An asymptotically stable robust controller formulation for a class of MIMO nonlinear systems with uncertain dynamics

Abstract-This work concentrates on tracking control of dynamically positioned surface vessels with asymmetric added mass terms affecting the system model at the acceleration level. Specifically, we propose a novel continuous robust controller for surface vessels that, in addition to asymmetric added mass in its inertia matrix, contains unstructured uncertainties in all its system matrices. The proposed controller compensates the overall system uncertainties and ensures asymptotic tracking, while requiring only the knowledge of the sign of the leading principle minors of the input gain matrix. Lyapunov based approaches are applied in order to prove the stability of the closed-loop system and asymptotic convergence of the tracking error signal.

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“…Proof: The proof is similar to that of the one given in [24], it can also be found in Appendix B of [23].…”

Section: Stability Analysismentioning

confidence: 68%

“…Proof: Due to page limitations, only a highlight of the proof is provided. The reader is referred to [23] for a similar proof. The non-negative function V 1 (z) ∈ R is defined as…”

Section: Stability Analysismentioning

confidence: 94%

A robust tracking controller for dynamically positioned surface vessels with added mass

Bıdıklı

Tatlıcıoğlu

Zergeroğlu

2014

53rd IEEE Conference on Decision and Control

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“…The most general case of the proof is given in Appendix D of [17]. The proof for the Theorem 2 can be obtained by using 2, 3, λ 1 , λ 2 , λ 3 and Γ instead of n, m, λ 2 , λ 3 , λ 4 and α given in the mentioned study, respectively.…”

Section: Stability Analysismentioning

confidence: 99%

Robust control design for positioning of an unactuated surface vessel

Bıdıklı

Tatlıcıoğlu

Zergeroğlu

2015

2015 IEEE/RSJ International Conference on Intelligent Robots and Systems (IROS)

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Abstract-In this paper, a robust controller is designed to achieve accurate positioning of an unactuated surface vessel by using multiple unidirectional tugboats. After initially locating opposing tugboats to specific configurations, the control problem is transformed into a second order system with an uncertain non-symmetric input gain matrix. Upon applying a matrix decomposition, a robust controller is proposed. Detailed stability analysis ensured asymptotic tracking. Numerical simulation results demonstrate the efficiency of the proposed controller. I. INTRODUCTIONThe positioning of large surface vessels like barges, platforms and unactuated ships is considered as the marine example of the swarm robotic applications. Since these types of large vessels can not generate necessary position and orientation control effort due to their low speed operation, they are in need of assistance of multiple tugboats. As a result of this, this objective is realized via a group of tugboats that are strategically positioned along the vessel's hull. Manipulation with multiple tugboats can be seen as a feasible solution for these type of applications. However, the radio communication between all involved tugboats, especially in human manipulated tugboats, affects the control performance dramatically. Although, the communication performance is increased with advanced global positioning systems, control of these type of systems is still a challenging problem because of possible problems that may arise in communication system during manipulation. As a natural result of these, above mentioned marine control problem has attracted attention of the control community.In the last decade, different types of controller designs have been proposed for these type of applications. In [1], orientation tracking control of a unactuated vessel through the utilization of a swarm of vehicles operating in a decentralized fashion was achieved via presented robust control strategy. In order to design this robust controller, the influence of the other swarm vehicle was treated as a force disturbance into the model dynamics. In [2], an exact model knowledge position and orientation tracking controller was proposed for an unactuated surface vessel. In [3], an adaptive position

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“…Provided the entries of the control gain matrix k 1 are chosen to be greater than the upper bound of the auxiliary term N d (t), the proof in [16] can be traced to demonstrate the non-negativeness of P (t).…”

Section: Boundedness/stability Proofmentioning

confidence: 99%

“…The proof of (44) can be found in [15] or in [16]. At this stage, to prove the overall stability of the closedloop system and the asymptotic convergence of the error signals, we define the following non-negative function, denoted by V (t) ∈ R,…”

Section: Boundedness/stability Proofmentioning

confidence: 99%

Lyapunov-based output feedback learning control of robot manipulators

Dogan

Tatlıcıoğlu

Zergeroğlu

et al. 2015

2015 American Control Conference (ACC)

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Abstract-This paper address the output feedback learning tracking control problem for robot manipulators with repetitive desired joint level trajectories. Specifically, an observer-based output feedback learning controller for periodic trajectories with known period have been proposed. The proposed learning controller guarantees semi-global asymptotic tracking despite the existence of parametric uncertainties associated with the robot dynamics and lack of velocity measurements. A learningbased feedforward term in conjunction with a novel observer formulation is designed to obtain the aforementioned result. The stability of the controller-observer couple is guaranteed via Lyapunov based arguments. Numerical studies performed on a two link robot manipulator are also presented to demonstrate the viability of the proposed method.

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An asymptotically stable robust controller formulation for a class of MIMO nonlinear systems with uncertain dynamics

Cited by 8 publications

References 21 publications

A robust tracking controller for dynamically positioned surface vessels with added mass

A robust tracking controller for dynamically positioned surface vessels with added mass

Robust control design for positioning of an unactuated surface vessel

Lyapunov-based output feedback learning control of robot manipulators

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