Otonality and utonality

Last updated April 27, 2023

13-limit utonality

Otonality^[1] and utonality^[2] are terms introduced by Harry Partch to describe chords whose pitch classes are the harmonics or subharmonics of a given fixed tone (identity ^[3]), respectively. For example: 1/1, 2/1, 3/1,... or 1/1, 1/2, 1/3,....

An Otonality is that set of pitches generated by the numerical factors (...identities)...over a numerical constant (... numerary nexus ) in the denominator. Conversely, a Utonality is the inversion of an Otonality, a set of pitches with a numerical constant in the numerator over the numerical factors...in the denominator.^[4]

Definition

G(=11), A(=98), B(=54), B(=118), D(=32), F(=74)

Otonality on G = lower line of the tonality diamond bottom left to top right.

G(=11), F(=169), E(=85), D(=1611), C(=43), A(=87)

Utonality under G = lower line of the tonality diamond bottom right to top left.

A Utonality is a ...chord that is the inversion of an Otonality: it is formed by building the same interval sequence as that of an Otonality downward from the root of the chord, rather than upward. The analogy, in this case, is not to the harmonic series but to the subharmonic, or undertone series.^[5]

An otonality^[1] is a collection of pitches which can be expressed in ratios, expressing their relationship to the fixed tone, that have equal denominators and consecutive numerators. For example, 1/1, 5/4, and 3/2 (just major chord) form an otonality because they can be written as 4/4, 5/4, 6/4. This in turn can be written as an extended ratio 4:5:6. Every otonality is therefore composed of members of a harmonic series. Similarly, the ratios of a utonality share the same numerator and have consecutive denominators. 7/4, 7/5, 7/6, and 1/1 (7/7) form a utonality, sometimes written as 1/4:5:6:7, or as 7/7:6:5:4. Every utonality is therefore composed of members of a subharmonic series. This term is used extensively by Harry Partch in Genesis of a Music.^[3]

An otonality corresponds to an arithmetic series of frequencies, or lengths of a vibrating string. Brass instruments naturally produce otonalities, and indeed otonalities are inherent in the harmonics of a single fundamental tone. Tuvan Khoomei singers produce otonalities with their vocal tracts.

Utonality^[2] is the opposite, corresponding to a subharmonic series of frequencies, or an arithmetic series of wavelengths (the inverse of frequency). The arithmetical proportion "may be considered as a demonstration of utonality ('minor tonality')."^[6]

If otonality and utonality are defined broadly, every just intonation chord is both an otonality and a utonality. For example, the minor triad in root position is made up of the 10th, 12th and 15th harmonics, and 10/10, 12/10 and 15/10 meets the definition of otonal. A better, narrower definition requires that the harmonic (or subharmonic) series members be adjacent. Thus 4:5:6 is an otonality, but 10:12:15 is not. (Alternate voicings of 4:5:6, such as 5:6:8, 3:4:5:6, etc. would presumably also be otonalities.) Under this definition, only a few chord types qualify as otonalities or utonalities. The only otonality triads are the major triad 4:5:6 and the diminished triad 5:6:7. The only such tetrad is the dominant seventh tetrad 4:5:6:7.

Microtonalists have extended the concept of otonal and utonal to apply to all just intonation chords. A chord is otonal if its odd limit increases on being melodically inverted, utonal if its odd limit decreases, and ambitonal if its odd limit is unchanged.^[7] Melodic inversion is not inversion in the usual sense, in which C–E–G becomes E–G–C or G–C–E. Instead, C–E–G is turned upside down to become C–A♭–F. A chord's odd limit is the largest of the odd limits of each of the numbers in the chord's extended ratio. For example, the major triad in close position is 4:5:6. These three numbers have odd limits of 1, 5 and 3 respectively. The largest of the three is 5, thus the chord has an odd limit of 5. Its melodic inverse 10:12:15 has an odd limit of 15, which is greater, therefore the major triad is otonal. A chord's odd limit is independent of its voicing, so alternate voicings such as 5:6:8, 3:4:5:6, etc. are also otonal.

All otonalities are otonal, but not all otonal chords are otonalities. Likewise, all utonalities are a subset of utonal chords.

The major ninth chord 8:10:12:15:18 is also otonal. Examples of ambitonal chords are the major sixth chord (12:15:18:20) and the major seventh chord (8:10:12:15). Ambitonal chords often can be reasonably interpreted as either major or minor. For example, C^M6, in certain contexts or voicings, can be interpreted as Am⁷.

