Difference between revisions of "Waring problem"
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− | A problem in number theory formulated in 1770 by | + | A problem in number theory formulated in 1770 by E. Waring in the following form: Any natural number is a sum of 4 squares, of 9 cubes and of 19 fourth-powers. In other words, for all $n\geq2$ there exists a $k=k(n)$, depending only on $n$, such that every natural number is the sum of $k$ $n$-th powers of non-negative integers. D. Hilbert in 1909 was the first to give a general solution of Waring's problem with a very rough estimate of the value of $k$ as a function of $n$; this is why the problem is sometimes known as the |
− | E. Waring in the following form: Any natural number is a sum of 4 | + | Hilbert–Waring problem. Let $J_{k,n}(N)$ be the number of solutions of the equation |
− | squares, of 9 cubes and of 19 fourth-powers. In other words, for all | ||
− | $n\geq2$ there exists a $k=k(n)$, depending only on $n$, such that | ||
− | every natural number is the sum of $k$ $n$-th powers of non-negative | ||
− | integers. D. Hilbert in 1909 was the first to give a general solution | ||
− | of Waring's problem with a very rough estimate of the value of $k$ as | ||
− | a function of $n$; this is why the problem is sometimes known as the | ||
− | Hilbert–Waring problem. Let $J_{k,n}(N)$ be the number of solutions of | ||
− | the equation | ||
− | + | \begin{equation}\label{war}x_1^n+\cdots+x_k^n=N\end{equation} | |
− | in non-negative integers. Hilbert's theorem then states that there | + | in non-negative integers. Hilbert's theorem then states that there exists a $K=k(n)$ for which $J_{K,n}(N)\geq1$ for any $N\geq1$. G.H. Hardy and J.E. Littlewood, who applied the [[Circle method|circle method]] to the Waring problem, demonstrated in 1928 that for $k\geq(n-2)2^{n-1}+5$ the value of $J_{k,n}(N)$ is given by an asymptotic formula of the type |
− | exists a $K=k(n)$ for which $J_{K,n}(N)\geq1$ for any | ||
− | $N\geq1$. G.H. Hardy and J.E. Littlewood, who applied the | ||
− | [[Circle method|circle method]] to the Waring problem, demonstrated in | ||
− | 1928 that for $k\geq(n-2)2^{n-1}+5$ the value of $J_{k,n}(N)$ is given | ||
− | by an asymptotic formula of the type | ||
− | + | \begin{equation}\label{asym}J_{k,n}(N)=AN^{k/n-1}+O(N^{k/n-1-\gamma}),\end{equation} | |
− | where $A=A(N)\geq c_0>0$, while $c_0$ and $\gamma>0$ are | + | where $A=A(N)\geq c_0>0$, while $c_0$ and $\gamma>0$ are constants. Consequently, if $N\geq N_0(n)$, equation \ref{war} has a solution. |
− | constants. Consequently, if $N\geq N_0(n)$, equation | ||
− | solution | ||
− | |||
− | |||
− | |||
− | |||
− | |||
− | a) It is known that $G(n)\geq n+1$. It was proved in 1934 by | + | An elementary proof of Waring's problem was given in 1942 by Yu.V. Linnik. There exist many different generalizations of Waring's problem (the variables run through a certain subset of the set of natural numbers; the number $N$ is represented by polynomials $f_1(x_1),\ldots,f_k(x_k)$ rather than by monomials $x_1^n,\ldots,x_k^n$; equation (1) is replaced by a congruence, etc.). |
− | I.M. Vinogradov, using his own method, that | + | |
+ | Research on Waring's problem has mainly focused on sharpening estimates for the following three questions: | ||
+ | # Find the smallest $k$ such that \ref{war} has solutions for all sufficiently large $N$; | ||
+ | # Find the smallest $k$ such that \ref{war} has solutions for all $N$; | ||
+ | # Find the smallest $k$ such that the number of solutions to \ref{war}, $J_{k,n}(N)$, is given by the asymptotic formula \ref{asym}. | ||
+ | |||
+ | These quantities are known as $G(n)$, $g(n)$, and $k_0(n)$ respectively. Clearly, $k_0(n)\geq G(n)$ and $g(n)\geq G(n)$. The progress on bounds for these quantities is detailed below. | ||
+ | |||
+ | == Solvable for $N$ sufficiently large == | ||
+ | Let $G(n)$ be the smallest integer such that equation \ref{war} is solvable for $k\geq G(n)$ and $N$ sufficiently large depending on $n$. | ||
+ | |||
+ | It is known that $G(n)\geq n+1$. It was proved in 1934 by I.M. Vinogradov, using his own method, that | ||
