Definition of the Subject
In this article, we discuss some of the key issues involved in the design and implementation of the emerging class of“invertebrate‐like” continuum robots . Using two case studies of continuumrobots developed recently at Clemson University, we overview the issues involved in realizing continuum robots and their deployment. The potential ofthese types of robots for enhanced productivity in novel applications is discussed.
In the first case study, we describe the design of the “OctArm” continuum manipulator robot hardware, and discuss the results of field testing of these novel “trunk‐like” robots. OctArmrobots are able to adapt their shape to their environment, to access difficult-to-reach areas, and to perform adaptive grasping using their entirearms. Lessons learned and implications for future robot manipulators in the field are discussed.
In the second case study, we describe the new “Animated Work Environment ” (AWE) concept. AWE is an...
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Abbreviations
- Degree of freedom:
-
(Sub)set of a physically reconfigurable system whose configuration can always be specified by a single variable.
- Kinematics:
-
Geometric (and differential geometric) models of mechanical systems, not including effects of dynamics (masses, forces, inertias, etc.).
- Robot:
-
A physically reconfigurable system that has multiple degrees of freedom and is (at least partially) computer‐controlled.
- Actuators:
-
Devices used to transfer mass (herein portions of a robot system) from one place to another within the system's environment.
- Sensors:
-
Devices used to infer information, usually either about the internal state of a system, or about external environment surrounding that system.
- Control:
-
Use of sensors and actuators to reconfigure a system (herein robots) according to a desired plan.
- Continuum:
-
Continuous in nature; herein usually the backbone/core of a robot.
- OctArm:
-
Continuum robot manipulator inspired by octopus arms.
- AWE:
-
(“Animated Work Environment”) Reconfigurable environment featuring continuum robot components, focused on work environments featuring computing.
Bibliography
Aarts E, Marzano S (2003) The New Everyday: Views on Ambient Intelligence. 010 Publishers, Rotterdam
Anderson VC, Horn RC (1967) Tensor arm manipulator design. Trans ASME, vol. 67-DE-57. American Society of Mechanical Engineers, New York, pp 1–12
Aoki T, Ochiai A, Hirose S (2004) Study on slime robot: development of the mobile robot prototype model using bridle bellows. In: Proc. IEEE International Conference on Robotics and Automation, New Orleans, Louisiana, pp 2808–2813
Bailly Y, Amirat Y (2005) Modeling and Control of a Hybrid Continuum Active Catheter for Aortic Aneurysm Treatment. In: Proceedings of the IEEE International Conference on Robotics and Automation, Barcelona, Spain, pp 936–941
Beyer H, Holtzblatt K (1999) Contextual Design: Defining Customer-Centered Systems. Morgan Kaufman Publishers, San Francisco
Binder T, De Michelis G, Gervautz M, Jacucci G, Matkovic K, Psik T, Wagner I (2004) Supporting configurability in a mixed-media environment for design students. In: Thomas P (ed) Personal Ubiquitous Computing, vol. 8, Issue 5. Springer, London, pp 310–325
Bondarenko O, Janssen R (2005) Documents at Hand: Learning from Paper to Improve Digital Technologies. In: Proceedings of the Computer-Human-Interaction (CHI) 2005 Conference, Association for Computing Machinery. ACM, New York
Braganza D, Nath N, Walker ID, Dawson D (2006) Neural Network Grasping Controller for Continuum Robots. Proc. IEEE Conference on Decision and Control, San Diego, CA, pp 6445–6449
Braganza D, McIntyre M, Walker ID, Dawson D (2006) Whole Arm Grasping Control for Redundant Robot Manipulators. In: Proc. American Control Conference, Minneapolis, MN, pp 3194–3199
Buckingham R (2002) Snake arm robots, Industrial Robot. Int J 29(3):242–245
Burry M (2004) Convergent Design. In: Redmond J, Durling D, de Bono A (eds) Futureground Design Research Society International Conference vol 2 Proc. Monash University Press, Victoria
