Superparticular ratio

Superparticular numbers are ratios of the form (n+1)/n, or 1+1/n, where n is a whole number other than 1. In ancient Greece they were known as Epimoric (επιμοριοσ, epimorios) ratios, which is literally translated as "above a part."

These ratios have some peculiar properties:
* The difference tone of the dyad is also the virtual fundamental.
* The first 6 such ratios ([[3_2|3/2]], [[4_3|4/3]], [[5_4|5/4]], [[6_5|6/5]], [[7_6|7/6]], [[8_7|8/7]]) are notable [[harmonic entropy]] minima.
* The difference (i.e. quotient) between two successive epimoric ratios is always an epimoric ratio.
* The sum (i.e. product) of two successive epimoric ratios is either an epimoric ratio or an [[Superpartient|epimeric ratio]].
* Every epimoric ratio can be split into the product of two epimoric ratios. One way is via the identity 1+1/n = (1+1/(2n))*(1+1/(2n+1)), but more than one such splitting method may exist.
* If a/b and c/d are Farey neighbors, that is if a/b < c/d and bc - ad = 1, then (c/d)/(a/b) = bc/ad is epimoric.

Curiously enough, the ancient Greeks did not consider 2/1 to be superparticular because it is a [[Harmonic|multiple of the fundamental]] (the same rule applies to all natural harmonics in the Greek system).

See: [[List of Superparticular Intervals]] and the Wikipedia page for [[http://en.wikipedia.org/wiki/Superparticular_number|Superparticular number]].

<html><head><title>superparticular</title></head><body>Superparticular numbers are ratios of the form (n+1)/n, or 1+1/n, where n is a whole number other than 1. In ancient Greece they were known as Epimoric (επιμοριοσ, epimorios) ratios, which is literally translated as &quot;above a part.&quot;<br />
<br />
These ratios have some peculiar properties:<br />
<ul><li>The difference tone of the dyad is also the virtual fundamental.</li><li>The first 6 such ratios (<a class="wiki_link" href="/3_2">3/2</a>, <a class="wiki_link" href="/4_3">4/3</a>, <a class="wiki_link" href="/5_4">5/4</a>, <a class="wiki_link" href="/6_5">6/5</a>, <a class="wiki_link" href="/7_6">7/6</a>, <a class="wiki_link" href="/8_7">8/7</a>) are notable <a class="wiki_link" href="/harmonic%20entropy">harmonic entropy</a> minima.</li><li>The difference (i.e. quotient) between two successive epimoric ratios is always an epimoric ratio.</li><li>The sum (i.e. product) of two successive epimoric ratios is either an epimoric ratio or an <a class="wiki_link" href="/Superpartient">epimeric ratio</a>.</li><li>Every epimoric ratio can be split into the product of two epimoric ratios. One way is via the identity 1+1/n = (1+1/(2n))*(1+1/(2n+1)), but more than one such splitting method may exist.</li><li>If a/b and c/d are Farey neighbors, that is if a/b &lt; c/d and bc - ad = 1, then (c/d)/(a/b) = bc/ad is epimoric.</li></ul><br />
Curiously enough, the ancient Greeks did not consider 2/1 to be superparticular because it is a <a class="wiki_link" href="/Harmonic">multiple of the fundamental</a> (the same rule applies to all natural harmonics in the Greek system).<br />
<br />
See: <a class="wiki_link" href="/List%20of%20Superparticular%20Intervals">List of Superparticular Intervals</a> and the Wikipedia page for <a class="wiki_link_ext" href="http://en.wikipedia.org/wiki/Superparticular_number" rel="nofollow">Superparticular number</a>.</body></html>