Abstract
Design specifications for a high-endurance and range unmanned ground vehicle (UGV) with a gimballed landing platform on top of it for takeoff/landing, transporting to the target area and recharging of small/miniature unmanned helicopters are presented and justified. Specification constraints include UGV strict payload limitations, limited free space affecting power supply availability that impacts on-board available energy, limited endurance and operational range, as well as limitations and restrictions related to electric and non-electric small unmanned vertical takeoff and landing (VTOL) vehicles, similar to those of UGV with the most important being limited flying time. Focusing on the All Terrain Robot Vehicle (ATRV-Jr) UGV and a helicopter of the size of the Maxi Joker 2 as a testbed, a detailed analysis of component power consumption reveals reasons for reduced runtime and operational range. After a comparative study of state of the art power supply and battery technologies, a hybrid battery configuration is proposed that improves more than 500% the manufacturer-specified ATRV-Jr endurance (or 1,000% the currently used custom-made ATRV-Jr endurance) by considering: (1) optimum design with weight, volume, runtime and rechargeability being major restrictions and concerns, and (2) use of lower power sensors and processors without affecting UGV functionality and operability. A sun-tracking solar array that collects and stores energy is integrated with the UGV gimballed landing platform. Simulations demonstrate the validity of the design. Although the testbed is specific, the design itself is generic enough and suitable for other UGV/VTOL vehicles.
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Baker, M.: Euclidean space. http://www.euclideanspace.com/ (2005)
Buchmann, I.: Understanding your batteries in a portable world. Article on battery choice and maximize service life. In: Proc. of the Fourteenth Annual Battery Conference on Applications and Advances, pp. 369–373 (1999)
Buchmann, I.: Batteries in Portable World, 2nd edn. Cadex Electronics Inc, Canada (2001)
Bullard, G.L., Sierra-Alcazar, H.B., Lee, H.L., Morris, J.L.: Operating principles of the ultracapacitor. IEEE Trans. Magnetics. 25(1), 102–106 (1989)
Chan, C.C.: The state of the art of electric vehicles. J. Asian Elect. Veh. 2(2), 579–600 (2004)
Conway, B.E.: Electrochemical supercapacitors: Scientific Fundamentals and Technological Applications, 1st edn. Springer, New York (1999)
Dougal, R.A., White, R.E.: Power and life extension of battery-ultracapacitor hybrids. IEEE Trans. Compon. Packag. Technol. 25(1), 120–131 (2002)
Dunn, F.: 3D Math primer for graphics and game development. Wordware, Texas, USA (2002)
EPCOS, Electronic Parts and Components (2005) General technical information ultracapacitor technology. www.epcos.com/ultracapacitor.htm
Garcia, R., Valavanis, K., Kontitsis, M.: A high power, inexpensive on-board vision system for miniature unmanned VTOL vehicles. Tech. Rep. 4, CRASAR, USF (2005)
Gavrichenkov, I.: CPU Category – Intel Pentium D 820 CPU Review, Page 3, 05/27/2005. http://www.xbitlabs.com/articles/cpu/display/pentiumd-820_3.html (2006)
Intel United States: Mobile Intel Pentium 4 ProcessorsM, Enhanced Intel SpeedStep Technology. http://www.intel.com/support/processors/mobile/pentium4/sb/cs-007499.htm (2006)
Intel United States: Mobile Intel Pentium 4 ProcessorsM, Voltage Requirements. http://www.intel.com/support/processors/mobile/pentium4/sb/cs-007501.htm (2006)
King, A.D.: Inertial navigation-40 years of evolution. GEC Rev. 13(3), 140–149 (2003)
Laboratories, S.N.: Robotics online – fuel cell powered mobile robots case study. http://www.roboticsonline.com/public/articles/index.cfm?cat=99 (2006)
