Linear Matrix Inequalities in multivariable ship’s steering

Rybczak, Monika

doi:10.2478/v10012-012-0021-7

Cited by 6 publications

(4 citation statements)

References 8 publications

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“…The simulation model is based on papers of W. Gierusz as shown in [19,20]. It belong to 3DOF class, and takes into account movement on a single plane without including list, trim and draught during Silm Lake trials as described in [21,22].…”

Section: Training Shipmentioning

confidence: 99%

Improvement of control precision for ship movement using a multidimensional controller

Rybczak

2018

Automatika

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This paper presents the influence of a first stage inertial element on the operation of a state space controller for a third dimension object. First chapter presents a brief introduction to linear matrix inequalities as one of the methods of controller analysis and synthesis, with examples, and helps to places the below paper in this wide field of science. Chapter two presents the controlled object, which is a model of a very large crude carrier (VLCC) ship, called Blue Lady, along with its mathematical state space model. Chapter three shows state space controller design using numerical methods of linear equalities optimization, where the given values are u longitudinal, v lateral and r rotational velocities. Presented there is also the implementation method of an inertial element to a multidimensional object for space state controller synthesis. Chapter four shows computer simulation results and focuses on showing influence of the proposed design on control error of the multidimensional closed loop system. Finally, chapter five concludes and comments simulation results and shows possible direction of future studies. ARTICLE HISTORY

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Section: Training Shipmentioning

confidence: 99%

Improvement of control precision for ship movement using a multidimensional controller

Rybczak

2018

Automatika

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“…The other factors require the application of nonlinear control methods developed in academic communities and tested on models or training ships. The first group of such methods applies control theory extensions, namely (sample references given only): model reference adaptive control [3], linearization by feedback [4], H∞ robust control and matrix inequalities [5,6], sliding mode [7,8], and backstepping [9,10]. The second group refers to solutions acquired from artificial intelligence, such as: fuzzy logic [11], neural networks [12] or other [13].…”

Section: Introductionmentioning

confidence: 99%

Consistent Design of PID Controllers for an Autopilot

Świder

Trybus

Stec

2023

Polish Maritime Research

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A consistent approach to the development of tuning rules for course-keeping and path-tracking PID controllers for a ship autopilot are presented. The consistency comes from the observation that for each of the controllers the controlled plant can be modelled by an integrator with inertia. In the case of the course controller, it is the well-known Nomoto model. The PID controller may be implemented in series or parallel form, the consequence of which is a 2nd or 3rd order of the system, specified by a double or triple closed-loop time constant. The new tuning rules may be an alternative to the standard ones given in [1,2]. It is shown that, whereas the reference responses for the standard and new rules are almost the same, the new rules provide better suppression of disturbances such as wind, waves or current. The parallel controller is particularly advantageous. The path-tracking PID controller can provide better tracking accuracy than the conventional PI. Simulated path-tracking trajectories generated by a cascade control system are presented. The novelty of this research is in the theory, specifically in the development of new tuning rules for the two PID autopilot controllers that improve disturbance suppression.

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“…The further development of control algorithms used in dynamic positioning systems was associated with the emergence of alternative control strategies such as robust control [55][56][57][58][59][60][61][62][63], modal control [64,65], adaptive control [66] and model predictive control [46,[67][68][69]. Other solutions for control systems were related to the developments taking place in non-linear control [70,71] using methods such as backstepping [72][73][74][75][76][77][78], dynamic surface control [79,80], active direct surface control [81], nonlinear PID control [18,82,83], port-Hamiltonian framework [84] and sliding mode control [85][86][87].…”

Section: Introductionmentioning

confidence: 99%

Control of Dynamic Positioning System with Disturbance Observer for Autonomous Marine Surface Vessels

Tomera

Podgórski

2021

Sensors

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The main goal of the research is to design an efficient controller for a dynamic positioning system for autonomous surface ships using the backstepping technique for the case of full-state feedback in the presence of unknown external disturbances. The obtained control commands are distributed to each actuator of the overactuated vessel via unconstrained control allocation. The numerical hydrodynamic model of CyberShip I and the model of environmental disturbances are applied to simulate the operation of the ship control system using the time domain analysis. Simulation studies are presented to illustrate the effectiveness of the proposed controller and its robustness to external disturbances.

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Linear Matrix Inequalities in multivariable ship’s steering

Cited by 6 publications

References 8 publications

Improvement of control precision for ship movement using a multidimensional controller

Improvement of control precision for ship movement using a multidimensional controller

Consistent Design of PID Controllers for an Autopilot

Control of Dynamic Positioning System with Disturbance Observer for Autonomous Marine Surface Vessels

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