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| <h2>IMPORTED REVISION FROM WIKISPACES</h2>
| | {{Interwiki |
| This is an imported revision from Wikispaces. The revision metadata is included below for reference:<br>
| | | de = Intervallraum |
| : This revision was by author [[User:xenwolf|xenwolf]] and made on <tt>2016-02-20 03:30:31 UTC</tt>.<br>
| | | en = Monzos and interval space |
| : The original revision id was <tt>575335349</tt>.<br>
| | | ja = モンゾと音程空間 |
| : The revision comment was: <tt></tt><br>
| | }} |
| The revision contents are below, presented both in the original Wikispaces Wikitext format, and in HTML exactly as Wikispaces rendered it.<br>
| | {{Expert|Monzo}} |
| <h4>Original Wikitext content:</h4>
| | This page gives the formal mathematical definition of a '''monzo''' and shows its relation to '''interval space'''. |
| <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;white-space: pre-wrap ! important" class="old-revision-html"><span style="display: block; text-align: right;">Other languages: [[xenharmonie/Intervallraum|Deutsch]]
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| </span>
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| This page gives the formal mathematical definition of a monzo. For a simpler explanation with examples, visit the [[monzos]] page.
| | == Definition == |
|
| |
|
| =Definition:=
| | A [[Harmonic limit|''p''-limit]] rational number ''q'' can by definition be factored into primes of size less than or equal to ''p'', giving |
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| |
|
| A [[Harmonic Limit|p-limit]] rational number q can by definition be factored into primes of size less than or equal to p, giving
| | <math>q = 2^{e_2} \, 3^{e_3} \, 5^{e_5} \dotso p^{e_p}</math> |
| [[math]]
| |
| q = 2^{e_2} \, 3^{e_3} \, 5^{e_5} \dotso p^{e_p} | |
| [[math]]
| |
| where the exponents are integers (positive, negative, or zero.) This is often written in [[http://mathworld.wolfram.com/Ket.html|ket vector]] ([[http://en.wikipedia.org/wiki/Bra-ket_notation|wp]]) notation as
| |
| [[math]]
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| |e_2 \, e_3 \, e_5 \dotso e_p\rangle
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| [[math]]
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| in which case it is called a **monzo**, where the name refers to the enthusiastic advocacy of [[Joe Monzo]].
| |
|
| |
|
| The [[Tenney Height|Tenney height]] of this monzo is given by
| | where the exponents are integers (positive, negative, or zero.) This is often written in [http://mathworld.wolfram.com/Ket.html ket vector] (→ [[Wikipedia: Bra-ket notation]]) notation as |
| [[math]]
| |
| \| |e_2 \, e_3 \dotso e_p \rangle \| = |e_2| + |e_3| \log_2 3 + \dotsb + |e_p| \log_2 p
| |
| [[math]] | |
|
| |
|
| which is a [[http://en.wikipedia.org/wiki/Normed_vector_space|vector space norm]]; hence we may [[http://en.wikipedia.org/wiki/Embedding|embed]] the p-limit monzos into a normed vector I space of dimension n = π(p) via a map M:monzos ⟶ I. The monzos under this embedding now define a [[http://en.wikipedia.org/wiki/Lattice_%28group%29|lattice]], which is a discrete subgroup spanning the finite dimensional real normed vector space I. If we change coordinates by multiplying values in the coordinate belonging to the prime k by log2(k), then the norm becomes the standard [[http://mathworld.wolfram.com/L1-Norm.html|L1 norm]]. This vector space is Tenney interval space, and the transformed coordinates with the standard L1 norm form the standard basis for Tenney space. It should be noted that while monzos correspond uniquely to positive real numbers (always rational numbers in the case of monzos), vectors in Tenney space do not. For instance, while |1 0> represents 2, so does |0 log3(2)>.
| | <math>|e_2 \, e_3 \, e_5 \dotso e_p\rangle</math> |
|
| |
|
| Because of the mathematical advantages of Euclidean norms, a Euclidean norm is often placed on the vectors in interval space instead of an L1 norm, in which case we have [[Tenney-Euclidean metrics|Tenney-Euclidean interval space]] instead of Tenney interval space. Explicitly, if we take the monzo |e2 e3 ... ep> then the Tenney-Euclidean norm, or TE norm, of it is
| | in which case it is called a '''monzo''', where the name refers to the enthusiastic advocacy of [[Joe Monzo]]. |
| [[math]]
| |
| \sqrt{e_2^2 + (e_3\log_2 3)^2 + \dotsb + (e_p\log_2 p)^2}
| |
| [[math]]
| |
| and if the coordinates are the weighted interval space coordinates, then the TE norm is the [[http://mathworld.wolfram.com/L2-Norm.html|standard Euclidean, or L2, norm]].
