" chord in the quarter-tone scale, akin not to the tonic but to the major chord of traditional tonality.
Neutral second on C
8-tet scale on C
Major second on C
The "subminor seventh": Bthree quarter flat=Ahalf sharp, 19 quarter tones. It approximates the harmonic seventh, B7. Maneri-Sims notation: B

The term quarter tone can refer to a number of different intervals, all very close in size. For example, some 17th- and 18th-century theorists used the term to describe the distance between a sharp and enharmonically distinct flat in mean-tone temperaments (e.g., D–E). In the quarter-tone scale, also called 24-tone equal temperament (24-TET), the quarter tone is 50 cents, or a frequency ratio of 242 or approximately 1.0293, and divides the octave into 24 equal steps (equal temperament). In this scale the quarter tone is the smallest step. A semitone is thus made of two steps, and three steps make a three-quarter tone or neutral second, half of a minor third. The 8-TET scale is composed of three-quarter tones. Four steps make a whole tone.

Quarter tones and intervals close to them also occur in a number of other equally tempered tuning systems. 22-TET contains an interval of 54.55 cents, slightly wider than a quarter-tone, whereas 53-TET has an interval of 45.28 cents, slightly smaller. 72-TET also has equally tempered quarter-tones, and indeed contains three quarter-tone scales, since 72 is divisible by 24. The smallest interval in 31 equal temperament (the "diesis" of 38.71 cents) is half a chromatic semitone, one-third of a diatonic semitone and one-fifth of a whole tone, so it may function as a quarter tone, a fifth-tone or a sixth-tone.

Just intonation tuning systems

In just intonation the quarter tone can be represented by the septimal quarter tone, 36:35 (48.77 cents), or by the undecimal quarter tone (i.e. the thirty-third harmonic), 33:32 (53.27 cents), approximately half the semitone of 16:15 or 25:24. The ratio of 36:35 is only 1.23 cents narrower than a 24-TET quarter tone. This just ratio is also the difference between a minor third (6:5) and septimal minor third (7:6).

Composer Ben Johnston, to accommodate the just septimal quarter tone, uses a small "7" (7) as an accidental to indicate a note is lowered 49 cents, or an upside down "7" (7 upside-down) to indicate a note is raised 49 cents, or a ratio of 36:35. Johnston uses an upward and downward arrow to indicate a note is raised or lowered by a ratio of 33:32, or 53 cents. The Maneri-Sims notation system designed for 72-et uses the accidentals and for a quarter tone (36:35 or 48.77 cents) up and down.

Playing quarter tones

Quarter tone clarinet by Fritz Schüller

Any tunable musical instrument can be used to perform quarter tones, if two players and two identical instruments, with one tuned a quarter tone higher, are used. As this requires neither a special instrument nor special techniques, much quarter toned music is written for pairs of pianos, violins, harps, etc. The retuning of the instrument, and then returning it to its former pitch, is easy for violins, harder for harps, and slow and relatively expensive for pianos.

The following deals with the ability of single instruments to produce quarter tones. In Western instruments, this means "in addition to the usual 12-tone system". Because many musical instruments manufactured today (2018) are designed for the 12-tone scale, not all are usable for playing quarter tones. Sometimes special playing techniques must be used.

Conventional musical instruments that cannot play quarter tones (except by using special techniques—see below) include:

  • Most standard or unmodified non-electronic keyboard instruments, such as pianos, organs, and accordions
  • Fretted string instruments such as guitars, bass guitars, and ukuleles (though on these it is possible to play quarter tones by pitch-bending, with special tunings, or with customized necks)
  • Pitched percussion instruments, if standard techniques are used, and if the instruments are not tunable
  • Western wind instruments that use keys or valves
    • Woodwind instruments, such as clarinets, saxophones, flutes, and oboes (though with many of these, it is still possible using non-standard techniques such as special fingerings or by the player manipulating their embouchure, to play at least some quarter tones, if not a whole scale)
    • Valved brass instruments (trumpet, tuba) (though, as with woodwinds, embouchure manipulation, as well as harmonic tones that fall closer to quarter-tones than half-tones, make quarter-tone scales possible; the horn technique of adjusting pitch with the right hand in the bell makes this instrument an exception)
  • Harmonica (although note bending is a common technique)

Conventional musical instruments that can play quarter tones include

Other instruments can be used to play quarter tones when using audio signal processing effects such as pitch shifting.

