MOS diagrams: Difference between revisions
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*[[Joe Monzo]]'s helixes could also be of use here... | *[[Joe Monzo]]'s helixes could also be of use here... | ||
[[Category:mos]] | [[Category:mos]] | ||
== L and s == | |||
The mechanics of scale generation are such that — when iterating from one scale to the next densest one — all large steps in the preceding scale become one large step and one small step in the new scale. | |||
Another way to think about this is that a small-step-sized chunk has been split off of each of the former large steps. The remainder can be either larger or smaller than the small step | |||
* If it is larger, then it stays the large step. | |||
* If it is smaller, then it becomes the new small step, and everything that used to be a small step is now a large step. | |||
[[File:MOS iteration rules for L and s.png|452x452px]] | |||
We are reasoning about MOS concepts in the abstract here. These truths about large and small steps are true whether they are 100¢ or 4516.8¢, and all we really care about are their ratios. So if we treat our small steps’ size as <span><math>1</math></span> then we can treat our large steps’ size as equal to the <span><math>L{:}s</math></span> ratio. | |||
So the <span><math>L{:}s</math></span> ratio decreases by <span><math>1</math></span> because if an <span><math>s</math></span>-sized chunk has been sliced off <span><math>L</math></span>, and <span><math>s</math></span>’s size is <span><math>1</math></span>, then <span><math>1</math></span> should be subtracted from <span><math>L</math></span>. | |||
When <span><math>L - s > s</math></span>: | |||
<math> | |||
\begin{align} | |||
L’{:}s’ &= (L - s){:}s \\ | |||
&= (L - 1){:}1 \\ | |||
&= L - 1 | |||
\end{align} | |||
</math> | |||
When <span><math>L - s < s</math></span>, the result is simply reciprocated: | |||
<math> | |||
\begin{align} | |||
L’{:}s’ &= s{:}(L - s) \\ | |||
&= 1{:}(L - 1) \\ | |||
&= \frac{1}{L - 1} | |||
\end{align} | |||
</math> | |||
Revision as of 20:54, 10 February 2020
The moment-of-symmetry process of unfolding a scale takes, for most people, a conceptual leap or two. Below are visualizations of the process:
- From the Wilson Archives on Kraig Grady's [Anaphoria.com:
- The first set of 32 horograms.
- The Scale Tree is the basis of the horograms.
- Moments of Symmetry, of Equal Divisions of the Octave.
- From David Finnamore's Elevenminstrel.com: 5- To 9-Tone, Octave-Repeating Scales From Wilson's Golden Horagrams of the Scale Tree.
- Charles Lucy describes a technique involving dis-continuous chains of fifths (i.e. skipping some).
- Joe Monzo's helixes could also be of use here...
L and s
The mechanics of scale generation are such that — when iterating from one scale to the next densest one — all large steps in the preceding scale become one large step and one small step in the new scale.
Another way to think about this is that a small-step-sized chunk has been split off of each of the former large steps. The remainder can be either larger or smaller than the small step
- If it is larger, then it stays the large step.
- If it is smaller, then it becomes the new small step, and everything that used to be a small step is now a large step.
We are reasoning about MOS concepts in the abstract here. These truths about large and small steps are true whether they are 100¢ or 4516.8¢, and all we really care about are their ratios. So if we treat our small steps’ size as [math]\displaystyle{ 1 }[/math] then we can treat our large steps’ size as equal to the [math]\displaystyle{ L{:}s }[/math] ratio.
So the [math]\displaystyle{ L{:}s }[/math] ratio decreases by [math]\displaystyle{ 1 }[/math] because if an [math]\displaystyle{ s }[/math]-sized chunk has been sliced off [math]\displaystyle{ L }[/math], and [math]\displaystyle{ s }[/math]’s size is [math]\displaystyle{ 1 }[/math], then [math]\displaystyle{ 1 }[/math] should be subtracted from [math]\displaystyle{ L }[/math].
When [math]\displaystyle{ L - s > s }[/math]:
[math]\displaystyle{ \begin{align} L’{:}s’ &= (L - s){:}s \\ &= (L - 1){:}1 \\ &= L - 1 \end{align} }[/math]
When [math]\displaystyle{ L - s < s }[/math], the result is simply reciprocated:
[math]\displaystyle{ \begin{align} L’{:}s’ &= s{:}(L - s) \\ &= 1{:}(L - 1) \\ &= \frac{1}{L - 1} \end{align} }[/math]