Multi-point Contact Models for Dynamic Self-Righting of a Hexapod Robot
Degree type
Discipline
Subject
Kodlab
Funder
Grant number
License
Copyright date
Distributor
Related resources
Author
Contributor
Abstract
In this paper, we report on the design of a model-based controller that can achieve dynamical self-righting of a hexapod robot. Extending on our earlier work in this domain, we introduce a tractable multi-point contact model with Coulomb friction. We contrast the singularities inherent to the new model with other available methods and show that for our specific application, it yields dynamics which are well-defined. We then present a feedback controller that achieves “maximal” performance under morphological and actuation constraints, while ensuring the validity of the model by staying away from singularities. Finally, through systematic experiments, we demonstrate that our controller is capable of robust flipping behavior. For more information: Kod*Lab
Advisor
Date of presentation
Conference name
Conference dates
Conference location
Date Range for Data Collection (Start Date)
Date Range for Data Collection (End Date)
Digital Object Identifier
Series name and number
Volume number
Issue number
Publisher
Publisher DOI
Comments
BibTeX entry @inproceedings{Saranli-Sixth International WAFR-2004, author = {Uluc Saranli and Alfred A. Rizzi et al}, title = {Multi-Point Contact Models for Dynamic Self-Righting of a Hexapod Robot}, booktitle = {Proceedings ofthe Sixth International WAFR}, year = {2004}, address = {Utrrecht/Zeist, The Netherlands}, month = {July}, } We thank Prof. Matt Mason for his insight on friction models and the connection to Painleve's problem. This work was supported in part by DARPA/ONR Grant N00014-98-1-0747.