| |
|
| |
|
| =Alternate Definition:=
| | The [[Tenney height]] of this monzo is given by |
|
| |
|
| Given a rational number q, we can rewrite it in monzo form by the following definition:
| | <math>\| |e_2 \, e_3 \dotso e_p \rangle \| = |e_2| + |e_3| \log_2 3 + \dotsb + |e_p| \log_2 p</math> |
| [[math]]
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| q = |v_2 (q) \,v_3 (q) \, v_5 (q) \dotso v_p (q)\rangle
| |
| [[math]]
| |
|
| |
|
| The [[Tenney Height|Tenney height]] of this monzo is given by
| | which is a [[Wikipedia: Normed vector space|vector space norm]]; hence we may [[Wikipedia: Embedding|embed]] the ''p''-limit monzos into a normed vector I space of dimension ''n'' = π (''p'') via a map M:monzos ⟶ I. The monzos under this embedding now define a [[Wikipedia:Lattice %28group%29|lattice]], which is a discrete subgroup spanning the finite dimensional real normed vector space I. If we change coordinates by multiplying values in the coordinate belonging to the prime ''k'' by log<sub>2</sub> (''k''), then the norm becomes the standard [http://mathworld.wolfram.com/L1-Norm.html L1 norm]. This vector space is Tenney interval space, and the transformed coordinates with the standard L1 norm form the standard basis for Tenney space. It should be noted that while monzos correspond uniquely to positive real numbers (always rational numbers in the case of monzos), vectors in Tenney space do not. For instance, while {{monzo| 1 0 }} represents 2, so does {{monzo| 0 log<sub>3</sub> (2)}}. |
| [[math]] | |
| \| |v_2 (q) \, v_3 (q) \dotso v_p (q) \rangle \| = |v_2 (q)| + |v_3 (q)| \log_2 3 + \dotsb + |v_p (q)| \log_2 p
| |
| [[math]]
| |
|
| |
|
| Where vp(q) is the [[http://en.wikipedia.org/wiki/P-adic_order|p-adic valuation]] of q.
| | Because of the mathematical advantages of Euclidean norms, a Euclidean norm is often placed on the vectors in interval space instead of an L1 norm, in which case we have [[Tenney-Euclidean metrics|Tenney-Euclidean interval space]] instead of Tenney interval space. Explicitly, if we take the monzo {{monzo| ''e''<sub>2</sub> ''e''<sub>3</sub> … ''e''<sub>''p''</sub> }} then the Tenney-Euclidean norm, or TE norm, of it is |
|
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|
| =Example:= | | <math>\sqrt{e_2^2 + (e_3\log_2 3)^2 + \dotsb + (e_p\log_2 p)^2}</math> |
| | |
| | and if the coordinates are the weighted interval space coordinates, then the TE norm is the [http://mathworld.wolfram.com/L2-Norm.html standard Euclidean, or L2, norm]. |
| | |
| | == Alternate definition == |
| | Given a rational number ''q'', we can rewrite it in monzo form by the following definition: |
| | |
| | <math>q = |v_2 (q) \,v_3 (q) \, v_5 (q) \dotso v_p (q)\rangle</math> |
| | |
| | The [[Tenney height]] of this monzo is given by |
| | |
| | <math>\| |v_2 (q) \, v_3 (q) \dotso v_p (q) \rangle \| = |v_2 (q)| + |v_3 (q)| \log_2 3 + \dotsb + |v_p (q)| \log_2 p</math> |
| | |
| | Where ''v''<sub>''p''</sub> (''q'') is the [[Wikipedia: P-adic order|''p''-adic valuation]] of ''q''. |
| | |
| | == Example == |
| | The 5-limit interval 16/15 factors as 2<sup>4</sup> 3<sup>-1</sup> 5<sup>-1</sup>, so it has a monzo representation of {{monzo| 4 -1 -1 }}. In weighted coordinates, that becomes {{monzo| 4 -log<sub>2</sub> (3) -log<sub>2</sub> (5) }}, approximately {{monzo| 4 -1.585 -2.322 }}. |
|
| |
|
| The 5-limit interval 16/15 factors as 2^4 3^(-1) 5^(-1), so it has a monzo representation of |4 -1 -1>. In weighted coordinates, that becomes |4 -log2(3) -log2(5)>, approximately |4 -1.585 -2.322>.
