Cent (music)

One cent compared to a semitone on a truncated monochord.
Octaves increase exponentially when measured on a linear frequency scale (Hz).
Octaves are equally spaced when measured on a logarithmic scale (cents).

The cent is a logarithmic unit of measure used for musical intervals. Twelve-tone equal temperament divides the octave into 12 semitones of 100 cents each. Typically, cents are used to express small intervals, or to compare the sizes of comparable intervals in different tuning systems, and in fact the interval of one cent is too small to be heard between successive notes.

Alexander J. Ellis based the measure on the acoustic logarithms decimal semitone system developed by Gaspard de Prony in the 1830s, at Robert Holford Macdowell Bosanquet's suggestion. Ellis made extensive measurements of musical instruments from around the world, using cents extensively to report and compare the scales employed,[1] and further described and employed the system in his 1875 edition of Hermann von Helmholtz's On the Sensations of Tone. It has become the standard method of representing and comparing musical pitches and intervals.[2][3]


Comparison of equal-tempered (black) and Pythagorean (green) intervals showing the relationship between frequency ratio and the intervals' values, in cents.

Like a decibel's relation to intensity, a cent is a ratio between two close frequencies. For the ratio to remain constant over the frequency spectrum, the frequency range encompassed by a cent must be proportional to the two frequencies. An equally tempered semitone (the interval between two adjacent piano keys) spans 100 cents by definition. An octave—two notes that have a frequency ratio of 2:1 -- spans twelve semitones and therefore 1200 cents. Since a frequency raised by one cent is simply multiplied by this constant cent value, and 1200 cents doubles a frequency, the ratio of frequencies one cent apart is precisely equal to 21/1200, the 1200th root of 2, which is approximately 1.0005777895.

If one knows the frequencies a and b of two notes, the number of cents measuring the interval from a to b may be calculated by the following formula (similar to the definition of decibel):

Likewise, if one knows a note a and the number n of cents in the interval from a to b, then b may be calculated by:

To compare different tuning systems, convert the various interval sizes into cents. For example, in just intonation the major third is represented by the frequency ratio 5:4. Applying the formula at the top shows that this is about 386 cents. The equivalent interval on the equal-tempered piano would be 400 cents. The difference, 14 cents, is about a seventh of a half step, easily audible.

Piecewise linear approximation

As x increases from 0 to 1/12, the function 2x increases almost linearly from 1.00000 to 1.05946. The exponential cent scale can therefore be accurately approximated as a piecewise linear function that is numerically correct at semitones. That is, n cents for n from 0 to 100 may be approximated as 1+0.0005946n instead of 2n/1200. The rounded error is zero when n is 0 or 100, and is about 0.72 cents high when n is 50, where the correct value of 21/24 = 1.02930 is approximated by 1 + 0.0005946*50 = 1.02973. This error is well below anything humanly audible, making this piecewise linear approximation adequate for most practical purposes.

Human perception

Waveforms of a unison (blue) versus a cent (red), nearly indistinguishable.

It is difficult to establish how many cents are perceptible to humans; this accuracy varies greatly from person to person. One author stated that humans can distinguish a difference in pitch of about 5-6 cents.[4] The threshold of what is perceptible, technically known as the just noticeable difference (JND), also varies as a function of the frequency, the amplitude and the timbre. In one study, changes in tone quality reduced student musicians' ability to recognize, as out-of-tune, pitches that deviated from their appropriate values by ±12 cents.[5] It has also been established that increased tonal context enables listeners to judge pitch more accurately.[6] Free, online web sites for self-testing are available.[7] "While intervals of less than a few cents are imperceptible to the human ear in a melodic context, in harmony very small changes can cause large changes in beats and roughness of chords."[8]

When listening to pitches with vibrato, there is evidence that humans perceive the mean frequency as the center of the pitch.[9] One study of modern performances of Schubert's Ave Maria found that vibrato span typically ranged between ±34 cents and ±123 cents with a mean of ±71 cents and noted higher variation in Verdi's opera arias.[10]

Normal adults are able to recognize pitch differences of as small as 25 cents very reliably. Adults with amusia, however, have trouble recognizing differences of less than 100 cents and sometimes have trouble with these or larger intervals.[11]


A centitone (also Iring) is a musical interval (21/600) of two cents (22/1200)[12] proposed as a unit of measurement ( Play ) by Widogast Iring in Die reine Stimmung in der Musik (1898) as 600 steps per octave and later by Joseph Yasser in A Theory of Evolving Tonality (1932) as 100 steps per equal tempered whole tone.

