Hilbert's seventeenth problem explained

Hilbert's seventeenth problem is one of the 23 Hilbert problems set out in a celebrated list compiled in 1900 by David Hilbert. It concerns the expression of positive definite rational functions as sums of quotients of squares. The original question may be reformulated as:

• Given a multivariate polynomial that takes only non-negative values over the reals, can it be represented as a sum of squares of rational functions?

Hilbert's question can be restricted to homogeneous polynomials of even degree, since a polynomial of odd degree changes sign, and the homogenization of a polynomial takes only nonnegative values if and only if the same is true for the polynomial.

Motivation

See main article: Polynomial SOS.

The formulation of the question takes into account that there are non-negative polynomials, for example^[1]

which cannot be represented as a sum of squares of other polynomials. In 1888, Hilbert showed that every non-negative homogeneous polynomial in n variables and degree 2d can be represented as sum of squares of other polynomials if and only if either (a)n = 2 or (b) 2d = 2 or (c) n = 3 and 2d = 4.^[2] Hilbert's proof did not exhibit any explicit counterexample: only in 1967 the first explicit counterexample was constructed by Motzkin.^[3] Furthermore, if the polynomial has a degree 2d greater than two, there are significantly many more non-negative polynomials that cannot be expressed as sums of squares.^[4]

The following table summarizes in which cases every non-negative homogeneous polynomial (or a polynomial of even degree) can be represented as a sum of squares:

Any homogeneous polynomial of degree 2d and n variables can be represented as sum of squares?		2d (Degree)				Any polynomial of degree 2d and n variables can be represented as sum of squares?		2d (Degree)
		2	4	≥6				2	4	≥6
n (Number of variables)	1	Yes	Yes	Yes		n (Number of variables)	1	Yes	Yes	Yes
	2	Yes	Yes	Yes			2	Yes	Yes	No
	3	Yes	Yes	No			3	Yes	No	No
	≥4	Yes	No	No			≥4	Yes	No	No

Solution and generalizations

The particular case of n = 2 was already solved by Hilbert in 1893.^[5] The general problem was solved in the affirmative, in 1927, by Emil Artin,^[6] for positive semidefinite functions over the reals or more generally real-closed fields. An algorithmic solution was found by Charles Delzell in 1984.^[7] A result of Albrecht Pfister^[8] shows that a positive semidefinite form in n variables can be expressed as a sum of 2ⁿ squares.^[9]

Dubois showed in 1967 that the answer is negative in general for ordered fields.^[10] In this case one can say that a positive polynomial is a sum of weighted squares of rational functions with positive coefficients.^[11] McKenna showed in 1975 that all positive semidefinite polynomials with coefficients in an ordered field are sums of weighted squares of rational functions with positive coefficients only if the field is dense in its real closure in the sense that any interval with endpoints in the real closure contains elements from the original field.^[12]

A generalization to the matrix case (matrices with polynomial function entries that are always positive semidefinite can be expressed as sum of squares of symmetric matrices with rational function entries) was given by Gondard, Ribenboim^[13] and Procesi, Schacher,^[14] with an elementary proof given by Hillar and Nie.^[15]

Minimum number of square rational terms

It is an open question what is the smallest number

such that any n-variate, non-negative polynomial of degree d can be written as sum of at most

square rational functions over the reals. An upper bound due to Pfister in 1967 is:^[8]

In the other direction, a conditional lower bound can be derived from computational complexity theory. An n-variable instance of 3-SAT can be realized as a positivity problem on a polynomial with n variables and d=4. This proves that positivity testing is NP-Hard. More precisely, assuming the exponential time hypothesis to be true,

.

In complex analysis the Hermitian analogue, requiring the squares to be squared norms of holomorphic mappings, is somewhat more complicated, but true for positive polynomials by a result of Quillen.^[16] The result of Pfister on the other hand fails in the Hermitian case, that is there is no bound on the number of squares required, see D'Angelo–Lebl.^[17]

See also

• Polynomial SOS
• Positive polynomial
• Sum-of-squares optimization
• SOS-convexity

References

• Book: Pfister, Albrecht . Albrecht Pfister (mathematician)

. Felix E. Browder . Felix Browder . Mathematical Developments Arising from Hilbert Problems . . XXVIII.2 . 1976 . . 0-8218-1428-1 . Albrecht Pfister (mathematician) . Hilbert's seventeenth problem and related problems on definite forms . 483–489 .

