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<h2>IMPORTED REVISION FROM WIKISPACES</h2>
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This is an imported revision from Wikispaces. The revision metadata is included below for reference:<br>
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: This revision was by author [[User:guest|guest]] and made on <tt>2011-08-26 23:04:23 UTC</tt>.<br>
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: The original revision id was <tt>248746967</tt>.<br>
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The [[BP|Bohlen-Pierce (BP) scale]] seems to have been the first such arrangement to be seriously studied and made into music. As the equivalent harmonics are 1:3:9:27 etc., filling in 3-9 isoharmonically, one arrives at the fundamental consonant triad of BP music - 3:5:7:(9). The [[MOSScales|MOS]] that are most naturally formed from these harmonics are of the forms 4L+1s (pentatonic) and 4L+5s (nonatonic), and through these formulae many equal divisions can be derived. Which brings forward one analogy with diatonic music (3rd and 5th harmonics under octaves) or diatonic function in general: that 4edt and 9edt can be directly compared to 5edo and 7edo (and indeed they sound like they can). In contrast to the state of meantone temperaments, the simplest true nonatonic L=2 s=1 (13edt, the traditional tempered BP scale) is the most accurate and evenly-tempered, in terms of just 5 and 7, for a long way. But, formations with Large and small steps of different relative sizes are no less valuable, for their capability of representing other intervals and harmonics (eg. 17edt), for the use of extended harmonies that would be tempered together with only 13 tones, and to allow use of other non-nonatonic scale formations.
The [[BP|Bohlen-Pierce (BP) scale]] seems to have been the first such arrangement to be seriously studied and made into music. As the equivalent harmonics are 1:3:9:27 etc., filling in 3-9 isoharmonically, one arrives at the fundamental consonant triad of BP music - 3:5:7:(9). The [[MOSScales|MOS]] that are most naturally formed from these harmonics are of the forms 4L+1s (pentatonic) and 4L+5s (nonatonic), and through these formulae many equal divisions can be derived. Which brings forward one analogy with diatonic music (3rd and 5th harmonics under octaves) or diatonic function in general: that 4edt and 9edt can be directly compared to 5edo and 7edo (and indeed they sound like they can). In contrast to the state of meantone temperaments, the simplest true nonatonic L=2 s=1 (13edt, the traditional tempered BP scale) is the most accurate and evenly-tempered, in terms of just 5 and 7, for a long way. But, formations with Large and small steps of different relative sizes are no less valuable, for their capability of representing other intervals and harmonics (eg. 17edt), for the use of extended harmonies that would be tempered together with only 13 tones, and to allow use of other non-nonatonic scale formations.


Because the Bohlen Pierce family of equally tempered tritaves, which follow the MOS 4L+5s for integer L and s, is arguably as important to the set of EDT as 5L+2s diatonicism is to octave temperaments, here is a list of them. [Also, the way I see it, as 4edt and 9edt are comparable to 5edo and 7edo, then the "counterparts" of Blackwood and Whitewood would be found in multiples therein and would be octatonic and octadecatonic, eg. 12edt and 27edt. Alas, Ryan has priority ;) ] It's not like you can't do the math but this makes it quicker for you.
And of course, diatonicism isn't the whole of octave based temperaments, and other MOSes and the equal divisions based on them may approximate other systems of harmonics altogether! For example, 15edt very well approximates the 5th and 13th harmonics, and 12edt, the 13th and 17th. **One should bear in mind that, assuming tritave equivalence, when determining which harmonics are represented, the ratios of 3 in the denominator are fungible instead of those of 2.** For example making the fifth harmonic 5:3 a "major sixth" by conventional (and arbitrarily silly for the purposes of xenharmony, even with octaves) pitch class terminology.
 
There are other uses, or conceptualizations, of tritave-based tunings. Purely intuitive use of these myriad, assuredly xenharmonic structures comes to mind (see "EDO" versus "equal temperament"). Another intent might be to find or define temperaments (such as Magic, Hanson, etc.), or to provide exact formulae for stretching/compressing what would musically be used as an "ordinary" octave of ~2:1. (And given the stable nature of octave-based systems, some aesthetic overlap even in the most tritave-equivalent of music, would be forseeable.) For instance, the Bernhard-Stopper (19edt) temperament, might for instance be found useful in tuning pianoforti, being equivalent to 12edo, except for a 2c sharp octave which is relevant to inharmonicity.
 
