We propose a human-operator guided planning approach to pushing-based manipulation in clutter. Most recent approaches to manipulation in clutter employs randomized planning. The problem, however, remains a challenging one where the planning times are still in the order of tens of seconds or minutes, and the success rates are low for difficult instances of the problem. We build on these control-based randomized planning approaches, but we investigate using them in conjunction with human-operator input. In our framework, the human operator supplies a high-level plan, in the form of an ordered sequence of objects and their approximate goal positions. We present experiments in simulation and on a real robotic setup, where we compare the success rate and planning times of our human-in-the-loop approach with fully autonomous sampling-based planners. We show that with a minimal amount of human input, the low-level planner can solve the problem faster and with higher success rates.
Manipulation in clutter requires solving complex sequential decision making problems in an environment rich with physical interactions. The transfer of motion planning solutions from simulation to the real world, in open-loop, suffers from the inherent uncertainty in modelling real world physics. We propose interleaving planning and execution in real-time, in a closed-loop setting, using a Receding Horizon Planner (RHP) for pushing manipulation in clutter. In this context, we address the problem of finding a suitable value function based heuristic for efficient planning, and for estimating the cost-to-go from the horizon to the goal. We estimate such a value function first by using plans generated by an existing sampling-based planner. Then, we further optimize the value function through reinforcement learning. We evaluate our approach and compare it to state-of-the-art planning techniques for manipulation in clutter. We conduct experiments in simulation with artificially injected uncertainty on the physics parameters, as well as in real world tasks of manipulation in clutter. We show that this approach enables the robot to react to the uncertain dynamics of the real world effectively. arXiv:1803.08100v2 [cs.RO]
We present a predictive system for non-prehensile, physics-based motion planning in clutter with a human-inthe-loop. Recent shared-autonomous systems present motion planning performance improvements when high-level reasoning is provided by a human. Humans are usually good at quickly identifying high-level actions in high-dimensional spaces, and robots are good at converting high-level actions into valid robot trajectories. In this paper, we present a novel framework that permits a single human operator to effectively guide a fleet of robots in a virtual warehouse. The robots are tackling the problem of Reaching Through Clutter (RTC), where they are reaching onto cluttered shelves to grasp a goal object while pushing other obstacles out of the way. We exploit information from the motion planning algorithm to predict which robot requires human help the most and assign that robot to the human. With twenty virtual robots and a single human-operator, the results suggest that this approach improves the system's overall performance compared to a baseline with no predictions. The results also show that there is a cap on how many robots can effectively be guided simultaneously by a single human operator.
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