• Book: Lam, Tsit-Yuen . Introduction to Quadratic Forms over Fields . 67 . . American Mathematical Society . 2005 . 0-8218-1095-2 . 1068.11023 .
• Book: Lorenz, Falko . Algebra. Volume II: Fields with Structure, Algebras and Advanced Topics . 2008 . . 978-0-387-72487-4 . 15–27 . 1130.12001 .
• Book: Rajwade, A. R. . Squares . 171 . London Mathematical Society Lecture Note Series . . 1993 . 0-521-42668-5 . 0785.11022 .

Notes and References

1. [Marie-Françoise Roy]
2. Hilbert. David. Ueber die Darstellung definiter Formen als Summe von Formenquadraten. Mathematische Annalen. September 1888. 32. 3. 342–350. 10.1007/bf01443605. 177804714 .
3. Book: Motzkin. T. S.. Inequalities. 1967. Academic Press. Shisha. Oved. 205–224. The arithmetic-geometric inequality.
4. Blekherman . Grigoriy . 2006 . There are significantly more nonegative polynomials than sums of squares . . en . 153 . 1 . 355–380 . 10.1007/BF02771790 . free . 0021-2172.
5. Hilbert. David. Über ternäre definite Formen. Acta Mathematica. December 1893. 17. 1. 169–197. 10.1007/bf02391990. free.
6. Artin. Emil. Über die Zerlegung definiter Funktionen in Quadrate. Abhandlungen aus dem Mathematischen Seminar der Universität Hamburg. 1927. 5. 1. 100–115. 10.1007/BF02952513. 122607428 .
7. 0547.12017 . Delzell . C.N. . A continuous, constructive solution to Hilbert's 17th problem . . 76 . 3 . 365–384 . 1984 . 10.1007/BF01388465 . 1984InMat..76..365D . 120884276 .
8. Pfister . Albrecht . Albrecht Pfister (mathematician) . Zur Darstellung definiter Funktionen als Summe von Quadraten . German . . 4 . 4 . 229–237 . 1967 . 0222.10022 . 10.1007/bf01425382. 1967InMat...4..229P . 122180608 .
9. Lam (2005) p.391
10. 0164.04502 . Dubois . D.W. . Note on Artin's solution of Hilbert's 17th problem . Bull. Am. Math. Soc. . 73 . 4 . 540–541 . 1967 . 10.1090/s0002-9904-1967-11736-1. free .
11. Lorenz (2008) p.16
12. Book: McKenna, K. . New facts about Hilbert's seventeenth problem . Springer, Berlin, Heidelberg . 1975 . Model Theory and Algebra, Lecture Notes in Mathematics . 498 . 220-230.
13. 0298.12104 . 432613 . Gondard . Danielle . Ribenboim . Paulo . Paulo Ribenboim . Le 17e problème de Hilbert pour les matrices . Bull. Sci. Math. (2) . 98 . 1974 . 1 . 49–56 .
14. 432612 . 0347.16010 . Procesi . Claudio . Schacher . Murray . A non-commutative real Nullstellensatz and Hilbert's 17th problem . Ann. of Math. . 2 . 104. 1976 . 3 . 395–406 . 10.2307/1970962. 1970962 .
15. 1126.12001 . Hillar . Christopher J. . Nie . Jiawang . An elementary and constructive solution to Hilbert's 17th problem for matrices . Proc. Am. Math. Soc. . 136 . 1 . 73–76 . 2008 . math/0610388 . 10.1090/s0002-9939-07-09068-5. 119639574 .
16. 0198.35205 . Quillen . Daniel G. . On the representation of hermitian forms as sums of squares . Invent. Math. . 5 . 4 . 237–242 . 1968 . 10.1007/bf01389773. 1968InMat...5..237Q . 119774934 .
17. 1309.12001 . D'Angelo . John P. . Lebl . Jiri . Pfister's theorem fails in the Hermitian case . Proc. Am. Math. Soc. . 140 . 4 . 1151–1157 . 2012 . 1010.3215 . 10.1090/s0002-9939-2011-10841-4. 92993604 .