A distributed coordinated consensus problem for multiple networked Euler-Lagrange systems is studied.The communication between agents is subject to time delays,unknown parameters and nonlinear inputs,but only with the...A distributed coordinated consensus problem for multiple networked Euler-Lagrange systems is studied.The communication between agents is subject to time delays,unknown parameters and nonlinear inputs,but only with their states available for measurement.When the communication topology of the system is connected,an adaptive control algorithm with selfdelays and uncertainties is suggested to guarantee global full-state synchro-nization that the difference between the agent's positions and ve-locities asymptotically converges to zero.Moreover,the distributed sliding-mode law is given for chaotic systems with nonlinear inputs to compensate for the effects of nonlinearity.Finally,simulation results show the effectiveness of the proposed control algorithm.展开更多
Redundancy control can effectively enhance the stability and robustness of a system.Based on the conventional redundancy control switchover and majority arbitration strategy,this paper introduces the concept of hetero...Redundancy control can effectively enhance the stability and robustness of a system.Based on the conventional redundancy control switchover and majority arbitration strategy,this paper introduces the concept of heterogeneity and dynamics,constructs a dynamic heterogeneous redundancy-based microcontroller architecture DHR-MCU,and designs a fixed-leader distributed consensus algorithm that satisfies the program running state control of this architecture.The theoretical analysis and actual measurement of the prototype system prove that this architecture has good anti-attack and self-recovery capabilities under normal functions and performances and meets the general robust features in terms of safety and security.展开更多
基金supported by the National Natural Sciences Foundation of China(60974146)
文摘A distributed coordinated consensus problem for multiple networked Euler-Lagrange systems is studied.The communication between agents is subject to time delays,unknown parameters and nonlinear inputs,but only with their states available for measurement.When the communication topology of the system is connected,an adaptive control algorithm with selfdelays and uncertainties is suggested to guarantee global full-state synchro-nization that the difference between the agent's positions and ve-locities asymptotically converges to zero.Moreover,the distributed sliding-mode law is given for chaotic systems with nonlinear inputs to compensate for the effects of nonlinearity.Finally,simulation results show the effectiveness of the proposed control algorithm.
文摘Redundancy control can effectively enhance the stability and robustness of a system.Based on the conventional redundancy control switchover and majority arbitration strategy,this paper introduces the concept of heterogeneity and dynamics,constructs a dynamic heterogeneous redundancy-based microcontroller architecture DHR-MCU,and designs a fixed-leader distributed consensus algorithm that satisfies the program running state control of this architecture.The theoretical analysis and actual measurement of the prototype system prove that this architecture has good anti-attack and self-recovery capabilities under normal functions and performances and meets the general robust features in terms of safety and security.