Below is a large list of EDT's; additionally, some equal divisions of the tritave are known by alternate names or have special interest:
 
[[5edt]] (Tritave counterpart of Magic)
[[6edt]] (Tritave counterpart of Hanson)
[[7edt]] (Tritave counterpart of Orwell)
[[8edt]] (Tritave counterpart of Blacksmith)
[[11edt]] "Euler Temperament"
[[BP|"Bohlen-Pierce" or "BP"]]
[[19ED3|"Bernhard Stopper"]]
[[39edt]] Triple Bohlen-Pierce (Erlich)
 
=Individual pages for EDT's=
 
|| [[edt|1edt]] || [[2edt]] || [[3edt]] || [[4edt]] || [[5edt]] || [[6edt]] || [[7edt]] || [[8edt]] || [[9edt]] || [[10edt]] || [[11edt]] || [[12edt]] ||
|| [[13edt]] || [[14edt]] || [[15edt]] || [[16edt]] || [[17edt]] || [[18edt]] || [[19edt]] || [[20edt]] || [[21edt]] || [[22edt]] || [[23edt]] || [[24edt]] ||
|| [[25edt]] || [[26edt]] || [[27edt]] || [[28edt]] || [[29edt]] || [[30edt]] || [[31edt]] || [[32edt]] || [[33edt]] || [[34edt]] || [[35edt]] || [[36edt]] ||
|| [[37edt]] || [[38edt]] || [[39edt]] || [[40edt]] || [[41edt]] || [[42edt]] || [[43edt]] ||  || [[45edt]] || [[46edt]] || [[47edt]] || [[48edt]] ||
 
Because the Bohlen Pierce family of equally tempered tritaves, which follow the MOS 4L+5s for integer L and s, is arguably as important to the set of EDT as 5L+2s diatonicism is to octave temperaments, here is a list of them. It's not like you can't do the math but this makes it quicker for you.


L=1 s=0 4 edt
L=1 s=0 4 edt
Line 33: Line 55:
L=7 s=5 53
L=7 s=5 53
L=7 s=6 58 5sharp1 7sharp10 (Schism*)
L=7 s=6 58 5sharp1 7sharp10 (Schism*)
*Schismy, by which I mean, the most accurate value for 5/3 and-or 7/3 is found outside the 4L+5s MOS.
*Schism, by which I mean, the most accurate value for 5/3 and-or 7/3 is found outside the 4L+5s MOS.
 
[Also, the way I see it, as 4edt and 9edt are comparable to 5edo and 7edo, then the "counterparts" of Blackwood and Whitewood would be found in multiples therein and would be octatonic and octadecatonic, eg. 12edt and 27edt. Alas, Ryan has priority ;) ]</pre></div>
 
And of course, diatonicism isn't the whole of octave based temperaments, and other MOSes and the equal divisions based on them may approximate other systems of harmonics altogether! For example, 15edt very well approximates the 5th and 13th harmonics, and 12edt, the 13th and 17th. **One should bear in mind that, assuming tritave equivalence, when determining which harmonics are represented, the ratios of 3 in the denominator are fungible instead of those of 2.** For example making the fifth harmonic 5:3 a "major sixth" by conventional (and arbitrarily silly for the purposes of xenharmony, even with octaves) pitch class terminology.
 
There are other uses, or conceptualizations, of tritave-based tunings. Purely intuitive use of these myriad, assuredly xenharmonic structures comes to mind (see "EDO" versus "equal temperament"). Another intent might be to find or define temperaments (such as Magic, Hanson, etc.), or to provide exact formulae for stretching/compressing what would musically be used as an "ordinary" octave of ~2:1. (And given the stable nature of octave-based systems, some aesthetic overlap even in the most tritave-equivalent of music, would be forseeable.) For instance, the Bernhard-Stopper (19edt) temperament, might for instance be found useful in tuning pianoforti, being equivalent to 12edo, except for a 2c sharp octave which is relevant to inharmonicity.
 
Below is a large list of EDT's; additionally, some equal divisions of the tritave are known by alternate names or have special interest:
 
[[5edt]] (Tritave counterpart of Magic)
[[6edt]] (Tritave counterpart of Hanson)
[[7edt]] (Tritave counterpart of Orwell)
[[8edt]] (Tritave counterpart of Blacksmith)
[[11edt]] "Euler Temperament"
[[BP|"Bohlen-Pierce" or "BP"]]
[[19ED3|"Bernhard Stopper"]]
[[39edt]] Triple Bohlen-Pierce (Erlich)
 
