In this paper, we describe the Linear Temporal Logic-based reactive motion planning. We address the problem of motion planning for mobile robots, wherein the goal specification of planning is given in complex environments. The desired task specification may consist of complex behaviors of the robot, including specifications for environment constraints, need of task optimality, obstacle avoidance, rescue specifications, surveillance specifications, safety specifications, etc. We use Linear Temporal Logic to give a representation for such complex task specification and constraints. The specifications are used by a verification engine to judge the feasibility and suitability of plans. The planner gives a motion strategy as output. Finally a co...
This thesis is motivated by time and safety critical applications involving the use of autonomous ve...
Abstract — Manipulation planning from high-level task spec-ifications, even though highly desirable,...
The final version of this work is available at https://doi.org/10.1016/j.ifacol.2017.08.1578 Copyri...
In this paper, we describe the Linear Temporal Logic-based reactive motion planning. We address the ...
Abstract — This paper addresses the challenge of creating correct-by-construction controllers for ro...
This thesis focuses on temporal logic-based motion planning for autonomous ve- hicles. Specically pl...
Abstract—This paper describes an approach for solving motion planning problems for mobile robots inv...
Motivated by robotic motion planning, we develop a framework for control policy synthesis for both n...
This paper describes a holistic method for automatically synthesizing controllers for a team of robo...
Temporal-logic-based motion planning (TMP) provides a fully automated correct-by-design controller s...
Abstract — In this paper we propose a generic framework for real-time motion planning based on model...
International audienceIn this paper, we address the temporal logic motion planning problem for mobil...
In this thesis, we consider the problem of motion planning for robots with hybrid locomotion dynamic...
In this paper, a critical review on temporal logic motion planning is presented. The review paper ai...
Automated planning for manipulation tasks is highly desirable, for it enables robot manipulators to ...
This thesis is motivated by time and safety critical applications involving the use of autonomous ve...
Abstract — Manipulation planning from high-level task spec-ifications, even though highly desirable,...
The final version of this work is available at https://doi.org/10.1016/j.ifacol.2017.08.1578 Copyri...
In this paper, we describe the Linear Temporal Logic-based reactive motion planning. We address the ...
Abstract — This paper addresses the challenge of creating correct-by-construction controllers for ro...
This thesis focuses on temporal logic-based motion planning for autonomous ve- hicles. Specically pl...
Abstract—This paper describes an approach for solving motion planning problems for mobile robots inv...
Motivated by robotic motion planning, we develop a framework for control policy synthesis for both n...
This paper describes a holistic method for automatically synthesizing controllers for a team of robo...
Temporal-logic-based motion planning (TMP) provides a fully automated correct-by-design controller s...
Abstract — In this paper we propose a generic framework for real-time motion planning based on model...
International audienceIn this paper, we address the temporal logic motion planning problem for mobil...
In this thesis, we consider the problem of motion planning for robots with hybrid locomotion dynamic...
In this paper, a critical review on temporal logic motion planning is presented. The review paper ai...
Automated planning for manipulation tasks is highly desirable, for it enables robot manipulators to ...
This thesis is motivated by time and safety critical applications involving the use of autonomous ve...
Abstract — Manipulation planning from high-level task spec-ifications, even though highly desirable,...
The final version of this work is available at https://doi.org/10.1016/j.ifacol.2017.08.1578 Copyri...