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Scale 1295: "Huyian"

Scale 1295: Huyian, Ian Ring Music Theory

Bracelet Diagram

The bracelet shows tones that are in this scale, starting from the top (12 o'clock), going clockwise in ascending semitones. The "i" icon marks imperfect tones that do not have a tone a fifth above. Dotted lines indicate axes of symmetry.

Tonnetz Diagram

Tonnetz diagrams are popular in Neo-Riemannian theory. Notes are arranged in a lattice where perfect 5th intervals are from left to right, major third are northeast, and major 6th intervals are northwest. Other directions are inverse of their opposite. This diagram helps to visualize common triads (they're triangles) and circle-of-fifth relationships (horizontal lines).

Common Names

Dozenal
Huyian

Analysis

Cardinality

Cardinality is the count of how many pitches are in the scale.

6 (hexatonic)

Pitch Class Set

The tones in this scale, expressed as numbers from 0 to 11

{0,1,2,3,8,10}

Forte Number

A code assigned by theorist Allen Forte, for this pitch class set and all of its transpositional (rotation) and inversional (reflection) transformations.

6-9

Rotational Symmetry

Some scales have rotational symmetry, sometimes known as "limited transposition". If there are any rotational symmetries, these are the intervals of periodicity.

none

Reflection Axes

If a scale has an axis of reflective symmetry, then it can transform into itself by inversion. It also implies that the scale has Ridge Tones. Notably an axis of reflection can occur directly on a tone or half way between two tones.

none

Palindromicity

A palindromic scale has the same pattern of intervals both ascending and descending.

no

Chirality

A chiral scale can not be transformed into its inverse by rotation. If a scale is chiral, then it has an enantiomorph.

yes
enantiomorph: 3605

Hemitonia

A hemitone is two tones separated by a semitone interval. Hemitonia describes how many such hemitones exist.

3 (trihemitonic)

Cohemitonia

A cohemitone is an instance of two adjacent hemitones. Cohemitonia describes how many such cohemitones exist.

2 (dicohemitonic)

Imperfections

An imperfection is a tone which does not have a perfect fifth above it in the scale. This value is the quantity of imperfections in this scale.

3

Modes

Modes are the rotational transformations of this scale. This number does not include the scale itself, so the number is usually one less than its cardinality; unless there are rotational symmetries then there are even fewer modes.

5

Prime Form

Describes if this scale is in prime form, using the Rahn/Ring formula.

no
prime: 175

Generator

Indicates if the scale can be constructed using a generator, and an origin.

none

Deep Scale

A deep scale is one where the interval vector has 6 different digits.

no

Interval Structure

Defines the scale as the sequence of intervals between one tone and the next.

[1, 1, 1, 5, 2, 2]

Interval Vector

Describes the intervallic content of the scale, read from left to right as the number of occurences of each interval size from semitone, up to six semitones.

<3, 4, 2, 2, 3, 1>

Interval Spectrum

The same as the Interval Vector, but expressed in a syntax used by Howard Hanson.

p3m2n2s4d3t

Distribution Spectra

Describes the specific interval sizes that exist for each generic interval size. Each generic <g> has a spectrum {n,...}. The Spectrum Width is the difference between the highest and lowest values in each spectrum.

<1> = {1,2,5}
<2> = {2,3,4,6,7}
<3> = {3,4,5,7,8,9}
<4> = {5,6,8,9,10}
<5> = {7,10,11}

Spectra Variation

Determined by the Distribution Spectra; this is the sum of all spectrum widths divided by the scale cardinality.

4

Maximally Even

A scale is maximally even if the tones are optimally spaced apart from each other.

no

Maximal Area Set

A scale is a maximal area set if a polygon described by vertices dodecimetrically placed around a circle produces the maximal interior area for scales of the same cardinality. All maximally even sets have maximal area, but not all maximal area sets are maximally even.

no

Interior Area

Area of the polygon described by vertices placed for each tone of the scale dodecimetrically around a unit circle, ie a circle with radius of 1.

1.866

Polygon Perimeter

Perimeter of the polygon described by vertices placed for each tone of the scale dodecimetrically around a unit circle.

5.485

Myhill Property

A scale has Myhill Property if the Interval Spectra has exactly two specific intervals for every generic interval.

no

Balanced

A scale is balanced if the distribution of its tones would satisfy the "centrifuge problem", ie are placed such that it would balance on its centre point.

no

Ridge Tones

Ridge Tones are those that appear in all transpositions of a scale upon the members of that scale. Ridge Tones correspond directly with axes of reflective symmetry.

none

Propriety

Also known as Rothenberg Propriety, named after its inventor. Propriety describes whether every specific interval is uniquely mapped to a generic interval. A scale is either "Proper", "Strictly Proper", or "Improper".

Improper

Heteromorphic Profile

Defined by Norman Carey (2002), the heteromorphic profile is an ordered triple of (c, a, d) where c is the number of contradictions, a is the number of ambiguities, and d is the number of differences. When c is zero, the scale is Proper. When a is also zero, the scale is Strictly Proper.

(29, 19, 65)

Common Triads

These are the common triads (major, minor, augmented and diminished) that you can create from members of this scale.

* Pitches are shown with C as the root

Triad TypeTriad*Pitch ClassesDegreeEccentricityCloseness Centrality
Major TriadsG♯{8,0,3}000

The following pitch classes are not present in any of the common triads: {1,2,10}

Since there is only one common triad in this scale, there are no opportunities for parsimonious voice leading between triads.

Modes

Modes are the rotational transformation of this scale. Scale 1295 can be rotated to make 5 other scales. The 1st mode is itself.

