A Nonlinear Robust Controller Design for Ship Dynamic Positioning Based on <svg xmlns:xlink="http://www.w3.org/1999/xlink" xmlns="http://www.w3.org/2000/svg" style="vertical-align:-4.1996pt" id="M1" height="15.599pt" version="1.1" viewBox="-0.0657574 -11.3994 17.6499 15.599" width="17.6499pt"><g transform="matrix(.017,0,0,-0.017,0,0)"><path id="g113-77" d="M541 160L512 170C485 116 462 88 439 67C411 41 376 35 318 35C272 35 238 37 224 48C207 61 205 85 212 121L290 533C305 611 308 615 391 622L397 650H139L133 622C217 615 221 612 206 533L126 118C111 41 103 34 23 26L17 0H474C489 31 528 124 541 160Z"/></g><g transform="matrix(.012,0,0,-0.012,10.948,4.134)"><path id="g50-51" d="M414 144C384 79 371 75 317 75H135L276 221C367 316 408 376 408 465C408 570 327 635 237 635C179 635 131 609 100 575L42 494L67 471C94 510 138 565 205 565C277 565 321 517 321 435C321 348 258 270 195 195C146 137 88 81 33 26V0H411C423 44 433 88 446 135L414 144Z"/></g></svg>-Gain Disturbance Rejection

Xia, Guoqing; Xue, Jingjing; Guo, Ang; Liu, Caiyun; Chen, Xinghua

doi:https://doi.org/10.1155/2016/9275065

Journal of Control Science and Engineering

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Research Article | Open Access

Volume 2016 | Article ID 9275065 | https://doi.org/10.1155/2016/9275065

A Nonlinear Robust Controller Design for Ship Dynamic Positioning Based on -Gain Disturbance Rejection

Guoqing Xia,¹Jingjing Xue,¹Ang Guo,¹Caiyun Liu,¹and Xinghua Chen¹

Academic Editor: Defeng He

Received01 Aug 2016

Accepted22 Sept 2016

Published01 Nov 2016

Abstract

In ship motion control process, it is difficult to design ship controller due to the effects of environmental disturbances such as wind, waves, current, and unmodelled dynamics. In order to solve these problems, a nonlinear robust controller based on -gain disturbance rejection is proposed in this paper. To steer ships to the desired position, an error feedback control law on account of Lyapunov functions is designed. Then, to satisfy the -gain disturbance rejection, proper parameters are chosen based on the system dissipative property. In order to verify the performance of the proposed controller, the MATLAB simulation results in two situations which are without and with the effects of environmental disturbances are demonstrated.

1. Introduction

With the exploration and exploitation of ocean resource and improvement of modern technology, ship Dynamic Positioning (DP) control system is increasingly utilized on floating vessel or platform control systems. DP is defined as follows: “Only depend on the propeller can automatically keep the position of floating structure (maintaining in fixed position or presetting tracked for equipment or ship)” [1]. DP control process has experienced several stages, from Proportion Integration Differentiation (PID) control, advanced output feedback control, to nonlinear adaptive control and hybrid control, especially for hybrid DP control which automatically switched among controller set, improving the performance and maneuverability of DP ships [2].

But in ship motion control process, it is difficult to design ship controller due to effects of environmental disturbances such as wind, waves, current, and unmodelled dynamics. And among control methods of DP system, fuzzy control, backstepping control, neural network control, and hybrid control (see, e.g., [3–10]) are commonly used. Not depending on ship’s accurate model, robust fuzzy control by using optimal control technique on DP ships was designed and had good performance in disturbance rejection and fast response and had good robustness [4]. In order to eliminate the effects of uncertainties, backstepping control method was applied to construct appropriate virtual control law. And neural network control of DP ships was utilized to solve the problem of approximate of uncertainties and unmodelled items [5]. Bateman et al. [6] developed a backstepping method improving ability of control response and disturbance rejecting performance under the low and high gain. And the article [11] designed a recursive backstepping controller to maintain ship in fixed position and the controller had good performance of response and maneuvering motion. Chen et al. [12–14] proposed the finite time tracking control method to handle the problem of external disturbances and had good performance. The hybrid control was designed to switch the control situation automatically and had good performance to reject changes of external environment [3]. All of these papers proposed kind of methods to solve the problem of environmental disturbances.

