Collective Actuation

International Journal of Robotics Research

Jason D. Campbell and Padmanabhan Pillai

27(3-4):299–314

2008

Abstract

Modular robot designers confront an inherent tradeoff between size and power: Smaller, more numerous modules increase the adaptability of a given volume or mass of robot—allowing the aggregate robot to take on a wider variety of configurations—but do so at a cost of reducing the power and complexity budget of each module. Fewer, larger modules can incorporate more powerful actuators and stronger hinges but at a cost of overspecializing the resulting robot in favor of corresponding uses. In the paper we describe a technique for coordinating the efforts of many tiny modules to achieve forces and movements larger than those possible for individual modules. In a broad sense, the question of actuator capacity and range thus may become one of software coding and ensemble topology as well as of hardware design. An important aspect of this technique is its ability to bend complex and large-scale structures and to realize the equivalent of large scale joints. Although our results do not suggest that modular robots will replace high power purpose-built robots, they do offer an increase in the plausible scalability of modular robot self-reconfiguration and facilitate a corresponding increase in adaptability.

@article{campbell-ijrr-srmr,
  author = {Campbell, Jason D. and Pillai, Padmanabhan},
  title = {Collective Actuation},
  journal = {International Journal of Robotics Research},
  volume = {27},
  number = {3-4},
  year = {2008},
  pages = {299-314},
  keywords = {Actuation, Controlling Ensembles},
  abstract = {Modular robot designers confront an inherent tradeoff
     between size and power: Smaller, more numerous modules increase
     the adaptability of a given volume or mass of robot---allowing
     the aggregate robot to take on a wider variety of
     configurations---but do so at a cost of reducing the power and
     complexity budget of each module. Fewer, larger modules can
     incorporate more powerful actuators and stronger hinges but at a
     cost of overspecializing the resulting robot in favor of
     corresponding uses. In the paper we describe a technique for
     coordinating the efforts of many tiny modules to achieve forces
     and movements larger than those possible for individual modules.
     In a broad sense, the question of actuator capacity and range
     thus may become one of software coding and ensemble topology as
     well as of hardware design. An important aspect of this technique
     is its ability to bend complex and large-scale structures and to
     realize the equivalent of large scale joints. Although our
     results do not suggest that modular robots will replace high
     power purpose-built robots, they do offer an increase in the
     plausible scalability of modular robot self-reconfiguration and
     facilitate a corresponding increase in adaptability.},
}

