Matrix polynomial

In mathematics, a matrix polynomial is a polynomial with square matrices as variables. Given an ordinary, scalar-valued polynomial

P(x)=\sum _{i=0}^{n}{a_{i}x^{i}}=a_{0}+a_{1}x+a_{2}x^{2}+\cdots +a_{n}x^{n},

this polynomial evaluated at a matrix A is

P(A)=\sum _{i=0}^{n}{a_{i}A^{i}}=a_{0}I+a_{1}A+a_{2}A^{2}+\cdots +a_{n}A^{n},

where I is the identity matrix.[1]

A matrix polynomial equation is an equality between two matrix polynomials, which holds for the specific matrices in question. A matrix polynomial identity is a matrix polynomial equation which holds for all matrices A in a specified matrix ring M_n(R).

Characteristic and minimal polynomial

The characteristic polynomial of a matrix A is a scalar-valued polynomial, defined by $p_{A}(t)=\det \left(tI-A\right)$ . The Cayley–Hamilton theorem states that if this polynomial is viewed as a matrix polynomial and evaluated at the matrix A itself, the result is the zero matrix: $p_{A}(A)=0$ . The characteristic polynomial is thus a polynomial which annihilates A.

There is a unique monic polynomial of minimal degree which annihilates A; this polynomial is the minimal polynomial. Any polynomial which annihilates A (such as the characteristic polynomial) is a multiple of the minimal polynomial.[2]

It follows that given two polynomials P and Q, we have $P(A)=Q(A)$ if and only if

P^{(j)}(\lambda _{i})=Q^{(j)}(\lambda _{i})\qquad {\text{for }}j=0,\ldots ,n_{i}-1{\text{ and }}i=1,\ldots ,s,

where $P^{(j)}$ denotes the jth derivative of P and $\lambda _{1},\dots ,\lambda _{s}$ are the eigenvalues of A with corresponding indices $n_{1},\dots ,n_{s}$ (the index of an eigenvalue is the size of its largest Jordan block).[3]

Matrix geometrical series

Matrix polynomials can be used to sum a matrix geometrical series as one would an ordinary geometric series,

S=I+A+A^{2}+\cdots +A^{n}

AS=A+A^{2}+A^{3}+\cdots +A^{n+1}

(I-A)S=S-AS=I-A^{n+1}

S=(I-A)^{-1}(I-A^{n+1})

If I − A is nonsingular one can evaluate the expression for the sum S.

Notes

Horn & Johnson 1990, p. 36.
Horn & Johnson 1990, Thm 3.3.1.
Higham 2000, Thm 1.3.

References

Gohberg, Israel; Lancaster, Peter; Rodman, Leiba (2009) [1982]. Matrix Polynomials. Classics in Applied Mathematics. 58. Lancaster, PA: Society for Industrial and Applied Mathematics. ISBN 0-898716-81-0. Zbl 1170.15300.
Higham, Nicholas J. (2000). Functions of Matrices: Theory and Computation. SIAM. ISBN 089-871-777-9.CS1 maint: ref=harv (link).
Horn, Roger A.; Johnson, Charles R. (1990). Matrix Analysis. Cambridge University Press. ISBN 978-0-521-38632-6.CS1 maint: ref=harv (link).

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[FOOTNOTEHornJohnson199036-1] Horn & Johnson 1990, p. 36.

[FOOTNOTEHornJohnson1990Thm_3.3.1-2] Horn & Johnson 1990, Thm 3.3.1.

[FOOTNOTEHigham2000Thm_1.3-3] Higham 2000, Thm 1.3.

Matrix polynomial

Characteristic and minimal polynomial

Matrix geometrical series

See also

Notes

References