The H∞ proportional-integral-differential(PID) feedback for arbitrary-order delayed multi-agent system is investigated to improve the system performance. The closed-loop multi-input multi-output(MIMO) control framework with the distributed PID controller is firstly described for the multi-agent system in a unified way. Then, by using the matrix theory, the prescribed H∞performance criterion of the multi-agent system is shown to be equivalent to several independent H∞ performance constraints of the single-input single-output(SISO) subsystem with respect to the eigenvalues of the Laplacian matrix. Subsequently, for each subsystem,the set of the PID controllers satisfying the required H∞ performance constraint is analytically characterized based on the extended Hermite-Biehler theorem. Finally, the three-dimensional set of the decentralized H∞ PID control parameters is derived by finding the intersection of the H∞ PID regions for all the decomposed subsystems. The simulation results reveal the effectiveness of the proposed method. The closed-loop multi-input multi-output (MIMO) control framework with the distributed PID controller is Then, by using the matrix theory, the prescribed H∞ performance criterion of the multi-agent system is shown to be equivalent to several independent H∞ performance constraints of the single-input single-output (SISO) subsystem with respect to the eigenvalues ​​of the Laplacian matrix. 是 什么 意思 _For each subsystem, the set of the PID controllers satisfies the required H∞ performance constraint is based on the extended Hermite-Biehler theorem. Finally, the three-dimensional set of the decentralized H∞ PID control parameters is derived by finding the intersection of the H∞ PID regions for all the decomposed subsystems. The simulation r esults reveal the effectiveness of the proposed method.