Active entanglement enables stochastic, topological grasping

Active entanglement enables stochastic, topological grasping

Grasping, in both biological and engineered mechanisms, can be highly sensitive to the gripper and object morphology, as well as perception and motion planning. Here, we circumvent the need for feedback or precise planning by using an array of fluidically actuated slender hollow elastomeric filament...

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Veröffentlicht in:Proceedings of the National Academy of Sciences - PNAS 2022-10, Vol.119 (42), p.e2209819119-e2209819119
Hauptverfasser: Becker, Kaitlyn, Teeple, Clark, Charles, Nicholas, Jung, Yeonsu, Baum, Daniel, Weaver, James C, Mahadevan, L, Wood, Robert
Format: Artikel
Sprache:eng
Schlagworte:
Arrays
Complexity
Computer applications
Elastomers
Entanglement
Filaments
Grasping
Hand Strength
Mathematical morphology
Motion detection
Motion planning
Physical Sciences
Robotics - methods
Stochasticity
Strategy
Topology
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Beschreibung
Zusammenfassung:Grasping, in both biological and engineered mechanisms, can be highly sensitive to the gripper and object morphology, as well as perception and motion planning. Here, we circumvent the need for feedback or precise planning by using an array of fluidically actuated slender hollow elastomeric filaments to actively entangle with objects that vary in geometric and topological complexity. The resulting stochastic interactions enable a unique soft and conformable grasping strategy across a range of target objects that vary in size, weight, and shape. We experimentally evaluate the grasping performance of our strategy and use a computational framework for the collective mechanics of flexible filaments in contact with complex objects to explain our findings. Overall, our study highlights how active collective entanglement of a filament array via an uncontrolled, spatially distributed scheme provides options for soft, adaptable grasping.
ISSN:0027-8424
1091-6490
DOI:10.1073/pnas.2209819119