In the search for useful strategies for movement of robotic systems (e.g. manipulators, platforms) in constrained environments (e.g. in space, underwater), there appear to be new principles emerging from a deeper geometric understanding of optimal movements of nonholonomically constrained systems. In our work, we have exploited some new formulas for geometric phase shifts to derive effective control strategies. The theory of connections in principal bundles provides the proper framework for questions of the type addressed in this paper. we outline the essentials of this theory. A related optimal control problem and its localizations are also considered
We deal with motion planning problems for nonholonomic systems. Our approach is based on optimal con...
1 Motivation Nonholonomic mechanical systems naturally occur whenthere are rolling constraints [4] o...
As applications have grown in the fields of robotics and automation, power systems, and electronic c...
Robotic locomotion is based in a variety of instances upon cyclic changes in the shape of a robot me...
This dissertation is concerned with dynamic modeling and kinematic control of constrained mechanical...
This paper uses geometric methods to study basic problems in locomotion. We consider in detail the c...
UnrestrictedThe goal of this work is to develop methods to optimally control autonomous robotic vehi...
: In this paper we present a simplified formulation of the necessary conditions for optimal controls...
In this dissertation we examine a class of systems where nonholonomic kinematic constraints are comb...
Abstract. This paper discusses dynamical systems for disk-covering and sphere-packing prob-lems. We ...
(Department of Mathematics) The proposed research is based on theoretical study and experiments whic...
Abstract In this paper, we describe a constrained Lagrangian and Hamiltonian formalism for the optim...
iii This thesis is a collection of seven independent papers dealing with different topics in the ana...
This paper addresses the problem of constrained motion for a manipulator performing a task while in ...
Abstract. In this paper, we consider a geometric formalism for optimal control of under-actuated mec...
We deal with motion planning problems for nonholonomic systems. Our approach is based on optimal con...
1 Motivation Nonholonomic mechanical systems naturally occur whenthere are rolling constraints [4] o...
As applications have grown in the fields of robotics and automation, power systems, and electronic c...
Robotic locomotion is based in a variety of instances upon cyclic changes in the shape of a robot me...
This dissertation is concerned with dynamic modeling and kinematic control of constrained mechanical...
This paper uses geometric methods to study basic problems in locomotion. We consider in detail the c...
UnrestrictedThe goal of this work is to develop methods to optimally control autonomous robotic vehi...
: In this paper we present a simplified formulation of the necessary conditions for optimal controls...
In this dissertation we examine a class of systems where nonholonomic kinematic constraints are comb...
Abstract. This paper discusses dynamical systems for disk-covering and sphere-packing prob-lems. We ...
(Department of Mathematics) The proposed research is based on theoretical study and experiments whic...
Abstract In this paper, we describe a constrained Lagrangian and Hamiltonian formalism for the optim...
iii This thesis is a collection of seven independent papers dealing with different topics in the ana...
This paper addresses the problem of constrained motion for a manipulator performing a task while in ...
Abstract. In this paper, we consider a geometric formalism for optimal control of under-actuated mec...
We deal with motion planning problems for nonholonomic systems. Our approach is based on optimal con...
1 Motivation Nonholonomic mechanical systems naturally occur whenthere are rolling constraints [4] o...
As applications have grown in the fields of robotics and automation, power systems, and electronic c...