MOS scale
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=MOS scales= An important class of scales are MOS scales (the acronym MOS from "Moment of symmetry"). These are derived by iterating a interval g, called the generator, inside a larger interval, called the period, and reducing to the period when the iterates become larger than the period. Usually the period is an octave or an nth root of 2, but it can in theory be any positive number. The resulting scale is called a MOS when it has exactly two sizes of steps when sorted into ascending order of size. The term and scale construction method were invented by Erv Wilson. His original paper can be found here [[http://anaphoria.com/mos.PDF]]. There is also an introduction [[http://anaphoria.com/wilsonintroMOS.html]]. It generalizes the classical diatonic and pentatonic scales. ==Theory of MOS== Let us represent the period as 1. This would be the logarithm base 2 of 2 if the period is an octave, or in general we can measure intervals by the log base P when P is the period. Suppose the fractions a/b and c/d are a [[http://en.wikipedia.org/wiki/Farey_sequence#Sequence_length|Farey pair]], meaning that a/b < c/d and bc - ad = 1. If g = (1-t)(a/b) + t(c/d) for 0 <= t <= 1, then when t = 0, the scale generated by g will consist of an equal division of 1 (representing P) into steps of size 1/b, and when t = 1 into steps of size 1/d. In between, when t = b/(b + d), we obtain a generator equal to the [[http://en.wikipedia.org/wiki/Mediant_%28mathematics%29|mediant]] (a + c)/(b + d) and which will divide the period into b+d equal steps. For all other values a/b < g < c/d we obtain two different sizes of steps, the small steps s, and the large steps L, with the total number of steps b+d, and these scales are the MOS associated to the Farey pair. ==Classification of MOS== An obvious first rough classification of MOS scales is given by the number of elements of the scale - the number of large intervals (L) and the number of small intervals (s). E.g., the diatonic scale in 12-tone equal temperament could be described as [[5L 2s]] (5 large steps and 2 small steps). Since numbers tend to be dry, Graham Breed has proposed a [[MOSNamingScheme|naming scheme for MOS scales]]. ==MOS in equal temperaments== In the special case of an equal temperament, more concrete things about MOS can be stated. In an equal temparement, all intervals - and hence also the intervals L and s - are integer multiples of a smallest unit. (Example: in case of the diatonic scale in 12EDO, L would be 2 and s 1.) If we have an arbitrary MOS scale in an n-tone equal temperament, with a steps of size L and b steps of size s, there holds a*L +b*s = n. which is a linear diophantine equation! This means that given a, b and n, all possible MOS types can be calculated via the general solution of the corresponding linear diophantine equation. Below is a list of MOS with number of elements from 5 to 10, in equal temperaments up to 36. Not all mathematical possibilities are listed - solutions of the equation that would yield too "exotic" scale steps (too small/too big diffference between s and L) are excluded. (The concrete - sort of arbitrary - restrictions applied were: a solution appears if 7/6 < L/s < 5.) || [[PentatonicMOS|Pentatonic MOS]] || || || || || || [[1L 4s]] || || [[2L 3s]] || || [[3L 2s]] || || [[4L 1s]] || || || || || || || [[HexatonicMOS|Hexatonic MOS]] || || || || || [[1L 5s]] || || [[2L 4s]] || || [[3L 3s]] || || [[4L 2s]] || || [[5L 