This paper studies the global exponential synchronization of uncertain complex delayed dynamical networks. The network model considered is general dynamical delay networks with unknown network structure and unknown co...This paper studies the global exponential synchronization of uncertain complex delayed dynamical networks. The network model considered is general dynamical delay networks with unknown network structure and unknown coupling functions but bounded. Novel delay-dependent linear controllers are designed via the Lyapunov stability theory. Especially, it is shown that the controlled networks are globally exponentially synchronized with a given convergence rate. An example of typical dynamical network of this class, having the Lorenz system at each node, has been used to demonstrate and verify the novel design proposed. And, the numerical simulation results show the effectiveness of proposed synchronization approaches.展开更多
Hybrid energy storage system(HESS)is an effective solution to address power imbalance problems caused by variability of renewable energy resources and load fluctuations in DC microgrids.The goal of HESS is to efficien...Hybrid energy storage system(HESS)is an effective solution to address power imbalance problems caused by variability of renewable energy resources and load fluctuations in DC microgrids.The goal of HESS is to efficiently utilize different types of energy storage systems,each with its unique characteristics.Normally,the energy management of HESS relies on centralized control methods,which have limitations in flexibility,scalability,and reliability.This paper proposes an innovative artifi-cial neural network(ANN)based model predictive control(MPC)method,integrated with a decentralized pow-er-sharing strategy for HESS.In the proposed technique,MPC is employed as an expert to provide data to train the ANN.Once the ANN is finely tuned,it is directly utilized to control the DC-DC converters,eliminating the need for the extensive computations typically required by conven-tional MPC.In the proposed control scheme,virtual re-sistance droop control for fuel cell(FC)and virtual ca-pacitance droop control for battery are designed in a decentralized manner to achieve power-sharing,enhance lifespan,and ensure HESS stability.As a result,the FC is able to support steady state loads,while the battery han-dles rapid load variations.Simulation results using Matlab/Simulink demonstrate the effective performance of the proposed controller under different loads and input variations,showcasing improved performance compared to conventional MPC.展开更多
文摘This paper studies the global exponential synchronization of uncertain complex delayed dynamical networks. The network model considered is general dynamical delay networks with unknown network structure and unknown coupling functions but bounded. Novel delay-dependent linear controllers are designed via the Lyapunov stability theory. Especially, it is shown that the controlled networks are globally exponentially synchronized with a given convergence rate. An example of typical dynamical network of this class, having the Lorenz system at each node, has been used to demonstrate and verify the novel design proposed. And, the numerical simulation results show the effectiveness of proposed synchronization approaches.
基金supported by the National Natural Sci-ence Foundation(NNSF)of China(No.62103443)Hunan Natural Science Foundation(No.2022JJ40630).
文摘Hybrid energy storage system(HESS)is an effective solution to address power imbalance problems caused by variability of renewable energy resources and load fluctuations in DC microgrids.The goal of HESS is to efficiently utilize different types of energy storage systems,each with its unique characteristics.Normally,the energy management of HESS relies on centralized control methods,which have limitations in flexibility,scalability,and reliability.This paper proposes an innovative artifi-cial neural network(ANN)based model predictive control(MPC)method,integrated with a decentralized pow-er-sharing strategy for HESS.In the proposed technique,MPC is employed as an expert to provide data to train the ANN.Once the ANN is finely tuned,it is directly utilized to control the DC-DC converters,eliminating the need for the extensive computations typically required by conven-tional MPC.In the proposed control scheme,virtual re-sistance droop control for fuel cell(FC)and virtual ca-pacitance droop control for battery are designed in a decentralized manner to achieve power-sharing,enhance lifespan,and ensure HESS stability.As a result,the FC is able to support steady state loads,while the battery han-dles rapid load variations.Simulation results using Matlab/Simulink demonstrate the effective performance of the proposed controller under different loads and input variations,showcasing improved performance compared to conventional MPC.
