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In number theory, Waring's Problem, proposed in
1770 by Edward Waring, asks whether
for every natural number k there exists an associated positive
integer s such that every natural number is the sum of at most s
kth powers of natural numbers. The affirmative answer was provided by David Hilbert in 1909. Sometimes this topic is described as
Hilbert-Waring's theorem.
For every k, we denote the least such s by g(k). Note we have g(1) = 1. Some
simple computations show that 7 requires 4 squares, 23 requires 9 cubes, and 79 requires 19 fourth-powers. Waring conjected that
these values were in fact the best possible.
Lagrange's four-square theorem of
1770 states that every natural number is the sum of at most four squares; since three
squares are not enough, this theorem establishes g(2) = 4. Lagrange's four-square theorem was conjectured by Fermat in 1640 and was first stated
in 1621.
Over the years various bounds were established, using increasingly sophisticated and complex proof techniques. For example,
Liouville showed that g(4) is at most 53. Hardy and Littlewood showed that all sufficiently large numbers are the sum of at most 19 fourth powers.
That g(3) = 9 was established from 1909 to 1912 by Wieferich and A. J. Kempner, g(4) = 19 in 1986 by R.
Balasubramanian, F. Dress, and J.-M. Deshouillers, g(5) = 37 in 1964 by Jing-run
Chen and g(6) = 73 in 1940 by Pillai.
All the other values of g are now also known, as a result of work by Dickson, Pillai, Rubugunday and Niven. Their
formula contains two cases, and it is conjectured that the second case never occurs; in the first case, the formula reads
- g(k) = floor((3/2)k) +
2k - 2 for k ≥ 6.
Further Reading
- W. J. Ellison: Waring's problem. American Mathematical Monthly, volume 78 (1971), pp. 10-76. Survey, contains the
precise formula for g(k) and a simplified version of Hilbert's proof.
- Hans Rademacher and Otto Toeplitz, The Enjoyment of Mathematics (1933) (ISBN 0-691-02351-4). Has a proof of the
Lagrange theorem, accessible to high school students.
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