1s]] || || || || || || [[HeptatonicMOS|Heptatonic MOS]] || || || || [[1L 6s]] || || [[2L 5s]] || || [[3L 4s]] || || [[4L 3s]] || || [[5L 2s]] || || [[6L 1s]] || || || || || [[OctatonicMOS|Octatonic MOS]] || || || [[1L 7s]] || || [[2L 6s]] || || [[3L 5s]] || || [[4L 4s]] || || [[5L 3s]] || || [[6L 2s]] || || [[7L 1s]] || || || || [[NonatonicMOS|Nonatonic MOS]] || || [[1L 8s]] || || [[2L 7s]] || || [[3L 6s]] || || [[4L 5s]] || || [[5L 4s]] || || [[6L 3s]] || || [[7L 2s]] || || [[8L 1s]] || || || [[DecatonicMOS|Decatonic MOS]] || [[1L 9s]] || || [[2L 8s]] || || [[3L 7s]] || || [[4L 6s]] || || [[5L 5s]] || || [[6L 4s]] || || [[7L 3s]] || || [[8L 2s]] || || [[9L 1s]] || <span style="color: #0000ee;"> </span> =MOS As Applied To Rhythms= David Canright was the first to suggest Fibonacci Rhythms in 1/1. This lead to Kraig Grady to be the first to apply MOS patterns to rhythms. Two papers on the subject can be found here [[http://anaphoria.com/hora.PDF]] and [[http://anaphoria.com/horo2.PDF]] MOS structures and thinking can be applied to the design of rhythms as well. See [[MOS Rhythm Tutorial]] =[[MOSDiagrams]]=
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<html><head><title>MOSScales</title></head><body><!-- ws:start:WikiTextHeadingRule:0:<h1> --><h1 id="toc0"><a name="MOS scales"></a><!-- ws:end:WikiTextHeadingRule:0 -->MOS scales</h1>
<br />
An important class of scales are MOS scales (the acronym MOS from "Moment of symmetry"). These are derived by iterating a interval g, called the generator, inside a larger interval, called the period, and reducing to the period when the iterates become larger than the period. Usually the period is an octave or an nth root of 2, but it can in theory be any positive number. The resulting scale is called a MOS when it has exactly two sizes of steps when sorted into ascending order of size.<br />
<br />
The term and scale construction method were invented by Erv Wilson. His original paper can be found here <a class="wiki_link_ext" href="http://anaphoria.com/mos.PDF" rel="nofollow">http://anaphoria.com/mos.PDF</a>. There is also an introduction <a class="wiki_link_ext" href="http://anaphoria.com/wilsonintroMOS.html" rel="nofollow">http://anaphoria.com/wilsonintroMOS.html</a>. It generalizes the classical diatonic and pentatonic scales.<br />
<br />
<!-- ws:start:WikiTextHeadingRule:2:<h2> --><h2 id="toc1"><a name="MOS scales-Theory of MOS"></a><!-- ws:end:WikiTextHeadingRule:2 -->Theory of MOS</h2>
Let us represent the period as 1. This would be the logarithm base 2 of 2 if the period is an octave, or in general we can measure intervals by the log base P when P is the period. Suppose the fractions a/b and c/d are a <a class="wiki_link_ext" href="http://en.wikipedia.org/wiki/Farey_sequence#Sequence_length" rel="nofollow">Farey pair</a>, meaning that a/b < c/d and bc - ad = 1. If g = (1-t)(a/b) + t(c/d) for 0 <= t <= 1, then when t = 0, the scale generated by g will consist of an equal division of 1 (representing P) into steps of size 1/b, and when t = 1 into steps of size 1/d. In between, when t = b/(b + d), we obtain a generator equal to the <a class="wiki_link_ext" href="http://en.wikipedia.org/wiki/Mediant_%28mathematics%29" rel="nofollow">mediant</a> (a + c)/(b + d) and which will divide the period into b+d equal steps. For all other values a/b < g < c/d we obtain two different sizes of steps, the small steps s, and the large steps L, with the total number of steps b+d, and these scales are the MOS associated to the Farey pair.<br />
