The twelfth root of two or (or equivalently) is an algebraicirrational number, approximately equal to 1.0594631. It is most important in Western music theory, where it represents the frequencyratio (musical interval) of a semitone (Playⓘ) in twelve-tone equal temperament. This number was proposed for the first time in relationship to musical tuning in the sixteenth and seventeenth centuries. It allows measurement and comparison of different intervals (frequency ratios) as consisting of different numbers of a single interval, the equal tempered semitone (for example, a minor third is 3 semitones, a major third is 4 semitones, and perfect fifth is 7 semitones).[a] A semitone itself is divided into 100 cents (1 cent = ).
Octaves (12 semitones) increase exponentially when measured on a linear frequency scale (Hz).
Octaves are equally spaced when measured on a logarithmic scale (cents).
The twelfth root of two to 20 significant figures is 1.0594630943592952646.[2] Fraction approximations in increasing order of accuracy include 18/17, 89/84, 196/185, 1657/1564, and 18904/17843.
As of December 2013[update], its numerical value has been computed to at least twenty billion decimal digits.[3]
The equal-tempered chromatic scaleedit
A musical interval is a ratio of frequencies and the equal-tempered chromatic scale divides the octave (which has a ratio of 2:1) into twelve equal parts. Each note has a frequency that is 21⁄12 times that of the one below it.[citation needed]
Applying this value successively to the tones of a chromatic scale, starting from A above middle C (known as A4) with a frequency of 440 Hz, produces the following sequence of pitches:
The final A (A5: 880 Hz) is exactly twice the frequency of the lower A (A4: 440 Hz), that is, one octave higher.
Other tuning scalesedit
Other tuning scales use slightly different interval ratios:
The just or Pythagorean perfect fifth is 3/2, and the difference between the equal tempered perfect fifth and the just is a grad, the twelfth root of the Pythagorean comma (12√531441/524288).
The equal tempered Bohlen–Pierce scale uses the interval of the thirteenth root of three (13√3).
Stockhausen's Studie II (1954) makes use of the twenty-fifth root of five (25√5), a compound major third divided into 5×5 parts.
One octave of 12-tet on a monochord (linear)The chromatic circle depicts equal distances between notes (logarithmic)
Since the frequency ratio of a semitone is close to 106% (), increasing or decreasing the playback speed of a recording by 6% will shift the pitch up or down by about one semitone, or "half-step". Upscale reel-to-reel magnetic tape recorders typically have pitch adjustments of up to ±6%, generally used to match the playback or recording pitch to other music sources having slightly different tunings (or possibly recorded on equipment that was not running at quite the right speed). Modern recording studios utilize digital pitch shifting to achieve similar results, ranging from cents up to several half-steps (note that reel-to-reel adjustments also affect the tempo of the recorded sound, while digital shifting does not).
Historyedit
Historically this number was proposed for the first time in relationship to musical tuning in 1580 (drafted, rewritten 1610) by Simon Stevin.[4] In 1581 Italian musician Vincenzo Galilei may be the first European to suggest twelve-tone equal temperament.[1] The twelfth root of two was first calculated in 1584 by the Chinese mathematician and musician Zhu Zaiyu using an abacus to reach twenty four decimal places accurately,[1] calculated circa 1605 by Flemish mathematician Simon Stevin,[1] in 1636 by the French mathematician Marin Mersenne and in 1691 by German musician Andreas Werckmeister.[5]
^"The smallest interval in an equal-tempered scale is the ratio , so , where the ratio r divides the ratio p (= 2/1 in an octave) into n equal parts."[1]
^Komsta, Łukasz. "Computations page". Komsta.net. Retrieved 23 December 2016.[unreliable source?]
^Christensen, Thomas (2002), The Cambridge History of Western Music Theory, p. 205, ISBN978-0521686983
^Goodrich, L. Carrington (2013). A Short History of the Chinese People, [unpaginated]. Courier. ISBN9780486169231. Cites: Chu Tsai-yü (1584). New Remarks on the Study of Resonant Tubes.