Chen G, Tu PM, Herve TR, Prelle C (2005) Design and modeling of a micro‐robotic manipulator for colonoscopy. In: Proc. 5th Int Workshop on Research and Education in Mechatronics, Annecy, France, pp 109–114
Chrikjian GS (1992) Theory and Applications of Hyperredundant Robotic Mechanisms. Ph D Thesis, Department of Applied Mechanics, California Institute of Technology. Pasadena
Chirikjian GS, Burdick JW (1991) Selected Applications and Intrinsic Kinematics of Hyper-Redundant Robots. In: Proc. 4th American Nuclear Society Topical Meeting on Robotics and Remote Systems, pp 61–70
Chirikjian GS, Burdick JW (1993) Design and Experiments with a 30 DOF Robot. In: Proc. IEEE International Conference on Robotics and Automation, Atlanta, pp 113–119
Chirikjian GS (1995) Hyper‐redundant manipulator dynamics: a continuum approximation. Adv Robot 9(3):217–243
Chirikjian GS, Burdick JW (1994) A modal approach to hyper‐redundant manipulator kinematics. IEEE Trans Robot Autom 10(3):343–354
Chitrakaran V, Behal A, Dawson D, Walker ID (2007) Setpoint Regulation of Continuum Robots Using a Fixed Camera. Robotica 25(5):581–586
Cieslak R, Morecki A (1999) Elephant trunk type elastic manipulator – a tool for bulk and liquid type materials transportation. Robotica 17:11–16
Csencsits M, Jones BA, McMahan W, Walker ID (2005) User interfaces for continuum robot arms. In: Proc. IEEE/RSJ Int Conf on Intelligent Robots and Systems, Edmonton, Canada, pp 3011–3018
deCOI (2004) Aegis Hypersurface. In: Mark Galthorpe/dECOi, “Precise Indeterminacy”, Praxis: J Writ Build, Issue 6:28–45
Ganz A (2006) Principal Investigator, NeTS: Animated Spaces for the Digital Society: The ASPEN Architecture, NSF Award Abstract – #0434985
Garlan D, Siewiorek D, Smailagic A, Steenkiste P (2002) Project Aura: Toward Distraction-Free Pervasive Computing. In: Satyanarayanan M (ed) IEEE Pervasive Computing. IEEE, New York, pp 22–30
Gravagne IA, Walker ID (2000) Kinematic Transformations for Remotely Actuated Planar Continuum Robots. In: Proc. IEEE International Conference on Robotics and Automation, San Francisco, CA. IEEE, New York, pp 19–26
Gravagne IA, Walker ID (2002) Manipulability, Force and Compliance Analysis for Planar Continuum Manipulators. IEEE Trans Robot Autom 18(3):263–273
Gravagne IA, Rahn CD, Walker ID (2003) Large deflection dynamics and control for planar continuum robots. IEEE/ASME Trans Mechatron 8(2):299–307
Green KE, Gugerty LJ, Walker ID, Witte JC (2005) AWE (Animated Work Environment): Ambient Intelligence in Working Life. In: Proc. Conference on Intelligent Ambience and Well–Being (Ambience 05), Tampere, Finland, September 2005, pp 1–7 (CD-ROM proceedings)
Green KE, Walker ID, Gugerty LJ, Witte JC (2006) Three Robot–Rooms/The AWE Project. In: Proc. CHI 2006, Montreal, Canada, April 2006, pp 809–814
Greypilgrim Company http://www.greypilgrim.com. Accessed 2 Aug 1999
Hannan MW, Walker ID (2001) Analysis and Experiments with an Elephant’s Trunk Robot. Adv Robot 15(8):847–858
Hannan MW, Walker ID (2003) Kinematics and the Implementation of an elephant’s trunk manipulator and other continuum style robots. J Robot Syst 20(2):45–63
Hannan MW, Walker ID (2005) Real-Time Shape Estimation for Continuum Robots Using Vision. Robotica 23(5):645–651
Hirose S (1993) Biologically inspired robots. Oxford University Press, New York
IBM Blue Space Research (2005) http://www.research.ibm.com/bluespace
Ikuta K, Ichikawa H, Suzuki K, Yajima D, Multi‐degree of Freedom Hydraulic Pressure Driven Safety Active Catheter. In: Proc. IEEE International Conference on Robotics and Automation, pp 4161–4166
Immega G (1992) Tentacle‐like manipulators with adjustable tension lines. US Patent #5,317,952
Immega G, Antonelli K (1995) The KSI tentacle manipulator. In: Proc. IEEE Intl. Conf. Robotics and Automation, Nagoya, Japan, pp 3149–3154
Ivanescu M, Stoian V (1995) A variable structure controller for a tentacle manipulator. In: Proc. IEEE Intl. Conf. Robotics and Automation, Nagoya, Japan, pp 3155–3160
