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Legendre's three-square theorem

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In mathematics, Legendre's three-square theorem states that a natural number can be represented as the sum of three squares of integers

if and only if n is not of the form for nonnegative integers a and b.

Distances between vertices of a double unit cube are square roots of the first six natural numbers due to the Pythagorean theorem (√7 is not possible due to Legendre's three-square theorem)

The first numbers that cannot be expressed as the sum of three squares (i.e. numbers that can be expressed as ) are

7, 15, 23, 28, 31, 39, 47, 55, 60, 63, 71 ... (sequence A004215 in the OEIS).
a
b
0 1 2
0 7 28 112
1 15 60 240
2 23 92 368
3 31 124 496
4 39 156 624
5 47 188 752
6 55 220 880
7 63 252 1008
8 71 284 1136
9 79 316 1264
10 87 348 1392
11 95 380 1520
12 103 412 1648
Unexpressible values
up to 100 are in bold

History

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Pierre de Fermat gave a criterion for numbers of the form 8a + 1 and 8a + 3 to be sums of a square plus twice another square, but did not provide a proof.[1] N. Beguelin noticed in 1774[2] that every positive integer which is neither of the form 8n + 7, nor of the form 4n, is the sum of three squares, but did not provide a satisfactory proof.[3] In 1796 Gauss proved his Eureka theorem that every positive integer n is the sum of 3 triangular numbers; this is equivalent to the fact that 8n + 3 is a sum of three squares. In 1797 or 1798 A.-M. Legendre obtained the first proof of his 3 square theorem.[4] In 1813, A. L. Cauchy noted[5] that Legendre's theorem is equivalent to the statement in the introduction above. Previously, in 1801, Gauss had obtained a more general result,[6] containing Legendre's theorem of 1797–8 as a corollary. In particular, Gauss counted the number of solutions of the expression of an integer as a sum of three squares, and this is a generalisation of yet another result of Legendre,[7] whose proof is incomplete. This last fact appears to be the reason for later incorrect claims according to which Legendre's proof of the three-square theorem was defective and had to be completed by Gauss.[8]

With Lagrange's four-square theorem and the two-square theorem of Girard, Fermat and Euler, the Waring's problem for k = 2 is entirely solved.

Proofs

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The "only if" of the theorem is simply because modulo 8, every square is congruent to 0, 1 or 4. There are several proofs of the converse (besides Legendre's proof). One of them is due to Dirichlet (in 1850), and has become classical.[9] It requires three main lemmas:

Relationship to the four-square theorem

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This theorem can be used to prove Lagrange's four-square theorem, which states that all natural numbers can be written as a sum of four squares. Gauss[10] pointed out that the four squares theorem follows easily from the fact that any positive integer that is 1 or 2 mod 4 is a sum of 3 squares, because any positive integer not divisible by 4 can be reduced to this form by subtracting 0 or 1 from it. However, proving the three-square theorem is considerably more difficult than a direct proof of the four-square theorem that does not use the three-square theorem. Indeed, the four-square theorem was proved earlier, in 1770.

See also

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Notes

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  1. ^ "Fermat to Pascal" (PDF). September 25, 1654. Archived (PDF) from the original on July 5, 2017.
  2. ^ Nouveaux Mémoires de l'Académie de Berlin (1774, publ. 1776), pp. 313–369.
  3. ^ Leonard Eugene Dickson, History of the theory of numbers, vol. II, p. 15 (Carnegie Institute of Washington 1919; AMS Chelsea Publ., 1992, reprint).
  4. ^ A.-M. Legendre, Essai sur la théorie des nombres, Paris, An VI (1797–1798), p. 202 and pp. 398–399.
  5. ^ A. L. Cauchy, Mém. Sci. Math. Phys. de l'Institut de France, (1) 14 (1813–1815), 177.
  6. ^ C. F. Gauss, Disquisitiones Arithmeticae, Art. 291 et 292.
  7. ^ A.-M. Legendre, Hist. et Mém. Acad. Roy. Sci. Paris, 1785, pp. 514–515.
  8. ^ See for instance: Elena Deza and M. Deza. Figurate numbers. World Scientific 2011, p. 314 [1]
  9. ^ See for instance vol. I, parts I, II and III of : E. Landau, Vorlesungen über Zahlentheorie, New York, Chelsea, 1927. Second edition translated into English by Jacob E. Goodman, Providence RH, Chelsea, 1958.
  10. ^ Gauss, Carl Friedrich (1965), Disquisitiones Arithmeticae, Yale University Press, p. 342, section 293, ISBN 0-300-09473-6