The scientist’s investigation covers issues in Control theory, Lyapunov function, Exponential stability, Nonlinear system and State. His research investigates the connection with Control theory and areas like Bounded function which intersect with concerns in Output feedback. His research investigates the link between Lyapunov function and topics such as Backstepping that cross with problems in Feedback form.
His Exponential stability research incorporates themes from Control system, Robust control, Discrete time and continuous time and Applied mathematics. His work on Nonlinear control and Lyapunov approach as part of general Nonlinear system research is frequently linked to Quantized feedback, Quantization and Functional approach, thereby connecting diverse disciplines of science. The LTI system theory research he does as part of his general Linear system study is frequently linked to other disciplines of science, such as Reduction, therefore creating a link between diverse domains of science.
His primary areas of study are Control theory, Nonlinear system, Lyapunov function, Exponential stability and Linear system. His Control theory research is multidisciplinary, incorporating elements of State and Bounded function. His Nonlinear system study combines topics from a wide range of disciplines, such as Control system, Stability, Discrete time and continuous time, Observer and Applied mathematics.
His Lyapunov function research integrates issues from Nonlinear control, Mathematical analysis and Stability theory. His work carried out in the field of Exponential stability brings together such families of science as Type and Feed forward. His studies deal with areas such as Upper and lower bounds, Pointwise and Interval as well as Linear system.
Frédéric Mazenc mainly focuses on Control theory, Nonlinear system, Exponential stability, Observer and Linear system. The Control theory study combines topics in areas such as Pointwise and Bounded function. Frédéric Mazenc combines subjects such as Control, Point and Applied mathematics with his study of Nonlinear system.
In most of his Exponential stability studies, his work intersects topics such as Positive systems. His biological study spans a wide range of topics, including Finite time, Tracking, State, Output feedback and Nonholonomic system. As a part of the same scientific study, he usually deals with the Linear system, concentrating on Trajectory and frequently concerns with Upper and lower bounds.
Control theory, Nonlinear system, Lyapunov function, Exponential stability and Linear system are his primary areas of study. His Control theory research incorporates elements of Pointwise and Bounded function. His studies examine the connections between Nonlinear system and genetics, as well as such issues in Control system, with regards to Disturbance and Lyapunov approach.
His research in Lyapunov function intersects with topics in Nonlinear control, Control theory and Stability theory. As a member of one scientific family, he mostly works in the field of Exponential stability, focusing on Positive systems and, on occasion, Lyapunov exponent, Lyapunov equation, Lyapunov redesign and Lyapunov optimization. His Linear system research integrates issues from Stability, Class, Upper and lower bounds and Mathematical optimization.
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Adding integrations, saturated controls, and stabilization for feedforward systems
F. Mazenc;L. Praly.
IEEE Transactions on Automatic Control (1996)
Global stabilization by output feedback: examples and counterexamples
F. Mazenc;L. Praly;W. P. Dayawansa.
Systems & Control Letters (1994)
Interval observers for linear time-invariant systems with disturbances
Frédéric Mazenc;Olivier Bernard.
Backstepping design for time-delay nonlinear systems
F. Mazenc;P.-A. Bliman.
IEEE Transactions on Automatic Control (2006)
Global asymptotic stabilization for chains of integrators with a delay in the input
F. Mazenc;S. Mondie;S.-I. Niculescu.
IEEE Transactions on Automatic Control (2003)
Global asymptotic stabilization of feedforward systems with delay in the input
F. Mazenc;S. Mondie;R. Francisco.
IEEE Transactions on Automatic Control (2004)
Brief paper: Further results on input-to-state stability for nonlinear systems with delayed feedbacks
Frédéric Mazenc;Michael Malisoff;Zongli Lin.
Global uniform asymptotic stabilization of an underactuated surface vessel
F. Mazenc;K. Pettersen;H. Nijmeijer.
IEEE Transactions on Automatic Control (2002)
Brief Tracking trajectories of the cart-pendulum system
FréDéRic Mazenc;Samuel Bowong.
Asymptotically Stable Interval Observers for Planar Systems With Complex Poles
F. Mazenc;O. Bernard.
IEEE Transactions on Automatic Control (2010)
Profile was last updated on December 6th, 2021.
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