Related Papers

Controlling Ensembles
	Collective Actuation	bib
	Jason D. Campbell and Padmanabhan Pillai. International Journal of Robotics Research, 27(3-4):299–314,2008.
	@article{campbell-ijrr-srmr, author = {Campbell, Jason D. and Pillai, Padmanabhan}, title = {Collective Actuation}, journal = {International Journal of Robotics Research}, volume = {27}, number = {3-4}, year = {2008}, pages = {299-314}, keywords = {Actuation, Controlling Ensembles}, abstract = {Modular robot designers confront an inherent tradeoff between size and power: Smaller, more numerous modules increase the adaptability of a given volume or mass of robot---allowing the aggregate robot to take on a wider variety of configurations---but do so at a cost of reducing the power and complexity budget of each module. Fewer, larger modules can incorporate more powerful actuators and stronger hinges but at a cost of overspecializing the resulting robot in favor of corresponding uses. In the paper we describe a technique for coordinating the efforts of many tiny modules to achieve forces and movements larger than those possible for individual modules. In a broad sense, the question of actuator capacity and range thus may become one of software coding and ensemble topology as well as of hardware design. An important aspect of this technique is its ability to bend complex and large-scale structures and to realize the equivalent of large scale joints. Although our results do not suggest that modular robots will replace high power purpose-built robots, they do offer an increase in the plausible scalability of modular robot self-reconfiguration and facilitate a corresponding increase in adaptability.}, }
	Generalizing Metamodules to Simplify Planning in Modular Robotic Systems	pdf bib
	Daniel Dewey, Siddhartha S. Srinivasa, Michael P. Ashley-Rollman, Michael De Rosa, Padmanabhan Pillai, Todd C. Mowry, Jason D. Campbell, and Seth Copen Goldstein. In Proceedings of IEEE/RSJ 2008 International Conference on Intelligent Robots and Systems IROS '08, September, 2008.
	@inproceedings{dewey-iros08, author = {Dewey, Daniel and Srinivasa, Siddhartha S. and Ashley-Rollman, Michael P. and De~Rosa, Michael and Pillai, Padmanabhan and Mowry, Todd C. and Campbell, Jason D. and Goldstein, Seth Copen}, title = {Generalizing Metamodules to Simplify Planning in Modular Robotic Systems}, booktitle = {Proceedings of IEEE/RSJ 2008 International Conference on Intelligent Robots and Systems {IROS '08}}, year = {2008}, address = {Nice, France}, month = {September}, abstract = {In this paper we develop a theory of metamodules and an associated distributed asynchronous planner which generalizes previous work on metamodules for lattice-based modular robotic systems. All extant modular robotic systems have some form of non-holonomic motion constraints. This has prompted many researchers to look to metamodules, i.e., groups of modules that act as a unit, as a way to reduce motion constraints and the complexity of planning. However, previous metamodule designs have been specific to a particular modular robot. By analyzing the constraints found in modular robotic systems we develop a holonomic metamodule which has two important properties: (1) it can be used as the basic unit of an efficient planner and (2) it can be instantiated by a wide variety of different underlying modular robots, e.g., modular robot arms, expanding cubes, hex-packed spheres, etc. Using a series of transformations we show that our practical metamodule system has a provably complete planner. Finally, our approach allows the task of shape transformation to be separated into a planning task and a resource allocation task. We implement our planner for two different metamodule systems and show that the time to completion scales linearly with the diameter of the ensemble.}, url = {http://www.cs.cmu.edu/~claytronics/papers/dewey-iros08.pdf}, keywords = {Meld, Planning, Multi-Robot Formations, Controlling Ensembles, Robotics}, }
	Locomotion of Miniature Catom Chains: Scale Effects on Gait and Velocity	bib
	David Johan Christensen and Jason D. Campbell. In Proceedings of the IEEE International Conference on Robotics and Automation (ICRA '07), pages 2254–2260, April, 2007.
	@inproceedings{Christensen-icra07, author = {Christensen, David Johan and Campbell, Jason D.}, title = {Locomotion of Miniature Catom Chains: Scale Effects on Gait and Velocity}, booktitle = {Proceedings of the IEEE International Conference on Robotics and Automation ({ICRA '07})}, venue = {IEEE International Conference on Robotics and Automation (ICRA)}, month = {April}, pages = {2254-2260}, keywords = {Biologically Inspired, Actuation, Controlling Ensembles}, year = {2007}, }
	Collective Actuation	pdf bib
	Jason D. Campbell and Padmanabhan Pillai. In RSS 2006 Workshop on Self-Reconfigurable Modular Robots, August, 2006.