=Individual pages for EDT's=
 
|| [[edt|1edt]] || [[2edt]] || [[3edt]] || [[4edt]] || [[5edt]] || [[6edt]] || [[7edt]] || [[8edt]] || [[9edt]] || [[10edt]] || [[11edt]] || [[12edt]] ||
|| [[13edt]] || [[14edt]] || [[15edt]] || [[16edt]] || [[17edt]] || [[18edt]] || [[19edt]] || [[20edt]] || [[21edt]] || [[22edt]] || [[23edt]] || [[24edt]] ||
|| [[25edt]] || [[26edt]] || [[27edt]] || [[28edt]] || [[29edt]] || [[30edt]] || [[31edt]] || [[32edt]] || [[33edt]] || [[34edt]] || [[35edt]] || [[36edt]] ||
|| [[37edt]] || [[38edt]] || [[39edt]] || [[40edt]] || [[41edt]] || [[42edt]] || [[43edt]] ||  || [[45edt]] || [[46edt]] || [[47edt]] || [[48edt]] ||</pre></div>
<h4>Original HTML content:</h4>
<h4>Original HTML content:</h4>
<div style="width:100%; max-height:400pt; overflow:auto; background-color:#f8f9fa; border: 1px solid #eaecf0; padding:0em"><pre style="margin:0px;border:none;background:none;word-wrap:break-word;width:200%;white-space: pre-wrap ! important" class="old-revision-html">&lt;html&gt;&lt;head&gt;&lt;title&gt;edt&lt;/title&gt;&lt;/head&gt;&lt;body&gt;&lt;!-- ws:start:WikiTextHeadingRule:0:&amp;lt;h1&amp;gt; --&gt;&lt;h1 id="toc0"&gt;&lt;a name="Division of the tritave (3/1) into n equal parts"&gt;&lt;/a&gt;&lt;!-- ws:end:WikiTextHeadingRule:0 --&gt;Division of the tritave (3/1) into n equal parts&lt;/h1&gt;
<div style="width:100%; max-height:400pt; overflow:auto; background-color:#f8f9fa; border: 1px solid #eaecf0; padding:0em"><pre style="margin:0px;border:none;background:none;word-wrap:break-word;width:200%;white-space: pre-wrap ! important" class="old-revision-html">&lt;html&gt;&lt;head&gt;&lt;title&gt;edt&lt;/title&gt;&lt;/head&gt;&lt;body&gt;&lt;!-- ws:start:WikiTextHeadingRule:0:&amp;lt;h1&amp;gt; --&gt;&lt;h1 id="toc0"&gt;&lt;a name="Division of the tritave (3/1) into n equal parts"&gt;&lt;/a&gt;&lt;!-- ws:end:WikiTextHeadingRule:0 --&gt;Division of the tritave (3/1) into n equal parts&lt;/h1&gt;
Line 63: Line 63:
&lt;br /&gt;
&lt;br /&gt;
The &lt;a class="wiki_link" href="/BP"&gt;Bohlen-Pierce (BP) scale&lt;/a&gt; seems to have been the first such arrangement to be seriously studied and made into music. As the equivalent harmonics are 1:3:9:27 etc., filling in 3-9 isoharmonically, one arrives at the fundamental consonant triad of BP music - 3:5:7:(9). The &lt;a class="wiki_link" href="/MOSScales"&gt;MOS&lt;/a&gt; that are most naturally formed from these harmonics are of the forms 4L+1s (pentatonic) and 4L+5s (nonatonic), and through these formulae many equal divisions can be derived. Which brings forward one analogy with diatonic music (3rd and 5th harmonics under octaves) or diatonic function in general: that 4edt and 9edt can be directly compared to 5edo and 7edo (and indeed they sound like they can). In contrast to the state of meantone temperaments, the simplest true nonatonic L=2 s=1 (13edt, the traditional tempered BP scale) is the most accurate and evenly-tempered, in terms of just 5 and 7, for a long way. But, formations with Large and small steps of different relative sizes are no less valuable, for their capability of representing other intervals and harmonics (eg. 17edt), for the use of extended harmonies that would be tempered together with only 13 tones, and to allow use of other non-nonatonic scale formations.&lt;br /&gt;
The &lt;a class="wiki_link" href="/BP"&gt;Bohlen-Pierce (BP) scale&lt;/a&gt; seems to have been the first such arrangement to be seriously studied and made into music. As the equivalent harmonics are 1:3:9:27 etc., filling in 3-9 isoharmonically, one arrives at the fundamental consonant triad of BP music - 3:5:7:(9). The &lt;a class="wiki_link" href="/MOSScales"&gt;MOS&lt;/a&gt; that are most naturally formed from these harmonics are of the forms 4L+1s (pentatonic) and 4L+5s (nonatonic), and through these formulae many equal divisions can be derived. Which brings forward one analogy with diatonic music (3rd and 5th harmonics under octaves) or diatonic function in general: that 4edt and 9edt can be directly compared to 5edo and 7edo (and indeed they sound like they can). In contrast to the state of meantone temperaments, the simplest true nonatonic L=2 s=1 (13edt, the traditional tempered BP scale) is the most accurate and evenly-tempered, in terms of just 5 and 7, for a long way. But, formations with Large and small steps of different relative sizes are no less valuable, for their capability of representing other intervals and harmonics (eg. 17edt), for the use of extended harmonies that would be tempered together with only 13 tones, and to allow use of other non-nonatonic scale formations.&lt;br /&gt;
&lt;br /&gt;
Because the Bohlen Pierce family of equally tempered tritaves, which follow the MOS 4L+5s for integer L and s, is arguably as important to the set of EDT as 5L+2s diatonicism is to octave temperaments, here is a list of them. [Also, the way I see it, as 4edt and 9edt are comparable to 5edo and 7edo, then the &amp;quot;counterparts&amp;quot; of Blackwood and Whitewood would be found in multiples therein and would be octatonic and octadecatonic, eg. 12edt and 27edt. Alas, Ryan has priority ;) ] It's not like you can't do the math but this makes it quicker for you.&lt;br /&gt;
&lt;br /&gt;
L=1 s=0 4 edt&lt;br /&gt;
L=1 s=1 9 edt (5flat40 7sharp18)&lt;br /&gt;
L=2 s=1 13 (5flat7 7flat3)&lt;br /&gt;
L=3 s=1 17 (5sharp10 7flat12)&lt;br /&gt;
L=3 s=2 22 (~14edo)&lt;br /&gt;
L=4 s=1 21&lt;br /&gt;
L=4 s=3 31&lt;br /&gt;
L=5 s=1 25&lt;br /&gt;
L=5 s=2 30 (~19edo) (5sharp3 7flat8)&lt;br /&gt;
L=5 s=3 35 (~22edo) (5flat14 7sharp0)&lt;br /&gt;
L=5 s=4 40&lt;br /&gt;
L=6 s=1 29&lt;br /&gt;
L=6 s=5 49 (~31EDO) (5sharp8 7sharp8) (Schism*)&lt;br /&gt;
L=7 s=1 33&lt;br /&gt;
L=7 s=2 38&lt;br /&gt;
L=7 s=3 43 (~27edo) (5sharp0 7flat6)&lt;br /&gt;
L=7 s=4 48 (5flat13 7flat0)&lt;br /&gt;
L=7 s=5 53&lt;br /&gt;
L=7 s=6 58 5sharp1 7sharp10 (Schism*)&lt;br /&gt;
*Schismy, by which I mean, the most accurate value for 5/3 and-or 7/3 is found outside the 4L+5s MOS.&lt;br /&gt;
&lt;br /&gt;
&lt;br /&gt;
&lt;br /&gt;
And of course, diatonicism isn't the whole of octave based temperaments, and other MOSes and the equal divisions based on them may approximate other systems of harmonics altogether! For example, 15edt very well approximates the 5th and 13th harmonics, and 12edt, the 13th and 17th. &lt;strong&gt;One should bear in mind that, assuming tritave equivalence, when determining which harmonics are represented, the ratios of 3 in the denominator are fungible instead of those of 2.&lt;/strong&gt; For example making the fifth harmonic 5:3 a &amp;quot;major sixth&amp;quot; by conventional (and arbitrarily silly for the purposes of xenharmony, even with octaves) pitch class terminology.&lt;br /&gt;
And of course, diatonicism isn't the whole of octave based temperaments, and other MOSes and the equal divisions based on them may approximate other systems of harmonics altogether! For example, 15edt very well approximates the 5th and 13th harmonics, and 12edt, the 13th and 17th. &lt;strong&gt;One should bear in mind that, assuming tritave equivalence, when determining which harmonics are represented, the ratios of 3 in the denominator are fungible instead of those of 2.&lt;/strong&gt; For example making the fifth harmonic 5:3 a &amp;quot;major sixth&amp;quot; by conventional (and arbitrarily silly for the purposes of xenharmony, even with octaves) pitch class terminology.&lt;br /&gt;
Line 214: Line 190:
&lt;/table&gt;
&lt;/table&gt;


