Sylvester equation
In mathematics, in the field of control theory, a Sylvester equation is a matrix equation of the form:[1]
Then given matrices A, B, and C, the problem is to find the possible matrices X that obey this equation. All matrices are assumed to have coefficients in the complex numbers. For the equation to make sense, the matrices must have appropriate sizes, for example they could all be square matrices of the same size. But more generally, A and B must be square matrices of sizes n and m respectively, and then X and C both have n rows and m columns.
A Sylvester equation has a unique solution for X exactly when there are no common eigenvalues of A and −B. More generally, the equation AX + XB = C has been considered as an equation of bounded operators on a (possibly infinite-dimensional) Banach space. In this case, the condition for the uniqueness of a solution X is almost the same: There exists a unique solution X exactly when the spectra of A and −B are disjoint.[2]
Existence and uniqueness of the solutions
Using the Kronecker product notation and the vectorization operator , we can rewrite Sylvester's equation in the form
where is of dimension , is of dimension , of dimension and is the identity matrix. In this form, the equation can be seen as a linear system of dimension .[3]
Proposition. Given complex matrices and , Sylvester's equation has a unique solution for all if and only if and have no common eigenvalues.
Proof. Consider the linear transformation given by .
(i) Suppose that and have no common eigenvalues. Then their characteristic polynomials and have highest common factor . Hence there exist complex polynomials and such that . By the Cayley–Hamilton theorem, ; hence . Let be any solution of ; so and repeating this one sees that . Hence by the rank plus nullity theorem is invertible, so for all there exists a unique solution .
(ii) Conversely, suppose that is a common eigenvalue of and . Note that is also an eigenvalue of the transpose . Then there exist non-zero vectors and such that and . Choose such that , the vector whose entries are the complex conjugates of . Then has no solution , as is clear from the complex bilinear pairing ; the right-hand side is positive whereas the left is zero.
Roth's removal rule
Given two square complex matrices A and B, of size n and m, and a matrix C of size n by m, then one can ask when the following two square matrices of size n + m are similar to each other: and . The answer is that these two matrices are similar exactly when there exists a matrix X such that AX − XB = C. In other words, X is a solution to a Sylvester equation. This is known as Roth's removal rule.[4]
One easily checks one direction: If AX − XB = C then
Roth's removal rule does not generalize to infinite-dimensional bounded operators on a Banach space.[5]
Numerical solutions
A classical algorithm for the numerical solution of the Sylvester equation is the Bartels–Stewart algorithm, which consists of transforming and into Schur form by a QR algorithm, and then solving the resulting triangular system via back-substitution. This algorithm, whose computational cost is arithmetical operations,[citation needed] is used, among others, by LAPACK and the lyap
function in GNU Octave.[6] See also the sylvester
function in that language.[7][8] In some specific image processing application, the derived Sylvester equation has a closed form solution.[9]
See also
Notes
- ^ This equation is also commonly written in the equivalent form of AX − XB = C.
- ^ Bhatia and Rosenthal, 1997
- ^ However, rewriting the equation in this form is not advised for the numerical solution since this version is costly to solve and can be ill-conditioned.
- ^ Gerrish, F; Ward, A.G.B (Nov 1998). "Sylvester's matrix equation and Roth's removal rule". The Mathematical Gazette. 82 (495): 423–430. doi:10.2307/3619888. JSTOR 3619888.
- ^ Bhatia and Rosenthal, p.3
- ^ "Function Reference: Lyap".
- ^ "Functions of a Matrix (GNU Octave (version 4.4.1))".
- ^ The
syl
command is deprecated since GNU Octave Version 4.0 - ^ Wei, Q.; Dobigeon, N.; Tourneret, J.-Y. (2015). "Fast Fusion of Multi-Band Images Based on Solving a Sylvester Equation". IEEE. 24 (11): 4109–4121. arXiv:1502.03121. Bibcode:2015ITIP...24.4109W. doi:10.1109/TIP.2015.2458572. PMID 26208345.
References
- Sylvester, J. (1884). "Sur l'equations en matrices ". C. R. Acad. Sci. Paris. 99 (2): 67–71, 115–116.
- Bartels, R. H.; Stewart, G. W. (1972). "Solution of the matrix equation ". Comm. ACM. 15 (9): 820–826. doi:10.1145/361573.361582.
- Bhatia, R.; Rosenthal, P. (1997). "How and why to solve the operator equation ?". Bull. London Math. Soc. 29 (1): 1–21. doi:10.1112/S0024609396001828.
- Lee, S.-G.; Vu, Q.-P. (2011). "Simultaneous solutions of Sylvester equations and idempotent matrices separating the joint spectrum". Linear Algebra Appl. 435 (9): 2097–2109. doi:10.1016/j.laa.2010.09.034.
- Wei, Q.; Dobigeon, N.; Tourneret, J.-Y. (2015). "Fast Fusion of Multi-Band Images Based on Solving a Sylvester Equation". IEEE Transactions on Image Processing. 24 (11): 4109–4121. arXiv:1502.03121. Bibcode:2015ITIP...24.4109W. doi:10.1109/TIP.2015.2458572. PMID 26208345.
- Birkhoff and MacLane. A survey of Modern Algebra. Macmillan. pp. 213, 299.