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The twelfth root of two or 2 12 sqrt 12 2 or equivalently 2 1 12 displaystyle 2 1 12 is an algebraic irrational number approximately equal to 1 0594631 It is most important in Western music theory where it represents the frequency ratio musical interval of a semitone Play in twelve tone equal temperament This number was proposed for the first time in relationship to musical tuning in the sixteenth and seventeenth centuries It allows measurement and comparison of different intervals frequency ratios as consisting of different numbers of a single interval the equal tempered semitone for example a minor third is 3 semitones a major third is 4 semitones and perfect fifth is 7 semitones a A semitone itself is divided into 100 cents 1 cent 2 1200 2 1 1200 displaystyle sqrt 1200 2 2 1 1200 Octaves 12 semitones increase exponentially when measured on a linear frequency scale Hz Octaves are equally spaced when measured on a logarithmic scale cents Contents 1 Numerical value 2 The equal tempered chromatic scale 2 1 Other tuning scales 3 Pitch adjustment 4 History 5 See also 6 Notes 7 References 8 Further readingNumerical value editThe twelfth root of two to 20 significant figures is 1 059463 094 359 295 2646 2 Fraction approximations in increasing order of accuracy include 18 17 89 84 196 185 1657 1564 and 18904 17843 As of December 2013 update its numerical value has been computed to at least twenty billion decimal digits 3 The equal tempered chromatic scale editA musical interval is a ratio of frequencies and the equal tempered chromatic scale divides the octave which has a ratio of 2 1 into twelve equal parts Each note has a frequency that is 21 12 times that of the one below it citation needed Applying this value successively to the tones of a chromatic scale starting from A above middle C known as A4 with a frequency of 440 Hz produces the following sequence of pitches Note Standard interval name s relating to A 440 Frequency Hz Multiplier Coefficient to six places Just intonation ratioA Unison 440 00 20 12 1 000000 1A B Minor second Half step Semitone 466 16 21 12 1 059463 16 15B Major second Full step Whole tone 493 88 22 12 1 122462 9 8C Minor third 523 25 23 12 1 189207 6 5C D Major third 554 37 24 12 1 259921 5 4D Perfect fourth 587 33 25 12 1 334839 4 3D E Augmented fourth Diminished fifth Tritone 622 25 26 12 1 414213 7 5E Perfect fifth 659 26 27 12 1 498307 3 2F Minor sixth 698 46 28 12 1 587401 8 5F G Major sixth 739 99 29 12 1 681792 5 3G Minor seventh 783 99 210 12 1 781797 16 9G A Major seventh 830 61 211 12 1 887748 15 8A Octave 880 00 212 12 2 000000 2The final A A5 880 Hz is exactly twice the frequency of the lower A A4 440 Hz that is one octave higher Other tuning scales edit Other tuning scales use slightly different interval ratios The just or Pythagorean perfect fifth is 3 2 and the difference between the equal tempered perfect fifth and the just is a grad the twelfth root of the Pythagorean comma 12 531441 524288 The equal tempered Bohlen Pierce scale uses the interval of the thirteenth root of three 13 3 Stockhausen s Studie II 1954 makes use of the twenty fifth root of five 25 5 a compound major third divided into 5 5 parts The delta scale is based on 50 3 2 The gamma scale is based on 20 3 2 The beta scale is based on 11 3 2 The alpha scale is based on 9 3 2 Pitch adjustment editSee also Audio time stretching and pitch scaling nbsp One octave of 12 tet on a monochord linear nbsp The chromatic circle depicts equal distances between notes logarithmic Since the frequency ratio of a semitone is close to 106 1 05946 100 105 946 displaystyle 1 05946 times 100 105 946 nbsp increasing or decreasing the playback speed of a recording by 6 will shift the pitch up or down by about one semitone or half step Upscale reel to reel magnetic tape recorders typically have pitch adjustments of up to 6 generally used to match the playback or recording pitch to other music sources having slightly different tunings or possibly recorded on equipment that was not running at quite the right speed Modern recording studios utilize digital pitch shifting to achieve similar results ranging from cents up to several half steps note that reel to reel adjustments also affect the tempo of the recorded sound while digital shifting does not History editHistorically this number was proposed for the first time in relationship to musical tuning in 1580 drafted rewritten 1610 by Simon Stevin 4 In 1581 Italian musician Vincenzo Galilei may be the first European to suggest twelve tone equal temperament 1 The twelfth root of two was first calculated in 1584 by the Chinese mathematician and musician Zhu Zaiyu using an abacus to reach twenty four decimal places accurately 1 calculated circa 1605 by Flemish mathematician Simon Stevin 1 in 1636 by the French mathematician Marin Mersenne and in 1691 by German musician Andreas Werckmeister 5 See also editFret Just intonation Practical difficulties Music and mathematics Piano key frequencies Scientific pitch notation Twelve tone technique The Well Tempered ClavierNotes edit The smallest interval in an equal tempered scale is the ratio r n p displaystyle r n p nbsp so r p n displaystyle r sqrt n p nbsp where the ratio r divides the ratio p 2 1 in an octave into n equal parts 1 References edit a b c d Joseph George Gheverghese 2010 The Crest of the Peacock Non European Roots of Mathematics p 294 5 Third edition Princeton ISBN 9781400836369 Sloane N J A ed Sequence A010774 Decimal expansion of 12th root of 2 The On Line Encyclopedia of Integer Sequences OEIS Foundation Komsta Lukasz Computations page Komsta net Retrieved 23 December 2016 unreliable source Christensen Thomas 2002 The Cambridge History of Western Music Theory p 205 ISBN 978 0521686983 Goodrich L Carrington 2013 A Short History of the Chinese People unpaginated Courier ISBN 9780486169231 Cites Chu Tsai yu 1584 New Remarks on the Study of Resonant Tubes Further reading editBarbour J M 1933 A Sixteenth Century Chinese Approximation for p American Mathematical Monthly 40 2 69 73 doi 10 2307 2300937 JSTOR 2300937 Ellis Alexander Helmholtz Hermann 1954 On the Sensations of Tone Dover Publications ISBN 0 486 60753 4 Partch Harry 1974 Genesis of a Music Da Capo Press ISBN 0 306 80106 X Retrieved from https en wikipedia org w index php title Twelfth root of two amp oldid 1175689675, wikipedia, wiki, book, books, library,
