Stretched and compressed tuning: Difference between revisions
m →In xenharmonic music: Added phoenix |
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* [[Musical cells]] | * [[Musical cells]] | ||
* [[Pelog]] | * [[Pelog]] | ||
* [[Phoenix]] tuning | |||
* [[The Riemann zeta function and tuning#Optimal octave stretch|Optimal octave stretch]] (zeta stretch) | * [[The Riemann zeta function and tuning#Optimal octave stretch|Optimal octave stretch]] (zeta stretch) | ||
** [[5- to 8-tone scales in zeta stretched 15edo]] | ** [[5- to 8-tone scales in zeta stretched 15edo]] | ||
Revision as of 04:18, 27 January 2024
In stretched tuning, two notes an equivalence apart, whose fundamental frequencies theoretically have an exact ratio, are tuned slightly farther apart (a stretched equivalence).
In compressed tuning, also known as narrowed tuning, two notes an equivalence apart, whose fundamental frequencies theoretically have an exact ratio, are tuned slightly closer together (a compressed or narrowed equivalence).
In 12edo
Stretched tuning is used even outside of a xenharmonic context. Most acoustic and some electric pianos have overtones which do not exactly line up with the harmonic series, so stretched octaves are usually used to compensate.
In xenharmonic music
Within a xenharmonic context, stretched or compressed tuning may be used to reduce the harmonic entropy of a scale without sacrificing its melodic shape, or to achieve other artistic goals.
Examples include (but are not limited to):
- 23edo and octave stretching
- 27edo and octave compression
- Musical cells
- Pelog
- Phoenix tuning
- Optimal octave stretch (zeta stretch)
- Stretched harmonic series