SN scale: Difference between revisions
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A '''step-nested scale''', '''SN scale''', or '''SNS''' is a scale generated through iteratively performing the following two moves: | |||
A | |||
a) | a) Add a new smaller step at the top or bottom of every existing step, or | ||
b) | b) Add the existing smallest step at the top or bottom of every larger step: i.e. replacing '''x''' with '''xs''' or '''sx''' for every occurrence of any step '''x''' such that '''x''' > '''s''' at the current stage, where '''s''' is the current smallest step. | ||
Each iteration of a) | Each iteration of a) increases the rank of the scale by 1. <!-- In any of the steps, "bottom" may be replaced with "top", but the choice of "bottom" and "top" must be consistent. Todo: Prove this or find relevant literature on episturmian words to clarify this.--> | ||
An SN scale of rank 2, a 2-SN scale, is a [[MOS scale]]. Accordingly, SN scales are a generalization of MOS scales into arbitrary rank. [[ | An SN scale of rank 2, a 2-SN scale, is a [[MOS scale]]. Accordingly, SN scales are a generalization of MOS scales into arbitrary rank. [[Equal division]]s are rank-1 SN scales, which can be generated by applying a) once, introducing a step of a single degree of the ET. | ||
SN scales are [[chirality|mirror-symmetric]], and may be uniquely defined by a ''step signature'' - a generalization of the MOS signature into arbitrary rank. | SN scales are [[chirality|mirror-symmetric]], and may be uniquely defined by a ''step signature'' - a generalization of the MOS signature into arbitrary rank. | ||
==Examples == | == Examples == | ||
The diatonic scale can be generated by iterating a) twice, introducing first the octave, then the perfect fifth, and then iterating b) 3 times. It has step signature 5'''L'''2'''s''', and in the symmetric mode, it has step arrangement '''LsLLLsL'''. No other arrangement of 5 large and 2 small step sizes results in a SN scale. | |||
The double harmonic scale can be generated by iterating a) three times, introducing first the octave, then the fifth, then the major third, leading to a major seven tetrad, and then applying b) once. It has step signature | {| class="wikitable" | ||
|+ Producing the diatonic MOS via the SNS procedure | |||
|- | |||
! Stage !! Move !! Scale (Cumulative form) !! Smallest step !! Step signature !! Word !! Visualization | |||
|- | |||
! 1 | |||
|| a): add '''a''' | |||
|| {1/1, 2/1} || 2/1 = '''a''' || 1'''a''' || '''a''' || {{step vis|53 }}┤ | |||
|- | |||
! 2 | |||
|| a): add '''b''' | |||
|| {1/1, '''3/2''', 2/1} || 4/3 = '''a''' || 1'''a'''1'''b''' || '''ba''' || {{step vis|31 22}} | |||
|- | |||
! 3 | |||
|| b): '''b''' → '''ab''' | |||
|| {1/1, '''4/3''', 3/2, 2/1} || 9/8 = '''b''' || 2'''a'''1'''b''' || '''aba''' || {{step vis|22 9 22}} | |||
|- | |||
! 4 | |||
|| b): '''a''' → '''ba''' | |||
|| {1/1, '''9/8''', 4/3, 3/2, '''27/16''', 2/1} || 9/8 = '''b''' || 2'''a'''3'''b''' || '''babba''' || {{Step vis|9 13 9 9 13}} | |||
|- | |||
! 5 | |||
|| b): '''a''' → '''ba''' | |||
|| {1/1, 9/8, '''81/64''', 4/3, 3/2, 27/16, '''243/128''', 2/1} || 256/243 = '''a''' || 2'''a'''5'''b''' || '''bbabbba''' || {{Step vis|9 9 4 9 9 9 4}} | |||
|} | |||
MET-24 can be generated from the diatonic scale by iterating b) once more, and then applying a), introducing a quarter-tone type step. It has step signature 5'''L'''12'''M'''7'''s'''. A capital '''M''' specifies that the size of the medium step is closer to the size of the large step than to the size of the small step. A lower case '''m''' would specify the opposite. We may write the signature alternatively as (5,12,7). | |||
