# Pythagorean tuning

Pythagorean tuning (Greek: Πυθαγόρεια κλίμακα) is a tuning of the syntonic temperament[1] in which the generator is the ratio 3:2 (i.e., the untempered perfect fifth), which is 702 cents wide (see the figure labelled "The syntonic tuning continuum" below).

The syntonic tuning continuum, showing Pythagorean tuning at 702 cents.[1]

Hence, it is a system of musical tuning in which the frequency ratios of all intervals are based on the ratio 3:2, "found in the harmonic series."[2] This ratio, also known as the "pure" perfect fifth, is chosen because it is one of the most consonant and easy to tune by ear.

Pythagorean diatonic scale on C  .
Diatonic scale on C   12-tone equal tempered and  just intonation.
Pythagorean (tonic) major chord on C   (compare  equal tempered and   just).

The system had been mainly attributed to Pythagoras (sixth century BC) by modern authors of music theory, while Ptolemy, and later Boethius, ascribed the division of the tetrachord by only two intervals, called "semitonium", "tonus", "tonus" in Latin (256:243 x 9:8 x 9:8), to Eratosthenes. The so-called "Pythagorean tuning" was used by musicians up to the beginning of the 16th century. Leo Gunther[clarification needed] wrote, that "the Pythagorean system would appear to be ideal because of the purity of the fifths, but other intervals, particularly the major third, are so badly out of tune that major chords [may be considered] a dissonance."[2][3]

The Pythagorean scale is any scale which may be constructed from only pure perfect fifths (3:2) and octaves (2:1)[4] or the gamut of twelve pitches constructed from only pure perfect fifths and octaves, and from which specific scales may be drawn (see Generated collection). For example, the series of fifths generated above gives seven notes, a diatonic major scale on C in Pythagorean tuning, shown in notation on the top right. In Greek music it was used to tune tetrachords and the twelve tone Pythagorean system was developed by medieval music theorists using the same method of tuning in perfect fifths, however there is no evidence that Pythagoras himself went beyond the tetrachord.[5]

## Method

Pythagorean tuning is based on a stack of intervals called perfect fifths, each tuned in the ratio 3:2, the next simplest ratio after 2:1. Starting from D for example (D-based tuning), six other notes are produced by moving six times a ratio 3:2 up, and the remaining ones by moving the same ratio down:

E♭—B♭—F—C—G—D—A—E—B—F♯—C♯—G♯

This succession of eleven 3:2 intervals spans across a wide range of frequency (on a piano keyboard, it encompasses 77 keys). Since notes differing in frequency by a factor of 2 are given the same name, it is customary to divide or multiply the frequencies of some of these notes by 2 or by a power of 2. The purpose of this adjustment is to move the 12 notes within a smaller range of frequency, namely within the interval between the base note D and the D above it (a note with twice its frequency). This interval is typically called the basic octave (on a piano keyboard, an octave encompasses only 13 keys ).

For instance, the A is tuned such that its frequency equals 3:2 times the frequency of D — if D is tuned to a frequency of 288 Hz, then A is tuned to 432 Hz. Similarly, the E above A is tuned such that its frequency equals 3:2 times the frequency of A, or 9:4 times the frequency of D — with A at 432 Hz, this puts E at 648 Hz. Since this E is outside the above-mentioned basic octave (i.e. its frequency is more than twice the frequency of the base note D), it is usual to halve its frequency to move it within the basic octave. Therefore, E is tuned to 324 Hz, a 9:8 (= one epogdoon) above D. The B at 3:2 above that E is tuned to the ratio 27:16 and so on. Starting from the same point working the other way, G is tuned as 3:2 below D, which means that it is assigned a frequency equal to 2:3 times the frequency of D — with D at 288 Hz, this puts G at 192 Hz. This frequency is then doubled (to 384 Hz) to bring it into the basic octave.

When extending this tuning however, a problem arises: no stack of 3:2 intervals (perfect fifths) will fit exactly into any stack of 2:1 intervals (octaves). For instance a stack such as this, obtained by adding one more note to the stack shown above

A♭—E♭—B♭—F—C—G—D—A—E—B—F♯—C♯—G♯

will be similar but not identical in size to a stack of 7 octaves. More exactly, it will be about a quarter of a semitone larger (see Pythagorean comma). Thus, A and G, when brought into the basic octave, will not coincide as expected. The table below illustrates this, showing for each note in the basic octave the conventional name of the interval from D (the base note), the formula to compute its frequency ratio, its size in cents, and the difference in cents (labeled ET-dif in the table) between its size and the size of the corresponding one in the equally tempered scale.