Quarter-tone pianos have been built, which consist essentially of two pianos with two keyboards stacked one above the other in a single case, one tuned a quarter tone higher than the other.[citation needed]

Music of the Middle East

Many Persian dastgah and Arabic maqamat contain intervals of three-quarter tone size; a short list of these follows.

  1. Bayati (بیاتی): D Ehalf flat F G A B C D
    
\relative c' {
\time 8/4 \omit Staff.TimeSignature
d4 eeh f g a bes c d \bar "|"
}
  2. Rast (راست):
    C D Ehalf flat F G A Bhalf flat C (ascending)
    C B A G F Ehalf flat D C (descending)
    
\relative c' {
\time 8/4 \omit Staff.TimeSignature
c4 d eeh f g a beh c \bar "|"
}
  3. Saba (صبا): D Ehalf flat F G A B C D
    
\relative c' {
\time 8/4 \omit Staff.TimeSignature
d4 eeh f ges a bes c d \bar "|"
}
  4. Sigah (سه گاه): Ehalf flat F G A Bhalf flat C D Ehalf flat
    
\relative c' {
\time 8/4 \omit Staff.TimeSignature
eeh f g a beh c d eeh \bar "|"
}
  5. ‘Ajam (عجم)
  6. Hoseyni

The Islamic philosopher and scientist Al-Farabi described a number of intervals in his work in music, including a number of quarter tones.

Assyrian/Syriac Church Music Scale:

  1. Qadmoyo (Bayati)
  2. Trayono (Hussayni)
  3. Tlithoyo (Segah)
  4. Rbiʿoyo (Rast)
  5. Hmishoyo
  6. Shtithoyo (ʿAjam)
  7. Shbiʿoyo
  8. Tminoyo

Quarter-tone scale

Known as gadwal in Arabic, the quarter-tone scale was developed in the Middle East in the eighteenth century and many of the first detailed writings in the nineteenth century Syria describe the scale as being of 24 equal tones. The invention of the scale is attributed to Mikhail Mishaqa whose work Essay on the Art of Music for the Emir Shihāb (al-Risāla al-shihābiyya fi 'l-ṣināʿa al-mūsīqiyya) is devoted to the topic but also makes clear his teacher Sheikh Muhammad al-Attar (1764–1828) was one of many already familiar with the concept.


\relative c' {
\cadenzaOn \omit Staff.TimeSignature
\tempo 1 = 90 \set Score.tempoHideNote = ##t
c1 cih cis cisih d dih dis disih e eih f fih fis fisih g gih gis gisih a aih ais aisih b bih \bar "|" c \bar "|." \break
c1 ceh b beh bes beseh a aeh aes aeseh g geh ges geseh f feh e eeh ees eeseh d deh des deseh \bar "|" c \bar "|."
}

The quarter tone scale may be primarily a theoretical construct in Arabic music. The quarter tone gives musicians a "conceptual map" they can use to discuss and compare intervals by number of quarter tones, and this may be one of the reasons it accompanies a renewed interest in theory, with instruction in music theory a mainstream requirement since that period.

Previously, pitches of a mode were chosen from a scale consisting of seventeen tones, developed by Safi al-Din al-Urmawi in the thirteenth century.

Composer Charles Ives chose the chord C–Dhalf sharp–F–Ghalf sharp–B as good possibility for a "secondary" chord in the quarter-tone scale, akin to the minor chord of traditional tonality. He considered that it may be built upon any degree of the quarter tone scale Here is the secondary "minor" and its "first inversion":


\relative c' {
\omit Staff.TimeSignature
\set Score.tempoHideNote = ##t
<c dih f gih bes>1 \bar "|" <c f gih bes dih>1 \bar "|."
}

In popular Western music

The bass descent of Nancy Sinatra's version of "These Boots Are Made for Walkin' " includes quarter tone descents. Several quarter-tone albums have been recorded by Jute Gyte, a one-man avantgarde black metal band from Missouri, USA. Another quartertone metal album was issued by the Swedish band Massive Audio Nerve. Australian psychedelic rock band King Gizzard & the Lizard Wizard's albums Flying Microtonal Banana, K.G., and L.W. heavily emphasize quarter-tones and used a custom-built guitar in 24-TET tuning. Jazz violinist/violist Mat Maneri, in conjunction with his father Joe Maneri, made a crossover fusion album, Pentagon (2005), that featured experiments in hip hop with quarter tone pianos, as well as electric organ and mellotron textures, along with distorted trombone, in a post-Bitches Brew type of mixed Jazz/rock.