| |
| The TE norm is therefore | | The TE norm is therefore |
| [[math]]
| |
| \sqrt{(4^2 + log2(3)^2 + log2(5)^2)} ≅ \sqrt{23.903} ≅ 4.889.
| |
|
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|
| [[math]] | | <math>\sqrt{(4^2 + \log_2(3)^2 + \log_2(5)^2)} ≅ \sqrt{23.903} ≅ 4.889. |
| | </math> |
| | |
| | == See also == |
| | * [[Fractional monzos]] |
| | * [[Vals and tuning space]] |
|
| |
|
| //see also [[Fractional monzos]], [[Vals and Tuning Space]]...//</pre></div>
| | [[Category:Regular temperament theory]] |
| <h4>Original HTML content:</h4>
| | [[Category:Interval space]] |
| <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"><html><head><title>Monzos and Interval Space</title></head><body><span style="display: block; text-align: right;">Other languages: <a class="wiki_link" href="https://xenharmonie.wikispaces.com/Intervallraum">Deutsch</a><br />
| | [[Category:Math]] |
| </span><br />
| | [[Category:Monzo]] |
| <br />
| |
| This page gives the formal mathematical definition of a monzo. For a simpler explanation with examples, visit the <a class="wiki_link" href="/monzos">monzos</a> page.<br />
| |
| <br />
| |
| <!-- ws:start:WikiTextHeadingRule:7:&lt;h1&gt; --><h1 id="toc0"><a name="Definition:"></a><!-- ws:end:WikiTextHeadingRule:7 -->Definition:</h1>
| |
| <br />
| |
| A <a class="wiki_link" href="/Harmonic%20Limit">p-limit</a> rational number q can by definition be factored into primes of size less than or equal to p, giving<br />
| |
| <!-- ws:start:WikiTextMathRule:0:
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| [[math]]&lt;br/&gt;
| |
| q = 2^{e_2} \, 3^{e_3} \, 5^{e_5} \dotso p^{e_p}&lt;br/&gt;[[math]]
| |
| --><script type="math/tex">q = 2^{e_2} \, 3^{e_3} \, 5^{e_5} \dotso p^{e_p}</script><!-- ws:end:WikiTextMathRule:0 --><br />
| |
| where the exponents are integers (positive, negative, or zero.) This is often written in <a class="wiki_link_ext" href="http://mathworld.wolfram.com/Ket.html" rel="nofollow">ket vector</a> (<a class="wiki_link_ext" href="http://en.wikipedia.org/wiki/Bra-ket_notation" rel="nofollow">wp</a>) notation as<br />
| |
| <!-- ws:start:WikiTextMathRule:1:
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| [[math]]&lt;br/&gt;
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| |e_2 \, e_3 \, e_5 \dotso e_p\rangle&lt;br/&gt;[[math]]
| |
| --><script type="math/tex">|e_2 \, e_3 \, e_5 \dotso e_p\rangle</script><!-- ws:end:WikiTextMathRule:1 --><br />
| |
| in which case it is called a <strong>monzo</strong>, where the name refers to the enthusiastic advocacy of <a class="wiki_link" href="/Joe%20Monzo">Joe Monzo</a>.<br />
| |
| <br />
| |
| The <a class="wiki_link" href="/Tenney%20Height">Tenney height</a> of this monzo is given by<br />
| |
| <!-- ws:start:WikiTextMathRule:2:
| |
| [[math]]&lt;br/&gt;
| |
| \| |e_2 \, e_3 \dotso e_p \rangle \| = |e_2| + |e_3| \log_2 3 + \dotsb + |e_p| \log_2 p&lt;br/&gt;[[math]]
| |
| --><script type="math/tex">\| |e_2 \, e_3 \dotso e_p \rangle \| = |e_2| + |e_3| \log_2 3 + \dotsb + |e_p| \log_2 p</script><!-- ws:end:WikiTextMathRule:2 --><br />
| |
| <br />
| |
| which is a <a class="wiki_link_ext" href="http://en.wikipedia.org/wiki/Normed_vector_space" rel="nofollow">vector space norm</a>; hence we may <a class="wiki_link_ext" href="http://en.wikipedia.org/wiki/Embedding" rel="nofollow">embed</a> the p-limit monzos into a normed vector I space of dimension n = π(p) via a map M:monzos ⟶ I. The monzos under this embedding now define a <a class="wiki_link_ext" href="http://en.wikipedia.org/wiki/Lattice_%28group%29" rel="nofollow">lattice</a>, which is a discrete subgroup spanning the finite dimensional real normed