ELD: Difference between revisions
Cmloegcmluin (talk | contribs) add formula for mathematician benefit |
Cmloegcmluin (talk | contribs) →Examples: update row headers per agreement at https://en.xen.wiki/w/Talk:APS |
||
| (7 intermediate revisions by 3 users not shown) | |||
| Line 1: | Line 1: | ||
An '''ELD''', or ''' | An '''ELD''' ('''equal length division'''), '''ALD''' ('''arithmetic length division'''), or '''IFD''' ('''inverse-arithmetic frequency division'''), is an [[Arithmetic tunings|arithmetic]] and [[period]]ic [[tuning]] in which each period is divided to a number of steps of equal length difference. | ||
== Specification == | |||
Its full specification is ''n''-ELD-''p'' (''n'' equal length divisions of ''p''), or ''n''-ALD-''p'' (''n'' arithmetic length divisions of ''p''), or ''n''-IFD-''p'' (''n'' inverse-arithmetic frequency division of ''p''). | |||
== Formula == | |||
To find the steps for an ''n''-ELD-''p'', begin by recognizing that while the ratio between your root pitch's string length and the length you would pluck to get the lowest pitch is <span><math>p</math></span> (or <span><math>\frac p1</math></span>), if you are going to move arithmetically (by repeated addition) from <span><math>1</math></span> to <span><math>p</math></span>, then the difference in string length that you need to cover is not actually <span><math>p</math></span>, but only <span><math>p - 1</math></span>. And because you are dividing it into <span><math>n</math></span> parts, each step will have a size of <span><math>\frac{p-1}{n}</math></span>. So, the formula for the length of step <span><math>k</math></span> of an n-ELDp is: | |||
To find the steps for an n- | |||
<math> | <math> | ||
| Line 18: | Line 14: | ||
This way, when <span><math>k</math></span> is <span><math>0</math></span>, <span><math>L(k)</math></span> is simply <span><math>1</math></span>. And when <span><math>k</math></span> is <span><math>n</math></span>, <span><math>L(k)</math></span> is simply <span><math>1 + (p-1) = p</math></span>. | This way, when <span><math>k</math></span> is <span><math>0</math></span>, <span><math>L(k)</math></span> is simply <span><math>1</math></span>. And when <span><math>k</math></span> is <span><math>n</math></span>, <span><math>L(k)</math></span> is simply <span><math>1 + (p-1) = p</math></span>. | ||
== Tip about tunings based on length == | |||
Note that because frequency is the inverse of length, if a frequency lower than the root pitch's frequency is asked for, the length will be greater than 1; at this point the physical analogy to a length of string breaks down somewhat, since it is not easy to imagine dynamically extending the length of a string to accommodate such pitches. However, it is not much of a stretch (pun intended) to tolerate lengths > 1, if the analogy is adapted to a switching from one string to another, and any string length imaginable is instantly available. | |||
== Relationship to other tunings == | |||
=== Vs. EPD === | |||
It is possible to — instead of equally dividing the octave in 12 equal parts by pitch — divide it into 12 equal parts by '''length'''. You will have 12-ELDO. However, that's not exactly ideal because, as with arithmetic sequences, different acronyms are used to distinguish rational (JI) tunings from irrational (non-JI) tunings, and so ELD are typically reserved for irrational tunings, such as 12-ELDφ. So it would be more appropriate to name this tuning 12-UDO, for utonal divisions of the octave. | |||
=== Vs. UD === | |||
An [[UD|''n''-UD-''p'' (or utonal division)]] is equivalent to an ''n''-ELD-''p'' except that the period ''p'' of the UD must be rational. | |||
=== Vs. EFD === | |||
The analogous otonal equivalent of an ELD is an [[EFD|EFD (equal frequency division)]]. | |||
=== Vs. ALS === | |||
One period of an ELD will be equivalent to some [[ALS|ALS (arithmetic length sequence)]]; specifically ''n''-ELD((''p'' - 1)/''n'') = ''n''-ALS-''p''. | |||
=== Vs. EDL === | |||
An ELD is not to be confused with [[EDL|EDL, equal division of length]]. The latter term does not take an interval parameter because it is assumed to be the length of an entire string, and then only an octave subset of that is taken. | |||
== Examples == | |||
{| class="wikitable" | {| class="wikitable" | ||
| Line 30: | Line 54: | ||
! 4 | ! 4 | ||
|- | |- | ||
! frequency (f) | ! frequency (''f'', ratio) | ||
|(1) | |(1) | ||
|1.11 | |1.11 | ||
| Line 37: | Line 61: | ||
|φ | |φ | ||
|- | |- | ||
! pitch ( | ! pitch (log₂''f'', octaves) | ||
|(0) | |(0) | ||
|0.14 | |0.14 | ||
| Line 44: | Line 68: | ||
|0.69 | |0.69 | ||
|- | |- | ||
! length (1/f) | ! length (1/''f'', ratio) | ||
|(1) | |(1) | ||
|0.90 | |0.90 | ||
| Line 62: | Line 86: | ||
! 4 | ! 4 | ||
|- | |- | ||
! frequency (f) | ! frequency (''f'', ratio) | ||
|(1) | |(1) | ||
|0.87 | |0.87 | ||
| Line 69: | Line 93: | ||
|1/φ | |1/φ | ||
|- | |- | ||
! pitch ( | ! pitch (log₂''f'', octaves) | ||
|(0) | |(0) | ||
| -0.21 | | -0.21 | ||
| Line 76: | Line 100: | ||
| -0.69 | | -0.69 | ||
|- | |- | ||
! length (1/f) | ! length (1/''f'', ratio) | ||
|(1+(0/4)(φ-1)) = (0φ + 4)/4 = 1 | |(1+(0/4)(φ-1)) = (0φ + 4)/4 = 1 | ||
|1+(1/4)(φ-1) = (1φ + 3)/4 | |1+(1/4)(φ-1) = (1φ + 3)/4 | ||
| Line 84: | Line 108: | ||
|} | |} | ||
[[Category:Utonality]] | [[Category:Utonality]] | ||
[[Category:Subharmonic]] | [[Category:Subharmonic]] | ||
[[Category:Subharmonic series]] | [[Category:Subharmonic series]] | ||
Latest revision as of 20:37, 19 October 2023
An ELD (equal length division), ALD (arithmetic length division), or IFD (inverse-arithmetic frequency division), is an arithmetic and periodic tuning in which each period is divided to a number of steps of equal length difference.
