LMIs in Control/Click here to continue/Notation

Notations

Notations Related to Subspaces

$ℝ$	set of all real numbers
$ℝ^{+}$	set of all positive real numbers
$ℝ^{-}$	set of all negative real numbers
$ℂ$	set of all complex numbers
$ℂ^{+}$	right-half complex plane
$ℂ^{-}$	left-half complex plane
$ℝ^{n}$	set of all real vectors of dimension $n$
$ℂ^{n}$	set of all complex vectors of dimension $n$ $n$
$ℝ^{m \times n}$	set of all real matrices of dimension $m \times n$
$ℂ^{m \times n}$	set of all complex matrices of dimension $m \times n$
$ℝ_{r}^{m \times n}$	set of $m \times n$ real matrices with rank $r$
$ℂ_{r}^{m \times n}$	set of $m \times n$ complex matrices with rank $r$
${\bar{ℂ}}^{+}$	closed right-half complex plane, ${\bar{ℂ}}^{+} = {s \| s \in ℂ, R e (s) \leq 0}$
ker $(T)$	kernel of transformation or matrix $T$
Image $(T)$	image of transformation or matrix $T$
conv $(𝔽)$	convex hull of set $𝔽$
$𝕊^{n}$	set of symmetric matrix in $ℝ^{n \times n}, 𝕊^{n} = {M \| M = M^{T}, M \in ℝ^{n \times n}}$
$𝔽_{B}$	boundary set of $𝔽$
$𝔽_{E}$	set of all extreme points of $𝔽$

Notations Related to Vectors and Matrices

$0_{n}$	zero vector in $ℝ^{n}$
$0_{m \times n}$	zero matrix in $ℝ^{m \times n}$
$I_{n}$	identity matrix of order $n$
$A^{- 1}$	inverse matrix of matrix $A$
$A^{T}$	transpose of matrix $A$
$^{-} A$	complex conjugate of matrix $A$
$A^{H}$	transposed complex conjugate of matrix $A$
Re( $A$ )	real part of matrix $A$
Im( $A$ )	imaginary part of matrix $A$
det( $A$ )	determinant of matrix $A$
Adj $A$ )	adjoint of matrix $A$
trace( $A$ )	trace of matrix $A$
rank( $A$ )	rank of matrix $A$
$κ (A)$	condition number of matrix $A$
$ρ (A)$	spectral radius of matrix $A$
$A > 0$	$A$ is Hermite (symmetric) positive definite
$A \geq 0$	$A$ is Hermite (symmetric) semi-positive definite
$A > B$	$A - B > 0$
$A \geq B$	$A - B \geq 0$
$A < 0$	$A$ is Hermite (symmetric) negative definite
$A \geq 0$	$A$ is Hermite (symmetric) semi-negative definite
$A < B$	$A - B < 0$
$A^{\frac{1}{2}}$	$A - B \leq 0$
$A^{\frac{1}{2}}$	matrix $Z$ satisfying $Z^{T} Z = A > 0$
$λ (A)$	set of all eigenvalues of matrix $A$
$λ_{i} (A)$	$i$ th eigenvalue of matrix $A$
$λ_{m a x} (A)$	maximum eigenvalue of matrix $A$
$λ_{m i n} (A)$	minimum eigenvalue of matrix $A$
$σ_{i} (A)$	$i$ th singular value of matrix $A$
$σ_{m a x} (A)$	maximum singular value of matrix $A$
$σ_{m i n} (A)$	minimum singular value of matrix $A$
$⟨ A ⟩_{s}$	sum of matrix $A$ and its transpose, $⟨ A ⟩_{s} = A + A^{T}$
${‖ A ‖}_{2}$	spectral norm of matrix $A$
${‖ A ‖}_{F}$	Frobenius norm of matrix $A$
${‖ A ‖}_{1}$	row-sum norm of matrix $A$
${‖ A ‖}_{\infty}$	column-sum norm of matrix $A$