Ancient Greek tetrachords

Greek Dorian enharmonic genus: two disjunct tetrachords each of a quarter tone, quarter tone, and major third.

The enharmonic genus of the Greek tetrachord consisted of a ditone or an approximate major third, and a semitone, which was divided into two microtones. Aristoxenos, Didymos and others presented the semitone as being divided into two approximate quarter tone intervals of about the same size, while other ancient Greek theorists described the microtones resulting from dividing the semitone of the enharmonic genus as unequal in size (i.e., one smaller than a quarter tone and one larger).

Interval size in equal temperament

Here are the sizes of some common intervals in a 24-note equally tempered scale, with the interval names proposed by Alois Hába (neutral third, etc.) and Ivan Wyschnegradsky (major fourth, etc.):

19-Limit just intonation intervals approximated in 24-TET
Interval name Size
(steps)
Size
(cents)
MIDI Just ratio Just
(cents)
MIDI Error
(cents)
octave 24 1200 2:1 1200.00 +00.00
semidiminished octave 23 1150 35:18 1151.23 01.23
supermajor seventh 23 1150 27:14 1137.04 +12.96
major seventh 22 1100 15:80 1088.27 +11.73
neutral seventh, major tone 21 1050 11:60 1049.36 +00.64
neutral seventh, minor tone 21 1050 20:11 1035.00 +15.00
large just minor seventh 20 1000 9:5 1017.60 −17.60
small just minor seventh 20 1000 16:90 0996.09 +03.91
supermajor sixth/subminor seventh 19 0950 7:4 0968.83 −18.83
major sixth 18 0900 5:3 0884.36 +15.64
neutral sixth 17 0850 18:11 0852.59 02.59
minor sixth 16 0800 8:5 0813.69 −13.69
subminor sixth 15 0750 14:90 0764.92 −14.92
perfect fifth 14 0700 3:2 0701.96 01.96
minor fifth 13 0650 16:11 0648.68 +01.32
lesser septimal tritone 12 0600 7:5 0582.51 +17.49
major fourth 11 0550 11:80 0551.32 01.32
perfect fourth 10 0500 4:3 0498.04 +01.96
tridecimal major third 09 0450 13:10 0454.21 04.21
septimal major third 09 0450 9:7 0435.08 +14.92
major third 08 0400 5:4 0386.31 +13.69
undecimal neutral third 07 0350 11:90 0347.41 +02.59
minor third 06 0300 6:5 0315.64 −15.64
septimal minor third 05 0250 7:6 0266.87 −16.87
tridecimal five-quarter tone 05 0250 15:13 0247.74 +02.26
septimal whole tone 05 0250 8:7 0231.17 +18.83
major second, major tone 04 0200 9:8 0203.91 03.91
major second, minor tone 04 0200 10:90 0182.40 +17.60
neutral second, greater undecimal 03 0150 11:10 0165.00 −15.00
neutral second, lesser undecimal 03 0150 12:11 0150.64 00.64
15:14 semitone 02 0100 15:14 0119.44 −19.44
diatonic semitone, just 02 0100 16:15 0111.73 −11.73
21:20 semitone 02 0100 21:20 0084.47 +15.53
28:27 semitone 01 0050 28:27 0062.96 −12.96
33:32 semitone 01 0050 33:32 0053.27 −3.27
unison 00 0000 1:1 0000.00 +00.00

Moving from 12-TET to 24-TET allows the better approximation of a number of intervals. Intervals matched particularly closely include the neutral second, neutral third, and (11:8) ratio, or the 11th harmonic. The septimal minor third and septimal major third are approximated rather poorly; the (13:10) and (15:13) ratios, involving the 13th harmonic, are matched very closely. Overall, 24-TET can be viewed as matching the 11th and 13th harmonics more closely than the 7th.

See also


This page was last updated at 2024-03-17 00:59 UTC. Update now. View original page.

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