$$G(n)\leq 3n(\ln n+9).$$ | $$G(n)\leq 3n(\ln n+9).$$ | ||
− | Moreover, many results are available concerning $G(n)$ for small | + | Moreover, many results are available concerning $G(n)$ for small values of $n$: $G(4)=16$ (H. Davenport, 1939); $G(3)=7$ (Yu.V. Linnik, 1942). |
− | values of $n$: $G(4)=16$ (H. Davenport, 1939); $G(3)=7$ (Yu.V. Linnik, | ||
− | 1942). | ||
− | + | == Solvable for all $N$ == | |
− | [[Vinogradov method|Vinogradov method]], that | + | |
+ | Let $g(n)$ be the smallest integer such that equation \ref{war} is solvable for $k\geq g(n)$ and $N\geq1$. | ||
+ | |||
+ | It was shown in 1936 by L. Dickson and S. Pillai, who also used the [[Vinogradov method|Vinogradov method]], that | ||
$$G(n)=2^n+\left[\left(\frac{3}{2}\right)^n\right]-2$$ | $$G(n)=2^n+\left[\left(\frac{3}{2}\right)^n\right]-2$$ | ||
− | for all $n>6$ for which | + | for all $n>6$ for which |
− | $$\left(\frac{3}{2}\right)^n-\left[\left(\frac{3}{2}\right)^n\right]\ | + | $$\left(\frac{3}{2}\right)^n-\left[\left(\frac{3}{2}\right)^n\right]\leq1-\left(\frac{1}{2}\right)^n\left\{\left[\left(\frac{3}{2}\right)^n\right]+2\right\}.$$ |
− | |||
− | The last condition was demonstrated in 1957 by K. Mahler for all | + | The last condition was demonstrated in 1957 by K. Mahler for all sufficiently large $n$. |
− | sufficiently large $n$. | ||
− | + | It is known that $g(2)=4$ (J.L. Lagrange, 1770), $g(3)=9$ (A. Wieferich, A. Kempner, 1912), $g(4)=19$ (R. Balusabramanian, J. Deshouillers, F. Dress, 1986), $g(5)=37$ (Chen-Jingrun, 1964). See also [[Circle method|Circle method]] and {{Cite|HaWr}}–{{Cite|Sh}}. | |
− | |||
− | $$ | ||
+ | == Asymptotic formula == | ||
+ | Let $k_0(n)$ be the smallest integer such that the asymptotic formula \ref{asym} applies to $J_{k,n}(N)$ if $k\geq k_0(n)$. | ||
− | + | The best result of all must be credited to Vinogradov, who showed that | |
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− | + | $$k_0(n)\leq 4n^2\ln n.$$ | |
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− | + | ==References== | |
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|valign="top"|{{Ref|Vi2}}||valign="top"| I.M. Vinogradov, "The method of trigonometric sums in the theory of numbers", Interscience (1954) (Translated from Russian) | |valign="top"|{{Ref|Vi2}}||valign="top"| I.M. Vinogradov, "The method of trigonometric sums in the theory of numbers", Interscience (1954) (Translated from Russian) | ||
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|valign="top"|{{Ref|HaWr}}||valign="top"| G.H. Hardy, E.M. Wright, "An introduction to the theory of numbers", Oxford Univ. Press (1979) pp. Chapt. 6 | |valign="top"|{{Ref|HaWr}}||valign="top"| G.H. Hardy, E.M. Wright, "An introduction to the theory of numbers", Oxford Univ. Press (1979) pp. Chapt. 6 |
Revision as of 11:12, 23 April 2012
2020 Mathematics Subject Classification: Primary: 11P05 [MSN][ZBL]
A problem in number theory formulated in 1770 by E. Waring in the following form: Any natural number is a sum of 4 squares, of 9 cubes and of 19 fourth-powers. In other words, for all $n\geq2$ there exists a $k=k(n)$, depending only on $n$, such that every natural number is the sum of $k$ $n$-th powers of non-negative integers. D. Hilbert in 1909 was the first to give a general solution of Waring's problem with a very rough estimate of the value of $k$ as a function of $n$; this is why the problem is sometimes known as the Hilbert–Waring problem. Let $J_{k,n}(N)$ be the number of solutions of the equation
\begin{equation}\label{war}x_1^n+\cdots+x_k^n=N\end{equation}
in non-negative integers. Hilbert's theorem then states that there exists a $K=k(n)$ for which $J_{K,n}(N)\geq1$ for any $N\geq1$. G.H. Hardy and J.E. Littlewood, who applied the circle method to the Waring problem, demonstrated in 1928 that for $k\geq(n-2)2^{n-1}+5$ the value of $J_{k,n}(N)$ is given by an asymptotic formula of the type
\begin{equation}\label{asym}J_{k,n}(N)=AN^{k/n-1}+O(N^{k/n-1-\gamma}),\end{equation}
where $A=A(N)\geq c_0>0$, while $c_0$ and $\gamma>0$ are constants. Consequently, if $N\geq N_0(n)$, equation \ref{war} has a solution.
