The Underwater Swimming Manipulator—A Bioinspired Solution for Subsea Operations

Sverdrup-Thygeson, Jørgen; Kelasidi, Eleni; Pettersen, Kristin Y.; Gravdahl, Jan Tommy

doi:10.1109/joe.2017.2768108

Cited by 47 publications

(28 citation statements)

References 47 publications

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“…where T (q) ∈ R 6×m is the thruster configuration matrix, τ thr ∈ R m is the vector of thruster forces, and τ q ∈ R (n−1) represents the joint torques. To implement the control input, a thruster allocation scheme as proposed in [27] needs to be implemented to distribute the desired control inputs onto the thrusters. The vector of body-fixed velocities, ζ, is defined as…”

Section: Modelling and The Tracking Control Problemmentioning

confidence: 99%

Tracking Control of an Articulated Intervention Autonomous Underwater Vehicle in 6DOF Using Generalized Super-twisting: Theory and Experiments

Borlaug

Pettersen

Gravdahl

2021

IEEE Trans. Contr. Syst. Technol.

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The articulated intervention autonomous underwater vehicle (AIAUV) is an underwater swimming manipulator with intervention capabilities. Station-keeping and trajectory tracking are essential for the AIAUV to be able to move in confined spaces and to perform intervention tasks. In this paper, we propose using a generalized super-twisting algorithm (GSTA), which is an extension of the regular super-twisting algorithm, for the trajectory tracking of the position and orientation of the base of the AIAUV in 6DOF. We also propose using a higher-order sliding mode observer (HOSMO) for estimating the linear and angular velocities when velocity measurements are unavailable. Furthermore, we show the ultimate boundedness of the tracking errors for a control law using the GSTA and for a control law that combines the GSTA with a HOSMO. We also prove that the GSTA gives global uniform finite-time stability. Finally, we demonstrate the applicability of the proposed control laws with comprehensive simulation and experimental results.

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Section: Modelling and The Tracking Control Problemmentioning

confidence: 99%

Tracking Control of an Articulated Intervention Autonomous Underwater Vehicle in 6DOF Using Generalized Super-twisting: Theory and Experiments

Borlaug

Pettersen

Gravdahl

2021

IEEE Trans. Contr. Syst. Technol.

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“…where T (q) ∈ R 6×m is the thruster configuration matrix, τ thr ∈ R m is the vector of thruster forces and τ q ∈ R (n−1) represents the joint torques. To implement the control input τ (q), a thruster allocation scheme as proposed in [26] needs to be implemented to distribute the desired control inputs onto the m thrusters. The vector of body-fixed velocities, ζ, is defined as…”

Section: Modelling and The Tracking Control Problemmentioning

confidence: 99%

“…Theorem 1: Consider the error dynamics given by (13) and let the sliding surface σ be defined by (15). Let the control input be given by (26). Then, the closed-loop dynamics is described by (28), and the origin of this cascade system is uniformly globally asymptotically stable (UGAS), which ensures the asymptotic convergence of the tracking error when…”

Section: A Overall Closed-loop Dynamicsmentioning

confidence: 99%

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Tracking control of an articulated intervention AUV in 6DOF using the generalized super-twisting algorithm

Borlaug

Pettersen

Gravdahl

2019

2019 American Control Conference (ACC)

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The articulated intervention AUV (AIAUV) is an underwater swimming manipulator (USM) with intervention capabilities. Station-keeping and trajectory tracking are essential for the AIAUV to be able to move in confined spaces and to perform intervention tasks. In this paper we propose using the generalized super twisting algorithm, which is an extension of the regular super-twisting algorithm, for the trajectory tracking of the joint angles, position and orientation of the base of the AIAUV in 6DOF. Furthermore, we show the ultimate boundedness of the tracking errors. We also demonstrate the applicability of the proposed control law and compare the performance with the regular super-twisting algorithm with adaptive gains.

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“…The performance of the motor also directly determines the control accuracy of the arm. Therefore, it is important to select a suitable motor [12]. Through the analysis of the requirements of the mechanical arm test performance to be satisfied by the underwater manipulator test platform, the selection of the motor needs to be satisfied, the high torque supports load, high precision, and the rotation and stop.…”

Section: B Motor Designmentioning

confidence: 99%

Underwater Robotic Arm Test Platform

Junwei¹,

Shuzhao²,

Wang³

et al. 2019

Proceedings of the 2019 International Conference on Precision Machining, Non-Traditional Machining and Intelligent Manufacturin

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For the problem that the mechanical arm is unstable under water and the position accuracy is low. This paper designed an underwater manipulator test platform. Good attitude control and high grip accuracy can be achieved. Through the analysis of the mechanical body, the overall structural layout of the mechanical arm and the hardware control of the mechanical arm are determined. Considering the working requirements of the test platform is to meet the load-bearing weight of 30kg, the operating range is not less than 400mm, etc., and design a motor suitable for this platform. Finally, stress simulation and finite element analysis of the load-bearing parts (U-shaped plate) of the platform are carried out. The results show that the maximum displacement of the U-shaped bottom plate is located in the middle of the bottom plate, which is approximately 4.553e-0.002mm. The maximum stress is 1.505e+0.007N/m^2. The yield stress of the material is 6.204e+0.008N/m^2, which satisfies the requirement of yield stress. Prove that the design is reasonable.

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The Underwater Swimming Manipulator—A Bioinspired Solution for Subsea Operations

Cited by 47 publications

References 47 publications

Tracking Control of an Articulated Intervention Autonomous Underwater Vehicle in 6DOF Using Generalized Super-twisting: Theory and Experiments

Tracking Control of an Articulated Intervention Autonomous Underwater Vehicle in 6DOF Using Generalized Super-twisting: Theory and Experiments

Tracking control of an articulated intervention AUV in 6DOF using the generalized super-twisting algorithm

Underwater Robotic Arm Test Platform

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