	@inproceedings{campbell-rss06, author = {Campbell, Jason D. and Pillai, Padmanabhan}, title = {Collective Actuation}, booktitle = {RSS 2006 Workshop on Self-Reconfigurable Modular Robots}, venue = {Robotics: Science and Systems Workshop on Self-Reconfigurable Modular Robots}, year = {2006}, month = {August}, keywords = {Actuation, Controlling Ensembles}, url = {http://www.cs.cmu.edu/~claytronics/papers/campbell-rss06.pdf}, abstract = {Modular robot designers confront an inherent tradeoff between size and power: Smaller, more numerous modules increase the adaptability of a given volume or mass of modules---allowing the aggregate robot to take on a wider variety of configurations – but do so at the expense of the power and complexity of each module. Fewer, larger modules can incorporate more powerful actuators, more powerful bonds, and stronger hinges but at a cost of overspecializing the resulting robot in favor of correspond-ing uses. We describe a technique for coordinating the efforts of many tiny modules to achieve forces and movements be-yond those possible for individual modules. Our approach is predominantly applicable to spherical and cylindrical modules and their faceted counterparts, but may apply to some chain-style modular robot systems. Thus actuator capacity and range becomes a function of software and dynamic topology as well as of hardware. An important aspect of this technique is its ability to bend complex and large-scale structures and to realize the equivalent of large scale joints.}, }
	Hierarchical Motion Planning for Self-reconfigurable Modular Robots	pdf bib
	Preethi Srinivas Bhat, James Kuffner, Seth Copen Goldstein, and Siddhartha S. Srinivasa. In 2006 IEEE/RSJ International Conference on Intelligent Robots and Systems (IROS), October, 2006.
	@inproceedings{bhat06, author = {Bhat, Preethi Srinivas and Kuffner, James and Goldstein, Seth Copen and Srinivasa, Siddhartha S.}, title = {Hierarchical Motion Planning for Self-reconfigurable Modular Robots}, booktitle = {2006 IEEE/RSJ International Conference on Intelligent Robots and Systems (IROS)}, venue = {IEEE/RSJ International Conference on Intelligent Robots and Systems (IROS)}, year = {2006}, month = {October}, keywords = {Planning, Controlling Ensembles, Hierarchical Algorithms}, url = {http://www.cs.cmu.edu/~claytronics/papers/bhat06.pdf}, abstract = {Motion planning for a self-reconfigurable robot involves coordinating the movement and connectivity of each of its homogeneous modules. Reconfiguration occurs when the shape of the robot changes from some initial configuration to a target configuration. Finding an optimal solution to reconfiguration problems involves searching the space of possible robot configurations. As this space grows exponentially with the number of modules, optimal planning becomes intractable. We propose a hierarchical planning approach that computes heuristic global reconfiguration strategies efficiently. Our approach consists of a base planner that computes an optimal solution for a few modules and a hierarchical planner that calls this base planner or reuses pre-computed plans at each level of the hierarchy to ultimately compute a global suboptimal solution. We present results from a prototype implementation of the method that efficiently plans for self-reconfigurable robots with several thousand modules.We also discuss tradeoffs and performance issues including scalability, heuristics and plan optimality.}, }
	Scalable Shape Sculpting via Hole Motion: Motion Planning in Lattice-Constrained Module Robots	pdf bib
	Michael De Rosa, Seth Copen Goldstein, Peter Lee, Jason D. Campbell, and Padmanabhan Pillai. In Proceedings of the 2006 IEEE International Conference on Robotics and Automation (ICRA '06), May, 2006.
	@inproceedings{derosa-icra06, author = {De~Rosa, Michael and Goldstein, Seth Copen and Lee, Peter and Campbell, Jason D. and Pillai, Padmanabhan}, title = {Scalable Shape Sculpting via Hole Motion: Motion Planning in Lattice-Constrained Module Robots}, month = {May}, booktitle = {Proceedings of the 2006 {IEEE} International Conference on Robotics and Automation (ICRA '06)}, venue = {IEEE International Conference on Robotics and Automation (ICRA)}, year = {2006}, keywords = {Planning, Controlling Ensembles, Stochastic Algorithms}, url = {http://www.cs.cmu.edu/~claytronics/papers/derosa-icra06.pdf}, abstract = {We describe a novel shape formation algorithm for ensembles of 2-dimensional lattice-arrayed modular robots, based on the manipulation of regularly shaped voids within the lattice (``holes''). The algorithm is massively parallel and fully distributed. Constructing a goal shape requires time proportional only to the complexity of the desired target geometry. Construction of the shape by the modules requires no global communication nor broadcast floods after distribution of the target shape. Results in simulation show 97.3\% shape compliance in ensembles of approximately 60,000 modules, and we believe that the algorithm will generalize to 3D and scale to handle millions of modules.}, }
Actuation
	Analysis and Modeling of Capacitive Power Transfer in Microsystems	bib
	Mustafa Emre Karagozler, Seth Copen Goldstein, and David S. Ricketts. Circuits and Systems I: Regular Papers, IEEE Transactions on, 59(7):1557 –1566,July, 2012.
	@article{karagozler-TCCS12, author = {Karagozler, Mustafa Emre and Goldstein, Seth Copen and Ricketts, David S.}, journal = {Circuits and Systems I: Regular Papers, IEEE Transactions on}, title = {Analysis and Modeling of Capacitive Power Transfer in Microsystems}, year = {2012}, month = {July}, volume = {59}, number = {7}, pages = {1557 -1566}, keywords = {Actuation, Adhesion,Power}, doi = {10.1109/TCSI.2011.2177011}, issn = {1549-8328}, }
