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8 results on '"Van Den Berg, Jur P."'

1. Multi-Armed Bandit Models for 2D Grasp Planning with Uncertainty

Author

Laskey, Michael, Mahler, Jeff, McCarthy, Zoe, Pokorny, Florian T, Patil, Sachin, Van Den Berg, Jur, Kragic, Danica, Abbeel, Pieter, and Goldberg, Ken

Subjects
Bioengineering
Abstract

For applications such as warehouse order fulfillment, robot grasps must be robust to uncertainty arising from sensing, mechanics, and control. One way to achieve robustness is to evaluate the performance of candidate grasps by sampling perturbations in shape, pose, and gripper approach and to compute the probability of force closure for each candidate to identify a grasp with the highest expected quality. Since evaluating the quality of each grasp is computationally demanding, prior work has turned to cloud computing. To improve computational efficiency and to extend this work, we consider how Multi-Armed Bandit (MAB) models for optimizing decisions can be applied in this context. We formulate robust grasp planning as a MAB problem and evaluate convergence times towards an optimal grasp candidate using 100 object shapes from the Brown Vision 2D Lab Dataset with 1000 grasp candidates per object. We consider the case where shape uncertainty is represented as a Gaussian process implicit surface (GPIS) with Gaussian uncertainty in pose, gripper approach angle, and coefficient of friction. We find that Thompson Sampling and the Gittins index MAB methods converged to within 3% of the optimal grasp up to 10x faster than uniform allocation and 5x faster than iterative pruning.

Published
2015

2. Potential-based bounded-cost search and Anytime Non-Parametric A⁎

Author

Stern, Roni, Felner, Ariel, van den Berg, Jur, Puzis, Rami, Shah, Rajat, and Goldberg, Ken

Subjects
Bioengineering, Heuristic search, Anytime algorithms, Robotics, Artificial Intelligence and Image Processing, Computation Theory and Mathematics, Cognitive Sciences, Artificial Intelligence & Image Processing
Abstract

This paper presents two new search algorithms: Potential Search (PTS) and Anytime Potential Search/Anytime Non-Parametric A* (APTS/ANA*). Both algorithms are based on a new evaluation function that is easy to implement and does not require user-tuned parameters. PTS is designed to solve bounded-cost search problems, which are problems where the task is to find as fast as possible a solution under a given cost bound. APTS/ANA* is a non-parametric anytime search algorithm discovered independently by two research groups via two very different derivations. In this paper, co-authored by researchers from both groups, we present these derivations: as a sequence of calls to PTS and as a non-parametric greedy variant of Anytime Repairing A*. We describe experiments that evaluate the new algorithms in the 15-puzzle, KPP-COM, robot motion planning, gridworld navigation, and multiple sequence alignment search domains. Our results suggest that when compared with previous anytime algorithms, APTS/ANA*: (1) does not require user-set parameters, (2) finds an initial solution faster, (3) spends less time between solution improvements, (4) decreases the suboptimality bound of the current-best solution more gradually, and (5) converges faster to an optimal solution when reachable. © 2014 Elsevier B.V.

Published
2014

5. Using workspace information as a guide to non-uniform sampling in probabilistic roadmap planners

Author

van den Berg, Jur P. and Overmars, Mark H.

Subjects
Robots -- Motion, Combinatorial probabilities -- Usage, Geometric probabilities -- Usage, Probabilities -- Usage, Computers and office automation industries, Engineering and manufacturing industries, Company business planning, Planning, Usage
Abstract

Abstract The probabilistic roadmap (PRM) planner is a popular method for robot motion planning problems with many degrees of freedom. However, it has been shown that the method performs less [...]

Published
2005

6. Roadmap-based motion planning in dynamic environments

Author

van den Berg, Jur P. and Overmars, Mark H.

Subjects
Algorithm, Technology application, Robotics -- Research, Incremental motion control -- Research, Algorithms -- Research, Algorithms -- Technology application
Abstract

In this paper, a new method is presented for motion planning in dynamic environments, that is, finding a trajectory for a robot in a scene consisting of both static and dynamic, moving obstacles. We propose a practical algorithm based on a roadmap that is created for the static part of the scene. On this roadmap, an approximately time-optimal trajectory from a start to a goal configuration is computed, such that the robot does not collide with any moving obstacle. The trajectory is found by performing a two-level search for a shortest path. On the local level, trajectories on single edges of the roadmap are found using a depth-first search on an implicit grid in state-time space. On the global level, these local trajectories are coordinated using an A*-search to find a global trajectory to the goal configuration. The approach is applicable to any robot type in configuration spaces with any dimension, and the motions of the dynamic obstacles are unconstrained, as long as they are known beforehand. The approach has been implemented for both free-flying and articulated robots in three-dimensional workspaces, and it has been applied to multirobot motion planning, as well. Experiments show that the method achieves interactive performance in complex environments. Index Terms--Dynamic environments, motion planning, multiple robots.

Published
2005

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