In mathematics, specifically linear algebra, a real symmetric matrix A is copositive if
for every nonnegative vector (where the inequalities should be understood coordinate-wise). Some authors do not require A to be symmetric.[1] The collection of all copositive matrices is a proper cone;[2] it includes as a subset the collection of real positive-definite matrices.
Copositive matrices find applications in economics, operations research, and statistics.
Examples
edit- Every real positive-semidefinite matrix is copositive by definition.
- Every symmetric nonnegative matrix is copositive. This includes the zero matrix.
- The exchange matrix is copositive but not positive-semidefinite.
Properties
editIt is easy to see that the sum of two copositive matrices is a copositive matrix. More generally, any conical combination of copositive matrices is copositive.
Let A be a copositive matrix. Then we have that
- every principal submatrix of A is copositive as well. In particular, the entries on the main diagonal must be nonnegative.
- the spectral radius ρ(A) is an eigenvalue of A.[3]
Every copositive matrix of order less than 5 can be expressed as the sum of a positive semidefinite matrix and a nonnegative matrix.[4] A counterexample for order 5 is given by a copositive matrix known as Horn-matrix:[5]
Characterization
editThe class of copositive matrices can be characterized using principal submatrices. One such characterization is due to Wilfred Kaplan:[6]
- A real symmetric matrix A is copositive if and only if every principal submatrix B of A has no eigenvector v > 0 with associated eigenvalue λ < 0.
Several other characterizations are presented in a survey by Ikramov,[3] including:
- Assume that all the off-diagonal entries of a real symmetric matrix A are nonpositive. Then A is copositive if and only if it is positive semidefinite.
The problem of deciding whether a matrix is copositive is co-NP-complete.[7]
References
edit- Berman, Abraham; Robert J. Plemmons (1979). Nonnegative Matrices in the Mathematical Sciences. Academic Press. ISBN 0-12-092250-9.
- ^ Changqing Xu. "Copositive matrix". MathWorld. Retrieved 23 September 2024.
- ^ Copositive matrix at PlanetMath.
- ^ a b Ikramov, Kh. D.; Savel'eva, N. V. (1 January 2000). "Conditionally definite matrices". Journal of Mathematical Sciences. 98 (1): 1–50. doi:10.1007/BF02355379. ISSN 1573-8795.
- ^ Diananda, P. H. (January 1962). "On non-negative forms in real variables some or all of which are non-negative". Mathematical Proceedings of the Cambridge Philosophical Society. 58 (1): 17–25. doi:10.1017/S0305004100036185. ISSN 1469-8064.
- ^ Dür, Mirjam (2010). "Copositive Programming – a Survey" (PDF). In Diehl, Moritz; Glineur, Francois; Jarlebring, Elias; Michiels, Wim (eds.). Recent Advances in Optimization and its Applications in Engineering. Berlin, Heidelberg: Springer. pp. 3–20. doi:10.1007/978-3-642-12598-0_1. ISBN 978-3-642-12598-0.
- ^ Kaplan, Wilfred (1 July 2000). "A test for copositive matrices". Linear Algebra and Its Applications. 313 (1): 203–206. doi:10.1016/S0024-3795(00)00138-5. ISSN 0024-3795.
- ^ Schweighofer, Markus; Vargas, Luis Felipe (19 October 2023). "Sum-of-squares certificates for copositivity via test states". arXiv:2310.12853 [math.AG].