2nd mode:
Scale 2695
Scale 2695: Rakian, Ian Ring Music TheoryRakian
3rd mode:
Scale 3395
Scale 3395: Vepian, Ian Ring Music TheoryVepian
4th mode:
Scale 3745
Scale 3745: Xuvian, Ian Ring Music TheoryXuvian
5th mode:
Scale 245
Scale 245: Raga Dipak, Ian Ring Music TheoryRaga Dipak
6th mode:
Scale 1085
Scale 1085: Gozian, Ian Ring Music TheoryGozian

Prime

The prime form of this scale is Scale 175

Scale 175Scale 175: Bewian, Ian Ring Music TheoryBewian

Complement

The hexatonic modal family [1295, 2695, 3395, 3745, 245, 1085] (Forte: 6-9) is the complement of the hexatonic modal family [175, 1505, 1925, 2135, 3115, 3605] (Forte: 6-9)

Inverse

The inverse of a scale is a reflection using the root as its axis. The inverse of 1295 is 3605

Scale 3605Scale 3605: Olkian, Ian Ring Music TheoryOlkian

Enantiomorph

Only scales that are chiral will have an enantiomorph. Scale 1295 is chiral, and its enantiomorph is scale 3605

Scale 3605Scale 3605: Olkian, Ian Ring Music TheoryOlkian

Transformations:

In the abbreviation, the subscript number after "T" is the number of semitones of tranposition, "M" means the pitch class is multiplied by 5, and "I" means the result is inverted. Operation is an identical way to express the same thing; the syntax is <a,b> where each tone of the set x is transformed by the equation y = ax + b

Abbrev Operation Result Abbrev Operation Result
T0 <1,0> 1295       T0I <11,0> 3605
T1 <1,1> 2590      T1I <11,1> 3115
T2 <1,2> 1085      T2I <11,2> 2135
T3 <1,3> 2170      T3I <11,3> 175
T4 <1,4> 245      T4I <11,4> 350
T5 <1,5> 490      T5I <11,5> 700
T6 <1,6> 980      T6I <11,6> 1400
T7 <1,7> 1960      T7I <11,7> 2800
T8 <1,8> 3920      T8I <11,8> 1505
T9 <1,9> 3745      T9I <11,9> 3010
T10 <1,10> 3395      T10I <11,10> 1925
T11 <1,11> 2695      T11I <11,11> 3850
Abbrev Operation Result Abbrev Operation Result
T0M <5,0> 1085      T0MI <7,0> 1925
T1M <5,1> 2170      T1MI <7,1> 3850
T2M <5,2> 245      T2MI <7,2> 3605
T3M <5,3> 490      T3MI <7,3> 3115
T4M <5,4> 980      T4MI <7,4> 2135
T5M <5,5> 1960      T5MI <7,5> 175
T6M <5,6> 3920      T6MI <7,6> 350
T7M <5,7> 3745      T7MI <7,7> 700
T8M <5,8> 3395      T8MI <7,8> 1400
T9M <5,9> 2695      T9MI <7,9> 2800
T10M <5,10> 1295       T10MI <7,10> 1505
T11M <5,11> 2590      T11MI <7,11> 3010

The transformations that map this set to itself are: T0, T10M

Nearby Scales:

These are other scales that are similar to this one, created by adding a tone, removing a tone, or moving one note up or down a semitone.

Scale 1293Scale 1293: Huxian, Ian Ring Music TheoryHuxian
Scale 1291Scale 1291: Huwian, Ian Ring Music TheoryHuwian
Scale 1287Scale 1287: Hutian, Ian Ring Music TheoryHutian
Scale 1303Scale 1303: Epolimic, Ian Ring Music TheoryEpolimic
Scale 1311Scale 1311: Bynian, Ian Ring Music TheoryBynian
Scale 1327Scale 1327: Zalian, Ian Ring Music TheoryZalian
Scale 1359Scale 1359: Aerygian, Ian Ring Music TheoryAerygian
Scale 1423Scale 1423: Doptian, Ian Ring Music TheoryDoptian
Scale 1039Scale 1039: Gixian, Ian Ring Music TheoryGixian
Scale 1167Scale 1167: Aerodimic, Ian Ring Music TheoryAerodimic
Scale 1551Scale 1551: Jorian, Ian Ring Music TheoryJorian
Scale 1807Scale 1807: Larian, Ian Ring Music TheoryLarian
Scale 271Scale 271: Bodian, Ian Ring Music TheoryBodian
Scale 783Scale 783: Etuian, Ian Ring Music TheoryEtuian
Scale 2319Scale 2319: Oduian, Ian Ring Music TheoryOduian
Scale 3343Scale 3343: Vajian, Ian Ring Music TheoryVajian

This scale analysis was created by Ian Ring, Canadian Composer of works for Piano, and total music theory nerd. Scale notation generated by VexFlow, graph visualization by Graphviz, and MIDI playback by MIDI.js. All other diagrams and visualizations are © Ian Ring. Some scale names used on this and other pages are ©2005 William Zeitler (http://allthescales.org) used with permission.

Pitch spelling algorithm employed here is adapted from a method by Uzay Bora, Baris Tekin Tezel, and Alper Vahaplar. (An algorithm for spelling the pitches of any musical scale) Contact authors Patent owner: Dokuz Eylül University, Used with Permission. Contact TTO

Tons of background resources contributed to the production of this summary; for a list of these peruse this Bibliography. Special thanks to Richard Repp for helping with technical accuracy, and George Howlett for assistance with the Carnatic ragas.