&lt;/body&gt;&lt;/html&gt;</pre></div>
&lt;br /&gt;
Because the Bohlen Pierce family of equally tempered tritaves, which follow the MOS 4L+5s for integer L and s, is arguably as important to the set of EDT as 5L+2s diatonicism is to octave temperaments, here is a list of them. It's not like you can't do the math but this makes it quicker for you.&lt;br /&gt;
&lt;br /&gt;
L=1 s=0 4 edt&lt;br /&gt;
L=1 s=1 9 edt (5flat40 7sharp18)&lt;br /&gt;
L=2 s=1 13 (5flat7 7flat3)&lt;br /&gt;
L=3 s=1 17 (5sharp10 7flat12)&lt;br /&gt;
L=3 s=2 22 (~14edo)&lt;br /&gt;
L=4 s=1 21&lt;br /&gt;
L=4 s=3 31&lt;br /&gt;
L=5 s=1 25&lt;br /&gt;
L=5 s=2 30 (~19edo) (5sharp3 7flat8)&lt;br /&gt;
L=5 s=3 35 (~22edo) (5flat14 7sharp0)&lt;br /&gt;
L=5 s=4 40&lt;br /&gt;
L=6 s=1 29&lt;br /&gt;
L=6 s=5 49 (~31EDO) (5sharp8 7sharp8) (Schism*)&lt;br /&gt;
L=7 s=1 33&lt;br /&gt;
L=7 s=2 38&lt;br /&gt;
L=7 s=3 43 (~27edo) (5sharp0 7flat6)&lt;br /&gt;
L=7 s=4 48 (5flat13 7flat0)&lt;br /&gt;
L=7 s=5 53&lt;br /&gt;
L=7 s=6 58 5sharp1 7sharp10 (Schism*)&lt;br /&gt;
*Schism, by which I mean, the most accurate value for 5/3 and-or 7/3 is found outside the 4L+5s MOS.&lt;br /&gt;
[Also, the way I see it, as 4edt and 9edt are comparable to 5edo and 7edo, then the &amp;quot;counterparts&amp;quot; of Blackwood and Whitewood would be found in multiples therein and would be octatonic and octadecatonic, eg. 12edt and 27edt. Alas, Ryan has priority ;) ]&lt;/body&gt;&lt;/html&gt;</pre></div>

