Abstract
This paper aims to democratize the design and fabrication of robots, enabling people of all skill levels to make robots without needing expert domain knowledge. Existing work in computational design and rapid fabrication has explored this question of customization for physical objects but so far has not been able to conquer the complexity of robot designs. We have developed Interactive Robogami, a tool for composition-based design of ground robots that can be fabricated as flat sheets and then folded into 3D structures. This rapid prototyping process enables users to create lightweight, affordable, and materially versatile robots with short turnaround time. Using Interactive Robogami, designers can compose new robot designs from a database of print and fold parts. The designs are tested for the users’ functional specifications via simulation and fabricated upon user satisfaction. We present six robots designed and fabricated using a 3D printing based approach, as well as a larger robot cut from sheet metal. We have also conducted a user study that demonstrates our tool is intuitive for novice designers and expressive enough to create a wide variety of ground robot designs.
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Paper
paper
Acknowledgements
Support for this project has been provided in part by NSF Grant Nos. 1240383 and 1138967, by the DoD through the NDSEG Fellowship Program. We are also grateful to the following people for resources, discussions and suggestions: Ankur Mehta, Joseph DelPreto, Jacob Haip, and Isaque Dutra.
Citation
Adriana Schulz, Cynthia Sung, Andrew Spielberg, Wei Zhao, Robin Cheng, Eitan Grinspun, Daniela Rus and Wojciech Matusik
Interactive robogami: An end-to-end system for design of robots with ground locomotion.
The International Journal of Robotics Research 36, no. 10 (2017): 1131-1147.
@article{Schulz:2017,
author = author={Schulz, Adriana and Sung, Cynthia and Spielberg, Andrew and Zhao, Wei
and Cheng, Robin and Grinspun, Eitan and Rus, Daniela and Matusik, Wojciech},
title={Interactive robogami: An end-to-end system for design of robots with
ground locomotion},
journal={The International Journal of Robotics Research},
year = {2017},
volume = {36},
number = {10},
pages = {1131--1147},
publisher = {SAGE Publications Sage UK: London, England},
}
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