vector space I. If we change coordinates by multiplying values in the coordinate belonging to the prime k by log2(k), then the norm becomes the standard <a class="wiki_link_ext" href="http://mathworld.wolfram.com/L1-Norm.html" rel="nofollow">L1 norm</a>. This vector space is Tenney interval space, and the transformed coordinates with the standard L1 norm form the standard basis for Tenney space. It should be noted that while monzos correspond uniquely to positive real numbers (always rational numbers in the case of monzos), vectors in Tenney space do not. For instance, while |1 0&gt; represents 2, so does |0 log3(2)&gt;.<br />
| |
| <br />
| |
| Because of the mathematical advantages of Euclidean norms, a Euclidean norm is often placed on the vectors in interval space instead of an L1 norm, in which case we have <a class="wiki_link" href="/Tenney-Euclidean%20metrics">Tenney-Euclidean interval space</a> instead of Tenney interval space. Explicitly, if we take the monzo |e2 e3 ... ep&gt; then the Tenney-Euclidean norm, or TE norm, of it is<br />
| |
| <!-- ws:start:WikiTextMathRule:3:
| |
| [[math]]&lt;br/&gt;
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| \sqrt{e_2^2 + (e_3\log_2 3)^2 + \dotsb + (e_p\log_2 p)^2}&lt;br/&gt;[[math]]
| |
| --><script type="math/tex">\sqrt{e_2^2 + (e_3\log_2 3)^2 + \dotsb + (e_p\log_2 p)^2}</script><!-- ws:end:WikiTextMathRule:3 --><br />
| |
| and if the coordinates are the weighted interval space coordinates, then the TE norm is the <a class="wiki_link_ext" href="http://mathworld.wolfram.com/L2-Norm.html" rel="nofollow">standard Euclidean, or L2, norm</a>.<br />
| |
| <br />
| |
| <!-- ws:start:WikiTextHeadingRule:9:&lt;h1&gt; --><h1 id="toc1"><a name="Alternate Definition:"></a><!-- ws:end:WikiTextHeadingRule:9 -->Alternate Definition:</h1>
| |
| <br />
| |
| Given a rational number q, we can rewrite it in monzo form by the following definition:<br />
| |
| <!-- ws:start:WikiTextMathRule:4:
| |
| [[math]]&lt;br/&gt;
| |
| q = |v_2 (q) \,v_3 (q) \, v_5 (q) \dotso v_p (q)\rangle&lt;br/&gt;[[math]]
| |
| --><script type="math/tex">q = |v_2 (q) \,v_3 (q) \, v_5 (q) \dotso v_p (q)\rangle</script><!-- ws:end:WikiTextMathRule:4 --><br />
| |
| <br />
| |
| The <a class="wiki_link" href="/Tenney%20Height">Tenney height</a> of this monzo is given by<br />
| |
| <!-- ws:start:WikiTextMathRule:5:
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| [[math]]&lt;br/&gt;
| |
| \| |v_2 (q) \, v_3 (q) \dotso v_p (q) \rangle \| = |v_2 (q)| + |v_3 (q)| \log_2 3 + \dotsb + |v_p (q)| \log_2 p&lt;br/&gt;[[math]]
| |
| --><script type="math/tex">\| |v_2 (q) \, v_3 (q) \dotso v_p (q) \rangle \| = |v_2 (q)| + |v_3 (q)| \log_2 3 + \dotsb + |v_p (q)| \log_2 p</script><!-- ws:end:WikiTextMathRule:5 --><br />
| |
| <br />
| |
| Where vp(q) is the <a class="wiki_link_ext" href="http://en.wikipedia.org/wiki/P-adic_order" rel="nofollow">p-adic valuation</a> of q.<br />
| |
| <br />
| |
| <!-- ws:start:WikiTextHeadingRule:11:&lt;h1&gt; --><h1 id="toc2"><a name="Example:"></a><!-- ws:end:WikiTextHeadingRule:11 -->Example:</h1>
| |
| <br />
| |
| The 5-limit interval 16/15 factors as 2^4 3^(-1) 5^(-1), so it has a monzo representation of |4 -1 -1&gt;. In weighted coordinates, that becomes |4 -log2(3) -log2(5)&gt;, approximately |4 -1.585 -2.322&gt;.<br />
| |
| The TE norm is therefore<br />
| |
| <!-- ws:start:WikiTextMathRule:6:
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| [[math]]&lt;br/&gt;
| |
| \sqrt{(4^2 + log2(3)^2 + log2(5)^2)} ≅ \sqrt{23.903} ≅ 4.889.&lt;br /&gt;
| |
| &lt;br/&gt;[[math]]
| |
| --><script type="math/tex">\sqrt{(4^2 + log2(3)^2 + log2(5)^2)} ≅ \sqrt{23.903} ≅ 4.889.
