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Velocity controller for a class of vehicles

Autorzy
Identyfikatory
Warianty tytułu
Języki publikacji
EN
Abstrakty
EN
This paper addresses the problem of velocity tracking control for various fully-actuated robotic vehicles. The presented method, which is based on transformation of equations of motion allows one to use, in the control gain matrix, the dynamical couplings existing in the system. Consequently, the dynamics of the vehicle is incorporated into the control process what leads to fast velocity error convergence. The stability of the system under the controller is derived based on Lyapunov argument. Moreover, the robustness of the proposed controller is shown too. The general approach is valid for 6 DOF models as well as other reduced models of vehicles. Simulation results on a 6 DOF indoor airship validate the described velocity tracking methodology.
Rocznik
Strony
43--58
Opis fizyczny
Bibliogr. 31 poz., fig., tab.
Twórcy
autor
  • Chair of Control and Systems Engineering, Poznan University of Technology, ul. Piotrowo 3a, 60-965 Poznan, Poland
autor
  • Chair of Control and Systems Engineering, Poznan University of Technology, ul. Piotrowo 3a, 60-965 Poznan, Poland
Bibliografia
  • [1] Adamski W., Herman P., Bestaoui Y., Kozlowski K., Control of Airship in Case of Unpredictable Environment Conditions Proceedings of the 2010 Conference on Control and Fault Tolerant Systems, Nice, France, October 6-8, 2010, 843–848.
  • [2] Ashrafiuon H., Muske K.R., McNinch L.C., Soltan R.A., Sliding-Mode Tracking Control of Surface Vessels IEEE Transactions on Industrial Electronics, 55, 11, 2008, 4004-4012.
  • [3] Azinheira J.R., Moutinho A., Hover Control of an UAV With Backstepping Design Including Input Saturations IEEE Transactions on Control Systems Technology, 16, 3, 2008, 517–526.
  • [4] Bestaoui Y., Dynamique dirigeable AS500 complete archive Unpublished report, 2007.
  • [5] Breivik M., Hovstein V.E., Fossen T.I., Straight-Line Target Tracking for Unmanned Surface Vehicles Modeling, Identification and Control, 29, 4, 2008, 131–149.
  • [6] Caharija W., Pettersen K.Y., Sorensen A.J., Candeloro M., Gravdahl J.T., Relative velocity control and integral line of sight for path following of autonomous surface vessels: Merging intuition with theory Proceedings of IMechE Part M: J Engineering for the Maritime Environment, 228, 2, 2014, 180–191.
  • [7] Chwa D., Global Tracking Control of Under actuated Ships With Input and Velocity Constraints Using Dynamic Surface Control Method IEEE Transactions on Control Systems Technology, 19, 6, 2011, 1357–1370.
  • [8] Ferreira B., Matos A., Cruz N., Pinto M., Modeling and Control of the MARES Autonomous Underwater Vehicle Marine Technology Society Journal, 44, 2, 2010, 19–36.
  • [9] Fischer N., Hughes D., Walters P., Schwartz E.M., Dixon W.E., Nonlinear RISE-Based Control of an Autonomous Underwater Vehicle IEEE Transactions on Robotics, 30, 4, 2014, 845–852.
  • [10] Fossen T.I., Guidance and Control of Ocean Vehicles John Wiley and Sons, Chichester, 1994.
  • [11] Fukao T., Fujitani K., Kanade T., Image-based Tracking Control of a Blimp Proceedings of the 42nd IEEE Conference on Decision and Control, Maui, Hawaii USA, December, 2003, 5414–5419.
  • [12] Garcia-Valdovinos L.G., Salgado-Jimenez T., Bandala-Sanchez M., Nava-Balanzar L., Hernandez-Alvarado R., Cruz-Ledesma J.A., Modelling, Design and Robust Control of a Remotely Operated Underwater Vehicle International Journal of Advanced Robotic Systems, 11, 1, 2014, 1–16.
  • [13] Hayashi R., Osuka K., Ono T., Trajectory Control of an Air Cushion Vehicle Proceedings of the IEEE/RSJ/GI International Conference on Intelligent Robots and Systems ‘94, Advanced Robotic Systems and the Real World, IROS, 1994, 1906–1913.
