Extends model-free CBF design to higher relative degree via funnel control, avoiding dynamic models and full state feedback, with validation on a 7DOF manipulator.
A neural signed configuration distance function for path planning of picking manipulators
1 Pith paper cite this work. Polarity classification is still indexing.
abstract
Picking manipulators are task specific robots, with fewer degrees of freedom compared to general-purpose manipulators, and are heavily used in industry. The efficiency of the picking robots is highly dependent on the path planning solution, which is commonly based on sampling-based multi-query methods. The planner is robustly able to solve the problem, but its heavy use of collision-detection limits the planning capabilities for online use. We approach this problem by presenting a novel implicit obstacle representation for path planning, a neural signed configuration distance function (nSCDF), which allows us to form collision-free balls in the configuration space. We use the ball representation to re-formulate a state of the art multi-query path planner, i.e., instead of points, we use balls in the graph. Our planner returns a collision-free corridor, which allows us to use convex programming to produce optimized paths. From our numerical experiments, we observe that our planner produces paths that are close to those from an asymptotically optimal path planner, in significantly less time.
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2026 1verdicts
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A model-free approach to control barrier functions for higher-order systems
Extends model-free CBF design to higher relative degree via funnel control, avoiding dynamic models and full state feedback, with validation on a 7DOF manipulator.