Editing Combinatoriality (section)

==Hexachordal combinatoriality==
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[[File:Elliott Carter - Piano Concerto - Hexachordal combinatoriality chords.png|thumb|Combinatorial all-trichord hexachords from [[Elliott Carter]]'s Piano Concerto, mm. 59–60<ref>Mead, Andrew (2002). "Twelve-Tone Composition and the Music of Elliott Carter", ''Concert Music, Rock, and Jazz Since 1945: Essays and Analytical Studies'', pp. 80–81. Elizabeth West Marvin, Richard Hermann; eds. University Rochester. {{ISBN|9781580460965}}.</ref>[[File:Elliott Carter - Piano Concerto - Hexachordal combinatoriality chords.mid]]]]

A 12-tone row has hexachordal combinatoriality with another 12-tone row if their respective first (as well as second, because a 12-tone row itself forms an aggregate by definition) hexachords form an aggregate.

There are four main types of combinatoriality. A hexachord may be:
*Prime combinatorial ([[transposition (music)|transposition]])
*Retrograde combinatorial ([[retrograde (music)|retrograde]])
*Inversional combinatorial ([[Melodic inversion|inversion]])
*Retrograde-inversional combinatorial ([[retrograde inversion|retrograde-inversion]])
and thus:
*Semi-combinatorial (by one of the above)
*All-combinatorial (by all)

Prime (transpositional) combinatoriality of a hexachord refers to the property of a hexachord whereby it forms an aggregate with one or more of its transpositions. Alternatively, transpositional combinatoriality is the lack of shared pitch classes between a hexachord and one or more of its transpositions. For example, 0 2 4 6 8 t, and its transposition up one semitone (+1): 1 3 5 7 9 e, have no notes in common.

Retrograde hexachordal combinatoriality is considered trivial, since any row has retrograde hexachordal combinatoriality with itself (''all'' tone rows have retrograde combinatoriality).

Inversional combinatoriality is a relationship between two rows, a principal row and its inversion. The principal row's first half, or six notes, are the inversion's last six notes, though not necessarily in the same order. Thus, the first half of each row is the other's [[Complement (set theory)|complement]]. The same conclusion applies to each row's second half as well. When combined, these rows still maintain a fully chromatic feeling and don't tend to reinforce certain pitches as tonal centers as might happen with freely combined rows. For example, the row from Schoenberg's ''Moses und Aron'', above contains: 0 1 4 5 6 7, this inverts to: 0 e 8 7 6 5, add three = 2 3 8 9 t e.
 01  4567     : 1st hexachord P0/2nd hexachord I3
   23    89te : 2nd hexachord P0/1st hexachord I3
 complete chromatic scale
Retrograde-inversional combinatoriality is a lack of shared pitches between the hexachords of a row and its retrograde-inversion.

Babbitt also described the semi-combinatorial row and the all-combinatorial row, the latter being a row which is combinatorial with any of its derivations and their transpositions.
{{anchor|Semi-combinatorial}}'''Semi-combinatorial''' sets are sets whose hexachords are capable of forming an aggregate with one of its basic transformations (R, I, RI) transposed. There are thirteen hexachords that are semi-combinatorial by inversion only. 
 (0)  0 1 2 3 4 6 // e t 9 8 7 5
 (1)  0 1 2 3 5 7 // e t 9 8 6 4
 (2)  0 1 2 3 6 7 // e t 9 8 5 4
 (3)  0 1 2 4 5 8 // e t 9 7 6 3
 (4)  0 1 2 4 6 8 // e t 9 7 5 3
 (5)  0 1 2 5 7 8 // e t 9 6 4 3
 (6)  0 1 3 4 6 9 // e t 8 7 5 2
 (7)  0 1 3 5 7 9 // e t 8 6 4 2
 (8)  0 1 3 5 8 9 // 7 6 4 2 e t
 (9)  0 1 3 6 7 9 // e t 8 5 4 2
 (10) 0 1 4 5 6 8 // 3 2 e t 9 7
 (11) 0 2 3 4 6 8 // 1 e t 9 7 5
 (12) 0 2 3 5 7 9 // 1 e t 8 6 4
Any hexachord which contains a zero in its [[interval vector]] possesses transpositional combinatoriality (in other words: to achieve combinatoriality a hexachord cannot be transposed by an interval equaling a note it contains). For example, there is one hexachord which is combinatorial by transposition (T6):
 (0) 0 1 3 4 5 8 // 6 7 9 t e 2
Neither hexachord contains tritones.

