A dynamic model and a robust controller for a fully-actuated marine surface vessel

A nonlinear six degree-of-freedom dynamic model is presented for a marine surface vessel. The formulation closely follows the current literature on ship modeling. It considers the effects of inertial forces, wave excitations, retardation forces, nonlinear restoring forces, wind and current loads along with linear viscous damping terms. The capability of the model is shown through its prediction of the ship response during a turning-circle maneuver. The ship model is used herein as a test bed to assess the performance of the proposed controller. The present study assumes that the ship is fully actuated and all state variables of the system are available through measurements. A nonlinear robust controller, based on the sliding mode methodology, has been designed based on a reduced-order version of the ship model. The latter accounts only for the surge, sway and yaw motions of the ship. The initial simulation results, generated based on the reduced-order model of the marine vessel, demonstrate robust performance and good tracking characteristics of the controller in the presence of structured uncertainties and external disturbances. Furthermore, they illustrate the adverse effects of the physical limitations of the propulsion system on the controlled response of the ship. Next, the same controller is implemented on the six degree-of-freedom model of the ship. The simulation results reveal tracking characteristics of the controller that are similar to those observed in the initial results, in spite of significantly larger modeling uncertainties.

[1]  David E. Hess,et al.  Neural Network Predictions of the 4-Quadrant Wageningen Propeller Series (CD-ROM) , 2006 .

[2]  Thor I. Fossen,et al.  Path following control system for a tanker ship model , 2007 .

[3]  H. Nijmeijer,et al.  Underactuated ship tracking control: Theory and experiments , 2001 .

[4]  Edward V. Lewis,et al.  Principles of naval architecture , 1988 .

[5]  Thor I. Fossen,et al.  A survey on Nonlinear Ship Control: from Theory to Practice , 2000 .

[6]  John-Morten Godhavn,et al.  Nonlinear tracking of underactuated surface vessels , 1996, Proceedings of 35th IEEE Conference on Decision and Control.

[7]  Thor I. Fossen,et al.  Nonlinear Thrust Controller for Marine Propellers in Four-Quadrant Operations , 2007, 2007 American Control Conference.

[8]  Shyh-Kuang Ueng,et al.  A ship motion simulation system , 2008, Virtual Reality.

[9]  R. M. Isherwood WIND RESISTANCE OF MERCHANT SHIPS , 1972 .

[10]  R. A. Barr,et al.  TECHNICAL BASIS FOR MANEUVERING PERFORMANCE STANDARDS , 1981 .

[11]  J. N. Newman,et al.  Computation of wave effects using the panel method , 2003 .

[12]  Thor I. Fossen A Nonlinear Unified State-Space Model for Ship Maneuvering and Control in a Seaway , 2005, Int. J. Bifurc. Chaos.

[13]  Thor I. Fossen,et al.  Nonlinear output feedback control of dynamically positioned ships using vectorial observer backstepping , 1998, IEEE Trans. Control. Syst. Technol..

[14]  Thor Inge Fossen,et al.  High Performance Ship Autopilot With Wave Filter , 1993 .

[15]  Thor I. Fossen,et al.  Guidance and control of ocean vehicles , 1994 .

[16]  V.-D. Giap,et al.  Control of large ship motions in harbor maneuvers by applying sliding mode control , 2004, The 8th IEEE International Workshop on Advanced Motion Control, 2004. AMC '04..

[17]  W. Janna,et al.  Introduction to Fluid Mechanics , 2012 .

[18]  Olav Egeland,et al.  State-space representation of radiation forces in time-domain vessel models , 2006 .

[19]  Thor I. Fossen,et al.  Nonlinear control of ships minimizing the position tracking errors , 1999 .

[20]  Thor I. Fossen,et al.  Tutorial on nonlinear backstepping: Applications to ship control , 1999 .

[21]  Odd M. Faltinsen,et al.  Sea loads on ships and offshore structures , 1990 .

[22]  Petar V. Kokotovic,et al.  Nonlinear Control of Ships: A Locally Optimal Design , 1998 .