Ivanescu M, Bizdoaca N, Pana D (2003) Dynamic control for a tentacle manipulator with SMA actuators. In: Proc. IEEE Intl. Conf. Robotics and Automation, Taipei, Taiwan, pp 2079–2084
Ivanescu M, Popescu N, Popescu D (2005) A Variable Length Tentacle Manipulator Control System. In: Proc. IEEE International Conference on Robotics and Automation, Barcelona, Spain, pp 3274–3279
Jones BA, McMahan W, Walker ID (2004) Design and analysis of a novel pneumatic manipulator. In: Proc. 3rd IFAC Symposium on Mechatronic Systems, Sydney, Australia, pp 745–750
Jones BA, Csencsits M, McMahan W, Chitrakaran V, Grissom M, Pritts M, Rahn CD, Walker ID (2006) Grasping, manipulation, and exploration tasks with the OctArm continuum manipulator, video in Proceedings of the International Conference on Robotics and Automation, Orlando, FL
Jones BA, Walker ID (2006a) Three-Dimensional Modeling and Display of Continuum Robots. In: Proc. IEEE/RSJ International Conference on Intelligent Robots and Systems (IROS), Beijing, China, pp 5872–5877
Jones BA, Walker ID (2006b) Kinematics for Multi-Section Continuum Robots. IEEE Trans Robot 22(1):43–55
Jones BA, Walker ID (2006c) Practical Kinematics for Real-Time Implementation of Continuum Robots. IEEE Trans Robot 22(6):1087–1099
Kier WM, Smith KK (1985) Tongues, tentacles and trunks: The biomechanics of movement in muscular‐hydrostats. Zool. J Linn Soc 83:307–324
Lane DM, Davies JBC, Robinson G, O’Brien DJ, Sneddon J, Seaton E, Elfstrom E (1999) The AMADEUS dextrous subsea hand: design, modeling, and sensor processing. IEEE J Ocean Eng 24(1):96–111
Larson K (2004) House_n Current Projects http://architecture.mit.edu/%7Ekll/Project%20List%20Sept-2004.pdf. Accessed 2 Jun 2008
McCarter R (ed) (1987) Building; Machines. Pamphlet Architecture/Princeton Architectural Press, New York
McMahan W, Jones BA, Walker ID, Chitrakaran V, Seshadri A, Dawson D (2004) Robotic manipulators inspired by cephalopod limbs. In: Proc. of the CDEN Design Conf., Montreal, Canada, pp 1–10
McMahan W, Jones BA, Walker ID (2005) Design and implementation of a multi‐section continuum robot: Air-Octor. In: Proc. IEEE/RSJ Intl. Conf. on Intelligent Robots and Systems, Edmonton, Canada, pp 3345–3352
McMahan W, Jones BA, Chitrakaran V, Csencsits M, Grissom M, Pritts M, Rahn CD, Walker ID (2006), Field trials and testing of the OctArm continuum manipulator. In: Proceedings of the International Conference on Robotics and Automation, Orlando, FL, USA, pp 2336–2341
Mehling JS, Diftler MA, Chu M, Valvo M (2006) A Minimally Invasive Tendril Robot for In-Space Inspection. In: Proc. BioRob 2006 Conference, pp 690–695
MIT Media Lab/FPC (2002), Media House Project: BCN, 26.09–06.10, Barcelona: FPC
Mitchell WJ (2000) City of Bits. MIT, Cambridge
Mitchell WJ (2000) e-topia. MIT, Cambridge
Mitchell WJ (2003) ME++. MIT, Cambridge
Mochiyama H, Shimemura E, Kobayashi H (1998) Shape Correspondence between a Spatial Curve and a Manipulator with Hyper Degrees of Freedom. Proc. IEEE International Conference on Robotics and Automation, pp 161–166
Mochiyama H, Suzuki T (2003) Kinematics and dynamics of a cable-like hyper‐flexible manipulator. ICRA, Taipei, Taiwan, pp 3672–3677
Niranjan RK, Ganz A (2004) Animated Space Architecture for Multimedia Experience – ASkME. In: Proceedings, Broadnets 2004, San Jose, pp 1–6
O. C. Robotics http://www.ocrobotics.com/mediagallery/images.htm. Accessed 30 May 2008
Ohno H, Hirose S (2001) Design of slim slime robot and its gait of locomotion. In: Proc. IEEE/RSJ Int Conf on Intelligent Robots and Systems, Maui, Hawaii, pp 707–715
Oosterhuis K (2003) Hyperbodies: Towards an E‑motive architecture. Birkäuser, Basel
Pritts MB, Rahn CD (2004) Design of an artificial muscle continuum robot. In: Proc. IEEE Intl. Conf. Robotics and Automation, New Orleans, Louisiana, pp 4742–4746
‘Q’ Mobile workstation concept for Steelcase (2005) http://www.ideo.com/portfolio/re.asp?x=12378. Accessed 2 Jun 2008
Robinson G, Davies JBC (1999) Continuum robots – a state of the art. In: Proc. IEEE Intl. Conf. Robotics and Automation, Detroit, Michigan, pp 2849–2854
