A simple pole-shifting gain matrix $K$ which avoids solving Lyapunov equations (2402.10489v1)

Abstract: It is well known that if $A\in\mathbb{C}^{N\times N}$ and $B\in\mathbb{C}^{N\times M}$ form a controllable pair (in the sense that the Kalman matrix $[B\ |\ AB\ | \ \dots\ |\ A^{N-1}B]$ has full rank) then, there exists $K\in\mathbb{C}^{M\times N}$ such that the matrix $A+BK$ has only eigenvalues with negative real parts. The matrix $K$ is not unique, and is usually defined by a solution of a Lyapunov equation, which, in case of large $N$, is not easily manageable from the computational point of view. In this work, we show that, for general matrices $A$ and $B$, if they satisfy the controllability Kalman rank condition, then $$K=-\overline{B}^\top\sum_{k=1}^N\left[(\overline{A}^\top+\gamma_kI)^{-1}\right]\left{\sum_{k=1}^N\left[(A+\gamma_kI)^{-1}B\overline{B}^\top(\overline{A}^\top+\gamma_kI)^{-1}\right]\right}^{-1}$$ ensures that the matrix $A+BK$ has all the eigenvalues with the real part less than $-\gamma_1$. Here, $0<\gamma_1<\gamma_2<\dots<\gamma_N$ are $N$ positive numbers, large enough such that $A+\gamma_kI$ is invertible, for each $k$.