Relationship to standard Western music theory

Partch said that his 1931 coinage of "otonality" and "utonality" was "hastened" by having read Henry Cowell's discussion of undertones in New Musical Resources (1930).^[5]

The 5-limit otonality is simply a just major chord, and the 5-limit utonality is a just minor chord. Thus otonality and utonality can be viewed as extensions of major and minor tonality respectively. However, whereas standard music theory views a minor chord as being built up from the root with a minor third and a perfect fifth, a utonality is viewed as descending from what's normally considered the "fifth" of the chord,^{[ citation needed ]} so the correspondence is not perfect. This corresponds with the dualistic theory of Hugo Riemann:

In the era of meantone temperament, augmented sixth chords of the kind known as the German sixth (or the English sixth, depending on how it resolves) were close in tuning and sound to the 7-limit otonality, called the tetrad. This chord might be, for example, A♭-C-E♭-G ♭[F♯] Play (help·info). Standing alone, it has something of the sound of a dominant seventh, but considerably less dissonant. It has also been suggested that the Tristan chord, for example, F-B-D♯-G♯ can be considered a utonality, or 7-limit utonal tetrad, which it closely approximates if the tuning is meantone, though presumably less well in the tuning of a Wagnerian orchestra.

Whereas 5-limit chords associate otonal with major and utonal with minor, 7-limit chords that don't use 5 as a prime factor reverse this association. For example, 6:7:9 is otonal but minor, and 14:18:21 is utonal but major.

Consonance

Though Partch presents otonality and utonality as being equal and symmetric concepts, when played on most physical instruments an otonality sounds much more consonant than a similar utonality, due to the presence of the missing fundamental phenomenon. In an otonality, all of the notes are elements of the same harmonic series, so they tend to partially activate the presence of a "virtual" fundamental as though they were harmonics of a single complex pitch. Utonal chords, while containing the same dyads and roughness as otonal chords, do not tend to activate this phenomenon as strongly. There are more details in Partch's work.^[3]

Use

Partch used otonal and utonal chords in his music. Ben Johnston ^[8] often uses the otonal as an expanded tonic chord: 4:5:6:7:11:13 (C:E:G:B ♭:F↑:A ♭) and bases the opening of the third movement of his String Quartet No. 10 on this thirteen-limit Otonality on C.^[9] The mystic chord has been theorized as being derived from harmonics 8 through 14 without 12: 8:9:10:11:13:14 (C:D:E:F↑:A ♭:B ♭), and as harmonics 7 through 13: 7:8:9:10:(11:)12:13 (C:D -:E :F ♯:(G↑ -:)A :B ♭-); both otonal. Yuri Landman published a microtonal diagram that compares series of otonal and utonal scales with 12TET and the harmonic series.^[10] He applies this system for just transposition with a set of electric microtonal kotos.

Related Research Articles

In music, just intonation or pure intonation is the tuning of musical intervals as whole number ratios of frequencies. An interval tuned in this way is said to be pure, and is called a just interval. Just intervals consist of tones from a single harmonic series of an implied fundamental. For example, in the diagram, if the notes G3 and C4 are tuned as members of the harmonic series of the lowest C, their frequencies will be 3 and 4 times the fundamental frequency. The interval ratio between C4 and G3 is therefore 4:3, a just fourth.

In music theory, the tritone is defined as a musical interval composed of three adjacent whole tones. For instance, the interval from F up to the B above it is a tritone as it can be decomposed into the three adjacent whole tones F–G, G–A, and A–B.

In music theory, a leading-tone is a note or pitch which resolves or "leads" to a note one semitone higher or lower, being a lower and upper leading-tone, respectively. Typically, the leading tone refers to the seventh scale degree of a major scale, a major seventh above the tonic. In the movable do solfège system, the leading-tone is sung as ti.

In music theory, limit or harmonic limit is a way of characterizing the harmony found in a piece or genre of music, or the harmonies that can be made using a particular scale. The term limit was introduced by Harry Partch, who used it to give an upper bound on the complexity of harmony; hence the name.

In music theory, a minor seventh is one of two musical intervals that span seven staff positions. It is minor because it is the smaller of the two sevenths, spanning ten semitones. The major seventh spans eleven. For example, the interval from A to G is a minor seventh, as the note G lies ten semitones above A, and there are seven staff positions from A to G. Diminished and augmented sevenths span the same number of staff positions, but consist of a different number of semitones.