	Electrostatic actuation and control of micro robots using a post-processed high-voltage SOI CMOS chip	bib
	Mustafa Emre Karagozler, A. Thaker, Seth Copen Goldstein, and David S. Ricketts. In Circuits and Systems (ISCAS), 2011 IEEE International Symposium on, ():2509 –2512,May, 2011.
	@inproceedings{karagozler-iscas11, author = {Karagozler, Mustafa Emre and Thaker, A. and Goldstein, Seth Copen and Ricketts, David S.}, booktitle = {Circuits and Systems (ISCAS), 2011 IEEE International Symposium on}, title = {Electrostatic actuation and control of micro robots using a post-processed high-voltage SOI CMOS chip}, year = {2011}, month = {May}, volume = {}, number = {}, pages = {2509 -2512}, keywords = {Robot Fabrication, Actuation}, doi = {10.1109/ISCAS.2011.5938114}, issn = {0271-4302}, }
	Stress-driven mems assembly+ electrostatic forces= 1mm diameter robot	pdf bib
	Mustafa Emre Karagozler, Seth Copen Goldstein, and J Robert Reid. In Intelligent Robots and Systems, 2009. IROS 2009. IEEE/RSJ International Conference on, pages 2763–2769, 2009.
	@inproceedings{karagozler-iros2009, title = {Stress-driven mems assembly+ electrostatic forces= 1mm diameter robot}, author = {Karagozler, Mustafa Emre and Goldstein, Seth Copen and Reid, J Robert}, booktitle = {Intelligent Robots and Systems, 2009. IROS 2009. IEEE/RSJ International Conference on}, pages = {2763--2769}, year = {2009}, keywords = {Robot Fabrication, Actuation}, url = {http://www.cs.cmu.edu/~claytronics/papers/karagozler-iros09.pdf}, }
	Collective Actuation	bib
	Jason D. Campbell and Padmanabhan Pillai. International Journal of Robotics Research, 27(3-4):299–314,2008.
	@article{campbell-ijrr-srmr, author = {Campbell, Jason D. and Pillai, Padmanabhan}, title = {Collective Actuation}, journal = {International Journal of Robotics Research}, volume = {27}, number = {3-4}, year = {2008}, pages = {299-314}, keywords = {Actuation, Controlling Ensembles}, abstract = {Modular robot designers confront an inherent tradeoff between size and power: Smaller, more numerous modules increase the adaptability of a given volume or mass of robot---allowing the aggregate robot to take on a wider variety of configurations---but do so at a cost of reducing the power and complexity budget of each module. Fewer, larger modules can incorporate more powerful actuators and stronger hinges but at a cost of overspecializing the resulting robot in favor of corresponding uses. In the paper we describe a technique for coordinating the efforts of many tiny modules to achieve forces and movements larger than those possible for individual modules. In a broad sense, the question of actuator capacity and range thus may become one of software coding and ensemble topology as well as of hardware design. An important aspect of this technique is its ability to bend complex and large-scale structures and to realize the equivalent of large scale joints. Although our results do not suggest that modular robots will replace high power purpose-built robots, they do offer an increase in the plausible scalability of modular robot self-reconfiguration and facilitate a corresponding increase in adaptability.}, }
	A Modular Robotic System Using Magnetic Force Effectors	pdf bib
	Brian Kirby, Burak Aksak, Seth Copen Goldstein, James F. Hoburg, Todd C. Mowry, and Padmanabhan Pillai. In Proceedings of the IEEE International Conference on Intelligent Robots and Systems (IROS '07), October, 2007.
	@inproceedings{bkirby-iros07, author = {Kirby, Brian and Aksak, Burak and Goldstein, Seth Copen and Hoburg, James F. and Mowry, Todd C. and Pillai, Padmanabhan}, title = {A Modular Robotic System Using Magnetic Force Effectors}, booktitle = {Proceedings of the IEEE International Conference on Intelligent Robots and Systems ({IROS '07})}, venue = {IEEE/RSJ International Conference on Intelligent Robots and Systems (IROS)}, year = {2007}, month = {October}, abstract = {One of the primary impediments to building ensembles with many modular robots is the complexity and number of mechanical mechanisms used to construct the individual modules. As part of the Claytronics project---which aims to build very large ensembles of modular robots---we investigate how to simplify each module by eliminating moving parts and reducing the number of mechanical mechanisms on each robot by using force-at-a-distance actuators. Additionally, we are also investigating the feasibility of using these unary actuators to improve docking performance, implement intermodule adhesion, power transfer, communication, and sensing.}, keywords = {Actuation, Adhesion}, url = {http://www.cs.cmu.edu/~claytronics/papers/bkirby-iros07.pdf}, }
	Electrostatic Latching for Inter-module Adhesion, Power Transfer, and Communication in Modular Robots	pdf bib
	Mustafa Emre Karagozler, Jason D. Campbell, Gary K. Fedder, Seth Copen Goldstein, Michael Philetus Weller, and Byung W. Yoon. In Proceedings of the IEEE International Conference on Intelligent Robots and Systems (IROS '07), October, 2007. See karagozler-msreport07.