Revision as of 23:08, 26 August 2011

IMPORTED REVISION FROM WIKISPACES

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This revision was by author guest and made on 2011-08-26 23:08:46 UTC.
The original revision id was 248747393.
The revision comment was:

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=Division of the tritave (3/1) into n equal parts= 

After the octave (roughly 2:1 but it has been tuned sharp and flat for various reasons), the next simple "frame interval" available is the ratio 3:1. Among other names, the third harmonic has been called the "perfect twelfth" "triple" or "tritave". There has been argument whether pitches a tritave apart can be heard as equivalent, but with proper context and/or experience, at least some people find that they can. Arguably that is the single criterion for calling the tritave a true frame interval. Some put a great emphasis on timbre, claiming that a lack of even harmonics (octaves) emphasizes the property of tritave equivalence, or at least enhances the perception of [[BP]] harmonies, though the necessity of this claim is arguable. It is certain that musically valuable organizations of pitch can arise through the equal division of non-octave intervals regardless of equivalence, and either way, the multitude of equal divisions of the tritave are rich and ripe for exploration.

The [[BP|Bohlen-Pierce (BP) scale]] seems to have been the first such arrangement to be seriously studied and made into music. As the equivalent harmonics are 1:3:9:27 etc., filling in 3-9 isoharmonically, one arrives at the fundamental consonant triad of BP music - 3:5:7:(9). The [[MOSScales|MOS]] that are most naturally formed from these harmonics are of the forms 4L+1s (pentatonic) and 4L+5s (nonatonic), and through these formulae many equal divisions can be derived. Which brings forward one analogy with diatonic music (3rd and 5th harmonics under octaves) or diatonic function in general: that 4edt and 9edt can be directly compared to 5edo and 7edo (and indeed they sound like they can). In contrast to the state of meantone temperaments, the simplest true nonatonic L=2 s=1 (13edt, the traditional tempered BP scale) is the most accurate and evenly-tempered, in terms of just 5 and 7, for a long way. But, formations with Large and small steps of different relative sizes are no less valuable, for their capability of representing other intervals and harmonics (eg. 17edt), for the use of extended harmonies that would be tempered together with only 13 tones, and to allow use of other non-nonatonic scale formations.

And of course, diatonicism isn't the whole of octave based temperaments, and other MOSes and the equal divisions based on them may approximate other systems of harmonics altogether! For example, 15edt very well approximates the 5th and 13th harmonics, and 12edt, the 13th and 17th. **One should bear in mind that, assuming tritave equivalence, when determining which harmonics are represented, the ratios of 3 in the denominator are fungible instead of those of 2.** For example making the fifth harmonic 5:3 a "major sixth" by conventional (and arbitrarily silly for the purposes of xenharmony, even with octaves) pitch class terminology.

There are other uses, or conceptualizations, of tritave-based tunings. Purely intuitive use of these myriad, assuredly xenharmonic structures comes to mind (see "EDO" versus "equal temperament"). Another intent might be to find or define temperaments (such as Magic, Hanson, etc.), or to provide exact formulae for stretching/compressing what would musically be used as an "ordinary" octave of ~2:1. (And given the stable nature of octave-based systems, some aesthetic overlap even in the most tritave-equivalent of music, would be forseeable.) For instance, the Bernhard-Stopper (19edt) temperament, might for instance be found useful in tuning pianoforti, being equivalent to 12edo, except for a 2c sharp octave which is relevant to inharmonicity.

