In mathematics, the class of Z-matrices are those matrices whose off-diagonal entries are less than or equal to zero; that is, the matrices of the form:
Note that this definition coincides precisely with that of a negated Metzler matrix or quasipositive matrix, thus the term quasinegative matrix appears from time to time in the literature, though this is rare and usually only in contexts where references to quasipositive matrices are made.
The Jacobian of a competitive dynamical system is a Z-matrix by definition. Likewise, if the Jacobian of a cooperative dynamical system is J, then (−J) is a Z-matrix.
Related classes are L-matrices, M-matrices, P-matrices, Hurwitz matrices and Metzler matrices. L-matrices have the additional property that all diagonal entries are greater than zero. M-matrices have several equivalent definitions, one of which is as follows: a Z-matrix is an M-matrix if it is nonsingular and its inverse is nonnegative. All matrices that are both Z-matrices and P-matrices are nonsingular M-matrices.
In the context of quantum complexity theory, these are referred to as stoquastic operators.[1]
See also
References
- ↑ Bravyi, Sergey; DiVincenzo, David P.; Oliveira, Roberto I.; Terhal, Barbara M. (2006). "The Complexity of Stoquastic Local Hamiltonian Problems". arXiv:quant-ph/0606140.
- Huan T.; Cheng G.; Cheng X. (1 April 2006). "Modified SOR-type iterative method for Z-matrices". Applied Mathematics and Computation. 175 (1): 258–268. doi:10.1016/j.amc.2005.07.050.
- Saad, Y. (1996). Iterative methods for sparse linear systems (2nd ed.). Philadelphia, PA.: Society for Industrial and Applied Mathematics. p. 28. ISBN 0-534-94776-X.
- Berman, Abraham; Plemmons, Robert J. (2014). Nonnegative Matrices in the Mathematical Sciences. Academic Press. ISBN 9781483260860.