[[File:Stockhausen - Gruppen tone row.png|thumb|upright=1.3|''[[Gruppen]]''{{'}}s main first-order all-combinatorial tone row, though this property is not exploited compositionally in that work.<ref>[[Jonathan Harvey (composer)|Harvey, Jonathan]] (1975). ''The Music of Stockhausen'', pp. 56–58. {{ISBN|0-520-02311-0}}.</ref>[[File:Stockhausen - Gruppen tone row.mid]]]]
[[File:'Ode-to-Napoleon' hexachord.png|thumb|[["Ode-to-Napoleon" hexachord]]<ref>[[David Lewin]], "Re: Intervallic Relations Between Two Collections of Notes". ''[[Journal of Music Theory]]'' 3, no. 2 (November 1959): 298–301. p. 300.</ref> in [[set (music)|prime form]]<ref name="Toorn">Van den Toorn, Pieter C. (1996). ''Music, Politics, and the Academy'', pp. 128–129. {{ISBN|0-520-20116-7}}.</ref> One of Babbitt's six all-combinatorial hexachord "source sets".<ref name="Toorn"/>[[File:'Ode-to-Napoleon' hexachord.mid]]]]

{{anchor|All-combinatorial}}'''All-combinatorial''' sets are sets whose hexachords are capable of forming an aggregate with any of its basic transformations transposed.
There are six source sets, or basic hexachordally all-combinatorial sets, each hexachord of which may be reordered within itself:
 (A)  0 1 2 3 4 5 // 6 7 8 9 t e
 (B)  0 2 3 4 5 7 // 6 8 9 t e 1
 (C)  0 2 4 5 7 9 // 6 8 t e 1 3
 (D)  0 1 2 6 7 8 // 3 4 5 9 t e
 (E)  0 1 4 5 8 9 // 2 3 6 7 t e
 (F)  0 2 4 6 8 t // 1 3 5 7 9 e

Note: t = 10, e = 11.

Because the first three sets (''A'', ''B'', and ''C'') each satisfy all four criteria for just one transpositional value, set ''D'' satisfies them for two transpositional values, ''E'' for three values, and ''F'', for six transpositions, Babbitt designates these four groups as "first-order", "second-order", "third-order", and "sixth-order" all-combinatorial hexachords, respectively.<ref>[[John Rahn]], ''Basic Atonal Theory'', Longman Music Series (New York and London: Longman, 1980): 118.</ref> Notice that the first set, set "A," is the first six notes of an ascending chromatic scale, and that the last set, set "F," is a whole-tone scale.<ref>{{cite web |url=http://www.ramseycastaneda.com/music-theory/all-combinatorial-hexachords.html |title=All-Combinatorial Hexachords |last=Castaneda |first=Ramsey |date=March 2016 |access-date=1 June 2016}}</ref>

Combinatoriality may be used to create an [[chromatic scale|aggregate]] of all twelve tones, though the term often refers simply to combinatorial rows stated together.

'''Hexachordal combinatoriality''' is a concept in post-tonal theory that describes the combination of hexachords, often used in reference to the music of the [[Second Viennese school]]. In music that consistently utilizes all twelve chromatic tones (particularly twelve-tone and [[serial music]]), the aggregate (collection of all 12 pitch classes) may be divided into two hexachords (collections of 6 pitches). This breaks the aggregate into two smaller pieces, thus making it easier to sequence notes, progress between rows or aggregates, and combine notes and aggregates.