	@inproceedings{karagozler-iros07, author = {Karagozler, Mustafa Emre and Campbell, Jason D. and Fedder, Gary K. and Goldstein, Seth Copen and Weller, Michael Philetus and Yoon, Byung W.}, title = {Electrostatic Latching for Inter-module Adhesion, Power Transfer, and Communication in Modular Robots}, booktitle = {Proceedings of the IEEE International Conference on Intelligent Robots and Systems ({IROS '07})}, venue = {IEEE/RSJ International Conference on Intelligent Robots and Systems (IROS)}, see = {karagozler-msreport07}, year = {2007}, month = {October}, abstract = {A simple and robust inter-module latch is possibly the most important component of a modular robotic system. This paper describes a latch based on capacitive coupling which not only provides significant adhesion forces, but can also be used for inter-module power transmission and communication. The key insight that enables electrostatic adhesion to be effective at the macroscale is to combine flexible electrodes with a geometery that uses shear forces to provide adhesion. To measure the effectiveness of our latch we incorporated it into a 28cm x 28cm x 28cm modular robot. The result is a latch which requires almost zero static power and yet can hold over 0.6N/cm^2 of latch area.}, keywords = {Actuation, Adhesion}, url = {http://www.cs.cmu.edu/~claytronics/papers/karagozler-iros07.pdf}, }
	Harnessing Capacitance for Inter-Robot Latching, Communication, and Power Transfer	pdf bib
	Mustafa Emre Karagozler. Master's Thesis, Carnegie Mellon University, May, 2007. Also appeared as Electrostatic Latching for Inter-module Adhesion, Power Transfer, and Communication in Modular Robots in IROS '07.
	@mastersthesis{karagozler-msreport07, author = {Karagozler, Mustafa Emre}, title = {Harnessing Capacitance for Inter-Robot Latching, Communication, and Power Transfer}, venue = {Masters Thesis}, also = {Electrostatic Latching for Inter-module Adhesion, Power Transfer, and Communication in Modular Robots in IROS '07}, month = {May}, year = {2007}, school = {Carnegie Mellon University}, abstract = {A simple and robust inter-module latch is possibly the most important component of a modular robotic system. This report describes a latch based on capacitive coupling which not only provides significant adhesion forces, but can also be used for inter-module power transmission and communication. The key insight that enables electrostatic adhesion to be effective at the macro scale is to combine flexible electrodes with a geometry that uses shear forces to provide adhesion. To measure the effectiveness of our latch we incorporated it into a 28cm x 28cm x 28cm modular robot. The result is a latch which requires almost zero static power and yet can hold over 0.6N/cm2 of latch area.}, keywords = {Actuation, Adhesion, Power}, url = {http://www.cs.cmu.edu/~claytronics/papers/karagozler-msreport07.pdf}, }
	Locomotion of Miniature Catom Chains: Scale Effects on Gait and Velocity	bib
	David Johan Christensen and Jason D. Campbell. In Proceedings of the IEEE International Conference on Robotics and Automation (ICRA '07), pages 2254–2260, April, 2007.
	@inproceedings{Christensen-icra07, author = {Christensen, David Johan and Campbell, Jason D.}, title = {Locomotion of Miniature Catom Chains: Scale Effects on Gait and Velocity}, booktitle = {Proceedings of the IEEE International Conference on Robotics and Automation ({ICRA '07})}, venue = {IEEE International Conference on Robotics and Automation (ICRA)}, month = {April}, pages = {2254-2260}, keywords = {Biologically Inspired, Actuation, Controlling Ensembles}, year = {2007}, }
	Collective Actuation	pdf bib
	Jason D. Campbell and Padmanabhan Pillai. In RSS 2006 Workshop on Self-Reconfigurable Modular Robots, August, 2006.
	@inproceedings{campbell-rss06, author = {Campbell, Jason D. and Pillai, Padmanabhan}, title = {Collective Actuation}, booktitle = {RSS 2006 Workshop on Self-Reconfigurable Modular Robots}, venue = {Robotics: Science and Systems Workshop on Self-Reconfigurable Modular Robots}, year = {2006}, month = {August}, keywords = {Actuation, Controlling Ensembles}, url = {http://www.cs.cmu.edu/~claytronics/papers/campbell-rss06.pdf}, abstract = {Modular robot designers confront an inherent tradeoff between size and power: Smaller, more numerous modules increase the adaptability of a given volume or mass of modules---allowing the aggregate robot to take on a wider variety of configurations – but do so at the expense of the power and complexity of each module. Fewer, larger modules can incorporate more powerful actuators, more powerful bonds, and stronger hinges but at a cost of overspecializing the resulting robot in favor of correspond-ing uses. We describe a technique for coordinating the efforts of many tiny modules to achieve forces and movements be-yond those possible for individual modules. Our approach is predominantly applicable to spherical and cylindrical modules and their faceted counterparts, but may apply to some chain-style modular robot systems. Thus actuator capacity and range becomes a function of software and dynamic topology as well as of hardware. An important aspect of this technique is its ability to bend complex and large-scale structures and to realize the equivalent of large scale joints.}, }

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