In music theory, a major chord is a chord that has a root, a major third, and a perfect fifth. When a chord comprises only these three notes, it is called a major triad. For example, the major triad built on C, called a C major triad, has pitches C–E–G:

In music theory, a minor chord is a chord that has a root, a minor third, and a perfect fifth. When a chord comprises only these three notes, it is called a minor triad. For example, the minor triad built on C, called a C minor triad, has pitches C–E♭–G:

In music theory, a diminished triad is a triad consisting of two minor thirds above the root. It is a minor triad with a lowered (flattened) fifth. When using chord symbols, it may be indicated by the symbols "dim", "^o", "m^♭5", or "MI^(♭5)". However, in most popular-music chord books, the symbol "dim" and "^o" represents a diminished seventh chord, which in some modern jazz books and music theory books is represented by the "dim7" or "^o⁷" symbols.

In music theory, the concept of root is the idea that a chord can be represented and named by one of its notes. It is linked to harmonic thinking—the idea that vertical aggregates of notes can form a single unit, a chord. It is in this sense that one speaks of a "C chord" or a "chord on C"—a chord built from C and of which the note C is the root. When a chord is referred to in Classical music or popular music without a reference to what type of chord it is, it is assumed a major triad, which for C contains the notes C, E and G. The root need not be the bass note, the lowest note of the chord: the concept of root is linked to that of the inversion of chords, which is derived from the notion of invertible counterpoint. In this concept, chords can be inverted while still retaining their root.

In Western music, the adjectives major and minor may describe an interval, chord, scale, or key. A composition, movement, section, or phrase may also be referred to by its key, including whether that key is major or minor.

The 43-tone scale is a just intonation scale with 43 pitches in each octave. It is based on an eleven-limit tonality diamond, similar to the seven-limit diamond previously devised by Max Friedrich Meyer and refined by Harry Partch.

In music theory and tuning, a tonality diamond is a two-dimensional diagram of ratios in which one dimension is the Otonality and one the Utonality. Thus the n-limit tonality diamond is an arrangement in diamond-shape of the set of rational numbers r, $, such that the odd part of both the numerator and the denominator of r, when reduced to lowest terms, is less than or equal to the fixed odd number n . Equivalently, the diamond may be considered as a set of pitch classes, where a pitch class is an equivalence class of pitches under octave equivalence. The tonality diamond is often regarded as comprising the set of consonances of the n-limit. Although originally invented by Max Friedrich Meyer, the tonality diamond is now most associated with Harry Partch.$

In music, 53 equal temperament, called 53 TET, 53 EDO, or 53 ET, is the tempered scale derived by dividing the octave into 53 equal steps. Play (help·info) Each step represents a frequency ratio of 2^1⁄53, or 22.6415 cents, an interval sometimes called the Holdrian comma.

In music, septimal meantone temperament, also called standard septimal meantone or simply septimal meantone, refers to the tempering of 7-limit musical intervals by a meantone temperament tuning in the range from fifths flattened by the amount of fifths for 12 equal temperament to those as flat as 19 equal temperament, with 31 equal temperament being a more or less optimal tuning for both the 5- and 7-limits. Meantone temperament represents a frequency ratio of approximately 5 by means of four fifths, so that the major third, for instance C–E, is obtained from two tones in succession. Septimal meantone represents the frequency ratio of 56 (7 × 2³) by ten fifths, so that the interval 7:4 is reached by five successive tones. Hence C–A♯, not C–B♭, represents a 7:4 interval in septimal meantone.

In music, the undertone series or subharmonic series is a sequence of notes that results from inverting the intervals of the overtone series. While overtones naturally occur with the physical production of music on instruments, undertones must be produced in unusual ways. While the overtone series is based upon arithmetic multiplication of frequencies, resulting in a harmonic series, the undertone series is based on arithmetic division.

<span class="mw-page-title-main">Tonality flux</span>

Tonality flux is Harry Partch's term for the kinds of subtle harmonic changes that can occur in a microtonal context from notes moving from one chord to another by tiny increments of voice leading. For instance, within a major third G-B, there can be a minor third G to B, such that in moving from one to the other each line shifts less than a half-step. Within a just intonation scale, this could be represented by

Genesis of a Music is a book first published in 1949 by microtonal composer Harry Partch (1901–1974).

<span class="mw-page-title-main">Hexany</span> Class of musical pitch sets

In musical tuning systems, the hexany, invented by Erv Wilson, represents one of the simplest structures found in his combination product sets.

<span class="mw-page-title-main">Scale of harmonics</span>

The scale of harmonics is a musical scale based on the noded positions of the natural harmonics existing on a string. This musical scale is present on the guqin, regarded as one of the first string instruments with a musical scale. Most fret positions appearing on Non-Western string instruments (lutes) are equal to positions of this scale. Unexpectedly, these fret positions are actually the corresponding undertones of the overtones from the harmonic series. The distance from the nut to the fret is an integer number lower than the distance from the fret to the bridge.