The double harmonic scale can be generated by iterating a) three times, introducing first the octave, then the fifth, then the major third, leading to a major seven tetrad, and then applying b) once. It has step signature 2'''L'''1'''M'''4'''s''', and in the symmetric mode, it has step arrangement '''sLsMsLs'''. | |||
For more examples of 3-SN scales, see [[Gallery of 3-SN scales]]. | For more examples of 3-SN scales, see [[Gallery of 3-SN scales]]. | ||
The simplest 4-SN scale is generated by iterating a) 4 times, leading to the scale abacabad. If we map the intervals introduced with a) as 2/1, 3/2, 7/6, and 15/14, we get the scale 15/14 7/6 5/4 3/2 45/28 7/4 15/8 2/1, with step signature (1,2,4,1), mapped to (6/5, 7/6, 15/14, 16/15). | The simplest 4-SN scale is generated by iterating a) 4 times, leading to the scale abacabad. If we map the intervals introduced with a) as 2/1, 3/2, 7/6, and 15/14, we get the scale 15/14 7/6 5/4 3/2 45/28 7/4 15/8 2/1, with step signature (1,2,4,1), mapped to (6/5, 7/6, 15/14, 16/15). | ||
== | == Denoting SN scales == | ||
Where the [[Meantone]] tempered diatonic scale can be | Where the [[Meantone]] tempered diatonic scale can be denoted Meantone[7], we may instead describe it through its derivation as an SN scale through denoting it (2/1, 3/2: 81/80)[7], which specifies that a) introduces the intervals 2/1 and 3/2, and then b) is applied until a 7-note scale is reached, and that 81/80 is tempered out in the scale. | ||
The scale SNS (2/1, 3/2, 5/4: 225/224)[7] describes a [[Marvel]] tempered double harmonic scale, with step signatures (2,1,4) mapped to (~7/6, ~9/8, 16/15~15/14). | The scale SNS (2/1, 3/2, 5/4: 225/224)[7] describes a [[Marvel]] tempered double harmonic scale, with step signatures (2,1,4) mapped to (~7/6, ~9/8, 16/15~15/14). | ||
MET-24, as a (2.3.7.11.13) Parapyth tempered scale can be | MET-24, as a (2.3.7.11.13) Parapyth tempered scale can be denoted ((2/1, 3/2)[12], 28/27~33/32: 352/351, 364/363))[24] (the simplest basis set for commas tempered out is chosen to specify the temperament), with step signatures (5, 12, 7) mapped to (~27/26, 28/27~33/32, ~64/63). | ||
== | == Algorithm == | ||
The above scales all have a period of an octave - and therefore a) first introduces the interval of an octave, however, the period of an SN scale, as with the mapping of any new smallest step introduced, is arbitrary. | The above scales all have a period of an octave - and therefore a) first introduces the interval of an octave, however, the period of an SN scale, as with the mapping of any new smallest step introduced, is arbitrary. | ||
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SN scales are based on epi-Christoffel words form combinatorics, which generalize finite Sturmian words. Finite Sturmian words are equivalent to well-formed scales, and equivalently equivalent to MOS scales that are not ''Multi-MOS'' scales, wich are MOS scales of more than one period, typically with a period that divides the octave evenly. The algorithm for generating SN scales introduced above is equivalent to the two epi-Sturmian morphisms that generate epi-Christoffel words. | SN scales are based on epi-Christoffel words form combinatorics, which generalize finite Sturmian words. Finite Sturmian words are equivalent to well-formed scales, and equivalently equivalent to MOS scales that are not ''Multi-MOS'' scales, wich are MOS scales of more than one period, typically with a period that divides the octave evenly. The algorithm for generating SN scales introduced above is equivalent to the two epi-Sturmian morphisms that generate epi-Christoffel words. | ||