NoteInterval from DFormulaFrequency
ratio
Size
(cents)
ET-dif
(cents)
Adiminished fifth$\left( \frac{2}{3} \right) ^6 \times 2^4$$\frac{1024}{729}$588.27-11.73
Eminor second$\left( \frac{2}{3} \right) ^5 \times 2^3$$\frac{256}{243}$90.22−9.78
Bminor sixth$\left( \frac{2}{3} \right) ^4 \times 2^3$$\frac{128}{81}$792.18−7.82
Fminor third$\left( \frac{2}{3} \right) ^3 \times 2^2$$\frac{32}{27}$294.13−5.87
Cminor seventh$\left( \frac{2}{3} \right) ^2 \times 2^2$$\frac{16}{9}$996.09−3.91
Gperfect fourth$\frac{2}{3} \times 2$$\frac{4}{3}$498.04-1.96
Dunison$\frac{1}{1}$$\frac{1}{1}$0 .000.00
Aperfect fifth$\frac{3}{2}$$\frac{3}{2}$701.961.96
Emajor second$\left( \frac{3}{2} \right) ^2 \times \frac{1}{2}$$\frac{9}{8}$203.913.91
Bmajor sixth$\left( \frac{3}{2} \right) ^3 \times \frac{1}{2}$$\frac{27}{16}$905.875.87
Fmajor third$\left( \frac{3}{2} \right) ^4 \times \left( \frac{1}{2} \right) ^2$$\frac{81}{64}$407.827.82
Cmajor seventh$\left( \frac{3}{2} \right) ^5 \times \left( \frac{1}{2} \right) ^2$$\frac{243}{128}$1109.789.78
Gaugmented fourth$\left( \frac{3}{2} \right) ^6 \times \left( \frac{1}{2} \right) ^3$$\frac{729}{512}$611.7311.73

In the formulas, the ratios 3:2 or 2:3 represent an ascending or descending perfect fifth (i.e. an increase or decrease in frequency by a perfect fifth), while 2:1 or 1:2 represent an ascending or descending octave.

The major scale based on C, obtained from this tuning is:[6]

 Note Ratio Step C D E F G A B C 1/1 9/8 81/64 4/3 3/2 27/16 243/128 2/1 — 9/8 9/8 256/243 9/8 9/8 9/8 256/243 —

In equal temperament, pairs of enharmonic notes such as A and G are thought of as being exactly the same note — however, as the above table indicates, in Pythagorean tuning they have different ratios with respect to D, which means they are at a different frequency. This discrepancy, of about 23.46 cents, or nearly one quarter of a semitone, is known as a Pythagorean comma.

To get around this problem, Pythagorean tuning ignores A, and uses only the 12 notes from E to G. This, as shown above, implies that only eleven just fifths are used to build the entire chromatic scale. The remaining fifth (from G to E) is left badly out-of-tune, meaning that any music which combines those two notes is unplayable in this tuning. A very out-of-tune interval such as this one is known as a wolf interval. In the case of Pythagorean tuning, all the fifths are 701.96 cents wide, in the exact ratio 3:2, except the wolf fifth, which is only 678.49 cents wide, nearly a quarter of a semitone flatter.

If the notes G and E need to be sounded together, the position of the wolf fifth can be changed. For example, a C-based Pythagorean tuning would produce a stack of fifths running from D to F, making F-D the wolf interval. However, there will always be one wolf fifth in Pythagorean tuning, making it impossible to play in all keys in tune.

## Size of intervals

The table above shows only intervals from D. However, intervals can be formed by starting from each of the above listed 12 notes. Thus, twelve intervals can be defined for each interval type (twelve unisons, twelve semitones, twelve intervals composed of 2 semitones, twelve intervals composed of 3 semitones, etc.).