Salisbury K, Townsend W, Ebrman B, DiPietro D (1988) Preliminary design of a whole-arm manipulation system (WAMS). In: Proc. IEEE Intl. Conf. Robotics and Automation, Philadelphia, Pennsylvania, pp 254–260
Sears P, Dupont P (2006) A Steerable Needle Technology Using Curved Concentric Tubes. In: Proc. IEEE/RSJ International Conference on Intelligent Robots and Systems, Beijing, China, pp 2850–2856
Simaan N (2005) Snake-Like Units Using Flexible Backbones and Actuation Redundancy for Enhanced Miniaturization. In: Proc. IEEE International Conference on Robotics and Automation, Barcelona, Spain, pp 3023–3028
Smith KK, Kier WM (1989) Trunks, tongues, and tentacles: Moving with skeletons of muscle. Am Sci 77:28–35
Spong MW, Hutchinson S, Vidyasagar M (2006) Robot modeling and control. John Wiley & Sons, New York
Suzumori K, Iikura S, Tanaka H (1991) Development of flexible microactuator and its applications to robotic mechanisms. In: Proc. IEEE Intl. Conf. Robotics and Automation, Sacramento, California, pp 1622–1627
Suzumori K, Iikura S, Tanaka H (1992), Applying a flexible microactuator to robotic mechanisms. Control Syst Mag IEEE 12:21–27
Tatlicioglu E, Walker ID, Dawson D (2007) Dynamic Modelling for Planar Extensible Continuum Robot Manipulators. In: Proc. IEEE International Conference on Robotics and Automation, Rome, Italy, pp 1357–1362
Thomann F, Betemps M, Redarce T (2003) The development of a bendable colonoscopic tip. In: International Conference on Robotics and Automation, Taipei, Taiwan, pp 658–663
Tsukagoshi H, Kitagawa A, Segawa M (2001) Active Hose: an artificial elephant’s nose with maneuverability for rescue operation. In: Proc. IEEE Intl. Conf. Robotics and Automation, Seoul, Korea, pp 2454–2459
Vitruvius (1985) De Architectura [On Architecture]. trans. F. Granger. Harvard University Press, Cambridge
Walker ID (2000) Issues in Creating ‘Invertebrate’ Robots. In: Proc. Conference on Adaptive Manipulation with Animals and Machines, Montreal, Canada, pp 1–6
Walker ID, Dawson D, Flash T, Grasso F, Hanlon R, Hochner B, Kier WM, Pagano C, Rahn CD, Zhang Q (2005) Continuum Robot Arms Inspired by Cephalopods. In: Proc. SPIE Conference on Unmanned Ground Vehicle Technology VII, Orlando, FL, pp 303–314
Walker ID, Carreras C, McDonnell R, Grimes G (2006) Extension Versus Bending for Continuum Robots. Int J Adv Robot Syst 3(2):171–178
Wilson JF, Li D, Chen Z, George RT (1993) Flexible Robot Manipulators and Grippers: Relatives of elephant Trunks and Squid Tentacles. In: Dario P (ed) Robots and Biological Systems: Towards a New Bionics? Nato Asi Series. Springer, New York, pp 474–494
Xu K, Simaan N (2006) Actuation Compensation for Flexible Surgical Snake-like Robots with Redundant Remote Actuation. In: Proc. IEEE International Conference on Robotics and Automation, pp 4148–4154
Yamada H, Hirose S (2006) Study on the 3D Shape of Active Cord Mechanism. In: Proc. IEEE International Conference on Robotics and Automation, pp 2890–2895
Yang J, Potratz J, Abdel-Malek K (2006) A Hyper‐Redundant Continuous Robot. In: Proc. IEEE International Conference on Robotics and Automation. pp 1854–1859
Yang J, Pena Pitarch E, Potratz J, Beck S, Abdel-Malek K (2006) Synthesis and analysis of a flexible elephant trunk robot. Adv Robot 20(6): 631–659
Siciliano B, Khatib O (2008) Springer Handbook of Robotics. Chapter 11, Kinematically Redundant Manipulators. in press
Acknowledgments
The authors acknowledge support from the US National Science Foundation under grant number IIS‐0534423, and from the Defense Advanced ResearchProjects Agency (DARPA) Defense Sciences Office through the Space and Naval Warfare Systems Center, San Diego, Contract Number N66001-03-C-8043.
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Walker, I.D., Green, K.E. (2009). Continuum Robots. In: Meyers, R. (eds) Encyclopedia of Complexity and Systems Science. Springer, New York, NY. https://doi.org/10.1007/978-0-387-30440-3_96
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