| |
| </script><!-- ws:end:WikiTextMathRule:6 --><br />
| |
| <br />
| |
| <em>see also <a class="wiki_link" href="/Fractional%20monzos">Fractional monzos</a>, <a class="wiki_link" href="/Vals%20and%20Tuning%20Space">Vals and Tuning Space</a>...</em></body></html></pre></div>
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|
This is an expert page. It is written to allow experienced readers to learn more about the advanced elements of the topic.
The corresponding beginner page for this topic is Monzo.
|
This page gives the formal mathematical definition of a monzo and shows its relation to interval space.
Definition
A p-limit rational number q can by definition be factored into primes of size less than or equal to p, giving
[math]\displaystyle{ q = 2^{e_2} \, 3^{e_3} \, 5^{e_5} \dotso p^{e_p} }[/math]
where the exponents are integers (positive, negative, or zero.) This is often written in ket vector (→ Wikipedia: Bra-ket notation) notation as
[math]\displaystyle{ |e_2 \, e_3 \, e_5 \dotso e_p\rangle }[/math]
in which case it is called a monzo, where the name refers to the enthusiastic advocacy of Joe Monzo.
The Tenney height of this monzo is given by
[math]\displaystyle{ \| |e_2 \, e_3 \dotso e_p \rangle \| = |e_2| + |e_3| \log_2 3 + \dotsb + |e_p| \log_2 p }[/math]
which is a vector space norm; hence we may embed the p-limit monzos into a normed vector I space of dimension n = π (p) via a map M:monzos ⟶ I. The monzos under this embedding now define a lattice, which is a discrete subgroup spanning the finite dimensional real normed vector space I. If we change coordinates by multiplying values in the coordinate belonging to the prime k by log2 (k), then the norm becomes the standard L1 norm. This vector space is Tenney interval space, and the transformed coordinates with the standard L1 norm form the standard basis for Tenney space. It should be noted that while monzos correspond uniquely to positive real numbers (always rational numbers in the case of monzos), vectors in Tenney space do not. For instance, while [1 0⟩ represents 2, so does [0 log3 (2)⟩.
Because of the mathematical advantages of Euclidean norms, a Euclidean norm is often placed on the vectors in interval space instead of an L1 norm, in which case we have Tenney-Euclidean interval space instead of Tenney interval space. Explicitly, if we take the monzo [e2 e3 … ep⟩ then the Tenney-Euclidean norm, or TE norm, of it is
[math]\displaystyle{ \sqrt{e_2^2 + (e_3\log_2 3)^2 + \dotsb + (e_p\log_2 p)^2} }[/math]
and if the coordinates are the weighted interval space coordinates, then the TE norm is the standard Euclidean, or L2, norm.
Alternate definition
Given a rational number q, we can rewrite it in monzo form by the following definition:
[math]\displaystyle{ q = |v_2 (q) \,v_3 (q) \, v_5 (q) \dotso v_p (q)\rangle }[/math]
The Tenney height of this monzo is given by
[math]\displaystyle{ \| |v_2 (q) \, v_3 (q) \dotso v_p (q) \rangle \| = |v_2 (q)| + |v_3 (q)| \log_2 3 + \dotsb + |v_p (q)| \log_2 p }[/math]
Where vp (q) is the p-adic valuation of q.
Example
The 5-limit interval 16/15 factors as 24 3-1 5-1, so it has a monzo representation of [4 -1 -1⟩. In weighted coordinates, that becomes [4 -log2 (3) -log2 (5)⟩, approximately [4 -1.585 -2.322⟩.
The TE norm is therefore
[math]\displaystyle{ \sqrt{(4^2 + \log_2(3)^2 + \log_2(5)^2)} ≅ \sqrt{23.903} ≅ 4.889.
}[/math]
See also
