Add to ORKGThis thesis develops a series of knowledge-oriented physics-based motion planning algorithms for grasping and manipulation in cluttered an uncertain environments. The main idea is to use high-level knowledge-based reasoning to define the manipulation constraints that define the way how robot should interact with the objects in the environment. These interactions are modeled by incorporating the physics-based model of rigid body dynamics in planning. The first part of the thesis is focused on the techniques to integrate the knowledge with physics-based motion planning. The knowledge is represented in terms of ontologies, a prologbased knowledge inference process is introduced that defines the manipulation constraints. These constraints are...
In manipulation planning, dynamic interactions between the objects and the robots play a significant...
This paper presents a strategy for planning robot motions in dynamic, cluttered, and uncertain envir...
This thesis presents planners and controllers for robust physics-based manipulation in real-time. By...
Grasping an object in unstructured and uncertain environments is a challenging task, particularly wh...
© 20xx IEEE. Personal use of this material is permitted. Permission from IEEE must be obtained for a...
This thesis develops a series of modeling and reasoning tools for knowledge-oriented manipulation pl...
Robotic manipulation involves actions where contacts occur between the robot and the objects. In thi...
Physics-based motion planning is a challenging task, since it requires the computation of the robot ...
This thesis addresses the combination of task and motion planning which deals with different types o...
Robots must successfully plan and execute tasks in the presence of uncertainty. Uncertainty arises...
A number of outstanding problems in robotic motion and manipulation involve tasks where degrees of f...
The final version of this work is available at https://doi.org/10.1016/j.ifacol.2017.08.1578 Copyri...
The book covers a variety of topics in Information and Communications Technology (ICT) and their imp...
This paper presents an algorithm for automatic planning of robot grasping motions that are insensiti...
Service robots that can assist humans in performing day-to-day tasks will need to be general-purpose...
In manipulation planning, dynamic interactions between the objects and the robots play a significant...
This paper presents a strategy for planning robot motions in dynamic, cluttered, and uncertain envir...
This thesis presents planners and controllers for robust physics-based manipulation in real-time. By...
Grasping an object in unstructured and uncertain environments is a challenging task, particularly wh...
© 20xx IEEE. Personal use of this material is permitted. Permission from IEEE must be obtained for a...
This thesis develops a series of modeling and reasoning tools for knowledge-oriented manipulation pl...
Robotic manipulation involves actions where contacts occur between the robot and the objects. In thi...
Physics-based motion planning is a challenging task, since it requires the computation of the robot ...
This thesis addresses the combination of task and motion planning which deals with different types o...
Robots must successfully plan and execute tasks in the presence of uncertainty. Uncertainty arises...
A number of outstanding problems in robotic motion and manipulation involve tasks where degrees of f...
The final version of this work is available at https://doi.org/10.1016/j.ifacol.2017.08.1578 Copyri...
The book covers a variety of topics in Information and Communications Technology (ICT) and their imp...
This paper presents an algorithm for automatic planning of robot grasping motions that are insensiti...
Service robots that can assist humans in performing day-to-day tasks will need to be general-purpose...
In manipulation planning, dynamic interactions between the objects and the robots play a significant...
This paper presents a strategy for planning robot motions in dynamic, cluttered, and uncertain envir...
This thesis presents planners and controllers for robust physics-based manipulation in real-time. By...