Add to ORKGThis work presents a novel motion planning framework, rooted in nonlinear programming theory, that treats uncertain fully and under-actuated dynamical systems described by ordinary differential equations. Uncertainty in multibody dynamical systems comes from various sources, such as: system parameters, initial conditions, sensor and actuator noise, and external forcing. Treatment of uncertainty in design is of paramount practical importance because all real-life systems are affected by it, and poor robustness and suboptimal performance result if it’s not accounted for in a given design. In this work uncertainties are modeled using Generalized Polynomial Chaos and are solved quantitatively using a least-square collocation method. The computa...
Developing efficient control algorithms for practical scenarios remains a key challenge for the scie...
This paper develops a novel probabilistic framework for stochastic nonlinear and uncertain control p...
AbstractIn robotics uncertainty exists at both planning and execution time. Effective planning must ...
Variation occurs in many multi-body dynamic (MBD) systems in the geometry, mass, or forces. This var...
Multibody dynamics plays the key role in the modeling, simulation, design, and control of many engin...
This study explores the use of generalized polynomial chaos theory for modeling complex nonlinear mu...
Motion planning under uncertainty is essential to autonomous robots. Over the past decade, the scal...
This paper proposes a novel approach to the solution of optimal control problems under uncertainty (...
This is the first part of a two-part article. A new computational approach for parameter estimation...
We use Lyapunov-like functions and convex optimization to propagate uncertainty in the initial condi...
A method for modeling uncertainties that exist in a robotic system, based on stochastic differential...
AbstractThis paper deals with the initial development of a methodology for controlling real-life, mu...
In a wide variety of research fields, dynamic modeling is employed as an instrument to learn and und...
This thesis explores the potential for utilizing direct methods in optimal control to solve trajecto...
Kinodynamic motion planning addresses the problem of finding the control inputs to a dynamical syste...
Developing efficient control algorithms for practical scenarios remains a key challenge for the scie...
This paper develops a novel probabilistic framework for stochastic nonlinear and uncertain control p...
AbstractIn robotics uncertainty exists at both planning and execution time. Effective planning must ...
Variation occurs in many multi-body dynamic (MBD) systems in the geometry, mass, or forces. This var...
Multibody dynamics plays the key role in the modeling, simulation, design, and control of many engin...
This study explores the use of generalized polynomial chaos theory for modeling complex nonlinear mu...
Motion planning under uncertainty is essential to autonomous robots. Over the past decade, the scal...
This paper proposes a novel approach to the solution of optimal control problems under uncertainty (...
This is the first part of a two-part article. A new computational approach for parameter estimation...
We use Lyapunov-like functions and convex optimization to propagate uncertainty in the initial condi...
A method for modeling uncertainties that exist in a robotic system, based on stochastic differential...
AbstractThis paper deals with the initial development of a methodology for controlling real-life, mu...
In a wide variety of research fields, dynamic modeling is employed as an instrument to learn and und...
This thesis explores the potential for utilizing direct methods in optimal control to solve trajecto...
Kinodynamic motion planning addresses the problem of finding the control inputs to a dynamical syste...
Developing efficient control algorithms for practical scenarios remains a key challenge for the scie...
This paper develops a novel probabilistic framework for stochastic nonlinear and uncertain control p...
AbstractIn robotics uncertainty exists at both planning and execution time. Effective planning must ...