Below is a large list of EDT's; additionally, some equal divisions of the tritave are known by alternate names or have special interest:

[[5edt]] (Tritave counterpart of Magic)
[[6edt]] (Tritave counterpart of Hanson)
[[7edt]] (Tritave counterpart of Orwell)
[[8edt]] (Tritave counterpart of Blacksmith)
[[11edt]] "Euler Temperament"
[[BP|"Bohlen-Pierce" or "BP"]]
[[19ED3|"Bernhard Stopper"]]
[[39edt]] Triple Bohlen-Pierce (Erlich)

=Individual pages for EDT's= 

|| [[edt|1edt]] || [[2edt]] || [[3edt]] || [[4edt]] || [[5edt]] || [[6edt]] || [[7edt]] || [[8edt]] || [[9edt]] || [[10edt]] || [[11edt]] || [[12edt]] ||
|| [[13edt]] || [[14edt]] || [[15edt]] || [[16edt]] || [[17edt]] || [[18edt]] || [[19edt]] || [[20edt]] || [[21edt]] || [[22edt]] || [[23edt]] || [[24edt]] ||
|| [[25edt]] || [[26edt]] || [[27edt]] || [[28edt]] || [[29edt]] || [[30edt]] || [[31edt]] || [[32edt]] || [[33edt]] || [[34edt]] || [[35edt]] || [[36edt]] ||
|| [[37edt]] || [[38edt]] || [[39edt]] || [[40edt]] || [[41edt]] || [[42edt]] || [[43edt]] ||   || [[45edt]] || [[46edt]] || [[47edt]] || [[48edt]] ||

Because the Bohlen Pierce family of equally tempered tritaves, which follow the MOS 4L+5s for integer L and s, is arguably as important to the set of EDT as 5L+2s diatonicism is to octave temperaments, here is a list of them. It's not like you can't do the math but this makes it quicker for you.

L=1 s=0 4 edt
L=1 s=1 9 edt (5flat40 7sharp18)
L=2 s=1 13 (5flat7 7flat3)
L=3 s=1 17 (5sharp10 7flat12)
L=3 s=2 22 (~14edo)
L=4 s=1 21
L=4 s=3 31
L=5 s=1 25
L=5 s=2 30 (~19edo) (5sharp3 7flat8)
L=5 s=3 35 (~22edo) (5flat14 7sharp0)
L=5 s=4 40
L=6 s=1 29
L=6 s=5 49 (~31EDO) (5sharp8 7sharp8) (Schism*)
L=7 s=1 33
L=7 s=2 38
L=7 s=3 43 (~27edo) (5sharp0 7flat6)
L=7 s=4 48 (5flat13 7flat0)
L=7 s=5 53
L=7 s=6 58 5sharp1 7sharp10 (Schism*)
*Schism, by which I mean, the most accurate value for 5/3 and-or 7/3 is found outside the 4L+5s MOS.
[Also, the way I see it, as 4edt and 9edt are comparable to 5edo and 7edo, then the "counterparts" of Blackwood and Whitewood would be found in multiples therein and would be octatonic and octadecatonic, eg. 12edt and 27edt. Alas, Ryan has priority ;) ]

Original HTML content:

