Michael Z. Q. Chen mainly investigates Control theory, Nonlinear system, Control engineering, Consensus and Sliding mode control. His Control theory research incorporates elements of Aperiodic graph and State. His study in Control engineering is interdisciplinary in nature, drawing from both Adaptive observer, Directed graph, Graph and Robustness.
Michael Z. Q. Chen combines subjects such as Bounded function and Controllability with his study of Consensus. Michael Z. Q. Chen has included themes like Observability, Weak topology and Lipschitz continuity, Topology in his Controllability study. His research investigates the connection between Sliding mode control and topics such as Control system that intersect with problems in Vehicle dynamics, Active suspension and Variable structure control.
His scientific interests lie mostly in Control theory, Inerter, Multi-agent system, Topology and Nonlinear system. His work carried out in the field of Control theory brings together such families of science as Control engineering and Bounded function. His Inerter research is multidisciplinary, incorporating perspectives in Realization and Suspension.
His research investigates the connection between Multi-agent system and topics such as Graph that intersect with issues in Uniform consensus. His research on Topology also deals with topics like
His primary scientific interests are in Control theory, Inerter, Control, Topology and Smart grid. As part of his studies on Control theory, he frequently links adjacent subjects like Electric power system. His research in Inerter intersects with topics in Tuned mass damper, Realization and Skyhook.
His study on Control also encompasses disciplines like
His primary areas of investigation include Control theory, Multi-agent system, Topology, Control system and Synchronization. In most of his Control theory studies, his work intersects topics such as Integrator. Michael Z. Q. Chen has researched Multi-agent system in several fields, including Directed graph, Discrete time and continuous time and Linear-quadratic regulator.
His work carried out in the field of Topology brings together such families of science as Network model, Lyapunov stability, Topology and Complex network. His research investigates the connection with Control system and areas like PID controller which intersect with concerns in Actuator. Michael Z. Q. Chen has included themes like State, Consensus, Computer simulation, Algebraic Riccati equation and Adaptive system in his Synchronization study.
This overview was generated by a machine learning system which analysed the scientist’s body of work. If you have any feedback, you can contact us here.
Semi-Global Leader-Following Consensus of Linear Multi-Agent Systems With Input Saturation via Low Gain Feedback
Housheng Su;M. Z. Q. Chen;J. Lam;Zongli Lin.
IEEE Transactions on Circuits and Systems I-regular Papers (2013)
Semiglobal Observer-Based Leader-Following Consensus With Input Saturation
Housheng Su;Michael Z. Q. Chen;Xiaofan Wang;James Lam.
IEEE Transactions on Industrial Electronics (2014)
Unknown Input Observer-Based Robust Fault Estimation for Systems Corrupted by Partially Decoupled Disturbances
Zhiwei Gao;Xiaoxu Liu;Michael Z. Q. Chen.
IEEE Transactions on Industrial Electronics (2016)
Chattering-free discrete-time sliding mode control
Haibo Du;Xinghuo Yu;Michael Z.Q. Chen;Shihua Li.
Influence of inerter on natural frequencies of vibration systems
Michael Z.Q. Chen;Yinlong Hu;Lixi Huang;Guanrong Chen.
Journal of Sound and Vibration (2014)
Fuzzy Control for Uncertain Vehicle Active Suspension Systems via Dynamic Sliding-Mode Approach
Shiping Wen;Michael Z. Q. Chen;Zhigang Zeng;Xinghuo Yu.
systems man and cybernetics (2017)
Observer-Based Consensus Tracking of Nonlinear Agents in Hybrid Varying Directed Topology
Yang Cao;Liangyin Zhang;Chanying Li;Michael Z. Q. Chen.
IEEE Transactions on Systems, Man, and Cybernetics (2017)
Multi-agent containment control with input saturation on switching topologies
Housheng Su;Michael Z. Q. Chen.
Iet Control Theory and Applications (2015)
Finite-time consensus of multiple nonholonomic chained-form systems based on recursive distributed observer
Haibo Du;Guanghui Wen;Xinghuo Yu;Shihua Li.
H∞ pinning synchronization of directed networks with aperiodic sampled-data communications
Guanghui Wen;Wenwu Yu;Michael Z. Q. Chen;Xinghuo Yu.
IEEE Transactions on Circuits and Systems I-regular Papers (2014)
Profile was last updated on December 6th, 2021.
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