[[File:Schoenberg - Piano Piece op.33a tone row.png|thumb|center|400px|The principal forms, P1 and I6, of Schoenberg's ''Piano Piece'', op.&nbsp;33a, tone row feature hexachordal combinatoriality and contains three perfect fifths each, which is the relation between P1 and I6.<ref>{{cite book|last=Leeuw|first=Ton de|author-link=Ton de Leeuw|year=2005|title=Music of the Twentieth Century: A Study of Its Elements and Structure|pages=155–157|translator=Stephen Taylor|location=Amsterdam|publisher=Amsterdam University Press|isbn=90-5356-765-8}} Translation of ''Muziek van de twintigste eeuw: een onderzoek naar haar elementen en structuur''. Utrecht: Oosthoek, 1964. Third impression, Utrecht: Bohn, Scheltema & Holkema, 1977. {{ISBN|90-313-0244-9}}.</ref>[[File:Schoenberg - Piano Piece op.33a tone row.mid]]]]

Occasionally a hexachord may be combined with an inverted or transposed version of itself in a special case which will then result in the aggregate (complete set of 12 chromatic pitches).

A row (B{{Music|flat}}=0: 0 6 8 5 7 e 4 3 9 t 1 2) used by Schoenberg may be divided into two hexachords:
 B{{Music|flat}} E  F{{Music|sharp}} E{{Music|flat}} F  A // D  C{{Music|sharp}} G  G{{Music|sharp}} B  C

When you invert the first hexachord and transpose it, the following hexachord, a reordering of the second hexachord, results:
 G  C{{Music|sharp}} B  D  C  G{{Music|sharp}} = D  C{{Music|sharp}} G  G{{Music|sharp}} B  C

Thus, when you superimpose the original hexachord 1 (P0) over the transposed inversion of hexachord 1 (I9 in this case), the entire collection of 12 pitches results. If you continued the rest of the transposed, inverted row (I9) and superimposed original hexachord 2, you would again have the full complement of 12 chromatic pitches.

[[File:Schoenberg - Variations for Orchestra op. 31 tone row.png|thumb|center|upright=1.4|In Schoenberg's ''Variations for Orchestra'', Op. 31, tone row form P1's second half has the same notes, in a different order, as the first half of I10: "Thus it is possible to employ P1 and I10 simultaneously and in parallel motion without causing note doubling."{{sfn|Leeuw|2005|pp=154–155}}[[File:Schoenberg - Variations for Orchestra op. 31 tone row I10.mid]]]]

Hexachordal combinatoriality is closely related to the theory of the [[trope (music)|44 tropes]] created by [[Josef Matthias Hauer]] in 1921, although it seems that Hauer had no influence on Babbitt at all. Furthermore, there is little proof suggesting that Hauer had extensive knowledge about the inversional properties of the tropes earlier than 1942 at least.<ref>Diederichs, Joachim. Fheodoroff, Nikolaus. Schwieger, Johannes (eds.). 2007. ''Josef Matthias Hauer: Schriften, Manifeste, Dokumente'' 428–440. Vienna: Verlag Lafite</ref> The earliest records on combinatorial relations of hexachords, however, can be found amongst the theoretical writings of the Austrian composer and music theorist [[Othmar Steinbauer]].{{efn|Steinbauer (1895–1962) was a former student of Arnold Schoenberg and Josef Matthias Hauer. See [[:de:Othmar Steinbauer|Steinbauer article on de.wikipedia.org.]]}} He undertook elaborate studies on the trope system in the early 1930s which are documented in an unpublished typescript ''Klang- und Meloslehre'' (1932). Steinbauer's materials dated between 1932 and 1934 contain comprehensive data on combinatorial trichords, tetrachords and hexachords including semi-combinatorial and all-combinatorial sets. They may therefore be the earliest records in music history.<ref>Sedivy, Dominik. 2011. ''Serial Composition and Tonality. An Introduction to the Music of Hauer and Steinbauer'', p. 70. Vienna: edition mono/monochrom. {{ISBN|978-3-902796-03-5}}.
Sedivy, Dominik. 2012. ''Tropentechnik. Ihre Anwendung und ihre Möglichkeiten'', 258–264. Salzburger Stier 5. Würzburg: Königshausen & Neumann. {{ISBN|978-3-8260-4682-7}}</ref> A compilation of Steinbauer's morphological material has in parts become publicly available in 1960 with his script ''Lehrbuch der Klangreihenkomposition'' (author's edition) and was reprinted in 2001.<ref>Neumann, Helmut. 2001. ''Die Klangreihen-Kompositionslehre nach Othmar Steinbauer (1895–1962)'', 184–187, 201–213, 234–236. 2 vols.. Frankfurt et al.: Peter Lang</ref>