Locally finite operator

In mathematics, a linear operator $f:V\to V$ is called locally finite if the space $V$ is the union of a family of finite-dimensional $f$ -invariant subspaces.^[1]^[2]^: 40

In other words, there exists a family $\{V_{i}\vert i\in I\}$ of linear subspaces of $V$ , such that we have the following:

$\bigcup _{i\in I}V_{i}=V$
$(\forall i\in I)f[V_{i}]\subseteq V_{i}$
Each $V_{i}$ is finite-dimensional.

An equivalent condition only requires $V$ to be the spanned by finite-dimensional $f$ -invariant subspaces.^[3]^[4] If $V$ is also a Hilbert space, sometimes an operator is called locally finite when the sum of the $\{V_{i}\vert i\in I\}$ is only dense in $V$ .^[2]^: 78–79

Examples edit

Every linear operator on a finite-dimensional space is trivially locally finite.
Every diagonalizable (i.e. there exists a basis of $V$ whose elements are all eigenvectors of $f$ ) linear operator is locally finite, because it is the union of subspaces spanned by finitely many eigenvectors of $f$ .
The operator on $\mathbb {C} [x]$ , the space of polynomials with complex coefficients, defined by $T(f(x))=xf(x)$ , is not locally finite; any $T$ -invariant subspace is of the form $\mathbb {C} [x]f_{0}(x)$ for some $f_{0}(x)\in \mathbb {C} [x]$ , and so has infinite dimension.
The operator on $\mathbb {C} [x]$ defined by $T(f(x))={\frac {f(x)-f(0)}{x}}$ is locally finite; for any $n$ , the polynomials of degree at most $n$ form a $T$ -invariant subspace.^[5]

References edit

^ Yucai Su; Xiaoping Xu (2000). "Central Simple Poisson Algebras". arXiv:math/0011086v1.
^ ^a ^b DeWilde, Patrick; van der Veen, Alle-Jan (1998). Time-Varying Systems and Computations. Dordrecht: Springer Science+Business Media, B.V. doi:10.1007/978-1-4757-2817-0. ISBN 978-1-4757-2817-0.
^ Radford, David E. (Feb 1977). "Operators on Hopf Algebras". American Journal of Mathematics. 99 (1). Johns Hopkins University Press: 139–158. doi:10.2307/2374012. JSTOR 2374012.
^ Scherpen, Jacquelien; Verhaegen, Michel (September 1995). On the Riccati Equations of the H^∞ Control Problem for Discrete Time-Varying Systems. 3rd European Control Conference (Rome, Italy). CiteSeerX 10.1.1.867.5629.
^ Joppy (Apr 28, 2018), answer to "Locally Finite Operator". Mathematics StackExchange. StackOverflow.

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[1] Yucai Su; Xiaoping Xu (2000). "Central Simple Poisson Algebras". arXiv:math/0011086v1.

[ControlBk-2] DeWilde, Patrick; van der Veen, Alle-Jan (1998). Time-Varying Systems and Computations. Dordrecht: Springer Science+Business Media, B.V. doi:10.1007/978-1-4757-2817-0. ISBN 978-1-4757-2817-0.

[Radford-3] Radford, David E. (Feb 1977). "Operators on Hopf Algebras". American Journal of Mathematics. 99 (1). Johns Hopkins University Press: 139–158. doi:10.2307/2374012. JSTOR 2374012.

[ControlProc-4] Scherpen, Jacquelien; Verhaegen, Michel (September 1995). On the Riccati Equations of the H^∞ Control Problem for Discrete Time-Varying Systems. 3rd European Control Conference (Rome, Italy). CiteSeerX 10.1.1.867.5629.

[5] Joppy (Apr 28, 2018), answer to "Locally Finite Operator". Mathematics StackExchange. StackOverflow.

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