Generator sequence: Difference between revisions
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Certain [[generator-offset property|generator-offset]] scales are examples. For example, [[diasem]] is AGS(8/7, 7/6) or AGS(7/6, 8/7) depending on [[chirality]]. The trivial case AGS(x) is stacking a single generator x to make a rank-2 scale, such as a [[MOS scale]]. | Certain [[generator-offset property|generator-offset]] scales are examples. For example, [[diasem]] is AGS(8/7, 7/6) or AGS(7/6, 8/7) depending on [[chirality]]. The trivial case AGS(x) is stacking a single generator x to make a rank-2 scale, such as a [[MOS scale]]. | ||
When all generators x<sub>i</sub> in the AGS recipe AGS(x<sub>1</sub>, ..., x<sub>r</sub>) | When all generators x<sub>i</sub> in the AGS recipe AGS(x<sub>1</sub>, ..., x<sub>r</sub>) [[subtend]] the same number of steps, we call the resulting scale ''well-formed AGS''. In such a situation, we call the (logarithmic) average of the generators the ''guide generator'', and the leftover interval after stacking ''n'' − 1 of the generators in the recipe (analogous to the imperfect generator in [[MOS]] scales) must also subtend this number of steps. | ||
== AGS scale series == | == AGS scale series == | ||
Revision as of 04:42, 23 July 2023
Generator sequence (AGS) is a scale-building procedure first described by Scott Dakota. The notation AGS(x1, ..., xr) denotes a scale-building procedure where a (periodic) scale is built by stacking x1 first, x2 second, ..., reducing by the scale's equave when necessary. When xr is stacked, we go back to x1 and start stacking x1 again, then x2, ... Currently, the study of AGSs is dominated by constant structure AGS scales, which are obtained by stopping the stacking procedure at scale sizes that yield constant-structure scales.
Certain generator-offset scales are examples. For example, diasem is AGS(8/7, 7/6) or AGS(7/6, 8/7) depending on chirality. The trivial case AGS(x) is stacking a single generator x to make a rank-2 scale, such as a MOS scale.
When all generators xi in the AGS recipe AGS(x1, ..., xr) subtend the same number of steps, we call the resulting scale well-formed AGS. In such a situation, we call the (logarithmic) average of the generators the guide generator, and the leftover interval after stacking n − 1 of the generators in the recipe (analogous to the imperfect generator in MOS scales) must also subtend this number of steps.
AGS scale series
Only CS sizes at least 5 are listed.
- The Zarlino series, AGS(5/4, 6/5): 5, 7, 10, 17, 24, 41 and 65-forms.
- Other scales with the same AGS structure of two thirds adding up to 3/2 share the same CS sizes, including undecimal Zarlino (AGS(11/9, 27/22)), and Neogothic Zarlino (AGS(14/11, 13/11) with 364/363 tempered), although the latter may break at higher sizes depending on how the intervals are tuned.
- The Tas/diasem series, AGS(7/6, 8/7): 5, 9, 14, 19, 24, and 29-forms
- The Tri-Stone series, AGS(3/2, 14/9): 5, 8, 13, and 18-forms.
- The Zil series, AGS(8/7, 7/6, 8/7, 7/6, 8/7, 7/6, 8/7, 189/160, 8/7, 7/6): 5, 9, 14, 19, and 24-forms.
- The Porcusmine series, AGS(9/5, 50/27): 5, 6, 7, 8, 15, 23, 38, 61, and 99-forms.
- An unnamed 5-limit Mavila detemper, AGS(3/2, 3/2, 64/45): 5, 7, 9, 16, and 25-forms.
- The Rhombi series, AGS(14/9, 11/7, 52/33, 81/52): 5, 8, 11, 14, 17, 31, 48, and 65-forms.
- The Dwyn series: AGS(25/24 21/20 22/21 23/22 24/23 21/20 22/21 23/22 24/23): 15, 16, 31, and 46-forms.
Conjectures about AGS scales
- If S is a monotonic well-formed AGS scale, then it is generically constant structure.
- Let n be the cardinality of a constant structure well-formed AGS scale S with equave E. Then n is the cardinality of an E-equivalent primitive MOS generated by the guide generator of S.