Iring noticed that the Grad/Werckmeister (1.96 cents, 12 per Pythagorean comma) and the schisma (1.95 cents) are nearly the same (≈ 614 steps per octave) and both may be approximated by 600 steps per octave (2 cents).[13] Yasser promoted the decitone, centitone, and millitone (10, 100, and 1000 steps per whole tone = 60, 600, and 6000 steps per octave = 20, 2, and 0.2 cents).[14][15]

For example: Equal tempered perfect fifth = 700 cents = 175.6 savarts = 583.3 millioctaves = 350 centitones.[16]

Centitones Cents
1 centitone 2 cents
0.5 centitone 1 cents
21/600 22/1200
50 per semitone 100 per semitone
100 per whole tone 200 per whole tone

Sound files

The following audio files play various intervals. In each case the first note played is middle C. The next note is sharper than C by the assigned value in cents. Finally, the two notes are played simultaneously.

Note that the JND for pitch difference is 5-6 cents. Played separately, the notes may not show an audible difference, but when they are played together, beating may be heard (for example if middle C and a note 10 cents higher are played). At any particular instant, the two waveforms reinforce or cancel each other more or less, depending on their instantaneous phase relationship. A piano tuner may verify tuning accuracy by timing the beats when two strings are sounded at once.

 Play middle C & 1 cent above , beat frequency = 0.16 Hz
 Play middle C & 10.06 cents above , beat frequency = 1.53 Hz
 Play middle C & 25 cents above , beat frequency = 3.81 Hz

One Cent Interval
The file plays middle C, a tone 1 cent sharper, and both tones together.

Problems playing this file? See media help.
Six Cents Interval
The file plays middle C, a tone 6 cents sharper, and both tones together.

Problems playing this file? See media help.
Ten Cents Interval
The file plays middle C, a tone 10 cents sharper, and both tones together.

Problems playing this file? See media help.

See also



  1. Alexander Ellis: On the Musical Scales of Various Nations HTML transcription of the 1885 article in the Journal of the Society of Arts (Accessed September 2008)
  2. Benson, Dave (2007). Music: A Mathematical Offering, p.166. Cambridge. ISBN 9780521853873. "The system most often employed in the modern literature."
  3. Renold, Maria (2004). Intervals, Scales, Tones and the Concert Pitch C =128 Hz, p.138. Translated from German by Bevis Stevens, edited by Anna Meuss (1998). Temple Lodge. ISBN 9781902636467. "Interval proportions can be converted to the cent values which are in common use today."
  4. D.B. Loeffler, "Instrument Timbres and Pitch Estimation in Polyphonic Music". Master's Thesis, Department of Electrical and Computer Engineering, Georgia Tech. April (2006)
  5. J. M. Geringer; M.D. Worthy, "Effects of Tone-Quality Changes on Intonation and Tone-Quality Ratings of High School and College Instrumentalists", Journal of Research in Music Education, Vol. 47, No. 2. (Summer, 1999), pp. 135-149.
  6. C.M. Warrier; R.J. Zatorre (February 2002), "Influence of tonal context and timbral variation on perception of pitch" (PDF), Perception & Psychophysics, 64 (2): 198–207, doi:10.3758/BF03195786, retrieved 2008-09-27
  7. "Adaptive pitch test Adaptive Pitch Test, archived from the original on 2014-06-25]", Tonometric.com
  8. Benson (2007), p.368.
  9. J.C. Brown; K.V. Vaughn (September 1996), "Pitch Center of Stringed Instrument Vibrato Tones" (PDF), Journal of the Acoustical Society of America, 100 (3): 1728–1735, Bibcode:1996ASAJ..100.1728B, doi:10.1121/1.416070, PMID 8817899, retrieved 2008-09-28
  10. E. Prame (July 1997), "Vibrato extent and intonation in professional Western lyric singing", The Journal of the Acoustical Society of America, 102 (1): 616–621, Bibcode:1997ASAJ..102..616P, doi:10.1121/1.419735
  11. I. Peretz; K.L. Hyde (August 2003), "What is specific to music processing? Insights from congenital amusia" (PDF), Trends in Cognitive Sciences, 7 (8): 362–367, doi:10.1016/S1364-6613(03)00150-5, PMID 12907232, retrieved 2008-09-27
  12. Randel, Don Michael (1999). The Harvard Concise Dictionary of Music and Musicians, p.123. ISBN 9780674000841. Randel, Don Michael (2003). The Harvard Concise Dictionary of Music and Musicians, p.154 & 416. ISBN 9780674011632.
  13. "Logarithmic Interval Measures", Huygens-Fokker.org.
  14. Yasser, Joseph (1932). A Theory of Evolving Tonality, p.14. American Library of Musicology.
  15. Farnsworth, Paul Randolph (1969). The Social Psychology of Music, p.24. ISBN 9780813815473.
  16. Apel, Willi (1970). Harvard Dictionary of Music, p.363. Taylor & Francis.


External links

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