Latt, M., Leis, J., Arulepp, M., Kuura, H., Lust, E.: Latest developments in carbide derived carbon for energy storage applications. In: Proc. of 16th International Seminar on Double Layer Capacitors and Hybrid Energy Storage Devices (2006)
Mastragostino, M.: Electrochemical Supercapacitors in Advances in Lithium Ion Batteries chap. 16. Kluwer Academic/Plenum (2002)
Maxwell Technologies: Ultracapacitor application notes. www.maxwell.com/ultracapacitors/support/app_notes.html (2005)
Meng, N.: Feasibility study of renewable hydrogen in Hong Kong. Research Seminar on Thermofluid Mechanics (2004)
Mullens, K., Pacis, E., Stancliff, S., Burmeister, A., Denewiler, T., Bruch, M., Everett, H.: An automated UAV mission system. In: AUVSI Unmanned Systems in International Security, SPAWAR Systems Center, Allied Aerospace (2003)
Ozpineci, B., Tolbert, L.M., Su, G., Du, Z.: Optimum fuel cell utilization with multilevel DC-DC converters. In: Proc. of Nineteenth Annual IEEE Applied Power Electronics Conference and Exposition (APEC’04), vol. 3, pp. 1572–1576 (2004)
Pappas, G., Rosenfeld, R., Beam, A.: The ARPA/Navy unmanned undersea vehicle program. Unmanned Systems 11(2), 41–44 (1993)
Rosenfeld, R.L., Prokopius, P.R., Meyer, A.P.: Fuel cell power system development for submersibles. In: Proc. of the 1992 Symposium on Autonomous Underwater Vehicle Technology, pp. 184–188 (1992)
Smith, R.: Open Dynamics Engine. http://www.ode.org/ (2005)
Sourceforgenet: Player/stage/gazebo project page. http://playerstage.sourceforge.net/ (2005)
Space and Naval Warfare Systems Command: Joint robotics program, tech database, robotic platforms, unmanned ground vehicles, ATRV-Jr specifications. http://robot.spawar.navy.mil/images/database/Platforms/UGV/doc/atrvjr_tech_2001.pdf (2005)
Storvik, M.: Guidance system for automatic approach to a ship. Master’s thesis, Norwegian University of Science and Technology (2003)
Sunwize Technologies, Inc: Homepage. http://www.sunwize.com/ (2005)
Swider-Lyons, K.E., Carlin, R.T., Rosenfeld, R.L., Nowak, R.J.: Technical issues and opportunities for fuel cell development for autonomous underwater vehicles. In: Proceedings of the 2002 Workshop on Autonomous Underwater Vehicles, pp. 61–64 (2002)
Wilhelm, A., Pharoah, J., Surgenor, B.: Fuel cell today – fuel cells and mobile robots. http://www.fuelcelltoday.com/FuelCellToday/FCTFiles/FCTArticleFiles/Article_933_FuelCellsandMobileRobots.pdf (2006)
Yamamoto, I., Aoki, T., Tsukioka, S., Yoshida, H., Hyakudome, T., Sawa, T., Ishibashi, S., Inada T., Yokoyama, K., Maeda, T., lshiguro, S., Hirayama, H., Hirokawa, K., Hashimoto, A., Hisatome, N., Tani, T.: Fuel cell system of AUV urashima. In: Proc. of OCEANS’04 MTS/IEEE TECHNO-OCEAN’04, 3, 1732–1737 (2004)
Zheng, F., Garg, N., Sobti, S., Zhang, C., Joseph, R.E., Krishnamurthy, A., Wang, R.Y.: Considering the energy consumption of mobile storage alternatives. 11th IEEE/ACM International Symposium on Modeling, Analysis and Simulation of Computer Telecommunications Systems, MASCOTS 2003, pp. 36–45, 12–15 October 2003
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This work was supported by the US Army Research Office, Grant Number W91-11NF-06-1-0069 and SPAWAR, Grant Number N00039-06-C-0062.
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Ioannou, S., Dalamagkidis, K., Valavanis, K.P. et al. Improving Endurance and Range of a UGV with Gimballed Landing Platform for Launching Small Unmanned Helicopters. J Intell Robot Syst 53, 399–416 (2008). https://doi.org/10.1007/s10846-008-9243-4
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DOI: https://doi.org/10.1007/s10846-008-9243-4