Frequency ratio of the 144 intervals in D-based Pythagorean tuning. Interval names are given in their shortened form. Pure intervals are shown in bold font. Wolf intervals are highlighted in red.[7] Numbers larger than 999 are shown as powers of 2 or 3. Other versions of this table are provided here and here.
Approximate size in cents of the 144 intervals in D-based Pythagorean tuning. Interval names are given in their shortened form. Pure intervals are shown in bold font. Wolf intervals are highlighted in red.[7]

As explained above, one of the twelve fifths (the wolf fifth) has a different size with respect to the other eleven. For a similar reason, each of the other interval types, except for the unisons and the octaves, has two different sizes in Pythagorean tuning. This is the price paid for seeking just intonation. The tables on the right and below show their frequency ratios and their approximate sizes in cents. Interval names are given in their standard shortened form. For instance, the size of the interval from D to A, which is a perfect fifth (P5), can be found in the seventh column of the row labeled D. Strictly just (or pure) intervals are shown in bold font. Wolf intervals are highlighted in red.[7]

The reason why the interval sizes vary throughout the scale is that the pitches forming the scale are unevenly spaced. Namely, the frequencies defined by construction for the twelve notes determine two different semitones (i.e. intervals between adjacent notes):

1. The minor second (m2), also called diatonic semitone, with size
$S_1 = {256 \over 243} \approx 90.225 \ \hbox{cents}$
(e.g. between D and E)
2. The augmented unison (A1), also called chromatic semitone, with size
$S_2 = {3^7 \over 2^{11}} = {2187 \over 2048} \approx 113.685 \ \hbox{cents}$
(e.g. between E and E)

Conversely, in an equally tempered chromatic scale, by definition the twelve pitches are equally spaced, all semitones having a size of exactly

$S_E = \sqrt[12]{2} = 100.000 \ \hbox{cents}.$

As a consequence all intervals of any given type have the same size (e.g., all major thirds have the same size, all fifths have the same size, etc.). The price paid, in this case, is that none of them is justly tuned and perfectly consonant, except, of course, for the unison and the octave.

By definition, in Pythagorean tuning 11 perfect fifths (P5 in the table) have a size of approximately 701.955 cents (700+ε cents, where ε ≈ 1.955 cents). Since the average size of the 12 fifths must equal exactly 700 cents (as in equal temperament), the other one must have a size of 700−11ε cents, which is about 678.495 cents (the wolf fifth). Notice that, as shown in the table, the latter interval, although enharmonically equivalent to a fifth, is more properly called a diminished sixth (d6). Similarly,

• 9 minor thirds (m3) are ≈ 294.135 cents (300−3ε), 3 augmented seconds (A2) are ≈ 317.595 cents (300+9ε), and their average is 300 cents;
• 8 major thirds (M3) are ≈ 407.820 cents (400+4ε), 4 diminished fourths (d4) are ≈ 384.360 cents (400−8ε), and their average is 400 cents;
• 7 diatonic semitones (m2) are ≈ 90.225 cents (100−5ε), 5 chromatic semitones (A1) are ≈ 113.685 cents (100+7ε), and their average is 100 cents.

In short, similar differences in width are observed for all interval types, except for unisons and octaves, and they are all multiples of ε, the difference between the Pythagorean fifth and the average fifth.

Notice that, as an obvious consequence, each augmented or diminished interval is exactly 12ε (≈ 23.460) cents narrower or wider than its enharmonic equivalent. For instance, the d6 (or wolf fifth) is 12ε cents narrower than each P5, and each A2 is 12ε cents wider than each m3. This interval of size 12ε is known as a Pythagorean comma, exactly equal to the opposite of a diminished second (≈ −23.460 cents). This implies that ε can be also defined as one twelfth of a Pythagorean comma.

## Pythagorean intervals

Four of the above mentioned intervals take a specific name in Pythagorean tuning. In the following table, these specific names are provided, together with alternative names used generically for some other intervals. Notice that the Pythagorean comma does not coincide with the diminished second, as its size (524288:531441) is the reciprocal of the Pythagorean diminished second (531441:524288). Also ditone and semiditone are specific for Pythagorean tuning, while tone and tritone are used generically for all tuning systems. Interestingly, despite its name, a semiditone (3 semitones, or about 300 cents) can hardly be viewed as half of a ditone (4 semitones, or about 400 cents). All the intervals with prefix sesqui- are justly tuned, and their frequency ratio, shown in the table, is a superparticular number (or epimoric ratio). The same is true for the octave.

