Journal ArticleDOI
Probabilistic Collision Checking With Chance Constraints
Noel E. Du Toit,J.W. Burdick +1 more
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TLDR
An alternative formulation of probabilistic collision checking that accounts for robot and obstacle uncertainty is presented which allows for dependent object distributions and has been applied to robot-motion planning in dynamic, uncertain environments.Abstract:
Obstacle avoidance, and by extension collision checking, is a basic requirement for robot autonomy. Most classical approaches to collision-checking ignore the uncertainties associated with the robot and obstacle's geometry and position. It is natural to use a probabilistic description of the uncertainties. However, constraint satisfaction cannot be guaranteed, in this case, and collision constraints must instead be converted to chance constraints. Standard results for linear probabilistic constraint evaluation have been applied to probabilistic collision evaluation; however, this approach ignores the uncertainty associated with the sensed obstacle. An alternative formulation of probabilistic collision checking that accounts for robot and obstacle uncertainty is presented which allows for dependent object distributions (e.g., interactive robot-obstacle models). In order to efficiently enforce the resulting collision chance constraints, an approximation is proposed and the validity of this approximation is evaluated. The results presented here have been applied to robot-motion planning in dynamic, uncertain environments.read more
Citations
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Journal ArticleDOI
Funnel libraries for real-time robust feedback motion planning:
Anirudha Majumdar,Russ Tedrake +1 more
TL;DR: By explicitly taking into account the effect of uncertainty, the robot can evaluate motion plans based on how vulnerable they are to disturbances, and constitute one of the first examples of provably safe and robust control for robotic systems with complex nonlinear dynamics that need to plan in real time in environments with complex geometric constraints.
Journal ArticleDOI
Robot navigation in dense human crowds: Statistical models and experimental studies of human-robot cooperation
TL;DR: It is concluded that a cooperation model is critical for safe and efficient robot navigation in dense human crowds and the salient characteristics of nearly any dynamic navigation algorithm.
Journal ArticleDOI
Robot Motion Planning in Dynamic, Uncertain Environments
Noel E. Du Toit,J.W. Burdick +1 more
TL;DR: To approximately solve the stochastic dynamic programming problem that is associated with DUE planning, a partially closed-loop receding horizon control algorithm is presented whose solution integrates prediction, estimation, and planning while also accounting for chance constraints that arise from the uncertain locations of the robot and obstacles.
Journal ArticleDOI
Chance-Constrained Collision Avoidance for MAVs in Dynamic Environments
Hai Zhu,Javier Alonso-Mora +1 more
TL;DR: A tight bound for approximation of collision probability is developed, which makes the CCNMPC formulation tractable and solvable in real time.
Posted Content
Funnel Libraries for Real-Time Robust Feedback Motion Planning
Anirudha Majumdar,Russ Tedrake +1 more
TL;DR: In this paper, a library of "funnels" along different maneuvers of the system that the state is guaranteed to remain within (despite bounded disturbances) when the feedback controller corresponding to the maneuver is executed is computed.
References
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Book
Probabilistic Robotics
TL;DR: This research presents a novel approach to planning and navigation algorithms that exploit statistics gleaned from uncertain, imperfect real-world environments to guide robots toward their goals and around obstacles.
MonographDOI
Planning Algorithms: Introductory Material
TL;DR: This coherent and comprehensive book unifies material from several sources, including robotics, control theory, artificial intelligence, and algorithms, into planning under differential constraints that arise when automating the motions of virtually any mechanical system.
Book
Robot Motion Planning
TL;DR: This chapter discusses the configuration space of a Rigid Object, the challenges of dealing with uncertainty, and potential field methods for solving these problems.
Journal ArticleDOI
The dynamic window approach to collision avoidance
TL;DR: This approach, designed for mobile robots equipped with synchro-drives, is derived directly from the motion dynamics of the robot and safely controlled the mobile robot RHINO in populated and dynamic environments.
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