<html><head><title>edt</title></head><body><!-- ws:start:WikiTextHeadingRule:0:&lt;h1&gt; --><h1 id="toc0"><a name="Division of the tritave (3/1) into n equal parts"></a><!-- ws:end:WikiTextHeadingRule:0 -->Division of the tritave (3/1) into n equal parts</h1>
 <br />
After the octave (roughly 2:1 but it has been tuned sharp and flat for various reasons), the next simple &quot;frame interval&quot; available is the ratio 3:1. Among other names, the third harmonic has been called the &quot;perfect twelfth&quot; &quot;triple&quot; or &quot;tritave&quot;. There has been argument whether pitches a tritave apart can be heard as equivalent, but with proper context and/or experience, at least some people find that they can. Arguably that is the single criterion for calling the tritave a true frame interval. Some put a great emphasis on timbre, claiming that a lack of even harmonics (octaves) emphasizes the property of tritave equivalence, or at least enhances the perception of <a class="wiki_link" href="/BP">BP</a> harmonies, though the necessity of this claim is arguable. It is certain that musically valuable organizations of pitch can arise through the equal division of non-octave intervals regardless of equivalence, and either way, the multitude of equal divisions of the tritave are rich and ripe for exploration.<br />
<br />
The <a class="wiki_link" href="/BP">Bohlen-Pierce (BP) scale</a> seems to have been the first such arrangement to be seriously studied and made into music. As the equivalent harmonics are 1:3:9:27 etc., filling in 3-9 isoharmonically, one arrives at the fundamental consonant triad of BP music - 3:5:7:(9). The <a class="wiki_link" href="/MOSScales">MOS</a> that are most naturally formed from these harmonics are of the forms 4L+1s (pentatonic) and 4L+5s (nonatonic), and through these formulae many equal divisions can be derived. Which brings forward one analogy with diatonic music (3rd and 5th harmonics under octaves) or diatonic function in general: that 4edt and 9edt can be directly compared to 5edo and 7edo (and indeed they sound like they can). In contrast to the state of meantone temperaments, the simplest true nonatonic L=2 s=1 (13edt, the traditional tempered BP scale) is the most accurate and evenly-tempered, in terms of just 5 and 7, for a long way. But, formations with Large and small steps of different relative sizes are no less valuable, for their capability of representing other intervals and harmonics (eg. 17edt), for the use of extended harmonies that would be tempered together with only 13 tones, and to allow use of other non-nonatonic scale formations.<br />
<br />
And of course, diatonicism isn't the whole of octave based temperaments, and other MOSes and the equal divisions based on them may approximate other systems of harmonics altogether! For example, 15edt very well approximates the 5th and 13th harmonics, and 12edt, the 13th and 17th. <strong>One should bear in mind that, assuming tritave equivalence, when determining which harmonics are represented, the ratios of 3 in the denominator are fungible instead of those of 2.</strong> For example making the fifth harmonic 5:3 a &quot;major sixth&quot; by conventional (and arbitrarily silly for the purposes of xenharmony, even with octaves) pitch class terminology.<br />
<br />
There are other uses, or conceptualizations, of tritave-based tunings. Purely intuitive use of these myriad, assuredly xenharmonic structures comes to mind (see &quot;EDO&quot; versus &quot;equal temperament&quot;). Another intent might be to find or define temperaments (such as Magic, Hanson, etc.), or to provide exact formulae for stretching/compressing what would musically be used as an &quot;ordinary&quot; octave of ~2:1. (And given the stable nature of octave-based systems, some aesthetic overlap even in the most tritave-equivalent of music, would be forseeable.) For instance, the Bernhard-Stopper (19edt) temperament, might for instance be found useful in tuning pianoforti, being equivalent to 12edo, except for a 2c sharp octave which is relevant to inharmonicity.<br />
<br />
Below is a large list of EDT's; additionally, some equal divisions of the tritave are known by alternate names or have special interest:<br />
<br />
<a class="wiki_link" href="/5edt">5edt</a> (Tritave counterpart of Magic)<br />
<a class="wiki_link" href="/6edt">6edt</a> (Tritave counterpart of Hanson)<br />
<a class="wiki_link" href="/7edt">7edt</a> (Tritave counterpart of Orwell)<br />
<a class="wiki_link" href="/8edt">8edt</a> (Tritave counterpart of Blacksmith)<br />
<a class="wiki_link" href="/11edt">11edt</a> &quot;Euler Temperament&quot;<br />
<a class="wiki_link" href="/BP">&quot;Bohlen-Pierce&quot; or &quot;BP&quot;</a><br />
<a class="wiki_link" href="/19ED3">&quot;Bernhard Stopper&quot;</a><br />
<a class="wiki_link" href="/39edt">39edt</a> Triple Bohlen-Pierce (Erlich)<br />
<br />
<!-- ws:start:WikiTextHeadingRule:2:&lt;h1&gt; --><h1 id="toc1"><a name="Individual pages for EDT's"></a><!-- ws:end:WikiTextHeadingRule:2 -->Individual pages for EDT's</h1>
 <br />


