https://murray.cds.caltech.edu/index.php?action=history&feed=atom&title=Robotic_Manipulation_with_Flexible_Link_Fingers 2026-04-14T21:39:14Z Revision history for this page on the wiki MediaWiki 1.41.5 https://murray.cds.caltech.edu/index.php?title=Robotic_Manipulation_with_Flexible_Link_Fingers&diff=20010&oldid=prev 2016-05-15T06:20:04Z

<p>htdb2wiki: creating page for 1997_ss97-phd.html</p> <p><b>New page</b></p><div>{{HTDB paper<br /> | authors = Sudipto Sur<br /> | title = Robotic Manipulation with Flexible Link Fingers<br /> | source = PhD Dissertation, Caltech, January 1997<br /> | year = <br /> | type = PhD Dissertation<br /> | funding = NSF<br /> | url = http://www.cds.caltech.edu/~murray/preprints/ss97-phd.pdf<br /> | abstract = <br /> Robots with structural flexibility provide an attractive alternative<br /> to rigid robots for many of the new and evolving applications in<br /> robotics. In certain applications their use is unavoidable. The<br /> increased complexity in modeling and control of such robots is offset<br /> by desirable performance enhancements in some respects. In this thesis<br /> we present a singular perturbation approach for modeling, analysis and<br /> control of robots with flexibility. As our singular perturbation<br /> approach does not treat the flexible manipulator as a perturbation of<br /> the rigid manipulator, it can treat significant flexibility, beyond<br /> the linear range. Analysis based on this approach leads to some<br /> provably stable control laws for the hybrid position and force control<br /> of flexible-link manipulators. The analysis is done in the framework<br /> of a single robot manipulator in a constrained motion<br /> task. Simulations and experimental results are presented for this<br /> case. To show applicability of the results to more general and<br /> complex systems with flexibilities we also present experimental data<br /> from a planar, two-fingered, reconfigurable grasping setup which allows<br /> rigid and flexible configurations. The aim of the experimentation is<br /> to show the applicability of the control laws and analysis developed,<br /> and to determine the performance enhancements resulting from the<br /> introduction of flexibility. Experimental data is analysed to show the<br /> tradeoffs between controller complexity and performance enhancement as<br /> we deal with greater flexibility. Various performance criteria are set<br /> up and experimental results are discussed within their framework. We<br /> conclude that large flexibility can be controlled without too much<br /> additional effort, has performance comparable to that of rigid robots,<br /> and possesses enhancing properties which make it appealing for use in<br /> certain types of applications.<br /> <br /> | flags = NoRequest<br /> | tag = ss97-phd<br /> | id = 1997<br /> }}</div>

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