In addition, the key to these designed control methods is to ensure system stabilization. -gain disturbance rejection is especially used to reduce effects of disturbances by choosing proper control schemes and has good performance and robustness. An optimal -gain disturbance rejection control for linear system was designed based on Lyapunov-Krasovskii theories [15]. López-Martínez et al. [16] applied the problem of disturbance rejection to a twin-rotor system and designed the control law with PID control to make system stability in variable speed rotors. Paper [17] designed an uncertain switched nonlinear system to solve the problem of -gain. In order to handle the external disturbance and input constraint, Xiao et al. [18] proposed an adaptive -gain controller in the condition of attitude tracking in flexible spacecraft. Ahmed [19] proposed an -gain disturbance rejection neural controller for nonlinear system. Paper [20] designed a disturbance rejection control method in the base of the theories of -gain and port-controlled Hamiltonian system. In this paper, based on -gain disturbance rejection, the nonlinear robust controller is designed to steer the DP ships to the desired position and solve problems of uncertainties and unmodelled dynamics.

The structure of this paper is organized as follows. Section 2 states the control problem of DP ships subject to uncertain terms and disturbances. Section 3 presents the design of the nonlinear robust controller based on -gain disturbance rejection. MATLAB simulation results without and with the effects of environmental disturbances are demonstrated to verify the effectiveness of the proposed controller.

2. Problem Formulation

2.1. DP Ships’ Kinematics and Dynamics

In order to analyze DP ships’ kinematics, two reference coordinate systems which include Earth-fixed frame - and Body-fixed frame - are introduced in this paper. 3-Degree-Of-Freedom (3 DOF) horizontal motion (surge, sway, and yaw) is usually researched in DP control system. And the relationship between Earth-fixed frame and Body-fixed frame is shown as Figure 1.

For the DP control system, the kinematics and dynamics in low speed condition [21] are described as follows:where, is the vehicle’s position vector in Earth-fixed frame. represents the velocities in Body-fixed frame. is the system inertial matrix, represents the strictly positive linear damping matrix, and is the forces and moments vector produced by thrusters. is a vector of forces and moments produced by slowly varying environmental disturbances and unmodelled items. is the transformation matrix between Earth-fixed frame and Body-fixed frame expressed by

2.2. Control Objective

The DP control system is to steer the ship to maintain a fixed position or preset tracked position. The desired position vector is . The control objective is to design a nonlinear robust control law and choose proper parameters which satisfy the -gain disturbance rejection constrains. Thus the position is accurately approached to the desired position .

3. Nonlinear Robust Controller Design Based on -Gain Disturbance Rejection

In this section, in order to design a backstepping nonlinear robust controller based on disturbance rejection and achieve the control object, the nonlinear robust controller is designed to steer the DP ship to the desired position and solve problems of uncertainties and unmodelled dynamics. The following dynamic equation of DP ship is derived from (1):

With defining the error as , the following error dynamic equation based on (3) is written as Simply, letThus, the error dynamic equation (4) is rewritten as

3.1. -Gain Disturbance Rejection

-gain disturbance rejection is used to reduce the effect of disturbances by choosing proper parameters. In order to analyze the -gain disturbance rejection of a control system, the definitions of -gain and system dissipation are introduced in following part. And -gain can be determined by considering the following nonlinear system [15]: where, is the state vector of system; represents the input signal; is output vector; , , and represent the given function vector or matrix.

Assumption 1. The system is a free system and has an equilibrium point, that is when . At the same time, assume ; thus for any , , there exists when -norm satisfied the condition ofTherefore, -norm is called -gain which is less than or equal to . And is called disturbance rejection factor.

Assumption 2. If a positive semidefinite function , the following inequality is established when For any and any input signal , the system is called passive system when inequality (9) is established. And inequality (9) is called dissipative inequality, is energy storage function, and is the energy storage function.
Consider the following system:where is the state vector of system; represents input signal; is output vector; represents disturbance input signal; represents evaluation function with characterization of disturbance rejection performance; , , , , and are smooth functions with appropriate dimension or matrix. And the dissipative inequality of system (10) is where is energy storage function with the property of positive semidefinite. Thus the disturbance rejection problem is solved by inequality of (11).