<table class="wiki_table">
    <tr>
        <td><a class="wiki_link" href="/edt">1edt</a><br />
</td>
        <td><a class="wiki_link" href="/2edt">2edt</a><br />
</td>
        <td><a class="wiki_link" href="/3edt">3edt</a><br />
</td>
        <td><a class="wiki_link" href="/4edt">4edt</a><br />
</td>
        <td><a class="wiki_link" href="/5edt">5edt</a><br />
</td>
        <td><a class="wiki_link" href="/6edt">6edt</a><br />
</td>
        <td><a class="wiki_link" href="/7edt">7edt</a><br />
</td>
        <td><a class="wiki_link" href="/8edt">8edt</a><br />
</td>
        <td><a class="wiki_link" href="/9edt">9edt</a><br />
</td>
        <td><a class="wiki_link" href="/10edt">10edt</a><br />
</td>
        <td><a class="wiki_link" href="/11edt">11edt</a><br />
</td>
        <td><a class="wiki_link" href="/12edt">12edt</a><br />
</td>
    </tr>
    <tr>
        <td><a class="wiki_link" href="/13edt">13edt</a><br />
</td>
        <td><a class="wiki_link" href="/14edt">14edt</a><br />
</td>
        <td><a class="wiki_link" href="/15edt">15edt</a><br />
</td>
        <td><a class="wiki_link" href="/16edt">16edt</a><br />
</td>
        <td><a class="wiki_link" href="/17edt">17edt</a><br />
</td>
        <td><a class="wiki_link" href="/18edt">18edt</a><br />
</td>
        <td><a class="wiki_link" href="/19edt">19edt</a><br />
</td>
        <td><a class="wiki_link" href="/20edt">20edt</a><br />
</td>
        <td><a class="wiki_link" href="/21edt">21edt</a><br />
</td>
        <td><a class="wiki_link" href="/22edt">22edt</a><br />
</td>
        <td><a class="wiki_link" href="/23edt">23edt</a><br />
</td>
        <td><a class="wiki_link" href="/24edt">24edt</a><br />
</td>
    </tr>
    <tr>
        <td><a class="wiki_link" href="/25edt">25edt</a><br />
</td>
        <td><a class="wiki_link" href="/26edt">26edt</a><br />
</td>
        <td><a class="wiki_link" href="/27edt">27edt</a><br />
</td>
        <td><a class="wiki_link" href="/28edt">28edt</a><br />
</td>
        <td><a class="wiki_link" href="/29edt">29edt</a><br />
</td>
        <td><a class="wiki_link" href="/30edt">30edt</a><br />
</td>
        <td><a class="wiki_link" href="/31edt">31edt</a><br />
</td>
        <td><a class="wiki_link" href="/32edt">32edt</a><br />
</td>
        <td><a class="wiki_link" href="/33edt">33edt</a><br />
</td>
        <td><a class="wiki_link" href="/34edt">34edt</a><br />
</td>
        <td><a class="wiki_link" href="/35edt">35edt</a><br />
</td>
        <td><a class="wiki_link" href="/36edt">36edt</a><br />
</td>
    </tr>
    <tr>
        <td><a class="wiki_link" href="/37edt">37edt</a><br />
</td>
        <td><a class="wiki_link" href="/38edt">38edt</a><br />
</td>
        <td><a class="wiki_link" href="/39edt">39edt</a><br />
</td>
        <td><a class="wiki_link" href="/40edt">40edt</a><br />
</td>
        <td><a class="wiki_link" href="/41edt">41edt</a><br />
</td>
        <td><a class="wiki_link" href="/42edt">42edt</a><br />
</td>
        <td><a class="wiki_link" href="/43edt">43edt</a><br />
</td>
        <td><br />
</td>
        <td><a class="wiki_link" href="/45edt">45edt</a><br />
</td>
        <td><a class="wiki_link" href="/46edt">46edt</a><br />
</td>
        <td><a class="wiki_link" href="/47edt">47edt</a><br />
</td>
        <td><a class="wiki_link" href="/48edt">48edt</a><br />
</td>
    </tr>
</table>

<br />
Because the Bohlen Pierce family of equally tempered tritaves, which follow the MOS 4L+5s for integer L and s, is arguably as important to the set of EDT as 5L+2s diatonicism is to octave temperaments, here is a list of them. It's not like you can't do the math but this makes it quicker for you.<br />
<br />
L=1 s=0 4 edt<br />
L=1 s=1 9 edt (5flat40 7sharp18)<br />
L=2 s=1 13 (5flat7 7flat3)<br />
L=3 s=1 17 (5sharp10 7flat12)<br />
L=3 s=2 22 (~14edo)<br />
L=4 s=1 21<br />
L=4 s=3 31<br />
L=5 s=1 25<br />
L=5 s=2 30 (~19edo) (5sharp3 7flat8)<br />
L=5 s=3 35 (~22edo) (5flat14 7sharp0)<br />
L=5 s=4 40<br />
L=6 s=1 29<br />
L=6 s=5 49 (~31EDO) (5sharp8 7sharp8) (Schism*)<br />
L=7 s=1 33<br />
L=7 s=2 38<br />
L=7 s=3 43 (~27edo) (5sharp0 7flat6)<br />
L=7 s=4 48 (5flat13 7flat0)<br />
L=7 s=5 53<br />
L=7 s=6 58 5sharp1 7sharp10 (Schism*)<br />
*Schism, by which I mean, the most accurate value for 5/3 and-or 7/3 is found outside the 4L+5s MOS.<br />
[Also, the way I see it, as 4edt and 9edt are comparable to 5edo and 7edo, then the &quot;counterparts&quot; of Blackwood and Whitewood would be found in multiples therein and would be octatonic and octadecatonic, eg. 12edt and 27edt. Alas, Ryan has priority ;) ]</body></html>
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