<br />
<!-- ws:start:WikiTextHeadingRule:4:<h2> --><h2 id="toc2"><a name="MOS scales-Classification of MOS"></a><!-- ws:end:WikiTextHeadingRule:4 -->Classification of MOS</h2>
An obvious first rough classification of MOS scales is given by the number of elements of the scale - the number of large intervals (L) and the number of small intervals (s). E.g., the diatonic scale in 12-tone equal temperament could be described as <a class="wiki_link" href="/5L%202s">5L 2s</a> (5 large steps and 2 small steps).<br />
Since numbers tend to be dry, Graham Breed has proposed a <a class="wiki_link" href="/MOSNamingScheme">naming scheme for MOS scales</a>.<br />
<br />
<!-- ws:start:WikiTextHeadingRule:6:<h2> --><h2 id="toc3"><a name="MOS scales-MOS in equal temperaments"></a><!-- ws:end:WikiTextHeadingRule:6 -->MOS in equal temperaments</h2>
In the special case of an equal temperament, more concrete things about MOS can be stated.<br />
In an equal temparement, all intervals - and hence also the intervals L and s - are integer multiples of a smallest unit. (Example: in case of the diatonic scale in 12EDO, L would be 2 and s 1.)<br />
If we have an arbitrary MOS scale in an n-tone equal temperament, with a steps of size L and b steps of size s, there holds<br />
<br />
a*L +b*s = n.<br />
<br />
which is a linear diophantine equation! This means that given a, b and n, all possible MOS types can be calculated via the general solution of the corresponding linear diophantine equation.<br />
<br />
Below is a list of MOS with number of elements from 5 to 10, in equal temperaments up to 36.<br />
Not all mathematical possibilities are listed - solutions of the equation that would yield too "exotic" scale steps (too small/too big diffference between s and L) are excluded. (The concrete - sort of arbitrary - restrictions applied were: a solution appears if 7/6 < L/s < 5.)<br />
<br />
<table class="wiki_table">
<tr>
<td><a class="wiki_link" href="/PentatonicMOS">Pentatonic MOS</a><br />
</td>
<td><br />
</td>
<td><br />
</td>
<td><br />
</td>
<td><br />
</td>
<td><br />
</td>
<td><a class="wiki_link" href="/1L%204s">1L 4s</a><br />
</td>
<td><br />
</td>
<td><a class="wiki_link" href="/2L%203s">2L 3s</a><br />
</td>
<td><br />
</td>
<td><a class="wiki_link" href="/3L%202s">3L 2s</a><br />
</td>
<td><br />
</td>
<td><a class="wiki_link" href="/4L%201s">4L 1s</a><br />
</td>
<td><br />
</td>
<td><br />
</td>
<td><br />
</td>
<td><br />
</td>
<td><br />
</td>
</tr>
<tr>
<td><a class="wiki_link" href="/HexatonicMOS">Hexatonic MOS</a><br />
</td>
<td><br />
</td>
<td><br />
</td>
<td><br />
</td>
<td><br />
</td>
<td><a class="wiki_link" href="/1L%205s">1L 5s</a><br />
</td>
<td><br />
</td>
<td><a class="wiki_link" href="/2L%204s">2L 4s</a><br />
</td>
<td><br />
</td>
<td><a class="wiki_link" href="/3L%203s">3L 3s</a><br />
</td>
<td><br />
</td>
<td><a class="wiki_link" href="/4L%202s">4L 2s</a><br />
</td>
<td><br />
</td>
<td><a class="wiki_link" href="/5L%201s">5L 1s</a><br />
</td>
<td><br />
</td>
<td><br />
</td>
<td><br />
</td>
<td><br />
</td>
</tr>
<tr>
<td><a class="wiki_link" href="/HeptatonicMOS">Heptatonic MOS</a><br />
</td>
<td><br />
</td>
<td><br />
</td>
<td><br />
</td>
<td><a class="wiki_link" href="/1L%206s">1L 6s</a><br />
</td>
<td><br />
</td>
<td><a class="wiki_link" href="/2L%205s">2L 5s</a><br />
</td>
<td><br />
</td>
<td><a class="wiki_link" href="/3L%204s">3L 4s</a><br />
</td>
<td><br />
</td>
<td><a class="wiki_link" href="/4L%203s">4L 3s</a><br />
