Abstract
Manipulating objects using arms mounted to unmanned aerial vehicles (UAVs) is attractive because UAVs may access many locations that are otherwise inaccessible to other mobile manipulation platforms such as ground vehicles. Despite recent work, several major challenges remain to be overcome before it will be practical to manipulate objects from UAVs. Among these challenges are: (a) The constantly moving UAV platform and compliance of manipulator arms make it difficult to position the UAV and end-effector relative to an object of interest precisely enough for manipulation, and (b) The motions of the manipulator impact the stability of the host UAV, further complicating positioning. Solving these challenges will bring UAVs one step closer to being able to perform meaningful tasks such as infrastructure repair, disaster response, casualty extraction, and cargo resupply. Toward solutions to these challenges, this paper describes a hyper-redundant manipulator, manipulator control approaches and system design considerations to position the manipulator relative to objects of interest in such a way that impacts on platform stability are minimized.
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Ambrose, R.O., Aldridge, H., Askew, R.S., Burridge, R.R., Bluethmann, W., Diftler, M., Lovchik, C., Magruder, D., Rehnmark, F.: Robonaut: Nasa’s space humanoid. IEEE Intell. Syst. App. 15(4), 57–63 (2000)
Bourquardez, O., Mahony, R., Guenard, N., Chaumette, F., Hamel, T., Eck, L.: Image-based visual servo control of the translation kinematics of a quadrotor aerial vehicle. IEEE Trans. Robot. 25(3), 743–749 (2009)
Chaumette, F., Rives, P., Espiau, B.: Positioning of a robot with respect to an object, tracking it and estimating its velocity by visual servoing. In: Proceedings on IEEE International Conference on Robotics and Automation, 1991, pp. 2248–2253. IEEE (1991)
Corke, P.I.: A robotics toolbox for matlab. IEEE Robot. Autom. Mag. 3(1), 24–32 (1996)
Danko, T.W., Oh, P.Y.: A hyper-redundant manipulator for mobile manipulating unmanned aerial vehicles. In: 2013 International Conference on Unmanned Aircraft Systems (ICUAS), pp. 974–981. IEEE (2013)
Garage, W.: Personal robot 2 (pr2). Online: http://www.willowgarage.com. Cited at p. 14 (2013)
Hein, B.R., Chopra, I.: Hover performance of a micro air vehicle: rotors at low reynolds number. J. Am. Helicopter Soc. 52(3), 254–262 (2007)
Hogan, N.: Impedance control: an approach to manipulation. In: American Control Conference, 1984, pp. 304–313. IEEE (1984)
Jimenez-Cano, A., Martin, J., Heredia, G., Ollero, A., Cano, R.: Control of an aerial robot with multi-link arm for assembly tasks. In: IEEE Int. Conf. Robotics and Automation (ICRA). Karlsruhe, Germany (2013)
Korpela, C.M., Danko, T.W., Oh, P.Y.: Mm-uav: mobile manipulating unmanned aerial vehicle. J. Intell. Robot. Syst. 65(1–4), 93–101 (2012)
Kuntz, N., Oh, P.Y.: Towards autonomous cargo deployment and retrieval by an unmanned aerial vehicle using visual servoing. In: Proceedings of 2008 ASME Dynamic Systems and Controls Conference (2008)
Lippiello, V., Ruggiero, F.: Cartesian impedance control of a uav with a robotic arm. In: 10th International IFAC Symposium on Robot Control (2012)
Marques, L., Dinis, J., Coimbra, A.P., Crisóstomo, M.M., Ferreira, J.P.: 3D hyper-redundant robot. In: 11th Spanish Portuguese Conference on Electrical Engineering, Zaragoza, Spain, July 2009
Mellinger, D., Lindsey, Q., Shomin, M., Kumar, V.: Design, modeling, estimation and control for aerial grasping and manipulation. In: 2011 IEEE/RSJ International Conference on Intelligent Robots and Systems (IROS), pp. 2668–2673. IEEE (2011)
Mellinger, D., Shomin, M., Michael, N., Kumar, V.: Cooperative grasping and transport using multiple quadrotors. In: Distributed Autonomous Robotic Systems, pp. 545–558. Springer (2013)
Orsag, M., Korpela, C., Oh, P.: Modeling and control of mm-uav: mobile manipulating unmanned aerial vehicle. J. Intell. Robot. Syst. 69(1–4), 227–240 (2013)
Pines, D.J., Bohorquez, F.: Challenges facing future micro-air-vehicle development. J. Aircr. 43(2), 290–305 (2006)
Pounds, P.E., Bersak, D.R., Dollar, A.M.: Grasping from the air: hovering capture and load stability. In: 2011 IEEE International Conference on Robotics and Automation (ICRA), pp. 2491–2498. IEEE (2011)
Pounds, P.E., Dollar, A.: Hovering stability of helicopters with elastic constraints. In: ASME 2010 Dynamic Systems and Control Conference (DSCC2010), vol. 2, pp. 781–788. American Society of Mechanical Engineers (2010)
Srinivasa, S.S., Ferguson, D., Helfrich, C.J., Berenson, D., Collet, A., Diankov, R., Gallagher, G., Hollinger, G., Kuffner, J., Weghe, M.V.: Herb: a home exploring robotic butler. Auton. Robot. 28(1), 5–20 (2010)
Tsai, L.W., Morgan, A.P.: Solving the Kinematics of the Most General Six-and Five-Degree-of-Freedom Manipulators by Continuation Methods. ASME (1985)
Yoshikawa, T.: Manipulability of robotic mechanisms. Int. J. Robot. Res. 4(2), 3–9 (1985)
Zhao, J., Cui, X., Zhu, Y., Tang, S.: Ubot: a new reconfigurable modular robotic system with multimode locomotion ability. Ind. Robot. 39(2), 178–190 (2012)
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This project was supported in part by a US NSF CRI II-New, Award # CNS-1205490.
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Danko, T.W., Oh, P.Y. Design and Control of a Hyper-Redundant Manipulator for Mobile Manipulating Unmanned Aerial Vehicles. J Intell Robot Syst 73, 709–723 (2014). https://doi.org/10.1007/s10846-013-9935-2
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DOI: https://doi.org/10.1007/s10846-013-9935-2