User:Cturnes/Anderson-Jury Bezoutian

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An Anderson-Jury Bézoutian is a generalized form of the scalar Bézout matrix (or Bézoutian) that arises from the coefficients of polynomial matrices rather than univariate polynomials. The name Anderson-Jury is attributed to the authors of the seminal paper which first introduced the generalized Bezoutian form.^[1] They have been studied due to their connection with the stability of matrix polynomials^[2] and for their role in control theory^[3]. They are also of interest for their role in the inversion of block Hankel matrices.

Definition

Let the quadruple ${\displaystyle \{A(z),B(z),C(z),D(z)\}}$ be a set of four polynomial matrices. The Anderson-Jury Bézoutian form associated with the quadruple is given by:

${\displaystyle \Gamma (x,y)={\frac {1}{x-y}}\left[A(x)D(y)-B(x)C(y)\right].}$

Using the original definition supplied by B.D.O. Anderson and E.I. Jury, the polynomial matrices have the additional constraint that:

${\displaystyle A(x)D(x)=B(x)C(x),}$

which is necessary and sufficient for the polynomial form ${\displaystyle \Gamma (x,y)}$ to be integral in ${\displaystyle x,y}$. With this constraint, a real rational function of ${\displaystyle z}$ can be defined as ${\displaystyle W(z)=A(z)^{-1}B(z)=D(z)C(z)^{-1}}$. If ${\displaystyle A(z)}$ is of degree ${\displaystyle n}$, ${\displaystyle C(z)}$ is of degree ${\displaystyle m}$, ${\displaystyle D(z)}$ is of degree ${\displaystyle l}$, where ${\displaystyle l\leq m}$, then the Anderson-Jury Bézoutian of ${\displaystyle \{A(z),B(z),C(z),D(z)\}}$ may also be expressed as:

${\displaystyle \Gamma (x,y)=\sum _{i=1}^{n}\sum _{j=1}^{m}\Gamma _{ij}x^{i-1}y^{j-1},}$

with

${\displaystyle \Gamma _{ij}=\sum _{k\geq 0}(A_{i+k}D_{j-1-k}-B_{i+k}C_{j-1-k})=\sum _{k\geq 0}(B_{i-k-1}C_{j+k}-A_{i-k-1}C_{j-k}).}$

Properties

• Unlike the scalar Bézoutian matrix, the Anderson-Jury Bézoutian is not in general symmetric.
• For any block Hankel matrix ${\displaystyle H}$, there exists an Anderson-Jury Bézoutian which is a reflexive generalized inverse of ${\displaystyle H}$. For nonsingular ${\displaystyle H}$, the inverse of ${\displaystyle H}$ is an Anderson-Jury Bézoutian, as the reflexive generalized inverse is identically equal to the inverse.^[4]

Generalizations

Wimmer introduced the following, more general form of the Anderson-Jury Bézoutian^[5]: For a fixed field ${\displaystyle \mathbb {K} }$ let ${\displaystyle W\in \mathbb {K} ^{p\times q}(z)}$ be a strictly proper rational function. That is, let ${\displaystyle W}$ have the form

${\displaystyle W(z)=\sum _{i>0}W_{i}z^{-i},}$

where each ${\displaystyle W_{i}}$ is a ${\displaystyle p\times q}$ matrix with entries drawn from ${\displaystyle \mathbb {K} }$. Additionally, define the polynomial matrices

${\displaystyle A\in \mathbb {K} ^{p\times p}[z],\ C\in \mathbb {K} ^{q\times q}[z],\ B,D\in \mathbb {K} ^{p\times q}[z]}$

such that

${\displaystyle A[z]=A_{0}+A_{1}z+\cdots +A_{n}z^{n},\ \ C[z]=C_{0}+C_{1}z+\cdots +C_{m}z^{m}}$

are nonsingular and

${\displaystyle \pi _{-}(A^{-1}B)=\pi _{-}(DC^{-1})=W.}$

Here, ${\displaystyle \pi _{-}}$ is a projection operator that selects the strictly proper portion of a rational function (see Fuhrmann 1996^[6], Chapter 1, Section 3.4). Then the generalized Anderson-Jury Bézoutian ${\displaystyle B=B(A,B,C,D)}$ of the quadruple ${\displaystyle (A,B,C,D)}$ is the ${\displaystyle rp\times sq}$ matrix ${\displaystyle B=[B_{ij}],\ i=1,\ldots ,r,\ j=1,\ldots ,s}$, where the block entries ${\displaystyle B_{ij}}$ are given by the following equation:

${\displaystyle \Delta (x,y)=A(x){\frac {W(y)-W(x)}{x-y}}C(y)=\sum _{i=1}^{r}\sum _{j=1}^{s}B_{ij}x^{i-1}y^{j-1}.}$

In the standard Anderson-Jury Bézoutian, there is the additional assumption that

${\displaystyle \pi _{-}(A^{-1}B)=A^{-1}B\ \mathrm {and} \ \pi _{-}(DC^{-1})=DC^{-1},}$

in which case ${\displaystyle \Delta }$ becomes

${\displaystyle \Delta (x,y)={\frac {A(x)D(y)-B(x)C(y)}{x-y}}=\Gamma (x,y).}$

References

1. Anderson, B.D.O. and Jury, E.I., 1976, Generalized Bezoutian and Sylvester Matrices in Multivariable Linear Control, IEEE Transactions on Automatic Control, 21 (4): 551 - 556
2. Lerer, L. and Tismenetsky, M., 1986, Generalized Bezoutian and the inversion problem for Block matrices, I. general scheme, Integral equations and operator theory, 9 (6): 790 - 819
3. Bitmead, R.R., Kung, S.Y., Anderson, B.D.O., and Kailath, T., 1978, Greatest common divisors via generalized Sylvester and Bezout matrices, IEEE Transactions on Automatic Control, 23 (6): 1043 - 1047
4. Heinig, Georg, 1995, Generalized inverses of Hankel and Toeplitz mosaic matrices, Linear algebra and its applications, 216: 43 - 59
5. Wimmer, Harald K., 1989, Bezoutians of polynomial matrices and their generalized inverses, Linear algebra and its applications, 122 - 124: 475 - 487
6. Furhmann, Paul A., A Polynomial Approach to Linear Algebra, Springer, 1996 ISBN-13: 978-0387946436

External links

• example.com