Notations of Relations and Manipulations

Other Notations

Examples

Consider the square matrix $A \in ℝ^{n \times n}$ . The eigenvalues of $A$ are denoted by $λ_{i} (A), i = 1, 2, . . ., n$ . The matrix A is Hurwitz if all of its eigenvalues are in the open left-half complex plane (i.e., Re $λ_{i} (A), i = 1, 2, . . ., n$ ). A matrix is Schur if all of its eigenvalues are strictly within a unit disk centered at the origin of the complex plane (i.e., $| λ_{i} (A) | < 1, i = 1, . . ., n)$ . If $A \in 𝕊^{n}$ , then the minimum eigenvalue of A is denoted by $λ (A)$ and its maximum eigenvalue is denoted by $\bar{λ} (A)$ .

Consider the matrix B $\in ℝ^{n \times m}$ . The minimum singular value of B is denoted by $\underline{σ}$ (B) and its maximum singular value is denoted by $\bar{σ}$ (B). The range and nullspace of B are denoted by $ℝ$ (B) and $ℕ$ (B), respectively. The Frobenius norm of B is ||B|| = $\sqrt{t r (B^{H} B)}$ .

A state-space realization of the continuous-time linear time-invariant (LTI) system

$\dot{x} (t) = A x (t) + B u (t)$ ,

$y (t) = C x (t) + D u (t),$ .
is often written compactly as (A, B,C,D) in this document. The argument of time is often omitted in continuous-time state-space realizations, unless needed to prevent ambiguity. A state-space realization of the discrete-time LTI system

$x_{k + 1} = A_{d} x_{k} + B_{d} u_{k},$

$y_{k} = C_{d} x_{k} + D_{d} u_{k},$

is often written compactly as $(A_{d}, B_{d}, C_{d}, D_{d})$ .

The $ℋ$ ∞ norm of the LTI system $𝒢$ is denoted by || $𝒢$ ||∞ and the $ℋ_{2}$ norm of $𝒢$ is denoted by || $𝒢$ || $_{2}$ .

The inner product spaces $ℒ_{2} a n d ℒ_{2 e}$ for continuous-time signals are defined as follows.

${ℒ_{2}} = {x : ℝ_{\geq 0} \to ℝ^{n} | | | x | |_{2}^{2} = \int_{0}^{\infty} x^{T} (t) x (t) d t < \infty},$

${ℒ_{2 e}} = {x : ℝ_{\geq 0} \to ℝ^{n} | | | x | |_{2 T}^{2} = \int_{0}^{T} x^{T} (t) x (t) d t < \infty, \forall T \in ℝ_{\geq 0}} .$

The inner product sequence spaces ℓ2 and ℓ2e for discrete-time signals are defined as follows.
${𝓁_{2}} = {x : ℤ_{\geq 0} \to ℝ^{n} | | | x | |_{2}^{2} = \sum_{k = 0}^{\infty} x_{k}^{T} x_{k} < \infty,} .$
${𝓁_{2 e}} = {x : ℤ_{\geq 0} \to ℝ^{n} | | | x | |_{2 N}^{2} = \sum_{k = 0}^{N} x_{k}^{T} x_{k} < \infty, \forall N \in ℤ_{\geq 0}} .$

Reference

LMIs in Control Systems: Analysis, Design and Applications - by Guang-Ren Duan and Hai-Hua Yu, CRC Press, Taylor & Francis Group, 2013
LMI Properties and Applications in Systems, Stability, and Control Theory - A List of LMIs by Ryan Caverly and James Forbes.
LMIs in Systems and Control Theory - A downloadable book on LMIs by Stephen Boyd.

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LMIs in Control/Click here to continue/Notation

Contents

Notations Related to Subspaces

Notations Related to Vectors and Matrices

Notations of Relations and Manipulations

Other Notations

Examples

Reference

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LMIs in Control/Click here to continue/Notation

Notations Related to Subspaces

Notations Related to Vectors and Matrices

Notations of Relations and Manipulations

Other Notations

Examples

Reference

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