YBC 7289

YBC 7289

YBC 7289 is a Babylonian clay tablet notable for containing an accurate sexagesimal approximation to the square root of 2, the length of the diagonal of a unit square. This number is given to the equivalent of six decimal digits, "the greatest known computational accuracy ... in the ancient world".^[1] The tablet is believed to be the work of a student in southern Mesopotamia from some time between 1800 and 1600 BC.

Content

Babylonian clay tablet YBC 7289 with annotations. The diagonal displays an approximation of the square root of 2 in four sexagesimal figures, 1 24 51 10, which is good to about six decimal digits.
1 + 24/60 + 51/60² + 10/60³ = 1.41421296... The tablet also gives an example where one side of the square is 30, and the resulting diagonal is 42 25 35 or 42.4263888...

The tablet depicts a square with its two diagonals. One side of the square is labeled with the sexagesimal number 30. The diagonal of the square is labeled with two sexagesimal numbers. The first of these two, 1;24,51,10 represents the number 305470/216000 ≈ 1.414213, a numerical approximation of the square root of two that is off by less than one part in two million. The second of the two numbers is 42;25,35 = 30547/720 ≈ 42.426. This number is the result of multiplying 30 by the given approximation to the square root of two, and approximates the length of the diagonal of a square of side length 30.^[2]

Because the Babylonian sexagesimal notation did not indicate which digit had which place value, one alternative interpretation is that the number on the side of the square is 30/60 = 1/2. Under this alternative interpretation, the number on the diagonal is 30547/43200 ≈ 0.70711, a close numerical approximation of ${\displaystyle 1/{\sqrt {2}}}$, the length of the diagonal of a square of side length 1/2, that is also off by less than one part in two million. David Fowler and Eleanor Robson write, "Thus we have a reciprocal pair of numbers with a geometric interpretation…". They point out that, while the importance of reciprocal pairs in Babylonian mathematics makes this interpretation attractive, there are reasons for skepticism.^[2]

The reverse side is partly erased, but Robson believes it contains a similar problem concerning the diagonal of a rectangle whose two sides and diagonal are in the ratio 3:4:5.^[3]

Interpretation

Although YBC 7289 is frequently depicted (as in the photo) with the square oriented diagonally, the standard Babylonian conventions for drawing squares would have made the sides of the square vertical and horizontal, with the numbered side at the top.^[4] The small round shape of the tablet, and the large writing on it, suggests that it was a "hand tablet" of a type typically used for rough work by a student who would hold it in the palm of his hand.^[1][2] The student would likely have copied the sexagesimal value of the square root of 2 from another tablet, but an iterative procedure for computing this value can be found in another Babylonian tablet, BM 96957 + VAT 6598.^[2]

The mathematical significance of this tablet was first recognized by Otto E. Neugebauer and Abraham Sachs in 1945.^[2][5] The tablet "demonstrates the greatest known computational accuracy obtained anywhere in the ancient world", the equivalent of six decimal digits of accuracy.^[1] Other Babylonian tablets include the computations of areas of hexagons and heptagons, which involve the approximation of more complicated algebraic numbers such as ${\displaystyle {\sqrt {3}}}$.^[2] The same number ${\displaystyle {\sqrt {3}}}$ can also be used in the interpretation of certain ancient Egyptian calculations of the dimensions of pyramids. However, the much greater numerical precision of the numbers on YBC 7289 makes it more clear that they are the result of a general procedure for calculating them, rather than merely being an estimate.^[6]

The same sexagesimal approximation to ${\displaystyle {\sqrt {2}}}$, 1;24,51,10, was used much later by Greek mathematician Claudius Ptolemy in his Almagest.^[7][8] Ptolemy did not explain where this approximation came from and it may be assumed to have been well known by his time.^[7]

Provenance and curation

It is unknown where in Mesopotamia YBC 7289 comes from, but its shape and writing style make it likely that it was created in southern Mesopotamia, sometime between 1800BC and 1600BC.^[1][2]

At Yale, the Institute for the Preservation of Cultural Heritage has produced a digital model of the tablet, suitable for 3D printing.^[9][10][11] The original tablet is currently kept in the Yale Babylonian Collection at Yale University.^[10]

See also

• Plimpton 322
• IM 67118

References

1. Beery, Janet L.; Swetz, Frank J. (July 2012), "The best known old Babylonian tablet?", Convergence, Mathematical Association of America, doi:10.4169/loci003889
2. Fowler, David; Robson, Eleanor (1998), "Square root approximations in old Babylonian mathematics: YBC 7289 in context", Historia Mathematica, 25 (4): 366–378, doi:10.1006/hmat.1998.2209, MR 1662496
3. Robson, Eleanor (2007), "Mesopotamian Mathematics", in Katz, Victor J. (ed.), The Mathematics of Egypt, Mesopotamia, China, India, and Islam: A Sourcebook, Princeton University Press, p. 143, ISBN 978-0-691-11485-9
4. Friberg, Jöran (2007), Friberg, Jöran (ed.), A remarkable collection of Babylonian mathematical texts, Sources and Studies in the History of Mathematics and Physical Sciences, Springer, New York, p. 211, doi:10.1007/978-0-387-48977-3, ISBN 978-0-387-34543-7, MR 2333050
5. Neugebauer, O.; Sachs, A. J. (1945), Mathematical Cuneiform Texts, American Oriental Series, American Oriental Society and the American Schools of Oriental Research, New Haven, Conn., p. 43, MR 0016320
6. Rudman, Peter S. (2007), How mathematics happened: the first 50,000 years, Prometheus Books, Amherst, NY, p. 241, ISBN 978-1-59102-477-4, MR 2329364
7. Neugebauer, O. (1975), A History of Ancient Mathematical Astronomy, Part One, Springer-Verlag, New York-Heidelberg, pp. 22–23, ISBN 978-3-642-61910-6, MR 0465672
8. Pedersen, Olaf (2011), Jones, Alexander (ed.), A Survey of the Almagest, Sources and Studies in the History of Mathematics and Physical Sciences, Springer, p. 57, ISBN 978-0-387-84826-6
9. Lynch, Patrick (April 11, 2016), "A 3,800-year journey from classroom to classroom", Yale News, retrieved 2017-10-25
10. A 3D-print of ancient history: one of the most famous mathematical texts from Mesopotamia, Yale Institute for the Preservation of Cultural Heritage, January 16, 2016, retrieved 2017-10-25
11. Kwan, Alistair (April 20, 2019), Mesopotamian tablet YBC 7289, University of Auckland, doi:10.17608/k6.auckland.6114425.v1