  • [14] Herman P., Normalized-generalized-velocity-component-based controller for a rigid serial manipulator IEE Proceedings - Control Theory & Applications, 152, 2005, 581–586.
  • [15] Herman P., About inertial quasi-velocities interpretation and possible application International Journal of Robotics and Automation, 25, 4, 2010, 352–358.
  • [16] Herman P., Modified set-point controller for underwater vehicles Mathematics and Computers in Simulation, 80, 2010, 2317–2328.
  • [17] Lapierre L., Soetanto D., Nonlinear path-following control of an AUV Ocean Engineering, 34, 2007, 1734–1744.
  • [18] Lefeber E., Pettersen K.Y., Nijmeijer H., Tracking control of an under actuated ship IEEE Transactions on Control Systems Technology, 11, 1, 2003, 52–61.
  • [19] Loduha T.A., Ravani B., On First-Order Decoupling of Equations of Motion for Constrained Dynamical Systems Transactions of the ASME Journal of Applied Mechanics, 62, 1995, 216–222.
  • [20] Moutinho A., Mirisola L., Azinheira J., Dias J., Project DIVA: Guidance And Vision Surveillance Techniques for an Autonomous Airship, In: Robotics Research Trends, Xing P. Guo (Ed.) Nova Science Publishers, Inc., New York, 2007, 77–120.
  • [21] Munoz-Mansilla R., Chaos D., Aranda J., Díaz J.M., Application of quantitative feedback theory techniques for the control of a non-holonomic under actuated hovercraft IET Control Theory and Applications, 6, 14, 2012, 2188–2197.
  • [22] Neff A.E., Lee D., Chitrakaran V.K., Dawson D.M., Burg T.C., Velocity Control for a Quad-Rotor UAV Fly-By-Camera Interface Conference Proceedings - IEEE SoutheastCon 2007, Richmond, VA, 22-25 March, 2007, 273–278.
  • [23] Ohata Y., Ushijima S., Nenchev D.N., Development of an indoor blimp robot with internet-based teleoperation capability Proceedings of the 13th IASTED International Conference on Robotics and Applications, Wurzburg, Germany, August 29-31, 2007, 186–191.
  • [24] Pota H.R., Ahmed B., Garratt M., Velocity Control of a UAV using Backstepping Control Proceedings of the 45th IEEE Conference on Decision and Control, San Diego, CA, USA, December 13-15, 2006, 5894–5899.
  • [25] Serres J., Dray D., Ruffier F., Franceschini N., A vision-based autopilot for a miniature air vehicle: joint speed control and lateral obstacle avoidance Autonomous Robots, 49, 2008, 103–122.
  • [26] Skjetne R., Fossen T.I., Kokotovic P.V., Adaptive maneuvering, with experiments, for a model ship in a marine control laboratory Automatica, 41, 2005, 289–298.
  • [27] Slotine J.-J., Li W., Applied Nonlinear Control Prentice Hall, New Jersey, 1991.
  • [28] Wondergem M., Lefeber E., Pettersen K.Y., Nijmeijer H., Output Feedback Tracking of Ships IEEE Transactions on Control Systems Technology, 19, 2, 2011, 442–448.
  • [29] Yamasaki T., Goto N., Identification of Blimp Dynamics via Flight Tests Transactions of the Japan Society for Aeronautical and Space Sciences, 46, 153, 2003, 195–205.
  • [30] Yoon S.-M., Hong S., Park S.-J., Choi J.-S., Kim H.-W., Yeu T.-K., Track velocity control of crawler type underwater mining robot through shallow-water test Journal of Mechanical Science and Technology, 26, 10, 2012, 329–298.
  • [31] Zufferey J.-Ch., Guanella A., Beyeler A., Floreano D., Flying over the reality gap: From simulated to real indoor airships Autonomous Robots, 21, 2006, 243-254.
Uwagi
Opracowanie ze środków MNiSW w ramach umowy 812/P-DUN/2016 na działalność upowszechniającą naukę (zadania 2017).
Typ dokumentu
Bibliografia
Identyfikator YADDA
bwmeta1.element.baztech-c5850c1a-35d3-4bad-bfe3-2460ff74cb34
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