Rigidity of the structured singular value and applications
Abstract: The structured singular value $μ_E$ for a linear subspace $E$ of $M_n(\mathbb C)$ is defined by [ μ_E(A)=1 / \inf{|X| \ : \ X \in E, \ \det(I_n-AX)=0 } \quad (A \in M_n(\mathbb{C})), ] and $μ_E(A)=0$ if there is no $X \in E$ with $\det(I_n-AX)=0$. It is well-known that $μ_E(A)$ coincides with the spectral radius $r(A)$ when $E={cI_n: c \in \mathbb C }$ and $μ_E(A)=|A|$ when $E=M_n(\mathbb C)$, for all $A\in M_n(\mathbb C)$. Also, for any linear subspace $E$ satisfying ${cI_n: c \in \mathbb C } \subseteq E \subseteq M_n(\mathbb C)$, we have $r(A)\leq μ_E(A) \leq |A|$. We prove that if $E={cI_n: c \in \mathbb C }$ and $F$ is any linear subspace of $M_n(\mathbb C)$ containing $E$, then $μ_E=μ_F$ if and only if $E=F$. We prove the exact same rigidity theorem for the linear subspace consisting of the diagonal matrices of order $n$. On the contrary, when $E=M_n(\mathbb C)$, we show that there is a proper subspace $F$ of $M_n(\mathbb C)$, viz. the space of symmetric matrices such that $μ_E=μ_F=$ operator norm. Further, we characterize all linear subspaces $F\subseteq M_n(\mathbb C)$ such that $μ_F$ coincides with the operator norm. Next, we show that in general there is no subspace $E$ of $M_n(\mathbb C)$ such that $μ_E=$ the numerical radius, not even for $M_2(\mathbb C)$. We establish the rigidity of the structured singular value for each of the subspaces $E$ of $M_2(\mathbb C)$ such that the corresponding $μ_E$-unit ball induces the domains -- symmetrized bidisc, tetrablock, pentablock, hexablock.
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