</td>
<td><br />
</td>
<td><a class="wiki_link" href="/5L%202s">5L 2s</a><br />
</td>
<td><br />
</td>
<td><a class="wiki_link" href="/6L%201s">6L 1s</a><br />
</td>
<td><br />
</td>
<td><br />
</td>
<td><br />
</td>
</tr>
<tr>
<td><a class="wiki_link" href="/OctatonicMOS">Octatonic MOS</a><br />
</td>
<td><br />
</td>
<td><br />
</td>
<td><a class="wiki_link" href="/1L%207s">1L 7s</a><br />
</td>
<td><br />
</td>
<td><a class="wiki_link" href="/2L%206s">2L 6s</a><br />
</td>
<td><br />
</td>
<td><a class="wiki_link" href="/3L%205s">3L 5s</a><br />
</td>
<td><br />
</td>
<td><a class="wiki_link" href="/4L%204s">4L 4s</a><br />
</td>
<td><br />
</td>
<td><a class="wiki_link" href="/5L%203s">5L 3s</a><br />
</td>
<td><br />
</td>
<td><a class="wiki_link" href="/6L%202s">6L 2s</a><br />
</td>
<td><br />
</td>
<td><a class="wiki_link" href="/7L%201s">7L 1s</a><br />
</td>
<td><br />
</td>
<td><br />
</td>
</tr>
<tr>
<td><a class="wiki_link" href="/NonatonicMOS">Nonatonic MOS</a><br />
</td>
<td><br />
</td>
<td><a class="wiki_link" href="/1L%208s">1L 8s</a><br />
</td>
<td><br />
</td>
<td><a class="wiki_link" href="/2L%207s">2L 7s</a><br />
</td>
<td><br />
</td>
<td><a class="wiki_link" href="/3L%206s">3L 6s</a><br />
</td>
<td><br />
</td>
<td><a class="wiki_link" href="/4L%205s">4L 5s</a><br />
</td>
<td><br />
</td>
<td><a class="wiki_link" href="/5L%204s">5L 4s</a><br />
</td>
<td><br />
</td>
<td><a class="wiki_link" href="/6L%203s">6L 3s</a><br />
</td>
<td><br />
</td>
<td><a class="wiki_link" href="/7L%202s">7L 2s</a><br />
</td>
<td><br />
</td>
<td><a class="wiki_link" href="/8L%201s">8L 1s</a><br />
</td>
<td><br />
</td>
</tr>
<tr>
<td><a class="wiki_link" href="/DecatonicMOS">Decatonic MOS</a><br />
</td>
<td><a class="wiki_link" href="/1L%209s">1L 9s</a><br />
</td>
<td><br />
</td>
<td><a class="wiki_link" href="/2L%208s">2L 8s</a><br />
</td>
<td><br />
</td>
<td><a class="wiki_link" href="/3L%207s">3L 7s</a><br />
</td>
<td><br />
</td>
<td><a class="wiki_link" href="/4L%206s">4L 6s</a><br />
</td>
<td><br />
</td>
<td><a class="wiki_link" href="/5L%205s">5L 5s</a><br />
</td>
<td><br />
</td>
<td><a class="wiki_link" href="/6L%204s">6L 4s</a><br />
</td>
<td><br />
</td>
<td><a class="wiki_link" href="/7L%203s">7L 3s</a><br />
</td>
<td><br />
</td>
<td><a class="wiki_link" href="/8L%202s">8L 2s</a><br />
</td>
<td><br />
</td>
<td><a class="wiki_link" href="/9L%201s">9L 1s</a><br />
</td>
</tr>
</table>
<span style="color: #0000ee;"> </span><br />
<!-- ws:start:WikiTextHeadingRule:8:<h1> --><h1 id="toc4"><a name="MOS As Applied To Rhythms"></a><!-- ws:end:WikiTextHeadingRule:8 -->MOS As Applied To Rhythms</h1>
David Canright was the first to suggest Fibonacci Rhythms in 1/1. This lead to Kraig Grady to be the first to apply MOS patterns to rhythms. Two papers on the subject can be found here <a class="wiki_link_ext" href="http://anaphoria.com/hora.PDF" rel="nofollow">http://anaphoria.com/hora.PDF</a> and <a class="wiki_link_ext" href="http://anaphoria.com/horo2.PDF" rel="nofollow">http://anaphoria.com/horo2.PDF</a><br />
MOS structures and thinking can be applied to the design of rhythms as well. See <a class="wiki_link" href="/MOS%20Rhythm%20Tutorial">MOS Rhythm Tutorial</a><br />
<br />
<!-- ws:start:WikiTextHeadingRule:10:<h1> --><h1 id="toc5"><a name="MOSDiagrams"></a><!-- ws:end:WikiTextHeadingRule:10 --><a class="wiki_link" href="/MOSDiagrams">MOSDiagrams</a></h1>
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