Artificial-delay control is a method in which state and input measurements collected at an immediate past time instant (i.e. artificially delayed) are used to compensate the uncertain dynamics affecting the system at the current time. This work formulates an artificial-delay control method with adaptive gains in the presence of nonlinear (Euler-Lagrange) under-actuation. The appeal of studying Euler-Lagrange dynamics is to capture many robotics applications of practical interest, as demonstrated via stability and robustness analysis and via robotic ship and robotic aerial vehicle test cases.Accepted Author ManuscriptTeam DeSchutte
This research makes the Lorentz chaotic system to be synchronized with the L? chaotic system. For sy...
The control of physical systems in the presence of time-delays becomes particularly chal-lenging whe...
International audienceStabilization of nonlinear systems under delays is a central and challenging p...
This paper presents a practical adaptive time-delay control scheme (ATDC) and then applies it to rob...
This brief proposes a new adaptive-robust formulation for time-delay control (TDC) under a less-rest...
The robot manipulators are used in network-based industrial units, and even homes, by expending a si...
The design and tuning of a simple feedback strategy with delay to stabilize a class of underactuated...
This dissertation studies the stability and robustness of an adaptive control framework for underact...
The stability and safety of robotic systems are heavily impacted by delays and parametric uncertaint...
A model-reference adaptive control strategy is proposed for a delay chaotic system with known or unk...
This article proposes an enhanced adaptive time delay controller (ATDC) for robot manipulators subje...
This paper proposes a control framework that addresses the destabilizing effect of communication tim...
The objective of this dissertation is to explore the use of adaptive feedback control algorithms in ...
International audienceAn output robust adaptive control is designed for a class of Lipschitz nonline...
This study proposes an innovative reinforcement learning-based time-delay control (RL-TDC) scheme to...
This research makes the Lorentz chaotic system to be synchronized with the L? chaotic system. For sy...
The control of physical systems in the presence of time-delays becomes particularly chal-lenging whe...
International audienceStabilization of nonlinear systems under delays is a central and challenging p...
This paper presents a practical adaptive time-delay control scheme (ATDC) and then applies it to rob...
This brief proposes a new adaptive-robust formulation for time-delay control (TDC) under a less-rest...
The robot manipulators are used in network-based industrial units, and even homes, by expending a si...
The design and tuning of a simple feedback strategy with delay to stabilize a class of underactuated...
This dissertation studies the stability and robustness of an adaptive control framework for underact...
The stability and safety of robotic systems are heavily impacted by delays and parametric uncertaint...
A model-reference adaptive control strategy is proposed for a delay chaotic system with known or unk...
This article proposes an enhanced adaptive time delay controller (ATDC) for robot manipulators subje...
This paper proposes a control framework that addresses the destabilizing effect of communication tim...
The objective of this dissertation is to explore the use of adaptive feedback control algorithms in ...
International audienceAn output robust adaptive control is designed for a class of Lipschitz nonline...
This study proposes an innovative reinforcement learning-based time-delay control (RL-TDC) scheme to...
This research makes the Lorentz chaotic system to be synchronized with the L? chaotic system. For sy...
The control of physical systems in the presence of time-delays becomes particularly chal-lenging whe...
International audienceStabilization of nonlinear systems under delays is a central and challenging p...