An elementary proof of Waring's problem was given in 1942 by Yu.V. Linnik. There exist many different generalizations of Waring's problem (the variables run through a certain subset of the set of natural numbers; the number $N$ is represented by polynomials $f_1(x_1),\ldots,f_k(x_k)$ rather than by monomials $x_1^n,\ldots,x_k^n$; equation (1) is replaced by a congruence, etc.).
Research on Waring's problem has mainly focused on sharpening estimates for the following three questions:
- Find the smallest $k$ such that \ref{war} has solutions for all sufficiently large $N$;
- Find the smallest $k$ such that \ref{war} has solutions for all $N$;
- Find the smallest $k$ such that the number of solutions to \ref{war}, $J_{k,n}(N)$, is given by the asymptotic formula \ref{asym}.
These quantities are known as $G(n)$, $g(n)$, and $k_0(n)$ respectively. Clearly, $k_0(n)\geq G(n)$ and $g(n)\geq G(n)$. The progress on bounds for these quantities is detailed below.
Solvable for $N$ sufficiently large
Let $G(n)$ be the smallest integer such that equation \ref{war} is solvable for $k\geq G(n)$ and $N$ sufficiently large depending on $n$.
It is known that $G(n)\geq n+1$. It was proved in 1934 by I.M. Vinogradov, using his own method, that
$$G(n)\leq 3n(\ln n+9).$$
Moreover, many results are available concerning $G(n)$ for small values of $n$: $G(4)=16$ (H. Davenport, 1939); $G(3)=7$ (Yu.V. Linnik, 1942).
Solvable for all $N$
Let $g(n)$ be the smallest integer such that equation \ref{war} is solvable for $k\geq g(n)$ and $N\geq1$.
It was shown in 1936 by L. Dickson and S. Pillai, who also used the Vinogradov method, that
$$G(n)=2^n+\left[\left(\frac{3}{2}\right)^n\right]-2$$
for all $n>6$ for which
$$\left(\frac{3}{2}\right)^n-\left[\left(\frac{3}{2}\right)^n\right]\leq1-\left(\frac{1}{2}\right)^n\left\{\left[\left(\frac{3}{2}\right)^n\right]+2\right\}.$$
The last condition was demonstrated in 1957 by K. Mahler for all sufficiently large $n$.
It is known that $g(2)=4$ (J.L. Lagrange, 1770), $g(3)=9$ (A. Wieferich, A. Kempner, 1912), $g(4)=19$ (R. Balusabramanian, J. Deshouillers, F. Dress, 1986), $g(5)=37$ (Chen-Jingrun, 1964). See also Circle method and [HaWr]–[Sh].
Asymptotic formula
Let $k_0(n)$ be the smallest integer such that the asymptotic formula \ref{asym} applies to $J_{k,n}(N)$ if $k\geq k_0(n)$.
The best result of all must be credited to Vinogradov, who showed that
$$k_0(n)\leq 4n^2\ln n.$$
References
[De] | B.N. Delone, "The Peterburg school of number theory", Moscow-Leningrad (1947) (In Russian) |
[Hu] | L.-K. Hua, "Abschätzungen von Exponentialsummen und ihre Anwendung in der Zahlentheorie", Enzyklopaedie der Mathematischen Wissenschaften mit Einschluss ihrer Anwendungen, 1 : 2 (1959) (Heft 13, Teil 1) |
[Kh] | A.Ya. Khinchin, "Three pearls of number theory", Graylock (1952) (Translated from Russian) |
[Vi] | I.M. Vinogradov, "Selected works", Springer (1985) (Translated from Russian) |
[Vi2] | I.M. Vinogradov, "The method of trigonometric sums in the theory of numbers", Interscience (1954) (Translated from Russian) |
[HaWr] | G.H. Hardy, E.M. Wright, "An introduction to the theory of numbers", Oxford Univ. Press (1979) pp. Chapt. 6 |
[Sh] | D. Shanks, "Solved and unsolved problems in number theory", Chelsea, reprint (1978) |
[Va] | R.C. Vaughan, "The Hardy–Littlewood method", Cambridge Univ. Press (1981) |
Waring problem. Encyclopedia of Mathematics. URL: http://encyclopediaofmath.org/index.php?title=Waring_problem&oldid=24877