Sliding mode heading control of an overactuated, hover‐capable autonomous underwater vehicle with experimental verification

Tanakitkorn, Kantapon; Wilson, P.A.; Turnock, S.R.; Phillips, Alexander B.

doi:10.1002/rob.21766

Cited by 47 publications

(19 citation statements)

References 43 publications

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“…The experiment paths were crossed at 0.3, 0.6 and 1.0 m/s surge velocity. They represent low, medium and high speeds for Delphin2 and are well understood from previous experiments on diving control (Tanakitkorn et al, ) and heading control at the surface (Tanakitkorn, Wilson, Turnock, & Phillips, ). During the horizon tracking experiments, the control allocation at 1 m/s speed was varied, to increase the use of thrusters from the default thruster weight of 0 to a factor of 0.5 (“half”) and 1.0 (“full”; see Figure ).…”

Section: Testwood Lake Experiments Set‐upmentioning

confidence: 64%

“…When trying to get within an altitude region close to terrain, the vehicle operator can influence the quality of the results by modifying Table 1), whilst keeping the vehicle submerged throughout the path. (Tanakitkorn et al, 2016) and heading control at the surface (Tanakitkorn, Wilson, Turnock, & Phillips, 2017). During the horizon tracking experiments, the control allocation at 1 m/s speed was varied, to increase the use of thrusters from the default thruster weight of 0 to a factor of 0.5 ("half") and 1.0 ("full"; see Figure 14).…”

Section: Experiments Parameter Variationmentioning

confidence: 99%

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Experimental analysis of low‐altitude terrain following for hover‐capable flight‐style autonomous underwater vehicles

Schillai

Turnock

Rogers

et al. 2019

Journal of Field Robotics

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Operating an autonomous underwater vehicle (AUV) in close proximity to terrain typically relies solely on the vehicle sensors for terrain detection, and challenges the manoeuvrability of energy efficient flight‐style AUVs. This paper gives new results on altitude tracking limits of such vehicles by using the fully understood environment of a lake to perform repeated experiments while varying the altitude demand, obstacle detection and actuator use of a hover‐capable flight‐style AUV. The results are analysed for mission success, vehicle risk and repeatability, demonstrating the terrain following capabilities of the overactuated AUV over a range of altitude tracking strategies and how these measures better inform vehicle operators. A major conclusion is that the effects of range limits, bias and false detections of the sensors used for altitude tracking must be fully accounted for to enable mission success. Furthermore it was found that switching between hover‐ and flight‐style actuations based on speed, whilst varying the operation speed, has advantages for performance improvement over combining hover‐ and flight‐style actuators at high speeds.

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Section: Testwood Lake Experiments Set‐upmentioning

confidence: 64%

Section: Experiments Parameter Variationmentioning

confidence: 99%

Experimental analysis of low‐altitude terrain following for hover‐capable flight‐style autonomous underwater vehicles

Schillai

Turnock

Rogers

et al. 2019

Journal of Field Robotics

Self Cite

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“…Substituting the equation (12) in (11), the cost function can be expressed based on sliding function and its first derivative as follows:…”

Section: (4)mentioning

confidence: 99%

“…A control law for path tracking of marine vessel was adopted in [9], where a singular perturbation method was used to decompose the system into two Lyapunov theory based control subsystems. Some research projects concerning adopting the higher order sliding mode algorithms such as super-twisting for control of the maritime autonomous robots, were carried out in [10,11]. In [12] there were presented two control algorithms for the trajectory tracking of an autonomous marine platform, in which the input constraints and disturbances induced by constant ocean currents were regarded.…”

Section: Introductionmentioning

confidence: 99%

Model Predictive Super-Twisting Sliding Mode Control for an Autonomous Surface Vehicle

Esfahani

Szlapczynski

2019

Polish Maritime Research

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This paper presents a new robust Model Predictive Control (MPC) algorithm for trajectory tracking of an Autonomous Surface Vehicle (ASV) in presence of the time-varying external disturbances including winds, waves and ocean currents as well as dynamical uncertainties. For fulfilling the robustness property, a sliding mode control-based procedure for designing of MPC and a super-twisting term are adopted. The MPC algorithm has been known as an effective approach for the implementation simplicity and its fast dynamic response. The proposed hybrid controller has been implemented in MATLAB / Simulink environment. The results for the combined Model Predictive Super-Twisting Sliding Mode Control (MP-STSMC) algorithm have shown that it significantly outperforms conventional MPC algorithm in terms of the transient response, robustness and steady state response and presents an effective chattering attenuation in comparison with the Super-Twisting Sliding Mode Control (STSMC) algorithm.

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“…Generally, each UUV should have at least 3 moving parts to achieve no less than 5 degrees of freedom (DOFs) movement in a space. Some kinds of UUVs even have 10 moving parts for unique requirements, such as hover-capable (Tanakitkorn et al, 2017). The spindle-shaped UUVs usually have 6 moving parts, including a buoyancy regulation system, a forward main thruster and 4 rudders, which can achieve only 5 DOFs movement in a space.…”

Section: Introductionmentioning

confidence: 99%

Model analysis, design and experiment of a fan-wing underwater vehicle

Gao

Yang

2019

Ocean Engineering

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Sliding mode heading control of an overactuated, hover‐capable autonomous underwater vehicle with experimental verification

Cited by 47 publications

References 43 publications

Experimental analysis of low‐altitude terrain following for hover‐capable flight‐style autonomous underwater vehicles

Experimental analysis of low‐altitude terrain following for hover‐capable flight‐style autonomous underwater vehicles

Model Predictive Super-Twisting Sliding Mode Control for an Autonomous Surface Vehicle

Model analysis, design and experiment of a fan-wing underwater vehicle

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