To find the step arrangement of an ''r''-SN scale for arbitrary step sizes treated as letters of alphabet size ''r'', we iteratively apply the epi-Sturmian moprhism M in which a particular letter from the alphabet is added before each incidence of a different letter. To uncover the order of letters associated with the iterated application of the morphism we follow an algorithm T in which, from incidences (''X''1, ''X''2, ..., '' | To find the step arrangement of an ''r''-SN scale for arbitrary step sizes treated as letters of alphabet size ''r'', we iteratively apply the epi-Sturmian moprhism ''M'' in which a particular letter from the alphabet is added before each incidence of a different letter. To uncover the order of letters associated with the iterated application of the morphism we follow an algorithm T in which, from incidences (''X''<sub>1</sub>, ''X''<sub>2</sub>, ..., ''X''<sub>r</sub> ) of arbitrary letters '''S<sub>1</sub>''', '''S<sub>2</sub>''', ..., and '''S<sub>r</sub>''' respectively, we subtract from the highest incidence value the sum of all other incidence values: | ||
Iteratively applying T to (10,5,2) as an example: | Iteratively applying T to (10,5,2) as an example: | ||
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(10,5,2)->(3,5,2)->(3,0,2)->(1,0,2)->(1,0,1)->(0,0,1) | (10,5,2)->(3,5,2)->(3,0,2)->(1,0,2)->(1,0,1)->(0,0,1) | ||
In the last step, since both '''S<sub>1</sub>''' and '''S<sub>3</sub>''' have the same incidence value, we can pick either of them to subtract from (in this case, '''S<sub>1</sub>'''). | |||
We list in order the letter with the highest incidence in each step (relabeling '''S<sub>1</sub>''', '''S<sub>2</sub>''', and '''S<sub>3</sub>''' as '''a''', '''b''', and '''c''' respectively): '''abacac''' | |||
M''abaca''(''c'') = M''abac''(''ac'') = M''aba''(''cac'') = M''ab''(''acaac'') = M''a''(''babcbababc'') = ''abaabacabaabaabac''. | To generate the word, we apply ''M''<sub>'''abaca'''</sub>('''c'''). We proceed: | ||
''M''<sub>'''abaca'''</sub>('''c''') = ''M''<sub>'''abac'''</sub>('''ac''') = ''M''<sub>'''aba'''</sub>('''cac''') = ''M''<sub>'''ab'''</sub>('''acaac''') = ''M''<sub>'''a'''</sub>('''babcbababc''') = '''abaabacabaabaabac'''. | |||
We can then apply mappings to the step sizes to defined the word as a scale. | We can then apply mappings to the step sizes to defined the word as a scale. | ||
If at any point in the application of T a negative number is reached, that combination of step incidences does not correspond to an SN scale. Accordingly, though for rank-2, any possible step signature corresponds to an SN scale, for higher ranks only a small portion of possible step signatures correspond to SN scales. The step signature (2,2,3), for example, does not correspond to an SN scale, as the iterative application of T leads to a negative number, i.e., (2,2,3)->(2,2,-1). | If at any point in the application of T a negative number is reached, that combination of step incidences does not correspond to an SN scale. Accordingly, though for rank-2, any possible step signature corresponds to an SN scale, for higher ranks only a small portion of possible step signatures correspond to SN scales. The step signature (2,2,3), for example, does not correspond to an SN scale, as the iterative application of T leads to a negative number, i.e., (2,2,3)->(2,2,-1). | ||
TODO: Prove that this algorithm yields the same result as the first definition given. | |||
== Step-nested differential scales == | == Step-nested differential scales == | ||
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SNDS ((2/1, 3/2)[5], ''x''))[10] - (2/1, 3/2)[5] = SNS (2/1, 3/2)[5] (dipentatonic SNS) | SNDS ((2/1, 3/2)[5], ''x''))[10] - (2/1, 3/2)[5] = SNS (2/1, 3/2)[5] (dipentatonic SNS) | ||
[[Category: | |||
[[Category:Scale]] | |||
[[Category:MOS scale]] | [[Category:MOS scale]] | ||