Number of
semitones
Generic namesSpecific names
Quality and numberOther naming conventionsPythagorean tuning5-limit tuning1/4-comma
meantone
FullShort
0commaPythagorean comma
(524288:531441)
diesis (128:125)
0diminished secondd2(531441:524288)
1minor secondm2semitone,
half tone,
half step
diatonic semitone,
minor semitone
limma (256:243)
1augmented unisonA1chromatic semitone,
major semitone
apotome (2187:2048)
2diminished thirdd3tone, whole tone, whole step
2major secondM2sesquioctavum (9:8)
3minor thirdm3semiditone (32:27)sesquiquintum (6:5)
4major thirdM3ditone (81:64)sesquiquartum (5:4)
5perfect fourthP4diatessaronsesquitertium (4:3)
6diminished fifthd5tritone
6augmented fourthA4
7perfect fifthP5diapentesesquialterum (3:2)
12(perfect) octaveP8diapasonduplex (2:1)

## History

Because of the wolf interval, this tuning is rarely used nowadays, although it is thought to have been widespread. In music which does not change key very often, or which is not very harmonically adventurous, the wolf interval is unlikely to be a problem, as not all the possible fifths will be heard in such pieces.

Because most fifths in Pythagorean tuning are in the simple ratio of 3:2, they sound very "smooth" and consonant. The thirds, by contrast, most of which are in the relatively complex ratios of 81:64 (for major thirds) and 32:27 (for minor thirds), sound less smooth.[8] For this reason, Pythagorean tuning is particularly well suited to music which treats fifths as consonances, and thirds as dissonances. In western classical music, this usually means music written prior to the 15th century.

From about 1510 onward, as thirds came to be treated as consonances, meantone temperament, and particularly quarter-comma meantone, which tunes thirds to the relatively simple ratio of 5:4, became the most popular system for tuning keyboards. At the same time, syntonic-diatonic just intonation was posited by Zarlino as the normal tuning for singers.

However, meantone presented its own harmonic challenges. Its wolf intervals proved to be even worse than those of the Pythagorean tuning (so much so that it often required 19 keys to the octave as opposed to the 12 in Pythagorean tuning). As a consequence, meantone was not suitable for all music.

From around the 18th century, as the desire grew for instruments to change key, and therefore to avoid a wolf interval, this led to the widespread use of well temperaments and eventually equal temperament.

In 2007, the discovery of the syntonic temperament [1] exposed the Pythagorean tuning as being a point on the syntonic temperament's tuning continuum.

## Discography

• Bragod is a duo giving historically informed performances of mediaeval Welsh music using the crwth and six-stringed lyre using Pythagorean tuning
• Gothic VoicesMusic for the Lion-Hearted King (Hyperion, CDA66336, 1989), directed by Christopher Page (Leech-Wilkinson)
• Lou Harrison performed by John Schneider and the Cal Arts Percussion Ensemble conducted by John Bergamo - Guitar & Percussion (Etceter Records, KTC1071, 1990): Suite No. 1 for guitar and percussion and Plaint & Variations on "Song of Palestine"

## References

### Footnotes

1. ^ a b c Milne, Andrew; Sethares, W.A., Plamondon, J. (December 2007). "Invariant Fingerings Across a Tuning Continuum". Computer Music Journal 31 (4): 15–32. doi:10.1162/comj.2007.31.4.15. Retrieved 2013-07-11.
2. ^ a b Benward & Saker (2003). Music: In Theory and Practice, Vol. I, p. 56. Seventh Edition. ISBN 978-0-07-294262-0.
3. ^ Gunther, Leon (2011). The Physics of Music and Color, p.362. ISBN 978-1-4614-0556-6.
4. ^ Sethares, William A. (2005). Tuning, Timbre, Spectrum, Scale, p.163. ISBN 1-85233-797-4.
5. ^ Peter A. Frazer The Development of Musical Tuning Systems
6. ^ Asiatic Society of Japan (1879). Transactions of the Asiatic Society of Japan, Volume 7, p.82. Asiatic Society of Japan.
7. ^ a b c Wolf intervals are operationally defined herein as intervals composed of 3, 4, 5, 7, 8, or 9 semitones (i.e. major and minor thirds or sixths, perfect fourths or fifths, and their enharmonic equivalents) the size of which deviates by more than one syntonic comma (about 21.5 cents) from the corresponding justly intonated interval. Intervals made up of 1, 2, 6, 10, or 11 semitones (e.g. major and minor seconds or sevenths, tritones, and their enharmonic equivalents) are considered to be dissonant even when they are justly tuned, thus they are not marked as wolf intervals even when they deviate from just intonation by more than one syntonic comma.
8. ^ However, 3/28 is described as "almost exactly a just major third." Sethares (2005), p.60.