Specification
Its full specification is n-ELD-p (n equal length divisions of p), or n-ALD-p (n arithmetic length divisions of p), or n-IFD-p (n inverse-arithmetic frequency division of p).
Formula
To find the steps for an n-ELD-p, begin by recognizing that while the ratio between your root pitch's string length and the length you would pluck to get the lowest pitch is [math]\displaystyle{ p }[/math] (or [math]\displaystyle{ \frac p1 }[/math]), if you are going to move arithmetically (by repeated addition) from [math]\displaystyle{ 1 }[/math] to [math]\displaystyle{ p }[/math], then the difference in string length that you need to cover is not actually [math]\displaystyle{ p }[/math], but only [math]\displaystyle{ p - 1 }[/math]. And because you are dividing it into [math]\displaystyle{ n }[/math] parts, each step will have a size of [math]\displaystyle{ \frac{p-1}{n} }[/math]. So, the formula for the length of step [math]\displaystyle{ k }[/math] of an n-ELDp is:
[math]\displaystyle{ L(k) = 1 + (\frac kn)(p-1) }[/math]
This way, when [math]\displaystyle{ k }[/math] is [math]\displaystyle{ 0 }[/math], [math]\displaystyle{ L(k) }[/math] is simply [math]\displaystyle{ 1 }[/math]. And when [math]\displaystyle{ k }[/math] is [math]\displaystyle{ n }[/math], [math]\displaystyle{ L(k) }[/math] is simply [math]\displaystyle{ 1 + (p-1) = p }[/math].
Tip about tunings based on length
Note that because frequency is the inverse of length, if a frequency lower than the root pitch's frequency is asked for, the length will be greater than 1; at this point the physical analogy to a length of string breaks down somewhat, since it is not easy to imagine dynamically extending the length of a string to accommodate such pitches. However, it is not much of a stretch (pun intended) to tolerate lengths > 1, if the analogy is adapted to a switching from one string to another, and any string length imaginable is instantly available.
Relationship to other tunings
Vs. EPD
It is possible to — instead of equally dividing the octave in 12 equal parts by pitch — divide it into 12 equal parts by length. You will have 12-ELDO. However, that's not exactly ideal because, as with arithmetic sequences, different acronyms are used to distinguish rational (JI) tunings from irrational (non-JI) tunings, and so ELD are typically reserved for irrational tunings, such as 12-ELDφ. So it would be more appropriate to name this tuning 12-UDO, for utonal divisions of the octave.
Vs. UD
An n-UD-p (or utonal division) is equivalent to an n-ELD-p except that the period p of the UD must be rational.
Vs. EFD
The analogous otonal equivalent of an ELD is an EFD (equal frequency division).
Vs. ALS
One period of an ELD will be equivalent to some ALS (arithmetic length sequence); specifically n-ELD((p - 1)/n) = n-ALS-p.
Vs. EDL
An ELD is not to be confused with EDL, equal division of length. The latter term does not take an interval parameter because it is assumed to be the length of an entire string, and then only an octave subset of that is taken.
Examples
| quantity | (0) | 1 | 2 | 3 | 4 |
|---|---|---|---|---|---|
| frequency (f, ratio) | (1) | 1.11 | 1.24 | 1.40 | φ |
| pitch (log₂f, octaves) | (0) | 0.14 | 0.31 | 0.49 | 0.69 |
| length (1/f, ratio) | (1) | 0.90 | 0.81 | 0.71 | 1/φ |
| quantity | (0) | 1 | 2 | 3 | 4 |
|---|---|---|---|---|---|
| frequency (f, ratio) | (1) | 0.87 | 0.76 | 0.68 | 1/φ |
| pitch (log₂f, octaves) | (0) | -0.21 | -0.39 | -0.55 | -0.69 |
| length (1/f, ratio) | (1+(0/4)(φ-1)) = (0φ + 4)/4 = 1 | 1+(1/4)(φ-1) = (1φ + 3)/4 | 1+(2/4)(φ-1) = (2φ + 2)/4 | 1+(3/4)(φ-1) = (3φ + 1)/4 | 1+(4/4)(φ-1) = (4φ + 0)/4 = φ |