3.2. DP Nonlinear Backstepping Controller Design

DP’s nonlinear control law is designed based on backstepping theory. The control law is designed by error dynamic equation (6) as

Thus (6) can be rewritten as

In order to design the disturbance rejection control law , define the error varieties aswhere is to be designed as parameter matrix; at the same time, let

Thus, combining (13), (14), and (15), the derivative of and is determined as

In order to prove the stability of subsystem in (14), Lyapunov function is defined as

Thus, the deviation of is determined as

, when , so the subsystem with is stabilization. And to prove the stability of , Lyapunov function is defined as

Thus deviation of is determined as

Combine (16) and (20), so

Design the feedback control law aswhere is to be designed as parameter. And plug (22) into (21), so (21) is rewritten as

Thus, if

If , consider the following inequality:

Let , then

when the following error inequality is workable:where is the upper bound of . Thus the subsystem with is stabilization. Thus the Lyapunov stability can be proved based on the above equations from (13) to (26). And the control law is to be designed to make the system stable under disturbance rejection.

3.3. Efficiency Proof of -Gain Disturbance Rejection

The control law is derived above without considering the capacity of disturbance rejection. And -gain disturbance rejection of the robust nonlinear controller in this section is proved.

First, evaluation function mentioned in Section 3.2 is shown as where are the weighted factors. In order to prove the efficiency of -gain disturbance rejection, the following dissipative inequality needs to be proved:

Define auxiliary function as

Combining (29) with (30), the auxiliary function is rewritten as

If the parameters are designed to satisfy the following inequality:

Thus ; that is,

Therefore,

Parameters should satisfy inequality (32); thus the efficiency of disturbance rejection can be proved. Therefore the control law is designed as

4. Simulation Results

To verify the performance of proposed robust nonlinear controller based on -gain disturbance rejection, it is assessed in the MATLAB simulation environment with a 3-DOF nonlinear model of DP ship. The desired position vector can be given as follows:

The initial position and attitude vector is

The inertia matrix and damping matrix are given as

The simulating time is 100 s and the step time is 0.2 s. The desired position is a step signal and its derivate is not to be determined. In order to generate the smoothly desired path, the 2-order filter is applied aswhere is the natural frequency, is the relative damping ratio, and is the designed parameter. Thus the desired position is generated smoothly and the figure of the desired path is shown as Figure 2.

And to validate the effectiveness of controller, two groups of simulating results are demonstrated without and with the effects of environmental disturbances. And let the slowly varying environmental disturbances be

In one situation, without the effects of environmental disturbances, the outputs of ship motion curves (such as the position, position error, and control law ) are shown as Figures 3, 4, and 5. And the parameters in the designed control law are chosen as

From Figures 3, 4, and 5, the desired path is well approached by the real simulating motion path. And the designed control law effectively steers the ship motion to the desired position though the position error changing in some upper and lower bounds.

The other situation is with the effects of environmental disturbances; the outputs of ship motion curves are demonstrated from Figures 6, 7, and 8. In this condition, the desired path is well approached by the real simulating motion path, and the designed control law effectively controls the ship motion to the desired position although the control law is in shock at the first 10 s. And the position error also can be changed in some acceptable ranges.

5. Conclusions

In this paper, the problem of Dynamic Positioning for offshore structures has been researched under the nonlinear robust controller based on -gain disturbance rejection. At first, the nonlinear controller is designed based on robust nonlinear control theories and the efficiency of disturbance rejection is proved by designing the parameters. Then, two groups of simulating results are demonstrated without and with the effects of environmental disturbances. And the simulating results validate the performance of the controller.

Competing Interests

The authors declare that there are no competing interests regarding the publication of this paper.

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Copyright

Copyright © 2016 Guoqing Xia et al. This is an open access article distributed under the Creative Commons Attribution License, which permits unrestricted use, distribution, and reproduction in any medium, provided the original work is properly cited.

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