User:Inthar/Epimorphic temperament: Difference between revisions

(12 intermediate revisions by the same user not shown)

Line 1:

An '''epimorphic temperament''' of an [[epimorphic]] scale ''S'' on a JI group ''A'' is a temperament supported by its [[epimorphic val]] (linear map ''v'': ''A'' → ℤ such that ''v''(''S''[''i'']) = ''i'') on ''G''. Some [[exotemperament]]s (including vals for small edos) can be used as epimorphic temperaments for small CS scales:

* The 2.3.5 temperament [[dicot]] supports [[nicetone]] (3L2M2s), [[blackdye]] (5L2M3s) and superzarlino (a 17-form) scale structures.

* The 2.3.7 temperament [[semaphore]] supports [[archylino]] (2L3M2s), [[diasem]] (5L2M2s), and other scales in the [[Tas series]].

~~== Facts ==~~

~~=== Definition: constant structure (CS) ===~~

Given a periodic scale ''S'', let <math>C_k</math> be the set of ''k''-steps of ''S''. Then ''S'' is ''constant structure'' (CS) if for any <math>i, j \in \mathbb{Z}</math> we have <math>C_i \cap C_j = \varnothing.</math>

~~=== If the steps of a CS scale are linearly independent, then the scale is epimorphic ===~~

Theorem: Suppose ''S'' is a 2/1-equivalent increasing constant structure JI scale of length ''n''. Let <math>C_1</math> be the set of 1-steps of ''S'', and suppose that <math>C_1</math> is a ''basis'' for the JI group ''A'' generated by it. Then there exists an epimorphic val <math> v: A \to \mathbb{Z}</math> which is a val of ''n''-edo (and a similar statement holds for other equaves).

~~the condition of linear independence cannot be omitted, since otherwise the scale {5/4, 32/25, 2/1} is a counterexample.~~

~~{{proof|contents=~~

Define <math>v:A \to \mathbb{Z}</math> by defining <math>v(\mathbf{s}) = 1</math> for any step <math>\mathbf{s} \in C_1</math> and extending uniquely by linearity. Then for any <math>i \in \mathbb{Z}</math> we have

~~<math>v(S[i]) = v(S[i]/S[i-1]\cdots S[1]) = v(S[i]/S[i-1]) + \cdots + v(S[1]) = i.</math>~~

~~That <math>v(2) = n</math> is also automatic.~~

}}

~~=== Epimorphic scales are CS ===~~

@@ Line 1: / Line 1: @@
-An '''epimorphic temperament''' of an [[epimorphic]] scale ''S'' on a JI group ''A'' is a temperament supported by its [[epimorphic val]] (linear map ''v'': ''A'' → ℤ such that ''v''(''S''[''i'']) = ''i'') on ''G''. Some [[exotemperament]]s (including vals for small edos) can be used as epimorphic temperaments for small CS scales:
-* The 2.3.5 temperament [[dicot]] supports [[nicetone]] (3L2M2s), [[blackdye]] (5L2M3s) and superzarlino (a 17-form) scale structures.
-* The 2.3.7 temperament [[semaphore]] supports [[archylino]] (2L3M2s), [[diasem]] (5L2M2s), and other scales in the [[Tas series]].
-== Facts ==
-=== Definition: constant structure (CS) ===
-Given a periodic scale ''S'', let <math>C_k</math> be the set of ''k''-steps of ''S''. Then ''S'' is ''constant structure'' (CS) if for any <math>i, j \in \mathbb{Z}</math> we have <math>C_i \cap C_j = \varnothing.</math>
-=== If the steps of a CS scale are linearly independent, then the scale is epimorphic ===
-Theorem: Suppose ''S'' is a 2/1-equivalent increasing constant structure JI scale of length ''n''. Let <math>C_1</math> be the set of 1-steps of ''S'', and suppose that <math>C_1</math> is a ''basis'' for the JI group ''A'' generated by it. Then there exists an epimorphic val <math> v: A \to \mathbb{Z}</math> which is a val of ''n''-edo (and a similar statement holds for other equaves).
-the condition of linear independence cannot be omitted, since otherwise the scale {5/4, 32/25, 2/1} is a counterexample.
-{{proof|contents=
-Define <math>v:A \to \mathbb{Z}</math> by defining <math>v(\mathbf{s}) = 1</math> for any step <math>\mathbf{s} \in C_1</math> and extending uniquely by linearity. Then for any <math>i \in \mathbb{Z}</math> we have
-<math>v(S[i]) = v(S[i]/S[i-1]\cdots S[1]) = v(S[i]/S[i-1]) + \cdots + v(S[1]) = i.</math>
-That <math>v(2) = n</math> is also automatic.
-}}
-=== Epimorphic scales are CS ===