Deaho Moon scite author profile

Deaho Moon

5Publications

96Citation Statements Received

17Citation Statements Given

How they've been cited

147

How they cite others

122

Affiliations

University of California, Berkeley, University of California, Los Angeles

Publications

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Rapid prototyping design and control of tensegrity soft robot for locomotion

Kim

Agogino

Moon

et al. 2014

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Co-robots that can effectively move with and operate alongside humans in a variety of conditions could revolutionize the utility of robots for a wide range of applications. Unfortunately, most current robotic systems have difficulty operating in human environments that people easily traverse, much less interact with people. Wheeled robots have difficulty climbing stairs or going over rough terrain. Heavy and powerful legged robots pose safety risks when interacting with humans. Compliant, lightweight tensegrity robots built from interconnected tensile (cables) and compressive (rods) elements are promising structures for co-robotic applications. This paper describes design and control of a rapidly prototyped tensegrity robot for locomotion. The software and hardware of this robot can be extended to build a wide range of tensegrity robotic configurations and control strategies. This rapid prototyping approach will greatly lower the barrier-of-entry in time and cost for research groups studying tensegrity robots suitable for co-robot applications.

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Robust learning of tensegrity robot control for locomotion through form-finding

Kim

Agogino

Toghyan

et al. 2015

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Design of a spherical tensegrity robot for dynamic locomotion

Kim

Moon

Bin

et al. 2017

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ModMan: An Advanced Reconfigurable Manipulator System With Genderless Connector and Automatic Kinematic Modeling Algorithm

Yun

Moon²,

Ha³

et al. 2020

IEEE Robot. Autom. Lett.

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Walk-Burrow-Tug: Legged Anchoring Analysis Using RFT-Based Granular Limit Surfaces

Huh

Cao

Aderibigbe

et al. 2023

IEEE Robot. Autom. Lett.

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Deaho Moon

Rapid prototyping design and control of tensegrity soft robot for locomotion

Robust learning of tensegrity robot control for locomotion through form-finding

Design of a spherical tensegrity robot for dynamic locomotion

ModMan: An Advanced Reconfigurable Manipulator System With Genderless Connector and Automatic Kinematic Modeling Algorithm

Walk-Burrow-Tug: Legged Anchoring Analysis Using RFT-Based Granular Limit Surfaces

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