References

1 2 Partch, Harry, 1901-1974 (1974). Genesis of a music : an account of a creative work, its roots and its fulfillments (Second edition, enlarged ed.). New York. p. 72. ISBN 0-306-71597-X. OCLC 624666.{{cite book}}: CS1 maint: multiple names: authors list (link)
1 2 Partch, Harry, 1901-1974 (1974). Genesis of a music : an account of a creative work, its roots and its fulfillments (Second edition, enlarged ed.). New York. p. 75. ISBN 0-306-71597-X. OCLC 624666.{{cite book}}: CS1 maint: multiple names: authors list (link)
1 2 3 Partch, Harry, 1901-1974 (August 1974). Genesis of a music : an account of a creative work, its roots and its fulfillments (Second edition, enlarged ed.). New York. ISBN 0-306-71597-X. OCLC 624666.{{cite book}}: CS1 maint: multiple names: authors list (link)
↑ Gilmore, Bob (1998). Harry Partch: A Biography, p.431, n.69. Yale. ISBN 9780300065213.
1 2 Gilmore, Bob (1998). Harry Partch: A Biography, p.68. Yale. ISBN 9780300065213.
↑ Partch, Harry. Genesis of a Music , p.69. 2nd ed. Da Capo Press, 1974. ISBN 0-306-80106-X.
↑ "Otonality and utonality", Xenharmonic Wiki. Opens with: "For the basic concepts, see the Wikipedia article Otonality and Utonality." Accessed: December 18, 2017.
↑ Johnston, Ben. (2006). "Maximum clarity" and other writings on music. Gilmore, Bob, 1961-2015. Urbana: University of Illinois Press. ISBN 978-0-252-09157-5. OCLC 811408988.
↑ Coessens, Kathleen; ed. (2017). Experimental Encounters in Music and Beyond, p.104. Leuven. ISBN 9789462701106.
↑ http://www.hypercustom.nl/utonaldiagram.jpg ^{[ bare URL image file ]}

External links

Otonality and ADO system at 96-EDO
Utonality and EDL system at 96-EDO

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[:0-1] 1 2 Partch, Harry, 1901-1974 (1974). Genesis of a music : an account of a creative work, its roots and its fulfillments (Second edition, enlarged ed.). New York. p. 72. ISBN 0-306-71597-X. OCLC 624666.{{cite book}}: CS1 maint: multiple names: authors list (link)

[:1-2] 1 2 Partch, Harry, 1901-1974 (1974). Genesis of a music : an account of a creative work, its roots and its fulfillments (Second edition, enlarged ed.). New York. p. 75. ISBN 0-306-71597-X. OCLC 624666.{{cite book}}: CS1 maint: multiple names: authors list (link)

[:2-3] 1 2 3 Partch, Harry, 1901-1974 (August 1974). Genesis of a music : an account of a creative work, its roots and its fulfillments (Second edition, enlarged ed.). New York. ISBN 0-306-71597-X. OCLC 624666.{{cite book}}: CS1 maint: multiple names: authors list (link)

[4] Gilmore, Bob (1998). Harry Partch: A Biography, p.431, n.69. Yale. ISBN 9780300065213.

[Gilmore-5] 1 2 Gilmore, Bob (1998). Harry Partch: A Biography, p.68. Yale. ISBN 9780300065213.

[6] Partch, Harry. Genesis of a Music , p.69. 2nd ed. Da Capo Press, 1974. ISBN 0-306-80106-X.

[7] "Otonality and utonality", Xenharmonic Wiki. Opens with: "For the basic concepts, see the Wikipedia article Otonality and Utonality." Accessed: December 18, 2017.

[8] Johnston, Ben. (2006). "Maximum clarity" and other writings on music. Gilmore, Bob, 1961-2015. Urbana: University of Illinois Press. ISBN 978-0-252-09157-5. OCLC 811408988.

[9] Coessens, Kathleen; ed. (2017). Experimental Encounters in Music and Beyond, p.104. Leuven. ISBN 9789462701106.

[10] ttp://www.hypercustom.nl/utonaldiagram.jpg ^{[ bare URL image file ]}

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v t e Harry Partch
List of works List of instruments
Works	Genesis of a Music (1949) Delusion of the Fury (1966)
Topics	43-tone scale Quadrangularis Reversum Otonality and Utonality Odentity and Udentity Tonality diamond Tonality flux
Related	West Coast School
Category